Some exemplary embodiments include a hybrid vehicle cooling system comprising a closed loop coolant flowpath including a valve operable to direct coolant flow to an internal combustion engine or to an internal combustion engine bypass, a thermostat operable to direct coolant flow from the internal c
Some exemplary embodiments include a hybrid vehicle cooling system comprising a closed loop coolant flowpath including a valve operable to direct coolant flow to an internal combustion engine or to an internal combustion engine bypass, a thermostat operable to direct coolant flow from the internal combustion engine or the internal combustion engine bypass to a radiator or a radiator bypass, a plurality of hybrid powertrain components positioned in parallel to receive coolant flow from the radiator or the radiator bypass, a mechanically driven coolant pump operable to pump coolant through the closed loop coolant flowpath, and an electrically driven coolant pump operable to pump coolant through the closed loop coolant flowpath. Additional exemplary embodiments include methods of operation and/or control of hybrid vehicle cooling systems.
대표청구항▼
1. A hybrid vehicle cooling system comprising: a closed loop coolant flowpath including at least one valve operable to selectably direct coolant flow to an internal combustion engine or to an internal combustion engine bypass, wherein the internal combustion engine bypass is configured to bypass the
1. A hybrid vehicle cooling system comprising: a closed loop coolant flowpath including at least one valve operable to selectably direct coolant flow to an internal combustion engine or to an internal combustion engine bypass, wherein the internal combustion engine bypass is configured to bypass the coolant flow around the internal combustion engine,a thermostat operable to direct coolant flow from the internal combustion engine and from the internal combustion engine bypass to a radiator or a radiator bypass,a plurality of hybrid powertrain components and a hybrid powertrain component bypass each positioned in the closed loop coolant flowpath downstream of the radiator and the radiator bypass, wherein the plurality of hybrid powertrain components are positioned in parallel to one another and in series with the internal combustion engine and the radiator, and further comprising a plurality of control valves each associated with a respective one of the plurality of hybrid powertrain components to control coolant flow thereto;a mechanically driven coolant pump operable to pump coolant through the closed loop coolant flowpath; andan electrically driven coolant pump operable to pump coolant through the closed loop coolant flowpath, wherein the electrically driven coolant pump is positioned in series with the mechanically driven coolant pump, wherein each of the plurality of hybrid powertrain components is positioned in series with the mechanically driven coolant pump and with the electrically driven coolant pump to each selectively receive coolant flow produced by both of the electrically driven coolant pump and the mechanically driven coolant pump from the radiator or the radiator bypass. 2. A hybrid vehicle cooling system according to claim 1 comprising: a controller configured to control the system to operate in a first mode wherein the engine is on, the mechanically driven coolant pump operates to pump coolant through the closed loop coolant flowpath up to a threshold coolant flow rate, and the mechanically driven coolant pump and the electrically driven coolant pump operate to pump coolant through the closed loop coolant flowpath above the threshold coolant flow rate. 3. A hybrid vehicle cooling system according to claim 2 comprising: a controller configured to control the system to operate in a second mode wherein the engine is off, the mechanically driven coolant pump is off, the at least one valve directs coolant flow to the internal combustion engine bypass, and the electrically driven coolant pump operates to pump coolant through the closed loop coolant flowpath to bypass the mechanically driven coolant pump and the internal combustion engine. 4. A hybrid vehicle cooling system according to claim 3 comprising: a controller operable to control the system to operate in a third mode wherein one or more of the plurality of hybrid powertrain components is controlled to heat the coolant effective to heat the engine. 5. A hybrid vehicle cooling system according to claim 1 wherein the plurality of hybrid powertrain components include a motor/generator, a clutch, and power electronics that are each positioned in parallel to one another in the closed loop coolant flowpath. 6. A hybrid vehicle cooling system according to claim 1 wherein the mechanically driven coolant pump and the electrically driven coolant pump are positioned in series with one another in the coolant flow path upstream of the engine and downstream of the plurality of hybrid powertrain components and coolant flow from the plurality of hybrid powertrain components is received by the electrically driven coolant pump and supplied from the electrically driven coolant pump to the mechanically driven coolant pump and then to the engine. 7. A hybrid vehicle cooling system according to claim 1 wherein the system has a required peak coolant flow rate and the maximum coolant flow rate provided by the mechanically driven coolant flow pump is less than the required peak coolant flow rate. 8. A hybrid vehicle cooling system according to claim 1 wherein the internal combustion engine bypass further bypasses the mechanically driven coolant pump and the mechanically driven coolant pump is operable to pump coolant through the engine and the electrically driven coolant pump is operable to pump coolant through the mechanically driven coolant pump and the engine or through the engine bypass. 9. A hybrid vehicle system comprising: an internal combustion engine;a radiator;an electric machine;power electronics operable to provide power to the electric machine;a coolant flowpath in thermal communication with the internal combustion engine, the radiator, the electric machine, and the power electronics, wherein the electric machine and the power electronics are connected in parallel to one another in the coolant flowpath to each selectively receive coolant from the radiator, and the internal combustion engine and the radiator are connected in series in the coolant flowpath and in series to each of the electric machine and the power electronics, and further comprising an internal combustion engine bypass that is configured to bypass the coolant flow around the internal combustion engine and a valve operable to selectively direct coolant to the radiator through the internal combustion engine or through the internal combustion engine bypass;a mechanically driven coolant pump to pump coolant through the internal combustion engine, wherein the internal combustion engine bypass is further configured to bypass the mechanically driven coolant pump, and an electrically driven coolant pump operable to circulate coolant through the coolant flowpath through the internal combustion engine bypass and through the mechanically driven coolant pump and the internal combustion engine, wherein each of the mechanically driven coolant pump and the electrically driven coolant pump are connected in the flow path in series to one another and in series to each of the electric machine and the power electronics to each provide coolant flow through the internal combustion engine to the radiator and from the radiator to the electric machine and the power electronics; anda controller operable to control the electric machine and the power electronics to provide power to the electric machine;wherein the controller is operable to selectively increase the temperature of the internal combustion engine by controlling at least one of the electric machine and the power electronics to provide increased heat to the coolant in thermal communication with the internal combustion engine and by circulation of the coolant to the internal combustion engine with the at least one of the mechanically driven coolant pump and the electrically driven coolant pump. 10. A hybrid vehicle cooling system according to claim 9 wherein the controller is operable to selectively operate the electrically driven coolant pump to increase coolant flow rate provided by the mechanically driven coolant pump driven by the internal combustion engine. 11. A hybrid vehicle system according to claim 9 wherein the controller is operable to selectively direct coolant to the internal combustion engine bypass to bypass the mechanically driven coolant pump and the internal combustion engine. 12. A hybrid vehicle system according to claim 9 wherein the electric machine comprises a motor/generator. 13. A method comprising: operating an internal combustion engine;pumping coolant with an engine driven coolant pump up to a threshold coolant flow rate through a closed loop flowpath in thermal communication with the internal combustion engine, a radiator, an electric motor, power electronics, and an electrically driven coolant pump, wherein the internal combustion engine is connected in the flowpath in series with the radiator and each of the electric motor and the power electronics, and the electric motor and the power electronics are connected in the flowpath in parallel with one another and in series with the electrically driven coolant pump, the engine driven coolant pump, the internal combustion engine, and the radiator;determining an engine temperature condition;controlling operation of the electric motor or the power electronics to increase heat transfer to the coolant effective to heat the engine based upon the engine temperature condition; andpumping coolant through the engine, the radiator and each of the electric machine and the power electronics through the closed loop flowpath with the engine driven coolant pump in conjunction with electrically driven coolant pump providing an increased coolant flow to the engine driven coolant pump above the threshold coolant flow rate. 14. A method according to claim 13 wherein the controlling operation of the electric motor or the power electronics to increase heat transfer to the coolant effective to heat the engine includes controlling the electric motor or the power electronics to increase heat rejection therefrom to the coolant by operating the electric motor or the power electronics at a reduced efficiency while meeting output demand therewith. 15. A method according to claim 13 comprising: controlling a valve to selectively direct coolant flow through the engine or through an engine bypass. 16. A method according to claim 13 comprising: pumping coolant through the closed loop flowpath with an electrically driven coolant pump and directing coolant to bypass the engine while the engine is off. 17. A method according to claim 13 comprising: selectively cooling the coolant by transferring heat from the coolant with the radiator. 18. A hybrid vehicle system according to claim 9 further comprising a clutch between the internal combustion engine and the electric machine, wherein the clutch is positioned in parallel to the electric machine and the power electronics in the coolant flowpath to selectively receive coolant from the radiator, and wherein each of the mechanically driven coolant pump and the electrically driven coolant pump are connected in the flow path in series to one another and in series to the clutch to each provide coolant flow through the internal combustion engine to the radiator and from the radiator to the clutch. 19. The method of claim 13, further comprising a clutch between the engine and the electric machine in thermal communication with the closed loop coolant flowpath, wherein the clutch is connected to the closed loop coolant flowpath in parallel with the electric motor and the power electronics, and wherein pumping coolant through the closed loop flowpath includes pumping coolant to the clutch.
Taylor, Danny R.; Ekdahl, Earl; Quinn, Jr., Stanley B., Control method for transitions between open and closed loop operation in electronic VCT controls.
Tankersley Jerome B. (Fredericksburg VA) Boothe Richard W. (Roanoke VA) Konrad Charles E. (Roanoke VA), Electric vehicle drive train with direct coupling transmission.
Albright ; Jr. Harold D. (2201 Providence Rd. Charlotte NC 28211) Rollins William R. (30 Dawn Dr. South Windsor CT 06074), Hybrid power system for driving a motor vehicle.
Aoyama Shunichi,JPX ; Kitada Shinichiro,JPX ; Hattori Noboru,JPX ; Matsuo Isaya,JPX, Hybrid vehicle employing parallel hybrid system, using both internal combustion engine and electric motor for propulsion.
Joanne T. Woestman ; Prabhakar B. Patil ; Ross M. Stunz ; Thomas E. Pilutti, Strategy to use an on-board navigation system for electric and hybrid electric vehicle energy management.
Auerbach, Michael; Brunner, Johannes; Kleisch, Ralf; Oberting, Andreas, Temperature control system for hybrid powertrain and method of operating a temperature control system.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.