Various methods for determining a holding current based on a pressure differential across a wastegate valve are provided. In one example, a method of operating a wastegate comprises determining a holding current with which to hold a wastegate valve at a desired position, the holding current determined based on a pressure differential across the wastegate valve.

A method of and apparatus for operating a supercharger for an automotive engine is disclosed. The supercharger has: an input shaft for coupling to an engine crankshaft, and coupled to the rotor of a first electrical machine and a first component of an epicyclic gear train; and an output shaft connected to a compressor and a second component of the epicyclic gear train; wherein the third component of the epicyclic gear train is connected to the rotor of a second electrical machine. The first electrical machine is selectively operable to supply electrical energy to the second electrical machine. The method includes the steps of: (a) calculating a required speed of the second electrical machine that would give rise to a required pressure at an outlet of the compressor; and (b) setting the speed of the second electrical machine to the calculated required speed.

A method of and apparatus for operating a supercharger for an automotive engine is disclosed. The supercharger has: an input shaft for coupling to an engine crankshaft, and coupled to the rotor of a first electrical machine and a first component of an epicyclic gear train; and an output shaft connected to a compressor and a second component of the epicyclic gear train; wherein the third component of the epicyclic gear train is connected to the rotor of a second electrical machine. The first electrical machine is selectively operable to supply electrical energy to the second electrical machine. The method includes the steps of: (a) calculating a required speed of the second electrical machine that would give rise to a required pressure at an outlet of the compressor; and (b) setting the speed of the second electrical machine to the calculated required speed.

A supercharger assembly has a supercharger housing defining an air inlet and an air outlet; an impeller disposed in the supercharger housing; an impeller shaft connected to the impeller for driving the impeller; a driveshaft connected to the impeller shaft for driving the impeller shaft, the driveshaft defining an oil supply passage; and a torsional damper connected to the driveshaft for driving the driveshaft. The torsional damper is configured for being operatively connected to a crankshaft of an internal combustion engine. The oil supply passage is positioned to supply oil to the torsional damper for lubricating the torsional damper.

A hybrid-electric genset includes a direct current (DC) bus, an engine, and an electric generator configured to receive mechanical power from the engine and generate first alternating current (AC) power. The hybrid-electric genset further includes an inverter configured to convert the first AC power to DC power and output the DC power to the DC bus. The hybrid-electric genset further includes a controller configured to control the engine to increase or decrease the AC power output by the electric generator. The DC bus is configured to attach to at least one battery pack or supercapacitor. The at least one battery pack or supercapacitor is configured to maintain a nominal voltage of the DC bus approximately at a nominal battery pack voltage of the at least one battery pack.

A combustion engine includes a supercharger which pressurizes intake air to be supplied to an engine body. A lubrication system for the combustion engine includes a main lubrication passage through which lubricating oil flows to lubricate the engine body, a supercharger lubrication passage through which lubricating oil flows to lubricate the supercharger, and an oil pump which supplies a shared lubricating oil to both of the main and supercharger lubrication passages.

A combustion engine includes a supercharger which pressurizes intake air to be supplied to an engine body. A lubrication system for the combustion engine includes a main lubrication passage through which lubricating oil flows to lubricate the engine body, a supercharger lubrication passage through which lubricating oil flows to lubricate the supercharger, and an oil pump which supplies a shared lubricating oil to both of the main and supercharger lubrication passages.

A compressor housing (12) for a turbocharger includes a recirculation cavity (4) formed in a portion of the compressor housing (12). The recirculation cavity (4) is defined by an inner cavity wall (2) and an outer cavity wall (5). In addition, an inlet groove (1) and an outlet (7) are formed in the recirculation cavity (4) for circulating airflow from the compressor housing (12) through the recirculation cavity (4), and at least one recirculation noise obstruction (6) is fixedly secured within the recirculation cavity (4) to disrupt air flow through the cavity and reduce noise in the compressor housing (12).

A compressor housing (12) for a turbocharger includes a recirculation cavity (4) formed in a portion of the compressor housing (12). The recirculation cavity (4) is defined by an inner cavity wall (2) and an outer cavity wall (5). In addition, an inlet groove (1) and an outlet (7) are formed in the recirculation cavity (4) for circulating airflow from the compressor housing (12) through the recirculation cavity (4), and at least one recirculation noise obstruction (6) is fixedly secured within the recirculation cavity (4) to disrupt air flow through the cavity and reduce noise in the compressor housing (12).

A turbocharger includes a two-stage serial compressor having first and second impellers, with a crossover duct for leading air from the first impeller into the second impeller for further compression. The compressor housing also defines a bypass duct from the crossover duct to the air discharge duct from the compressor, and a bypass valve disposed in the bypass duct. Under certain operating conditions (such as high-flow, low-pressure-ratio conditions) the bypass valve can be opened to bypass the second impeller, such that the compressor behaves like a single-stage compressor. At other operating conditions, the bypass valve is closed so that the compressor provides two-stage compression for higher pressure ratios.