Closed loop pressure control for dual air spring configuration
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B60G-017/04
B60G-017/052
F16F-009/05
B60G-017/016
B60G-017/048
B60G-017/015
출원번호
US-0416310
(2009-04-01)
등록번호
US-8899603
(2014-12-02)
발명자
/ 주소
VanRaaphorst, David A.
출원인 / 주소
ArvinMeritor Technology, LLC
대리인 / 주소
Brooks Kushman P.C.
인용정보
피인용 횟수 :
0인용 특허 :
12
초록▼
An active air suspension system includes an air spring assembly that has a piston airbag and a primary airbag mounted around the piston airbag to provide a variable force and rate dual air spring configuration. The air suspension system is configured to accurately control pressure within the piston
An active air suspension system includes an air spring assembly that has a piston airbag and a primary airbag mounted around the piston airbag to provide a variable force and rate dual air spring configuration. The air suspension system is configured to accurately control pressure within the piston airbags in a closed-loop manner. Continuous control of the piston pressure provides an accurate increase or decrease of spring rate or force depending on the controller inputs.
대표청구항▼
1. An air suspension system comprising: at least one air spring assembly including a piston airbag and a primary air bag mounted around said piston airbag;at least one pressure sensor that continuously measures pressure within said piston airbag, said pressure sensor generating a pressure signal tha
1. An air suspension system comprising: at least one air spring assembly including a piston airbag and a primary air bag mounted around said piston airbag;at least one pressure sensor that continuously measures pressure within said piston airbag, said pressure sensor generating a pressure signal that corresponds to a measured pressure;a valve assembly that controls air supply into and out of said piston airbag; anda controller that receives said pressure signal as an input, compares this input to at least one desired piston airbag characteristic, and generates an output signal to modify pressure within said piston airbag if said input is different from said desired piston airbag characteristic, wherein said controller determines spring displacement and compensates for deflection based on spring displacement and piston pressure. 2. The air suspension system according to claim 1 wherein said desired piston airbag characteristic comprises a desired piston airbag diameter to provide a desired spring stiffness. 3. The air suspension system according to claim 2 wherein said controller continuously receives pressure input signals from said pressure sensor indicating pressure changes within said piston airbag, and wherein said controller actively adjusts pressure within said piston airbag in response to the pressure changes to maintain said desired spring stiffness in a closed-loop manner. 4. The air suspension system according to claim 3 wherein said controller generates electric control signals to actively control said valve assembly to control air flow into and out of said piston airbag. 5. The air suspension system according to claim 2 wherein said at least one air spring assembly comprises a plurality of air spring assemblies each having one primary airbag and one associated piston airbag, said valve assembly comprises a separate valve assembly for each air spring assembly, and said at least one pressure sensor comprises a plurality of pressure sensors with one pressure sensor being associated with each piston airbag, and wherein said controller continuously receives pressure input signals from each of said pressure sensors indicating specific pressure changes within said associated piston airbag, and wherein said controller actively adjusts pressure within each of said piston airbags in response to the pressure changes to maintain said desired spring stiffness in a closed-loop manner. 6. The air suspension system according to claim 5 wherein said controller generates a plurality of control signals to control air supply into and out of each piston airbag independently of all other piston airbags. 7. The air suspension system according to claim 5 including at least one damper mounted to each air spring assembly. 8. The air suspension system according to claim 7 wherein said at least one damper comprises an electrically controlled shock absorber. 9. The air suspension system according to claim 5 wherein each of said separate valve assemblies includes an inlet valve and an outlet valve that are separate from each other and are controlled independently of each other. 10. The air suspension system according to claim 5 wherein said controller continuously adjusts spring force and spring rate of each of said air spring assemblies by individually controlling air flow into and out of each piston airbag and each primary airbag. 11. A method of controlling airflow within an air suspension system comprising the steps of: (a) providing at least one air spring assembly including a piston airbag and a primary air bag mounted around the piston airbag, and providing a valve assembly that controls air supply into and out of the piston airbag;(b) continuously measuring pressure within the piston airbag and generating a pressure signal that corresponds to a measured pressure;(c) receiving pressure signals from step (b) as an input, comparing this input to at least one desired piston airbag characteristic, and generating an output control signal to modify pressure within the piston airbag via the valve assembly if the input is different from the desired piston airbag characteristic; and(d) receiving a plurality of driver inputs, receiving a plurality of vehicle inputs, and determining a compensated target pressure for each air spring assembly based on the measured pressure, driver inputs, and vehicle inputs wherein the compensated target pressure comprises the at least one desired piston airbag characteristic. 12. The method according to claim 11 wherein the desired piston airbag characteristic comprises a desired piston airbag diameter to provide a desired spring stiffness. 13. The method according to claim 11 including continuously receiving pressure input signals from a pressure sensor indicating pressure changes within the piston airbag, and actively adjusting pressure within the piston airbag in response to the pressure changes to maintain the desired spring stiffness in a closed-loop manner. 14. The method according to claim 11 wherein the at least one air spring assembly comprises a plurality of air spring assemblies each having one primary airbag and one associated piston airbag, the valve assembly comprises a separate valve assembly for each air spring assembly, and including providing a plurality of pressure sensors with one pressure sensor being associated with each piston airbag, and including the steps of continuously receiving pressure input signals from each of the pressure sensors indicating specific pressure changes within the associated piston airbag, and actively adjusting pressure within each of the piston airbags in response to the pressure changes to maintain the desired spring stiffness for each air spring assembly in a closed-loop manner. 15. The method according to claim 11 including providing the air spring assembly with a lower mount to be attached to a longitudinally extending arm member, a piston support attached to the lower mount, and an upper mount to be attached to a vehicle structure, and including mounting a lower end of the piston airbag to a first portion of the piston support, mounting an upper end of the piston airbag to a second portion of the piston support, mounting a lower end of the primary airbag to the upper end of the piston airbag, mounting an upper end of the primary airbag to the upper mount, and mounting an outer structure of a damper to the lower mount. 16. The air suspension system according to claim 1 wherein said air spring assembly includes a lower mount to be attached to a longitudinally extending arm member, a piston support attached to said lower mount, and an upper mount to be attached to a vehicle structure, and wherein a lower end of said piston airbag is mounted to a first portion of said piston support, an upper end of said piston airbag is mounted to a second portion of said piston support, a lower end of said primary airbag is mounted to said upper end of said piston airbag, and an upper end of said primary airbag is mounted to said upper mount. 17. The air suspension system according to claim 16 including a damper having an outer structure that is mounted to said lower mount. 18. The air suspension system according to claim 1 wherein said controller receives a plurality of driver inputs and a plurality of vehicle inputs, and wherein said controller determines a compensated target pressure for said air spring assembly based on said inputs, with the compensated target pressure comprising the at least one desired piston airbag characteristic. 19. An air suspension system comprising: at least one air spring assembly including a piston airbag and a primary air bag mounted around said piston airbag, wherein said at least one air spring assembly comprises a plurality of air spring assemblies each having one primary airbag and one associated piston airbag;at least one damper mounted to each air spring assembly, wherein said at least one damper comprises an electrically controlled shock absorber;at least one pressure sensor that continuously measures pressure within said piston airbag, said pressure sensor generating a pressure signal that corresponds to a measured pressure, wherein said at least one pressure sensor comprises a plurality of pressure sensors with one pressure sensor being associated with each piston airbag;a valve assembly that controls air supply into and out of said piston airbag, wherein said valve assembly comprises a separate valve assembly for each air spring assembly; anda controller that receives said pressure signal as an input, compares this input to at least one desired piston airbag characteristic, and generates an output signal to modify pressure within said piston airbag if said input is different from said desired piston airbag characteristic, wherein said desired piston airbag characteristic comprises a desired piston airbag diameter to provide a desired spring stiffness, wherein said controller continuously receives pressure input signals from each of said pressure sensors indicating specific pressure changes within said associated piston airbag, and wherein said controller actively adjusts pressure within each of said piston airbags in response to the pressure changes to maintain said desired spring stiffness in a closed-loop manner. 20. An air suspension system comprising: at least one air spring assembly including a piston airbag and a primary air bag mounted around said piston airbag;at least one pressure sensor that continuously measures pressure within said piston airbag, said pressure sensor generating a pressure signal that corresponds to a measured pressure;a valve assembly that controls air supply into and out of said piston airbag; anda controller that receives said pressure signal as an input, compares this input to at least one desired piston airbag characteristic, and generates an output signal to modify pressure within said piston airbag if said input is different from said desired piston airbag characteristic, wherein said controller receives a plurality of driver inputs and a plurality of vehicle inputs, and wherein said controller determines a compensated target pressure for said air spring assembly based on said inputs, with the compensated target pressure comprising the at least one desired piston airbag characteristic. 21. A method of controlling airflow within an air suspension system comprising the steps of: (a) providing at least one air spring assembly including a piston airbag and a primary air bag mounted around the piston airbag, and providing a valve assembly that controls air supply into and out of the piston airbag;(b) continuously measuring pressure within the piston airbag and generating a pressure signal that corresponds to a measured pressure;(c) receiving pressure signals from step (b) as an input, comparing this input to at least one desired piston airbag characteristic, generating an output control signal to modify pressure within the piston airbag via the valve assembly if the input is different from the desired piston airbag characteristic; and(d) determining spring displacement;wherein step (c) further includes compensating for deflection based on spring displacement and piston pressure.
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이 특허에 인용된 특허 (12)
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Hamilton James M. (1167 Loma Portal Dr. El Cajon CA 92020) Woods Lonnie K. (2722 Lindsay Michelle Alpine CA 92001), Computer optimized adaptive suspension system having combined shock absorber/air spring unit.
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