System and method for operating an electric motor by limiting performance
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B60W-020/00
출원번호
UP-0422731
(2006-06-07)
등록번호
US-7533744
(2009-07-01)
발명자
/ 주소
Mack, David J.
출원인 / 주소
Ford Global Technologies, LLC
대리인 / 주소
Kelley, David B.
인용정보
피인용 횟수 :
7인용 특허 :
21
초록▼
A method and system for limiting motor performance in a hybrid electric vehicle system. During a condition in a primary drivetrain, the method limits performance of an electric motor used in an auxiliary drivetrain to control energy consumed from a battery in the auxiliary drivetrain. A calculation
A method and system for limiting motor performance in a hybrid electric vehicle system. During a condition in a primary drivetrain, the method limits performance of an electric motor used in an auxiliary drivetrain to control energy consumed from a battery in the auxiliary drivetrain. A calculation or measurement is made to determine available battery energy remaining in the battery after the condition. The performance of the electric motor is then limited based on the available battery energy.
대표청구항▼
What is claimed: 1. A method for use in an electrically driven vehicle having a primary drivetrain and an auxiliary drivetrain, the auxiliary drivetrain being an electric only drivetrain having capabilities to power an electric motor used to drive the vehicle with energy from a limited supply of st
What is claimed: 1. A method for use in an electrically driven vehicle having a primary drivetrain and an auxiliary drivetrain, the auxiliary drivetrain being an electric only drivetrain having capabilities to power an electric motor used to drive the vehicle with energy from a limited supply of stored energy, the method comprising: controlling a driving characteristic of the auxiliary drive train based on a first performance limiting strategy, the first performance limiting strategy based in part on future availability of the primary drivetrain; and switching control of the driving characteristic to a second performance limiting strategy associated with future unavailability of the primary drivetrain, the second performance limiting strategy associated with controlling power consumption of the electric motor in such a manner as to limit consumption of the stored energy for all motor power demands and not only motor power demands associated with particular vehicle speeds; wherein the second performance limiting strategy includes setting a plurality of maximum vehicle speed ranges based on battery state of charge, the battery state of charge for a battery of the auxiliary drivetrain. 2. The method of claim 1 wherein setting the maximum vehicle speed ranges includes setting the maximum vehicle speed to one of 45 mph if the battery state of charge is above 50%, 35 mph if the battery state of charge is between 50% and 45%, 25 mph if the battery state of charge is between 45% and 35%, and 15 mph if the battery state of charge is between 35% and 20%. 3. A method for use in an electrically driven vehicle having a primary drivetrain and an auxiliary drivetrain, the auxiliary drivetrain being an electric only drivetrain having capabilities to power an electric motor used to drive the vehicle with energy from a limited supply of stored energy, the method comprising: controlling a driving characteristic of the auxiliary drive train based on a first performance limiting strategy, the first performance limiting strategy based in part on future availability of the primary drivetrain; and switching control of the driving characteristic to a second performance limiting strategy associated with future unavailability of the primary drivetrain, the second performance limiting strategy associated with controlling power consumption of the electric motor in such a manner as to limit consumption of the stored energy for all motor power demands and not only motor power demands associated with particular vehicle speeds; wherein the second performance limiting strategy includes setting a plurality of maximum power ranges based on battery state of charge, the battery state of charge for a battery of the auxiliary drivetrain. 4. The method of claim 3 wherein setting the maximum power ranges includes setting the maximum power to one of 25 kW if the battery state of charge is above 50%, 15 kW if the battery state of charge is between 50% and 45%, 10 kW if the battery state of charge is between 45% and 25%, and 5 kW if the battery state of charge is between 35% and 20%. 5. A method for use in an electrically driven vehicle having a primary drivetrain and an auxiliary drivetrain, the auxiliary drivetrain being an electric only drivetrain having capabilities to power an electric motor used to drive the vehicle with energy from a limited supply of stored energy, the method comprising: controlling a driving characteristic of the auxiliary drive train based on a first performance limiting strategy, the first performance limiting strategy based in part on future availability of the primary drivetrain; and switching control of the driving characteristic to a second performance limiting strategy associated with future unavailability of the primary drivetrain, the second performance limiting strategy associated with controlling power consumption of the electric motor in such a manner as to limit consumption of the stored energy for all motor power demands and not only motor power demands associated with particular vehicle speeds; wherein the second performance limiting strategy includes setting a plurality of maximum vehicle speed and a maximum power ranges based on battery state of charge, the battery state of charge for a battery of the auxiliary drivetrain. 6. The method of claim 5 wherein setting the maximum speed and the maximum power ranges comprises setting the maximum speed and the maximum power to one of 45 mph and 25 kW if the battery state of charge is above 50%, 35 mph and 15 kW if the battery state of charge is between 50% and 45%, 25 mph and 10 kW if the battery state of charge is between 45% and 35%, and 15 mph and 5 kW if the battery state of charge is between 35% and 20%. 7. A method of limiting power consumption of an electric motor used to drive a vehicle when a fuel supplied primary power source is unavailable to power the motor, the method comprising: powering the motor with energy from an electric only auxiliary powertrain, the electric only auxiliary powertrain having capabilities to power the electric motor with energy from a limited supply of stored energy; limiting power consumption of the electric motor in such as manner as to limit consumption of the stored energy as a function of motor power demands determined as a function of vehicle speed, load, and acceleration; and limiting motor operations so as to minimize energy consumption from the auxiliary drivetrain and to maximize a length of time for which the vehicle is operable. 8. The method of claim 7 further comprising limiting power consumption as a function of a state of charge of a battery of the auxiliary drivetrain, the battery storing the limited supply of stored energy. 9. The method of claim 7 further comprising limiting power consumption as a function of a discharge limit of a battery of the auxiliary drivetrain, the battery storing the limited supply of stored energy. 10. The method of claim 7 further comprising limiting actual power consumed by the electric motor according to the following algorithm: wherein: AP=actual power (kW); MP=maximum power (kW); MS=maximum vehicle speed (mph); and VS=actual vehicle speed (mph). 11. A vehicle controller configured for: controlling a driving characteristic of an auxiliary drivetrain based on a first performance limiting strategy, the first performance limiting strategy based in part on future availability of the primary drivetrain; switching control of the driving characteristic to a second performance limiting strategy associated with future unavailability of the primary drivetrain, the second performance limiting strategy associated with controlling power consumption of an electric motor in such a manner as to limit consumption of stored energy for all motor power demands and not only motor power demands associated with particular vehicle speeds; and when the controller is further configured for one of: setting the second performance limiting strategy to include a plurality of maximum vehicle speed ranges based on battery state of charge for a battery of the auxiliary drivetrain setting the second performance limiting strategy to include a plurality of maximum power ranges based on battery state of charge for a battery of the auxiliary drivetrain setting the second performance limiting strategy to include a plurality of maximum vehicle speed and a maximum power ranges based on battery state of charge, the battery state of charge for a battery of the auxiliary drivetrain limiting the consumption of stored energy as a function of available energy and independently of vehicle speed; or setting the second performance limiting strategy to include limiting actual power consumed by the motor according to the following algorithm: wherein: AP =actual power (kW); MP =maximum power (kW); MS =maximum vehicle speed (mph); and VS =actual vehicle speed (mph).
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