Abstract: Systems and methods for a fault protection are provided that can be implemented in a hybrid electric vehicle (HEV) to limit the magnitude of a current that flows when an AC-to-chassis fault (ACF) occurs between an AC connection and the chassis of the HEV. An electric machine having a winding, an inverter sub-module (ISM) having a first switch and a second switch, and fault protection elements (FPEs), coupled to the ISM, are provided. The winding is coupled to the ISM coupled via the AC connection. The FPEs can include, for example, first and second inductances. To limit the magnitude of the current, the current can be passed along a first current path that includes the second inductance when the first switch is closed, and can be passed along a second current path that includes the first inductance when the second switch is closed.

Abstract: Systems and methods for a fault protection are provided that can be implemented in a hybrid electric vehicle (HEV) to limit the magnitude of a current that flows when an AC-to-chassis fault (ACF) occurs between an AC connection and the chassis of the HEV. An electric machine having a winding, an inverter sub-module (ISM) having a first switch and a second switch, and fault protection elements (FPEs), coupled to the ISM, are provided. The winding is coupled to the ISM coupled via the AC connection. The FPEs can include, for example, first and second inductances. To limit the magnitude of the current, the current can be passed along a first current path that includes the second inductance when the first switch is closed, and can be passed along a second current path that includes the first inductance when the second switch is closed.

Abstract: A system and method for transferring power from power sources to an AC power system are disclosed. Briefly described, one embodiment electrically couples an external AC power source to a first input power control (IPC) module that is rated at a first AC input power capacity and that is rated at a first direct current (DC) input power capacity, operates the first IPC module up to the first AC input power capacity in response to receiving AC power from an external AC power source, electrically couples an external DC power source to a second IPC module that is rated at a second AC input power capacity and that is rated at a second DC input power capacity, and operates the second IPC module up to the second DC input power capacity in response to receiving DC power from an external DC power source.

Abstract: A system and method for isolating sources and loads of a power system are disclosed. Briefly described, one embodiment includes at least a DC bus operable at a DC bus voltage; a non-isolated first primary converter module electrically coupled to the DC bus and operable to receive a first amount of power from a first power source, and operable to convert the received power from the first power source into a first amount of DC power at the DC bus voltage; and an isolated second primary converter module electrically coupled to the DC bus and operable to receive a second amount of power from a second power source, and operable to convert the received power from the second power source into a second amount of DC power at the DC bus voltage, wherein the second power source is electrically isolated from the DC bus by the isolated second primary converter module.

Abstract: A system and method for controlling power flow between power sources and a load in a power system are disclosed. Briefly described, one embodiment is a method for transferring power from a plurality of power sources to an AC system through an IPC module. The IPC module receives a first amount of power from a first power source that is external to the IPC module, receives a second amount of power from a second power source that is external to the IPC module, controls at least a first amount of direct current (DC) power through a first primary converter module coupled to a DC bus, receives a second amount of DC power from a second primary converter module coupled to the DC bus, converts the first and the second amounts of DC power into AC power, and transfers the AC power to the AC power system.

Abstract: A system and method for responding to abrupt load changes on a power system transfers an initial amount of power from an external power source to the AC power system through a secondary converter module; senses an abrupt load change occurring-on the AC power system; and transfers auxiliary direct current (DC) power to the secondary converter module.

Abstract: A system and method for coupling generation resources to an electric grid at a common location are disclosed. Briefly described, one embodiment includes at least a direct current (DC) bus operable at a DC bus voltage, a plurality of primary converter module sites on the DC bus, each of the primary converter module sites operable to electrically couple one of a plurality of primary converter modules to the DC bus, and a secondary converter module coupled to the DC bus and electrically coupleable to the AC system, the secondary converter module operable to convert an amount of DC current received from the DC bus into AC power that is transferred to the AC system at an AC system voltage, wherein the amount of DC current corresponds to power received from the plurality of primary converter modules.

Abstract: A system and method for responding to abrupt load changes on a power system are disclosed. Briefly described, one embodiment transfers an initial amount of power from an external power source to the AC power system through a secondary converter module; senses an abrupt load change occurring on the AC power system; where, in response to sensing the abrupt load change, transfers auxiliary direct current (DC) power to the secondary converter module, wherein the auxiliary DC power corresponds to at least a portion of the abrupt load change; where, in response to sensing the abrupt load change, transfers the initial amount of power from the external power source and the auxiliary DC power through the secondary converter module to the AC power system; and where, in response to sensing the abrupt load change, maintains transfer of the initial amount of power from the external power source through the secondary converter module.

Abstract: A system and method for isolating sources and loads of a power system are disclosed. Briefly described, one embodiment includes at least a DC bus operable at a DC bus voltage; a non-isolated first primary converter module electrically coupled to the DC bus and operable to receive a first amount of power from a first power source, and operable to convert the received power from the first power source into a first amount of DC power at the DC bus voltage; and an isolated second primary converter module electrically coupled to the DC bus and operable to receive a second amount of power from a second power source, and operable to convert the received power from the second power source into a second amount of DC power at the DC bus voltage, wherein the second power source is electrically isolated from the DC bus by the isolated second primary converter module.

Abstract: A system and method for transferring power from power sources to an AC power system are disclosed. Briefly described, one embodiment electrically couples an external AC power source to a first input power control (IPC) module that is rated at a first AC input power capacity and that is rated at a first direct current (DC ) input power capacity, operates the first IPC module up to the first AC input power capacity in response to receiving AC power from an external AC power source, electrically couples an external DC power source to a second IPC module that is rated at a second AC input power capacity and that is rated at a second DC input power capacity, and operates the second IPC module up to the second DC input power capacity in response to receiving DC power from an external DC power source.

Abstract: A system and method for controlling power flow between power sources and a load in a power system are disclosed. Briefly described, one embodiment is a method for transferring power from a plurality of power sources to an AC system through an IPC module. The IPC module receives a first amount of power from a first power source that is external to the IPC module, receives a second amount of power from a second power source that is external to the IPC module, controls at least a first amount of direct current (DC) power through a first primary converter module coupled to a DC bus, receives a second amount of DC power from a second primary converter module coupled to the DC bus, converts the first and the second amounts of DC power into AC power, and transfers the AC power to the AC power system.

Abstract: Independent phase output voltage control for a 3-phase 4-wire DC/AC inverter, for example, is provided. With the independent phase output voltage control, all three phase output voltages from the DC/AC inverter can be separately and effectively controlled to provide balanced 3-phase voltages from the DC/AC inverter to an unbalanced load, and/or to provide unbalanced 3-phase voltages from the DC/AC inverter to a balanced or unbalanced load. The independent phase output voltage control method can be applied to an inverter power system, with outputs of N-phase (N+1) wire configurations. Here, N can be any integer number greater than zero.

Abstract: The present invention relates to a system and method for compensating the voltage distortion and minimizing the available voltage range loss both caused by switching dead-time of solid-state switch components in power conversion devices. As a result, the power quality supplied from the power conversion devices can be improved and the output voltage of such devices can be increased.

Abstract: The present invention relates to a system and method for compensating the voltage distortion and minimizing the available voltage range loss both caused by switching dead-time of solid switch components in power conversion devices. As a result, the power quality supplied from the power conversion devices can be improved and the output voltage of such devices can be increased.