Patent application number | Description | Published |
20080257619 | System and method of inhibiting the affects of driveline backlash in a hybrid propulsion system - A hybrid electric vehicle is provided. The hybrid electric vehicle includes an internal combustion engine, a mechanical torque transmission device for transmitting engine torque to at least one wheel, the mechanical torque transmission device having a lash region, an electric energy conversion device connected downstream of the mechanical torque transmission device, and a control system. The control system, adjusts the electric energy conversion device to meet a desired vehicle response, adjusts the internal combustion engine torque to transition through the lash region, and then adjusts the electric energy conversion device torque and the internal combustion engine torque to meet the desired vehicle response. | 10-23-2008 |
20080314663 | System and Method of Extending Regenerative Braking in a Hybrid Electric Vehicle - A method of generating brake force to decelerate a vehicle is provided. The vehicle includes an internal combustion engine coupled to an input of a first electric energy device, the first electric energy device having an output coupled to a transmission device, and a second electric energy conversion device coupled downstream of the transmission device, the first and second electric energy conversion devices being powered at least by a battery. The method includes during a deceleration condition, generating brake torque via the second electric energy conversion device to generate electric energy storable in the battery; and rotating the internal combustion engine via torque output from the first electric energy device to deplete electric energy from the battery. | 12-25-2008 |
20120265382 | Torque Modulation in a Hybrid Vehicle Downshift During Regenerative Braking - A controller and a control strategy minimizes shift shock in a hybrid electric vehicle during a downshift conducted while the vehicle is in a regenerative braking mode by maintaining total powertrain torque at a desired target during the downshift. The controller has three preferable modes including modulating just engine torque, modulating just electric motor torque or simultaneously modulating both motor and engine torque. | 10-18-2012 |
20130158756 | Hybrid Vehicle Drive Control System and Method for Providing Motor Torque Boost Compensating for Engine Delay and Torque Exceeding Maximum Engine Torque - A vehicle control system including a combustion engine and an electric motor selectively provided torque to a transmission separately or in combination to meet driver torque demand. The engine has a maximum torque output value and a torque increase delay response function spanning a predetermined time period. A motor torque boost signal requests an increase in torque provided from an electric motor if the engine torque request signal exceeds the maximum torque output of the engine or the torque increase delay response function of the engine. The motor torque boost signal is time limited and a second level of motor torque boost may be provided for a second limited time period. | 06-20-2013 |
20130179014 | ENERGY MANAGEMENT CONTROL SYSTEM - A system and method for controlling energy distribution within a HEV powertrain are provided. A feedforward battery power value is generated in response to input indicative of a driver torque request. A feedback battery power modification value is generated in response to input indicative of actual battery power and the driver torque request. A battery power request is calculated based a sum of the feedforward battery power value and the feedback battery power modification value. | 07-11-2013 |
20130244829 | Transmission Control During Regenerative Braking - A system and method for controlling a hybrid electric vehicle during regenerative braking is provided. The system and method include a brake controller adapted to cause, for a selected transmission gear, a first torque ratio to be applied to a regenerative brake system during regenerative braking and a second torque ratio, different from the first torque ratio, to be applied when the vehicle is not regenerative braking. The first torque ratio results in an increased braking torque generated by the regenerative brake system compared with application of the second torque ratio. | 09-19-2013 |
20130274969 | Feed Forward and Feedback Adjustment of Motor Torque During Clutch Engagement - A hybrid electric vehicle having a motor and an engine that are selectively connected on a driveline and controlled by a controller. The controller is configured to schedule additional motor torque to compensate for engine inertia drag based upon a clutch pressure value and a clutch slip speed value during a period of clutch engagement. The controller is also configured to maintain vehicle acceleration using a proportional integral controller to adjust the motor torque during a period of clutch engagement. | 10-17-2013 |
20130296100 | Controlled Regenerative Braking Torque Incrementing in Hybrid Vehicle Downshift - A controller and control strategies minimize shift shock in a hybrid electric vehicle during a downshift during regenerative braking by maintaining the transmission input speed substantially linear when the transmission input speed is slowing. The controller and the control strategies control the regenerative braking torque during a downshift occurring during regenerative braking in such a way that the transmission input speed is maintained substantially linear when the transmission input speed is slowing during a torque phase of the downshift. | 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 |
20130297105 | ENGINE START FOR A HYBRID ELECTRIC 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 start the engine using one of a plurality of start sequences that control the electric machine, the upstream and downstream clutches. The engine start sequence is selected based on transmission gearbox input speed and a driver demand input. A method of controlling a hybrid vehicle is provided. An engine is selectively coupled to an electric machine by an upstream clutch with the electric machine selectively coupled to a transmission gearbox by a downstream clutch. The engine is started using a control sequence to control the electric machine, upstream clutch, and downstream clutch. The control sequence is determined by a vehicle state based on transmission gearbox input speed and a driver demand input. | 11-07-2013 |
20130297106 | HYBRID VEHICLE CONTROL UTILIZING GRADE DATA - A method of controlling a hybrid vehicle having a step ratio transmission is disclosed. The method utilizes terrain data to reduce the number of shift events. The method comprises receiving data indicative of a grade profile of an anticipated route, identifying a forecast shift sequence comprising a forecast downshift event and an adjacent forecast upshift event, and adjusting the shift criteria based on the time between the forecast shift events, the road grade between the forecast shift events, and the state of a storage battery. | 11-07-2013 |
20130297108 | CONTROLLING A POWERTRAIN AND A CLUTCH OF A VEHICLE - A vehicle includes an engine and is at least partially propelled by a fraction battery and a traction motor. A clutch is configured to be coupled to the traction motor. An electrical and/or mechanical pump provides pressure to control the clutch. At least one controller determines if the clutch is slipping. In response to the clutch slipping, the at least one controller commands an increase in speed of an input of the clutch such that the available line pressure to control the slipping of the clutch is increased. The line pressure is then applied to the clutch in order to control the slipping of the clutch. | 11-07-2013 |
20130297111 | DRIVELINE LASH CONTROL METHOD DURING DRIVER TIP-IN/OUT - A hybrid electric vehicle has a traction motor, a driveline connected to a vehicle wheel, and a controller. The controller is configured to control motor torque through a region surrounding vehicle wheel torque reversal, control driveline input torque during torque reversal of driveline output torque to limit rate of change of driveline output torque, and control motor torque during a torque reversal of at least one driveline component to limit rate of change of the torque applied to the driveline component. A method for controlling a vehicle having a traction motor includes controlling the traction motor torque through a region surrounding a vehicle wheel torque reversal, controlling driveline input torque during torque reversal of driveline output torque to limit rate of change of output torque, and controlling traction motor torque during a torque reversal of a powertrain component to limit rate of change of the torque applied to the component. | 11-07-2013 |
20130297112 | METHODS AND SYSTEMS FOR A HYBRID VEHICLE - Systems and methods for learning torque estimate errors and updating torque estimation models are presented. In one example, torque errors are learned during an engine shut-down, after a disconnect clutch coupled between an engine and an electric machine has been released. An updated torque estimation model is then used to control torque during subsequent engine operation to improve drive feel and vehicle performance. | 11-07-2013 |
20130297113 | METHODS AND SYSTEMS FOR A HYBRID VEHICLE - Systems and methods for learning torque estimate errors and updating torque estimation models are presented. In one example, torque errors are learned during an engine shut-down, after a disconnect clutch coupled between an engine and an electric machine has been released. An updated torque estimation model is then used to control torque during subsequent engine operation to improve drive feel and vehicle performance. | 11-07-2013 |
20130297125 | TORQUE FILLING AND TORQUE COORDINATION DURING TRANSIENTS IN A HYBRID VEHICLE - A system and method for controlling a vehicle powertrain is provided. The system and method sets a required transmission input torque during a transient event. A required traction motor torque and a required engine torque, in combination, are set to fulfill the required transmission input torque. The system and method includes estimates an actual engine torque during a delay in providing the required engine torque during the transient event. A transient traction motor torque is commanded based on a difference between the actual engine torque and the required transmission input torque. The commanded transient motor torque compensates for the delay in providing the required engine torque in order to prevent torque disturbances during the transient event. | 11-07-2013 |
20130297126 | OPPORTUNISTIC CHARGING OF HYBRID VEHICLE BATTERY - A control system for a modular hybrid electric vehicle operates an internal combustion engine at a torque level above the driver demanded torque improving the engine's efficiency. A traction motor driveably connected to the engine is operated at a torque level such that the combined torque satisfies the driver demand. The traction motor torque is limited to avoid inefficient combinations of speed and torque at which the motor is inefficient. During idle operation, the traction motor is operated at a torque determined from a battery state of charge and the engine is operated to maintain a predetermined speed. If the engine speed drops below a threshold, motor torque is adjusted to reduce the load on the engine to avoid stalling. | 11-07-2013 |
20130331230 | TRANSMISSION CONTROL DURING REGENERATIVE BRAKING - A system and method for controlling a hybrid electric vehicle during regenerative braking is provided. The system and method include a brake controller adapted to cause, for a selected transmission gear, a first torque ratio to be applied to a regenerative brake system during regenerative braking and a second torque ratio, different from the first torque ratio, to be applied when the vehicle is not regenerative braking. The first torque ratio results in an increased braking torque generated by the regenerative brake system compared with application of the second torque ratio. | 12-12-2013 |
20140004997 | Active Damping During Clutch Engagement for Engine Start | 01-02-2014 |
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 |
20140148309 | Method and Apparatus for Reducing Torque During a Transmission Upshift for a Hybrid Vehicle - A hybrid vehicle powertrain that has an engine and an electric machine that may separately or jointly provide torque to a multi-speed transmission. A drivetrain including the engine and the motor is controlled to reduce the requested level of torque provided to the transmission during an upshift. The method is initiated by a request for a reduction of the level of torque and checking the operating state of the engine. If the engine is not on, the torque from the motor is reduced. If the engine is on, the torque from the motor is reduced first and then the torque from the engine is reduced to the requested level of torque. | 05-29-2014 |
20140200794 | METHODS AND SYSTEMS FOR A HYBRID VEHICLE - Systems and methods for learning torque estimate errors and updating torque estimation models are presented. In one example, torque errors are learned during an engine shut-down, after a disconnect clutch coupled between an engine and an electric machine has been released. An updated torque estimation model is then used to control torque during subsequent engine operation to improve drive feel and vehicle performance. | 07-17-2014 |
20140222273 | METHODS AND SYSTEMS FOR A HYBRID VEHICLE - Systems and methods for learning torque estimate errors and updating torque estimation models are presented. In one example, torque errors are learned during an engine shut-down, after a disconnect clutch coupled between an engine and an electric machine has been released. An updated torque estimation model is then used to control torque during subsequent engine operation to improve drive feel and vehicle performance. | 08-07-2014 |
20140343756 | METHOD AND APPARATUS FOR DRIVELINE SOFTENING UTILIZING A VEHICLE TO CLOUD TO VEHICLE SYSTEM - A vehicle includes a power source, such as an engine, an electric machine, or combination thereof. A torque converter is selectively coupled to the power source such that torque is altered before being distributed into a transmission of the vehicle. A torque converter bypass clutch enables torque from the power source to selectively transmit torque directly to the transmission with little or no torque altering provided by the torque converter. At least one controller in the vehicle is in communication with a remote facility in a vehicle-to-cloud (V2C) system. The controller sends road condition data to the remote facility regarding a road segment. During a subsequent drive to or over the road segment, the controller receives the road condition data and enables the torque converter bypass clutch to slip to dampen driveline disturbances when the vehicle passes over the road segment. | 11-20-2014 |
20150025724 | METHODS AND SYSTEMS FOR RESTARTING AN ENGINE - Systems and methods for improving operation of a hybrid vehicle are presented. In one example, torque output of a motor is controlled to include a reserve torque for starting an engine that may be selectively coupled to the motor. Additionally, the motor torque compensates for disconnect clutch closing. | 01-22-2015 |
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 |
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 |
20150112522 | Hybrid-Electric Vehicle Plug-Out Mode Energy Management - A vehicle includes an engine, an electric machine, a battery, and at least one controller. The vehicle may further comprise a port for supplying power to a load external to the vehicle. The controller is programmed to operate the engine at a power level based on a difference between a battery voltage and a reference voltage such that a power output by the electric machine reduces the difference. The power level may define an engine operating point that minimizes fuel consumption. The operating point may be an engine torque and an engine speed. The power level may be further based on a state of charge of the battery. The electric machine may be operated to cause the engine to rotate at an engine speed corresponding to the selected power level. The difference may be caused by varying power drawn by a load external to the vehicle. | 04-23-2015 |
20150112523 | HYBRID VEHICLE ENGINE START - A vehicle includes an engine having a crankshaft, a transmission having an input, and an electric machine mechanically coupled to the transmission input. The vehicle further includes a clutch configured to mechanically couple the electric machine and engine crankshaft, and at least one controller. The at least one controller, in response to an engine start condition and subsequent partial engagement of the clutch, outputs a torque command for the electric machine to increase the speed of the crankshaft to a speed of the electric machine before commanding fuel injection of the engine. The torque command is based on driver demanded torque and a change in speed of the crankshaft caused by changes in pressure to the clutch. | 04-23-2015 |
20150112524 | HYBRID VEHICLE ENGINE STARTS - A vehicle includes a starter motor, an engine having an output mechanically coupled to the starter motor, a transmission having an input, and an electric machine mechanically coupled to the transmission input. The vehicle further includes a clutch configured to mechanically couple the electric machine and the output of the engine, and at least one controller. The at least one controller is programmed to initiate an engine start based on driver demand. The controller is further configured to enable pressure to the clutch for the engine start if driver demand is less than a calibratable torque value or enable the starter motor for the engine start if the driver demand is greater than a calibratable torque value. The controller may lock the clutch to the output of the engine in response to the speed of the engine being approximately equal to the speed of the electric machine. | 04-23-2015 |
20150112525 | HYBRID VEHICLE POWERTRAIN MANAGEMENT SYSTEM AND METHOD - A vehicle is provided with a powertrain including an electric motor, an internal combustion engine, and a turbocharger. The vehicle further includes a controller programmed to apply a variable filter to engine torque commands that are responsive to driver demand. The filter affects commands having a rate of increase greater than a predetermined threshold such that corresponding rates of increase in both engine torque and turbocharger speed are limited to respective rates less than the maximum available levels in order to reduce a surge in engine output emissions. The controller additionally issues commands for motor torque such that overall powertrain torque satisfies the driver demand. | 04-23-2015 |
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 |
20150134159 | SYSTEM FOR CONTROLLING OVERALL COASTING TORQUE IN A HYBRID ELECTRIC VEHICLE - A hybrid vehicle is provided that includes an engine, a reversible electric machine capable of generating and providing electric power, and a clutch for selectively engaging the engine to the electric machine. While the vehicle is traveling, an operator of the vehicle may release (“tip-out”) the accelerator pedal, indicating a desire for a reduction in speed and/or acceleration of the vehicle. If the clutch is engaged during the tip-out, the at least one controller is programmed to disengage the clutch and alter a commanded torque to the electric machine in response to the tip-out of the accelerator pedal to simulate compression braking of the engine. If the vehicle is operating in an electric-only mode of propulsion during the tip-out, and if a state-of-charge of the battery is relatively high, the controller is programmed to activate the engine and provide compression torque to the driveline in response to the tip-out. | 05-14-2015 |
20150134160 | METHOD AND SYSTEM FOR SELECTING AN ENGINE OPERATING POINT FOR A HYBRID VEHICLE - A vehicle includes a powertrain having an engine and an electric machine (M/G) connected by an upstream clutch, and a gearbox connected to the M/G by a torque converter. A controller is configured to, in response to a Park or Neutral gear selection and an electrical power request from the M/G, operate the engine at an engine speed and an engine torque based on the request and M/G speed and torque for improved powertrain efficiency. A method is provided for controlling a vehicle. In response to a Park or Neutral gear selection and an electrical power request from the M/G, the engine is operated at an engine speed and an engine torque based on the request and M/G speed and torque for improved powertrain efficiency. | 05-14-2015 |
20150134161 | LOAD-BASED VEHICLE OPERATING CONTROL - A hybrid electric vehicle includes an engine and an electric machine, both capable of providing propulsion power. A clutch is configured to selectively couple the engine to the electric machine. At times, the vehicle may be subject to excessive loads, such as a large amount of weight in the vehicle or the vehicle towing another object. At least one controller is programmed to engage the clutch and start the engine in response to a load of the vehicle exceeding a predetermined threshold and a release of the brake pedal while the vehicle is stopped and in drive. This increases available engine torque prior to vehicle launch in anticipation of an upcoming acceleration demand. | 05-14-2015 |
20150134162 | LOAD-BASED VEHICLE OPERATING CONTROL - A hybrid vehicle includes an engine and an electric machine, both capable of propelling the vehicle. The electric machine is electrically connected to a high voltage traction battery. The state of charge of the battery can decrease if the battery is used to power the electric machine, and can increase if the electric machine supplies power to the battery via regenerative braking. Constraints are placed on the vehicle such that the battery operates within a preferred operating window, defined between minimum and maximum state of charge thresholds. At least one controller is programmed to alter the preferred operating window of the battery in response to various vehicular activities, such as when the vehicle is towing another object, or when the vehicle weighs above a certain threshold due to contents within the vehicle, for example. | 05-14-2015 |
20150197240 | 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 traction motor and the inverter. | 07-16-2015 |
20150197242 | HYBRID VEHICLE TRANSMISSION SHIFT MANAGEMENT SYSTEM AND METHOD - A vehicle is provided with a powertrain including a battery-powered electric motor, an internal combustion engine, a transmission, and a powertrain controller. The controller is programmed to permit an upshift of a transmission gear ratio while a powertrain torque demand is less than a forecasted available powertrain torque sustainable over a predetermined upcoming duration of time. The controller is also programmed to inhibit an upshift while the torque demand exceeds the forecasted available powertrain torque to reduce successive gear shifts. The controller may be further programmed to, in response to battery a state of charge being less than a threshold, reduce the forecasted available powertrain torque by an amount sufficient to provide a recharge to a battery. The controller may be further still programmed to reduce the forecasted available powertrain torque by an amount sufficient to restart the engine while the powertrain is operating in an engine-off traction mode. | 07-16-2015 |
20150197243 | PREDICTIVE ENGINE PULL UP AND PULL DOWN IN HYBRID VEHICLE - A system and method for controlling a hybrid vehicle having an engine configured to automatically stop in response to an engine stop request and automatically start in response to an engine start request include selectively inhibiting an engine stop request based on an anticipated duration of an expected decreased driver power command state to reduce occurrence of successive automatic stops and automatic starts. | 07-16-2015 |
20150198243 | SYSTEMS AND METHODS FOR DRIVELINE TORQUE CONTROL - Systems and methods for improving operation of a hybrid vehicle are presented. In one example, a difference between estimated torque output of an active torque source in a driveline and actual torque output of the active torque source is mitigated via entering a driveline speed control mode. The methods and systems may be useful when switching between different driveline modes of operation. | 07-16-2015 |
20150203091 | POWERTRAIN CONTROL OF A HYBRID VEHICLE IN PARK OR NEUTRAL - A hybrid vehicle includes an engine and an electric machine selectively coupled to the engine via a clutch. The engine, electric machine, and clutch are arranged along a common axis. At least one controller is programmed to execute various commands when the vehicle is in park or neutral and the accelerator pedal of the vehicle is depressed. This enhances perceived vehicle reactions in response to accelerator pedal movement. To do so, the controller is programmed to control a rate of speed increase of the electric machine based on a rate of the depression of the accelerator pedal (e.g., “speed control”). Furthermore, the torque output of the engine is controlled to a target value irrespective of engine speed and engine torque is converted into electric energy via the electric machine (e.g., “torque control”). The rate of speed increase of the electric machine is altered when the engine is started. | 07-23-2015 |
20150203092 | TORQUE BASED ENERGY MANAGEMENT IN HYBRID VEHICLE - A system and method for controlling a powertrain in a hybrid vehicle having an engine and a traction motor include commanding the engine to provide an engine torque corresponding with a desired performance characteristic at a current engine speed. The method additionally includes commanding the motor to provide a motor torque to compensate a difference between an operator torque request and the engine torque. | 07-23-2015 |
20150203105 | ENGINE TORQUE IMBALANCE COMPENSATION IN HYBRID VEHICLE - A system and method for controlling a fraction motor in a hybrid vehicle includes varying a traction motor torque in response to an engine cylinder misfire. The traction motor torque is varied to compensate for an engine torque shortfall due to the engine cylinder misfire, reducing a torque imbalance caused by the misfire. | 07-23-2015 |
20150224976 | CANCELLING CREEP TORQUE IN A HYBRID VEHICLE - A hybrid vehicle includes an engine and an electric machine, both capable of propelling the vehicle. The electric machine provides creep torque to propel the vehicle at a slow speed or hold the vehicle when on an incline. At least one controller is programmed to cancel or otherwise inhibit the electric machine from generating the creep torque in response to a brake torque or brake torque request exceeding a calibratible threshold. The calibratible threshold varies based upon vehicle incline, vehicle mass, and/or vehicle speed. | 08-13-2015 |
20150239467 | HYBRID ELECTRIC VEHICLE AND METHOD OF STARTING ENGINE - Two methods may be used to start the engine of a hybrid electric vehicle while the vehicle is moving under electric power. When smoothness is most important, a disconnect clutch is partially engaged to initiate engine rotation and then released as the engine accelerates under its own power toward a motor speed. When rapid starting is most important, the disconnect clutch torque capacity is controlled to decrease the time required for the engine to accelerates to the motor speed. A torque converter bypass clutch is disengaged during the engine restart under either method. Also, the motor torque is adjusted under either method to compensate for the torque provided to the engine. | 08-27-2015 |
20150251649 | ACTIVE MOTOR DAMPING CONTROL OF A HYBRID ELECTRIC VEHICLE POWERTRAIN - A hybrid electric vehicle includes an engine and an electric motor both configured to generate a vehicle powertrain torque and a controller programmed to control the powertrain torque for a limited duration in anticipation of a powertrain torque variation scenario using a damping function, wherein the damping function adjusts the vehicle powertrain torque based on a difference between a measured motor speed and a desired motor speed using the electric motor to counteract a powertrain speed oscillation. | 09-10-2015 |
20150251657 | SYSTEM AND METHOD FOR MANAGING HYBRID VEHICLE REGENERATIVE BRAKING - A vehicle includes a powertrain having an electric machine configured to selectively apply regenerative braking torque to decelerate the vehicle. The vehicle also includes a controller programmed to control a rate of change of a regenerative braking torque limit during a transmission downshift that occurs during a regenerative braking event based on a change in speed of an output shaft of the powertrain caused by the transmission downshift. | 09-10-2015 |
20150266462 | SYSTEM AND METHOD FOR DETERMINING ENGINE DISCONNECT CLUTCH TORQUE - A system and method for estimating disconnect clutch torque during engine start with the motor in vehicles having an engine selectively coupled to the motor and transmission may be configured to control motor torque based on a clutch torque estimated from a difference in a measured powertrain state and a predicted powertrain state using motor torque as an input. The powertrain states may include, for example, motor speed, turbine speed, engine speed and clutch torque. An adaptive gain may be used to drive the difference between measured and estimated clutch torque toward zero. | 09-24-2015 |
20150266466 | Method and System for Adaptive Motor Power Loss Estimation in Hybrid Electric Vehicles - A control strategy for a hybrid electric vehicle powertrain having an engine, a motor, and a transmission includes operating the powertrain according to a motor power loss term that is adapted based on battery power supplied to the motor, motor power output, and an estimated motor power loss such that the motor power loss term changes over time and converges to a constant value to thereby be indicative of actual motor power loss. | 09-24-2015 |
20150267808 | METHOD AND APPARATUS FOR DRIVELINE SOFTENING IN A VEHICLE - A vehicle includes a power source, such as an engine, an electric machine, or combination thereof. A torque converter is selectively coupled to the power source such that drive torque can be altered before being distributed into a transmission of the vehicle. A torque converter bypass clutch enables torque from the power source to selectively transmit directly to the transmission with little or no torque altering provided by the torque converter. At least one controller in the vehicle is in communication with a storage device. The controller sends road condition data to the storage device regarding a road segment. During a subsequent drive to or over the road segment, the controller receives the road condition data and enables the torque converter bypass clutch to slip to dampen driveline disturbances when the vehicle passes over the road segment. | 09-24-2015 |
20150283996 | STEP-RATIO TRANSMISSION CONTROL FOR A HYBRID VEHICLE - A parallel hybrid electric vehicle discrete step-ratio automatic transmission shift strategy attempts to cause a speed of a motor to approach a target motor speed to increase fuel economy for a coupled engine when in hybrid mode. A controller shifts the transmission according to a magnitude of a driver torque demand, the current rotor or impeller speed, and whether the motor is consuming or producing current. | 10-08-2015 |
20150283997 | HYBRID VEHICLE ENGINE STARTS - A vehicle includes a starter motor, an engine having an output mechanically coupled to the starter motor, a transmission having an input, and an electric machine mechanically coupled to the transmission input. The vehicle further includes a clutch configured to mechanically couple the electric machine and the output of the engine, and at least one controller. The at least one controller is programmed to initiate an engine start based on driver demand. The controller is further configured to enable pressure to the clutch for the engine start if driver demand is less than a calibratable torque value or enable the starter motor for the engine start if the driver demand is greater than a calibratable torque value. The controller may lock the clutch to the output of the engine in response to the speed of the engine being approximately equal to the speed of the electric machine. | 10-08-2015 |