System for control of brake actuator based at least in part upon tire/road friction force
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B60T-008/66
B60T-008/60
출원번호
US-0088282
(2005-03-24)
등록번호
US-7448701
(2008-11-11)
발명자
/ 주소
Nilsson,Peter
Nockhammar,Ola
출원인 / 주소
Haldex Brake Products AB
대리인 / 주소
St. Onge Steward Johnston & Reens LLC
인용정보
피인용 횟수 :
7인용 특허 :
14
초록▼
A vehicle brake system includes a brake actuator associated with a wheel, the brake actuator having at least one moveable brake component, and a brake control system operative to determine a target rotational velocity of the wheel based at least in part on a relationship between an actual tire/road
A vehicle brake system includes a brake actuator associated with a wheel, the brake actuator having at least one moveable brake component, and a brake control system operative to determine a target rotational velocity of the wheel based at least in part on a relationship between an actual tire/road friction force and a target tire/road friction force, the brake control system determining a target position of the at least one moveable brake component based at least in part upon the target rotational velocity. The brake control system is operable to control actuation of the brake actuator based at least in part upon the target position of the at least one moveable brake component and at least in part based upon a current position of the at least one moveable brake component.
대표청구항▼
What is claimed is: 1. A vehicle brake system comprising: a brake actuator associated with a wheel, said brake actuator having at least one moveable brake component; a brake control system operative to determine a target rotational velocity of the wheel based at least in part on a relationship betw
What is claimed is: 1. A vehicle brake system comprising: a brake actuator associated with a wheel, said brake actuator having at least one moveable brake component; a brake control system operative to determine a target rotational velocity of the wheel based at least in part on a relationship between an actual tire/road friction force and a target tire/road friction force, said brake control system determining a target position of the at least one moveable brake component based at least in part upon the target rotational velocity; and wherein said brake control system is operable to control actuation of said brake actuator based at least in part upon a comparison of the target position of the at least one moveable brake component with a current position of the at least one moveable brake component. 2. The vehicle brake system of claim 1 wherein said actual tire/road friction force is determined based at least in part upon a determined brake torque and at least in part upon a determined rotational acceleration/retardation of the wheel. 3. The vehicle brake system of claim 2 wherein the actual tire/road friction force is determined based further at least in part upon dimensions of the wheel. 4. The vehicle brake system of claim 1 wherein the actual tire/road friction force is determined based at least in part upon determined static and dynamic properties of tire/road interactions of the wheel, at least in part upon a determined tire/road wheel slip of the wheel, at least in part upon a determined load force of the wheel, and at least in part upon a determined tire/road friction coefficient of the wheel. 5. The vehicle brake system of claim 4 wherein the tire/road friction coefficient of the wheel is determined based at least in part upon the determined tire/road wheel slip of the wheel, at least in part upon a determined brake torque of the wheel, at least in part upon the determined load force of the wheel, and at least in part upon dimensions of the wheel. 6. The vehicle brake system of claim 4 wherein the static and dynamic properties of tire/road interactions of the wheel are determined based at least in part upon the determined tire/road wheel slip of the wheel, at least in part upon a determined brake torque of the wheel, and at least in part upon the determined load force of the wheel. 7. The vehicle brake system of claim 6 wherein the static and dynamic properties of tire/road interactions of the wheel are determined based at least in part upon at least one of a tire pressure, a tire temperature and the determined tire/road friction coefficient of the wheel. 8. The vehicle brake system of claim 4 wherein the tire/road wheel slip of the wheel is measured directly. 9. The vehicle brake system of claim 4 wherein the tire/road wheel slip of the wheel is determined based at least in part upon a determined rotational velocity of the wheel and at least in part upon a determined linear velocity of the wheel. 10. The vehicle brake system of claim 9 wherein the linear velocity of the wheel is determined based at least in part upon a determined vehicle velocity. 11. The vehicle brake system of claim 10 wherein the linear velocity of the wheel is determined further based at least in part upon a determined steering angle. 12. The vehicle brake system of claim 9 wherein the linear velocity of the wheel is determined based at least in part upon a determined rate of vehicle rotation and at least in part upon dimensions of a vehicle. 13. The vehicle brake system of claim 10 wherein the vehicle velocity is determined at least in part based upon wheel rotational velocities of at least two wheels. 14. The vehicle brake system of claim 1 wherein said brake actuator comprises a self-energizing brake actuator. 15. The vehicle brake system of claim 1 wherein said brake actuator comprises an electromechanical brake actuator, actuation of which is at least partially achieved employing an electric motor. 16. The vehicle brake system of claim 1 wherein said brake actuator comprises a self-energizing electromechanical brake actuator. 17. A vehicle brake system comprising: a brake actuator associated with a wheel, said brake actuator having at least one moveable brake component; a brake control system operative to determine a target rotational velocity of the wheel based at least in part on a relationship between an actual tire/road friction force and a target tire/road friction force, and to determine a target position of the at least one moveable brake component based at least in part upon the target rotational velocity, said brake control system operative to control said brake actuator based at least in part upon a comparison of the target position of the at least one moveable brake component with a current position of the at least one moveable brake component in order to achieve the target rotational velocity; wherein said actual tire/road friction force is determined based at least in part upon determined static and dynamic properties of tire/road interactions of the wheel, at least in part upon a determined tire/road wheel slip of the wheel, at least in part upon a determined load force of the wheel, and at least in part upon a determined tire/road friction coefficient of the wheel; wherein the tire/road friction coefficient of the wheel is determined based at least in part upon the determined tire/road wheel slip of the wheel, at least in part upon a determined brake torque of the wheel, at least in part upon the determined load force of the wheel, and at least in part upon dimensions of the wheel; wherein the static and dynamic properties of tire/road interactions of the wheel are determined based at least in part upon the determined tire/road wheel slip of the wheel, at least in part upon a determined brake torque of the wheel, and at least in part upon the determined load force of the wheel; and wherein the tire/road wheel slip of the wheel is determined based at least in part upon a determined rotational velocity of the wheel and at least in part upon a determined linear velocity of the wheel. 18. The vehicle brake system of claim 17 wherein the linear velocity of the wheel is determined based at least in part upon a determined vehicle velocity. 19. The vehicle brake system of claim 18 wherein the linear velocity of the wheel is determined further based at least in part upon a determined steering angle. 20. The vehicle brake system of claim 18 wherein the vehicle velocity is determined at least in part based upon wheel rotational velocities of at least two wheels. 21. The vehicle brake system of claim 17 wherein said brake actuator comprises a self-energizing brake actuator. 22. The vehicle brake system of claim 17 wherein said brake actuator comprises an electromechanical brake actuator, actuation of which is at least partially achieved employing an electric motor. 23. The vehicle brake system of claim 17 wherein said brake actuator comprises a self-energizing electromechanical brake actuator. 24. A method for controlling a brake actuator associated with a wheel, the brake actuator having at least one moveable brake component, the method comprising the steps of: determining a target rotational velocity of the wheel based at least in part on a relationship between an actual tire/road friction force and a target tire/road friction force; determining a target position of the at least one moveable brake component based at least in part upon the target rotational velocity; and controlling actuation of the brake actuator based at least in part upon a comparison of the target position of the at least one moveable brake component with a current position of the at least one moveable brake component. 25. The method of claim 24 wherein the actual tire/road friction force is determined based at least in part upon a determined brake torque and at least in part upon a determined rotational acceleration/retardation of the wheel. 26. The method of claim 25 wherein the actual tire/road friction force is determined based further at least in part upon dimensions of the wheel. 27. The method of claim 24 wherein the actual tire/road friction force is determined based at least in part upon determined static and dynamic properties of tire/road interactions of the wheel, at least in part upon a determined tire/road wheel slip of the wheel, at least in part upon a determined load force of the wheel, and at least in part upon a determined tire/road friction coefficient of the wheel. 28. The method of claim 27 wherein the tire/road friction coefficient of the wheel is determined based at least in part upon the determined tire/road wheel slip of the wheel, at least in part upon a determined brake torque of the wheel, at least in part upon the determined load force of the wheel, and at least in part upon dimensions of the wheel. 29. The method of claim 27 wherein the static and dynamic properties of tire/road interactions of the wheel are determined based at least in part upon the determined tire/road wheel slip of the wheel, at least in part upon a determined brake torque of the wheel, and at least in part upon the determined load force of the wheel. 30. The method of claim 29 wherein the static and dynamic properties of tire/road interactions of the wheel are determined based at least in part upon at least one of a tire pressure, a tire temperature and the determined tire/road friction coefficient of the wheel. 31. The method of claim 27 wherein the tire/road wheel slip of the wheel is measured directly. 32. The method of claim 27 wherein the tire/road wheel slip of the wheel is determined based at least in part upon a determined rotational velocity of the wheel and at least in part upon a determined linear velocity of the wheel. 33. The method of claim 32 wherein the linear velocity of the wheel is determined based at least in part upon a determined vehicle velocity. 34. The method of claim 33 wherein the linear velocity of the wheel is further determined based at least in part upon a determined steering angle. 35. The method of claim 32 wherein the linear velocity of the wheel is based at least in part upon a determined rate of vehicle rotation and at least in part upon dimensions of a vehicle. 36. The method of claim 33 wherein the vehicle velocity is determined at least in part based upon wheel rotational velocities of at least two wheels. 37. The method of claim 24 wherein the brake actuator comprises a self-energizing brake actuator. 38. The method of claim 24 wherein the brake actuator comprises an electromechanical brake actuator, actuation of which is at least partially achieved employing an electric motor. 39. The method of claim 24 wherein the brake actuator comprises a self-energizing electromechanical brake actuator. 40. A method for controlling a brake actuator associated with a wheel, the brake actuator having at least one moveable brake component, said method comprising the steps of: determining a target rotational velocity of the wheel based at least in part on a relationship between an actual tire/road friction force and a target tire/road friction force; determining a target position of the at least one moveable brake component based at least in part upon the target rotational velocity; controlling the brake actuator based at least in part upon a comparison of the target position of the at least one moveable brake component with a current position of the at least one moveable brake component in order to achieve the target rotational velocity; and wherein the actual tire/road friction force is determined by employing the following steps: determining a tire/road wheel slip of the wheel based at least in part upon a determined rotational velocity of the wheel and at least in part upon a determined linear velocity of the wheel; determining static and dynamic properties of tire/road interactions of the wheel based at least in part upon the determined tire/road wheel slip of the wheel, at least in part upon a determined brake torque of the wheel, and at least in part upon a determined load force of the wheel; determining a tire/road friction coefficient of the wheel based at least in part upon the determined tire/road wheel slip of the wheel, at least in part upon the determined brake torque of the wheel, at least in part upon the determined load force of the wheel, and at least in part upon dimensions of the wheel; and determining the actual tire/road friction force based at least in part upon the determined static and dynamic properties of tire/road interactions of the wheel, at least in part upon the determined tire/road wheel slip of the wheel, at least in part upon the determined load force of the wheel, and at least in part upon the determined tire/road friction coefficient of the wheel. 41. The method of claim 40 wherein the linear velocity of the wheel is determined based at least in part upon a determined vehicle velocity. 42. The method of claim 41 wherein the linear velocity of the wheel is determined further based at least in part upon a determined steering angle. 43. The method of claim 41 wherein the vehicle velocity is determined at least in part based upon wheel rotational velocities of at least two wheels. 44. The method of claim 40 wherein the brake actuator comprises a self-energizing brake actuator. 45. The method of claim 40 wherein the brake actuator comprises an electromechanical brake actuator, actuation of which is at least partially achieved employing an electric motor. 46. The method of claim 40 wherein the brake actuator comprises a self-energizing electromechanical brake actuator. 47. A vehicle brake system comprising: a brake actuator associated with a wheel, said brake actuator having at least one moveable brake component; a brake control system operative to determine a target rotational velocity of the wheel based at least in part on a relationship between a measured wheel slip and a commanded wheel slip, said brake control system determining a target position of the at least one moveable brake component based at least in part upon the target rotational velocity; and wherein said brake control system is operable to control actuation of said brake actuator based at least in part upon a comparison of the target position of the at least one moveable brake component with a current position of the at least one moveable brake component. 48. The vehicle brake system of claim 47 wherein said brake actuator comprises a self-energizing brake actuator. 49. The vehicle brake system of claim 47 wherein said brake actuator comprises an electromechanical brake actuator, actuation of which is at least partially achieved employing an electric motor. 50. The vehicle brake system of claim 47 wherein said brake actuator comprises a self-energizing electromechanical brake actuator.
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이 특허에 인용된 특허 (14)
Nobuyoshi Onogi JP, Antiskid brake control system for automotive vehicles.
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