Patent application number | Description | Published |
20080196683 | HIGH PERFORMANCE OVERHEAD VALVETRAIN ASSEMBLY - A high performance overhead valvetrain assembly includes a hydraulic lash adjuster which is received within and supports a trunnion. The trunnion, in turn, is received within a cylindrical passageway in one end of a rocker arm. The opposite end of the rocker arm engages a valve stem. Between the trunnion and the valve stem is a roller adapted the engage a cam of a camshaft. The trunnion stabilized rocker arm permits significantly increased valve lift and improved engine performance. | 08-21-2008 |
20090159028 | HYDRAULICALLY LASHED END PIVOT ROCKER ARM - A hydraulically lashed end pivot rocker arm assembly finds application in high performance valve trains of internal combustion engines. The rocker arm is mounted at one end upon an eccentric bearing assembly and includes a surface for engaging a valve stem at the opposite end and a roller engaged by a camshaft disposed between the ends. The eccentric bearing assembly includes a stub shaft or cylindrical body that is received within a bore in the rocker arm and an eccentric bore which receives an inner shaft which extends along the cylinder head and supports the eccentric bearings and the rocker arm assemblies. The stub shaft or cylindrical body includes an ear or lug which is engaged by a hydraulic lash adjuster disposed parallel to and offset from the vertical plane of motion of the rocker arm. | 06-25-2009 |
20090211552 | DRY SUMP OIL TANK ASSEMBLY FOR A VEHICLE - A dry sump oil tank assembly for a vehicle is provided with a housing defining an internal cavity. The housing is configured with a laterally-extending portion to add lateral volume to the internal cavity and has at least one internal baffle attached to the housing within the internal cavity below the laterally-extending portion and configured to reduce sloshing of oil within the cavity. The dry sump oil tank assembly is particularly useful for high performance applications, such as racing vehicles, and may utilize components from standard vehicle applications, thus maximizing the economies of scale of producing such components and being suited for a vehicle that may be typically used in standard driving conditions, but occasionally subjected to high performance use. | 08-27-2009 |
20100224155 | CAMSHAFT DAMPING MECHANISM AND METHOD OF ASSEMBLY - A camshaft damping mechanism may include first and second housing members and a biasing member. The first housing member may be engaged with a camshaft. The second housing member may be slidably coupled to the first housing member and may abut an engine structure. The biasing member may be retained axially between the first and second housing members and may force the first housing member in an outward axial direction from the second housing member. | 09-09-2010 |
20100269773 | VALVETRAIN FOR OVERHEAD VALVE ENGINE - An engine assembly may include an engine structure, a camshaft rotationally supported within the engine structure and including a lobe, a first rocker arm, a valve lift mechanism, a valve, and a second rocker arm. The first rocker arm may include a first end rotationally coupled relative to the engine structure and a second end defining a cam engagement surface engaged with the lobe and a convex lift surface opposite the cam engagement surface. The valve lift mechanism may have a first end engaged with the lift surface of the first rocker arm. The second rocker arm may be supported relative to the engine structure and engaged with a second end of the valve lift mechanism and the valve to selectively open the valve based on displacement of the lift mechanism by the first rocker arm. | 10-28-2010 |
20110067660 | ENGINE ROCKER ARM - A rocker arm may include a valve engagement region, a lift mechanism engagement region, a pivot region, and a body portion. The valve engagement region may be located at a first longitudinal end of the rocker arm and on a first side of the rocker arm. The lift mechanism engagement region may be located at a second longitudinal end of the rocker arm. The pivot region may be located between the valve engagement region and the lift mechanism engagement region and may define a rotational axis for the rocker arm. The body portion may extend longitudinally between and couple the valve engagement region, the pivot region and the lift mechanism engagement region to one another. The body portion may define first and second ribs on a second side of the rocker arm that extend longitudinally between the valve engagement region and the lift mechanism engagement region. | 03-24-2011 |
20110083639 | CYLINDER DEACTIVATION TO REDUCE FUEL ENRICHMENT AFTER FUEL CUTOFF MODES - A system includes a fuel cutoff module and a cylinder deactivation module. The fuel cutoff module generates a fuel cutoff signal when a deceleration fuel cutoff condition occurs, wherein fueling to M cylinders of an engine is disabled based on the fuel cutoff signal, and wherein M is an integer greater than or equal to one. The cylinder deactivation module deactivates the M cylinders in response to the fuel cutoff signal. | 04-14-2011 |
20120006287 | ENGINE ASSEMBLY WITH INTEGRATED EXHAUST MANIFOLD - An engine assembly may include an engine structure, exhaust valves supported by the engine structure and a camshaft supported by the engine structure and engaged with the exhaust valves. The engine structure may define first, second, third and fourth combustion chambers arranged in series and a plurality of exhaust ports, each in communication with a corresponding combustion chamber. The engine structure may also define a flange region defining a first exhaust gas outlet axially aligned with the second combustion chamber and a second exhaust gas outlet axially aligned with the third combustion chamber. The engine structure may define first and second exhaust passages that extend from the first and second exhaust ports, respectively, to the first exhaust gas outlet and third and fourth exhaust passages that extend from the third and fourth exhaust ports, respectively, to the second exhaust gas outlet. | 01-12-2012 |
20120006295 | ENGINE ASSEMBLY INCLUDING ASYMMETRIC EXHAUST VALVE CONFIGURATION - An engine assembly may include an engine structure, a first valve and a second valve. The engine structure may define a combustion chamber and first and second exhaust ports in communication with the combustion chamber. The first valve may be arranged within the first exhaust port and have a first surface area. The second valve may be arranged within the second exhaust port and have a second surface area greater than the first surface area. | 01-12-2012 |
20120145097 | ENGINE ASSEMBLY INCLUDING CAMSHAFT WITH MULTIMODE LOBE - An engine assembly may include an engine structure, a first valve, a first valve lift mechanism and a first camshaft. The engine structure may define a first combustion chamber and a first port in communication with the first combustion chamber. The first valve may be located in the first port and the first valve lift mechanism may be engaged with the first valve. The first camshaft may be rotationally supported on the engine structure and may include a first double lobe engaged with the first valve lift mechanism. The first double lobe may define a first valve opening region including a first peak and a second valve opening region including a second peak rotationally offset from the first peak. | 06-14-2012 |
20120145103 | ENGINE ASSEMBLY INCLUDING CAMSHAFT WITH INDEPENDENT CAM PHASING - An engine assembly may define first and second combustion chamber and may include a camshaft having a first lobe region engaged with the first valve arrangement and a second lobe region engaged with the second valve arrangement and rotatable relative to the first lobe region. The cam phaser may be coupled to the camshaft and may include a first member and a second member rotatable relative to the first member. The first lobe region may be fixed for rotation with the first member and the second lobe region may be fixed for rotation with the second member to vary valve timing for the second combustion chamber independently from the valve timing of the first combustion chamber. | 06-14-2012 |
20120210958 | ENGINE ASSEMBLY INCLUDING CRANKSHAFT FOR V8 ARRANGEMENT - A crankshaft for a V8 engine includes first, second, third, fourth, fifth, sixth, seventh and eighth crank pins defined on the crankshaft. The second crank pin is rotationally offset from the first crank pin, the third crank pin is rotationally offset from the first and second crank pins, the fourth crank pin is rotationally offset from the first, second and third crank pins, the fifth crank pin is rotationally offset from the first, second, third and fourth crank pins, and the sixth pin is rotationally offset from the first, second, third, fourth and fifth crank pins. The seventh crank pin is rotationally aligned with the first crank pin and the eighth crank pin is rotationally aligned with the second crank pin. | 08-23-2012 |
20120234270 | ENGINE ASSEMBLY INCLUDING CRANKSHAFT FOR V4 ARRANGEMENT - An engine assembly may include an engine structure and a crankshaft. The engine structure may include an engine block defining a first bank of cylinders defining two cylinders and a second bank of cylinders defining two cylinders forming a V4 arrangement. The crankshaft may include a first crank pin, a second crank pin, a third crank pin and a fourth crank. The fourth crank pin may be rotationally offset from the first crank pin by a first angle of less than two hundred and seventy degrees in the rotational direction of the crankshaft. The second and third crank pins may be located rotationally between the first crank pin and the fourth crank pin in the rotational direction. | 09-20-2012 |
20120260897 | Internal Combustion Engine - An internal combustion engine comprises a working cylinder, an EGR cylinder, an intake system for supplying a combustion air charge to the cylinders, a first exhaust system for removing exhaust gas from the working cylinder and to the atmosphere, a second exhaust system for removing exhaust from the EGR cylinder and supplying the exhaust gas through an EGR supply conduit to the intake system, an EGR bypass conduit extending between and fluidly connecting the EGR supply conduit and the first exhaust treatment system, a first valve assembly disposed in the EGR supply conduit between the intake system and an inlet of the EGR bypass conduit and a second valve assembly disposed in the EGR bypass conduit. | 10-18-2012 |
20130146004 | CRANKSHAFT FOR AN INTERNAL COMBUSTION ENGINE - A crankshaft for an internal combustion engine comprises at least four main journals aligned on a crankshaft axis of rotation and at least three crankpins, each disposed about a respective crankpin axis and positioned between the main journals. Each of the respective crankpin axes is oriented parallel to, and spaced radially from, the crankshaft axis of rotation. Each of the crankpins is joined to a pair of crank arms for force transmission between the crankpin and the pair of crank arms. Each pair of crank arms is joined to a respective main journal for transmitting torque between the pair of crank arms and the main journal. At least two of the crankpins are positioned substantially in phase with one another and a third crankpin being positioned approximately 180 degrees apart from the at least two crankpins. | 06-13-2013 |
20140030086 | CENTRIFUGAL PUMP - Embodiments of the disclosure include a centrifugal pump assembly including a pump housing defining a cavity and an impeller disposed within the cavity, the impeller being affixed to a shaft. The pump housing includes an inner surface having a geometric pattern configured in increase a turbulence of a fluid flow over the inner surface. The impeller includes one or more blades and a shroud. The inner surface of the pump housing and the shroud of the impeller define a leakage path. | 01-30-2014 |
20140030099 | PUMP IMPELLER - An impeller, which is rotatable about an axis, includes an inlet shroud and a backing plate. An inlet orifice is defined by the inlet shroud, and a plurality of outlet orifices are radially outward of the inlet orifice. A plurality of vanes are disposed between the inlet shroud and the backing plate. The vanes are formed integrally as one-piece with the inlet shroud. | 01-30-2014 |
20140102429 | INLET MANIFOLD WITH DUAL PORT EGR - An inlet manifold comprises a plenum, a pair of intermediate runners, and two pair of terminal runners. A common EGR passage is in fluid communication with a pair of EGR injectors, each being in fluid communication with a respective intermediate runner. Each intermediate runner receives a split stream of EGR from its respective EGR injector and combines the split stream of EGR with a split stream of inlet air from the plenum to form an EGR-loaded stream. Each intermediate runner is in fluid communication a pair of terminal runners for distributing its EGR-loaded stream among the terminal runners. | 04-17-2014 |
20140109847 | ENGINE ASSEMBLY WITH VARIABLE VALVE DISPLACEMENT ON ONE CYLINDER BANK AND METHOD OF CONTROLLING SAME - An engine assembly includes an engine block having a first bank of cylinders and a second bank of cylinders. A crankshaft is supported by the engine block and is configured to be driven by torque due to combustion energy in the first and second banks of cylinders. A first set of valves is operable to control air flow into and out of the first bank of cylinders. Camshafts driven by the crankshaft are operatively connected to the first set of valves to control opening and closing of the first set of valves. A second set of valves is operable to control air flow into and out of the second bank of cylinders. A controller is operatively connected to the second set of valves and is configured to vary at least one of lift, duration, and timing of the second set of valves based on commanded torque at the crankshaft. | 04-24-2014 |
20140230772 | DUAL PATH SAIR FOR DUAL PLANE INTEGRATED EXHAUST MANIFOLDS - A secondary air injection or SAIR system is illustrated and described which includes a first air injection path defined by in part by a lower ditch formed in the head mounting surface of the cylinder block, and a second air injection path defined in part by a second ditch formed in the block mounting surface. The cylinder head gasket is used to separate and seal the first ditch from the second ditch. The first and second air injection paths are separate and isolated from one another such that secondary air may be selectively introduced through the first air injection path into the first exhaust leg and selective introduced through the second injection path into the second exhaust leg independent of the first air injection path. | 08-21-2014 |
20140283783 | CRANKSHAFT FOR VARIABLE DISPLACEMENT INTERNAL COMBUSTION ENGINE - A crankshaft includes a plurality of crankpins. The crankpins are defined on the crankshaft and are longitudinally spaced apart from each other along a rotational axis. Each of the crankpins is configured to be operatively connected to a piston of an engine including a plurality of cylinders. The engine is configured to deactivate one of the cylinders. At least two of the crankpins are substantially aligned with each other along a pin axis. At least one of the crankpins is rotationally offset from the pin axis in a rotational direction of the crankshaft such that the engine has an even firing order even when one of the cylinders is deactivated. | 09-25-2014 |
20140360459 | Reduced Torque Variation for Engines with Active Fuel Management - In one exemplary embodiment, a method for active fuel management in an engine having a plurality of cylinders is provided, the method including stopping a fuel flow into a first set of the plurality of cylinders, the stopping causing a deactivation of the first set of cylinders and continuing injection of fuel into a second set of the plurality of cylinders to provide power while the first set of cylinders are deactivated. The method also includes injecting gas into the first set of the plurality of cylinders when each of the first set of cylinders are at bottom dead center, the injected gas increasing a cylinder pressure in each of the first set of cylinders that reduces an amplitude of first order torque variations during operation of the engine while the first set of cylinders are deactivated. | 12-11-2014 |
20150013651 | Dedicated EGR Engine with Dynamic Load Control - An internal combustion engine comprises a first engine bank and a second engine bank. A first intake valve is disposed in an intake port of a cylinder of the first engine bank, and is configured for metering the first flow of combustion air by periodically opening and closing according to a first intake valve lift and duration characteristic. A variable valve train control mechanism is configured for affecting the first intake valve lift and duration characteristic. Either a lift or duration of the first intake valve is modulated so as to satisfy an EGR control criterion. | 01-15-2015 |
20150020781 | Engine Inlet For EGR-Air Flow Distribution - An intake manifold having an EGR-air flow distributor for distributing the desired air flow and EGR-air mixture through the intake manifold to each cylinder is disclosed. The EGR-air flow distributor includes a set of guide vanes defining plural flow channels in a plenum region of the inlet manifold. The EGR-air flow distributor also includes an EGR tube partially extending into the inlet manifold and having a slot formed therein for introducing EGR into the plenum region at a single location between the engine throttle and the guide vanes. | 01-22-2015 |
20150034028 | Targeted Cooling With Individualized Feeding Ports To Cylinders - A cooling system for an engine having a plurality of piston cylinders. The cooling system can include a liquid coolant source having liquid coolant and a cylinder cooling passage network having an inlet and an outlet for receiving and transmitting the liquid coolant. The cylinder cooling passage network having a plurality of individual upstream fluidic passages each being fluidly coupled to the inlet to directly receive the liquid coolant from the liquid coolant source in parallel flow. The cylinder cooling passage network further having a plurality of cylinder jacket passages each extending about at least a portion of a corresponding one of the plurality of piston cylinders and being positioned immediately adjacent thereto. The cylinder jacket passages are fluidly coupled directly to a corresponding one of the plurality of individual upstream fluidic passages to receive the liquid coolant and transmit the liquid coolant to the outlet for improved cooling performance. | 02-05-2015 |
20150059339 | Split/Dual Plane Integrated Exhaust Manifold For Dual Scroll Turbo Charger - An integrated exhaust manifold for use with an internal combustion engine and dual scroll turbocharger. The integrated exhaust manifold includes a first exhaust passageway fluidly connected between a first pair of piston cylinders and the dual scroll turbocharger for transporting exhaust gas from the first pair of piston cylinders to a first input of dual scroll turbocharger. The integrated exhaust manifold includes a second exhaust passageway fluidly connected between a second pair of piston cylinders and the dual scroll turbocharger for transporting exhaust gas from the second pair of piston cylinders to a second input of the dual scroll turbocharger. The second exhaust passageway is fluidly independent from the first exhaust passageway and the first and second exhaust passageways are positioned to define a septum area therebetween. A cooling system having a septum cooling jacket is use to cool the septum area between the first and second exhaust passageways. | 03-05-2015 |