IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
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출원번호 |
UP-0617706
(2006-12-28)
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등록번호 |
US-7628262
(2009-12-16)
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발명자
/ 주소 |
- Barnum, Stephen T.
- Tuttle, Michael D.
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출원인 / 주소 |
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인용정보 |
피인용 횟수 :
5 인용 특허 :
7 |
초록
▼
A system for controlling the engagement and disengagement of a viscous type coupling is accomplished by controlling the relative positioning of a spring loaded valve arm relative to a fluid port through the use of an electrically-activated, temperature-sensitive member, such as a NiTi wire. The char
A system for controlling the engagement and disengagement of a viscous type coupling is accomplished by controlling the relative positioning of a spring loaded valve arm relative to a fluid port through the use of an electrically-activated, temperature-sensitive member, such as a NiTi wire. The characteristics of shape memory alloy materials are such that they are hard above a predetermined temperature, but soft and ductile below a predetermined temperature. When engagement or disengagement of the coupling is desired, electrical current is introduced through the member, therein heating it above a predetermined temperature to harden it. This hardening causes the valve arm to either move to either cover or uncover a fluid port, depending upon the design arrangement of the valve arm relative to the fluid port. A controller coupled to a plurality of engine operating sensors and a power source controls the electrical activation as a function of a desired operating condition.
대표청구항
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What is claimed is: 1. A viscous coupling comprising: an output member; an input member coupled within said output member; a working chamber defined between said output member and said input member; a reservoir plate coupled between within said output member and between said input member and said o
What is claimed is: 1. A viscous coupling comprising: an output member; an input member coupled within said output member; a working chamber defined between said output member and said input member; a reservoir plate coupled between within said output member and between said input member and said output member, said reservoir plate having a first side and a second side; a fluid reservoir defined between said first side and said output member, said fluid reservoir having a quantity of viscous fluid; an operating chamber defined between said second side and said output member; a fluid port on said reservoir plate fluidically coupling said working chamber and said fluid reservoir; a spring loaded valve arm pivotably coupled to said first side of said reservoir plate; and an electrically-activated, temperature-sensitive elongated member coupled to said spring loaded valve arm for controlling the relative positioning of said spring loaded valve arm to cover and uncover said fluid port. 2. The viscous coupling of claim 1 further comprising: a power source coupled to said electrically-activated, temperature-sensitive member; and a controller coupled to said power source, said controller directing said power source to supply electricity to said electrically activated, temperature-sensitive member as a function of an engine operating condition. 3. The viscous coupling of claim 1, wherein said electrically activated, temperature-sensitive member comprises a nickel-titanium wire. 4. The viscous coupling of claim 1, wherein said electrically activated, temperature-sensitive member covers said fluid port when activated with electrical current. 5. The viscous coupling of claim 1, wherein said electrically activated, temperature-sensitive member uncovers said fluid port when activated with electrical current. 6. The viscous coupling of claim 1, wherein said fluid port comprises a scavenger port. 7. The viscous coupling of claim 1, wherein said fluid port comprises a fill port. 8. The viscous coupling of claim 1, wherein said spring loaded valve arm comprises: a valve arm pivotally coupled to said first side of said reservoir plate via a coupling pin; a coil spring coupled around said coupling pin, said coil spring urging said valve arm to a first position, said first position selected from the group consisting of a closed position and an open position, said closed position defined wherein said valve arm covers said fluid port and said open position defined wherein said valve arm does not cover said fluid port. 9. The viscous coupling of claim 1, wherein said spring loaded valve arm comprises: a valve arm pivotally coupled to said first side of said reservoir plate via a coupling pin; a stop coupled to said first side of said reservoir plate; a spring coupled to said stop and located between said valve arm and said stop, said spring urging said valve arm to a first position, said first position selected from the group consisting of a closed position and an open position, said closed position defined wherein said valve arm covers said fluid port and said open position defined wherein said valve arm does not cover said fluid port. 10. The viscous coupling of claim 9, wherein said spring is affixed to said valve arm. 11. A method for precisely controlling the torque output of a viscous coupling comprising; (a) providing a viscous coupling comprising: an output member; an input member coupled within said output member; a working chamber defined between said output member and said input member; a reservoir plate coupled between within said output member and between said input member and said output member, said reservoir plate having a first side and a second side; a fluid reservoir defined between said first side and said output member, said fluid reservoir having a quantity of viscous fluid; an operating chamber defined between said second side and said output member; a fluid port on said reservoir plate fluidically coupling said working chamber and said fluid reservoir; (b) coupling a spring loaded valve arm to said reservoir plate such that said spring loaded valve arm is urged to a first position, said first position selected from the group consisting of an open position and a closed position, said closed position defined wherein said spring loaded valve arm covers said fluid port and said open position defined wherein said spring loaded valve arm does not cover said fluid port; (c) coupling an electrically activated, temperature-sensitive member to said spring loaded valve arm; (d) coupling said electrically-activated, temperature-sensitive member to a power source; and (e) controlling the relative positioning of said valve arm between said closed position and said open position by introducing an electrical current from said power source through said electrically-activated, temperature-sensitive wire. 12. The method of claim 11, wherein (e) controlling the relative positioning of said valve arm comprises: (e) heating said electrically-activated, temperature-sensitive member above a predetermined temperature by introducing an electrical current through said electrically-activated, temperature-sensitive member, wherein said electrically-activated, temperature-sensitive member hardens above said predetermined temperature and causes said valve arm to move from said first position to a second position, wherein said second position comprises said open position when said first position comprises said closed position and wherein said second position comprises said closed position when said first position comprises said open position. 13. The method of claim 11, wherein (b) coupling a spring loaded valve arm to said reservoir plate comprises: coupling a coil spring around a coupling pin: coupling said valve arm to said first side of said reservoir plate using said coupling pin, wherein said coil spring urges said valve arm to a first position, said first position selected from the group consisting of an open position and a closed position, said closed position defined wherein said valve arm covers said fluid port and said open position defined wherein said valve arm does not cover said fluid port. 14. The method of claim 11, wherein (b) coupling a spring loaded valve arm to said reservoir plate comprises: coupling a stop to a first side of said reservoir plate; coupling a valve arm to said first side of said reservoir plate using a coupling pin; coupling a spring to said stop in a position between said stop and said valve arm, said spring urging said valve arm to a first position, said first position selected from the group consisting of an open position and a closed position, said closed position defined wherein said valve arm covers said fluid port and said open position defined wherein said valve arm does not cover said fluid port. 15. The method of claim 14, wherein (b) coupling a spring loaded valve arm to said reservoir plate further comprises affixing said spring to said valve arm. 16. The method of claim 11, wherein (e) controlling the relative positioning of said valve arm comprises: electrically coupling a controller to said power source; and controlling the relative positioning of said valve arm between said closed position and said open position by introducing a signal from said controller to said power source to introduce an electrical current from said power source through said electrically-activated, temperature-sensitive wire. 17. The method of claim 16, wherein (e) controlling the relative positioning of said valve arm further comprises: electrically coupling at least one sensor to said controller; measuring an operating parameter using said at least one sensor; sending a first signal from said at least one sensor to said controller as a function of said measured operating parameter; and controlling the relative positioning of said valve arm between said closed position and said open position by introducing a second signal from said controller to said power source to introduce an electrical current from said power source through said electrically-activated, temperature-sensitive member, said second signal being a function of said first signal. 18. The method of claim 11 further comprising (f) coupling the viscous coupling within a fan drive system. 19. The method of claim 11 further comprising (f) coupling the viscous coupling within a water pump system. 20. The method of claim 11, wherein (c) coupling an electrically-activated, temperature-sensitive member to said spring loaded valve arm comprises coupling an nickel-titanium wire to said spring loaded valve arm. 21. A viscous clutch comprising: a reservoir plate separating a fluid reservoir from a working chamber; a fluid hole contained within said reservoir plate, said fluid hole fluidically coupling said fluid reservoir and said working chamber; a spring loaded valve arm pivotally coupled to said first side of said reservoir plate; and an electrically-activated, temperature-sensitive member coupled to said spring loaded valve arm for controlling the relative positioning of said spring loaded valve arm to cover and uncover said fluid port. 22. The viscous clutch of claim 21, wherein said spring loaded valve arm comprises: a valve arm pivotally coupled to said first side of said reservoir plate via a coupling pin; a coil spring coupled around said coupling pin, said coil spring urging said valve arm to a first position, said first position selected from the group consisting of a closed position and an open position, said closed position defined wherein said valve arm covers said fluid port and said open position defined wherein said valve arm does not cover said fluid port. 23. The viscous clutch of claim 22, wherein said spring loaded valve arm comprises: a valve arm pivotally coupled to said first side of said reservoir plate via a coupling pin; a stop coupled to said first side of said reservoir plate; a spring coupled to said stop and located between said valve arm and said stop, said spring urging said valve arm to a first position, said first position selected from the group consisting of a closed position and an open position, said closed position defined wherein said valve arm covers said fluid port and said open position defined wherein said valve arm does not cover said fluid port. 24. The viscous clutch of claim 23, wherein said spring is affixed to said valve arm. 25. The viscous clutch of claim 21 further comprising: a power source coupled to said electrically-activated, temperature-sensitive member; and a controller coupled to said power source, said controller directing said power source to supply electricity to said electrically activated, temperature-sensitive member as a function of an engine operating condition. 26. The viscous clutch of claim 21 wherein said electrically activated, temperature-sensitive member comprises a nickel-titanium wire. 27. The viscous clutch of claim 21, wherein said electrically activated, temperature-sensitive member covers said fluid port when activated with electrical current. 28. The viscous clutch of claim 21, wherein said electrically activated, temperature-sensitive member uncovers said fluid port when activated with electrical current. 29. The viscous clutch of claim 21, wherein said fluid port comprises a scavenger port. 30. The viscous clutch of claim 21, wherein said fluid port comprises a fill port. 31. A viscous coupling comprising: an output member; an input member coupled within said output member; a working chamber defined between said output member and said input member; a reservoir plate coupled between within said output member and between said input member and said output member, said reservoir plate having a first side and a second side; a fluid reservoir defined between said first side and said output member, said fluid reservoir having a quantity of viscous fluid; an operating chamber defined between said second side and said output member; a fluid port on said reservoir plate fluidically coupling said working chamber and said fluid reservoir; a spring loaded valve arm pivotably coupled to said first side of said reservoir plate; and an elongated shape memory alloy member coupled to said spring loaded valve arm for controlling the relative positioning of said spring loaded valve arm to cover and uncover said fluid port. 32. The viscous coupling of claim 31 further comprising: a power source coupled to said shape memory alloy member; and a controller coupled to said power source, said controller directing said power source to supply electricity to said shape memory alloy member as a function of an engine operating condition. 33. The viscous coupling of claim 31 wherein said shape memory alloy member is a nickel-Titanide or nickel-Titanium wire member. 34. The viscous coupling of claim 31 wherein said shape memory alloy member is a copper-base alloy.
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