Hybrid powertrain and method for controlling a hybrid powertrain
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G06F-019/00
G06G-007/70
출원번호
US-0281088
(2007-03-09)
등록번호
US-8606482
(2013-12-10)
우선권정보
WO-PCT/SE2006/000314 (2006-03-09)
국제출원번호
PCT/SE2007/000229
(2007-03-09)
§371/§102 date
20080828
(20080828)
국제공개번호
WO2007/102776
(2007-09-13)
발명자
/ 주소
Carlhammar, Lars
Karlsson, Svante
Panagopoulos, Helene
출원인 / 주소
Volvo Technology Corporation
대리인 / 주소
WRB-IP LLP
인용정보
피인용 횟수 :
1인용 특허 :
5
초록▼
A hybrid powertrain includes a combustion engine, an electric machine arrangement, a gearbox operable to receive motive power from at least one of the combustion engine and the electric machine arrangement for providing motive power to a load of the powertrain. The powertrain is configurable in oper
A hybrid powertrain includes a combustion engine, an electric machine arrangement, a gearbox operable to receive motive power from at least one of the combustion engine and the electric machine arrangement for providing motive power to a load of the powertrain. The powertrain is configurable in operation so that its combustion engine is switchable between an inactive state and an active state. The combustion engine is cranked to switch it from its inactive state to its active state. Application of cranking torque to the combustion engine is controlled in operation to substantially temporally coincide with a gear change in the gearbox.
대표청구항▼
1. A hybrid powertrain including: a combustion engine;an electric machine arrangement;a gearbox operable to receive motive power from at least one of the combustion engine and the electric machine arrangement for providing corresponding motive power to a load;a control unit coupled in communication
1. A hybrid powertrain including: a combustion engine;an electric machine arrangement;a gearbox operable to receive motive power from at least one of the combustion engine and the electric machine arrangement for providing corresponding motive power to a load;a control unit coupled in communication with the combustion engine, the electric machine arrangement and the gearbox for controlling their operation;wherein the powertrain is configurable in operation so that its combustion engine is switchable between an inactive state and an active state, the combustion engine requiring to be cranked to switch it from its inactive state to its active state,whereinthe control unit includes multiple-inputs for receiving feedback signals derived from the powertrain and command signals to the powertrain and multiple-outputs for outputting output signals for controlling operation of the powertrain; andthe control unit further includes computing hardware operable to execute a torque simulation of the powertrain, the simulation being applicable in operation to process information provided at the multiple-inputs to compute a compensation, the control unit being operable to apply the compensation at the multiple outputs to reduce an amplitude of torque jerks occurring in operation in the powertrain when the engine is switched between its active and inactive states, wherein application of cranking torque to the combustion engine is controlled in operation by the control unit to substantially temporally coincide with a gear change in the gearbox. 2. A powertrain as claimed in claim 1, wherein, whilst the gearbox is in a neutral coupling state, the combustion engine is operable to be cranked by decelerating the electric machine arrangement to substantially a standstill, at least partially rotationally coupling via a rotational coupling arrangement the combustion engine to the electric machine arrangement, applying excitation to the electric machine arrangement to rotationally accelerate it and thereby accelerating the combustion engine to a threshold rotation rate, and then applying a fuel supply to the combustion engine to bring the combustion engine to an active state. 3. A powertrain as claimed in claim 2, wherein the rotational coupling arrangement includes a slipping clutch operable to provide a constant-torque coupling characteristic through at least part of its slippage range. 4. A powertrain as claimed in claim 1, wherein, whilst the gearbox is in a neutral coupling state, the combustion engine is operable to be cranked by maintaining the electric machine arrangement in a rotating state, at least partially coupling via a rotational coupling arrangement the combustion engine to the electric machine arrangement to transfer torque therefrom to the combustion engine thereby accelerating, the combustion engine to a threshold rotation rate, and then applying a fuel supply to the combustion engine to bring the combustion engine to an active state. 5. A powertrain as claimed in claim 1, wherein the rotational coupling arrangement of the powertrain includes a clutch couplable between the combustion engine and the electric machine arrangement. 6. A powertrain as claimed in claim 5, wherein the electric machine arrangement is coupled via a series arrangement of the clutch and a rotationally-compliant torque coupling to the combustion engine. 7. A powertrain as claimed in claim 1, wherein one or more rotational shafts of the combustion engine and the electric machine arrangement are provided with one or more sensors coupled to the control unit for determining a measure of torque coupled to the combustion engine when cranking the combustion engine and causing it to be activated, such measure of torque being processed by the control unit for providing control of the electric machine arrangement for at least partially compensating any abrupt changes in torque occurring in the powertrain. 8. A powertrain as claimed in claim 7, wherein the one or more sensors are implemented as rotation rate sensors for measuring rotation rate of their one or more shafts, the measure of torque being computed by the control unit from inertial moments of components parts of the powertrain and from angular acceleration temporally computed from the one or more measured rotation rates. 9. A vehicle including a hybrid powertrain as claimed in claim 1. 10. A vehicle as claimed in claim 9, the vehicle being selected from a group: a bus, a truck, a construction vehicle, a van, a passenger vehicle, a boat, a ship, a stationary machine, or any type of vehicle which is required in operation to exhibit relatively high acceleration in a stop-start manner of driving. 11. A method of controlling a hybrid powertrain the hybrid powertrain including a combustion engine, an electric machine arrangement, a gearbox operable to receive rotational power from one or more of the combustion engine and the electric machine arrangement, and to provide motive power to a load, a control unit coupled in communication with the combustion engine, the electric machine arrangement and the gearbox for controlling their operation, and wherein the powertrain is configurable in operation so that its combustion engine is switchable between inactive state and an active state, the combustion engine requiring to be cranked to switch it from its inactive state to its active state, the method comprising:receiving feedback signals derived from the powertrain and command signals at multiple inputs of the control unit, and outputting output signals at multiple-outputs of the powertrain for controlling operation of the powertrain;applying at the control unit a torque simulation of the powertrain executable on computing hardware of the control unit, the simulation being applicable in operation to process information provided at the multiple-inputs to compute a compensation, the control unit being operable to apply the compensation at the multiple-outputs to reduce an amplitude of torque jerks occurring in operation in the powertrain when the engine is switched between its active and inactive states;initiating a gear change by reducing torque supplied to the gearbox and then placing the gearbox in its neutral state; andcontrolling application of cranking torque to the combustion engine to substantially temporally coincide with the gearbox being in the neutral state the cranking torque and supply of fuel to the combustion engine being operable to cause the combustion engine to be activated. 12. A method as claimed in claim 11, the method including engaging the gearbox into gear and then increasing torque supplied to the gearbox. 13. A method as claimed in claim 12, the method including: whilst the gearbox is in a neutral coupling state, cranking the combustion engine by decelerating the electric machine arrangement to substantially a standstill;at least partially coupling via a rotational coupling arrangement the combustion engine to the electric machine arrangement,applying excitation to the electric machine arrangement to rotationallyaccelerate the electric machine arrangement and thereby accelerating the combustion engine to a threshold rotation rate; and thenapplying a fuel supply to the combustion engine to bring the combustion engine to an active stale. 14. A method as claimed in claim 13, the method including: whilst the gearbox is in a neutral coupling state, cranking the combustion engine by maintaining the electric machine arrangement in a rotating state;at least partially coupling via the rotational coupling arrangement the combustion engine to the electric machine arrangement to transfer torque from the electric machine arrangement to the combustion engine thereby accelerating the combustion engine to a threshold rotation rate; and thenapplying a fuel supply to the combustion engine to bring the combustion engine to an active state. 15. A method as claimed in claim 14, wherein the coupling arrangement includes a slipping clutch operable to provide a constant-torque coupling characteristic through at least part of its slippage range. 16. A non-transitory data carrier comprising a computer program, the computer program being executable on computing hardware for controlling a method as claimed in claim 11. 17. A non-transitory storage medium including a computer program comprising computer program code adapted to perform a method or for use in a method as claimed in claim 11 when the computer program is run on a programmable microcomputer. 18. The non-transitory storage medium including a computer program according to claim 17 adapted to be downloaded to a powertrain when run on a computer which is connected to the Internet. 19. A hybrid powertrain including: a combustion engine;an electric machine arrangement;a gearbox operable to receive motive power from at least one of the combustion engine and the electric machine arrangement for providing corresponding motive power to a load;a control unit coupled in communication with the combustion engine, the electric machine arrangement and the gearbox for controlling their operation;wherein the powertrain is configurable in operation so that its combustion engine is switchable between an inactive state and an active state, the combustion engine requiring to be cranked to switch it from its inactive state to its active state,whereinthe control unit includes multiple-inputs for receiving feedback signals derived from the powertrain and at least one command signal to the powertrain and multiple-outputs for outputting output signals for controlling operation of the powertrain; andthe control unit further includes computing hardware operable to execute a torque simulation of the powertrain, the simulation being applicable in operation to process information provided at the multiple-inputs to compute a compensation, the control unit being operable to apply the compensation to at least one of the multiple outputs to reduce an amplitude of torque jerks occurring in operation in the powertrain when the engine is switched between its active and inactive states, wherein application of cranking torque to the combustion engine is controlled in operation by the control unit to substantially temporally coincide with a gear change in the gearbox. 20. A hybrid powertrain according to claim 19, wherein the control unit being operable to apply the compensation to the electric machine arrangement.
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이 특허에 인용된 특허 (5)
Lutz Dieter,DEX ; Bauch-Panetzky Dieter,DEX ; Thieler Wolfgang,DEX, Drive arrangement for a hybrid vehicle.
Atsushi Matsubara JP; Kazutomo Sawamura JP; Shinichi Kitajima JP; Atsushi Izumiura JP; Teruo Wakashiro JP, Engine stall prevention apparatus for a hybrid vehicle provided with a mechanism that changes the engine speed depending on clutch state detection.
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