Systems and methods for compensating for compressibility and thermal expansion coefficient mismatch in buoyancy controlled underwater vehicles
원문보기
IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
US-0792620
(2010-06-02)
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등록번호 |
US-8381672
(2013-02-26)
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발명자
/ 주소 |
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출원인 / 주소 |
- University of Washington Center for Commercialization
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인용정보 |
피인용 횟수 :
8 인용 특허 :
4 |
초록
▼
Systems and methods for compensating for compressibility and thermal expansion coefficient mismatch in buoyancy controlled or buoyancy-driven underwater vehicles are disclosed herein. An underwater vehicle configured in accordance with one embodiment of the disclosure, for example, can include a hul
Systems and methods for compensating for compressibility and thermal expansion coefficient mismatch in buoyancy controlled or buoyancy-driven underwater vehicles are disclosed herein. An underwater vehicle configured in accordance with one embodiment of the disclosure, for example, can include a hull and a compartment carried by the hull and at least partially flooded with a first liquid having similar properties as a surrounding liquid into which the hull is configured to be deployed. The first liquid has a first compressibility and thermal expansion coefficient. The underwater vehicle can further include a compressibility and thermal expansion coefficient compensation system comprising a container filled or at least partially filled with a compressible liquid comprising silicone in the compartment. The compressible liquid has a second compressibility higher than the first compressibility and second thermal expansion coefficient higher than the first thermal expansion coefficient. The compressible liquid can include, for example, hexamethyldisiloxane (HMDS).
대표청구항
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1. An underwater vehicle, comprising: a hull;a compartment carried by the hull and at least partially flooded with a first liquid having similar properties as a surrounding liquid into which the hull is configured to be deployed, wherein the first liquid has a first compressibility; anda compressibi
1. An underwater vehicle, comprising: a hull;a compartment carried by the hull and at least partially flooded with a first liquid having similar properties as a surrounding liquid into which the hull is configured to be deployed, wherein the first liquid has a first compressibility; anda compressibility compensation system comprising a container in the compartment and at least partially filled with a compressible liquid comprising silicone, the compressible liquid having a second compressibility higher than the first compressibility. 2. The underwater vehicle of claim 1 wherein the compressible liquid comprises a polydimethylsiloxane (PDMS) silicone liquid. 3. The underwater vehicle of claim 1 wherein the compressible liquid comprises hexamethyldisiloxane (HMDS). 4. The underwater vehicle of claim 1 wherein the second compressiblity is at least double times greater than the first compressiblity. 5. The underwater vehicle of claim 1 wherein the first liquid has a first thermal expansion coefficient and the compressible liquid comprises a silicone fluid having a second thermal expansion coefficient higher than the first thermal expansion coefficient. 6. The underwater vehicle of claim 1 wherein the container comprises a flexible, pliable material having an arbitrary shape. 7. The underwater vehicle of claim 1 wherein the hull is a pressure hull and the surrounding liquid into which the pressure hull is to be deployed is seawater, and wherein: the pressure hull a volume V, compressibility KV, and thermal expansion coefficient αV;the compressible liquid has a volume VC, compressibility KC and thermal expansion coefficient αC;the seawater has a compressibility of KS and thermal expansion coefficient αS and wherein VC is approximately equivalent to V(KS-KV)-ⅆTⅆP(αS-αV)(KC-KS)-ⅆTⅆP(αC-αS), wherein dT/dP is the temperature gradient in the seawater. 8. The underwater vehicle of claim 1 wherein the compartment is a first compartment and the container is a first container, and wherein the underwater vehicle further comprises: a second compartment carried by the hull and at least partially flooded by the first fluid; anda second container in the second compartment and at least partially filled with the compressible liquid. 9. The underwater vehicle of claim 1 wherein the hull comprises a pressurized portion having a first volume, and wherein the compressibility compensation system has a second volume a fraction less than one of the first volume. 10. The underwater vehicle of claim 1 wherein the compartment have a generally hydrodynamic shape, and wherein the underwater vehicle further comprises: a wing fin coupled to the hull;a rudder fin coupled to the compartment, wherein the rudder fin is oriented generally normal to the wing fin; andan antenna coupled to the underwater vehicle and configured to exchange signals with a remote device. 11. The underwater vehicle of claim 1, further comprising: a buoyancy control system comprising an internal reservoir within the hull, an external hydraulic accumulator within the compartment, and a pump configured to change the buoyancy of the underwater vehicle by moving a liquid between the internal reservoir and the external hydraulic accumulator. 12. An underwater vehicle having a controllable buoyancy volume V, the underwater vehicle comprising a compressee having (a) a bladder, and (b) a compressible fluid within the bladder, wherein the compressee has a total volume VC less than V, and VC comprises approximately V(KS-KV)-ⅆTⅆP(αS-αV)(KC-KS)-ⅆTⅆP(αC-αS), where KS is the compressibility of the surrounding fluid, KV is the underwater vehicle compressibility, KC is the compressibility of the compressible fluid, αS is the thermal expansion coefficient of the surrounding fluid, αV is the thermal expansion coefficient of the underwater vehicle, αC is the thermal expansion coefficient of the compressible fluid, and dT/dP is the temperature gradient with respect to pressure of the surrounding fluid. 13. The underwater vehicle of claim 12 wherein the compressible fluid comprises a silicone-based fluid having a compressiblity at least double that of seawater. 14. A buoyancy controlled underwater vessel, comprising: a body having a compressibility less than a liquid medium into which the vessel is to be deployed, the body including a first portion configured to be pressurized and a second portion separated from the first portion, wherein the second portion is configured to be flooded with the liquid medium;a flexible, pliable container positioned within the second portion of the body; anda volume of silicone material at least partially filling the pliable container. 15. The underwater vessel of claim 14 wherein the silicone material comprises a polydimethylsiloxane (PDMS) silicone liquid. 16. The underwater vessel of claim 14 wherein the silicone material comprises hexamethyldisiloxane (HMDS). 17. The underwater vessel of claim 14 wherein the silicone material has a higher thermal expansion than water.
이 특허에 인용된 특허 (4)
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Nadolink Richard H. (Portsmouth RI), Inflatable undersea vehicle system of special utility as a daughter vessel to a mother vessel.
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Brill ; III ; Alfred P., Low oiling gel filled flexible articles and gels therefor.
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Dubois, Neil J., Self adjusting neutral buoyancy countermeasure and system.
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Stecker, Sr., David W., Surface or underwater dive vehicle.
이 특허를 인용한 특허 (8)
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Ensign, Scott Howard; Neve, Ryan, Devices for measuring parameters of water.
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Glezer, Ari; Weiss, Lora G.; Allen, Mark G., Marine vehicle systems and methods.
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Brandes, John C.; Bullock, Steven Edward; Cuschieri, Joseph M.; Forst, Vincent J.; Said, Brian Robert; Solenski, Joseph M., Polymer drag reduction systems on vehicle surfaces.
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Eriksen, Charles C., Systems and methods for compensating for compressibility and thermal expansion coefficient mismatch in buoyancy controlled underwater vehicles.
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Rikoski, Richard J.; Pompa, Jonathan; Damus, Robert S.; Owens, Dylan, Systems and methods for improving buoyancy in underwater vehicles.
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Morash, James; Pompa, Jonathan; Kfir, Ben; Damus, Robert S.; Rikoski, Richard J., Systems and methods for pressure tolerant energy systems.
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Morash, James; Pompa, Jonathan; Kfir, Ben; Damus, Robert S.; Rikoski, Richard J., Systems and methods for pressure tolerant energy systems.
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Thomas, David Glynn; Kalli, Christopher John; Stine, Eric Randal, Underwater vehicle and sensor.
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