초록 ▼

A hybrid vehicle comprises an internal combustion engine, a traction motor, a starter motor, and a battery bank, all controlled by a microprocessor in accordance with the vehicle's instantaneous torque demands so that the engine is run only under conditions of high efficiency, typically only when th

A hybrid vehicle comprises an internal combustion engine, a traction motor, a starter motor, and a battery bank, all controlled by a microprocessor in accordance with the vehicle's instantaneous torque demands so that the engine is run only under conditions of high efficiency, typically only when the load is at least equal to 30% of the engine's maximum torque output. In some embodiments, a turbocharger may be provided, activated only when the load exceeds the engine's maximum torque output for an extended period; a two-speed transmission may further be provided, to further broaden the vehicle's load range. A hybrid brake system provides regenerative braking, with mechanical braking available in the event the battery bank is fully charged, in emergencies, or at rest; a control mechanism is provided to control the brake system to provide linear brake feel under varying circumstances.

대표청구항 ▼

The invention claimed is: 1. A hybrid vehicle, comprising: at least two wheels, operable to receive power to propel said hybrid vehicle; a first alternating current (AC) electric motor, operable to provide power to said at least two wheels to propel said hybrid vehicle; a second AC electric motor;

The invention claimed is: 1. A hybrid vehicle, comprising: at least two wheels, operable to receive power to propel said hybrid vehicle; a first alternating current (AC) electric motor, operable to provide power to said at least two wheels to propel said hybrid vehicle; a second AC electric motor; an engine coupled to said second electric motor, operable to provide power to said at least two wheels to propel the hybrid vehicle, and/or to said second electric motor to drive the second electric motor to generate electric power; a first alternating current-direct current (AC-DC) converter having an AC side coupled to said first electric motor, operable to accept AC or DC current and convert the current to DC or AC current respectively; a second AC-DC converter coupled to said second electric motor, at least operable to accept AC current and convert the current to DC; an electrical storage device operable to store energy converted to DC by said AC-DC converters and to provide energy to be converted to AC by at least said first AC-DC converter to power at least said first electric motor; and a controller; wherein a rate of change of torque output of said engine is limited to a threshold value, wherein when a rate of change of road load exceeds said threshold value of the rate of change of torque output of the engine, said controller is operable to operate said first motor and/or said second motor to supply additional power to at least said two wheels to supply remaining required torque. 2. The hybrid vehicle of claim 1, wherein said threshold value is no more than about 2% per revolution. 3. The hybrid vehicle of claim 1, wherein said controller is operable to vary said threshold value with respect to a state of charge of said electrical storage device. 4. The hybrid vehicle of claim 1, wherein a maximum torque on at least said two wheels produced by said first electric motor or both electric motors is larger than a maximum torque on at least said two wheels produced by said engine. 5. The hybrid vehicle of claim 1, wherein a maximum rotational speed of said first electric motor is at least 50% larger than a maximum rotational speed of said engine. 6. The hybrid vehicle of claim 1, further comprising: a third AC electric motor; wherein said first AC electric motor is coupled to a first pair of wheels to provide power to said first pair of wheels to propel said hybrid vehicle, and said third AC electric motor is coupled to a second pair of wheels to provide power to said second pair of wheels to propel said hybrid vehicle. 7. The hybrid vehicle of claim 6, wherein relative amounts of power directed to said first and second pairs of wheels by the first and third electric motors, respectively, is controlled by said controller. 8. The hybrid vehicle of claim 6, wherein a torque range-broadening transmission is interposed between said engine and said at least said two wheels to which said engine is operable to provide power. 9. The hybrid vehicle of claim 6, wherein a maximum torque provided to said first and second pairs of two wheels by said first and third electric motors, or by said first and third electric motors and said second electric motor, is larger than a maximum torque on at least said two wheels produced by said engine. 10. The hybrid vehicle of claim 6, wherein a maximum rotational speed of said first electric motor is at least 50% larger than a maximum rotational speed of said engine. 11. The hybrid vehicle of claim 1, wherein said engine comprises a turbocharger operable to increase the maximum torque output by said engine, and wherein said turbocharger is so operated when the power required of said engine exceeds a predetermined value for at least a predetermined period of time. 12. The hybrid vehicle of claim 1, wherein said engine is preheated prior to starting. 13. The hybrid vehicle of claim 1, further comprising: a third AC electric motor; wherein said first AC electric motor is coupled to a first pair of wheels to provide power to said first pair of wheels to propel said hybrid vehicle, and said third AC electric motor is coupled to a second pair of wheels to provide power to said second pair of wheels to propel said hybrid vehicle; and wherein said engine comprises a turbocharger operable to increase the maximum torque output by said engine, and wherein said turbocharger is so operated when the power required of said engine exceeds a predetermined value for at least a predetermined period of time. 14. A method of control of a hybrid vehicle, said hybrid vehicle comprising: at least two wheels, operable to receive power to propel said hybrid vehicle; a first alternating current (AC) electric motor, operable to provide power to said at least two wheels to propel said hybrid vehicle; a second AC electric motor; an engine coupled to said second electric motor, operable to provide power to said at least two wheels to propel the hybrid vehicle, and/or to said second electric motor to drive the second electric motor to generate electric power; a first alternating current-direct current (AC-DC) converter having an AC side coupled to said first electric motor, operable to accept AC or DC current and convert the current to DC or AC current respectively; a second AC-DC converter coupled to said second electric motor, at least operable to accept AC current and convert the current to DC; an electrical storage device operable to store energy converted to DC by said AC-DC converters and to provide energy to be converted to AC by at least said first AC-DC converter to power at least said first electric motor; and a controller, operable to start and stop the engine to minimize fuel consumption, and to control the operation of said engine and said first and second motors, and wherein said controller limits a rate of change of torque output of said engine to a threshold value, and wherein when a rate of change of road load exceeds said threshold value of the rate of change of torque output of the engine, said controller is operable to operate said first motor and/or said second motor to supply additional power to at least said two wheels to supply remaining required torque. 15. The method of claim 14, wherein said threshold value is no more than about 2% per revolution. 16. The method of claim 14, wherein said controller is operable to vary said threshold value with respect to a state of charge of said electrical storage device. 17. The method of claim 14, wherein said engine comprises a turbocharger operable to increase the maximum torque output by said engine, and wherein said method comprises the further step of operating said turbocharger when the power required of said engine exceeds a predetermined value for at least a predetermined period of time. 18. The method of claim 14, comprising the further step of preheating said engine prior to starting. 19. A method for controlling a hybrid vehicle, comprising: operating a first alternating current (AC) electric motor comprised in the hybrid vehicle to propel the hybrid vehicle, comprising: providing direct current (DC) from an electrical storage device to a DC side of a first alternating current-direct current (AC-DC) converter; the first AC-DC converter converting the DC to AC; providing the AC to the first AC electric motor to drive the AC electric motor; and providing power from the first AC electric motor to at least two wheels of the hybrid vehicle; starting and operating an engine comprised in the hybrid vehicle to propel the vehicle and/or drive a second AC electric motor comprised in the hybrid vehicle to generate electric power, comprising providing power to the at least two wheels and/or the second AC electric motor respectively; converting the generated electric power from AC to DC using a second AC-DC converter; storing the converted electric power in the electrical storage device; limiting a rate of change of torque output of the engine to a threshold value; and operating the first and/or the second AC electric motors to supply additional power to the at least two wheels to supply remaining required torque when a rate of change of road load exceeds the threshold value of the rate of change of torque output of the engine. 20. The method of claim 19, further comprising: operating a third AC electric motor to provide power to the at least two wheels of the hybrid vehicle to propel the hybrid vehicle; wherein said providing power to the at least to wheels comprised in said operating the first AC electric motor comprises providing power to a first pair of wheels of the at least two wheels, and wherein said operating the third AC electric motor comprises providing power to a second pair of wheels of the at least to wheels. 21. The method of claim 19, further comprising: operating a turbocharger coupled to the engine of the hybrid vehicle to increase maximum torque output (MTO) produced by the engine when torque required of the engine exceeds a predetermined value for at least a predetermined period of time. 22. A method of control of a hybrid vehicle, said hybrid vehicle comprising: at least two wheels, operable to receive power to propel said hybrid vehicle; a first alternating current (AC) electric motor, operable to provide power to said at least two wheels to propel said hybrid vehicle; a second AC electric motor; an engine coupled to said second electric motor, operable to provide power to said at least two wheels to propel the hybrid vehicle, and/or to said second electric motor to drive the second electric motor to generate electric power; a first alternating current-direct current (AC-DC) converter having an AC side coupled to said first electric motor, operable to accept AC or DC and convert the AC or DC to DC or AC respectively; a second AC-DC converter coupled to said second electric motor, at least operable to accept AC and convert the AC to DC; an electrical storage device operable to store energy converted to DC by said AC-DC converters and to provide energy to be converted to AC by at least said first AC-DC converter to power at least said first electric motor; and a controller, operable to monitor road load and battery charging load; wherein said controller performs the following additional steps: starts and stops said engine at any speed of said hybrid vehicle; disables engine operation under operational circumstances where supplying the load with torque from said engine would result in the engine being required to supply torque at a level less than 20% of a maximum torque output (MTO) of said engine; and enables engine operation at any required combination of its speed and its torque, except said condition of disabling operation. 23. The method of claim 22, wherein said controller starts and operates said engine when said load on said engine is sufficient to require said engine to produce torque at least equal to a setpoint (SP), and wherein said SP is substantially less than the MTO of said engine. 24. The method of claim 23, wherein said controller disables engine operation when the load on said engine results in torque below a second setpoint (SP2), wherein said SP2 is less than said SP. 25. The method of claim 23, wherein said SP varies over said engine speed range. 26. The method of claim 23, wherein the controller is operable to start and operate the engine at torque output levels less than SP under abnormal and transient conditions to satisfy drivability and/or safety considerations. 27. The method of claim 22, wherein a rate of change of torque output of said engine is limited to a threshold value, wherein when a rate of change of the road load exceeds said threshold value of the rate of change of torque output of the engine, said controller is operable to operate said first motor and/or said second motor to supply additional power to at least said two wheels to supply remaining required torque. 28. The method of claim 27, wherein said threshold value is no more than about 2% per revolution. 29. The method of claim 27, wherein said controller is operable to vary said threshold value with respect to a state of charge of said electrical storage device. 30. The method of claim 22, wherein said engine comprises a turbocharger operable to increase the maximum torque output by said engine, and wherein said method comprises the further step of operating said turbocharger when the power required of said engine exceeds a predetermined value for at least a predetermined period of time. 31. The method of claim 22, comprising the further step of preheating said engine prior to starting. 32. The method of claim 22, wherein said vehicle comprises a cabin air conditioning system including a compressor driven by a further electric motor powered by power from said electrical storage device, whereby said air conditioning system is operable independently of the operation of said engine. 33. The method of claim 22, wherein when maximum DC power is being supplied from said electrical storage device, said maximum DC power is provided at a DC voltage of at least about 500 volts. 34. The method of claim 22, wherein DC power supplied from said electrical storage device is provided at a maximum current of no more than about 150 amperes. 35. The method of claim 22, wherein when maximum DC power is being supplied from said electrical storage device, the ratio of voltage to current is at least about 2.5:1. 36. A method for controlling a hybrid vehicle, comprising: operating a first alternating current (AC) electric motor comprised in the hybrid vehicle to propel the hybrid vehicle, comprising: providing direct current (DC) to a DC side of a first alternating current-direct current (AC-DC) converter, said DC being supplied from an electrical storage device; the first AC-DC converter converting the DC to AC; providing the AC to the first AC electric motor to drive the AC electric motor; and providing power from the first AC electric motor to at least two wheels of the hybrid vehicle; starting and operating an engine comprised in the hybrid vehicle to propel the vehicle and/or drive a second AC electric motor comprised in the hybrid vehicle to generate electric power, comprising providing power to the at least two wheels and/or the second AC electric motor respectively; converting the generated electric power from AC to DC using a second AC-DC converter; storing the converted electric power in the electrical storage device; and disabling engine operation when load on the engine results in the engine being required to supply torque at a level that is substantially less than a maximum torque output (MTO) of the engine; wherein said step of starting and operating the engine comprises starting and operating the engine at any required combination of its speed and its torque, except when the load on the engine would result in the engine being required to supply torque at a level that is substantially less than the MTO of the engine; and wherein said step of disabling and said step of starting and operating said engine occur independently of any particular speed of the hybrid vehicle. 37. The method of claim 36, wherein said vehicle further comprises a cabin air conditioning system including a compressor driven by a further electric motor powered by power from said electrical storage device, whereby said air conditioning system is operable independently of the operation of said engine. 38. The method of claim 36, wherein when maximum DC power is being supplied from said electrical storage device, said maximum DC power is provided at a DC voltage of at least about 500 volts. 39. The method of claim 36, wherein DC power supplied from said electrical storage device is provided at a maximum current of no more than about 150 amperes. 40. The hybrid vehicle of claim 36, wherein when maximum DC power is being supplied from said electrical storage device, the ratio of voltage to current is at least about 2.5:1. 41. A hybrid vehicle, comprising: at least two wheels, operable to receive power to propel said hybrid vehicle; a first alternating current (AC) electric motor, operable to provide power to said at least two wheels to propel said hybrid vehicle; a second AC electric motor; an engine coupled to said second electric motor, operable to provide power to said at least two wheels to propel the hybrid vehicle, and/or to said second electric motor to drive the second electric motor to generate electric power; a first alternating current-direct current (AC-DC) converter having an AC side coupled to said first electric motor, operable to accept AC or DC current and convert the current to DC or AC current respectively; a second AC-DC converter coupled to said second electric motor, at least operable to accept AC current and convert the current to DC; an electrical storage device operable to store energy converted to DC by said AC-DC converters and to provide energy to be converted to AC by at least said first AC-DC converter to power at least said first electric motor; and a controller operable to: start and stop said engine at any speed of said hybrid vehicle; monitor a signal responsive at least to road load; and start and operate said engine when said signal corresponds to a value at least equal to a setpoint (SP), wherein SP is approximately 20% of the MTO of said engine, and disable engine operation when said signal corresponds to a value less than the same or a different setpoint. 42. The hybrid vehicle of claim 41, wherein said controller disables operation of said engine when said signal is less than SP. 43. The hybrid vehicle of claim 41, wherein said controller is operable to disable engine operation when said signal is below a second setpoint (SP2), wherein SP2 is less than SP. 44. The hybrid vehicle of claim 41, wherein said second electric motor is sized so as to be able to accept said engine torque equal to at least said SP. 45. The hybrid vehicle of claim 41, wherein said SP varies over said engine speed range. 46. The hybrid vehicle of claim 41, wherein a rate of change of torque output of said engine is limited to a threshold value, wherein when a rate of change of the road load exceeds said threshold value of the rate of change of torque output of the engine, said controller is operable to operate said first motor and/or said second motor to supply additional power to at least said two wheels to supply remaining required torque. 47. The hybrid vehicle of claim 46, wherein said threshold value is no more than about 2% per revolution. 48. The hybrid vehicle of claim 46, wherein said controller is operable to vary said threshold value with respect to a state of charge of said electrical storage device. 49. The hybrid vehicle of claim 41, wherein a maximum torque on at least said two wheels produced by said first electric motor or both electric motors is larger than a maximum torque on at least said two wheels produced by said engine. 50. The hybrid vehicle of claim 41, wherein a maximum rotational speed of said first electric motor is at least 50% greater than a maximum rotational speed of said engine. 51. The hybrid vehicle of claim 41, wherein said first AC electric motor is coupled to a first pair of wheels to provide power to said first pair of wheels to propel said hybrid vehicle, and a third AC electric motor is provided coupled to a second pair of wheels to provide power to said second pair of wheels to propel said hybrid vehicle. 52. The hybrid vehicle of claim 51, wherein the relative amounts of power directed to said first and second pairs of wheels by the first and third electric motors, respectively, are controlled by said controller. 53. The hybrid vehicle of claim 51, wherein a torque range-broadening transmission is interposed between said engine and said at least said two wheels to which said engine is operable to provide power. 54. The hybrid vehicle of claim 51, wherein a maximum torque provided to said first and second pairs of two wheels by said first and third electric motors, or by said first and third electric motors and said second electric motor, is larger than a maximum torque on at least said two wheels produced by said engine. 55. The hybrid vehicle of claim 51, wherein a maximum rotational speed of said third electric motor is at least 50% greater than a maximum rotational speed of said engine. 56. The hybrid vehicle of claim 41, wherein said engine comprises a turbocharger operable to increase the maximum torque output by said engine, and wherein said turbocharger is so operated when the power required of said engine exceeds a predetermined value for at least a predetermined period of time. 57. The hybrid vehicle of claim 41, wherein said engine is preheated prior to starting. 58. The hybrid vehicle of claim 41, further comprising: a third AC electric motor; wherein said first alternating current (AC) electric motor is coupled to a first pair of wheels to provide power to said first pair of wheels to propel said hybrid vehicle, and said third AC electric motor is coupled to a second pair of wheels to provide power to said second pair of wheels to propel said hybrid vehicle; and wherein a rate of change of torque output of said engine is limited to a threshold value, wherein when a rate of change of the road load exceeds said threshold value of the rate of change of torque output of the engine, said controller is operable to operate said first motor and/or said second and/or third motors to supply additional power to at least said two wheels to supply remaining required torque. 59. The hybrid vehicle of claim 41, further comprising: a third AC electric motor; wherein said first alternating current (AC) electric motor is coupled to a first pair of wheels to provide power to said first pair of wheels to propel said hybrid vehicle, and said third AC electric motor is coupled to a second pair of wheels to provide power to said second pair of wheels to propel said hybrid vehicle; and wherein said engine comprises a turbocharger operable to increase the maximum torque output by said engine, and wherein said turbocharger is so operated when the power required of said engine exceeds a predetermined value for at least a predetermined period of time. 60. The hybrid vehicle of claim 41, wherein said engine comprises a turbocharger operable to increase the maximum torque output by said engine, and wherein said turbocharger is so operated when the power required of said engine exceeds a predetermined value for at least a predetermined period of time; and wherein a rate of change of torque output of said engine is limited to a threshold value, wherein when a rate of change of the vehicle load exceeds said threshold value of the rate of change of torque output of the engine, said controller is operable to operate said first motor and/or said second and/or third motors to supply additional power to at least said two wheels to supply remaining required torque. 61. The hybrid vehicle of claim 41, further comprising: a third AC electric motor; wherein said first alternating current (AC) electric motor is coupled to a first pair of wheels to provide power to said first pair of wheels to propel said hybrid vehicle, and said third AC electric motor is coupled to a second pair of wheels to provide power to said second pair of wheels to propel said hybrid vehicle; wherein said engine comprises a turbocharger operable to increase the maximum torque output by said engine, and wherein said turbocharger is so operated when the power required of said engine exceeds a predetermined value for at least a predetermined period of time; and wherein a rate of change of torque output of said engine is limited to a threshold value, wherein when a rate of change of the road load exceeds said threshold value of the rate of change of torque output of the engine, said controller is operable to operate said first motor and/or said second and/or third motors to supply additional power to at least said two wheels to supply remaining required torque. 62. The hybrid vehicle of claim 41, wherein a rate of change of torque output of said engine is limited to a threshold value, wherein when a rate of change of road load exceeds said threshold value of the rate of change of torque output of the engine, said controller is operable to operate said first motor and/or said second motor to supply additional power to at least said two wheels to supply remaining required torque. 63. The hybrid vehicle of claim 41, wherein said vehicle comprises a cabin air conditioning system including a compressor driven by a further electric motor powered by power from said electrical storage device, whereby said air conditioning system is operable independently of the operation of said engine. 64. The hybrid vehicle of claim 41, wherein when maximum DC power is being supplied from said electrical storage device, said maximum DC power is provided at a DC voltage of at least about 500 volts. 65. The hybrid vehicle of claim 41, wherein DC power supplied from said electrical storage device is provided at a maximum current of no more than about 150 amperes. 66. The hybrid vehicle of claim 41, wherein when maximum DC power is being supplied from said electrical storage device, the ratio of voltage to current is at least about 2.5:1. 67. A method for controlling a hybrid vehicle, comprising: operating a first alternating current (AC) electric motor comprised in the hybrid vehicle to propel the hybrid vehicle, comprising: providing direct current (DC) to a DC side of a first alternating current-direct current (AC-DC) converter, wherein said DC originates at an electrical storage device; the first AC-DC converter converting the DC to AC; providing the AC to the first AC electric motor to drive the AC electric motor; and providing power from the first AC electric motor to at least two wheels of the hybrid vehicle; starting and operating an engine comprised in the hybrid vehicle to propel the vehicle and/or drive a second AC electric motor comprised in the hybrid vehicle to generate electric power, comprising providing power to the at least two wheels and/or the second AC electric motor respectively; converting the generated electric power from AC to DC using a second AC-DC converter; storing the converted electric power in the electrical storage device; and disabling engine operation when load on the engine results in the engine being loaded to a value SP that is substantially less than a maximum torque output (MTO) of the engine; wherein said step of starting and operating the engine comprises starting and operating the engine at any required combination of its speed and its torque, except when the load on the engine would require the engine to supply less than SP; and wherein said steps of disabling and starting and operating said engine occur independently of any particular speed of the hybrid vehicle. 68. The method of claim 67, further comprising: limiting a rate of change of torque output of the engine to a threshold value; and operating the first and/or the second AC electric motors to supply additional power to the at least two wheels to supply remaining required torque when a rate of change of said road load exceeds the threshold value of the rate of change of torque output of the engine. 69. The method of claim 67, further comprising: operating a third AC electric motor to provide power to the at least two wheels of the hybrid vehicle to propel the hybrid vehicle; wherein said step of providing power to the at least two wheels comprised in said step of operating the first AC electric motor comprises providing power to a first pair of wheels of the at least two wheels, and wherein said step of operating the third AC electric motor comprises the step of providing power to a second pair of wheels of the at least two wheels. 70. The method of claim 67, further comprising: operating a turbocharger coupled to the engine of the hybrid vehicle to increase maximum torque output (MTO) produced by the engine when torque required of the engine exceeds a predetermined value for at least a predetermined period of time. 71. The method of claim 67, wherein said vehicle further comprises a cabin air conditioning system including a compressor driven by a further electric motor powered by power from said electrical storage device, whereby said air conditioning system is operable independently of the operation of said engine. 72. The method of claim 67, wherein when maximum DC power is being supplied from said electrical storage device, said maximum DC power is provided at a DC voltage of at least about 500 volts. 73. The method of claim 67, wherein DC power supplied from said electrical storage device is provided at a maximum current of no more than about 150 amperes. 74. The method of claim 67, wherein when maximum DC power is being supplied from said electrical storage device, the ratio of voltage to current is at least about 2.5:1.