Traction control system for an electric vehicle
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B60L-011/00
G06F-017/00
출원번호
UP-0381853
(2009-03-17)
등록번호
US-7747363
(2010-07-19)
발명자
/ 주소
Tang, Yifan
출원인 / 주소
Tesla Motors, Inc.
대리인 / 주소
Patent Law Office of David G. Beck
인용정보
피인용 횟수 :
18인용 특허 :
2
초록
A method and apparatus for optimizing the torque of the electric motor of an electric vehicle is provided, the torque adjustments taking into account wheel slip as well as other vehicular operating conditions.
대표청구항▼
What is claimed is: 1. An electric vehicle drive system, comprising: a drive system, comprising: an electric motor, said electric motor mechanically coupled to at least one wheel of a first vehicle axle, wherein said electric motor provides propulsion power to said at least one wheel of said first
What is claimed is: 1. An electric vehicle drive system, comprising: a drive system, comprising: an electric motor, said electric motor mechanically coupled to at least one wheel of a first vehicle axle, wherein said electric motor provides propulsion power to said at least one wheel of said first vehicle axle; and a power control module electrically connected to said electric motor, said power control module configured to receive motor torque commands, and said power control module configured to control said electric motor based on said motor torque commands; at least one wheel speed sensor; and a torque control system electrically connected to said power control module and to said at least one wheel speed sensor, wherein said torque control system outputs said motor torque commands to said power control module, wherein said torque control system further comprises: a traction control command generation unit for computing vehicle speed, wheel slip ratios corresponding to said at least one wheel speed sensor, and a slip error corresponding to said first vehicle axle; a torque control unit for computing an optimal motor torque request based on said vehicle speed and a required drive torque request; a traction control unit comprising: a first stage feedback control system for minimizing said slip error; and a torque limiter for transforming said optimal motor torque request into said motor torque command in response to an output from said first stage feedback control system. 2. The electric vehicle drive system of claim 1, wherein said torque control unit cycles at a first frequency, wherein said traction control unit cycles at a second frequency, and wherein said second frequency is between 10 and 30 times said first frequency. 3. The electric vehicle drive system of claim 2, wherein said first frequency is in the range of 100 Hz to 2 kHz. 4. The electric vehicle drive system of claim 1, further comprising at least one motor speed sensor, said traction control unit further comprising a second stage feedback control system for minimizing motor speed fast disturbances, wherein said torque limiter operates in response to said output from said first stage feedback control system and an output from said second stage feedback control system. 5. The electric vehicle drive system of claim 1, said torque control system further comprising a vehicle torque command generation unit for computing said required drive torque request from said vehicle speed and from a plurality of user input sensors, said user input sensors comprised of a brake sensor and an accelerator sensor. 6. The electric vehicle drive system of claim 1, further comprising: a motor speed sensor; a motor temperature sensor; and wherein said torque control system further comprises: a torque limiting unit for computing a motor maximum available torque, wherein said torque limiting unit is coupled to said motor speed and temperature sensors; and wherein said torque limiter limits said motor torque command by said motor maximum available torque. 7. The electric vehicle drive system of claim 6, further comprising a power control module temperature sensor, wherein said torque limiting unit is coupled to said power control module temperature sensor. 8. The electric vehicle drive system of claim 6, further comprising: an energy storage system (ESS) coupled to said power control module; an ESS temperature sensor; an ESS voltage sensor; an ESS current sensor; and wherein said torque limiting unit is coupled to said ESS temperature, voltage and current sensors. 9. The electric vehicle drive system of claim 1, said torque control system further comprising a torque limiting unit for computing a motor maximum available torque, wherein said optimal motor torque request is limited by said motor maximum available torque. 10. The electric vehicle drive system of claim 1, wherein said optimal motor torque request is interpolated from a look-up table. 11. The electric vehicle drive system of claim 1, wherein said torque control unit computes an optimal motor flux command, wherein said power control module is configured to receive said optimal motor flux commands and control said motor based on said motor torque commands and on said optimal motor flux commands. 12. The electric vehicle drive system of claim 1, further comprising: a motor speed sensor coupled to said electric motor and electrically connected to said torque control system; a steering sensor electrically connected to said torque control system; and wherein said traction control command generation unit computes said vehicle speed based on output from said motor speed sensor and said steering sensor. 13. A method of enhancing traction of an electric vehicle, the electric vehicle having an electric motor coupled to a first axle, the method comprising the steps of: a) monitoring at least one first wheel speed sensor corresponding to said first axle and monitoring a motor speed sensor, and computing a vehicle speed corresponding to said electric vehicle based on output from said at least one first wheel speed sensor and said motor speed sensor, wherein said vehicle speed computing step is performed by a traction control command generation unit; b) monitoring a brake sensor and an accelerator sensor, and computing a torque requirement request based on output from said brake sensor and said accelerator sensor and said vehicle speed, wherein said torque requirement request computing step is performed by a vehicle torque command generation unit; c) transforming said torque requirement request into an optimal motor torque request, wherein said torque requirement request transforming step is performed by a torque control unit; d) inputting a first wheel target slip ratio and computing a first slip error corresponding to said first axle based on output from said at least one first wheel speed sensor and said vehicle speed and said first wheel target slip ratio, wherein said first slip error computing step is performed by said traction control command generation unit; e) minimizing said slip error using a feedback control system implemented by a traction control unit, said traction control unit further performing the steps of transforming said optimal motor torque request into a motor torque command based on said step of minimizing said slip error; f) controlling said electric motor based on said motor torque command; and g) repeating steps a)-f) throughout operation of said electric vehicle. 14. The method of claim 13, further comprising the step of: monitoring a steering sensor, wherein said step of computing said vehicle speed is based on output from said at least one first wheel speed sensor, said motor speed sensor, and said steering sensor. 15. The method of claim 13, wherein said torque requirement request transforming step further comprises the step of interpolating data from a look-up table, said look-up table containing said optimal motor torque request as a function of said vehicle speed and said torque requirement request. 16. The method of claim 13, step c) further comprising the steps of: monitoring a motor temperature sensor; computing a motor maximum available torque based on output from said motor speed sensor and said motor temperature sensor; and limiting said optimal motor torque request by said motor maximum available torque. 17. The method of claim 16, further comprising the steps of monitoring a power control module temperature sensor, said power control module temperature sensor in thermal communication with a power control module, said power control module electrically connected to said motor, wherein said motor maximum available torque computing step is further based on output from said power control module temperature sensor. 18. The method of claim 16, further comprising the steps of: monitoring an energy storage system (ESS) temperature sensor, said ESS temperature sensor in thermal communication with an ESS, said ESS electrically connected to a power control module, said power control module electrically connected to said motor; monitoring an ESS voltage sensor; and monitoring an ESS current sensor, wherein said motor maximum available torque computing step is further based on output from said ESS temperature sensor, said ESS voltage sensor and said ESS current sensor. 19. The method of claim 13, further comprising the step of minimizing motor speed fast disturbances using a second feedback control system implemented by said traction control unit, wherein said step of transforming said optimal motor torque request into said motor torque command are based on said step of minimizing said slip error and based on said step of minimizing said motor speed fast disturbances. 20. The method of claim 13, step f) further comprising the steps of: monitoring a motor temperature sensor; computing a motor maximum available torque based on output from said motor speed sensor and said motor temperature sensor; and limiting said motor torque command by said motor maximum available torque. 21. The method of claim 20, further comprising the step of monitoring a power control module temperature sensor, said power control module temperature sensor in thermal communication with a power control module, said power control module electrically connected to said motor, wherein said motor maximum available torque computing step is further based on output from said power control module temperature sensor. 22. The method of claim 20, further comprising the steps of: monitoring an energy storage system (ESS) temperature sensor, said ESS temperature sensor in thermal communication with an ESS, said ESS electrically connected to a power control module, said power control module electrically connected to said motor; monitoring an ESS voltage sensor; and monitoring an ESS current sensor, wherein said motor maximum available torque computing step is further based on output from said ESS temperature sensor, said ESS voltage sensor and said ESS current sensor. 23. The method of claim 12, wherein steps a) through d) are repeated at a first frequency and steps e) through f) are repeated at a second frequency, wherein said second frequency is between 10 and 30 times said first frequency. 24. The method of claim 13, wherein steps b) and c) are repeated at a first frequency, steps e) through f) are repeated at a second frequency between 10 and 30 times said first frequency, and wherein steps a) and d) are repeated at a third frequency, said third frequency between said first and second frequencies. 25. The method of claim 13, further comprising the step of computing an optimal motor flux command, wherein said step of computing said optimal motor flux command further comprises the step of interpolating data from a look-up table, said look-up table containing said optimal motor flux command as a function of said vehicle speed and said torque requirement request.
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이 특허에 인용된 특허 (2)
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