초록

A switch/power conditioning module may be added to a hybrid vehicle to selectively supply power from an AC power bus to a load, providing on-vehicle standby power generating capability with a minimum of added hardware and/or when the vehicle is stationary.

대표청구항 ▼

The invention claimed is: 1. A method for operating a hybrid electric vehicle, comprising: converting direct current (DC) power received from a DC power storage device into alternating current (AC) real power and AC reactive power with a power inverter; operating an electric machine with the AC rea

The invention claimed is: 1. A method for operating a hybrid electric vehicle, comprising: converting direct current (DC) power received from a DC power storage device into alternating current (AC) real power and AC reactive power with a power inverter; operating an electric machine with the AC real power to produce torque that is used to start an engine; after the engine is started, controlling the power inverter such that the electric machine is operable in a generating mode wherein the electric machine receives at least AC reactive power from DC power received from the DC power storage device, and that DC power received from the DC power storage device is converted into AC current having a torque current component equal to zero, within a first preset tolerance, and having a magnetizing current component equal to a reference current value of the electric machine, within a second preset tolerance; and after an output voltage of the electric machine is at a preset voltage value and after an AC frequency of the electric machine is at a preset frequency value, operating the electric machine as a generator to generate AC power and operating a switch/power conditioning module to provide the generated AC power to a load. 2. The method of claim 1 wherein operating the electric machine with the AC real power to produce torque comprises: providing torque produced by the electric machine to a power train; and transferring the produced torque from the power train to the engine so that the engine is started. 3. The method of claim 1 wherein after the engine is started and the electric machine is operated in the generating mode, the electric machine receives only AC reactive power from the DC power storage device. 4. The method of claim 1 wherein after the engine is started, comprising: operating the electric machine in a free spinning mode; and operating a shaft of the engine at a rotational speed such that the AC frequency of the electric machine is at the preset frequency value. 5. The method of claim 1 wherein controlling the power inverter such that the magnetizing current component is equal to the reference current value comprises: regulating the magnetizing current component so that an induced back EMF voltage in the electric machine causes the output voltage of the electric machine to equal the preset voltage value, within a third preset tolerance. 6. The method of claim 1, after the engine is started, further comprising: providing torque from the engine to an AC generator so that an amount of AC power is generated by the AC generator; and converting the amount of AC power generated by the AC generator into an amount of DC power that is stored into the DC power storage device. 7. A power system for a hybrid electric vehicle, comprising: a power train operable to propel the hybrid electric vehicle; an electric machine physically coupled to the power train, operable as a motor to provide torque to the power train, and operable as a generator to produce alternating current (AC) power in response to receiving torque from the power train; an engine physically coupled to the power train, operable to provide torque to the power train, and operable to receive torque from the power train; a power inverter electrically coupled between a power storage device and the electric machine, the power inverter operable to transform direct current (DC) power received from at least the power storage device into AC real power and AC reactive power; a switch and power conditioning module electrically couplable to the electric machine, and operable to selectively supply a load; a DC/AC power converter electrically coupled between the power inverter and the load; a DC/AC power converter controller coupled to the DC/AC power converter; and an inverter controller controllably coupled to the power inverter, such that: when starting the engine, the inverter controller operates the power inverter to convert DC power received from the power storage device into the real AC power that is delivered to the electric machine so that the electric machine provides torque to the power train to start the engine; after starting the engine, the inverter controller operates the power inverter to convert DC power received from the power storage device into the reactive AC power so that the electric machine is operated in a generating mode wherein the electric machine receives AC reactive power; and after an output voltage of the electric machine is at a preset voltage value and after an AC frequency of the electric machine is at a preset frequency value, the switch/power conditioning module is operated to source the load with AC power, wherein the AC power is provided from the electric machine; wherein in response to receiving a signal from the inverter controller that is communicated after the electric machine is operated to the preset voltage value and the preset frequency value, the DC/AC power converter controller operates the DC/AC power converter to convert received DC power into AC power that is sourced to the load. 8. The hybrid power system of claim 7, further comprising: an engine controller controllably coupled to the engine and communicatively coupled to the inverter controller, and operable to control the engine in response to signals from the inverter controller, such that: when the engine is started, the engine controller starts the engine in response to the power train receiving torque from the electric machine; after the engine is started, the engine controller operates the engine at a revolution per minute (RPM) speed such that the electric machine operating in the generating mode is operated to the preset frequency value. 9. The hybrid power system of claim 8 wherein after the output voltage of the electric machine is at the preset voltage value and after the AC frequency of the electric machine is at the preset frequency value, the engine controller operates the engine such that torque is provided to the power train, and wherein a portion of the torque provided to the power train is received by the electric machine and used to provide the AC power to the load. 10. The hybrid power system of claim 7 wherein the switch/power conditioning module comprises: a Delta-Wye transformer with a set of three primary windings in a Delta configuration electrically coupled to the electric machine, and a set of three secondary windings in a Wye configuration electrically coupled to the load; a set of three inductors electrically coupled between the primary windings and the electric machine; and a set of three capacitors electrically coupled between the primary windings. 11. The hybrid power system of claim 7 wherein the switch/power conditioning module further comprises an enable/disable switch responsive to the inverter controller such that the enable/disable switch electrically decouples the load from the electric machine at least when the engine is started, and such that the enable/disable switch electrically couples the load to the electric machine at least when the electric machine is operated to the preset voltage value and the preset frequency value. 12. The hybrid power system of claim 7, further comprising: a power take off physically coupled to the power train; an AC generator physically coupled to the power take off and operable to generate AC power in response to receiving torque from the power take off; and an AC/DC power converter electrically coupled between the AC generator and the power storage device, and operable to transform generated AC power produced by the AC generator into DC power for storage by the power storage device. 13. The hybrid power system of claim 7 wherein the power inverter is bi-directionally operable by the inverter controller as an inverter and operable by the inverter controller as a rectifier, such that AC power generated by the electric machine is converted into the DC power stored by the power storage device in response to the power inverter being operated as the rectifier. 14. The hybrid power system of claim 7, further comprising: a flex coupling replacing the power train and physically coupling the engine and the electric machine; and a transmission mechanically coupling the electric machine to a set of wheels. 15. The hybrid power system of claim 7 wherein the engine is an induction motor. 16. A system of operating a hybrid electric vehicle, comprising: means for converting direct current (DC) power received from a DC power storage device into alternating current (AC) real power and AC reactive power with a power inverter; means for operating an electric machine with the AC real power to produce torque that is used to start an engine; means for controlling the power inverter after the engine is started such that the electric machine is operated in a generating mode wherein the electric machine receives at least AC reactive power from DC power received from the DC power storage device and the DC power received from the DC power storage device is converted into AC current having a torque current component equal to zero, within a first preset tolerance, and having a magnetizing current component equal to a reference current value of the electric machine, within a second preset tolerance; and means for operating the electric machine as a generator to generate AC power and operating a switch and power conditioning module to provide the generated AC power to a load after an output voltage of the electric machine is at a preset voltage value and after an AC frequency of the electric machine is at a preset frequency value. 17. A method for operating a hybrid electric vehicle, comprising: converting direct current (DC) power received from a DC power storage device into alternating current (AC) real power and AC reactive power with a power inverter; operating an electric machine with the AC real power to produce torque that is used to start an engine; after the engine is started, operating the electric machine in a free spinning mode; controlling the power inverter such that DC power received from the DC power storage device is converted into AC current having a torque current component equal to zero within a preset tolerance, and having a magnetizing current component equal to a reference current value of the electric machine with at least the AC reactive power is provided to the electric machine when a motor shaft of the electric machine is rotating at a speed at least equal to a preset speed, within a preset tolerance; and after an output voltage of the electric machine is at a preset voltage value and after an AC frequency of the electric machine is at a preset frequency value, operating the electric machine as a generator to generate AC power and operating a switch and power conditioning module to provide the generated AC power to a load. 18. The method of claim 17, wherein operating the electric machine in the free spinning mode comprises: halting a supply of the AC real power to the electric machine. 19. A power system for a hybrid electric vehicle, comprising: a power train operable to propel the hybrid electric vehicle; an electric machine physically coupled to the power train, operable as a motor to provide torque to the power train, and operable as a generator to produce alternating current (AC) power in response to receiving torque from the power train; an engine physically coupled to the power train, operable to provide torque to the power train, and operable to receive torque from the power train; a power inverter electrically coupled between a power storage device and the electric machine, the power inverter operable to transform direct current (DC) power received from at least the power storage device into AC real power and AC reactive power; a switch and power conditioning module electrically couplable to the electric machine, and operable to selectively supply a load; and an inverter controller controllably coupled to the power inverter, such that: when starting the engine, the inverter controller operates the power inverter to convert DC power received from the power storage device into the real AC power that is delivered to the electric machine so that the electric machine provides torque to the power train to start the engine; after starting the engine, the inverter controller operates the power inverter to such that DC power from the DC storage device is converted into AC current having a torque component equal to zero, within a first preset tolerance so that the electric machine operates in a free spinning mode and having a magnetizing current component equal to a reference current value of the electric machine within a second preset tolerance; after a motor shaft of the electric machine that is physically coupled to the power train is rotating at a speed greater than a preset speed, the inverter controller operates the power inverter to convert DC power received from the power storage device into the reactive AC power so that the electric machine is operated in a generating mode wherein the electric machine receives AC reactive power; and after an output voltage of the electric machine is at a preset voltage value and after an AC frequency of the electric machine is at a preset frequency value, the switch/power conditioning module is operated to source the load with AC power, wherein the AC power is provided from the electric machine.