Remotely adjustable degrees of freedom for suspension coupling
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B62M-027/02
B60G-017/027
B62D-055/104
출원번호
US-0218803
(2016-07-25)
등록번호
US-9944352
(2018-04-17)
발명자
/ 주소
Hawksworth, Jake
Hawksworth, Jeff
출원인 / 주소
Skinz Protective Gear
대리인 / 주소
Thompson, Craige
인용정보
피인용 횟수 :
0인용 특허 :
2
초록▼
Apparatus and associated methods relate to remote control over a number of degrees of freedom of coupling between a first suspension member and a second suspension member. In an illustrative embodiment, when in an uncoupled state, the first suspension member may move substantially independently of a
Apparatus and associated methods relate to remote control over a number of degrees of freedom of coupling between a first suspension member and a second suspension member. In an illustrative embodiment, when in an uncoupled state, the first suspension member may move substantially independently of any motion of the second suspension member. When in a coupled state, for example, the first suspension member may move in response to movement of the second suspension member. In some embodiments, the coupling between members may be altered by selectively permitting at least one degree of freedom of motion of the suspension system. For example, in some systems, a variable shock absorber may be selectively set to a fixed length in response to a control system signal. A remotely coupled suspension system may advantageously provide dynamically controllable suspension configurations for various riding conditions.
대표청구항▼
1. A snowmobile rear suspension system with dynamically controllable coupling to a front suspension system, the snowmobile rear suspension system comprising: a communication line operative to conduct a coupling mode signal from a proximal end thereof to a distal end thereof;an elongate slide rail ha
1. A snowmobile rear suspension system with dynamically controllable coupling to a front suspension system, the snowmobile rear suspension system comprising: a communication line operative to conduct a coupling mode signal from a proximal end thereof to a distal end thereof;an elongate slide rail having a track slot;a stationary member fixedly coupled to the elongate slide rail;a sliding member having a proximal end slidably coupled in the track slot to the elongate slide rail;a torque arm pivotally coupled to the sliding member, wherein the torque arm pivots about a proximal pivot point at the proximal end of the sliding member, wherein a distal end of the torque arm is adapted to couple to a tunnel of a snowmobile; and,a Remotely Adjustable Shock Member (RASM) having a first end and a second end slidably coupled to each other so as to permit contraction and expansion of a separation distance between the two ends, wherein the first end of the RASM couples to the stationary member, and the second end of the RASM couples to the sliding member, wherein the RASM is further operatively coupled to receive the coupling mode signal at the distal end of the communication line,wherein sliding of the sliding member within the track slot and pivoting of the torque arm about the proximal pivot point represent two degrees of freedom of the distal end of the torque arm relative to the slide rail, andwherein, in response to the coupling mode signal indicative of a first mode, the RASM substantially fixes a relative position of the sliding member relative to the slide rail in the first mode so as to remove one of the two degrees of freedom of the distal end of the torque arm relative to the elongate slide rail, and, in response to the coupling mode signal indicative of a second mode, the RASM permits freedom of movement of the torque arm about the proximal pivot point and freedom of movement of the sliding member within the track slot so as to permit the two degrees of freedom of the distal end of the torque arm relative to the elongate slide rail. 2. The snowmobile rear suspension system of claim 1, wherein the coupling mode signal comprises a mechanical signal that conducts via a mechanical linkage disposed in the communication line. 3. The snowmobile rear suspension system of claim 1, wherein the coupling mode signal comprises an electrical signal that conducts via the communication line. 4. The snowmobile rear suspension system of claim 1, wherein the coupling mode signal comprises a hydraulic signal that conducts via the communication line. 5. The snowmobile rear suspension system of claim 1, further comprising a controller operatively coupled to the proximal end of the communication line to transmit the coupling mode signal to the distal end of the communication line. 6. The snowmobile rear suspension system of claim 1, wherein the controller comprises a processor operatively coupled to a memory storage device that contains information representative of one or more predetermined parameters for governing operation of the RASM. 7. The snowmobile rear suspension system of claim 6, wherein the controller further comprises a processor operatively coupled to a memory containing instructions that, when executed by the controller, cause the processor to perform operations to control operation of the RASM, the operations comprising: a. receive a signal representative of a pitch measurement of the snowmobile's attitude;b. determine whether the received pitch measurement exceeds a predetermined threshold; and,c. generate the coupled mode signal based on the determination; andd. transmit the generated coupling mode signal to the RASM via an output port coupled to the proximal end of the communication line. 8. The snowmobile rear suspension system of claim 6, wherein the information representative of one or more predetermined parameters for governing operation of the RASM comprises user-selectable profile information for configuring the RASM. 9. The snowmobile rear suspension system of claim 1, wherein, in response to the coupling mode signal indicative of a third mode, a damping coefficient for slidable displacement between the first end and the second end of the RASM is adjustable over a range of stiffness values. 10. The snowmobile rear suspension system of claim 1, further comprising the snowmobile that contains the rear suspension system. 11. A method for dynamically controlling stiffness in a snowmobile suspension system, the method comprising: providing a communication line operative to conduct a coupling mode signal from a proximal end thereof to a distal end thereof;providing an elongate slide rail having a track slot;providing a stationary member fixedly coupled to the elongate slide rail;providing a sliding member having a proximal end slidably coupled in the track slot to the elongate slide rail;providing a torque arm pivotally coupled to the sliding member, wherein the torque arm pivots about a proximal pivot point at the proximal end of the sliding member; and,providing a Remotely Adjustable Shock Member (RASM) having a first end and a second end slidably coupled to each other so as to permit contraction and expansion of a separation distance between the two ends, wherein the first end of the RASM couples to the stationary member, and the second end of the RASM couples to the sliding member, wherein the RASM is further operatively coupled to receive the coupling mode signal at the distal end of the communication line,wherein sliding of the sliding member within the track slot and pivoting of the torque arm about the proximal pivot point represent two degrees of freedom of the distal end of the torque arm relative to the slide rail, andremoving one of the two degrees of freedom of the distal end of the torque arm relative to the slide rail in response to the coupling mode signal indicating a first mode. 12. The method of claim 11, further comprising: restoring the removed one of the two degrees of freedom of the distal end of the torque arm relative to the slide rail in response to the coupling mode signal indicating a second mode, wherein the second mode is different than the first mode. 13. The method of claim 12, further comprising transitioning the coupling mode signal from the first mode to the second mode while the snowmobile is being driven. 14. The method of claim 12, further comprising transitioning the coupling mode signal from the second mode to the first mode while the snowmobile is being driven. 15. The method of claim 12, wherein the step of restoring the removed one of the two degrees of freedom further comprises: controlling the RASM to permit freedom of movement of the torque arm about the proximal pivot point and freedom of movement of the sliding member within the track slot. 16. The method of claim 11, wherein the step of removing one of the two degrees of freedom of the distal end of the torque arm relative to the slide rail in response to the coupling mode signal indicative of a first mode further comprises: controlling the RASM to substantially fix a relative position of the sliding member relative to the slide rail. 17. The method of claim of claim 11, further comprising conducting the coupling mode signal from the proximal to the distal end of the communication line. 18. The method of claim of claim 11, further comprising operatively coupling a controller to the proximal end of the communication line, and generating from the controller the coupling mode signal, and transmitting from the controller the coupling mode signal to the distal end of the communication line. 19. A snowmobile rear suspension system with dynamically controllable coupling to a front suspension system, the snowmobile rear suspension system comprising: a communication line operative to conduct a coupling mode signal from a proximal end thereof to a distal end thereof;an elongate slide rail having a track slot;a stationary member fixedly coupled to the elongate slide rail;a sliding member having a proximal end slidably coupled in the track slot to the elongate slide rail;a torque arm pivotally coupled to the sliding member, wherein the torque arm pivots about a proximal pivot point at the proximal end of the sliding member, wherein a distal end of the torque arm is adapted to couple to a tunnel of a snowmobile; and,means for adjusting stiffness of the distal end of the torque arm relative to the elongate slide rail in response to the coupling mode signal,wherein sliding of the sliding member within the track slot and pivoting of the torque arm about the proximal pivot point represent two degrees of freedom of the distal end of the torque arm relative to the slide rail, andwherein, in response to the coupling mode signal indicative of a first mode, the means for remotely adjusting stiffness substantially fixes a relative position of the sliding member relative to the slide rail in the first mode so as to remove one of the two degrees of freedom of the distal end of the torque arm relative to the elongate slide rail. 20. The snowmobile rear suspension system of claim 19, wherein, in response to the coupling mode signal indicative of a second mode, the means for remotely adjusting stiffness permits freedom of movement of the torque arm about the proximal pivot point and freedom of movement of the sliding member within the track slot so as to permit the two degrees of freedom of the distal end of the torque arm relative to the elongate slide rail.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (2)
Polakowski, Stephen E.; Mattson, Steven G.; Muehlfeld, Christian, Snowmobile rear suspension system.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.