High-temperature thermal actuator utilizing phase change material
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G05D-023/02
F03G-007/06
B23P-019/00
출원번호
US-0801734
(2013-03-13)
등록번호
US-10047730
(2018-08-14)
발명자
/ 주소
Riley, Michael B.
Ambrosek, James
Gettamaneni, Kumaresh
Polley, Nolan
Way, R. J.
출원인 / 주소
Woodward, Inc.
대리인 / 주소
Cochran, William W.
인용정보
피인용 횟수 :
0인용 특허 :
24
초록▼
Disclosed is a high-temperature thermal actuator that utilizes the dimensional change of a phase change media hermetically sealed within a shell. This actuator regulates and controls flow of a fluid between an intake and an exhaust utilizing a valve. In one example, the disclosed embodiments operate
Disclosed is a high-temperature thermal actuator that utilizes the dimensional change of a phase change media hermetically sealed within a shell. This actuator regulates and controls flow of a fluid between an intake and an exhaust utilizing a valve. In one example, the disclosed embodiments operate in temperature range between 350° C. and 400° C. This actuation range is tailored for specific applications utilizing an exemplary combination of RbNO3 and CsNO3 in precise proportion that provides operation within this range.
대표청구항▼
1. A high-temperature thermal actuator comprising: a sealed volumetric confine comprising: a flexible metal wall with surfaces orthogonal to an axial orientation that allows flexural displacement towards the outside of said confine;an opposing wall with surfaces orthogonal to an axial orientation, a
1. A high-temperature thermal actuator comprising: a sealed volumetric confine comprising: a flexible metal wall with surfaces orthogonal to an axial orientation that allows flexural displacement towards the outside of said confine;an opposing wall with surfaces orthogonal to an axial orientation, approximately parallel to, and offset by a distance from, said flexible wall;at least one non-flexible wall that remains substantially rigid under operational circumstances, and that is disposed in a circumferential orientation to engage said flexible metal wall and said opposing wall thereby forming said sealed confine;a phase change media located within wherein said volume of said confine, said phase change media expands upon a change of state from solid to liquid as the temperature of said phase change media increases beyond 200° C., wherein said phase change media does not substantially change volume due to expansion from temperature prior to said change of state from solid to liquid; and,an actuator rod in contact with an outside surface of said flexible metal wall;wherein said actuator rod undergoes actuation displacement by being displaced when said flexible wall changes distance from said opposing wall in response to said change of state of said phase change media. 2. The high-temperature thermal actuator of claim 1 wherein said phase change media comprises one or more inorganic salts. 3. The high-temperature thermal actuator of claim 1 wherein said phase change media comprises one or more metals. 4. The high-temperature thermal actuator of claim 1 wherein said phase change media comprises one or more non-metals. 5. The high-temperature thermal actuator of claim 1 wherein said phase change media comprises any combination of one or more inorganic salts, one or more metals, and one or more non-metals. 6. The high-temperature thermal actuator of claim 1 wherein said sealed volumetric confine is a cylinder. 7. The high-temperature thermal actuator of claim 1 wherein said sealed volumetric confine contains a combination of said phase change media and an inert filler media. 8. A high-temperature thermal actuated valve comprising: a high-temperature thermal expansion module comprising: a sealed volumetric confine comprising: a flexible metal wall with planar surfaces orthogonal to an axial orientation that allows flexural displacement towards the outside of said confine;an opposing wall with planar surfaces orthogonal to an axial orientation, approximately parallel to, and offset by a distance from, said flexible wall;at least one non-flexible wall that remains substantially rigid under operational circumstances, and that is disposed in a circumferential orientation to engage said flexible metal wall and said opposing wall thereby forming said sealed confine; and,a phase change media located within said volume of said confine, wherein said phase change media expands upon a change of state from solid to liquid as the temperature of said phase change media increases beyond 200° C., wherein said phase change media does substantially not change volume due to expansion from temperature prior to said change of state from solid to liquid;an actuator rod in contact with an outside surface of said flexible metal wall, wherein said actuator rod undergoes actuation displacement by being displaced when said flexible wall changes distance from said opposing wall in response, to said change of state of said phase change media; and,a valve assembly in communication with said actuator rod that opens and closes in response to actuation displacement of said actuator rod from said opposing wall, thereby regulating the flow of a fluid. 9. The high-temperature thermal actuated valve of claim 8 wherein at least one additional thermal expansion module is placed in series with said thermal expansion module to impart additional actuation. 10. The high-temperature thermal actuated valve of claim 9 wherein said at least one additional thermal expansion module utilizes a second phase change media that changes phase at a different temperature than said phase change media to impart additional actuation at a second temperature. 11. The high-temperature thermal expansion module of claim 8 wherein said phase change media comprises one or more inorganic salt. 12. The high-temperature thermal expansion module of claim 8 wherein said phase change media comprises one or more metals. 13. The high-temperature thermal expansion module of claim 8 wherein said phase change media comprises one or more non-metals. 14. The high-temperature thermal expansion module of claim 8 wherein said phase change media comprises any combination of one or more inorganic salts, one or more metals, and one or more non-metals. 15. The high-temperature thermal expansion module of claim 8 wherein said sealed volumetric confine is a cylinder. 16. The high-temperature thermal actuator of claim 8 wherein said sealed volumetric confine contains a combination of said phase change media and an inert filler media. 17. A method of causing displacement with a high-temperature thermal actuator comprising: providing a sealed volumetric confine comprising: a flexible metal wall with planar surfaces orthogonal to an axial orientation that allows flexural displacement towards the outside of said confine;an opposing wall with planar surfaces orthogonal to an axial orientation, approximately parallel to and offset by a distance from said flexible wall;at least one non-flexible wall that remains substantially rigid under operational circumstances, and that is disposed in a circumferential orientation to engage said flexible metal wall and said opposing wall thereby forming said sealed confine;providing a phase change media within said volume of said confine;heating said phase change media past a phase transition point greater than 200° C., wherein said phase change media does not substantially change volume due to expansion from temperature prior to said change of state from solid to liquid;expanding said phase change media upon a change of state between solid and liquid; and,deflecting said metal wall away from said opposing wall and displacing an actuator rod in response to the force exerted by said phase change media upon said change of state. 18. The method of claim 17 further comprising the step: providing said phase change media comprising one or more inorganic salts. 19. The method of claim 17 further comprising the step: providing said phase change media comprising one or more metals. 20. The method of claim 17 further comprising the step: providing said phase change media comprising one or more non-metals. 21. The method of claim 17 further comprising the step: providing said phase change media comprising any combination of one or more inorganic salts, one or more metals, and one or more non-metals. 22. The method of claim 17 further comprising the step: providing said sealed volumetric confine in the shape of a cylinder. 23. The method of claim 17 further comprising the step: providing an inert filler media with said phase change media within said volume of said confine. 24. A method of opening and closing a valve with a high-temperature thermal actuator comprising: providing a sealed volumetric confine comprising: a flexible metal wall with planar surfaces orthogonal to an axial orientation that allows flexural displacement towards the outside of said confine;an opposing wall with planar surfaces orthogonal to an axial orientation, approximately parallel to and offset by a distance from said flexible wall;at least one non-flexible wall that remains substantially rigid under operational circumstances, and that is disposed in a circumferential orientation to engage said flexible metal wall and said opposing wall thereby forming said sealed confine;providing a phase change media within said volume of said confine;heating said phase change media to a phase transition point greater than 200° C., wherein said phase change media does not substantially change volume due to expansion from temperature prior to said phase transition point;expanding said phase change media upon a change of state between solid and liquid;changing a distance between said flexible metal wall and said opposing wall with the force exerted by said phase change media due to a phase change;displacing an actuator rod with the force exerted by said changing of said distance between said deformable metal wall and said opposing wall; and,regulating the flow of a fluid by opening or closing a valve assembly that is in communication with said actuator rod in response to said displacing of saidactuator rod. 25. The method of claim 24 further comprising the step: providing at least one additional thermal expansion module in series with said thermal expansion module to impart additional actuation. 26. The method of claim 25 further comprising the step: providing said at least one additional thermal expansion module utilizing a second phase change media that changes phase at a different temperature than said phase change media to impart additional actuation at a second temperature. 27. The method of claim 24 further comprising the step: providing said phase change media comprising one or more inorganic salt. 28. The method of claim 24 further comprising the step: providing said phase change media comprising one or more metals. 29. The method of claim 24 further comprising the step: providing said phase change media comprising one or more non-metals. 30. The method of claim 24 further comprising the step: providing said phase change media comprising any combination of one or more inorganic salts, one or more metals, and one or more non-metals. 31. The method of claim 24 further comprising the step: providing said sealed volumetric confine in the form of a cylinder. 32. The method of claim 24 further comprising the step: providing an inert filler media with said phase change media within said volume of said confine.
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