Abstract: A high-voltage energy regulated conversion circuit (HVERCC) (12) for coupling to a vehicle bus (24) includes a battery bus (28) and a heater bus (29). A high-voltage battery pack (30) is electrically coupled to the battery bus and a resistive load element (42) is electrically coupled to the heater bus (29). A high-voltage energy converter (HVEC) module (22) is electrically coupled to the vehicle bus (24), the high-voltage battery pack (30), and the resistive load element (42). The HVEC module regulates power on the vehicle bus (24), the battery bus (28), and the heater bus (29) and operates in multiple functional modes including a constant voltage mode, a constant current mode, and a constant battery current mode.

Abstract: A high-voltage energy regulated conversion circuit (HVERCC) (12) for electrically coupling to a vehicle bus (24) is provided. The HVERCC (12) includes a high-voltage energy converter (HVEC) module (22) coupled to the vehicle bus (24), a battery-pack high-voltage bus battery bus (28), and a WEG heater bus (29). The battery bus (28) is coupled to a high-voltage battery pack (30) and a WEG heater circuit (32). The HVEC module (22), the high-voltage battery pack (30), and the WEG heater circuit (32) are coupled to a logic controller (14) via a network (36). The logic controller (14) regulates the power on the vehicle bus (24), the battery bus (28), and the WEG heater bus (29). An operational method for the HVEC module (22) is also provided.

Abstract: The invention is an improved fuel cell system suited for application in a vehicle. Specifically, the invention provides an improved system to remove CO emissions that has a rapid dynamic response (about 1 second) and can operate over a wide range of temperatures (between 0 and 800 degrees Celsius). The fuel cell system comprises hydrogen fuel, a CO removal system based upon non-Faradaic electrochemical modification of catalyst activity (electrochemical promotion), and a fuel cell stack. The CO removal system comprises a catalyst/working electrode, an electrolyte, a counter electrode, and a power source. The CO removal system's intrinsic catalytic rate is greater than an intrinsic electrocatalytic rate. The catalyst can be Pt, Rh, Au, Cu/ZnO, Cu/CuO, ABO3(perovskite), zeolite, and Pd. The power source can be a battery, potentiostat, or galvanostat.

Abstract: A high-voltage energy regulated conversion circuit (HVERCC) (12) for coupling to a vehicle bus (24) includes a battery bus (28) and a heater bus (29). A high-voltage battery pack (30) is electrically coupled to the battery bus and a resistive load element (42) is electrically coupled to the heater bus (29). A high-voltage energy converter (HVEC) module (22) is electrically coupled to the vehicle bus (24), the high-voltage battery pack (30), and the resistive load element (42). The HVEC module regulates power on the vehicle bus (24), the battery bus (28), and the heater bus (29) and operates in multiple functional modes including a constant voltage mode, a constant current mode, and a constant battery current mode.

Abstract: This invention provides a new method and system to control strategies of a combined fuel cell and battery pack power system to produce an efficient and cost-effective powertrain with acceptable drivability and low emissions. The method and system provide strategies for vehicle start-up, power load changes, and steady state driving conditions. The strategies reduce vehicle maintenance cost by increasing the battery service life and fuel efficiency. Further, the strategies reduce vehicle cost by reducing fuel cell engine size required by a hybrid electric vehicle while responding rapidly to load changes. The strategies also provide increased fuel efficiency by recovery, storage, and re-use of the vehicle kinetic energy normally dissipated as heat during braking.

Abstract: A high-voltage energy regulated conversion circuit (HVERCC) 12 for electrically coupling to a vehicle bus 24 is provided. The HVERCC 12 includes a high-voltage energy converter (HVEC) module 22 coupled to the vehicle bus 24, a battery-pack high-voltage bus battery bus 28, and a WEG heater bus 29. The battery bus 28 is coupled to a high-voltage battery pack 30 and a WEG heater circuit 32. The HVEC module 22, the high-voltage battery pack 30, and the WEG heater circuit 32 are coupled to a logic controller 14 via a network 36. The logic controller 14 regulates the power on the vehicle bus 24, the battery bus 28, and the WEG heater bus 29. An operational method for the HVEC module 22 is also provided.

Abstract: The invention is an improved fuel cell system suited for application in a vehicle. Specifically, the invention provides an improved system to remove CO emissions that has a rapid dynamic response (about 1 second) and can operate over a wide range of temperatures (between 0 and 800 degrees Celsius). The fuel cell system comprises hydrogen fuel, a CO removal system based upon non-Faradaic electrochemical modification of catalyst activity (electrochemical promotion), and a fuel cell stack. The CO removal system comprises a catalyst/working electrode, an electrolyte, a counter electrode, and a power source. The CO removal system's intrinsic catalytic rate is greater than an intrinsic electrocatalytic rate. The catalyst can be Pt, Rh, Au, Cu/ZnO, Cu/CuO, ABO3(perovskite), zeolite, and Pd. The power source can be a battery, potentiostat, or galvanostat.

Abstract: This invention provides a new method and system to control strategies of a combined fuel cell and battery pack power system to produce an efficient and cost-effective powertrain with acceptable drivability and low emissions. The method and system provide strategies for vehicle start-up, power load changes, and steady state driving conditions. The strategies reduce vehicle maintenance cost by increasing the battery service life and fuel efficiency. Further, the strategies reduce vehicle cost by reducing fuel cell engine size required by a hybrid electric vehicle while responding rapidly to load changes. The strategies also provide increased fuel efficiency by recovery, storage, and re-use of the vehicle kinetic energy normally dissipated as heat during braking.

Abstract: A system (20, 30, 40, 50) and method for canceling a leakage current is provided that uses line voltages (L1, L2) that are out of phase with each other to produce a counter leakage potential that cancels leakage current. In one embodiment of the invention, the actual potential of the phases is measured (42, 52, 54) and used to determine the counter potential that is to be applied to the line voltage (L1 or L2) that is generating the leakage current. The counter potential is applied to the appropriate line voltage by way of a transistor circuit (Q1, Q2). The transistor circuit (Q1, Q2) is controlled through standard electronic circuitry (28), or by way of a microprocessor device (32).