Entries |
Document | Title | Date |
20080200302 | Method of Transmitting the Power of a Hybrid Vehicle Between a Heat Engine Shaft and a Wheel Axle Shaft of the Vehicle - The invention relates to a method of transmitting power between a shaft ( | 08-21-2008 |
20080220934 | HYBRID POWERTRAIN TORQUE CONTROL - A method of regulating a torque output of each of an internal combustion engine (ICE) and an electric machine (EM) in a hybrid powertrain system includes determining a desired axle torque of the hybrid powertrain system and arbitrating the desired axle torque and a first plurality of torque requests in an engine control module (ECM) of the hybrid powertrain system to provide an arbitrated axle torque request. The method further includes arbitrating a torque request, which is based on the arbitrated axle torque request, and a second plurality of torque requests in a hybrid control module (HCM) to provide a final torque request, and generating ICE control signals and EM control signals based on the final torque request. | 09-11-2008 |
20080234098 | METHOD OF OPERATING A HYBRID DRIVE SYSTEM AND HYBRID DRIVE SYSTEM WITH TWO PARTIAL DRIVES - A method of operating a hybrid drive system with a main driving machine | 09-25-2008 |
20080242498 | HYBRID VEHICLE INTEGRATED TRANSMISSION SYSTEM - A transmission for an alternatively powered vehicle includes an accessory unit selectively powered by at least one of an engine and a motor associated with the transmission. Clutches are used to selectively engage and disengage the engine and motor with the accessory unit. | 10-02-2008 |
20080254936 | Differential generation power distribution system - A differential generation power distribution system to drive an all wheel driving carrier by having a rotational kinetic energy output end of a rotational power unit coupled to an intermediate transmission and control interface device containing a main transmission comprised of controllable clutches and gear shifting control means to drive an intermediate differential gear set; one differential output end of the intermediate differential gear set to drive the front end transmission and thus the front end load; another differential output end of the intermediate differential gear set to drive an input end of a rotation part of a first electric machine of the rotational electric machine assembly; the output end of the rotation part of a second electric machine of the rotational electric machine assembly to directly or through the transmission drives the rear end load; and the rotational electric machine assembly for being subject to the drive control device to regulate and control the power distribution between the front end and the rear end loads. | 10-16-2008 |
20080261770 | Control apparatus for hybrid vehicle drive system - A control apparatus for a drive system of a hybrid vehicle including (a) an engine, (b) an electrically controlled differential portion which has a first electric motor, and a differential mechanism operatively connected to the engine and the first electric motor and a differential state of which is controlled by controlling an operating state of the first electric motor, (c) a mechanical transmission portion constituting a part of a power transmitting path, and (d) a second electric motor connected to a power transmitting path between the electrically controlled differential portion and a drive wheel of the hybrid vehicle, the control apparatus including a control portion which is operable when a terminal portion of a shifting action of the mechanical transmission portion and a starting operation of the engine overlap each other, the control portion being configured to implement one of the shifting action and the starting operation prior to the other. | 10-23-2008 |
20080269010 | Control device for vehicular power transmitting apparatus - A vehicle includes a differential portion ( | 10-30-2008 |
20080280726 | HYBRID POWERTRAIN WITH AN ENGINE INPUT CLUTCH AND METHOD OF CONTROL - A powertrain is provided with an input clutch that is disengagable to allow a transmission input member to rotate independently of engine speed under power of a motor and provide an alternative way to power vehicle accessories otherwise driven by engine torque, while still allowing the motor to start the engine. A powertrain having a parallel combination of input clutches including a friction input clutch and a selectable one-way clutch is provided, as well as a method of control of such a powertrain. Another method of controlling a hybrid vehicle powertrain includes starting the engine via torque from a motor with the input clutch biased in an engaged position. If vehicle operating conditions are more efficiently met without operating the engine, the input clutch is disengaged to so that torque is provided only by the motor to the output member and to vehicle accessories operatively connected to the input member. | 11-13-2008 |
20080300100 | Control apparatus for vehicular power transmitting system - A control apparatus for a vehicular power transmitting system including (a) an electrically controlled differential portion which has a differential mechanism and a first electric motor operatively connected to a rotary element of the differential mechanism and which is operable to control a differential state between a rotating speed of its input shaft connected to a drive power source and a rotating speed of its output shaft by controlling an operating state of the first electric motor, (b) a transmission portion ( | 12-04-2008 |
20080305924 | Launch control of a hybrid electric vehicle - A method for controlling a vehicle launch using a transmission having an input, a current gear, an input clutch associated with a target gear and an output, an engine and an electric machine for driving the input, includes the steps of determining a desired magnitude of torque to be produced at the transmission output, producing a predetermined magnitude of torque capacity of the input clutch, operating the engine such that a magnitude of torque at the transmission output is substantially equal to the desired transmission output torque, determining an crankshaft speed error, determining a desired change in torque at the transmission input that will reduce the crankshaft speed error, adjusting a magnitude of torque produced by the first electric machine such that the magnitude of torque at the transmission input is substantially equal to the desired torque at the transmission input, and engaging the input clutch. | 12-11-2008 |
20080305925 | Launch control of a hybrid electric vehicle - A method for controlling a vehicle launch using a transmission having an input, a current gear, an input clutch associated with a target gear and an output, an engine and an electric machine for driving the input, includes the steps of using the engine and the first electric machine to drive the transmission input at a desired magnitude of torque, determining a desired magnitude of torque capacity of the input clutch, determining a crankshaft speed error, determining a magnitude of a change in torque capacity of the input clutch that will reduce the crankshaft speed error, and increasing the torque capacity of the input clutch to a desired torque capacity whose magnitude is determined by adding the current magnitude of torque capacity of the input clutch and said change in torque capacity of the input clutch. | 12-11-2008 |
20080318729 | AUTOMOTIVE DRIVE APPARATUS - An engine, an electric motor-generator, an oil pump, an air conditioner, and a first power transmitting means that performs power transmission among a crank shaft of the engine, a rotating shaft of the electric motor-generator, and rotating shafts of the oil pump and the air conditioner are included. The first power transmitting means has: a crank pulley; a first electric motor-generator pulley; an oil pump pulley; an air conditioner pulley; a first belt that is wound around these pulleys; and a first one-way clutch that is interposed between the rotating shaft and the first electric motor-generator pulley so as to transmit a rotational driving force from the crank shaft to the rotating shaft without transmitting a rotational driving force from the rotating shaft to the crank shaft, and the electric motor-generator is motor driven while the engine is being driven. | 12-25-2008 |
20090005215 | Double step gear shifting in a hybrid electric vehicle - In a powertrain for a vehicle that includes an engine, a transmission having an input, a current gear, an input clutch, a target gear and an output for driving a load, and an electric machine for driving the load, a method for performing a gearshift from the current gear to the target gear comprising the steps of opening the input clutch, releasing a drive connection between the current gear and the output, producing a drive connection between the target gear and the output, using the electric machine to produce torque at the load, closing the input clutch; and reducing the torque produced by the electric machine. | 01-01-2009 |
20090011896 | SPLIT SERIAL-PARALLEL HYBRID DUAL-POWER DRIVE SYSTEM - A split serial-parallel hybrid dual-power drive system, comprised of two or more than two separation drive systems allowing independent operation to respectively drive the load, or all loads driven individually are incorporated in a common frame to drive land, surface, underwater transportation means or aircraft, industrial machines and equipment or any other load drive by rotational kinetic energy. | 01-08-2009 |
20090011897 | SPLIT SERIAL-PARALLEL HYBRID DUAL-POWER DRIVE SYSTEM - A split serial-parallel hybrid dual-power drive system, comprised of two or more than two separation drive systems allowing independent operation to respectively drive the load, or all loads driven individually are incorporated in a common frame to drive land, surface, underwater transportation means or aircraft, industrial machines and equipment or any other load drive by rotational kinetic energy. | 01-08-2009 |
20090011898 | SPLIT SERIAL-PARALLEL HYBRID DUAL-POWER DRIVE SYSTEM - A split serial-parallel hybrid dual-power drive system, comprised of two or more than two separation drive systems allowing independent operation to respectively drive the load, or all loads driven individually are incorporated in a common frame to drive land, surface, underwater transportation means or aircraft, industrial machines and equipment or any other load drive by rotational kinetic energy. | 01-08-2009 |
20090011899 | Method and device for adjusting the friction coefficient of a friction clutch situated in a hybrid power train - A method for adjusting the friction coefficient of a friction clutch situated in a hybrid power train between an electric machine and a combustion engine, actuated by a clutch actuator, the friction coefficient is adjusted by a torque transmitted by the friction clutch, which is determined when starting the combustion engine by the electric machine. | 01-08-2009 |
20090023549 | Electromechanical power transfer system with multiple dynamoelectric machines - An electromechanical power transfer system for a vehicle, comprises: an electrical power source; a system controller; at least two dynamoelectric machines; an electrically engageable clutch for each machine; an input shaft coupled to the jack shaft; an output shaft coupled to a load presented by the vehicle; and at least two electrically engageable transmission gear sets for coupling the input shaft to the output shaft; wherein the system controller selectively engages each machine clutch and each transmission gear set. | 01-22-2009 |
20090029824 | Drive apparatus for vehicle - A drive apparatus for vehicle, available to be minimized, is provided. A first planetary gear set (differential device) | 01-29-2009 |
20090036264 | WORK MACHINE - A work machine enabling a hybrid drive system to be directly driven by energy contained in a return fluid discharged from a hydraulic actuator. The work machine includes a hydraulic actuator control circuit and a swing control circuit. The hydraulic actuator control circuit serves to control hydraulic fluid supplied from pumps of a hybrid drive system to travel motors and work actuators. The swing control circuit serves to control a swing motor generator, which functions as an electric motor and, during braking of rotating motion of the upper structure, functions as a generator. The hydraulic actuator control circuit includes an energy recovery motor provided in a return passage, through which return fluid recovered from a work actuator flows. The energy recovery motor is adapted to be driven by return fluid and thereby drive a motor generator of the hybrid drive system. | 02-05-2009 |
20090042689 | Launch control of a hybrid electric vehicle - A method for controlling the launch of a vehicle having a powertrain that includes a first power path for driving a first wheel set and including an engine, a transmission having an input driveably connected to a crankshaft of the engine, a current gear, an input clutch associated with the current gear and an output connected to first wheel set, and a second power path including an electric machine for driving a second wheel set. The method includes determining a desired magnitude of wheel torque to be produced at the first wheel set, using the desired magnitude of wheel torque to be produced at the first wheel set to determine a magnitude of crankshaft torque, producing a predetermined magnitude of torque capacity at the input clutch, determining a crankshaft speed error, determining a change in magnitude of torque at the crankshaft that will reduce the crankshaft speed error, and operating the engine to produce a desired engine torque, whose magnitude is determined from the change in magnitude of torque at the crankshaft and the magnitude of desired crankshaft torque. | 02-12-2009 |
20090042690 | Control device for vehicle power transmitting apparatus - There is provided correspondence controlling means | 02-12-2009 |
20090054200 | Holding a Hybrid Electric Vehicle on an Inclined Surface - A method for controlling a vehicle powertrain that includes a first power path including a first electric machine driveably connected to a first wheel set and a second power path including a second electric machine driveably connected to a second wheel set, including determining a desired wheel torque required to hold the vehicle stationary on an inclined surface, determining a temperature of the first machine and a first reference temperature, determining a torque capacity of the first power path, and using the first power path to produce the desired wheel torque, if the temperature of the first electric machine is less than the first reference temperature and the torque capacity of the first power path is greater than the desired wheel torque. | 02-26-2009 |
20090054201 | Automotive drive train and method for reducing chatter in the same - The invention relates to a method for reducing chatter in automotive drive train which comprises an internal combustion engine as the drive and a clutch device. According to the method, a rotating component of the drive train is driven by means of the internal combustion engine and the speed of the component is detected. Any chatter is also detected. When chatter occurs, an electric motor is used to transmit a torque onto the rotating component in order to actively dampen the chatter. The rotating component is driven by the electric motor for any chatter component at which the speed of the rotating component decreases and the rotating component is slowed down by the electric motor for any chatter component at which the speed of the rotating component increases. | 02-26-2009 |
20090062061 | Preventing Rollback of a Hybrid Electric Vehicle - In a vehicle powertrain that includes an engine and an electric machine, a method for preventing rollback of a wheeled vehicle located on an incline includes determining a magnitude of wheel torque required to prevent the vehicle from rolling back, using the electric machine to produce the required magnitude of wheel torque at the wheels, transmitting engine torque to the wheels, and reducing torque produced by the electric machine while increasing engine torque such that the sum of wheel torque produced by the engine and electric machine is substantially equal to said required magnitude of wheel torque. | 03-05-2009 |
20090062062 | Method for controlling idle stop mode in hybrid electric vehicle - A method for controlling an idle stop mode in a hybrid electric vehicle is disclosed. The control method accords an oil pressure drain time that a continuously variable transmission clutch oil pressure is fully drained, a final off time of an engine, and a final control time of a motor when a hybrid electric vehicle enters an idle stop mode, thereby preventing a shock or shaking of the vehicle. | 03-05-2009 |
20090062063 | VEHICLE, DRIVING SYSTEM, AND CONTROL METHODS THEREOF - At the time of a Hi-to-Lo speed change of a transmission, which is configured to transmit an output torque of a motor to a driveshaft, in an accelerator off state or in a low acceleration state with the driver's slight depression of an accelerator pedal, an engine is controlled to be driven at a rotation speed of not lower than a speed change-time minimum rotation speed that is higher than an idling rotation speed. When the driver depresses the accelerator pedal to require a large torque demand, such drive control enables quick output of a large torque from the engine to a ring gear shaft as the driveshaft. | 03-05-2009 |
20090069148 | CONTROL ARCHITECTURE AND METHOD FOR ONE-DIMENSIONAL OPTIMIZATION OF INPUT TORQUE AND MOTOR TORQUE IN FIXED GEAR FOR A HYBRID POWERTRAIN SYSTEM - There is provided a control system for a powertrain system including an electro-mechanical transmission operative in a plurality of fixed gear modes and continuously variable modes. The control system is adapted to identify preferred operating conditions for operating the powertrain in a fixed gear operating range state. The method comprises determining a range of permissible input torques. States for input torque are iteratively selected, and a motor torque output from the first electrical machine is optimized based upon the selected state for the input torque. A motor torque output from the second electrical machine is determined based upon the optimized motor torque output from the first electrical machine. A cost for each of the iteratively selected states for the input torque and the motor torques from the first and second electrical machines is calculated. A preferred operating range is identified based upon the plurality of costs. | 03-12-2009 |
20090082171 | Output Split Electrically-Variable Transmission with Electric Propulsion Using One or Two Motors - An electrically-variable transmission is provided with input member and output member, first and second motor/generators, a first planetary gear set and a final drive gearset. Two or three torque-transmitting mechanisms that are selectively engagable alone or in different combinations to establish at least one forward electric-only operating mode including a series mode, an output split mode, and at least one neutral mode including a purely neutral mode and a neutral battery charge mode. The transmission optionally includes a one-way clutch selected from the group of friction clutch and dog clutch, or is a lockable one-way clutch, for enabling low loss forward operation, regenerative braking functionality, and/or reverse vehicle operation. | 03-26-2009 |
20090088290 | VEHICLE DRIVE DEVICE CONTROLLER - A vehicle drive apparatus is disclosed having a differential mechanism and an electric motor provided in the differential mechanism for miniaturizing the drive apparatus or improving fuel consumption while suppressing the occurrence of shifting shocks. A switching clutch C | 04-02-2009 |
20090093336 | Vehicle Creep Control in a Hybrid Electric Vehicle - In a powertrain that includes wheels for driving a vehicle, an engine including a crankshaft, a machine driveably connected to the crankshaft and able to operate alternately as an electric motor and electric generator, a transmission including an input clutch driveably connected to the crankshaft and an output driveably connected to at least two of the wheels, and an electric storage battery having a variable state of charge and electrically connected to the machine, a method for controlling vehicle creep including adjusting a torque capacity of the input clutch to a desired magnitude of input clutch torque transmitted to the wheels, determining a desired change in torque produced by the machine such that a speed of the crankshaft is controlled to a desired idle speed, using the magnitude of input clutch torque capacity and the desired change in torque produced by the machine to determine a desired magnitude machine torque, and using the machine to produce said desired magnitude of machine torque. | 04-09-2009 |
20090093337 | Holding a Hybrid Electric Vehicle on an Inclined Surface - In a powertrain that includes wheels supporting a vehicle, an engine, a first machine able to operate alternately as an electric motor and electric generator, a second machine electric able to operate as an electric motor, and an electric storage battery having a variable state of charge, a method for holding the vehicle stationary on an incline including determining a magnitude of torque at the wheels required to hold the vehicle on the incline, determining whether the state of charge is low or high relative to a reference state of charge, determining whether a temperature of the first machine is low or high relative to a first reference temperature, and whether a temperature of the second machine is low or high relative to a second reference temperature, using the engine and the machines in various combinations to produce the required torque at the wheels. | 04-09-2009 |
20090098976 | Hybrid Powertrain System Having Selectively Connectable Engine, Motor/Generator, and Transmission - A hybrid powertrain having an engine, multi-speed transmission connected to a final drive and not continuously connected to the engine, a single motor/generator connected to an energy storage device and a controller and not continuously connected to the engine or transmission, and three clutches. The first clutch is connected to the engine, the second clutch is connected to the transmission and first clutch, and the third clutch is connected to the motor/generator and first and second clutches. The first and second clutches are operable for selectively interconnecting the engine and transmission; the first and third clutches are operable for selectively interconnecting the engine and motor/generator; the second and third clutches are operable for selectively interconnecting the transmission and motor/generator; and the three clutches are operable for selectively interconnecting the engine, transmission and motor/generator to transmit power therebetween. An engine starter system may be connected to the engine to transmit power to and receive power from the engine. | 04-16-2009 |
20090098977 | Hybrid drive arrangement and method for controlling and/or regulating a starting process with a hybrid drive arrangement - A method is proposed for controlling and/or regulating a starting process in a hybrid drive arrangement of a vehicle, in which at least one control unit ( | 04-16-2009 |
20090105038 | HYBRID DRIVE HAVING A SEPARATING CLUTCH WHICH ASSISTS A DIRECT START - A method for operating a hybrid drive of a vehicle, having an internal combustion engine and having at least one electric drive, to which at least one traction battery is assigned, as well as to a hybrid drive, especially a parallel hybrid drive. The internal combustion engine is able to be started from the operating mode “purely electrical driving” of the hybrid drive using a direct start without a starter. | 04-23-2009 |
20090105039 | METHOD FOR MODEL BASED CLUTCH CONTROL AND TORQUE ESTIMATION - A method for operating a powertrain through selective application of a hydraulically actuated clutch includes monitoring a state of a pressure control switch operatively coupled the clutch, monitoring a hydraulic line pressure utilized by the pressure control switch to fill the clutch, determining a hydraulic flow rate flowing to the clutch based upon the state of the pressure control switch and the hydraulic line pressure, tracking a clutch fill volume of the clutch based upon the hydraulic flow rate, and controlling operation of the clutch based upon the clutch fill volume. | 04-23-2009 |
20090105040 | HYBRID DRIVE DEVICE - An output shaft of a rotating electrical machine and a drive device input shaft are disposed at different shaft center positions. A first gear meshing with a second gear provided on the output shaft of the rotating electrical machine for reducing rotation and transmitting the reduced rotation to a transmission input shaft is provided coaxially with the drive device input shaft, and at least a part of the clutch is disposed at an inner-diameter-side position so as to overlap a gear portion of the first gear in an axial direction. | 04-23-2009 |
20090111641 | Rear wheel drive apparatus for four wheel drive (4WD) hybrid electric vehicle - A real wheel drive apparatus for a four wheel drive hybrid electric vehicle includes: a motor generator ( | 04-30-2009 |
20090111642 | METHOD AND APPARATUS TO CONTROL CLUTCH STROKE VOLUME IN AN ELECTRO-MECHANICAL TRANSMISSION - A method for controlling a powertrain comprising a transmission coupled to an engine and an electric machine adapted to selectively transmit mechanical power to an output member via selective application of a plurality of hydraulically actuated torque transfer clutches includes filling one of the hydraulic clutches to a reference fill volume expected to create a touching state in the clutch, wherein the filling is accomplished through control of a pressure control solenoid, monitoring an actual fill time of the hydraulic clutch, monitoring a flow utilized in the filling, determining a measured fill volume based upon the actual fill time and the flow, calculating a fill volume error based upon the measured fill volume and the reference fill volume, and adjusting the reference fill volume based upon the fill volume error. | 04-30-2009 |
20090111643 | METHOD AND APPARATUS TO CONTROL CLUTCH FILL PRESSURE IN AN ELECTRO-MECHANICAL TRANSMISSION - A method to control a powertrain including a transmission, an engine, and an electric machine includes applying through a series of clutch fill events a series of incrementally changing command pressures in a pressure control solenoid controllably connected to a clutch within the transmission, monitoring a pressure switch fluidly connected to the pressure control solenoid and configured to indicate when the pressure switch is in a full feed state, determining changes in cycle times of the pressure switch corresponding to sequential applications of the series of incrementally changing command pressures, selecting a preferred command pressure to achieve a transient state in the clutch based upon the changes in pressure switch cycle times, and controlling the clutch based upon the preferred command pressure. | 04-30-2009 |
20090111644 | METHOD AND APPARATUS FOR CLUTCH TORQUE CONTROL IN MODE AND FIXED GEAR FOR A HYBRID POWERTRAIN SYSTEM - A method for controlling hydraulic line pressure of a hydraulic control system in an electromechanical transmission mechanically-operatively coupled to an internal combustion engine and an electric machine adapted to selectively transmit mechanical power to an output member via selective application of a plurality of hydraulically-applied torque transfer clutches includes monitoring requirements for transmission of clutch reactive torque in one of the clutches, monitoring a hydraulic line pressure within the hydraulic control system, determining a minimum clutch torque capacity required to keep the clutch from slipping, determining a hydraulic line pressure required to create the minimum clutch torque capacity, and modulating hydraulic line pressure applied to the clutch by modulating operation of the hydraulic control system based upon the hydraulic line pressure required to create the minimum clutch torque capacity. | 04-30-2009 |
20090111645 | METHOD AND APPARATUS TO CREATE A PSEUDO TORQUE PHASE DURING ONCOMING CLUTCH ENGAGEMENT TO PREVENT CLUTCH SLIP FOR A HYBRID POWERTRAIN SYSTEM - A method for controlling a powertrain comprising an electro-mechanical transmission mechanically-operatively coupled to an engine and an electric machine adapted to selectively transmit mechanical power to an output member through selective application of a plurality of torque-transfer clutches includes monitoring a clutch slip speed, synchronizing an oncoming clutch, and constraining reactive clutch torque limits for the oncoming clutch to achieve a reactive clutch torque that is less than an estimated clutch torque capacity. | 04-30-2009 |
20090118082 | METHOD AND APPARATUS TO PRIORITIZE INPUT ACCELERATION AND CLUTCH SYNCHRONIZATION PERFORMANCE IN NEUTRAL FOR A HYBRID POWERTRAIN SYSTEM - A method for controlling a powertrain includes operating a transmission in a neutral operating range state, monitoring commands affecting an input speed, monitoring a tracked clutch slip speed, determining constraints on an input acceleration based upon the commands, determining a clutch slip acceleration profile based upon the constraints on the input acceleration, determining an input acceleration profile based upon the clutch slip acceleration profile, and controlling the powertrain based upon the clutch slip acceleration profile and the input acceleration profile. | 05-07-2009 |
20090118083 | METHOD AND APPARATUS TO CONTROL ENGINE TORQUE TO PEAK MAIN PRESSURE FOR A HYBRID POWERTRAIN SYSTEM - A method to control a powertrain including a transmission, an engine, and an electric machine includes monitoring a rotational speed of the engine, monitoring a temperature of a transmission fluid, determining a maximum hydraulic pressure within a hydraulic control system based upon the rotational speed of the engine and the temperature of the transmission fluid, determining a predicted clutch torque capacity based upon the maximum hydraulic pressure, generating a preferred input torque from the engine based upon the predicted clutch torque capacity, and utilizing the preferred input torque to control the engine. | 05-07-2009 |
20090118084 | METHOD AND APPARATUS TO PERFORM ASYNCHRONOUS SHIFTS WITH ONCOMING SLIPPING CLUTCH TORQUE FOR A HYBRID POWERTRAIN SYSTEM - A method to control a powertrain including a transmission, an engine, and an electric machine includes monitoring a desired transmission shift including an oncoming clutch, monitoring operational parameters of the powertrain, monitoring a maximum electric machine torque capacity, determining a desired output torque profile through the desired transmission shift, determining a maximum electric machine torque capability profile through the desired transmission shift based upon the maximum electric machine torque capacity and the operational parameters, comparing the desired output torque profile to the maximum electric machine torque capability profile, determining a preferred oncoming clutch torque profile through the desired transmission shift based upon the comparing, and executing a clutch assisted shift based upon the preferred oncoming clutch torque profile. | 05-07-2009 |
20090118085 | METHOD AND APPARATUS FOR ADAPTING ENGINE OPERATION IN A HYBRID POWERTRAIN SYSTEM - A powertrain includes an engine coupled to an input member of a hybrid transmission. The hybrid transmission is operative to transfer power between an input member and a plurality of torque machines and an output member. A method for controlling the powertrain includes, monitoring operation of the hybrid transmission, determining motor torque offsets for the torque machines, transforming the motor torque offsets for the torque machines to an input torque offset and an output torque offset of the hybrid transmission, and adjusting operation of the engine based upon the input torque offset and the output torque offset of the hybrid transmission. | 05-07-2009 |
20090118086 | METHOD AND APPARATUS TO OFFLOAD OFFGOING CLUTCH TORQUE WITH ASYNCHRONOUS ONCOMING CLUTCH TORQUE, ENGINE AND MOTOR TORQUE FOR A HYBRID POWERTRAIN SYSTEM - A powertrain includes an electromechanical transmission mechanically-operatively coupled to an internal combustion engine and an electric machine adapted to selectively transmit mechanical power to an output member. A method for controlling the powertrain includes commanding a shift from a first operating range state to a second operating range state, identifying an off-going clutch, controlling torque output from said electric machine to offload reactive torque transmitted through said off-going clutch, selectively applying an oncoming clutch to offload reactive torque transmitted through said off-going clutch, and reducing a clutch torque capacity of said off-going clutch when said reactive torque transmitted through said off-going clutch is substantially zero. | 05-07-2009 |
20090124450 | METHOD AND SYSTEM FOR USING MECHANICAL POWER TO OPERATE A HYBRID ELECTRIC VEHICLE - An automotive transmission transitions from a drive gear to a neutral gear when an engine is shutdown. During a rolling pull-up, a crankshaft of the engine will be spun up to a desired speed and the transmission will transition from the neutral gear to an appropriate gear based on a shift schedule. A target transmission input speed is commanded to be a synchronous speed plus an offset to smoothly transition out of electric axle drive propulsion. | 05-14-2009 |
20090124451 | Hybrid Powertrain - A hybrid powertrain is provided that includes an engine operatively connected with an input member. The powertrain includes a transmission with first and second electric motor/generators, a differential gear set having multiple members, and selectively engagable torque-transmitting mechanisms. The input member, the output member, the engine and the motor/generators are selectively interconnected through the differential gear set by engagement of the torque-transmitting mechanisms in different combinations. An electronic controller controls the electric motor/generators, the engine and the torque-transmitting mechanisms to provide multiple operating modes between the input member and the output member, including an electric-only operating mode in which the engine is off and one motor generator acts as a motor to provide torque at the output member while the other electric motor/generator can remain substantially stationary, and another electric-only operating mode in which both electric motor/generators act as motors to provide torque at the output member. | 05-14-2009 |
20090124452 | Method for Starting a Piston Engine and Hybrid Drive for Performing the Method - A method is provided for starting a piston engine of a hybrid drive in an electric travel state. The hybrid drive includes at least the piston engine, an electric motor, a transmission, and a clutch situated between the piston engine and the electric motor. A converter lockup clutch, which is switchable into a slip state, is also provided. A slip is set at the converter lockup clutch, and a speed of the electric motor is then increased. The speed and the torque either do not change or only change in a predefined range at the output side of the converter lockup clutch. The clutch is closed to transmit a torque pulse, so that a first top dead center of the piston of the piston engine may be overcome. A predefined slip is then set at the clutch. | 05-14-2009 |
20090124453 | METHOD FOR OPERATING A HYBRID DRIVE SYSTEM HAVING A TORQUE CONVERTER - A method for operating a hybrid drive system, in particular of a motor vehicle, having at least one electric machine and one internal combustion engine, a disconnecting clutch being provided between the electric machine and the internal combustion engine and a torque converter having a turbine wheel being provided between the electric machine and a hybrid drive output, the disconnecting clutch being engaged for starting the internal combustion engine. It is provided that, as a function of the rotational speed of the turbine wheel of the torque converter, a rotational speed is predefined for the electric machine such that no sudden torque change occurs at the hybrid drive output when the internal combustion engine is started. | 05-14-2009 |
20090137362 | CONTROL DEVICE AND CONTROL METHOD OF AUTOMATIC TRANSMISSION - A control device of an automatic transmission includes a motor control portion to control an output of a motor that executes a control operation on a clutch control portion. The motor control portion includes a target motor current computation portion that computes a target motor current according to a desired driving state, a motor current detection portion that detects plural motor currents respectively corresponding to plural detection timings, a selection portion that selects a motor current corresponding to the desired driving state among the detected plural motor currents, and a motor driving portion that applies feedback control on an output of the motor according to a difference between the target motor current and the selected motor current. Hence, not only can the most suitable clutch control be applied for each gear-change interval at gear change, but also the comfortable feeling during the driving and the fuel efficiency can be enhanced. | 05-28-2009 |
20090143188 | Idle Speed Control of a Hybrid Electric Vehicle - In a powertrain that includes wheels for driving a vehicle, a crankshaft, a machine driveably connected to the crankshaft and able to operate alternately as an electric motor and electric generator, a transmission including an input clutch driveably connected to the crankshaft and an output driveably connected to the wheels, a method for controlling idle speed including producing a desired magnitude of input clutch torque capacity, producing a desired wheel torque, using an error represented by a difference between a desired crankshaft idle speed and a current crankshaft speed to determine a desired change in torque produced by the machine, using the magnitude of input clutch torque capacity and the desired change in torque produced by the machine to determine a desired magnitude machine torque, and using the machine to produce said desired magnitude of machine torque. | 06-04-2009 |
20090143189 | CONTROL APPARATUS OF A HYBRID VEHICLE AND METHOD FOR CONTROLLING THE SAME - Disclosed herein are embodiments of a control apparatus for a hybrid vehicle that is capable of suppressing overheating of the second clutch. Control is switched between engine-used slip drive control and motor drive control on a basis of a temperature of the second clutch. Control methods for a hybrid vehicle are also disclosed. | 06-04-2009 |
20090156355 | System and method for controlling clutch engagement in hybrid vehicle - The present invention provides a system and method for controlling clutch engagement in a hybrid vehicle, in which an appropriate clutch engagement mode is selected based on vehicle state, and the like, and a speed difference between both sections of a clutch and a torque transmitted to the vehicle during the clutch engagement process are controlled by reflecting a parameter changed by the clutch engagement mode, thus improving acceleration performance and driving performance, reducing engagement impact, and simply providing various clutch engagement modes. | 06-18-2009 |
20090176617 | METHOD FOR THE OPERATION OF A HYBRID DRIVE TRAIN IN A MOTOR VEHICLE - The hybrid drive train has an internal combustion engine connected to a first input shaft via a first clutch and connected to a second input shaft via a second clutch. An electric machine is connected to the second input shaft. The first input shaft is coupled to an output shaft via a first gear, and the second input shaft is coupled to the output shaft via two second gears. In the method for operating the hybrid, the first gear is engaged and torque is applied by the engine. To change, one of the second gears is engaged, engine torque is reduced by slipping the clutch while electric machine torque is increased. To change again, electric machine torque is reduced to zero, the other second gear is engaged while engine torque transmitted via the first clutch is increased by reducing slipping of the first clutch. | 07-09-2009 |
20090203497 | DUAL PUMP DESIGN FOR HYBRID ELECTRIC AUTOMATIC TRANSMISSION - A dual pump strategy for a hybrid electric automatic transmission necessitating one internal mechanically driven pump linked to the engine output shaft and an external fixed displacement pump powered by a brushless permanent magnet motor consisting of a controller with closed loop feedback control for operating such is disclosed. In neutral and electric drive mode, with the engine off, the flow demand for the transmission is sustained largely by the external pump. | 08-13-2009 |
20090253551 | HYDRAULIC CLUTCH CONTROL MECHANIZATION WITH ALL-MODE DEFAULT FOR USE IN A MULTIMODE HYBRID TRANSMISSION - A transmission includes first, second, third, and fourth clutches, first and second shift valves, and first, second, third, and fourth trim valves. Each trim valve is operative to control fluid pressure to a respective one of the first, second, third, and fourth clutches. The transmission also includes a controller. The controller is electrically operatively connected to the first and second shift valves and the first, second, third, and fourth trim valves to selectively provide a first clutch configuration for operating in a first mode and a second clutch configuration for operating in a second mode. The transmission also includes a clutch control mechanization for selectively moving to clutch configuration to a default position in the event power to the transmission is lost. | 10-08-2009 |
20090280951 | METHOD FOR OPERATING A VEHICLE DRIVETRAIN - A method for operating a vehicle drivetrain ( | 11-12-2009 |
20090291801 | CONTROLLER OF VEHICLE DRIVING DEVICE - A control system for a drive unit of a vehicle, in which a power distribution mechanism is arranged on a route from a prime mover to a wheel, and a transmission is arranged on an output side of the power distribution mechanism. The control system includes a revolution frequency controller that restrains a variation in a revolution frequency of the prime mover by controlling a revolution frequency of the reaction force establishing device until a predetermined time elapses since a commencement of a shifting operation of the transmission. The control system is capable of restraining a variation in an output torque, in case of carrying out a shifting operation of a transmission arranged on an output side of a prime mover. | 11-26-2009 |
20090312142 | Control Apparatus for Vehicular Automatic Transmission - A control apparatus for a vehicular automatic transmission, which permits effective reduction of deterioration of vehicle drivability upon operation of a brake operating member, and which is configured to increase a sweeping rate in a sweep control of the torque capacity of a coupling element of an automatic transmission portion | 12-17-2009 |
20090312143 | METHOD FOR CONTROLLING A HYBRID DRIVETRAIN - A method for controlling a hybrid drivetrain of a motor vehicle such that, during a thrust operation of the vehicle, a change takes place from a combustion-powered driving mode, in which the combustion engine is in a thrust operation, the separator clutch is engaged and the electric machine contributes no force, or from a combined driving mode in which the engine is in a thrust operation, the clutch is engaged and the electric machine operates as a generator, to an electric driving mode in which the engine is switched off, the clutch is disengaged and the electric machine operates as a generator. To efficiently change driving modes, the clutch is partially disengaged to a slip limit; the clutch is then completely disengaged; and when the clutch reaches the slip limit, the generator torque of the electric machine is increased inversely to the torque that can be transmitted by the clutch. | 12-17-2009 |
20090312144 | METHOD TO CONTROL A HYBRID DRIVE TRAIN - A method of controlling a hybrid drive train of a vehicle having, in series, an internal combustion engine, a clutch, an electric motor and a transmission with an output connected to the drive axle. During traction operation, the vehicle changes from an electric driving mode into a combination driving mode or a combustion engine driving mode, in that the clutch is engaged and the combustion engine torque is temporarily increased. The method includes regulating engagement of the clutch at least until reaching a starting rotational speed of the combustion engine such that the acceleration of the combustion engine occurs according to a predetermined progression of rotational speed and that the torque of the combustion engine is increased by the same amount as the transferable torque of the clutch is increased by the engagement process. | 12-17-2009 |
20100009804 | Variable Speed Drivetrain for Electronic Throttle Body - A variable speed drivetrain for an electronic throttle body is disclosed. The system includes a gear arrangement for the drivetrain of the electronic throttle body that includes a driving gear, a set of driven gears and a set of intermediate gears. The system also includes a clutch that is configured to selectively engage with one of the driven gears according to the selected mode of operation. | 01-14-2010 |
20100009805 | HYBRID DRIVE TRAIN OF A MOTOR VEHICLE - A hybrid gear train of a motor vehicle that has an internal combustion engine with a drive shaft, an electric motor with a rotor that operate as a motor and a generator, a transmission with two input shafts and an output shaft, as well as a differential transmission. At least one of the input shafts can be connected, via an assigned de-coupler, to the drive shaft, both of the input shafts can be connected by alternately assigned gearwheel sets of different ratios and in each case one assigned gear clutch to the output shaft. The differential transmission is designed as a simple planetary gearset that is coaxial with the first input shaft. The ring gear of this transmission is rotationally fixed to the one input shaft. The planet carrier is rotationally fixed to the second input shaft, and the sun gear is connected to and drives the rotor. | 01-14-2010 |
20100029436 | POWER OUTPUT APPARATUS, HYBRID VEHICLE PROVIDED WITH THE SAME, AND CONTROL METHOD OF POWER OUTPUT APPARATUS - In a hybrid vehicle, in order to stop an engine while a clutch is kept engaged and to transmit power from a motor to a drive shaft by changing a change speed state of a transmission when the power from a second motor is being transmitted to the drive shaft by the transmission, for example, a rotation speed of the first motor is adjusted so that the first motor can be connected to the drive shaft with the clutch disengaged while torque commands for both motors are set so that the power based on torque demand is outputted to the drive shaft, the power is transferred from the second motor to the first motor while both motors are connected to the drive shaft by the transmission, and the connection between the second motor and the drive shaft by the transmission is disconnected. | 02-04-2010 |
20100048347 | SPLIT SERIAL-PARALLEL HYBRID DUAL-POWER DRIVE SYSTEM - A split serial-parallel hybrid dual-power drive system, comprised of two or more than two separation drive systems allowing independent operation to respectively drive the load, or all loads driven individually are incorporated in a common frame to drive land, surface, underwater transportation means or aircraft, industrial machines and equipment or any other load drive by rotational kinetic energy. | 02-25-2010 |
20100048348 | SPLIT SERIAL-PARALLEL HYBRID DUAL-POWER DRIVE SYSTEM - A split serial-parallel hybrid dual-power drive system, comprised of two or more than two separation drive systems allowing independent operation to respectively drive the load, or all loads driven individually are incorporated in a common frame to drive land, surface, underwater transportation means or aircraft, industrial machines and equipment or any other load drive by rotational kinetic energy. | 02-25-2010 |
20100048349 | SPLIT SERIAL-PARALLEL HYBRID DUAL-POWER DRIVE SYSTEM - A split serial-parallel hybrid dual-power drive system, comprised of two or more than two separation drive systems allowing independent operation to respectively drive the load, or all loads driven individually are incorporated in a common frame to drive land, surface, underwater transportation means or aircraft, industrial machines and equipment or any other load drive by rotational kinetic energy. | 02-25-2010 |
20100056327 | Hybrid engine system - A hybrid engine and coupling system for use with a vehicle or other load which employs a motor/generator unit connected through controllable couplers to a kinetic energy storage device and to one or more internal combustion engine modules in a programmed manner. Several embodiments provide varying configurations to satisfy various power and packaging design requirements. | 03-04-2010 |
20100075798 | CONTROL APPARATUS FOR HYBRID VEHICLE - A control apparatus of hybrid vehicle having a first clutch which is in a disengaged state by being supplied with hydraulic fluid and a second clutch which is in an engaged state by being supplied with the hydraulic fluid, has a line pressure controller controlling a line pressure of the hydraulic fluid, and a drive mode controller changing a drive mode between HEV mode in which the first clutch is engaged and the vehicle travels with the engine and the motor/generator being a power source and EV mode in which the first clutch is disengaged and the vehicle travels with only the motor/generator being the power source. The line pressure controller sets the line pressure in HEV mode to a pressure level required for the engagement of the second clutch, and sets the line pressure in EV mode to a higher line pressure than the line pressure in HEV mode. | 03-25-2010 |
20100081541 | VEHICLE AND CONTROL METHOD OF VEHICLE - In response to a starting instruction of an engine at a gearshift position of a gearshift lever set to a parking position, a motor is controlled to form a fixed magnetic field on a stator of the motor at the level that is capable of preventing rotation of a rotating shaft against a torque applied to the rotating shaft within magnitude less than or equal to magnitude of a rotation restriction control torque based on a temperature of the motor and a discharge power from the battery, a motor is controlled to perform the motoring of the engine while the motor outputs a torque that makes a torque applied to the rotating shaft less than or equal to magnitude of the rotation restriction control torque, and the engine is controlled to be started with the motoring. | 04-01-2010 |
20100087289 | METHOD FOR CONTROLLING THE COUPLING AND THE DECOUPLING OF TWO MOTORS OF A PARALLEL HYBRID MOTIVE POWER GROUP - The invention relates to a method for controlling the coupling and the decoupling of the first motor and of the second motor of a parallel hybrid motive power group comprising a first motor ( | 04-08-2010 |
20100087290 | Hybrid Transmission with Disconnect Clutch and Method of Starting an Engine Using Same - A hybrid transmission is provided with a motor and a torque-transfer device is operable to transfer torque from the motor to a transmission input member upstream in power flow from the transmission gearing arrangement. The torque transfer device may be a fluid coupling, such as a torque converter, including a torque converter lock-up clutch. In other embodiments, the torque transfer device is a launch clutch that may be either a wet clutch engagable via pressurized transmission fluid, or a dry clutch, such as used in a manual transmission. A disconnect clutch is selectively engagable to operatively connect an engine connection member with the motor to permit the motor to start the engine, such as after a stop. Many embodiments of the transmission include a one-way clutch arranged in parallel with the disconnect clutch. A method of starting the engine using such a transmission is also provided. | 04-08-2010 |
20100105518 | Vehicle drive device - A vehicle drive device that includes a speed change mechanism; a fluid transmission device provided closer to an engine attachment side than the speed change mechanism is and including a lock-up clutch; an electric motor having a rotor and a stator and connecting the rotor to an input portion of the fluid transmission device; and an engine power cut-off clutch that transmits or cuts off a driving force of an engine to or from the fluid transmission device. | 04-29-2010 |
20100105519 | Vehicle drive device - A vehicle drive device that includes a speed change mechanism; a hydraulic transmission provided closer to an engine attachment side than the speed change mechanism is and including a lock-up clutch; an electric motor having a rotor and a stator and connecting the rotor to an input portion of the hydraulic transmission; and an engine power cut-off clutch that transmits or cuts off a driving force of an engine to or from the hydraulic transmission. | 04-29-2010 |
20100113213 | POWER OUTPUT APPARATUS, HYBRID VEHICLE HAVING THE SAME, AND METHOD OF CONTROLLING THE POWER OUTPUT APPARATUS - The hybrid vehicle transfers power between the two motors, releases a coupling between one of the motors and the drive shaft, adjusts the rotation speed of one of the motors which is released from the coupling to the drive shaft by the transmission so as to enable drive source element connection, and connects the clutch as well as cranks the engine by either one or the other motor when the engine is started while the clutch is released, the engine is stopped, both the motors are coupled to the drive shaft as well as at least one of the motors is caused to output power. | 05-06-2010 |
20100125021 | Controller for power transmission system - A controller for a power transmission system that uses an engine and a motor as driving force sources to transmit power and that includes a transmission unit is provided. The transmission unit has a plurality of engagement devices and establishes a plurality of gears having different speed ratios by the frictional engagement devices. The transmission unit is arranged downstream of the driving force sources. The controller includes a torque transmission capacity setting unit that, when the transmission unit shifts gears, varies torque transmission capacities of the frictional engagement devices on the basis of an operating state of the motor and an operating state of the engine. | 05-20-2010 |
20100125022 | METHOD FOR OPERATING A DRIVE TRAIN - A process of operating a motor vehicle drive train that comprises at least one hybrid drive having a combustion engine and an electric motor with a clutch connected between the combustion engine and the electric motor, and an automatic transmission is arranged between the hybrid drive and an output. The process including the step of disengaging the clutch to carry out a shift, after a reduction of load at the internal combustion engine and after a reduction of the torque that is transmitted between the internal combustion engine and the electric motor. Subsequently carrying out a gear shift by the automatic transmission and, thereafter, increasing the torque that is transmitted by the clutch. Increasing the load from the combustion engine, and optionally engaging the clutch. A load transfer by the electric motor occurs before and/or after the gear shift in the transmission is carried out. | 05-20-2010 |
20100130327 | Multi-Drive Fluid Pump - A multi-drive pump may include a pump housing, an inlet port, an outlet port, a primary pump gear, a secondary pump gear, a first internal mechanical drive mechanism coupled to the primary pump gear and a second internal mechanical drive mechanism and an internal electro-magnetic drive mechanism coupled to the secondary pump gear. The pump housing may define an internal volume fluidly coupled to the inlet port and the outlet port. The primary pump gear and the secondary pump gear may be positioned in the pump housing and coupled to one another. Rotation of the primary pump gear and the secondary pump gear draws fluid into the inlet port and expels fluid from the outlet port. The primary pump gear may be rotated by the first internal mechanical drive mechanism and the secondary pump gear may be rotated by the second internal mechanical drive mechanism and the internal electro-magnetic drive mechanism. | 05-27-2010 |
20100151990 | METHOD AND DEVICE FOR COMPENSATING A TRANSMITTED TORQUE OF A DISCONNECTING CLUTCH OR A HYBRID CLUTCH OF A HYBRID DRIVE - A method and a device for compensating a transmitted torque of a clutch between a regulated drive motor, in particular an electric motor, and an internal combustion engine of a hybrid drive when transitioning from an exclusive operation using the drive motor to a hybrid operation, a total torque from the drive motor and the internal combustion engine being jointly provided in hybrid operation, the rotational speed of the drive motor being controlled or regulated with the aid of a manipulated variable; the internal combustion engine being entrained at a controllable transmitted torque by coupling to the drive motor via a proportional clutch for performing the transition. The rotational speed of the drive motor is controlled or regulated as a function of a setpoint transmitted torque using which the drive motor is to be coupled to the internal combustion engine. | 06-17-2010 |
20100167870 | METHOD FOR CONTROLLING THE COUPLING AND THE DECOUPLING OF THE FIRST MOTOR AND SECOND MOTOR OF A PARALLEL HYBRID MOTIVE POWER GROUP - The invention relates to a method for controlling the coupling and the decoupling of the first motor and of the second motor of a parallel hybrid motive power group comprising a first motor ( | 07-01-2010 |
20100167871 | Control device - A control device includes a differential rotation obtaining unit; a direct-coupling control unit that decreases the differential rotation speed by increasing an engagement pressure of the direct-coupling clutch at a normal pressure increase rate determined depending on a traveling state of a vehicle so as to change the direct-coupling clutch from a released state to an engaged state; and a pressure increase control unit that changes to a rapid pressure increase rate larger than the normal pressure increase rate for increasing the engagement pressure by the direct-coupling control unit when the differential rotation speed becomes equal to or smaller than a predetermined pressure increase permission threshold in a state that an accelerator opening of the vehicle decreases. | 07-01-2010 |
20100173745 | Vehicle control device - A vehicle control device that includes an input member drive-coupled to an engine and a rotary electrical machine; an output member; and a transmission having a plurality of friction engagement elements, in which a plurality of shift speeds are switched by controlling engagement and release of the plurality of friction engagement elements, and a rotary driving force of the input member is shifted by a change gear ratio of one of the shift speeds and outputted to the output member. | 07-08-2010 |
20100179024 | HYBRID POWERTRAIN AND DUAL CLUTCH TRANSMISSION - An automatic dual clutch transmission includes an input clutch which selectively connects a prime mover to an electric motor. The electric motor, in turn, is connected to the inputs of a pair of coaxial friction clutches. Each of the coaxial outputs of the friction clutches drives an input gear with meshes with a pair of gears, one of which is associated with each of a respective pair of layshafts or countershafts. On each countershaft, between the pair of gears driven by the outputs of the two clutches, are a pair of synchronizer clutches which selectively synchronize and connect one of the two gears to the associated countershaft. A similar arrangement of a second pair of gears separated by synchronizer clutches connects the countershafts through a selected gear to a pair of output gears coupled to and driving a differential cage or spool. | 07-15-2010 |
20100184559 | HYBRID POWER DRIVING SYSTEM AND THE DRIVING METHOD - The present invention provides a hybrid power driving system, comprising: a first subsystem ( | 07-22-2010 |
20100197450 | METHOD FOR OPERATING A DRIVE TRAIN - A method for operating a drive train of a motor vehicle. The drive train comprising a hybrid drive with an internal combustion engine and an electric motor, a transmission arranged between the hybrid drive and a drive output, and a clutch arranged between the internal combustion engine and the electric motor. The internal combustion engine is started by engaging the clutch only when the electric motor is providing drive power. In this situation when shifting gears in the transmission with interruption of the traction force, immediately after the gear change and during a load build-up phase of the shift operation, the internal combustion engine is started by the electric motor without traction force interruption. The clutch is controlled to partially engage to start the combustion engine and then it is completely disengaged before reaching a synchronous speed between the combustion engine and the electric motor. | 08-05-2010 |
20100197451 | METHOD FOR OPERATING A DRIVE TRAIN - A method of operating a drive train of a motor vehicle whereby the drive train comprises at least a hybrid drive with a combustion engine and an electric motor, a transmission, positioned between the hybrid drive and an output, and a clutch, positioned between the combustion engine and the electric motor. When the electric motor is exclusively driving, the combustion engine can be started by engaging a clutch positioned between the combustion engine and the electric motor. In accordance with the invention, when there is an exclusive electromotive drive and the electric motor is operated in a deceleration mode and, when a request by a driver is interpreted as a desired change from a deceleration mode to a traction mode, the combustion engine is started, by using the deceleration/traction change, in a way that the clutch, positioned between the combustion engine and the electric motor, is at least partially engaged so that the clutch transfers the required torque which is needed for starting the combustion engine. | 08-05-2010 |
20100204004 | METHOD FOR CONTROLLING AND/OR REGULATING A HYBRID DRIVE ARRANGEMENT - A method of controlling and/or regulating a hybrid drive system of a vehicle, with at least one internal combustion engine and at least one electric machine which can be coupled to the input shaft of an automated transmission, at least some of the time, by at least one clutch to facilitate driving of the vehicle such that at least one energy accumulator is charged by the electric machine which is operated as a generator and driven by the internal combustion engine. The electric machine is a synchronizer machine that is continually energized by maintaining a nominal speed of the synchronizer machine below an inflexion speed (n_Eck) during the charging process. | 08-12-2010 |
20100204005 | METHOD FOR STARTING THE COMBUSTION ENGINE DURING A LOAD SHIFT IN PARALLEL HYBRID VEHICLES - A method for starting the internal combustion engine, in parallel hybrid vehicles, in which the internal combustion engine is started, during a shift under load in purely electric driving operation, by the electric machine. | 08-12-2010 |
20100204006 | METHOD FOR THE OPERATION OF A DRIVE TRAIN - A method of operating a drive train comprising a hybrid drive with a combustion engine and an electric motor; a transmission positioned between the hybrid drive and the output; and a clutch positioned between the combustion engine and the electric motor. When the electric motor exclusively drives the vehicle, the combustion engine can be started by engaging the clutch. At the time when the electric motor permanently or without traction force interruption is coupled to the output, and the rotational speed of the electric motor is greater than the starting rotational speed of the combustion engine, and a clutch, positioned between the combustion engine and the electric motor, is engagedly and disengagedly controlled so that the clutch is brought into slippage, via partial engagement, to start the combustion engine, and thereafter the clutch is completely disengaged before reaching a synchronous rotational speed between the combustion engine and the electric motor. | 08-12-2010 |
20100210411 | Clutch Engaging Control Method and Control System in Hybrid Power Output Device - The present invention provides a clutch engaging control method in a hybrid power output device, wherein the device comprises an engine, a first motor, a clutch and a second motor that are connected in sequence, a battery, and a speed reducing mechanism and a drive shaft that are connected to the output end of the second motor; the method comprises: (a) detecting the rotation speed ω | 08-19-2010 |
20100227734 | METHOD FOR CONTROLLING A MOTOR VEHICLE DRIVE TRAIN - A method for controlling a drivetrain including a combustion engine, electric motor/generator and a transmission inter-coupled, via a summarizing gear, with one output and two input elements and, via a clutch, with each other. One input element is fixed to the engine, the second input element is fixed to the motor/generator and the output element is fixed to the input shaft of the transmission. The clutch is between two elements of the summarizing gear. Before a gearshift, torques of the engine and motor/generator are reduced and the clutch disengaged. To quickly reduce torque in the summarizing gear, the engine torque is reduced after a defined time, such that the clutch disengages when the slippage is proportional to the lowering engine torque and the motor/generator torque, in a ratio of torques at the beginning of torque reduction, is reduced proportionally to the engine torque. | 09-09-2010 |
20100227735 | MULTI-MODE HYBRID TRANSMISSION AND SHIFT CONTROL METHOD FOR A MULTI-MODE HYBRID TRANSMISSION - A multi-mode, electrically variable, hybrid transmission and improved shift control methods for controlling the same are provided herein. The hybrid transmission configuration and shift control methodology presented herein allow for shifting between different EVT modes when the engine is off, while maintaining propulsion capability and minimum time delay for engine autostart. The shift control maneuver is able to maintain zero engine speed while producing continuous output torque throughout the shift by eliminating transition through a fixed gear mode or neutral state. Optional oncoming clutch pre-fill strategies and mid-point abort logic minimize the time to complete shift, and reduce the engine start delay if an intermittent autostart operation is initiated. | 09-09-2010 |
20100234171 | VEHICULAR POWER TRANSMISSION CONTROL APPARATUS - An apparatus comprises a changeover mechanism which is able to change a connection state of an electric motor output shaft to any one of states including, “an IN-Connection State” in which a power transmission path is provided between a transmission input shaft and the electric motor output shaft, “an OUT-Connection State” in which a power transmission path is provided between the transmission output shaft and the electric motor output shaft, and “a neutral state” in which no transmission path therebetween is provided. The changeover is carried out based on a combination of a vehicle speed V and a required driving torque T. When the vehicle starts to drive, “the IN-Connection State” is selected. After the start of the vehicle and while the vehicle speed V is increasing, the changeovers to “the OUT-Connection State”, “the IN-Connection State”, and “the neutral state” are sequentially carried out. | 09-16-2010 |
20100234172 | VEHICULAR POWER TRANSMISSION CONTROL APPARATUS - An apparatus comprises a changeover mechanism which is able to change a connection state to any one of three states, i.e., “an IN-Connection State” in which a power transmission path is provided between a transmission input shaft and the electric motor output shaft, “an OUT-Connection State” in which a power transmission path is provided between a transmission output shaft and the electric motor output shaft, and “a neutral connection state” in which no transmission path therebetween is provided. At a timing (time t | 09-16-2010 |
20100234173 | VEHICULAR POWER TRANSMISSION CONTROL APPARATUS - An apparatus comprises a changeover mechanism which is able to change a connection state of an electric motor output shaft to any one of states including, “an IN-Connection State” in which a power transmission path is provided between a transmission input shaft and the electric motor output shaft, “an OUT-Connection State” in which a power transmission path is provided between the transmission output shaft and the electric motor output shaft, and “a neutral connection state” in which no transmission path therebetween is provided. The changeover is carried out based on a combination (area) of a vehicle speed V and a required driving torque T. As for the changeover, an IN-connection area, in which an electric-motor-driving-wheels-maximum-torque is larger than in an OUT-Connection State and in a neutral connection area, is enlarged. | 09-16-2010 |
20100234174 | VEHICULAR POWER TRANSMISSION CONTROL APPARATUS - An apparatus comprises a changeover mechanism which is able to change a connection state of an electric motor output shaft to any one from alternatives consisting of “an IN-Connection State” in which a power transmission path is provided between a transmission input shaft and the electric motor output shaft, “an OUT-Connection State” in which a power transmission path is provided between the transmission output shaft and the electric motor output shaft, and “a neutral state” in which no transmission path therebetween is provided. The changeover is carried out based on a combination (area) of a vehicle speed V and a required driving torque T. As for the changeover, a neutral area is enlarged so that a possibility of selecting the neutral state becomes higher, as a battery temperature is higher, or as an electric motor temperature is higher, or as a remaining battery level is larger. | 09-16-2010 |
20100248892 | SHIFT CONTROL METHOD FOR A MULTI-MODE HYBRID TRANSMISSION - A method for regulating operation of a hybrid transmission selectively connectable to an engine includes deactivating an offgoing clutch to place the transmission in a first EVT mode. The transmission is then placed in an ETC mode and an oncoming clutch is actuated to place the transmission in a second EVT mode. An engine-on state is maintained during deactivation of the offgoing clutch and actuation of the oncoming clutch. Transitioning from the first to second EVT mode may be characterized by lack of a transition through a fixed-gear mode. The transmission may be configured to continuously produce output torque during the transition from the first to second EVT mode. The oncoming clutch may be synchronized to zero clutch slip prior to actuating the oncoming clutch. Engine speed may be varied while the offgoing clutch is disengaged and prior to actuating the oncoming clutch. | 09-30-2010 |
20100248893 | CONTROL APPARATUS FOR HYBRID VEHICLE - A control apparatus of hybrid vehicle has a drive mode change section, a temperature detection section detecting a second engagement element temperature, and a second engagement element protection control section. The drive mode change section changes drive modes of a first drive mode in which the first engagement element is disengaged and the second engagement element is engaged then the vehicle travels by only a driving force of the motor, a second drive mode in which the first and second engagement elements are respectively engaged then the vehicle travels by both driving forces of the engine and motor, and a third drive mode in which the second engagement element is slip-engaged then the vehicle travels by a driving force transmitted through the second engagement element. The second engagement element protection control section keeps an engine rotating state regardless of the drive mode when the second engagement element temperature is high. | 09-30-2010 |
20100261574 | AUTOMATIC TRANSMISSION WITH NORMALLY ENGAGED DISC CLUTCHES - An automatic variable transmission with normally engaged disc clutches includes a main transmission pump connected to the transmission and at least one clutch located within the transmission. The clutch is in an engaged position when the main transmission pump is not operating. The clutch assembly includes a piston moveable between an engaged position and a disengaged position and at least one spring is operably connected to the piston. The piston is operable to move the at least one spring between the engaged position and a disengaged position. A plurality of clutch plates may transfer torque when the at least one spring is in the engaged position. | 10-14-2010 |
20100261575 | MULTI-SPEED DUAL-CLUTCH TRANSMISSION FOR A HYBRID VEHICLE - A dynamically-shiftable multi-speed dual-clutch transmission (DCT) for operative connection to an engine and to an electric motor in a hybrid vehicle is provided. The DCT includes a first clutch, a second clutch and a third clutch. The first clutch is configured to transmit torque of the engine and withstand energy of the vehicle at launch from rest. The second clutch is configured to select a first set of forward speed ratios. The third clutch is configured to select a second set of forward speed ratios alternating with the speed ratios of the first set. The second and third clutches are each configured to withstand combined torque of the electric motor and torque of the engine during shifts into the respective set of forward speed ratios, but not to withstand torque of the engine at launch or energy of the vehicle at launch. | 10-14-2010 |
20100267518 | Hybrid Transmission and Method of Use - A hybrid transmission for a vehicle and its method of use are described. The transmission may have an internal combustion engine and an electric device. A torque converter is connected between the internal combustion engine and a set of direction clutches. The direction clutches are also connected to an intermediate gear set. The electric device is also connected to the intermediate gear set for providing rotational energy to the intermediate gear set or absorbing energy from the intermediate gear set. The electric device is connected to at least one super capacitor. | 10-21-2010 |
20100273603 | VEHICLE LAUNCH DEVICE HAVING FLUID COUPLING - A method of controlling an automatic shifting power transmission having a fluid coupling device, at least one reaction clutch disposed in series with the fluid coupling device, and an electric machine disposed in series with the fluid coupling device and the at least one reaction clutch includes partially engaging the at least one reaction clutch corresponding to a first gear engagement to effect a first gear launch maneuver when engine load is at or above a predetermined value. Next the electric machine is energized to provide additional torque to the first gear reaction clutch when the automatic shifting power transmission is in the first gear launch maneuver. The at least one reaction clutch corresponding to the first gear engagement is fully engaged when engine load is below the predetermined value. | 10-28-2010 |
20100273604 | HYBRID SYSTEM CONTROL METHOD - To reduce a torque drop caused by shift shock and time lag in a hybrid system. | 10-28-2010 |
20100279818 | Control of a Dry, Dual-Clutch Transmission During an Engine Restart of a Hybrid Electric Vehicle - A method for controlling an engine restart in a hybrid electric powertrain, including the steps of stopping the engine, using an electric power source and an electro-mechanical actuator connected to the source to engage a gear and stroke to zero torque capacity a dry clutch of a dual-clutch transmission, initiating an automatic engine restart, and increasing the torque capacity of the clutch to a desired torque capacity during the engine restart. | 11-04-2010 |
20100292047 | HYBRID VEHICLE DRIVE CONTROL APPARATUS - A hybrid vehicle drive control apparatus is basically provided with an engine ( | 11-18-2010 |
20100298089 | METHOD OF CLUTCH ACTUATION FOR HYBRID TRANSMISSIONS - A method of actuating a clutch includes commanding a shift, monitoring slip speed, beginning synchronization, filling to a pre-fill volume, and holding at the pre-fill volume. After slip speed reaches a trigger point, the clutch is filled to a first predicted touch point volume, which is greater than the pre-fill volume. The pre-fill volume is approximately 80 to 90 percent of the first predicted touch point volume. The method may determine slip speed derivative, and set the trigger point based thereupon. The method may monitor actual touch point volume and calculate a flow model, which is used to determine when the pre-fill volume has been reached. Filling the clutch to the pre-fill volume may begin simultaneously with commanding the shift. Pressure is generated by an auxiliary pump, which receives power from sources other than an internal combustion engine. | 11-25-2010 |
20100298090 | METHOD OF CLUTCH CONTROL TO START AN ENGINE WITH A HYBRID TRANSMISSION - A method of starting an internal combustion engine includes selecting a first or a second clutch, and pressurizing the selected clutch with an auxiliary pump. The pressurized clutch is synchronized using the first and second electric machines, and then engaging. The internal combustion engine is started with the first and second electric machines. The first and second clutches may be engine reactive clutches. Selecting the first or second clutch includes determining whether an input-split or compound-split mode is requested. If the input-split mode is requested the first clutch is selected, and if the compound-split mode is requested the second clutch is selected. The first and second electric machines may be high voltage machines, configured to operate in conjunction with a high-voltage battery pack. The first and second electric machines may be configured as propulsion motors for the vehicle. | 11-25-2010 |
20100304923 | Method For Controlling A Hybrid Drive - A method for controlling a hybrid drive of a vehicle, which includes at least one internal combustion engine and at least one electric machine, having a first clutch situated between the electric machine and the drive train of the vehicle and a second clutch situated between the electric machine and the internal combustion engine. Performance parameters of the hybrid drive are controlled as a function of the driver's intent. | 12-02-2010 |
20100304924 | HYBRID POWERTRAIN WITH TORQUE-MULTIPLYING ENGINE STARTING MECHANISM AND METHOD OF CONTROLLING A HYBRID POWERTRAIN - A hybrid powertrain is provided that provides engine starting from an electric-only mode with a reduced torque load on the motor/generator. The powertrain includes an engine and a motor/generator, which may be a single motor/generator in a strong or full hybrid, but is not limited to such. The motor provides propulsion torque in an electric-only operating mode, and is configured to apply torque to a transmission input member. A first clutch is selectively engagable to connect the engine output member for common rotation with the transmission input member. An engine starting mechanism is provided that multiplies motor torque used to start the engine so that less is diverted from propelling the vehicle, enabling a smaller motor/generator to be used. A method of controlling such a powertrain is also provided. | 12-02-2010 |
20100304925 | MOTOR VEHICLE CONTROL SYSTEM - A motor vehicle control system for controlling a motor vehicle with a hybrid drive comprising an internal combustion engine and an electric motor, with a strategy sub-component, a control sub-component and an actuator sub-component. The functional components include at least an internal combustion engine functional component, a transmission functional component, such that the strategy sub-component ( | 12-02-2010 |
20100311540 | METHOD FOR THE OPERATION OF A HYBRID DRIVE SYSTEM AND HYBRID DRIVE SYSTEM COMPRISING TWO SUB-TRANSMISSIONS - A method for the operation of a hybrid drive system is provided. The hybrid drive system has a first drive machine, for example an internal combustion engine, and a second drive machine, such as an electric machine. The hybrid drive system can also have a first gearshift sub-transmission and a second gearshift sub-transmission. The first gearshift sub-transmission can have a first input shaft that can be coupled to an output shaft using a first group of shifting gearwheel pairs, and the first input shaft can be coupled to the first drive machine. The second gearshift sub-transmission can have a second input shaft that is coupled to the output shaft using a second group of shifting gearwheel pairs, and the second input shaft can be connected with the second drive machine. | 12-09-2010 |
20110009236 | METHOD FOR TRANSITIONING CONTROL IN A MULTI-MODE HYBRID TRANSMISSION - A multi-mode hybrid transmission including a selectable one-way clutch and first and second torque machines transitions to operating in a target continuously variable mode including applying a selectable one-way clutch and controlling input torque and motor torques of the first and second torque machines using a second kinematic relationship. A multi-step process is executed to transition the first clutch to a deactivated state, transition the second selectable one-way clutch to the applied state, and transition to using the second kinematic relationship to achieve a preferred output torque. | 01-13-2011 |
20110009237 | METHOD FOR REDUCING GEAR SHIFTING SHOCK OF HYBRID ELECTRIC VEHICLE - The present invention provides a method which controls the hydraulic pressure of a clutch (an engine clutch) disposed between an engine and a drive motor, thus reducing gear shifting shock and vibration. The method comprises a slip preparation step of determining that gear shifting is required and reducing the hydraulic pressure of the clutch to a preset target hydraulic pressure from a point in time at which the gear shifting is required. The method further comprises a slip maintaining step of feedback-controlling the hydraulic pressure of the clutch such that a slip rate of the clutch is maintained constant after the hydraulic pressure of the clutch reaches the target hydraulic pressure; and a clutch lock-up completing step of increasing the hydraulic pressure of the clutch, from a point in time at which the gear shifting is completed, to a maximum hydraulic pressure for making a lock-up state of the clutch. | 01-13-2011 |
20110015032 | METHOD AND CONTROL DEVICE FOR OPERATING A HYBRID DRIVE - In a control unit and a method for operating a hybrid drive arrangement ( | 01-20-2011 |
20110021312 | HYBRID VEHICLE CONTROL DEVICE - A hybrid vehicle control device is provided with an engine stop control section and a fuel injection control section. The engine stop control section is configured to issue an engine speed reduction command to reduce an engine speed of an engine during an engine stopping operation occurring in response to establishment of an engine stop condition by using an electric motor and slip engaging a drive-wheel side clutch disposed between the electric motor and a drive wheel such that the drive-wheel side clutch transmits rotational torque between the electric motor and the drive wheel. The fuel injection control section is configured to issue a fuel injection command to continue fuel injection during the engine stopping operation until the engine speed decreases below a prescribed engine speed whereupon the fuel injection is stopped. | 01-27-2011 |
20110021313 | METHOD FOR OPERATING A DRIVE TRAIN OF A MOTOR VEHICLE - A method for operating a drivetrain of a motor vehicle having in the force flow direction and in the following order an internal combustion engine, a clutch, an electric motor, a transmission and an axle gearset, or an internal combustion engine, a clutch, an electric motor, a transmission input shaft, a transmission and an axle gearset. The electric motor is used for pre-lubricating and warming the transmission such that, with the vehicle clutch disengaged, the lubricant pump of the transmission is driven by the electric motor so bearings are supplied with lubricant before the engine is started, and the heat, produced by splashing the lubricant, additionally warms the transmission. | 01-27-2011 |
20110028269 | METHOD FOR REDUCING BACKLASH VIBRATIONS IN HYBRID ELECTRIC VEHICLE - The present invention provides a method for reducing backlash vibrations in a hybrid electric vehicle, in which the backlash vibrations generated between a motor and a driving wheel can be easily reduced by slipping a clutch in an automatic transmission when the direction of a motor driving torque is changed while the hybrid electric vehicle is running in electric vehicle (EV) mode. | 02-03-2011 |
20110034297 | POWERTRAIN WITH INPUT SHAFT AND ENGINE SPEED SYNCHRONIZATION AND METHOD FOR SHIFTING GEARS IN A POWERTRAIN - A powertrain includes a prime mover, a transmission, an input shaft adapted to transmit torque between the prime mover and the transmission, an output shaft adapted to transmit torque between the transmission and a driveline, and a master clutch between the prime mover and the input shaft, the clutch being movable between a disengaged position and an engaged position in which the clutch is not and is adapted to transmit torque between the prime mover and the input shaft, respectively. An electric motor is arranged for torque transmission with at least one of the input shaft and the output shaft, and a controller is provided for controlling the electric motor to rotate the input shaft at a rotational speed within an operating range of the prime mover when the clutch is moved from the disengaged to the engaged position. | 02-10-2011 |
20110039655 | METHOD AND DEVICE FOR CONTROLLING A CREEP MODE OF A VEHICLE HAVING A HYBRID DRIVE SYSTEM - The invention relates to a method and a device for controlling a creep mode of a vehicle having a hybrid drive system ( | 02-17-2011 |
20110045947 | METHOD AND DEVICE FOR CONTROLLING A CREEP MODE OF A VEHICLE COMPRISING A HYBRID DRIVE - The invention relates to a method for controlling a creep mode of a vehicle comprising a hybrid drive ( | 02-24-2011 |
20110053734 | METHOD FOR OPERATING A DRIVE TRAIN - A method of operating a drive train having a hybrid drive that comprises an internal combustion engine and an electric machine, a clutch connected between the combustion engine and electric machine, a transmission connected between the electric machine and an output drive, and a start-up element connected between the electric machine and the output drive. The method for starting-up the drive train, when the clutch connected between the combustion engine and the electric machine and the start-up element are both disengaged, and the electric machine is stopped and short-circuited. The method comprising the steps of accelerating the internal combustion engine to a rotational speed which depends on a short circuit torque of the electric machine that must be overcome; engaging the clutch connected between the combustion engine and electric machine; and bringing the combustion engine to a start-up speed depending on the driver's request; and engaging the start-up element. | 03-03-2011 |
20110065547 | STACKABLE MOTOR - A vehicle comprises a plurality of motors operatively connected with one another. The vehicle is powered with the plurality of motors individually and in combination with one another to primarily operate each of the plurality of motors within a predetermine efficiency range. | 03-17-2011 |
20110086739 | HYBRID DRIVE DEVICE - A hybrid drive device includes a fluid clutch including an inputting element to which an engine torque outputted from an engine is inputted and an outputting element connected to an input shaft of a transmission to integrally rotate therewith for outputting the torque to the input shaft, the fluid clutch transmitting the torque between the inputting element and the outputting element via a fluid either with or without incrementing the torque, and a motor generator connected to the input shaft for outputting a motor torque to the input shaft to drive the transmission. | 04-14-2011 |
20110086740 | POWER TRANSMISSION APPARATUS AND POWER TRANSMISSION CONTROL APPARATUS - A power transmission apparatus disposed includes: a motor for driving wheels, and transforms kinetic energy at the driving path to electrical energy; a normal close type clutch that includes an input and an output and is selectively set in an engaging state and a released state, wherein the clutch is normally set in the engaging state by a biasing member and is set in the released state when hydraulic pressure is applied; a hydraulic-pressure feeding device for supplying the adjusted hydraulic pressure to the clutch; and a control device for controlling the feeding device. When changing the clutch from the engaged state to the released state, if the difference between rotation numbers of the input and the output becomes equal to or larger than the predetermined value, the control device controls the feeding device to bring the clutch to a state just before the engaged state. | 04-14-2011 |
20110086741 | STACKABLE MOTOR WITH FLEXIBLE MODES OF OPERATION - A vehicle comprises a drive sub-system having an engine and a first motor and a generator sub-system having a transmission and a second motor. The transmission for the vehicle is driven with the first motor, the second motor and the engine individually and in combination such that the vehicle may selectively operate in a serial hybrid mode and a parallel hybrid mode. | 04-14-2011 |
20110092334 | CONSTRUCTION MACHINE AND CONTROL METHOD THEREOF - A construction machine comprises an electric motor/generator coupled to an electricity accumulator, an engine, a transmission coupled to drive wheels, an epicyclic gearing for coupling an output shaft of the electric motor/generator, an output shaft of the engine, and an input shaft of the transmission, the engine torque and/or the generator torque being transmitted to drive wheels, a clutch for directly coupling two among the output shaft of the electric motor/generator, the output shaft of the engine, and the input shaft of the transmission, and a controller configured to, under a condition in which the clutch is in an off-state, control engine speed based on the degree to which the accelerator is open and on the amount of electricity in the electricity accumulator, to control shifting of the transmission gear position based on the accelerator opening degree, operational state of the generator, and the electricity amount motor/generator. | 04-21-2011 |
20110118078 | Vehicle And Method For Controlling Engine Start In A Vehicle - A vehicle includes a motor/generator, a starter motor, a disconnect clutch disposed between the engine and the motor/generator, and at least one clutch disposed between the motor/generator and the vehicle drive wheels. When an engine start is requested, various parameters are controlled to ensure a smooth engine start wherein driveline torque disturbances are minimized. The starter motor is used to crank the engine at the lowest engine speeds when the engine-required torque is the highest. This reduces the amount of torque necessary to be supplied from the motor/generator, and further helps to reduce torque disturbances in the driveline. If the motor/generator is producing torque to propel the vehicle at the time the engine start is requested, a launch clutch or one or more transmission clutches can be controlled to provide slip between the motor/generator and the vehicle drive wheels to further reduce torque disturbances in the driveline. | 05-19-2011 |
20110118079 | SHIFTABLE CLUTCH DEVICE, PARTICULARLY FRICTION WET CLUTCH, DRIVE TRAIN FOR A HYBRID SYSTEM AND METHOD FOR OPERATING THE DRIVE TRAIN AND VEHICLE INCLUDING THE DRIVE TRAIN - A shiftable clutch device for disconnecting a first drive machine from a drive train and connecting it thereto, including a control device that can be actuated by a pressure medium, is characterized according to the invention in that the shiftable clutch device includes two partial clutches, a first partial clutch forming a main clutch and a second partial clutch forming a drag clutch, which are disposed and configured such that each is adapted to produce a drag torque in an end position of the control device, a first opening end position characterized by an open state of the main clutch and a second closing end position characterized by a closed state of the main clutch. | 05-19-2011 |
20110124465 | AUTOMOBILE DUAL-POWER AUTOMATIC TRANSMISSION BOX - An automobile dual-power automatic transmission box supplies two different power sources to a wheel to drive an automobile and includes a first power source for rotating a first drive shaft, a second drive shaft rotated by the first drive shaft, a third drive shaft for rotating the wheel, a second power source, a clutch unit for driving the second power source to rotate the third drive shaft when the wheel speed is less than a predetermined value, or driving the second drive shaft for rotating the third drive shaft if the wheel speed is greater than the predetermined value, and a speed change unit for retarding the second drive shaft if the wheel speed reaches the predetermined value, and the clutch unit will drive the first power source to rotate the third drive shaft until the wheel speed approaches the rotating speed of the third drive shaft. | 05-26-2011 |
20110172055 | METHOD FOR CARRYING OUT A SHIFT DURING HYBRID OPERATION IN A PARALLEL HYBRID VEHICLE - A method of carrying out a shift with traction force interruption during hybrid operation in a parallel hybrid vehicle having an automated transmission. The method comprises the steps of maintaining the coupling between the internal combustion engine ( | 07-14-2011 |
20110212809 | VEHICLE DRIVING APPARATUS - A vehicle driving apparatus configured with a drive power source, a fluid coupling, a transmission apparatus; and a control apparatus. A rotation of a drive input member driven by the drive power source is transmitted to a shift input member via the fluid coupling and a rotation of the shift input member is shifted by the transmission apparatus and then transmitted to an output member. When a state shift command for shifting from a non-transmission state to a transmission state is input into a control apparatus in a state in which the drive power source does not generate a driving force, the control apparatus performs a shift input rotation operation before engaging a frictional engagement element and shifting to the transmission state by causing the drive power source to generate the driving force and rotating the shift input member via the fluid coupling while maintaining the non-transmission state. | 09-01-2011 |
20110230307 | Method and device for operating a hybrid drive device during the start of an internal combustion engine - In a method for operating a hybrid drive device for a motor vehicle having at least one internal combustion engine, another drive unit and a separating clutch, to start the internal combustion engine the separating clutch is engaged, and during the start of the internal combustion engine, a setpoint rotational speed is predefined for the other drive unit. This setpoint rotational speed for the other drive unit is determined with the aid of a drivetrain model. | 09-22-2011 |
20110237387 | Individual-powered dual CVT differential system with stabilizing device - The present invention relates to a multi-motor driving common load, such as two or more motors, in which CVT is installed between the individual motor and the wheel group at individual load, when the multi-motor, such as two or more motors, installed at the common load structure individually drives the individual load through the arranged CVT to get rotational speed difference, and to make differential speed drive operation through the speed ratio variation by the CVT, and the stabilizing device constituted by torque limited coupling device with sliding damping during sliding is installed between the loads individually driven by the two CVTs. | 09-29-2011 |
20110237388 | AUTOMATIC TRANSMISSION FOR A HYBRID VEHICLE - An automatic transmission for a hybrid vehicle includes a hydraulic circuit ( | 09-29-2011 |
20110251017 | VEHICULAR POWER TRANSMISSION CONTROL APPARATUS - When it is determined that a driver requests a deceleration of a vehicle (t | 10-13-2011 |
20110251018 | VEHICLE ASSEMBLY WITH INDEPENDENT ELECTRIC WHEEL MOTORS FOR ELECTRIC HYBRID VEHICLES - A vehicle drive assembly is provided. The vehicle drive assembly includes an engine, a transmission operably coupled with the engine, an output shaft operably coupled with the transmission, a differential operably coupled with the output shaft, an axle shaft rotatably coupled to the differential, at least one wheel selectively coupled to the axle shaft via a rotatable axle stub, an electric wheel motor operably coupled to the at least one wheel via the rotatable axle stub, and a coupling device operably coupled with the electric wheel motor for selectively coupling the axle stub with the axle shaft. | 10-13-2011 |
20110256978 | Method and Device for Starting a Hybrid Vehicle - In a method for starting a hybrid vehicle having a first drive unit and a second drive unit, the setpoint starting torque is generated by the second drive unit. In this method, a starting clutch for connecting the first drive unit is brought into the slipping state when a predefined setpoint torque of the second drive unit is exceeded. | 10-20-2011 |
20110263379 | Multiple-Mode Power Split Hybrid Powertrain - A hybrid electric vehicle powertrain having a mechanical power source and an electro-mechanical power source, including a generator, a motor and a battery. Driving torque developed by the mechanical power source is delivered through one clutch of a geared transmission to a power output shaft. The electric motor of the electro-mechanical power source delivers driving torque through a second clutch of the geared transmission. A mechanical reverse drive torque is used to improve reverse drive performance. A reduction in duration of operation in a negative power split during a driving event is achieved to improve vehicle powertrain efficiency. A series drive is available as the mechanical power source drives the generator to charge the battery, which drives the motor. The generator may act as an engine starter motor. | 10-27-2011 |
20110269598 | ELECTRO-HYDRAULIC CONTROL SYSTEM FOR A HYBRID DRIVE UNIT - A control system for a hybrid drive unit includes a pressure regulator valve, a first variable bleed solenoid valve for controlling a stationary clutch and a second variable bleed solenoid valve for controlling a rotating clutch. The control system controls the stationary clutch and the rotating clutch to operate the hybrid drive unit in four different modes. | 11-03-2011 |
20110269599 | HYBRID VEHICLE - Disclosed is a hybrid vehicle with a transmission, the transmission including a transmission input shaft ( | 11-03-2011 |
20110287889 | METHOD FOR COUPLING AN INTERNAL COMBUSTION ENGINE OF A PARALLEL-HYBRID DRIVE TRAIN - A method of coupling a combustion engine of a parallel-hybrid drive train via a clutch positioned between the engine and an electric machine with the clutch device initially disengaged, the engine rotational speed approximately at an engine idling rotational speed, and the machine rotational speed larger than the engine idling rotation speed. When a request is made for a drive torque value which is larger than a torque threshold, the engine rotational speed is brought to a rotational speed value above the machine rotational speed and the clutch is slipping engaged once the rotational speed value is reached, while the engine, when the drive train decelerates and a request is made to couple the engine, is brought into deceleration cancellation and the engine rotational speed is brought up to the machine rotational speed while engaging the clutch and dependent on a transfer ability of the clutch. | 11-24-2011 |
20110294620 | POWER TRANSMISSION SYSTEM FOR HYBRID VEHICLE - A power transmission system for transmitting power from a crank shaft of an engine to a drive shaft of a transmission gear box via a clutch assembly is disclosed. The clutch assembly facilitates co-rotation of the crank and drive shaft when engaged and allows relative rotation between the crank and drive shaft when not engaged. The system includes an electric motor with an input/output shaft and a gear assembly coupled to the input/output and drive shaft. Rotation of the drive shaft is transmitted to rotation of the input/output shaft via the gear assembly and rotation of the input/output shaft is transmitted to rotation of the drive shaft via the gear assembly. The drive shaft is drivable by the engine via the crank shaft when the clutch assembly is engaged and is drivable by the electric motor via the input/output shaft and gear assembly when the clutch assembly is not engaged. | 12-01-2011 |
20110306463 | AUTOMATED MANUAL TRANSMISSION WITH HYBRID DRIVE - An automated manual transmission system ( | 12-15-2011 |
20110319225 | SHIFT CONTROLLER AND SHIFT CONTROLLING METHOD - A shift controller controls a transmission for a hybrid vehicle in which: an engine and a motor are connected together via a clutch; and the transmission is placed between the motor and driving wheels. The shift controller has: a first shift controlling unit which performs shift control on a basis of at least one of transmission efficiency of the transmission and power generation efficiency of the motor in a case where regeneration is performed with the clutch disengaged during deceleration of the hybrid vehicle; and a second shift controlling unit which performs shift control to make a transmission gear ratio of the transmission smaller than in the shift control performed by the first shift controlling unit in a case where the regeneration is performed with the clutch engaged during the deceleration of the hybrid vehicle. | 12-29-2011 |
20120004073 | HYBRID POWER DRIVE SYSTEM AND A DRIVE METHOD OF THE SAME - A hybrid power drive system comprises: an engine operatively coupled to a gearbox; a first motor operatively coupled to the engine; a first wheel group operatively coupled to the gearbox; a second motor operatively coupled to a second wheel group; an energy storage device connected to the first motor and the second motor, respectively. The gearbox comprises a first decelerating mechanism and a second decelerating mechanism. The first wheel group is operatively coupled to the first decelerating mechanism and the second decelerating mechanism, respectively. The engine is operatively coupled to the first decelerating mechanism and the second decelerating mechanism, respectively. | 01-05-2012 |
20120010041 | Transitioning Between Electric-Drive and Parallel-Drive in a Hybrid-Electric Vehicle Powertrain - A method for operating a vehicle powertrain includes driving first wheels using an electric machine, starting an engine, using a second electric machine driven by the engine to produce synchronous speed at a input of a transmission having a desired gear engaged, engaging a clutch that connects said input and the engine, and using the engine and the transmission to drive second wheels. | 01-12-2012 |
20120028757 | CONTROL APPARATUS FOR HYBRID VEHICLE - In a hybrid vehicle having a locking mechanism in which a play elimination process is required in the locking, a torque shock in the play elimination is reduced. In a hybrid vehicle | 02-02-2012 |
20120058858 | AUTOMOBILE DRIVING SYSTEM AND CONTROL METHOD THEREOF - An automobile driving system includes an engine and a transmission. The transmission includes a variable gear ratio mechanism and a gear ratio of the transmission can be set to infinity. A one-way clutch is provided at an output portion of the transmission. At a time of a engine stopping controller controlling to stop the engine, a transmission-and-control device uses inertia from the engine up to an input member of the one-way clutch as assisting force for driving operations of the variable gear ratio mechanism to change the gear ratio at the transmission to infinity or close to infinity, before the engine actually stops. | 03-08-2012 |
20120071295 | POWER TRANSMITTING DEVICE - Provided is a power transmitting device that lets a motor in a hybrid vehicle be smaller and lighter, prevents internal resistance and inertia of the generator motor from becoming driving resistance, and can effectively utilize energy. Via a first clutch ( | 03-22-2012 |
20120077638 | SHIFTING CONTROL APPARATUS FOR VEHICULAR POWER TRANSMITTING SYSTEM - A shifting control apparatus for a power transmitting system of a vehicle provided with a vehicle drive electric motor, and a step-variable automatic transmission constituting a part of a power transmitting path between said vehicle drive electric motor and drive wheels, the shifting control apparatus controls said vehicle drive electric motor to perform a regenerative operation in a coasting state of the vehicle, and controls said automatic transmission to perform a shift-down operation at a predetermined coasting shift-down vehicle speed in the coasting state, the shifting control apparatus is configured: to change said coasting shift-down vehicle speed according to a regenerative power of said vehicle drive electric motor; to control said vehicle drive electric motor in the coasting state of the vehicle, so as to perform the regenerative operation at a vehicle speed higher than a predetermined drive/driven switching vehicle speed value, and so as to generate a vehicle drive torque at a vehicle speed lower than said predetermined drive/driven switching vehicle speed value; and to lower said coasting shift-down vehicle speed value at which the shift-down operation of said automatic transmission to a lowest shift position thereof is performed, and said drive/driven switching vehicle speed value, with an increase of said regenerative power of said vehicle drive electric motor. | 03-29-2012 |
20120083385 | CONTROL OF A POWERTRAIN FOR A HYBRID SYSTEM - A powertrain includes a first electric motor coupled to an internal combustion engine with a ratio changing device and a second motor selectively coupled to the engine through an engine disconnect clutch, the second motor further coupled to an input shaft of a transmission. A method to control the powertrain includes monitoring a propelling torque provided by the second motor, monitoring a speed of the second motor, determining a condition of the second motor based upon the propelling torque and the speed of the second motor, selecting a control mode for the first motor based upon the condition of the second motor and controlling the first motor, the second motor, and the engine disconnect clutch based upon the control mode. | 04-05-2012 |
20120083386 | DRIVE ARRANGEMENT FOR A HYBRID VEHICLE AND METHOD FOR OPERATING AN ELECTRIC ENGINE IN A HYBRID VEHICLE - A hybrid vehicle has an internal combustion engine and an electric engine. A drive arrangement for the vehicle has a crankshaft-side clutch part rigidly connected to a crankshaft of the internal combustion engine, and the crankshaft-side clutch part may be coupled to a drive train shaft-side clutch part via a clutch. The clutch part on the drive train shaft side is mechanically connected to a drive train shaft via at least one element for torsional vibration isolation. The drive train shaft is configured at least partially as a rotor of the electric engine. The crankshaft-side clutch part, the clutch and the drive train shaft-side clutch part form at least one part of the primary mass of a dual-mass flywheel. The drive train shaft forms at least one part of the secondary mass of the dual-mass flywheel. | 04-05-2012 |
20120083387 | REHEATED GAS TURBINE SYSTEM, IN PARTICULAR SUCH A SYSTEM HAVING A FUEL CELL - The present invention relates to (with reference to FIG. | 04-05-2012 |
20120108385 | HYBRID VEHICLE AND CONTROL METHOD THEREFOR - The second clutch is caused to transition to an engaged state after setting the second clutch in a slip state when the vehicle starts in the hybrid start mode, the temperature of a magnet of the electric motor is estimated based on the temperature of the hydraulic oil and an operating condition of the electric motor when the second clutch is controlled to be in the slip state; and an output torque and a lower limit rotation speed of the electric motor is restricted and reduced when the estimated temperature of the magnet exceeds a restrictive temperature. | 05-03-2012 |
20120108386 | DRIVE CONTROL APPARATUS FOR HYBRID VEHICLE - A drive control apparatus for a hybrid vehicle which has an engine selectively set in one of a normal fuel-consumption operation mode and a low fuel-consumption operation mode for obtaining a lower fuel consumption; a generator selectively used for one of being driven by the engine and assisting driving of the engine; a motor for generating a driving force of the vehicle by electric power supplied by the generator or a battery device; and a clutch between the generator and wheels of the vehicle. The drive control apparatus has a control part for performing a low fuel-consumption driving assistance mode when the engine is set in the low fuel-consumption operation mode. In the low fuel-consumption driving assistance mode, the clutch is connected, and driving of the vehicle is assisted using one of the generator and the motor, which is selected in accordance with an operation state of the vehicle. | 05-03-2012 |
20120115675 | METHOD FOR CONTROLLING A DRIVE TRAIN - A method of controlling a drive-train of a motor vehicle, which comprises an internal combustion engine with a driveshaft, an electric machine in driving connection with the driveshaft of the internal combustion engine, a semi-automatic transmission with an input shaft and a plurality of gears that can be engaged selectively, and an automated friction clutch arranged between the driveshaft of the internal combustion engine and the input shaft of the transmission, such that a gearshift of the transmission occurs in combination with suitable control of the internal combustion engine while the friction clutch is at least partially and/or briefly engaged. To speed up the shifting process and to attenuate torque and speed surges during the shifting process, the electric machine is operated briefly as a generator and/or as a motor. | 05-10-2012 |
20120115676 | METHOD FOR CONTROLLING A HYBRID DRIVE TRAIN OF A VEHICLE - A method of controlling a hybrid drive-train of a vehicle in which the hybrid drive-train comprises a combustion engine having a driveshaft, an electric machine that can be connected to the driveshaft of the engine by a clutch, an automated transmission with an input which is connected to the rotor of the electric machine, and shifting elements for shifting between two gears. During electric driving operation with the engine stopped and the clutch disengaged, the engine can be drag-started in combination with a downshift in the transmission. Drag starting of the engine is carried out by disengaging the frictional shifting element to be disengaged to below a slipping limit, engaging the clutch until the engine reaches or exceeds its minimum starting speed, starting the engine self-starts, substantially disengaging the clutch, separately adjusting the engine and electric machine to the synchronous speed of the target gear, and fully engaging and disengaging associated shifting elements. | 05-10-2012 |
20120115677 | AUTOMATIC TRANSMISSION FOR HYBRID VEHICLE - An automatic transmission for a hybrid vehicle has a first clutch connecting a first drive gear shaft rotatably supporting drive gears G | 05-10-2012 |
20120122630 | METHOD AND DEVICE FOR STARTING AN INTERNAL COMBUSTION ENGINE OF A HYBRID DRIVE TRAIN - A method and a device are described for starting an internal combustion engine of a hybrid drive train, having an internal combustion engine and at least one additional machine, in particular an electric machine, a separating clutch, which is situated between the internal combustion engine and the additional machine, and a crankshaft angle sensor for detecting the instantaneous crankshaft angle of the internal combustion engine being provided. Arrangements are provided to perform the following operations to start the internal combustion engine when a high-voltage battery is essentially discharged, including a) the separating clutch is or has already been disengaged, b) the additional machine is accelerated, c) after conclusion of the acceleration operation of the additional machine, the separating clutch is engaged, so that the internal combustion engine is also accelerated, d) as soon as the crankshaft angle sensor system supplies a favorable crankshaft angle, the internal combustion engine is started by direct start. | 05-17-2012 |
20120129649 | METHOD FOR OPERATING A DRIVE TRAIN - A method of operating a drive train of a motor vehicle with a drive assembly which has a combustion engine and an automatic transmission with frictional shift elements positioned between the drive assembly and an output, namely for executing a traction upshift or a traction downshift in which at least one frictional shift element of the automatic transmission is engaged and at least one frictional shift element of the automatic transmission is disengaged. During execution of a traction upshift and at least, during the engagement procedure of a frictional shift element being engaged, reducing the torque provided by the combustion engine, and for executing a traction downshift at least during the lowering of the transferability of a frictional shift element being disengaged, reducing the torque provided by the combustion engine. | 05-24-2012 |
20120129650 | METHOD FOR ACCELERATING THE DECOUPLING OF A STARTING CLUTCH, WHICH RELEASABLE CONNECTS AN ELECTRIC MACHINE TO A TRANSMISSION INPUT, IN A HYBRID DRIVE TRAIN OF A VEHICLE - A method of accelerating decoupling of the starting clutch ( | 05-24-2012 |
20120129651 | SYSTEM FOR DRIVING AN ASSEMBLY ARRANGEMENT FOR A MOTOR VEHICLE - A system for driving an assembly arrangement for a motor vehicle, which assembly arrangement having at least one auxiliary assembly and an electric machine which is configured independently of a drive unit of the motor vehicle. It is possible for the electric machine to be operated both as a motor for driving the auxiliary assembly and as a generator for generating electric power. If required, it is possible for a separate engine which is configured as an internal combustion engine to be connected or fastened releasably via an interface to the assembly arrangement and to be coupled to the assembly arrangement for drive action, in order to supply the at least one auxiliary assembly and/or the electric machine with rotational drive moment. | 05-24-2012 |
20120135836 | HYBRID VEHICLE AND HYBRID POWER SYSTEM - An operation method of a hybrid vehicle having an automatic manual transmission system adapted to use at least two energy sources is provided with the following steps. Engaging an engine with a starter generator motor such that the engine and the starter generator motor rotate synchronously. Performing a speed changing by using a control unit assembly through controlling rotation speed of the traction motor and a rotation speed of the starter generator motor to a desired rotation speed for the speed changing according to a running state of the vehicle, such that the engine and the traction motor nearly rotate synchronously with the automatic manual transmission system to perform a gear ratio shifting process thereby to perform the speed changing. Controlling an automatic-switching clutch to engage or disengage the engine and the traction motor to achieve a plurality of driving mode for the vehicle. | 05-31-2012 |
20120142490 | SHIFTING CONTROL METHOD OF HYBRID VEHICLE - A gear shifting method of a hybrid vehicle may include releasing a clutch and brake of a transmission and determining a neutral condition status, controlling torque of an engine connected to one operational element of a first planetary gear set in a neutral condition, and controlling speed of a first motor/generator connected to the other operational element of the first planetary gear set. Accordingly, a speed of the first and second motor/generator are controlled and a torque of the engine is controlled in a neutral or parking state of a shift lever such that a mode change becomes easy and the torque of the engine is continuously controlled to improve a shift quality and a driving performance and to save fuel, while the neutral or parking state is changed to a drive or reverse state or the drive or reverse state is changed to the neutral or parking state. | 06-07-2012 |
20120178585 | FRICTION LAUNCH STRATEGY FOR A MOTOR VEHICLE POWERTRAIN - A control strategy for launching a motor vehicle includes using an electric motor to provide high torque at low speeds during synchronization of launch clutches. An internal combustion engine is started and connected with the electric motor to provide additional torque capacity. Selective engagement and disengagement of an engine disconnect clutch prevents the engine start from interfering with the motor vehicle launch. | 07-12-2012 |
20120190498 | Control Strategy for Multi-Mode Vehicle Propulsion System - A method for controlling a propulsion system for a vehicle including a transmission coupling an output shaft of the internal combustion engine to a drive wheel of the vehicle, wherein said transmission includes a lash region, the method comprising of adjusting an operating parameter of the engine so that at least one cylinder of the engine is transitioned between a first combustion mode and a second combustion mode, and varying a timing of said transition responsive to whether the transmission is operating within the lash region of the transmission. | 07-26-2012 |
20120202646 | CONTROL APPARATUS FOR HYBRID VEHICLE - A control apparatus of a hybrid vehicle provided with an engine, a motor, an automatic transmission performing a shift by engaging/disengaging a plurality of engagement elements, a first clutch arranged between the engine and the motor for transmitting/cutting a driving force between the engine and the motor and a second clutch arranged between the motor and driving wheels for transmitting/cutting a driving force from the motor to the driving wheels, has a slip control section that controls the second clutch to a slip state during the shift of the automatic transmission. In a case of a successive shift in which a current shift and a succeeding shift are successively performed, the slip control section gradually increases an engagement pressure of the second clutch when changing the slip state of the second clutch to a fully engaged state after the current shift is completed and before the succeeding shift is completed. | 08-09-2012 |
20120208671 | Series/Parallel Dual Motor Multi-Clutch Hybrid Driving Unit For Vehicle - A series/parallel dual motor dual-clutch hybrid electrical driving unit for vehicle includes: a main traction motor ( | 08-16-2012 |
20120208672 | SYSTEM, METHOD, AND APPARATUS FOR CONTROLLING POWER OUTPUT DISTRIBUTION IN A HYBRID POWER TRAIN - A method includes determining a machine shaft torque demand and a machine shaft speed, in response to the machine shaft torque demand and the machine shaft speed, determining a machine power demand, determining a power division description between an internal combustion engine, a first electrical torque provider, and a second electrical torque provider, determining a hybrid power train configuration as one of series and parallel, determining a baseline power division description in response to a vehicle speed and the machine power demand, determining a state-of-charge (SOC) deviation for an electrical energy storage device electrically coupled to the first electrical torque provider and the second electrical torque provider, and adjusting the baseline power division description in response to the SOC deviation and the hybrid power train configuration. | 08-16-2012 |
20120220420 | CONSTRUCTION MACHINE | 08-30-2012 |
20120225751 | ACCESSORY DRIVE MOTOR CONFIGURATION - An accessory drive motor configuration is disclosed. One embodiment of the accessory drive motor configuration is an apparatus including an internal combustion engine having a crankshaft, wherein the crankshaft is structured to provide traction power. The apparatus further includes an accessory drive system operably coupled to a shaft. The shaft is selectively coupled to an electro-mechanical device and selectively coupled to the internal combustion engine. The shaft extends through at least a portion of the electro-mechanical device. | 09-06-2012 |
20120238404 | METHOD FOR OPERATING A DRIVETRAIN - A method of operating a drive train having a hybrid drive including a combustion engine and electric motor, a clutch located between the engine and the motor, a transmission, a starting element and a brake pedal. For electric crawling from a state in which the clutch is disengaged, the brake pedal is activated and the combustion engine is turned off, initially the starting element is brought to or maintained at a filling pressure. Next, the rotational speed of the electric motor is adjusted to be higher, by a defined slippage rotational speed, than a transmission side rotational speed. When this slippage is reached, the starting element is further engaged to create a crawl torque at the output. The electric motor continues at rotational speed control so that the slippage is maintained. | 09-20-2012 |
20120244992 | DRIVING DEVICE FOR VEHICLE - A driving device with an input member connected to an engine, an output member connected to wheels, first and second rotating electrical machines, a differential gear unit including at least three rotational elements, and a control device. The control device includes a differential rotation reducing control, an engagement control, and a start up control that changes the rotation speed of the first rotating electrical machine, which allows the internal combustion engine to have a rotation speed at which starting is possible, made as a target value, when in direct engagement. The differential rotation reducing control changes the rotation speed of the first rotating electrical machine with the upper limit and the lower limit of a starting torque output range, which is a rotation speed range in which the torque necessary for starting the internal combustion engine may be output by the first rotating electrical machine, made as limits. | 09-27-2012 |
20120258838 | HYBRID SYSTEM - A hybrid system includes a hybrid module that is located between an engine and a transmission. The hybrid system includes an energy storage system for storing energy from and supplying energy to the hybrid module. An inverter transfers power between the energy storage system and the hybrid module. The hybrid system also includes a cooling system, a DC-DC converter, and a high voltage tap. The hybrid module is designed to recover energy, such as during braking, as well as power the vehicle. The hybrid module includes an electrical machine (eMachine) along with electrical and mechanical pumps for circulating fluid. A clutch provides the sole operative connection between the engine and the eMachine. The hybrid system further incorporates a power take off (PTO) unit that is configured to be powered by the engine and/or the eMachine. | 10-11-2012 |
20120264565 | CONTROL DEVICE - A control device controls a vehicle drive device including an input member connected to and driven by an internal combustion engine; an intermediate member connected to and driven by a rotating electrical machine; an output member connected to and driven by a wheel; a first engagement device provided between the input member and the intermediate member; and the second engagement device provided between the intermediate member and the output member. The rotating electrical machine generates power while the first engagement device is directly engaged, and has a differential rotation control region wherein the first engagement device is moved from direct engagement to slipping engagement and the second engagement device is moved from disengagement to slipping engagement during special takeoff control, which controls the vehicle so as to take off while the second engagement device is disengaged and the rotating electrical machine is generating power. | 10-18-2012 |
20120270697 | VEHICLE DRIVE DEVICE - A vehicle drive including an input coupled to an engine, an output coupled to wheels, an intermediate member between the input and output and coupled to a rotary electric machine, a friction engagement device between the input and intermediate member, and a control device. The control device, when starting the engine with the friction engagement device disengaged, engages the friction engagement device when a rotational speed difference between the input and intermediate member is equal to or less than a predetermined value; raises a rotational speed of the input using the rotary electric machine with the friction engagement device engaged to start the engine; and, when a rotational speed of the engine is equal to or more than a predetermined value, reduces an engagement pressure of the friction engagement device and the friction engagement device is returned to the engaged state when the rotational speed difference reaches a threshold. | 10-25-2012 |
20120270698 | VEHICLE DRIVE DEVICE - A vehicle drive device includes an input coupled to an internal combustion engine; an output coupled to wheels; first and second rotary electric machines; a differential including at least three rotary elements; a control; and an engagement device. The control determines, when engine stop conditions are established while the engagement device is drivably connected, the engine is operating, and the output member is rotating, whether rotation of the first electric machine when stop conditions are established is opposite to rotation of the first electric machine when rotation of the engine stops; executes torque control where the first electric machine outputs torque to reduce the rotational speed of the engine when the stop establishing rotational direction is opposite to the subject rotational direction; and issues a command to release the drivable connection when the rotational speed of the first electric machine falls within a rotational speed range that includes zero. | 10-25-2012 |
20120277059 | MOVING APPARATUS - A moving apparatus that is capable of properly driving an accessory while preventing driven parts from being driven when the accessory is driven in a state where the driven parts are at rest. In the moving apparatus VE | 11-01-2012 |
20120277060 | DRIVING FORCE TRANSMISSION DEVICE FOR HYBRID VEHICLE - A driving force transmission device for a hybrid vehicle is provided with a motor which drives a rotation shaft, and a connection/disconnection switching device which switches between connection and disconnection of driving force for driving wheels, the driving force being transmitted from an engine. The driving force transmission device is also provided with the auxiliary device driving mechanism, which includes one or more auxiliary device driving shafts for transmitting driving force to the in-vehicle accessory devices, one or more rotation transmission sections which transmit at least either engine's driving force or motor's driving force to one or more accessory device driving shafts via the rotation shaft, and a plurality of one-way clutches provided between the one or more rotation transmission sections and the one or more accessory device driving shafts. | 11-01-2012 |
20120289376 | HYBRID VEHICLE WITH DUAL CLUTCH TRANSMISSION - A vehicle includes an engine that generates an engine torque and a motor that generates a motor torque. A transmission can receive the engine torque, the motor torque, or both. The transmission includes a first gear set and a second gear set, as well as a first clutch that at least partially engages to transfer torque to the gears in the first gear set and a second clutch that at least partially engages to transfer torque to the gears in the second gear set. A controller can control the engine torque and the motor torque to control a speed of the engine to follow a desired speed profile. The controller can also control the engagement of the first clutch and the second clutch to optimize a desired gear state to minimize system losses. | 11-15-2012 |
20120295758 | METHOD FOR OPERATING A HYBRID VEHICLE - A method is provided for operating a hybrid drive train of a hybrid vehicle. The drive train has an internal combustion engine, a first electric machine, a transmission with an input shaft, a separating element and a first axle. The internal combustion engine can be connected to the first electric machine via the separating element. When the separating element is opened and the internal combustion engine is stationary, a difference in rotational speed occurs at the separating element between the internal combustion engine and the rotating first electric machine. The separating element is opened below and up to a maximum permissible difference in rotational speed at the separating element to drive the hybrid vehicle purely electrically by the first electric machine or to brake the vehicle or to coast. Above the maximum permissible difference in rotational speed the separating element and the first electric machine are separated from one another. | 11-22-2012 |
20120302396 | SYSTEM FOR DETERMINING THAT DRIVING OF A HYBRID VEHICLE IS DISABLED - A system for determining disablement of driving of a hybrid vehicle is disclosed. The system for determining disablement of driving of a hybrid vehicle may include: power electronic components having a battery at which DC electricity is stored, an inverter converting the DC electricity of the battery into AC electricity, and a motor receiving the AC electricity from the inverter and generating driving torque; an engine burning a fuel so as to generate driving torque and being selectively connected to the motor; an engine clutch selectively connecting the engine to the motor; a transmission connected to the motor to receive the driving torque of the motor or the driving torque of the engine; and a control portion controlling operations of the power electronic components, the engine, and the engine clutch, wherein the control portion turns off a system ready indication in a case that driving of the vehicle is disabled. | 11-29-2012 |
20120302397 | METHOD FOR OPTIMISING HYBRID VEHICLE BATTERY RECHARGING - The invention essentially relates to a method for optimising the recharging of a hybrid vehicle battery. When the clutch ( | 11-29-2012 |
20120309585 | METHOD AND APPARATUS FOR EXECUTING A TRANSMISSION SHIFT IN A POWERTRAIN SYSTEM INCLUDING A TORQUE MACHINE AND AN ENGINE - A method for operating a powertrain system including a torque machine coupled to an internal combustion engine that coupled to a transmission includes, upon commanding a shift in a transmission operating range, activating an immediate response mode to effect the shift. Activating the immediate response mode includes controlling the engine to achieve a predicted engine torque command, and controlling motor torque of the torque machine in response to a difference between an actual engine torque and an immediate crankshaft torque for shift command. An arbitrated predicted motor torque is determined A possible crankshaft torque is determined in response to the arbitrated predicted motor torque and the predicted engine torque command. Operation of the transmission at the end of the shift event is commanded in response to the possible crankshaft torque. A predicted response mode is activated to complete the shift in the transmission operating range. | 12-06-2012 |
20120309586 | CONTROL METHOD FOR VEHICLE DRIVE SOURCE OF HYBRID VEHICLE WHEN A TRANSMISSION MALFUNCTIONS - A system and method for controlling a power source when a transmission malfunctions in a hybrid vehicle is disclosed. In particular, a control unit confirms a speed of a transmission output is 0 rpms, detects whether the transmission is in park or neutral, and limits a speed of an engine and a motor in response to determining that the transmission is in park or neutral and that the transmission output is 0 rpms. | 12-06-2012 |
20120309587 | ENGINE STOP CONTROL SYSTEM FOR HYBRID ELECTRIC VEHICLE - An engine stop control system for a hybrid electric vehicle including a powertrain having an engine, an electric motor/generator, and driving wheels, including a first clutch coupling the engine to the motor/generator, a second clutch coupling the motor/generator to the driving wheels, a controller configured to select between two driving modes of the vehicle by controlling engagement and disengagement of the first clutch and the second clutch so that the vehicle may be driven either solely by the motor/generator or a combination of the engine and the motor/generator, and to control the stop position of the engine to be a desired stop position by controlling the rotation speed of the motor/generator while the first clutch in complete engagement and the second clutch in a slip state. | 12-06-2012 |
20120316028 | POWER TRANSMISSION CONTROLLING APPARATUS - A power transmission controlling apparatus of a vehicle includes a clutch capable of connecting/disconnecting power transmission between an engine and a motor/generator, and a torque converter enabling power transmission between the engine or/and the motor/generator and an automatic transmission. When the engine is started by motoring torque with engagement of the clutch during rotation of the motor/generator, the power transmission controlling apparatus sets a torque compensation amount by the motor/generator based on an estimated torque capacity of the clutch, and suppresses torque fluctuations on a power transmission path accompanying engagement of the clutch by power of the motor/generator containing the torque compensation amount. The power transmission controlling apparatus corrects the torque capacity or the torque compensation amount based on input torque of the torque converter. | 12-13-2012 |
20120322610 | METHOD AND APPARATUS FOR EXECUTING A SHIFT IN A POWERTRAIN SYSTEM - A method for activating an oncoming clutch in a transmission includes monitoring rotational speeds of clutch elements of the oncoming clutch wherein the clutch elements are coupled to first and second rotationally independent torque actuators. A control speed profile for the first rotationally independent torque actuator is commanded. A speed profile of the oncoming clutch approaching zero speed is generated as is a control speed profile for the second rotationally independent torque actuator corresponding to a speed of the first rotationally independent torque actuator, the speed profile of the oncoming clutch, and an output speed of the transmission. A speed of the second rotationally independent torque actuator is controlled using the control speed profile for the second rotationally independent torque actuator. A speed of the oncoming clutch is monitored and the oncoming clutch is activated when the speed of the oncoming clutch is zero. | 12-20-2012 |
20120322611 | METHOD AND APPARATUS FOR SIMULTANEOUS PARALLEL CONTROL OF A TORQUE PHASE AND AN INERTIA PHASE FOR HYBRID POWERTRAINS - A method to execute a shift in a powertrain including a plurality of torque generative devices rotatably connected through a first clutch includes operating the powertrain in a continuously variable operating range state, and monitoring a command to execute the shift including monitoring a target speed for a first torque generative device, and monitoring a command to disengage the first clutch. The first clutch is shifted from an engaged state to a disengaged state, including operating a torque phase of the first clutch wherein the first clutch is transitioned from the engaged state to the disengaged state, and simultaneous with the torque phase, operating an inertia speed phase of the first clutch wherein a speed of the first torque generative device is transitioned from an initial speed to the target speed. | 12-20-2012 |
20130005530 | VEHICULAR HYBRID DRIVE SYSTEM - A motor drive mode for driving a vehicle with only a second motor/generator is available in a selected one of two motor drive sub-modes consisting of a response-oriented motor drive sub-mode established by placing a forward drive clutch in a released state and placing a starting clutch in an engaged state, and a fuel-economy-oriented motor drive sub-mode established by placing the forward drive clutch in an engaged state and placing the starting clutch in a released state. In the response-oriented motor drive sub-mode in which an engine and a transmission are disconnected from each other, the engine can be efficiently started to change the vehicle drive mode to an engine drive mode, and an engaging action of only the forward drive clutch is required after starting of the engine, so that the engine drive mode can be established with a high response. In the fuel-economy-oriented motor drive sub-mode, the starting clutch is released to disconnect the transmission from the motor/generator, for reducing a power loss and improving fuel economy. After starting of the engine to establish the engine drive mode, an engaging action of only the starting clutch is required. | 01-03-2013 |
20130012353 | CONTROL DEVICE - A control device that controls a vehicle drive device, including a rotary electric machine and internal combustion engine that drive wheels, a first friction engagement device and a second friction engagement device. The control device is configured to execute rotational state control in which a rotational state of the rotary electric machine is controlled so as to establish a target rotational state with the second friction engagement device in a slip engagement state, and hydraulic pressure regulation control in which a hydraulic pressure supplied to the second friction engagement device is controlled on the basis of torque of the rotary electric machine produced during the rotational state control after the first friction engagement device is transitioned to a direct engagement state while the second friction engagement device is transitioned from the slip engagement state to a direct engagement state. | 01-10-2013 |
20130023379 | FLUID COUPLING FOR A HYBRID POWERTRAIN SYSTEM - A hybrid powertrain system includes an internal combustion engine, an electric machine coupled to a transmission, a fluid coupling including an impeller and a turbine wherein the impeller is mechanically coupled to a rotatable member of the electric machine and the turbine is mechanically coupled to a rotatable member of the internal combustion engine. The fluid coupling is effective to fluidically couple torque from the electric machine to the internal combustion engine when the impeller and turbine are not mechanically locked. | 01-24-2013 |
20130023380 | SIMULTANEOUS AUTO-START AND ASYNCHRONOUS SHIFT FOR A HYBRID VEHICLE - A vehicle includes an engine, a first motor, a second motor, and a gearbox. An oncoming clutch is configured to engage during a transition to a target operating mode to transfer an engine torque to the gearbox during the target operating mode. An off-going clutch is configured to transfer a reactive torque to the gearbox during the transition to the target operating mode. The off-going clutch is configured to be disengaged during at least a portion of the target operating mode. A controller is configured to simultaneously control the off-going clutch and the oncoming clutch during the transition. The controller is configured to control the reactive torque of the off-going clutch using a clutch torque profile associate with the target operating mode and the engagement of the oncoming clutch using a shift profile associated with target operating mode. | 01-24-2013 |
20130029803 | ASSEMBLY WITH A COMBUSTION ENGINE, AN ELECTRIC MACHINE AND A PLANETARY GEAR TRAIN ARRANGED THEREBETWEEN, AS WELL AS A METHOD FOR CHANGING AN OPERATING MODE OF SUCH ASSEMBLY - An assembly with a combustion engine and an electric machine, which are coupled with each other by way of a planetary gear train, employs a claw clutch or a toothed clutch, in particular as a brake, between a ring gear of the planetary gear train and a housing of the combustion engine. For this purpose, rotation speeds of the electric machine and the combustion engine set commensurate with a fixed gear ratio, and the brake is closed after the set rotation speeds have been attained with a predetermined minimum accuracy. In this way, machine elements which are compact and operate with insignificant wear, such as claw clutches or toothed clutches, can be employed as the clutch or brake. | 01-31-2013 |
20130029804 | ASSEMBLY WITH A PLANETARY GEAR TRAIN FOR A MOTOR VEHICLE, A MOTOR VEHICLE AND A METHOD FOR OPERATING A PLANETARY GEAR TRAIN - In an assembly with a planetary gear train, which includes the elements sun gear, planet carrier with planetary gears and ring gear, two elements, in particular the sun gear and the planet carrier, are coupled with each other via an overrunning clutch. A clutch bridges the overrunning clutch. Bridging is discontinuous and controlled by a control device based on the relative rotation of the two elements to be coupled. For example, one rotation speed sensor can measure the rotation speed of an electric machine, whereas another rotation speed sensor can measure the rotation speed of a crankshaft of an combustion engine. In a motor vehicle, the combustion engine can be coupled with an electric machine, using different gear ratios during startup or boosting and in generator operation. In addition, the electric machine can drive an air-conditioning compressor when the combustion engine is not running. | 01-31-2013 |
20130029805 | DRIVE CONTROL APPARATUS FOR VEHICLE AND METHOD OF CONTROLLING DRIVE APPARATUS FOR VEHICLE - A drive control apparatus for a vehicle includes an engine, an electric motor, a clutch mechanism, an engine rotation sensor, a motor rotation sensor, an acceleration and deceleration intention detecting portion, and a controller. The controller controls a rotation speed of the engine to be an acceleration intention target value greater than a rotation speed of the motor and thereafter brings the clutch mechanism into the engagement state in a case where the acceleration and deceleration intention detecting portion detects that the vehicle is in an acceleration intention mode, and controls the rotation speed of the engine to be a deceleration intention target value smaller than the rotation speed of the motor and thereafter brings the clutch mechanism into the engagement state in a case where the acceleration and deceleration intention detecting portion detects that the vehicle is in a deceleration intention mode. | 01-31-2013 |
20130035201 | Method and Device for Operating A Hybrid Vehicle - A method for operating a hybrid vehicle, having at least one first drive unit and one second drive unit, the second drive unit being started by at least one portion of the drive torque provided by the first drive unit in that the clutch situated between the first drive unit and the second drive unit is brought from a disengaged state into a slipping state. To improve the driving comfort of the hybrid vehicle during a start or a stop of the internal combustion engine, at least two clutches are shifted into the slipping state for starting the second drive unit. | 02-07-2013 |
20130035202 | POWER TRANSMISSION DEVICE - A power transmission device has a rigid body that includes a contact portion coming into contact with the first or second friction member and that moves the contact portion from a position of contact with the first or second friction member to a position of no contact with the first and second friction members, an elastic body that applies to the rigid body a force moving the contact portion to a position of contact with the first or second friction member, a first pushing mechanism that applies to the rigid body a pressure of liquid moving the contact portion to a position of contact with the first or second friction member, and a second pushing mechanism that applies to the rigid body a pressure of liquid moving the contact portion to a position of no contact with the first and second friction members. | 02-07-2013 |
20130035203 | CONTROL DEVICE FOR DRIVE MOTORS - A control system for driving motor configured to synchronize rotor phases of a plurality of driving motors of wheels using a single inverter. The control system comprises driving motor connected with a wheel to drive the wheel; a clutch interposed between the driving motor and the wheel; and a current control means connected with the driving motor to supply current thereto. A switching unit switches electrical connection in a manner to supply the current to both of the driving motors from one of the current control unit by interrupting the current supply from the other current control unit. The clutch interrupts torque transmission in case the switching mechanism switches the electrical connection in a manner to supply the current to both of the driving motors from one of the current control unit to drive the vehicle. | 02-07-2013 |
20130040778 | METHOD AND APPARATUS FOR CONTROLLING HYBRID ELECTRIC VEHICLES - A method for operating an engine and an integrated starter/generator/motor (ISGM) disposed in a hybrid electric vehicle, which includes launch and deceleration processes. The ISGM is used to both launch the vehicle and start the engine. The deceleration process includes operating a first clutch to disengage the engine from the ISGM during an initial phase, and engaging a second clutch during the initial phase to direct substantially all regenerative energy to provide the only source of electrical energy to recharge the energy storage device. | 02-14-2013 |
20130045833 | HYBRID VEHICLE DRIVING SYSTEM - In a hybrid vehicle in which power of electric motor is transmitted to a counter shaft | 02-21-2013 |
20130072347 | DRIVETRAIN FOR A PARALLEL HYBRID VEHICLE - A drivetrain ( | 03-21-2013 |
20130079192 | GEAR SHIFT CONTROL DEVICE FOR HYBRID VEHICLE DRIVE SYSTEM - A gear shift control device for controlling a hybrid vehicle drive system including an engine, an automated transmission, a clutch, and a motor generator, includes a torque indication device for indicating a driver request torque determined in accordance with an operation amount of an accelerator operated by a driver, a power generation interruption device changing a vehicle state to an engine driven state using all of the engine torque when a preliminary gear shift condition is satisfied in a state where the engine drives a driving wheel and the motor generator is actuated to generate an electric power, and a gear shift control device reducing the engine torque and generating an assist torque by actuating the motor generator, disconnecting the clutch, and returning the clutch to a connected state after changing gear sets of the gear train when a gear shift condition of the automated transmission is satisfied. | 03-28-2013 |
20130079193 | Hybrid Module - A hybrid module includes a housing, an input intended for rotationally coupling to an internal combustion engine, an output intended for rotationally coupling to an input of a gearbox, an electric machine arranged in the housing and having a stator and a rotor arranged within the stator radially, a separation clutch and a torsional vibration damper. The separation clutch and the torsional vibration damper are arranged within the rotor in both the radial and axial directions. | 03-28-2013 |
20130102437 | VEHICLE DRIVING SYSTEM AND CONTROL METHOD FOR VEHICLE DRIVING SYSTEM - A first engine ENG | 04-25-2013 |
20130109530 | DEVICE FOR A DRIVETRAIN OF A HYBRID VEHICLE, DRIVETRAIN AND METHOD FOR OPERATING THE SAME | 05-02-2013 |
20130116085 | HYBRID POWERTRAIN WITH MANUAL TRANSMISSION AND OFF-LATCHING CLUTCH, AND METHOD OF OPERATING THE SAME - A powertrain for a hybrid vehicle includes a clutch interconnecting an internal combustion engine and an electric motor. The electric motor is coupled to a manually operated gearbox operable in at least one electric only drive position and at least one hybrid drive position. A latch is coupled to the clutch and is moveable between a closed position inhibiting the clutch from interconnecting the internal combustion engine and the electric motor when the gearbox is disposed in the electric only drive position, and an open position allowing the clutch to interconnect the internal combustion engine and the electric motor when the gearbox is disposed in the hybrid drive position. | 05-09-2013 |
20130116086 | VEHICULAR POWER TRANSMITTING SYSTEM - Providing a vehicular power transmitting system which includes a torque limiter device and which is configured to reduce deterioration of durability of a rotary member disposed between an engine and the torque limiter device. | 05-09-2013 |
20130123063 | SYSTEM FOR HYBRID VEHICLE TO ENHANCE DRIVING PERFORMANCE DURING ELECTRIC MODE - Disclosed is system for a hybrid vehicle that includes an engine, a transmission, and a battery. The system may further include a first clutch configured to connect the engine with the transmission and having a first part and a second part; a first motor/generator configured to be connected to the first part and directly connected to the transmission; a second motor/generator configured to be connected to the second part; and a second clutch configured to connected the second motor/generator with the transmission. In particular, the first part and the second part may be clutches that can operate independently. | 05-16-2013 |
20130150206 | CLUTCH CONTROL DEVICE OF HYBRID VEHICLE - A clutch control of a hybrid vehicle can engage a clutch which not otherwise possible due to temporary factors, and can determine whether engaging members of the clutch have been successfully engaged. The clutch control controls the clutch having a pair of the engaging members which are provided in a power transmission path of the vehicle, and which are moved in the axial direction and engaged or released when switching is performed between power from a motor and power from an engine. The clutch control device has a rotation control unit for synchronizing the rotations of the engaging members when the clutch is shifted from a disengaged an engaged state, and a clutch engagement control unit for determining whether the engaging members have been engaged, based on rotational speed of the engaging members a predetermined time after axial movement of the engaging members. | 06-13-2013 |
20130150207 | VEHICLE POWER TRANSMISSION CONTROL DEVICE - In a state in which a vehicle travels while an internal-combustion-engine driving torque (Te) is transmitted to drive wheels, Te and a clutch torque Tc are decreased and an electric-motor driving torque (Tm) is increased based on the satisfaction of a shift-up condition (t | 06-13-2013 |
20130157806 | CONTROL DEVICE FOR HYBRID VEHICLE DRIVE SYSTEM - A control device for hybrid vehicle drive system includes an engine rotation speed control device performing a rotation speed control of an engine so that a rotation speed of an output shaft of the engine is assumed to be equal to a next gear shift stage input shaft rotation speed when an operation amount of an accelerator pedal increases from an operation amount smaller than a first predetermined amount to an operation amount greater than a second predetermined amount, at which gear stages are switched from a current gear shift stage to a next gear shift stage whose gear ratio is greater than the current gear shift stage, within a priority determining time, a front clutch engagement commanding device, a front clutch engaging device, a release side frictional engagement element releasing device, a motor generator rotation speed control device, and an engagement side frictional engagement element engaging device. | 06-20-2013 |
20130157807 | VEHICLE DRIVING SYSTEM CONTROL APPARATUS - A vehicle driving system control apparatus includes a power transmission device and a power transmission control section. The power transmission device includes an engine input shaft, a motor input shaft, an output shaft, an engine-side gear mechanism transmitting a power of the engine input shaft to the output shaft, a motor-side gear mechanism transmitting a power of the motor input shaft to the output shaft, a first clutch enables and disables a power transmission between the engine input shaft and the motor input shaft, a second clutch enables and disables a power transmission between the motor-side gear mechanism and the output shaft, and a third clutch enables and disables a power transmission between the engine-side gear mechanism and the output shaft. The power transmission control section determines statuses of the clutches and required torques of motor generators in correspondence with a rotation speed of an axle. | 06-20-2013 |
20130165294 | HYBRID MODULE AND TORQUE TRANSFER DEVICE - The present invention relates to a hybrid module with fastening means for fastening, for example, detachable fastening, of the hybrid module with a torque transfer device, such as a torque converter or a clutch, such as a dual clutch, where the hybrid module includes a drive shaft that can be connected to an internal combustion engine and can rotate around a rotary axis and an electric motor with a stator, a rotor, and a power take-off component that can be connected to the rotor and where the torque transfer device has a transfer component for connecting to the hybrid module, where the fastening means axially secure the power take-off component with respect to the transfer component and can produce the connection between fastening means and transfer component. | 06-27-2013 |
20130172146 | POWERTRAIN WITH DOUBLE EPICYCLIC GEAR TRAIN FOR A HYBRID TYPE MOTOR VEHICLE. - The present invention is a powertrain for a hybrid type motor vehicle comprising an electric machine ( | 07-04-2013 |
20130178330 | HYBRID VEHICLE AND CONTROL FOR A CLUTCH ENGAGING EVENT - A method for controlling a downstream clutch in a vehicle during an upstream torque disturbance includes slipping a downstream clutch by reducing the downstream clutch pressure, varying the downstream clutch pressure to a target threshold to control the slip of the downstream clutch, increasing the downstream clutch pressure to engage the downstream clutch. A vehicle includes a first prime mover, a second prime mover connected to the first prime mover using an upstream clutch, a transmission connected to the second prime mover using a downstream clutch, and a controller connected to the first and second prime movers and the upstream and downstream clutches. The controller is configured to (i) slip the downstream clutch by reducing the pressure, (ii) vary the downstream clutch pressure to a target threshold to control the slip, and (iii) increase the downstream clutch pressure to engage the clutch. | 07-11-2013 |
20130190133 | POWER TRANSMISSION CONTROL DEVICE FOR VEHICLE - This power transmission control device is applied to a hybrid vehicle, includes a manual transmission, a friction clutch, and a speed-reduction-ratio changeover mechanism. The speed-reduction-ratio changeover mechanism can change the speed reduction ratio of a second shaft connected to an output shaft of the manual transmission in relation to a first shaft connected to an output shaft of the vehicle motor. The speed reduction ratio of drive wheels to the output shaft of the vehicle motor is changed by changing the speed reduction ratio of the second shaft in relation to the first shaft. The operation for changing the speed reduction ratio is performed while a driver is operating a clutch pedal. Namely, while the driver is performing some operation, he or she receives a shock generated as a result of speed-reduction-ratio change operation. Accordingly, the driver becomes less likely to sense such a shock. | 07-25-2013 |
20130196817 | VEHICLE DRIVE DEVICE - A vehicle drive device comprising: an engine; a hydraulic transmission device constituting a portion of a power transmission path between the engine and drive wheels; and an electric motor, the engine and the hydraulic transmission device disposed to rotate around one axial center, the electric motor disposed with a rotation axial center different from the one axial center, the electric motor coupled to an input-side rotating element of the hydraulic transmission device receiving input of a drive force from the engine, the input-side rotating element being rotatable around the one axial center, the electric motor coupled to the input-side rotating element via an electric motor coupling rotating element coupled relatively non-rotatably to the input-side rotating element, a hydraulic pump rotationally driven by the input-side rotating element of the hydraulic transmission device disposed such that a rotor of the hydraulic pump rotates around the one axial center, and a coupling portion of the electric motor coupling rotating element for the input-side rotating element inserted into a pump-cover through-hole formed on an internal side of the pump-cover through-hole of the hydraulic pump in a radial direction, along with a portion of the input-side rotating element, and coupled relatively non-rotatably to the input-side rotating element in the pump-cover through-hole, in order to couple the input-side rotating element to the rotor. | 08-01-2013 |
20130217537 | DRIVE TRAIN WITH AN AUTOMATED AUXILIARY-RANGE TRANSMISSION - A drive train of a motor vehicle, with a hybrid drive having an internal combustion engine, and an electric machine, and an automated auxiliary range transmission, wherein the automated auxiliary range transmission has at least one main transmission and an auxiliary range unit mounted downstream of the main transmission, in particular as a range group, wherein an input shaft of the automated auxiliary range transmission is connected to the internal combustion engine of the hybrid drive via a controllable starter clutch, and an axle shaft of the automated auxiliary range transmission is connected to an axle drive, wherein the electric machine of the hybrid drive can be coupled to the force flux or torque flux of the drive train between the main transmission and the auxiliary range unites and/or between the auxiliary range unites and the axle drive. | 08-22-2013 |
20130217538 | CONTROL OF POWERSPLIT TRANSMISSION FOR AN ELECTRIC VEHICLE - A method for controlling a powersplit transmission includes connecting an engine to the transmission, provided an engine torque request is present; connecting a motor to the transmission, provided an engine torque request is absent and the engine is on; and disconnecting the engine and motor from the transmission, provided the engine is off, and using a traction motor to produce wheel torque. | 08-22-2013 |
20130252783 | POWERTRAIN SYSTEM FOR HYBRID VEHICLES HAVING COMPOUND AND SPLIT MODES OF OPERATION - A powertrain system for a vehicle is provided, including an internal combustion engine, a drivetrain gear for connection to a drivetrain of the vehicle, a gearset connecting the internal combustion engine to the drivetrain gear, a first electric machine connected to the gearset, a second electric machine, and at least one dynamic clutch selectively coupling the second electric machine to the drivetrain gear and the gearset. In a compound mode of operation, the at least one dynamic clutch couples the second electric machine and the gearset. In a split mode of operation, the at least one dynamic clutch couples the second electric machine and the drivetrain gear. | 09-26-2013 |
20130260957 | CONTROL DEVICE FOR HYBRID VEHICLE AUTOMATIC TRANSMISSION - A control device for a hybrid vehicle automatic transmission. A friction engagement element control unit includes a first play elimination control unit that sets a first pressure as the pressure for a first set time where the predetermined friction engagement element is engaged using a hydraulic pressure from the electric oil pump in a travel state in which only the rotary electric machine serves as a drive source. The first play elimination pressure is lower than a play elimination pressure for use in the case where the predetermined friction engagement element is engaged using a hydraulic pressure from the mechanical oil pump in a travel state in which the internal combustion engine serves as a drive source. | 10-03-2013 |
20130260958 | CLUTCH TYPE DRIVING MECHANISM FOR HYBRID POWERED VEHICLE - A clutch type driving mechanism used in a hybrid powered vehicle is disclosed to include a motor, a speed reducing mechanism, a hollow shaft, an output shaft and first and second one-way clutches. The motor provides a rotational kinetic energy through the hollow axle to the speed reducing mechanism. The speed reducing mechanism and the output shaft transfer a unidirectional rotary motion to the hollow shaft through the first one-way clutch and the second one-way clutch respectively. Thus, when the output shaft works as a drive shaft, it does not transfer the rotary motion to the speed reducing mechanism, avoiding power loss and allowing transfer of the rotational kinetic energy rapidly and efficiently without bearing much load. | 10-03-2013 |
20130267378 | DRIVE DEVICE FOR HYBRID ELECTRIC VEHICLE - A drive device includes an engine, a first motor/generator, and a first planetary gear set group having at least four rotatable members and disposed between the input shaft and the output shaft. Four vertical axes corresponding to the first to fourth rotatable members are arranged in order at intervals corresponding to gear ratios of the group in a common velocity-axis diagram to correspond to a first member to a fourth member, respectively. The first member is connectable with the input shaft. The second member is connectable with the output shaft. The third member is fixable to a stationary part. The fourth member is connected with the first motor/generator. The input shaft is connectable with the engine. | 10-10-2013 |
20130274062 | CONTROL DEVICE FOR DUAL CLUTCH TRANSMISSION AND CONTROL METHOD FOR DUAL CLUTCH TRANSMISSION - A control device for a dual clutch transmission includes a transmission control unit that determines immobility in an engaging-side clutch in a next stage side sticking and, when the engaging-side clutch in the next stage malfunctions and when a gear in a previous stage is out of engagement, engages the gear in the previous stage and thereafter controls a clutch torque capacity in the previous stage to a predetermined value, and a back torque limiter operates according to a predetermined condition to engage a release-side clutch in the previous stage. | 10-17-2013 |
20130281258 | HYBRID MODULE FOR A DRIVE TRAIN OF A VEHICLE - A hybrid module for a drive train of a vehicle having an internal combustion engine and a transmission. The hybrid module operates between the internal combustion engine and the transmission and has an electric drive, a clutch, and a freewheel, and the clutch and the freewheel are provided parallel to each other in order to transmit torque from the internal combustion engine toward the transmission, the freewheel transmits torque coming from the internal combustion engine to the transmission and opens for torque directed in the opposite direction, and a portion of the torque produced by the internal combustion transmitted by the freewheel can be set by setting a torque that can be transmitted by the clutch so that the vehicle can be driven by the internal combustion engine or the electric drive or both at the same time. | 10-24-2013 |
20130281259 | CONTROLLED GEROTOR ACTUATED PRE-TRANS PARALLEL HYBRID - A pre-transmission unit for a hybrid drive system includes an input shaft adapted to be driven by an internal combustion engine. An electric motor includes a rotor fixed for rotation with an output shaft, and a stator fixed to a housing. A multi-plate clutch is positioned in the housing to drivingly interconnect the input shaft and the rotor. The clutch includes a piston for applying an input force to the clutch plates. A pump is positioned in the housing and includes an input member fixed for rotation with the rotor. The pump provides pressurized fluid to the piston. A valve regulates the fluid pressure applied to the piston and varies the torque transferred by the clutch. | 10-24-2013 |
20130288850 | HYBRID DRIVE OF A MOTOR VEHICLE AND METHOD FOR CONTROLLING SAME - The invention relates to a hybrid drive of a motor vehicle which comprises an internal combustion engine (VM) with a drive shaft ( | 10-31-2013 |
20130288851 | POWER TRANSMISSION SYSTEM FOR USE IN VEHICLE - The power transmission system for use in a vehicle includes a power split device to perform power distribution among a flywheel for storing rotational energy as mechanical energy, an internal combustion engine and an electric rotating machine. The power transmission system is provided with an interrupting device configured to interrupt power transmission between a group of the flywheel and the electric rotating machine and a group of the internal combustion engine and drive wheels of the vehicle when rotational energy stored in the flywheel is transmitted to the electric rotating machine through the power split device under condition that power is transmitted between the internal combustion engine and the drive wheels. | 10-31-2013 |
20130288852 | METHOD FOR OPERATION OF A DRIVE TRAIN - A method of operating a drive train of a motor vehicle in which the drive train comprises at least a hybrid drive with an internal combustion engine and an electric motor, a clutch connected between the combustion engine and the electric motor, a transmission arranged between the hybrid drive and a drive output, and preferably a transmission-internal or -external starting element. When the combustion engine is entrained into motion with the help of the electric motor, the clutch connected between the internal combustion engine and the electric motor is partially engaged to a slipping condition where the clutch transmits a constant torque, and during this entrainment, and comparing an actual gradient of the combustion engine's speed produced with a nominal gradient of the combustion engine's speed. When the actual gradient is greater than the nominal gradient, the method concludes that the combustion engine is started and actively providing torque. | 10-31-2013 |
20130288853 | CONTROL DEVICE OF HYBRID VEHICLE (AS AMENDED) - It is provided a control device of a hybrid vehicle having a clutch in a power transmission path between an engine and a motor generator, the clutch controlling power transmission through the power transmission path depending on an engagement state, the hybrid vehicle interrupting the power transmission through the power transmission path by releasing the clutch during EV running while only the motor generator is used as a drive source for running, during the EV running while a release instruction for the clutch is output, if the engine being driven, a rotation speed of the engine is maintained within a predetermined rotation speed difference from a rotation speed of the motor generator. | 10-31-2013 |
20130288854 | DRIVING DEVICE FOR HYBRID VEHICLE - A driving device for hybrid vehicle, having an engine, a first motor capable of generating electric power by driving force of the engine, a second motor capable of supplying driving force to drive wheels, a first driving force transmission path for transmitting driving force of the engine to the drive wheels, a second driving force transmission path for transmitting driving force between the first motor and the engine, and a third driving force transmission path for transmitting driving force of the second motor to the drive wheels, includes a second damper capable of absorbing torque fluctuations in the second driving force transmission path and a third damper capable of absorbing torque fluctuations in the third driving force transmission path, in addition to a first damper capable of absorbing torque fluctuations in the first driving force transmission path. | 10-31-2013 |
20130296103 | Adjusting Motor Torque to Enable Slip of Torque Converter Clutch to be Maintained when Accelerator Pedal Released in Hybrid Vehicle - A controller and a control strategy for a hybrid electric vehicle having a traction motor between an engine and an automatic transmission include maintaining a bypass clutch of a torque converter in an engaged position and applying a motor torque from a traction motor to the torque converter such that slip of the torque converter does not otherwise reach zero while the bypass clutch is maintained in the engaged position. | 11-07-2013 |
20130296104 | BIASED SPEED CONTROL FOR AN ELECTRIC MACHINE IN A HYBRID VEHICLE - A vehicle is provided with an engine, an electric machine connected to the engine by an upstream clutch, a transmission gearbox connected to the electric machine by a downstream clutch, and a controller. The controller is configured to: (i) slip a downstream clutch, (ii) limit a torque output of an electric machine to a threshold value, (iii) engage an upstream clutch while the downstream clutch is slipping, and (iii) engage the downstream clutch. A method for controlling an electric machine in a vehicle during an upstream torque disturbance is provided. The downstream clutch is slipped and the torque output of an electric machine is limited to a threshold value. The upstream clutch is engaged while the downstream clutch is slipping. The downstream clutch is engaged. | 11-07-2013 |
20130296105 | Adjusting Motor Torque to Compensate for Uphill and Downhill Demands During Cruise Control in Hybrid Vehicle - A system and method for controlling a hybrid vehicle having an engine, a battery powered traction motor, and an automatic step-ratio transmission selectively coupled in series by a clutch include engaging the clutch to couple the engine and the motor and controlling motor torque to provide braking torque through the transmission to substantially maintain a cruise control speed. In one embodiment, a hybrid electric vehicle includes a battery powered traction motor connected to a transmission, an engine selectively coupled in series with the motor by a clutch, and a controller communicating with the traction motor and the engine and configured to control the motor to provide braking torque when the clutch is engaged and engine braking torque is insufficient to maintain cruise control speed of the vehicle as the vehicle travels downhill. | 11-07-2013 |
20130296106 | METHOD AND SYSTEM FOR CONTROLLING DRIVELINE LASH IN A HYBRID VEHICLE - A vehicle has an engine, an upstream clutch, an electric machine, a downstream clutch, a transmission gearbox, and a controller. The controller is configured to: (i) control engagement of the downstream clutch, (ii) monitor a vehicle torque, and (iii) control electric machine torque to a designated rate when the vehicle torque changes direction and the electric machine is operating. A method for controlling a hybrid vehicle includes engaging a clutch downstream of the electric machine, monitoring a vehicle torque, and controlling electric machine torque to a designated rate when vehicle torque changes direction and the electric machine is operating. A hybrid vehicle system has an electric machine and a controller configured to (i) control electric machine torque to a designated rate within a time zone, and (ii) control at least one of the electric machine torque and an engine torque to meet driver demand outside of the zone. | 11-07-2013 |
20130296107 | METHOD AND APPARATUS FOR STARTING A TURBOCHARGED ENGINE IN A HYBRID VEHICLE - A vehicle with a modular hybrid transmission that has a combustion engine including a turbocharger and an e-machine use barometric pressure, road grade, and estimated vehicle mass to develop a turbo lag estimate. If it is determined that undesirable turbo lag is likely, the system opens a disconnect clutch between the engine and the e-machine and the engine is started independently of the e-machine. The e-machine is then used to launch the vehicle while the engine is started. | 11-07-2013 |
20130296108 | Modular Hybrid Transmission with a One Way Clutch - A vehicle transmission system having a combustion engine, an electric motor and a transmission includes a first clutch operatively connected between the engine and the motor and a one way clutch. The one way clutch is connected in parallel with the first clutch that permits the engine to increase speed with the clutch disengaged until the engine speed matches the motor speed. The engine provides positive torque through the one way clutch to the motor and transmission upon matching the motor speed. The first clutch and the one way clutch may be a hybrid rocker one way clutch. | 11-07-2013 |
20130296109 | Method and Apparatus for Starting an Engine of a Modular Hybrid Transmission Based Upon Demanded Torque - A control system including a method and apparatus for operating a hybrid vehicle. A disconnect clutch selectively separates an electric machine from a combustion engine. If a wide open throttle or high torque command is requested and the combustion engine is shut down, a 12 volt starter may be used to start the combustion engine while disconnected from the electric machine and all of the electric machine torque available may be used for traction. | 11-07-2013 |
20130296110 | Modulating Engine Torque to Synchronization Engine Speed with Motor Speed for Disconnect Clutch Engagement in Hybrid Vehicle - A system and method for controlling a hybrid vehicle having an engine, a traction motor, and a transmission selectively coupled in series by a clutch include modulating engine torque while the clutch is disengaged and while engine speed is less than motor speed to increase the engine speed. The clutch is engaged to connect the engine to the motor in response to the engine speed exceeding the motor speed. | 11-07-2013 |
20130296111 | ENGINE RESTART TORQUE SPIKE MANAGEMENT SYSTEM FOR A HYBRID VEHICLE - A method for controlling a hybrid vehicle having a traction motor between an engine and a step ratio automatic transmission during a startup of the hybrid vehicle. The method includes performing at least one of adjusting a clutch or an oil pressure to change a transmission tie-up force or downshifting the transmission in response to an actuation rate of a vehicle driver demand. | 11-07-2013 |
20130296112 | CONTROLLING POWERTRAIN COMPONENTS FOR HILL-HOLDING IN A HYBRID ELECTRIC VEHICLE - A hybrid electric vehicle includes an engine and a traction motor coupled to the engine by a coupling device or a clutch for providing torque to wheels of the vehicle. An inverter is electrically connected to the traction motor. A second coupling device or at least one clutch at least indirectly selectively couples the motor to the drive wheels. A controller controls the second coupling device based upon a temperature of at least one of the fraction motor and the inverter. | 11-07-2013 |
20130296113 | CONTROLLING A TRACTION MOTOR DURING ENGINE PULL-UP IN A VEHICLE - A vehicle includes an engine and a fraction motor. A clutch is configured to selectively mechanically couple the engine to the traction motor. A controller or controllers are provided that are configured to command a change in magnitude of an electric current supplied to the electric machine. The command is made in response to initiation of the clutch engaging the traction motor to the engine. The change in magnitude of the electric current ensures the speed of the traction motor remains generally constant during clutch engagement while a speed of the engine is less than that of the traction motor. | 11-07-2013 |
20130296114 | VEHICLE AND METHOD FOR CONTROLLING POWERTRAIN COMPONENTS OF A VEHICLE - A vehicle includes an engine, a traction motor, and a torque converter that is driven by the traction motor. A clutch arrangement mechanically couples an output of the torque converter to transmission gearing. A controller is provided in the vehicle that is configured to command an increase in slip, or decrease in clutch pressure, in the clutch arrangement in response to an increase in speed of the traction motor. The commanding of an increase in slip enables a product of the torque ratio of the torque converter and an input torque to the torque converter to remain generally constant during the increase in speed of the traction motor. | 11-07-2013 |
20130296115 | System and Method for Controlling a Driveline in a Hybrid Vehicle - A system and a method for controlling a hybrid vehicle powertrain during a change from a two-wheel drive mode to a four-wheel drive mode is provided. In response to a request to couple the second pair of wheels to the powertrain, a driveline controller commands an increased torque from the electric motor to be applied to the first pair of wheels The increased torque from the electric motor is based on an AWD engagement torque of the second pair of wheels to counteract an engagement torque of a second pair of drive wheels before changing from the two-wheel drive mode to the four-wheel drive mode. | 11-07-2013 |
20130296116 | Hybrid Torque Converter Control During Rolling Engine Start For Driveline Damping - A system and method for controlling a hybrid vehicle including a transmission having a torque converter with a bypass clutch include controlling the slip between the impeller and the turbine of the torque converter in slip mode operation to regulate the converter torque ratio and maintain substantially constant torque at the turbine. Controlled slip uses the hydrodynamic coupling of the torque converter to balance the desired and delivered torque while damping torque disturbances transmitted through the driveline to manage noise, vibration and harshness (NVH). | 11-07-2013 |
20130296117 | SYSTEM AND APPARATUS FOR ENGINE FLARE CONTROL DURING TRANSMISSION GEAR SHIFT - A vehicle includes an engine, an electric machine, a transmission, and at least one controller. The at least one controller, in response to a gear shift of the transmission that causes a speed of the engine to exceed a predetermined speed, commands a change in current to the electric machine such that the speed of the engine decreases to a target speed to avoid engine flare. | 11-07-2013 |
20130296118 | METHODS AND SYSTEMS FOR A VEHICLE DRIVELINE - Systems and methods for improving operation of a hybrid vehicle are presented. In one example, driveline operating modes may be manually selected to improve hybrid driveline operation during off road conditions. The approaches may improve vehicle drivability and reduce driveline degradation. | 11-07-2013 |
20130296119 | METHODS AND SYSTEMS FOR CONDITIONALLY ENTERING A DRIVELINE SAILING MODE - Systems and methods for improving operation of a hybrid vehicle are presented. In one example, a driveline may selectively enter a sailing mode to provide quick driveline torque response with reduced impact on fuel economy. | 11-07-2013 |
20130296120 | METHODS AND SYSTEMS FOR DRIVELINE SAILING MODE ENTRY - Systems and methods for improving operation of a hybrid vehicle are presented. In one example, entry conditions for entering a driveline sailing mode are described. Driveline sailing mode may improve driveline torque response and vehicle drivability. | 11-07-2013 |
20130296121 | METHODS AND SYSTEMS FOR ENGINE STOPPING - Systems and methods for improving operation of a hybrid vehicle are presented. In one example, an engine is stopped to a desired position via slipping a driveline disconnect clutch so that engine starting may be improved. | 11-07-2013 |
20130296122 | METHODS AND SYSTEMS FOR OPERATING A VEHICLE DRIVELINE RESPONSIVE TO EXTERNAL CONDITIONS - Systems and methods for improving operation of a hybrid vehicle are presented. In one example, external data are a basis for operating a driveline disconnect clutch. For example, a vehicle destination may be a basis for opening a driveline disconnect clutch and beginning to discharging an energy storage device so that fewer hydrocarbons may be consumed by the vehicle. | 11-07-2013 |
20130296123 | METHODS AND SYSTEMS FOR ADAPTING A DRIVELINE DISCONNECT CLUTCH TRANSFER FUNCTION - Systems and methods for improving operation of a hybrid vehicle are presented. In one example, a transfer function of a driveline disconnect clutch is adapted. | 11-07-2013 |
20130296124 | METHODS AND SYSTEMS FOR A DRIVELINE DUAL MASS FLYWHEEL - Systems and methods for improving operation of a hybrid vehicle are presented. In one example, compensation is provided for a dual mass flywheel positioned in a vehicle driveline. The approaches may reduce driveline torque disturbances. | 11-07-2013 |
20130296125 | METHODS AND SYSTEMS FOR OPERATING A DRIVELINE CLUTCH - Systems and methods for improving operation of a hybrid vehicle are presented. In one example, operation of a driveline disconnect clutch is adjusted to compensate for clutch wear and manufacturing tolerances. | 11-07-2013 |
20130296126 | METHODS AND SYSTEMS FOR ENGINE CRANKING - Systems and methods for improving operation of a hybrid vehicle are presented. In one example, an engine may be started in one of two ways depending on operating conditions. In particular, the engine may be started via a lower power output electric machine or a higher power output electric machine. | 11-07-2013 |
20130296127 | TORQUE HOLE FILLING IN A HYBRID VEHICLE DURING AUTOMATIC TRANSMISSION SHIFTING - A system and method for reducing torque disturbances during a shift event for a hybrid vehicle having an engine selectively coupled to a traction motor and an automatic transmission to control or compensate actual transmission input shaft torque based on measured transmission input torque by controlling a torque source, such as a traction motor. The system and method may include an engine, a transmission, a traction motor between the engine and the transmission with the engine being selectively coupled to the motor and the transmission by a disconnect clutch and a controller configured to control motor torque to cause an actual transmission input shaft torque to achieve a target transmission input shaft torque during a transmission shift event. | 11-07-2013 |
20130296128 | METHOD AND SYSTEM TO MANAGE DRIVELINE OSCILLATIONS WITH CLUTCH PRESSURE CONTROL - A system and method for controlling a vehicle having an electric traction motor coupled to a transmission by a clutch include modifying torque transmitted to the driveline by modifying the clutch apply pressure in response to a difference between rotational speed of a driveline component and a filtered rotational speed of the driveline component to reduce driveline oscillation when the clutch is unlocked. The clutch pressure may be modified in response to a vehicle event that may otherwise induce driveline oscillations, such as a transmission ratio change or regenerative braking, for example. | 11-07-2013 |
20130310216 | VEHICLE DRIVE DEVICE - Mutual interference between a hydraulic pressure of a first engagement device and a hydraulic pressure of a second engagement device is suppressed even in the case where operation of the first engagement device and operation of the second engagement device coincide with each other. A vehicle drive device includes a first engagement device that selectively couples a rotary electric machine to an internal combustion engine, and a fluid coupling. The first engagement device includes a first oil chamber that is formed to apply a back pressure to a first piston. The fluid coupling includes a second oil chamber configured to control an engagement state of a second engagement device. The vehicle drive device includes a first control valve that controls a first oil chamber hydraulic pressure, and a second control valve that controls a second oil chamber hydraulic pressure independently of the first oil chamber hydraulic pressure. | 11-21-2013 |
20130310217 | HYBRID VEHICLE CLUTCH CONTROL DEVICE - The clutch control device for a hybrid vehicle comprises an engine, an automated manual transmission, a clutch device and a clutch actuator concluding an output rod and a master cylinder which generates a hydraulic pressure therein by closing an idle port in response to the stroke of the output rod, a slave cylinder in fluid communication with the master cylinder through a passage and controlling the clutch device to be in engagement state or disengagement state operated by the hydraulic pressure generated by the master cylinder and a clutch engagement state holding control portion for temporarily holding the clutch device to be in the engagement state by operating the master cylinder to close the idle port after the engagement state under the vehicle being running under a motor drive mode continued for a predetermined time. | 11-21-2013 |
20130310218 | TORQUE TRANSMISSION DEVICE - It is an object of the present invention to provide a compact torque transmission device. The torque transmission device includes an input-side member, an output-side member, a clutch and a pressing mechanism. The clutch is configured to transmit or cut torque between the input-side member and the output-side member. The pressing mechanism includes a pressing member for pressing the clutch, and a pressing device. The pressing device is a device for pressing the pressing member, and is disposed on the inner peripheral side of the clutch. | 11-21-2013 |
20130324359 | POWER TRANSMISSION APPARATUS FOR FOUR-WHEEL-DRIVE HYBRID VEHICLE - A power transmission apparatus ( | 12-05-2013 |
20130324360 | CONTROL APPARATUS FOR VEHICLE DRIVING SYSTEM - A first slip travel mode is traveling or starting in a state where a first clutch is fully connected and a third clutch is fully disconnected while a second clutch is slipped. A second slip travel mode is traveling or starting in a state where the first clutch is fully connected and the second clutch is fully disconnected while the third clutch is slipped. An overheat avoidance mode is traveling or starting in a state where the first clutch is fully disconnected and the second clutch is fully connected while the third clutch is slipped. When the second clutch is in a high-temperature state under the first slip travel mode or the third clutch is in a high-temperature state under the second slip travel mode, the slip travel mode is switched into the overheat avoidance mode. This reduces a heat value of the second clutch or third clutch. | 12-05-2013 |
20130324361 | DRIVE SYSTEM FOR HYBRID VEHICLE - A drive system for a hybrid vehicle includes an electric motor including a stator and a rotor, an input hub rotatably connected to an engine, an output hub to which the rotor is mounted, a clutch device connecting and disconnecting the input hub to the output hub, a case including a front sidewall portion, a rear sidewall portion and an outer circumferential wall portion connecting an outer circumferential portion of the front sidewall portion to an outer circumferential portion of the rear sidewall portion and housing the electric motor, the input hub, the output hub and the clutch device, a first bearing on which the input hub is journaled, a second bearing on which the output hub is journaled, and a third bearing positioned between the first bearing and the second bearing and relatively rotatably supporting the input hub and the output hub. | 12-05-2013 |
20130324362 | POWER TRANSMITTING APPARATUS FOR VEHICLE - A power transmitting apparatus may include: an electric supplementary drive unit; a torque converting device having first, second, and third rotation elements, wherein the first rotation element is connected to the electric supplementary drive unit, the second rotation element is connected to an engine, and the third rotation element is operated as an output element; a first input shaft directly connected to the second rotation element, and a second input shaft directly connected to the third rotation element; a direct coupling device selectively connecting two rotation elements among the first, second, and third rotation elements, a first speed output unit having first and second synchronizer modules, and a second speed output unit having third and fourth synchronizer modules; and a reverse speed device having an idle gear and engaging to any one input gear on the first and second input shafts. | 12-05-2013 |
20130331228 | CONTROL DEVICE OF HYBRID VEHICLE (AS AMENDED) - It is provided a control device of a hybrid vehicle having an engine, an electric motor, a clutch disposed in a power transmission path between the engine and the electric motor, and a hydraulic power transmission device with a lockup clutch disposed in a power transmission path between the electric motor and drive wheels, the control device being configured to engage the clutch and provide slip control of the lockup clutch when the engine is started from motor running using the electric motor, and to lower an engagement pressure of the lockup clutch as compared to the case of an engine start caused by an acceleration request from a driver if the start of the engine is an engine start caused by a request from a hybrid system. | 12-12-2013 |
20130337972 | POWER TRANSMITTING APPARATUS FOR VEHICLE - A power transmitting apparatus for a vehicle includes: an electric supplementary drive unit; a torque converting device including a planetary gear set having a first rotation element connected to the electric supplementary drive unit, a second rotation element connected to an engine, and a third rotation element operated as an output element; an input device including a first input shaft connected to the third rotation element through one clutch and provided with an input gear thereon, and a second input shaft coaxial with the first input shaft without rotational interference, connected to the second rotation element through the other clutch, and provided with an input gear thereon; a direct coupling device selectively connecting two rotation elements among the first, second, and third rotation elements of the torque converting device so as to cause the torque converting device to become a direct-coupling state; and a speed output device. | 12-19-2013 |
20130337973 | METHOD AND DEVICE FOR OPERATING A DRIVE DEVICE - The invention relates to a method for operating a drive device ( | 12-19-2013 |
20130345018 | HYBRID DRIVE OF A MOTOR VEHICLE - A hybrid drive of a motor vehicle having an automated manual transmission with two coaxial input shafts and a common output shaft. The input shafts are respectively driven by an engine and an electric machine and can couple the output shaft via respective groups of gearwheel sets. Each gearwheel set comprises a gear fixed to the associated input shaft and an idler gear supported by respective countershafts. At least two idler gears disposed on one of the two countershafts of two gearwheel sets, within the transmission, assigned to two different input shafts, can be coupled via a winding-path shift element, and the two output constants are disposed in a common radial plane by using a common output gear disposed on the output shaft. | 12-26-2013 |
20130345019 | HYBRID DRIVE OF A MOTOR VEHICLE AND METHOD FOR CONTROLLING A HYBRID DRIVE - A hybrid drive of a motor vehicle having an automated manual transmission with two input shafts and a common output shaft. The first input shaft can be connected to the drive shaft of an internal combustion engine by a clutch and can be brought into a drive connection to the output shaft by a first group of shiftable gearwheel sets. The second input shaft has a drive connection to the rotor of an electric machine, which can operate as a motor and a generator, and can be brought into a drive connection with the output shaft by a second group of selectively shiftable gearwheel sets. The input shafts can be coupled by coupling-shift element. The hybrid drive is provided with a second electric machine, which can operate as a motor and a generator and has a rotor that can be connected to the first input shaft. | 12-26-2013 |
20140004995 | METHOD FOR USE OF HYDRAULICALLY OR ELECTRICALLY CONTROLLED SOLENOIDS UNDER FAILED ON CONDITIONS | 01-02-2014 |
20140004996 | POWER TRANSMISSION CONTROL APPARATUS FOR VEHICLE | 01-02-2014 |
20140004997 | Active Damping During Clutch Engagement for Engine Start | 01-02-2014 |
20140011631 | AUTOMATIC MANUAL TRANSMISSION FOR A HYBRID CAR PROVIDED WITH AN INTERNAL COMBUSTION ENGINE AND WITH AN ELECTRICAL MACHINE - Examples include an automatic manual transmission for a hybrid car provided with an internal combustion engine and an electrical machine, the automatic manual transmission presents. Examples include a mechanical gearbox, a differential gear which receives the motion from a secondary shaft of the gearbox and transmits the motion to driving wheels, a clutch which is interposed between the secondary shaft of the gearbox and the differential gear, an auxiliary shaft along which the electrical machine is mounted, a first gear train which connects a first end of the auxiliary shaft arranged upstream of the electrical machine to a primary shaft of the gearbox, and a second gear train which connects a second end of the auxiliary shaft arranged downstream of the electrical machine to an output shaft of the clutch. | 01-09-2014 |
20140011632 | POWER TRANSMISSION CONTROL DEVICE FOR VEHICLE - A power transmission control device, which is applied to a hybrid-vehicle provided with an internal combustion engine (E/G) and a motor (M/G) as power sources, includes a manual transmission and a friction clutch, When the shift position is in “neutral”, the friction clutch is in an engaged state, an accelerator opening is “0”, and a battery remaining amount SOC is less than a threshold TH, a charge condition is satisfied. When the charge condition is satisfied, charge of a battery by using an E/G torque is carried out. Specifically, the M/G is driven, by using the VG torque, as an electrical power generator, and electric energy acquired by electric power generation by the M/G is used to charge the battery. As a result, for the HV-MT vehicle, by using the internal-combustion-engine torque, the battery for supplying the electric motor with the electric energy can be efficiently charged. | 01-09-2014 |
20140018206 | MOTOR VEHICLE HAVING AUXILIARY UNITS DRIVEN BY AN ELECTRIC MOTOR - A motor vehicle driven by an internal combustion engine is equipped with at least two auxiliary units and with an electric machine connected to a power source. The electric machine can be coupled to the auxiliary units by means of a dual clutch device. A control device can actuate the dual clutch device for coupling the auxiliary units to the electric machine according to preselected priorities. One or the other auxiliary unit, or all auxiliary units, or no auxiliary unit may be coupled to the electric machine. | 01-16-2014 |
20140018207 | CONTROL DEVICE OF HYBRID VEHICLE - A control device of a hybrid vehicle includes an engine and an electric motor, a clutch, and an automatic transmission. The motor is the only drive power source when the clutch is released. The control device is configured such that when a request for increasing drive torque while the motor is running is made, if start control of the engine and downshift control of the automatic transmission overlap, clutch engagement completion is a starting point to start a rotational change of an input rotation speed of the transmission toward a synchronous rotation speed after a shift, and a transmission torque capacity during the downshift control in the transmission until engagement completion of the clutch being set equal to or greater than an input torque of the transmission during the motor running and less than an input torque of the transmission at the time of engagement completion of the clutch. | 01-16-2014 |
20140038773 | METHOD AND APPARATUS FOR EXECUTING A TRANSMISSION RANGE SHIFT IN A MULTI-MODE POWERTRAIN SYSTEM - A method for controlling a powertrain system including an internal combustion engine coupled to a multi-mode transmission in response to a command to execute a shift from a first EVT Mode range to a second EVT Mode range includes executing a first shift from the first EVT Mode range to an intermediate transmission range. The multi-mode transmission operates in the intermediate transmission range and the engine is controlled at an engine torque command that corresponds to an output torque request. A second shift is executed from the intermediate transmission range to the second transmission range. The powertrain system operates in the second transmission range to transfer torque to an output member of the transmission. | 02-06-2014 |
20140045649 | CONTROL DEVICE - The present invention relates to a control device that controls a vehicle drive device in which a rotary electric machine is provided in a power transfer path that connects between an internal combustion engine and wheels and in which a first friction engagement device is provided between the internal combustion engine and the rotary electric machine and a second friction engagement device is provided between the rotary electric machine and the wheels. | 02-13-2014 |
20140051546 | CONTROL APPARATUS FOR HYBRID VEHICLE - A control apparatus for a hybrid vehicle includes: engine starting means for starting an engine when a need for switching to a 4-wheel drive mode has been forecasted, the hybrid vehicle having a series HV drive mode in which the hybrid vehicle is run with a second electric motor, in the released state of a connecting/disconnecting device, while a first electric motor is operated with a drive force of said engine to generate an electric energy, the control apparatus further including, as said engine starting means, series HV drive controlling means for starting said engine and enlarging a series HV drive mode region for running the hybrid vehicle in said series HV drive mode, so as to cover a portion or an entirety of an original EV drive mode region for running the hybrid vehicle in said EV drive mode, when the need for switching to said 4-wheel drive mode has been forecasted. | 02-20-2014 |
20140051547 | METHOD OF OPERATING A HYBRID POWERTRAIN WITH MANUAL TRANSMISSION AND OFF- LATCHING CLUTCH - A powertrain for a hybrid vehicle includes a clutch interconnecting an internal combustion engine and an electric motor. The electric motor is coupled to a manually operated gearbox operable in at least one electric only drive position and at least one hybrid drive position. A latch is coupled to the clutch and is moveable between a closed position inhibiting the clutch from interconnecting the internal combustion engine and the electric motor when the gearbox is disposed in the electric only drive position, and an open position allowing the clutch to interconnect the internal combustion engine and the electric motor when the gearbox is disposed in the hybrid drive position. | 02-20-2014 |
20140073478 | Method and Apparatus for Controlling Engine Shutdown in Hybrid Vehicles - A hybrid vehicle is provided that includes a control system that controls the time required for engine shut down. An electric machine or integrated starter-generator may be used to apply a load to the combustion engine after an engine shut down signal is received. By reducing the time required to shut down the engine in a controlled manner, the catalytic converter can be conditioned by providing a desired volume of air and fuel to the catalyst to reduce emissions and increase fuel economy. If an indication is received that it is no longer desirable to shut down the engine, the engine may be restarted conventionally or started in a quick start mode by refueling the engine is the engine operating at a sufficient speed for a quick restart. | 03-13-2014 |
20140073479 | METHOD FOR OPERATING A DRIVE TRAIN OF A VEHICLE - A method of operating a drive-train of a vehicle that comprises a combustion engine whose torque for driving the vehicle can be transmitted to a drive output via a transmission, with a hydraulically actuated clutch when the clutch is engaged. An electric machine provides torque which can act upon the drive-train. The clutch is closed by filling the clutch with hydraulic fluid through a circuit by way of a pump which can be driven by the engine and the electric machine. The method is to engage the clutch when the combustion engine is initially off and/or when the electric machine is initially switched off, determining a driving dynamic based on the behavior of the driver and adjusting the speed of the electric machine based on the determined driving dynamic such that the greater the determined driving dynamic is, the more rapidly the clutch is filled by the pump. | 03-13-2014 |
20140073480 | METHOD FOR CONTROLLING A HYBRID DRIVETRAIN - Method for controlling a hybrid drivetrain which has a drive engine and a dual-clutch gearbox which, to establish two power transmission paths, has a first and a second friction clutch and a first and a second component gearbox. An electric machine is connected to the second power transmission path downstream of the second friction clutch in the power flow direction. Purely electric driving operation can be realized by means of the second component gearbox assigned to the second friction clutch. In the event of a gear change in the second component gearbox during purely electric driving operation, a fill-in torque is provided. The fill-in torque is provided from inertial energy of the previously cranked, non-fired drive engine, wherein the drivetrain also has an electric starter motor, and wherein the starter motor is used to crank the drive engine. | 03-13-2014 |
20140080663 | VEHICLE AND CONTROL METHOD - When an engine is started in a motor running mode, a control unit performs engine starting control by raising the engine speed through slip engagement of an engine coupling/decoupling clutch, temporarily reducing engaging force of the engine coupling/decoupling clutch after the engine becomes able to rotate by itself, and then fully engaging the engine coupling/decoupling clutch. The control unit advances the intake valve opening/closing timing at an earlier point in time as the motor speed is higher. | 03-20-2014 |
20140080664 | HYBRID SYSTEM - A hybrid system includes a hybrid module that is located between an engine and a transmission. The hybrid system includes an energy storage system for storing energy from and supplying energy to the hybrid module. An inverter transfers power between the energy storage system and the hybrid module. The hybrid system also includes a cooling system, a DC-DC converter, and a high voltage tap. The hybrid module is designed to recover energy, such as during braking, as well as power the vehicle. The hybrid module includes an electrical machine (eMachine) along with electrical and mechanical pumps for circulating fluid. A clutch provides the sole operative connection between the engine and the eMachine. The hybrid system further incorporates a power take off (PTO) unit that is configured to be powered by the engine and/or the eMachine. | 03-20-2014 |
20140094340 | CONTROL DEVICE AND CONTROL METHOD FOR VEHICLE - A controller of a vehicle control device, at the time of shifting from a motor drive mode to an engine drive mode by starting an engine in the motor drive mode, starts the engine by slipping an engine separating clutch and igniting the engine in a state where a lockup clutch of a fluid transmission device is slipped. The fluid transmission device is interposed between an electric motor and a drive wheel. The engine separating clutch selectively couples the engine to the electric motor. Only the electric motor is a drive source in the motor drive mode. The engine is a drive source in the engine drive mode. The controller, at the time of the shifting, reduces a slip amount of the lockup clutch as a period of time from slip initiation timing of the engine separating clutch to ignition initiation timing of the engine extends. | 04-03-2014 |
20140094341 | HYBRID MODULE FOR A DRIVETRAIN OF A VEHICLE - A hybrid module for a drivetrain of a motor vehicle having a combustion engine and a transmission, wherein the hybrid module operates between the combustion engine and the transmission and has an electric drive, a decoupling clutch and a freewheeling mechanism, and wherein the decoupling clutch and the freewheeling mechanism, parallel to each other, are each provided to transmit torque from the combustion engine in the direction of the transmission, the freewheeling mechanism transmits torque coming from the combustion engine in the direction of the transmission and disengages in the case of torque in the opposite direction. | 04-03-2014 |
20140094342 | CONTROL DEVICE - A control device for a vehicle drive configured with a power transfer path that includes a first engagement device, a rotary electric machine, and a second engagement device. These elements being arranged in this order from an input member coupled to an engine to an output member that is coupled to the wheels of the vehicle. A mode control unit switches among a first, second, third and fourth control modes in which the rotating electrical machine generates electricity with: (i) both the first and second engagement devices, (ii) both the first and second engagement devices, (iii) the first engagement device in the direct engagement state and with the second engagement device, and (iv) with the first engagement device in the slip engagement state and with the second engagement device. | 04-03-2014 |
20140100076 | OUTPUT TORQUE ERROR MITIGATION FOR STRONG HYBRID PRNDL NEUTRAL OPERATION - A powertrain system includes an internal combustion engine, at least one electric machine and an electro-mechanical transmission operative to transmit torque to a driveline. A method for controlling the powertrain system includes enabling neutral operation of the transmission in response to an operator input, activating a first clutch coupled to a first planetary gear set, the first planetary gear set which includes a first element, a second element and a third element. Torque commands are coordinated between the engine and a first electric machine to establish a net zero output torque condition. If a violation of the net zero output torque condition is present, slippage of the first clutch is allowed to dissipate net output torque from reacting with the driveline of the powertrain system. | 04-10-2014 |
20140106927 | METHOD AND SYSTEM FOR IMPROVING VEHICLE LAUNCH - A method and a system for improving operation of a hybrid vehicle are presented. In one example, a clutch is operated while a vehicle is stopped and while a vehicle brake is applied to determine a clutch torque transfer function. The approach may improve vehicle launch after an engine stop. | 04-17-2014 |
20140106928 | METHOD FOR PERFORMING A BOOST OPERATION OF A HYBRID VEHICLE - A method for carrying out a boosting mode of a drive unit ( | 04-17-2014 |
20140106929 | DRIVE SYSTEM AND METHOD FOR CONTROLLING DRIVE SYSTEM - Provided are a drive system and a method for controlling the drive system which reduce a shock to a third shaft at the start of an internal combustion engine during EV driving. The drive system includes an engine, a first shaft connected to a crankshaft, a second shaft, a first clutch, a motor generator, a third shaft, a first transmission, a one-way clutch, and an ECU for controlling a gear ratio of the first transmission and the first clutch. The first transmission includes a rotating ring, a rocking portion, and a rotation radius variation mechanism. If an angular velocity of the rocking portion is higher than or equal to a rotational speed of the third shaft, the one-way clutch transmits a power in only one direction of the rocking portion to the third shaft. | 04-17-2014 |
20140113766 | Hybrid Vehicle - A hybrid vehicle includes an engine, a motor, and a belt stepless speed changer device having a driving rotary body, a driven rotary body, a first shaft member supporting the driving rotary body with allowing rotation thereof in unison, a second shaft member supporting the driven rotary body with allowing rotation thereof in unison, and an endless belt wound around the driving rotary body and the driven rotary body. The vehicle further includes a transmission case configured to receive the powers from the engine and the motor via the belt stepless speed changer device and a centrifugal clutch incorporated in a power transmission line extending form the engine to the first shaft member. The motor is disposed on the side opposite the engine across the driving rotary body, and the driving power of the motor is inputted to the first shaft member. | 04-24-2014 |
20140121057 | HYBRID MODULE FOR ARRANGEMENT IN A DRIVE TRAIN OF A MOTOR VEHICLE - A hybrid module ( | 05-01-2014 |
20140128215 | ENGINE DAMPER BYPASS FOR HYBRID POWERTRAINS - A powertrain includes an engine having a crankshaft, a transmission having an input member, and a damper operatively interconnecting the input member and the crankshaft to transmit torque from the crankshaft to the input member. An electric motor/generator is operatively connected to the transmission input member to selectively transmit torque thereto. A damper bypass system is operatively connected to the crankshaft and the input member. The damper bypass system is configured not to transfer torque from the crankshaft to the input member, but transmits torque from the input member to the crankshaft in response to input member torque exceeding crankshaft torque. | 05-08-2014 |
20140128216 | TORQUE TRANSMITTING DEVICE AND POWERTRAIN INCORPORATING A PERMANENT MAGNET MOTOR | 05-08-2014 |
20140128217 | CONTROL DEVICE FOR VEHICLE DRIVE DEVICE - A control device of a vehicle drive device comprises a hydraulic power transmission device having an input-side rotating element to which power from an engine is input and an output-side rotating element outputting power to drive wheels, a first electric motor directly or indirectly coupled to the input-side rotating element, and a second electric motor directly or indirectly coupled to the drive wheels, the vehicle drive device further comprising an electric path through which power is electrically transmitted by giving/receiving electric power between the first electric motor and the second electric motor and a mechanical path through which power is mechanically transmitted via the hydraulic power transmission device, the control device of the vehicle drive device being configured to control an operating point of the engine by adjusting a torque of the first electric motor, the control device being configured to adjust the torque of the first electric motor such that a sum of an engine torque and the torque of the first electric motor is balanced with an input-side load torque generated in the input-side rotating element depending on a speed ratio of the hydraulic power transmission device when the operating point of the engine is controlled, the control device being configured to calculate the input-side load torque based on engine rotation speed indicated by the target engine operating point and determine the torque of the first electric motor based on the engine torque indicated by the target engine operating point and the input-side load torque, the vehicle drive device further comprising a capacity variable device varying a characteristic of a capacity coefficient of the hydraulic power transmission device relative to a speed ratio of the hydraulic power transmission device that is a hydraulic characteristic of the hydraulic power transmission device for determining the input-side load torque. | 05-08-2014 |
20140128218 | METHOD FOR CONTROLLING A SEPARATING CLUTCH IN A HYBRID DRIVE TRAIN, AND DRIVE TRAIN - A hybrid drivetrain and method for controlling a friction clutch of a hybrid drivetrain of a motor vehicle having a combustion engine which is coupled by means of a freewheel to a transmission input shaft of a transmission to transmit the engine torque, and having an electric machine which starts the combustion engine and/or propels the motor vehicle, which friction clutch transmits to the combustion engine a summed torque formed of a starting torque for starting the combustion engine by means of the electric machine and a drag torque which acts on the combustion engine when the drivetrain is in drag mode. To be able to operate the friction clutch reliably and to avoid over-dimensioning of the friction clutch as a result of high summed torques, a torque present at the friction clutch is limited to a predefined transmission torque which can be transmitted via the friction clutch. | 05-08-2014 |
20140128219 | MODULAR POWERTRAIN COMPONENT FOR HYBRID ELECTRIC VEHICLES - An assembly includes a torque converter including a casing supported for rotation about an axis, a rotor hub secured to the torque converter casing for rotation about the axis, a leg member secured to and supporting the rotor hub for rotation about the axis, and an electric machine including a rotor secured to the rotor hub. | 05-08-2014 |
20140148304 | Adjusting Clutch Slip Based on Sensed Parameter of Transmission Shaft to Control NVH Level in Vehicle Powertrain - A vehicle powertrain includes a transmission and a clutch. The slip of the clutch is adjusted to a target where a magnitude of a sensed parameter of a shaft of the transmission corresponds to a desired noise, vibration, and harshness (NVH) level in the powertrain. The sensed parameter of the transmission shaft may be one of acceleration, speed, and torque of the transmission shaft. The transmission shaft may be one of the input shaft and output shaft of the transmission. | 05-29-2014 |
20140148305 | Method and Apparatus for Limiting Engine Torque to Protect Disconnect Clutch in a Hybrid Vehicle - A powertrain comprising an engine, a motor, a disconnect clutch connected between the engine and the motor, and a transmission. The transmission is connected to the motor by a launch clutch and selectively and indirectly connected to the engine by the disconnect clutch. A controller receives an engine torque output signal and reduces the torque output of the engine to the clutch capacity limit value. A system and a method are also provided for controlling a powertrain for a hybrid vehicle. | 05-29-2014 |
20140148306 | SYSTEM AND METHOD FOR CONTROLLING ENGINE CLUTCH DELIVERY TORQUE OF HYBRID ELECTRIC VEHICLE - A system and method for controlling engine clutch delivery torque of a hybrid electric vehicle when the engine clutch delivery torque is learned includes: an engine clutch configured to control power transmission between an engine and a motor; an integrated starter-generator (ISG) configured to start the engine or to generate electric power by output of the engine; a transmission configured to change power applied to wheels; and a controller configured to control the engine, the motor, the integrated starter-generator, and the engine clutch in a predetermined condition and to check their states under the predetermined condition, wherein while learning the engine clutch delivery torque, the controller operates and controls the integrated starter-generator in order for the engine to maintain an idle speed when the idle speed is varied above a predetermined value. | 05-29-2014 |
20140155221 | METHOD AND APPARATUS FOR CONTROLLING A SHIFT IN A MULTI-MODE POWERTRAIN SYSTEM - A method for operating a powertrain system includes executing a transmission shift between an initial electrically-variable transmission (EVT) range and a target EVT range. The transmission shift includes transitioning to operating with three speed degrees of freedom including controlling speed of a second torque machine to synchronize speed of an oncoming clutch associated with the target EVT range and coincidentally controlling speeds of a first torque machine and an engine to achieve a preferred speed of the output member of the transmission. The transmission shift further includes controlling torque output from the first torque machine in response to an output torque request, and activating the oncoming clutch upon synchronizing the speed of the oncoming clutch. Subsequent to the transmission shift, the powertrain system is operated in the target EVT range. | 06-05-2014 |
20140155222 | SYSTEM AND METHOD FOR LEARNING A TRANSFERRING TORQUE FOR HYBRID VEHICLE - A system and method for learning a transferring torque for a hybrid vehicle includes: an engine and a motor connected through a clutch; a Hybrid Starter Generator (HSG) that is connected to the engine and is used to start the engine; and a controller for transferring a charging power by the motor to the HSG in a case where the charging power by the motor is greater than or equal to a chargeable power of the battery when the transferring torque is learned through the clutch. | 06-05-2014 |
20140162838 | METHOD AND SYSTEM FOR ADJUSTING HYBRID VEHICLE DRIVELINE TORQUE - Methods and systems for improving operation of a hybrid vehicle are presented. In one example, an engine torque estimate may be adapted in response to a torque converter impeller speed error. The methods and systems may reduce the possibility of driveline torque disturbances. | 06-12-2014 |
20140162839 | CONTROL DEVICE OF HYBRID VEHICLE - In a case of engagement when a clutch K | 06-12-2014 |
20140162840 | METHOD AND SYSTEM FOR CONTROLLING ANTI-JERK OF HYBRID ELECTRIC VEHICLE - A method and system for controlling anti-jerk of a hybrid vehicle reduce shift vibration and shock by reverse phase controlling a drive motor during gear-shifting of a hybrid vehicle without a torque converter. The method includes determining whether a gear-shifting command is outputted from a transmission control unit of the hybrid vehicle; when it is determined that the gear-shifting command is outputted, confirming a gear-shifting range divided into at least three phases in accordance with the gear-shifting command; determining whether the corresponding divided gear-shifting range is an anti-jerk allowed gear-shifting range; and when it is determined that the corresponding gear-shifting range is the anti-jerk allowed gear-shifting range, reverse phase controlling a drive motor of the hybrid vehicle by a predetermined value in order to reduce or attenuate vibration and shock generated in the corresponding gear-shifting range. | 06-12-2014 |
20140162841 | CONTROL DEVICE - A control device controls a vehicle drive device in which a first engagement device, a rotary electric machine, a second engagement device, and an output member are arranged on a power transfer path from an internal combustion engine to wheels. The control device executes mode transition control that causes transition from (i) a first control mode in which both the first engagement device and the second engagement device are in a slip engagement state and the rotary electric machine generates electric power to (ii) a second control mode in which the first engagement device is in a direct engagement state, the second engagement device is in the slip engagement state, and the rotary electric machine generates electric power. | 06-12-2014 |
20140171259 | ELECTRIC HYBRID MODULE FOR A DUAL CLUTCH TRANSMISSION - An adapter module for a dual clutch transmission in a drivetrain is provided. The dual clutch transmission has a first input shaft and a second input shaft concentric with the first input shaft, a mainshaft, an output shaft, and a countershaft offset from the first and second input shafts. The countershaft is drivably connected to the first input shaft, the second input shaft, and the mainshaft. An alternative power source including an electric machine is provided for the drivetrain. An adapter module is disposed between the dual clutch transmission and the alternative power source. The adapter module has an adapter gearset connecting the electric machine to the dual clutch transmission and at least one clutch configured to (i) selectively drivingly connect the electric machine to the output shaft, and (ii) selectively drivingly connect the electric machine to the countershaft. | 06-19-2014 |
20140171260 | HYBRID VEHICLE DRIVE SYSTEM AND METHOD FOR FUEL REDUCTION DURING IDLE - A vehicle drive system for a vehicle including a first prime mover, a first prime mover driven transmission, and a rechargeable power source can be configured for reduced fuel consumption at idle. The vehicle drive system includes an electric motor in direct or indirect mechanical communication with the first prime mover, wherein the electric motor can receive power from the first prime mover driven transmission and can receive power from the first prime mover. The vehicle drive system also includes a control system. The control system causes the electric motor to rotate the first prime mover at a speed so that an electronic control module associated with the first prime mover does not cause fuel to be provided to the first prime mover while the vehicle is stopped, thereby reducing fuel consumption at idle for the vehicle | 06-19-2014 |
20140171261 | HYBRID DRIVING APPARATUS - A hybrid driving apparatus includes an engine configured to output a rotation driving force to an output shaft; an input shaft configured to rotate in association with rotation of driving wheels of a vehicle; a clutch that is provided between the output shaft and the input shaft to disengageably connect the output shaft and the input shaft; a clutch actuator configured to operate the clutch; a motor generator configured to rotate in association with rotation of the input shaft; a rust formation determining unit configured to determine whether there is a possibility of a rust formation on the clutch; and a rust formation suppressing unit configured to operate the clutch actuator in a case where the rust formation determining unit determines that there is the possibility of the rust formation on the clutch. | 06-19-2014 |
20140179488 | CONTROL APPARATUS AND CONTROL METHOD FOR HYBRID VEHICLE - Controlling a hybrid vehicle includes: reducing a rotation speed of a motor generator before a locking apparatus that locks the motor generator is switched from a disengaged condition to an engaged condition; starting to switch the locking apparatus to the engaged condition when the rotation speed decreases to a predetermined operation permission rotation speed; controlling the locking apparatus such that from the start of the switch to the engaged condition onward, the rotation speed decreases from the operation permission rotation speed to an engagement rotation speed with the motor generator in the engaged condition; and controlling the locking apparatus such that a decrease rate of the rotation speed when switching from the disengaged condition to the engaged condition in a low torque operation mode is higher than the decrease rate of the rotation speed when switching from the disengaged condition to the engaged condition in a high torque operation mode. | 06-26-2014 |
20140194246 | CONTROL DEVICE FOR HYBRID VEHICLE - In a series mode, a clutch rotational speed difference ΔN is calculated, and when the clutch rotational speed difference ΔN is within a first predetermined range R1, it is determined whether a sticking determination timer t indicates a first predetermined time t1 or longer. When a closed sticking timer t indicates the first predetermined time t1 or longer, fuel cut is performed, and the clutch rotational speed difference ΔN is re-calculated. When the closed sticking timer t indicates a second predetermined time t2 or longer, and the clutch rotational speed difference ΔN is within a second predetermined range R2, it is determined that there is closed sticking of a clutch. When the closed sticking timer t indicates less than the time t2, and the clutch rotational speed difference ΔN is out of the second predetermined range R2, it is determined that there is no closed sticking of the clutch. | 07-10-2014 |
20140206501 | POWER TRANSMISSION CONTROL DEVICE FOR VEHICLE - A power transmission control device is used for a hybrid vehicle including an internal combustion engine and a motor (MG) as power sources, and includes a manual transmission and a friction clutch. A torque of the motor (MG torque) is generally adjusted to the smaller one (=MG torque final reference value) of an MG torque reference value determined based on an accelerator opening and an MG torque limit value determined based on a clutch return stroke. Based on satisfaction of a predetermined condition relating to a clutch pedal operation performed by a driver, the MG torque is intentionally adjusted to a value shifted from the MG torque final reference value in place of the MG torque final reference value. As a result, a driving force which is more appropriate or better meets a driver's intention can be obtained. | 07-24-2014 |
20140213410 | VEHICLE PARKING APPARATUS AND METHOD FOR PARKING VEHICLE - A vehicle parking apparatus includes an engine, an electric motor, a transmission apparatus, a parking detection member, and a control unit. The transmission apparatus includes a first gear train configured to connect between the engine and a driving wheel, a second gear train configured to connect between the electric motor and the driving wheel, and a first switching mechanism selectively connecting and disconnecting between a predetermined first rotation element in the first gear train and a predetermined second rotation element in the second gear train. The control unit connects between the engine and the driving wheel by the first gear train, disconnects between the electric motor and the driving wheel by the second gear train, and disconnects the second gear train from the first gear train by the first switching mechanism in a case where the parking detection member detects the parked state of the vehicle. | 07-31-2014 |
20140221151 | BICYCLE DRIVE UNIT - A bicycle drive unit includes a motor, a crank axle, a torque combining mechanism, and a clutch mechanism. The crank axle is rotatable about a first rotational axis. The torque combining mechanism is operatively coupled to the motor and the crank axle. The torque combining mechanism has a sprocket mounting portion that is configured to be operatively attached to a sprocket such that the sprocket rotates about a second rotational axis of the sprocket in a first direction as the crank axle rotates about the first rotational axis in the first direction. The clutch mechanism is operatively disposed between the crank axle and the sprocket. The clutch mechanism is configured to rotate the sprocket about the second rotational axis in a second direction as the crank axle rotates about the first rotational axis in the second direction. The second direction is opposite the first direction. | 08-07-2014 |
20140221152 | CONTROL APPARATUS FOR HYBRID VEHICLE - Embodiments of control apparatus for hybrid vehicles are described which reduce the heat generated by a clutch and improve the response of the hybrid vehicle when an operator requests a high degree of acceleration while starting the engine and the transmission is required to perform a shift-down. In one embodiment, when the engine is required to start while the transmission is required to perform a shift-down action, the control apparatus holds a hydraulic pressure of a releasing side clutch of the transmission at a predetermined lowest stand-by value preventing a slipping action of the releasing side clutch, while a clutch K | 08-07-2014 |
20140221153 | DUAL MODE ELECTROMECHANICAL VARIABLE SPEED TRANSMISSION APPARATUS AND METHOD OF CONTROL - A dual-mode electro-mechanical variable speed transmission includes an input shaft, an output shaft system, a gear system having at least three branches, two electric machines, and at least a clutch. The first electric machine couples to a branch of the gear system, the output shaft system couples to another branch of the gear system, the input shaft couples to the remaining branch or one of the remaining branches of the gear system, and the second electric machine selectively couples either to the same branch that is coupled to the output shaft system with a speed ratio or to one of the remaining branches that that is not coupled to the first electric machine with a different speed ratio. The transmission provides at least two power splitting modes to cover different speed ratio regimes. The transmission can also provide at least a fixed output shaft to input shaft speed ratio. | 08-07-2014 |
20140243149 | HYBRID VEHICLE WITH POWER-SPLIT AND PARALLEL HYBRID TRANSMISSION AND METHOD OF CONTROLLING SAME - A hybrid vehicle has a powertrain that includes a transmission with a planetary gear set that has a first, a second, and a third member. An engine is connected for unitary rotation with the first member. A first final drive is operatively connectable with the carrier member and connected with the first axle. A first motor-generator is connected for unitary rotation with the third member. A second motor-generator is operatively connected for proportional rotation with one of the axles. A first clutch is selectively engageable to connect any two of the members for unitary rotation with one another. The planetary gear set provides an underdrive ratio of speed of the second member to speed of the engine when the sun gear member is stationary. | 08-28-2014 |
20140248992 | ENGINE ACCESSORY DRIVE SYSTEM - An electrified engine accessory drive (EEAD) system is provided that replaces the front engine accessory drive (FEAD) components (e.g., a/c compressor, air brake compressor; power steering pump, etc.) on vehicles, such as heavy duty trucks. Using such an EEAD system aims to reduce parasitic losses induced on a conventional engine by the front engine accessory drive (FEAD) while providing additional benefits, such as engine off vehicle and/or system operation. The EEAD systems may also be used in lieu of rear-end accessory drives and other accessory drives powering multiple accessories from a common driveshaft. | 09-04-2014 |
20140248993 | HYBRID VEHICLE - A hybrid vehicle includes a combustion engine ( | 09-04-2014 |
20140256506 | VEHICLE POWER TRANSMISSION DEVICE - A vehicle power transmission device having a torque converter in a power transmission path between an engine and drive wheels, the torque converter including an input-side rotating member disposed with a plurality of pump blades, an output-side rotating member disposed with a plurality of turbine blades receiving a fluid flow from the pump blades, and a stator disposed with a stator blade disposed between the pump blades and the turbine blades, the vehicle power transmission device includes: a case including a first chamber and a second chamber separated by a bulkhead disposed on an opposite side of the torque converter to the engine, the first chamber housing the torque converter, the second chamber being formed on an opposite side of the bulkhead to the torque converter, the first chamber and the second chamber being oil-tightly isolated from each other by an oil seal oil-tightly sealing a gap between an inner circumferential surface of the bulkhead and an outer circumferential surface of a cylindrical rotation shaft projected from the input-side rotating member toward the second chamber, the vehicle power transmission device being disposed with a thrust bearing between a side wall portion of the input-side rotating member closer to the bulkhead and the stator, the thrust bearing being disposed to partially or entirely overlap with the oil seal when viewed in a direction orthogonal to an axial center of the torque converter. a one way clutch being disposed between the stator and a non-rotating member which supports the stator, and a portion of the one way clutch protruding toward the second chamber as compared to the stator and an inner race of the one way clutch, the input-side rotating member having an annular projecting portion formed by projecting a portion at a radial position corresponding to the thrust bearing toward the bulkhead over entire circumference in the side wall portion of the input-side rotating member closer to the bulkhead, and the annular projecting portion containing the thrust bearing and a portion of the one way clutch. | 09-11-2014 |
20140274553 | Rear Drive Module For A Vehicle - A utility vehicle having a first axle that is coupled to first and second wheels, an internal combustion engine that drives a first output shaft, an electric drive motor that drives a second output shaft, and a torque transfer device coupled to the first axle and the first and second output shafts. The torque transfer device is operable in a first mode to receive torque from the first output shaft only and output a motive force to the first axle, a second mode to receive torque from the second output shaft only and output the motive force, a third mode to receive torque from the first output shaft and the second output shaft simultaneously and output the motive force, and a fourth mode to receive torque from the first output shaft and output a drive force to the second output shaft cause the electrical drive motor to generate electrical power. | 09-18-2014 |
20140287870 | HYBRID SYSTEM OF ENGINE AND MOTOR GENERATOR - An engine is provided with an output shaft and a motor generator connection shaft of a crankshaft at ends of a crank case and adapted such that the output shaft can be connected with an external driven apparatus. A motor generator has stators relatively fixed to the crank case and a rotor coupled with the motor generator connection shaft and rotating relative to the stators. An external apparatus connection shaft is connected with the rotor and disposed at an end of the motor generator on the opposite side of the engine. A clutch is disposed between the motor generator connection shaft and the rotor. A power storage unit stores electric power generated by the motor generator and supplies the electric power to the motor generator. A controller switches between an electric power generation function and a motor function, and engages and disengages the clutch. | 09-25-2014 |
20140296026 | HYBRID DRIVETRAIN AND METHOD FOR CONTROLLING THE SAME - A hybrid drivetrain for a motor vehicle has a first drive unit which has a first drive device by means of which first drive power can be provided. A second drive unit has a second drive device by means of which second drive power can be provided. A drive output device can be connected to driven wheels of the motor vehicle. A first gearbox arrangement has a first gearbox input and a first gearbox output. A second gearbox arrangement has a second gearbox input and a second gearbox output. The first drive device is connected to the first gearbox input and the second drive device is connected to the second gearbox input. The first and second gearbox outputs are connected to the drive output device. The first and second gearbox inputs can be connected to one another or separated from one another by means of a clutch. | 10-02-2014 |
20140296027 | CONTROL APPARATUS FOR VEHICLE - A control apparatus for a vehicle shifts a lock-up clutch to a slipping or released state when braking. The control apparatus causes an electric motor to output assist torque in a direction increasing a rotational speed of an engine, during control for shifting the lock-up clutch to a released state, when prescribed sudden braking is required during engine-powered travel in a locked-up state. Therefore, even if there is a time delay in actual implementation of shift from the locked-up state to the released state by the lock-up clutch, the rotational speed of the engine is increased (or maintained), or decrease in the rotational speed of the engine is suppressed, by the assist torque from the electric motor. | 10-02-2014 |
20140302964 | VEHICLE CONTROL APPARATUS - A vehicle control apparatus for a hybrid vehicle mounting a torque converter with a lock-up clutch in order to better accomplish good drivability as well as good gasoline mileage than conventional vehicle control apparatuses includes an engine, a motor generator, a torque convertor with the lock-up clutch, and a battery, and expands a lock-up region when the battery is not under a input/output limited state wider than when the battery is under the input/output limited state while the vehicle is being driven at least by the engine. | 10-09-2014 |
20140309079 | CONTROL DEVICE FOR VEHICLE DRIVE DEVICE - A control device of a vehicle drive device includes a fluid transmission device having an input-side rotating element to which power from an engine is input and an output-side rotating element outputting power to drive wheels, a first electric motor directly or indirectly coupled to the input-side rotating element, and a second electric motor directly or indirectly coupled to the drive wheels, the control device of a vehicle drive device having an electric path through which power is electrically transmitted by giving/receiving electric power between the first electric motor and the second electric motor and a mechanical path through which power is mechanically transmitted via the fluid transmission device, the control device of a vehicle drive device being configured to control an operating point of the engine by adjusting a torque of the first electric motor, the torque of the first electric motor being adjusted such that a sum of an engine torque and the torque of the first electric motor is balanced with an input-side load torque generated in the input-side rotating element depending on a speed ratio of the fluid transmission device, the input-side load torque being obtained based on an engine rotation speed indicated by a target engine operating point, and the torque of the first electric motor being determined based on the input-side load torque and the engine torque indicated by the target engine operating point, and the control device of a vehicle drive device adjusting a torque of the first electric motor while giving/receiving electric power between the first electric motor and the second electric motor to reduce a speed ratio of the fluid transmission device when a temperature of operating oil for actuating the fluid transmission device is lower as compared to when the temperature is higher. | 10-16-2014 |
20140315681 | THREE-SHAFT HYBRID TRANSMISSION FOR A MOTOR VEHICLE AND CONTROL METHOD - A hybrid transmission for a motor vehicle including a heat engine and electric drive machine, including two primary shafts respectively connected to the heat engine and electric machine, each supporting at least one intermediate drive on a first secondary shaft connected to wheels via a differential and a second secondary shaft sending motion of a primary shaft to the differential. A first coupling between the two primary shafts can occupy at least three positions of: the heat engine is uncoupled from the drive train connecting the electric machine to the wheels, or coupled by the second secondary shaft; the primary shaft connected to the heat engine is coupled to the first secondary shaft to drive the wheels with or without support of the electric machine; the primary shaft connected to the heat engine is coupled to the primary shaft connected to the electric machine, to add respective torques thereof. | 10-23-2014 |
20140315682 | CLUTCH DEVICE AND ELECTRIC MACHINE - The invention relates to a clutch device having an actuating device for a drivetrain of a motor vehicle, the drivetrain having an internal combustion engine, an electric machine with a stator and a rotor, and a transmission device, wherein the clutch device can be arranged in the drivetrain between the internal combustion engine at one side and the electric machine and the transmission device at the other side, the clutch device and the actuating device are integrated into the rotor of the electric machine, and the actuating device has a rotatable ramp device with first ramps and second ramps, wherein the clutch device has an electric actuator for actively rotating the ramp device, in order to structurally and/or functionally improve the clutch device, and to an electric machine having a stator, a rotor and a clutch device of this type integrated into the rotor. | 10-23-2014 |
20140323266 | METHODS AND SYSTEMS FOR ADJUSTING DRIVELINE OPERATION DURING AN ACCELERATOR TIP-OUT - Systems and methods for improving operation of a hybrid vehicle are presented. In one example, an engine may be operated at an idle speed while a driveline disconnect clutch separating the engine from a driveline is open in response to a reduction in driver demand torque. Engine torque may be applied to the driveline by simply closing the driveline disconnect clutch. | 10-30-2014 |
20140323267 | METHODS AND SYSTEMS FOR DRIVELINE SAILING MODE ENTRY - Systems and methods for improving operation of a hybrid vehicle are presented. In one example, entry conditions for entering a driveline sailing mode are described. Driveline sailing mode may improve driveline torque response and vehicle drivability. | 10-30-2014 |
20140329639 | CONTROL DEVICE - A control device for a vehicle. While subject control is performed, a second engagement control unit controls the engagement pressure of the second engagement device to a mid-control set pressure that has been set to be equal to or more than a first engagement pressure and equal to or less than a second engagement pressure. The first engagement pressure is a lower limit engagement pressure capable of maintaining the second engagement device in the directly coupled engaged state, in a state in which requested torque that is torque required to be transmitted to the wheels is transmitted to the wheels. The second engagement pressure is a lower limit engagement pressure capable of maintaining the second engagement device in the directly coupled engaged state, in a state in which maximum output torque of the rotary electric machine is transmitted to the wheels. | 11-06-2014 |
20140329640 | CLUTCH DEVICE - A clutch device having an actuating device for a drivetrain of a motor vehicle having an internal combustion engine, an electric machine with a stator and a rotor, and a transmission device, where the clutch device is situated in the drivetrain between the internal combustion engine on the one side and the electric machine and the transmission device on the other side, the clutch device and the actuating device being integrated into the rotor of the electric machine, in order to improve the construction and/or the function of the clutch device. | 11-06-2014 |
20140335996 | METHOD FOR OPERATING A DRIVE TRAIN - A method of operating a drive train of a motor vehicle comprising a drive assembly which has at least a combustion engine and an automatic transmission with frictional shift elements positioned between the drive assembly and an output. When executing a traction downshift in which at least one frictional shift element of the automatic transmission is engaged and at least one shift element of the automatic transmission is disengaged, the method comprising the steps of engaging at least a first frictional shift element of the automatic transmission, disengaging at least a second frictional shift element of the automatic transmission, and reducing torque, provided by the combustion engine, while reducing the transfer ability of the second frictional shift element for executing the traction downshift. | 11-13-2014 |
20140335997 | DRIVE DEVICE FOR HYBRID ELECTRIC VEHICLE - A drive device includes an engine, a first motor/generator, and a first planetary gear set group having at least four rotatable members and disposed between the input shaft and the output shaft. Four vertical axes corresponding to the first to fourth rotatable members are arranged in order at intervals corresponding to gear ratios of the group in a common velocity-axis diagram to correspond to a first member to a fourth member, respectively. The first member is connectable with the input shaft. The second member is connectable with the output shaft. The third member is fixable to a stationary part. The fourth member is connected with the first motor/generator. The input shaft is connectable with the engine. | 11-13-2014 |
20140335998 | POWER TRANSMISSION DEVICE FOR VEHICLE - A vehicle power transmission device is disposed on a hybrid vehicle having an engine and an electric motor, the vehicle power transmission device includes a first member having one of outer circumferential teeth disposed around one axial center or inner circumferential teeth meshing with the outer circumferential teeth and a second member having the other teeth, the inner circumferential teeth and the outer circumferential teeth meshes with each other to limit relative rotation around the one axial center between the first member and the second member, the relative rotation between the first member and the second member is limited to transmit torque of the electric motor to drive wheels. | 11-13-2014 |
20140335999 | DRIVE TRAIN OF A PURELY ELECTRICALLY ALL-WHEEL DRIVABLE MOTOR VEHICLE - A drive train ( | 11-13-2014 |
20140342871 | CONTROLLER OF HYBRID SYSTEM - In a controller of a hybrid system including an engine, a motor/generator, an automatic clutch to which engine torque is input, a gear group configured to transmit input torque to a driving wheel side, and a differential device provided with plural rotary elements to which a torque input side of the gear group, a rotating shaft of the motor/generator, and an output side of the automatic clutch are individually connected respectively, wherein at the time a vehicle is started by causing the motor/generator be in charge of a reaction force of the engine torque and transmitting the engine torque to the driving wheels via the differential device and the gear group, the automatic clutch is slip controlled in a semi-engaged state. | 11-20-2014 |
20140342872 | HYBRID VEHICLE POWER TRANSMISSION DEVICE - A power transmission device of a hybrid vehicle comprises: an electric differential portion having a first rotating element coupled to an engine, a second rotating element coupled to a first rotator, and a third rotating element coupled to a second rotator, the second rotator being disposed in a power transmission path including the third rotating element between the engine and drive wheels, the second rotator having a rotor shaft interposed in series in the power transmission path, a rotor of the second rotator being fixed, and making up a portion of the power transmission path. | 11-20-2014 |
20140342873 | VEHICLE CONTROL APPARATUS - To provide a vehicle control apparatus which can suppress a shock in a clutch from being generated at a time of starting an engine by a motor in a vehicle having the clutch provided therein between the engine and the motor, thereby improving a drivability of the vehicle. Provided is a vehicle control apparatus, comprising: an engine, a motor generator connected to vehicle wheels of a vehicle, and a clutch that switches a transmission state between a disengaging state and an engaging state, in which the vehicle control apparatus switches the clutch in the engaging state to start the engine by the motor generator. When the engine is started by the motor generator, the vehicle control apparatus constantly keeps the compensation torque of the motor generator smaller than the clutch torque of the clutch. | 11-20-2014 |
20140349810 | HYBRID DRIVE OF A MOTOR VEHICLE AND METHOD FOR OPERATING SAME - A hybrid drive of a motor vehicle has an internal combustion engine, an electric machine, and a transmission. The transmission is a multi-stage shifting transmission including two subtransmissions, each of which has a separate input shaft and a common output shaft. The first input shaft of a first subtransmission can be coupled and decoupled to the internal combustion engine. The second input shaft of a second subtransmission is rigidly coupled to the electric machine. Both input shafts can be coupled selectively to the common output shaft via form-locking shift elements. The first input shaft can be attached to multiple clutches in such a way that when a first friction-locking or form-locking clutch and a second friction-locking clutch connected in series are both engaged, the internal combustion engine is coupled to the first input shaft and to the first subtransmission. | 11-27-2014 |
20140349811 | VEHICLE DRIVING SYSTEM - A vehicle driving system in which a clutch is disposed between an engine output member and an automatic transmission and the clutch is used as a start clutch that is slip-controlled when a vehicle starts. When a lubricant relay valve is switched to the communicating position, oil from the pressure-regulating oil passage is supplied to the clutch via the input port, the output port, and the clutch lubricant passage. When the lubricant relay valve is switched to the cutoff position, the oil from the pressure-regulating oil passage is supplied to the clutch via the orifice and the clutch lubricant passage, the feedback pressure of the feedback port is increased, the communication rate between the pressure-regulating port and the back-pressure port is increased, and the amount of lubricant supplied from the back-pressure oil passage to the lubrication portion of the automatic transmission is increased. | 11-27-2014 |
20140371029 | CONTROL DEVICE - A control device that controls a vehicle drive device in which a first engagement device, a rotating electrical machine, a second engagement device, and an output member are sequentially arranged in this order from an input member side on a power transmission path that connects the input member drivingly coupled to an internal combustion engine to the output member drivingly coupled to wheels. The control device controls both the first engagement device and the second engagement device to a slip engaged state, and causes the rotating electrical machine to generate electric power. | 12-18-2014 |
20140378273 | METHOD AND SYSTEM FOR REDUCING DRIVELINE NVH - A method and a system for reducing driveline speed oscillations related to a driveline resonance frequency are described. Driveline speed oscillations may be reduced via slipping a driveline clutch or adjusting torque of a driveline motor/generator. The method and system may be activated during select vehicle operating conditions. | 12-25-2014 |
20150018170 | HYBRID DRIVE FOR A WATER VEHICLE - A hybrid drive for a watercraft, including a primary drive motor, which is situated inside the watercraft and drives a drive shaft, and an above-water transmission, which is situated after the drive shaft and has a transmission housing, for driving a vertical shaft branching off from the above-water transmission, as well as an electric secondary drive motor, which has a stator and a rotor and is able to drive the vertical shaft in addition to or alternatively to the primary drive motor. The secondary drive motor can be embodied with a hollow shaft and the stator of this motor can be coupled in a torsionally rigid fashion to the transmission housing of the above-water transmission. | 01-15-2015 |
20150024903 | DOUBLE CLUTCH SYSTEM FOR HYBRID ELECTRIC VEHICLE - A double clutch system may include a connecting shaft that is continuously connected to a motor/generator and is selectively connected to an engine and may transmit torque transmitted to the connecting shaft selectively to two input shafts. | 01-22-2015 |
20150031501 | HYBRID-ELECTRIC VEHICLE WITH CONTINUOUSLY VARIABLE TRANSMISSION - A hybrid-electric vehicle having a continuously variable transmission is provided. The continuously variable transmission further includes a forward disconnect clutch configured to selectively couple and decouple the continuously variable transmission and a first set of drive wheels. The hybrid-electric vehicle further includes a rear e-axle assembly, which allows the vehicle to operate in an electric-only mode, in which the vehicle is propelled with power generated solely by at least one electric power component. When the vehicle is operated in electric-only mode, the transmission disconnect clutch is disengaged, such that the continuously variable transmission is decoupled from the first set of drive wheels to allow the continuously variable transmission to operate in a low loss state. A method of transitioning an all-wheel drive hybrid-electric vehicle between an electric only mode and a hybrid mode, i.e., completing a “flying start,” is also provided. | 01-29-2015 |
20150031502 | METHOD FOR OPERATING A DRIVE TRAIN AND CONTROL DEVICE - A method for operating a drive train of a hybrid vehicle with a hybrid drive comprising at least an electric machine and an internal combustion engine, wherein an automated manual transmission is connected between the internal combustion engine and an output, wherein the electric machine is coupled via a friction clutch to a shaft of the automated manual transmission. Wherein in the automated manual transmission, by interruption of the drive torque provided by the hybrid drive on the output, shifts are executed in such a way that in a first phase the drive torque provided at the output is first reduced, subsequently in a second phase the actual gear shift is executed and following that in a third phase drive torque is built up at the output. Wherein for execution of the actual shift after a gear disengagement of an actual gear of the shift and before a gear engagement of a target gear of the shift, the automated manual transmission is synchronized using a flywheel mass of the electric machine such that, when the friction clutch is opened, the rotational speed of the electric machine is brought to an inertial rotational speed and that subsequently the friction clutch is first closed to the inertial synchronization of the manual transmission and subsequently at least partially opened again. | 01-29-2015 |
20150031503 | HYBRID SYSTEM CONTROL DEVICE - A control device of a hybrid system includes an engine; a motor/generator; an automatic clutch to a first engaging unit side of which an engine rotary shaft is connected; a differential device provided with a plurality of rotational elements to each of which an MG rotary shaft and a second engaging unit side of the automatic clutch are separately connected; a first transmission a rotary shaft of which is connected to the rotational element to which the second engaging unit is connected; a second transmission a rotary shaft of which is connected to another rotational element; and an output shaft connected to a driving wheel side, wherein at the time of EV driving, transmission control is performed and the automatic clutch is disengaged such that the first transmission and the second transmission can perform torque transmission between the input shaft and the output shaft. | 01-29-2015 |
20150038288 | VEHICLE POWERTRAIN WITH CLUTCH ACTUATOR PROVIDING ELECTRICAL POWER - A vehicle powertrain includes a first rotatable member and a second rotatable member. A clutch has an engaged state in which torque is transferred between the first rotatable member and the second rotatable member through the clutch. The clutch has a disengaged state in which torque is not transferred between the first rotatable member and the second rotatable member through the clutch. A clutch actuator includes a motor-generator that has a rotor rotatably drivable by one of the first rotatable member and the second rotatable member, and has a stator powerable to rotatably drive the rotor relative to said one of the first rotatable member and the second rotatable member. A controller is operatively connected to the stator and is configured to control the motor-generator to function as a generator to provide torque on the rotor. The motor-generator provides electrical power to a vehicle component. | 02-05-2015 |
20150038289 | BICYCLE DRIVE UNIT - A bicycle drive unit includes a crank axle, a motor, an output member and a torque combining mechanism. The crank axle is rotatable about a first rotational axis. The motor has an output shaft rotatable about a second rotational axis. The output member is rotatable about the first rotational axis in a first rotational direction as the crank axle rotates about the first rotational axis in the first rotational direction. The torque combining mechanism operatively couples the output shaft of the motor to the output member to transmit rotation of the output shaft of the motor to the output member. The torque combining mechanism operatively separates the output shaft of the motor from the output member for preventing rotation of the crank axle from being transmitted to the output shaft of the motor as the crank axle rotates about the first rotational axis in a second rotational direction. | 02-05-2015 |
20150038290 | DRIVETRAIN - The present invention relates to a drivetrain of a motor vehicle, having an internal combustion engine, having an electric machine, having a transmission unit, in particular a manual transmission, and having a clutch unit. The clutch unit comprises a first clutch actuable by a driver of the motor vehicle and a second clutch automatically actuable by a control unit. The electric machine can be coupled in terms of drive to the transmission unit by means of the first clutch and the internal combustion engine can be coupled in terms of drive to the electric machine by means of the second clutch. | 02-05-2015 |
20150045179 | DRIVE APPARATUS FOR HYBRID VEHICLE - The drive apparatus ( | 02-12-2015 |
20150045180 | PARALLEL POWER INPUT GEARBOX - A retrofittable hybrid parallel power flow distribution system for a vehicle. In various embodiments, the system comprises an electric rotating machine and a parallel power input gearbox. The parallel power input gearbox is structured and operable to receive torque from the electric rotating machine and/or an internal combustion engine of the vehicle and selectively distribute the received torque, i.e., a power flow, in any proportion/ratio to one or more of the electric rotating machine, a rear axle differential of the vehicle, a transmission or transfer case and front axle of the vehicle, or an auxiliary device of the vehicle. | 02-12-2015 |
20150045181 | VEHICLE POWER TRANSMISSION DEVICE - A power transmission apparatus for a vehicle is provided which is equipped with a power split device and a speed variator. The power transmission device is designed to set a speed ratio of speed of rotation of an output of a power source to speed of rotation of a driven wheel in a power circulation mode of a power split device to lie within one of a positive range in which a sign of the speed ratio is positive and a negative range in which a sign of the speed ratio is negative. This results in a decrease in degree of torque acting on the speed variator such as a continuously variable transmission, thus permitting a required degree of durability of the speed variator to be reduced. | 02-12-2015 |
20150051045 | METHODS AND SYSTEMS FOR VEHICLE DRIVELINE TORQUE ESTIMATION - Systems and methods for improving hybrid vehicle torque control are presented. The system and methods included may estimate driveline torque via springs of a dual mass flywheel. The estimated driveline torque may provide feedback for adjusting operation of a driveline disconnect clutch and/or engine torque. | 02-19-2015 |
20150065295 | DEVICE AND METHOD FOR CONTROLLING CLUTCH OF HYBRID VEHICLE - A device and method for controlling a clutch of a hybrid vehicle controls an engagement and a disengagement of an engine clutch installed between an engine and a motor. The device includes a acceleration request sensor for sensing driving situations in which acceleration is needed immediately after deceleration of the hybrid vehicle in a state where the engine clutch is engaged. A controller maintains the engagement state of the engine clutch even though a disengagement condition of the engine clutch is satisfied when receiving a sensed signal of the acceleration request sensor. | 03-05-2015 |
20150072829 | VEHICLE CONTROL APPARATUS - A control device of a vehicle including an engine, an electric motor, and a clutch configured to achieve a mechanically directly-coupled state of a power transmission path between the engine/the electric motor and drive wheels, the control device causing the clutch to be slip-engaged or released when the engine is started during motor running in which only the electric motor is used as a drive force source for running with the clutch engaged, the control device being configured such that when the clutch is engaged during the motor running, an engagement pressure is made lower than an engagement pressure when the clutch is engaged during engine running in which at least the engine is used as a drive force source for running, and in the case of running with the clutch engaged, the engagement pressure of the clutch is constantly adjusted based on output torque of the electric motor during the motor running, while the engagement pressure of the clutch is not adjusted during the engine running. | 03-12-2015 |
20150072830 | Hybrid Electric Vehicle Control Device - When a vehicle is to be started solely by a motor immediately after an engine is started or the shift position has been changed from N range to D range, a delay time for delaying pre-charge of first and second clutches is set in accordance with operating oil temperature. The pre-charge is executed after a lapse of the delay time. | 03-12-2015 |
20150072831 | Vehicle Shift Control Device - If, in uphill deceleration determination procedure, it is determined that the vehicle is being decelerated on an uphill slope, a transmission shift lever is in D range, the motor is in order, the start gear is a first specified gear or lower, a to-be-selected traveling gear is a second specified gear or lower, an actual even-numbered gear is a third specified gear or higher, and actual odd-numbered gear is a fourth specified gear or higher, a first, a second and a third synchronizer mechanisms are put in neutral position to create a state in which no gear is selected. Then, a shift to a gear suited for re-acceleration is conducted by activating operating the first, second and the third synchronizer mechanisms. | 03-12-2015 |
20150072832 | METHODS AND SYSTEMS FOR OPERATING A VEHICLE DRIVELINE - Systems and methods for improving operation of a hybrid vehicle are presented. In one example, an engine is accelerated to a speed of a driveline integrated starter/generator before the engine is coupled to the driveline integrated starter/generator. | 03-12-2015 |
20150080174 | Multimode Clutch for a Parallel Hybrid Vehicle - In a parallel hybrid vehicle having and internal combustion engine and an electric motor operatively connected to a transmission shaft, a multimode mechanical clutch selectively couples an output shaft of the internal combustion engine to the transmission shaft. The multimode clutch has a two-way unlocked mode where the output shaft and transmission shaft can rotate independently in either direction, and a one-way locked, one-way unlocked mode where the shafts are locked to rotate together in one direction and unlocked for independent rotation in the opposite direction. The clutch may also have a two-way locked mode where the shafts rotate together in both directions. Pawls may be provided to engage and disengage as needed to execute the modes of the multimode clutch actuator. | 03-19-2015 |
20150080175 | CONTROL DEVICE FOR HYBRID VEHICLE - A control device of a hybrid vehicle includes an engine, an electric motor configured to output power for running and power necessary for starting the engine, and a connecting/disconnecting clutch connecting/disconnecting a power transmission path between the engine and the electric motor, and the control device is configured to start the engine while the connecting/disconnecting clutch is controlled toward engagement during motor running for running by using only the electric motor as a drive force source for running with the connecting/disconnecting clutch released. | 03-19-2015 |
20150099605 | TRANSMISSION SYSTEM OF HYBRID ELECTRIC VEHICLE - A transmission system for a hybrid electric vehicle includes an input shaft connected to an output side of an engine, first and second motors/generators having a function of a motor and a generator and disposed in a transmission housing, a planetary gear set disposed on the input shaft and including three rotating elements, in which among three rotating elements, a first rotating element is directly connected to the first motor/generator and selectively connected to the input shaft and the transmission housing, a second rotating element is directly connected to the input shaft, and a third rotating element is connected to an output gear and connected to the second motor/generator, and a connection unit disposed at the selective connection part. | 04-09-2015 |
20150099606 | TRANSMISSION SYSTEM OF FOUR WHEEL DRIVE HYBRID ELECTRIC VEHICLE - A transmission system for a four wheel drive hybrid electric vehicle includes: an input shaft selectively connected to a front wheel transmission housing while being connected to an output shaft of an engine; a first motor/generator having disposed in the front wheel transmission housing; a second motor/generator having a function of the motor and the generator and connected to a rear wheel output gear disposed in a rear wheel transmission housing; a planetary gear set on the input shaft and including three rotating elements, in which among three rotating elements, a first rotating element is directly connected to the first motor/generator and selectively connected to the input shaft, a second rotating element is directly connected to the input shaft, and a third rotating element is selectively connected to a front wheel output gear; and a connection unit disposed at a selective connection part. | 04-09-2015 |
20150099607 | Method and Apparatus for Limiting Engine Torque to Protect Disconnect Clutch in a Hybrid Vehicle - A powertrain comprising an engine, a motor, a disconnect clutch connected between the engine and the motor, and a transmission. The transmission is connected to the motor by a torque converter and lock-up clutch and selectively and indirectly connected to the engine by the disconnect clutch. A controller receives an engine torque output signal and reduces the torque output of the engine to the clutch capacity limit value. A system and a method are also provided for controlling a powertrain for a hybrid vehicle. | 04-09-2015 |
20150105215 | HYBRID VEHICLE HAVING BRAKE FUNCTION - A hybrid vehicle having a brake function includes a hybrid starter and generator (HSG) for starting an engine or generating electricity by the engine. A clutch is disposed on a route for transmitting torque of the engine to a wheel, wherein the clutch selectively transmits the torque. A motor is disposed at a rear side of the clutch on the route, wherein the motor adds torque or generates electricity. An inverter is electrically connected to the HSG and the motor, and a battery is electrically connected to the inverter, wherein the battery stores or outputs electrical energy. A controller releases the clutch, controls the motor to generate the electricity through the torque transmitted from the wheel to the motor, and controls the HSG to consume the electricity generated from the motor, if a braking demand condition is satisfied. | 04-16-2015 |
20150105216 | METHODS AND SYSTEMS FOR LAUNCHING A VEHICLE - Systems and methods for improving operation of a hybrid vehicle are presented. In one example, an engine is started and idled before engine torque is required so that driveline torque response may be improved. | 04-16-2015 |
20150111693 | HYBRID VEHICLE IDLE AND CREEP CONTROL - A vehicle includes an engine having a crankshaft, a transmission having an input, and a torque converter mechanically coupled to the input. The vehicle further includes an electric machine mechanically coupled to the torque converter, a clutch configured to mechanically couple the electric machine and crankshaft, and one or more controllers. The one or more controllers are programmed to, in response to the transmission being in a drive or reverse gear and a speed of the vehicle being less than a predetermined value in an absence of driver demand, control the electric machine to achieve a target speed to cause the torque converter to output torque such that the speed of the vehicle approaches a generally constant speed less than or equal to the predetermined value when the vehicle is on a generally flat grade. | 04-23-2015 |
20150111694 | POWER TRANSMISSION SYSTEM OF HYBRID ELECTRIC VEHICLE - A power transmission system of a hybrid electric vehicle which uses an engine and first and second motor/generators as power sources may include an input device having a first input shaft receiving either or both of torques of the engine and the first motor/generator and provided with a first driving gear disposed thereon, and a second input shaft disposed in parallel with the first input shaft, receiving a torque of the second motor/generator, and provided with a second driving gear disposed thereon, an output device including an output shaft provided with one driven gear engaged with the first driving gear, a second driven gear engaged with the second driving gear, and an output gear disposed thereon, and outputting torque transmitted from the input device, and a final reduction device outputting torque transmitted from the output device as driving torque. | 04-23-2015 |
20150119192 | SYSTEMS AND METHODS FOR CONTROLLING AN AUTOMATIC TRANSMISSION DURING A FLYING ENGINE START USING A FLOW ACCUMULATOR - A system and method can control a transmission during a flying engine start. The method includes receiving a request for an internal combustion engine to be started while a vehicle is solely driven by an electric motor-generator. Further, the method determining a time lapse between a moment when a first clutch starts to be filled and a moment when a second clutch starts to be filled such that the first clutch and the second clutch reach first and second clutch pressure thresholds, respectively, at substantially the same time. The method includes transferring transmission fluid to the first clutch and transferring transmission fluid to the second clutch after the determined time lapse has passed since the first clutch started to be filled. | 04-30-2015 |
20150119193 | TRANSMISSION SYSTEM OF HYBRID ELECTRIC VEHICLE - A transmission system of a hybrid electric vehicle may include a first shaft connected to an engine, a first hollow shaft disposed without rotational interference with the first shaft and provided with a first output gear, a second hollow shaft disposed without rotational interference with the first hollow shaft and provided with a second output gear, a second shaft disposed in parallel with the first shaft and operably connected to the first shaft and the first hollow shaft through a gear unit so as to selectively transmit torque of the first shaft to the first hollow shaft, a clutch selectively connecting the second shaft to the first hollow shaft, a first motor/generator operably connected to the second hollow shaft, and a second motor/generator operably connected to the second shaft. | 04-30-2015 |
20150119194 | POWER TRANSMISSION SYSTEM OF HYBRID ELECTRIC VEHICLE - A power transmission system of a hybrid electric vehicle may include a first input device, a torque transmitting device, a second input device, an output device, and a final reduction device. The first input device may receive either or both of torques of an engine and a first motor/generator. The torque transmitting device may be disposed at a rear or downstream of the first input device and selectively receive torque from the first input device. The second input device may be disposed at a rear or downstream of the torque transmitting device, convert torque of a second motor/generator, and output the converted torque. The output device may receive torque from the torque transmitting device and/or the second input device and output the torque. The final reduction device may output the torque transmitted from the output device as driving torque. | 04-30-2015 |
20150126329 | SYSTEM AND METHOD FOR UPSHIFT TORQUE MODIFICATION USING AN UPSTREAM CLUTCH IN A HYBRID VEHICLE - A hybrid vehicle has an engine, an electric machine connected to the engine by an upstream clutch, a transmission gearbox connected to the electric machine by a downstream clutch, and a controller. The controller is configured to, in response to a commanded upshift of the gearbox, modulate a pressure of the upstream clutch. A method for controlling a vehicle includes, in response to a commanded upshift of a gearbox, controlling an upstream clutch to a first nonzero speed differential corresponding to a first inertia connected to and upstream of the gearbox to reduce inertia torque during the upshift. A method for controlling a vehicle includes, in response to a commanded upshift of a gearbox when the vehicle is beyond an electrical limit and a fast path torque reduction limit, slipping an upstream clutch and reducing torque outputs of an engine and an electric machine. | 05-07-2015 |
20150141198 | HYBRID VEHICLE - A hybrid vehicle of the present invention includes: an engine, a first motor, a second motor, a clutch and an electronic control unit. The first motor is connected with an output shaft of the engine. The second motor is connected with a driving wheel and configured to generate a driving torque at the driving wheel. The clutch is arranged between the output shaft of the engine and the driving wheel and configured to engage or disengage the output shaft of the engine and a rotary shaft connected with the driving wheel. The electronic control unit is configured to control the clutch to be engaged and control the first motor to generate the driving torque at the driving wheel, when the second motor cannot generate a predetermined output torque and the clutch is disengaged. | 05-21-2015 |
20150148188 | HYBRID POWER TRAIN FOR VEHICLE - A hybrid power train for a vehicle may include a shift module with a plurality of shift steps of a synchro-mesh type provided on a first input shaft and an output shaft, a second input shaft driven by a motor and arranged coaxially with the first input shaft, a shaft clutch means for coupling/decoupling the second input shaft and the first input shaft, a motor side driving gear arranged rotatably on the second input shaft, a motor side driven gear arranged rotatably on the output shaft to be meshed with the motor side driving gear, a first clutch means for coupling/decoupling the motor side driving gear to/from the second input shaft, a second clutch means provided for coupling/decoupling the motor side driven gear to/from the output shaft, and a variable gear ratio providing means provided on the second input shaft to alternatively transfer a rotational force of the second input shaft to the output shaft. | 05-28-2015 |
20150148189 | POWER TRANSMISSION SYSTEM OF HYBRID ELECTRIC VEHICLE - A power transmission system of a hybrid electric vehicle may include, a generating device adapted to generate electricity by torque of an engine or to start the engine. an input device adapted to receive the torque of the engine. a speed output device changing the torque transmitted from the input device into two speed steps and outputting the changed torque. an auxiliary power source disposed between the input device and the speed output device and adapted to supply torque to the speed output device or to generate electricity by the torque of the speed output device. a final reduction device outputting the torque transmitted from the speed output device. | 05-28-2015 |
20150291144 | PRESTROKING ENGINE DISCONNECT CLUTCH IN A HYBRID VEHICLE - A hybrid vehicle includes an engine and an electric machine selectively coupled to one another via a clutch. In one mode of operation, the vehicle can be propelled by only the electric machine while the engine is off. When additional torque is required from the engine, at least one controller transmits an engine start request. In order to start the engine, the clutch can be prestroked such that it fills with pressure prior to the engine to start the engine. While the vehicle is on, at least one controller is programmed to prestroke the clutch prior to the engine start request based at least upon the electric machine and the engine generating substantially zero torque. This increases the overall engine start time. | 10-15-2015 |
20150291154 | HYBRID DRIVE OF A MOTOR VEHICLE AND METHOD FOR OPERATING SAME - A hybrid drive for a motor vehicle includes an internal combustion engine, an electric machine and a transmission. The transmission is a multi-stage shifting transmission having first and second subtransmissions which have first and second input shafts, respectively, and share a common output shaft. The first and second input shafts can be coupled selectively to the common output shaft via form-locking shift elements of the subtransmissions. The first input shaft of the first subtransmission can be coupled to the electric machine, via a first clutch, and the second input shaft can be coupled to the internal combustion engine via a second clutch. A drive shaft of the electric machine can be connected to the second input shaft via a form-locking shift element. | 10-15-2015 |
20150298682 | POWER TRANSMISSION DEVICE FOR HYBRID VEHICLE AND HYBRID SYSTEM - A power transmission device for a hybrid vehicle includes: a power distribution mechanism including a plurality of rotation components; a friction engagement device which is interposed between the engine and the rotation component connected to the engine; and a control device which performs a stop control for the engine and a release control for the friction engagement device so as to cause the vehicle to travel only by the power of the second rotary machine and performs an engagement control for the friction engagement device while the vehicle travels only by the power of the second rotary machine so as to perform a push-start of the engine, and the control device controls the first rotary machine so that the friction engagement device is maintained in a half engagement state at a differential rotation speed higher than a predetermined rotation speed during the push-start of the engine. | 10-22-2015 |
20150314769 | POWER TRANSMISSION DEVICE - A power transmission device includes: an engine; a rotary machine; and an oil pump connected to each of a rotary shaft of the engine and a rotary shaft of the rotary machine through a one-way clutch. The power transmission device is configured to allow the rotary machine to rotate at a rotational speed higher than the rotational speed corresponding to a speed of the engine and lower than the rotational speed corresponding to an idling speed of the engine at the time of startup of the engine. | 11-05-2015 |
20150329106 | CONTROL DEVICE FOR HYBRID VEHICLE - A control device of a hybrid vehicle includes: an engine; a first electric motor; a second electric motor coupled to a drive shaft of the engine; a clutch disposed in a power transmission path between the engine and the first electric motor; an electric oil pump generating an oil pressure by electric power; a mechanical oil pump included in a power transmission path closer to the first electric motor relative to the clutch, the mechanical oil pump generating an oil pressure by a drive force of at least one of the engine and the first electric motor; and an electric storage device giving/receiving electric power to/from the second electric motor and supplying electric power to the electric oil pump. When an open failure occurs in the clutch, the second electric motor generates electricity by driving the engine and an oil amount supplied from the electric oil pump is larger than an oil amount supplied from the mechanical oil pump. | 11-19-2015 |
20150343890 | Modular Hybrid Transmission with a One Way Clutch - A vehicle transmission system having a combustion engine, an electric motor and a transmission includes a first clutch operatively connected between the engine and the motor and a one way clutch. The one way clutch is connected in parallel with the first clutch that permits the engine to increase speed with the clutch disengaged until the engine speed matches the motor speed. The engine provides positive torque through the one way clutch to the motor and transmission upon matching the motor speed. The first clutch and the one way clutch may be a hybrid rocker one way clutch. | 12-03-2015 |
20150344026 | METHODS AND SYSTEMS FOR OPERATING A DRIVELINE CLUTCH - Systems and methods for improving operation of a hybrid vehicle are presented. In one example, operation of a driveline disconnect clutch is adjusted to compensate for clutch wear and manufacturing tolerances. | 12-03-2015 |
20150352942 | Drive Unit for a Hybrid Vehicle and Method for Operating the Same - Drive unit for a hybrid vehicle, whereas the drive unit comprises a drive assembly ( | 12-10-2015 |
20150360552 | HYBRID POWERTRAIN FOR VEHICLE - A hybrid powertrain for a vehicle includes an input shaft rotating in response to a power received from an engine. output shaft is arranged parallel to the input shaft. A first motor generator is configured to transmit and receive a power to and from the output shaft. A second motor generator is configured to transmit and receive a power to and from the input shaft. A first clutch structure enables or disables transmission of the power between the first motor generator and the output shaft. A second clutch structure enables or disables transmission of the power between the input shaft and the output shaft. A third clutch structure enables or disables transmission of the power between the second motor generator and the input shaft. | 12-17-2015 |
20150360673 | CONTROL DEVICE FOR VEHICLE DRIVE APPARATUS - A control device for a vehicle drive apparatus, the vehicle drive apparatus including an output shaft connected to an engine; an input shaft connected to a wheel; an electric motor that generates rotational torque of the wheel; and a hydraulic clutch that connects the output shaft to the input shaft when placed in an engaged state, and disconnects the output shaft from the input shaft when placed in a released state. | 12-17-2015 |
20150360676 | CONTROL DEVICE AND CONTROL METHOD FOR A HYBRID VEHICLE - The control device for a hybrid vehicle includes: a mechanical power source; an electric motor to be used when the mechanical power source is started; a first clutch arranged between the mechanical power source and a first transmission mechanism including a plurality of gear shift stages; a second clutch arranged between the mechanical power source and a second transmission mechanism including a plurality of gear shift stages; an electrical power source coupled to an input shaft of the first transmission mechanism; and a control unit for controlling a torque of at least one of the second clutch or the electric motor so as to compensate a braking force decreased upon a gear shift in the electrical power source when a gear shift request for shifting the gear shift stage of the first transmission mechanism is made during a regeneration travel of the electrical power source. | 12-17-2015 |
20150360683 | METHODS AND SYSTEMS FOR OPERATING A DRIVELINE DISCONNECT CLUTCH - Systems and methods for improving operation of a hybrid vehicle are presented. In one example, application of a driveline disconnect clutch to start an engine is described. The approach applies the driveline disconnect clutch to rotate an engine and at least partially disengages the driveline disconnect clutch to reduce the possibility of a reduction in torque applied to vehicle wheels. | 12-17-2015 |
20150375736 | Method for Operating a Drive Unit for a Hybrid Vehicle - Method for operating a drive unit for a hybrid vehicle, whereas the drive unit comprises a drive assembly ( | 12-31-2015 |
20150375737 | VEHICLE DRIVE DEVICE - A first rotating machine and a second rotating machine, a first travel mode, in which one rotating machine of the first rotating machine and the second rotating machine is used as a power source, and a second travel mode, in which the first rotating machine and the second rotating machine are used as the power sources, are provided. Regarding at least one rotating machine of the first rotating machine and the second rotating machine, when transition from one of the first travel mode and the second travel mode to the other is made, a degree of change in a torque command value for said rotating machine is higher in the case where said rotating machine newly becomes the power source in a travel mode after transition than in the case where said rotating machine is used as the power source in a travel mode before transition. | 12-31-2015 |
20160001649 | DUAL RATIO DRIVE FOR VARIABLE SPEED HYBRID ELECTRIC SUPERCHARGER ASSEMBLY - An example engine assembly includes: an electric motor including an electric motor drive shaft; a first clutch positioned to apply torque through a first gear set to an internal combustion engine of the engine assembly; and a second clutch positioned to apply torque through a second gear set to a supercharger of the engine assembly. | 01-07-2016 |
20160001770 | METHOD AND CORRESPONDING DEVICE FOR COUPLING A SHAFT OF AN ELECTRIC MOTOR WITH A WHEEL SHAFT OF AN ELECTRICALLY POWERED OR HYBRID MOTOR VEHICLE - A method and device for coupling an electric motor shaft with a wheel shaft of a vehicle includes measurement of rotation speed of the electric motor and measurement of rotation speed of the wheels. The method also includes formulating via a closed-loop control a first operating setpoint for the electric motor based on the measured rotation speed of the electric motor and the measured rotation speed of the wheels; formulating a second operating setpoint based on the measured rotation speed of the wheels to which at least one coefficient is applied; controlling the operation of the motor around a final operating setpoint formulated based on adding together the first and second operating setpoints; and coupling, if the measured speed of the wheels to which the at least one coefficient is applied is equal to the measured speed of the motor, the electric motor shaft with the wheel shaft. | 01-07-2016 |
20160003207 | VEHICLE CONTROL DEVICE - A control device of a vehicle including an engine, an electric motor, and a clutch disposed on a power transmission path between the engine and the electric motor, the control device of a vehicle performing an ignition start causing combustion in a cylinder of the engine to rotate the engine at a start of the engine, the control device of a vehicle switching a cylinder in which combustion is first caused in the engine based on an actuation during a rotation stop process of the engine of an exhaust valve in a cylinder stopped in an expansion stroke, when performing the ignition start at the start of the engine. | 01-07-2016 |
20160009270 | METHODS AND SYSTEMS FOR IMPROVING HYBRID VEHICLE PERFORMANCE CONSISTENCY | 01-14-2016 |
20160016580 | METHODS AND SYSTEMS FOR STARTING AN ENGINE WHILE A VEHICLE IS CREEPING - Systems and methods for starting an engine of a hybrid vehicle that is in a creep mode are presented. In one example, a torque converter lockup clutch is released and vehicle speed is closed loop controlled in response to a request to start an engine. The vehicle speed is controlled so that a torque disturbance related to closing a driveline disconnect clutch may be reduced. | 01-21-2016 |
20160031431 | METHODS AND SYSTEM FOR TRANSITIONING BETWEEN CONTROL MODES WHILE CREEPING - Systems and methods for transitioning a torque source between speed control and torque control modes during a vehicle creep mode are disclosed. In one example, torque of an electric machine is adjusted in response to a torque converter model. The torque converter model provides for a locked or unlocked torque converter clutch. | 02-04-2016 |
20160031432 | METHODS AND SYSTEMS FOR IMPROVING HYBRID VEHICLE TRANSMISSION SHIFTING - Systems and methods for improving hybrid vehicle shifting are presented. Specifically, torque supplied to an input shaft of a transmission may be adjusted during torque and inertia phases of a transmission gear shift. The torque supplied to the transmission input shaft may be increased or decreased based on the shift and the shift phase. | 02-04-2016 |
20160031435 | METHODS AND SYSTEM FOR STARTING AN ENGINE OF A HYBRID VEHICLE - Systems and methods for starting an engine of a hybrid vehicle are disclosed. The systems and methods disclosed may apply to series or parallel hybrid driveline configurations. In one example, engine cranking torque may be adjusted in response to a variety of operating conditions so that the engine may be started faster or slower. | 02-04-2016 |
20160031439 | CLUTCH CONTROL TO ENTER POWERSPLIT HYBRID POWERTRAIN PARALLEL MODE - A selectively actuatable one-way clutch is controlled to brake or release a generator such that a powersplit hybrid powertrain enters or exits a parallel mode of operation. To brake the generator and enter the parallel mode, the clutch is activated while overrunning the generator before the generator is slowed to engage the clutch. To release the generator and exit the parallel mode, the generator is controlled to overrun the clutch before deactivating the clutch and returning the generator to a base speed control. | 02-04-2016 |
20160032990 | METHODS AND SYSTEM FOR APPLYING A DRIVELINE DISCONNECT CLUTCH - Systems and methods for improving operation of a driveline disconnect clutch for a hybrid vehicle shifting are presented. In one example, pressure of a working fluid supplied to the driveline disconnect clutch is adjusted in response to a rate of change in accelerator pedal position. Further, pressure of the working fluid may be decreased responsive to selected operating conditions. | 02-04-2016 |
20160046282 | METHODS AND SYSTEMS FOR STARTING AN ENGINE - Methods and systems are provided for improving engine restart operations occurring during a transmission shift in a hybrid vehicle. Engine speed is controller during cranking and run-up to approach a transmission input shaft speed that is based on the future gear of the transmission shift. Engine speed is controlled via adjustments to spark, throttle, and/or fuel, to expedite engine speed reaching the synchronous speed. | 02-18-2016 |
20160052382 | POWERTRAIN WITH TRANSMISSION-BASED MOTOR/GENERATOR FOR ENGINE STARTING AND REGENERATIVE BRAKING MODES - A powertrain is provided that has an engine with a rotatable crankshaft. The powertrain has a transmission with a transmission input member and a transmission output member. A final drive is operatively connected to the transmission output member and includes a drive axle. An engine clutch has an engaged state that operatively connects the engine crankshaft with the transmission input member, and has a disengaged state that operatively disconnects the engine crankshaft from the transmission input member. A motor/generator is provided and a first torque-transmitting device has a selectively engaged state in which the first torque-transmitting device transmits torque between the motor/generator and the transmission output member independent of the engine, the crankshaft, and the engine clutch. A second torque-transmitting device has a selectively engaged state in which the second torque-transmitting device transmits torque between the motor/generator and the crankshaft independent of the first torque-transmitting device and the engine clutch. | 02-25-2016 |
20160052509 | METHODS AND SYSTEM FOR LAUNCHING A HYBRID VEHICLE - Systems and methods for improving launching of a stopped hybrid vehicle are presented. The systems and methods adjust speed of a motor to reduce the possibility of noticeable impact between driveline gears during vehicle launch. In one example, motor speed is adjusted to a pump pressurization speed where driveline components may be moved to reduce impact between driveline gears during vehicle launch. | 02-25-2016 |
20160059846 | METHODS AND SYSTEMS FOR STARTING AN ENGINE - Methods and systems are provided for improving engine restart operations responsive to a heavy operator pedal tip-in. Engine torque and disconnect clutch capacity are controlled during cranking and engine speed run-up so as to provide excess torque to accelerate the engine to the motor speed and prepare the engine for elevated torque delivery after the engine connects to the driveline. At a time of connecting the engine to the driveline, the engine torque is transiently reduced to avert NVH issues related to engine speed overshooting or undershooting the target speed. | 03-03-2016 |
20160090076 | VEHICLE GEAR BOX AND CONTROL SYSTEM - A vehicle gear box includes: a gear shift mechanism including a first engaging device configured to engage/disengage power transmission between an engine and a first input shaft of a first gear position group and a second engaging device configured to engage/disengage power transmission between the engine and a second input shaft of a second gear position group; a differential mechanism configured to connect a rotational shaft of a rotator and the first input shaft and the second input shaft; a third engaging device configured to engage/disengage power transmission between the engine and the first engaging device and the second engaging device; and a control system configured to control the third engaging device and the rotator to perform control that switches the third engaging device to be in a disengaged state and drives the vehicle by the rotary power output from the rotator. | 03-31-2016 |
20160096522 | POWERSPLIT HYBRID POWERTRAIN WITH OVERDRIVE CLUTCH - A hybrid vehicle powertrain includes an internal combustion engine, first and second electric machines, traction wheels, and an output shaft having meshing gears configured to establish a final drive ratio between the output shaft and the traction wheels. The powertrain additionally includes a first mechanical linkage and a second mechanical linkage. The first mechanical linkage is configured to selectively transmit engine torque to the fraction wheels and selectively transmit electric machine torque to the traction wheels. The second mechanical linkage is configured to selectively transmit engine torque to the traction wheels. When transmitting engine torque to the wheels, the second mechanical linkage defines a fixed overdrive speed relationship between the engine and the fraction wheels. | 04-07-2016 |
20160101769 | CONTROLLING A CLUTCH BETWEEN AN ENGINE AND AN ELECTRIC MACHINE IN A HYBRID VEHICLE - A parallel hybrid vehicle includes an engine and a motor separated along a driveshaft by a clutch. The motor can operate (either alone or in combination with the engine) to provide positive drive torque to the wheels. The motor can also act as a generator and provide negative torque when converting mechanical energy from the driveshaft into mechanical energy to be stored in a battery. The clutch selectively couples the motor to the engine. Torque and its effects on the clutch can vary dramatically when the motor changes from providing positive and negative torque, and vice versa, while the engine is running. At least one controller in the vehicle is programmed to, while the engine is running, initiate an increase in pressure at the clutch in response to an anticipated change in torque provided by the motor from positive to negative or from negative to positive. | 04-14-2016 |
20160107638 | HYBRID VEHICLE HAVING INTERACTIVE MANUAL TRANSMISSION AND CONTROL METHOD THEREFOR - A hybrid vehicle includes: an engine; a driving motor/generator connected to an output shaft of the engine; a connection unit disposed between the engine and the driving motor/generator to separate the engine from the driving motor/generator when the engine is stopped and to connect the engine to the driving motor/generator when the engine is operated; a manual transmission connected to the driving motor/generator, for directly varying gear ratio without using an engine clutch according to a driving speed and a torque generated by the driving motor/generator and/or the engine; a position sensor for detecting a position of a manual gearshift lever; and a central control unit connected to the engine, the driving motor/generator, the connection unit, and the manual transmission. In order to perform a gearshift of the manual transmission, the central control unit separates the connection unit disposed between the engine and the driving motor/generator when the vehicle is stopped or driven at a preset speed or lower or connects the connection unit when the vehicle is driven at the preset speed or higher, and controls the driving motor/generator and/or the engine according to the detected position of the manual gearshift lever to adjust a speed of an input shaft of the manual transmission. | 04-21-2016 |
20160121877 | Stall-Start Method and Apparatus for a Parallel Hybrid Vehicle - The application relates to a method for stall-starting a hybrid vehicle comprising a combustion engine ( | 05-05-2016 |
20160121880 | SYNCHRONIZATION CONTROL METHOD FOR ENGINE CLUTCH LOCK-UP IN HYBRID ELECTRIC VEHICLE - A control method for synchronization of engine speed and motor speed when lock-up of an engine clutch of a hybrid electric vehicle is carried out. The synchronization control method includes increasing engine speed by controlling toward motor speed as a target speed when synchronization starts according to a demand for the lock-up of an engine clutch during travelling of the hybrid electric vehicle using motor driving power while the engine clutch is opened; estimating an engine speed at a time of speed change when the motor speed increases and reaches a preset changed speed at which a speed change is carried out; calculating motor speed after the speed change using the changed speed and information on gear ratio before and after the changed speed when the estimated engine speed at the time of speed change is less than the preset changed speed; and controlling the engine speed by changing the target speed into the motor speed after the speed change. | 05-05-2016 |
20160137188 | Control systems and methods for transmission of hybrid power vehicle - A transmission control system for a hybrid-power driving system includes at least a gear shifting actuation module to control engagement of specific gearwheels and a clutch actuation module to control a clutch that couples an engine to the transmission. Gear shifts are required for each of the engine and the electric motor in the hybrid-power driving system. The control system minimizes power loss when a gear shift is occurring for the engine or the electric motor. By selectively controlling the clutch and engagement of specific gearwheels, power loss associated with a gear shift for one of these power sources can be directly offset by using the other power source. | 05-19-2016 |
20160137189 | Control systems and methods for transmission of hybrid power vehicle - A transmission control system for a hybrid-power driving system includes at least a gear shifting actuation module to control engagement of specific gearwheels and a clutch actuation module to control a clutch that couples an engine to the transmission. Gear shifts are required for each of the engine and the electric motor in the hybrid-power driving system. By selectively controlling the clutch and engagement of specific gearwheels, the transmission control system can start the engine when the vehicle is initially powered by the electric motor alone. Starting the internal combustion engine in this case switches the vehicle from a pure motor driving mode to a hybrid driving mode. Additionally, the transmission control system can start the engine when the vehicle is in a parked state, for example, to put the vehicle in a battery charging mode for the electric motor. | 05-19-2016 |
20160159343 | CONTROL SYSTEM FOR HYBRID VEHICLE - A control system of a hybrid vehicle, in which a driving power source for travel includes an engine that is started by cranking, a motor that can control a torque, and a clutch that is coupled with the motor and in which a transmission torque capacity continuously changes depending on a change of a control amount is configured to estimate a torque of the clutch based on the torque that the motor outputs, and change rates of the rotational speed of the motor and the clutch caused by changing the control amount, when the torque that the motor outputs is transmitted by the clutch that is in a slip state by changing the control amount. | 06-09-2016 |
20160167638 | Dynamic Deceleration Control for Hybrid Vehicle to Achieve a Consistent Overrun Response | 06-16-2016 |
20160375890 | DRIVE CONTROL APPARATUS - A drive control apparatus includes a motor control unit and a gear shift control unit, and controls a power transmission system including first and second motors and a gear shift mechanism. When the gear shift mechanism is changed from a first gear stage to a second gear stage during deceleration of the vehicle, the motor control unit controls the first motor to be at a target rotation speed determined based on a gear ratio of a second power transmission gear and a rotation speed of an output shaft, and controls a second motor such that required brake torque is generated by the second motor. The gear shift control unit controls the gear shift mechanism so as to be in a neutral state in which power is not transmitted between an input shaft and the output shaft, until a rotation speed of the first motor becomes the target rotation speed. | 12-29-2016 |
20160375891 | Method and Apparatus for Starting an Engine in a Hybrid Vehicle - A method and apparatus for starting an engine in a hybrid vehicle being driven by an electric motor is disclosed. The motor is operably configured to deliver mechanical power through an automatic transmission to at least one vehicle drive wheel to cause an acceleration of the vehicle. The method involves coupling the engine to the motor to cause an inertial load on the motor thus causing the motor to decelerate to a reduced rotational speed to provide a starting torque to the engine for starting the engine, and causing the automatic transmission to change gear ratio to a target gear ratio associated with the reduced rotational speed while causing the motor to decelerate, the motor being operable to deliver increased torque at the reduced rotational speed, thereby generally maintaining the acceleration of the vehicle. | 12-29-2016 |
20170232955 | METHOD AND SYSTEM FOR CONTROLLING CATALYST TEMPERATURE | 08-17-2017 |
20180022355 | HYBRID VEHICLE | 01-25-2018 |