Multi-layer insulation composite material including bandgap material, storage container using same, and related methods
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B29D-022/00
B32B-009/04
B32B-009/00
출원번호
US-0152467
(2008-05-13)
등록번호
US-8211516
(2012-07-03)
발명자
/ 주소
Bowers, Jeffrey A.
Hyde, Roderick A.
Ishikawa, Muriel Y.
Jung, Edward K. Y.
Kare, Jordin T.
Leuthardt, Eric C.
Myhrvold, Nathan P.
Nugent, Jr., Thomas J.
Tegreene, Clarence T.
Whitmer, Charles
Wood, Jr., Lowell L.
출원인 / 주소
Tokitae LLC
대리인 / 주소
Workman Nydegger
인용정보
피인용 횟수 :
13인용 특허 :
50
초록▼
In one embodiment, a multi-layer insulation (MLI) composite material includes a first thermally-reflective layer and a second thermally-reflective layer spaced from the first thermally-reflective layer. At least one of the first or second thermally-reflective layers includes bandgap material that is
In one embodiment, a multi-layer insulation (MLI) composite material includes a first thermally-reflective layer and a second thermally-reflective layer spaced from the first thermally-reflective layer. At least one of the first or second thermally-reflective layers includes bandgap material that is reflective to infrared electromagnetic radiation. A region between the first and second thermally-reflective layers impedes heat conduction between the first and second thermally-reflective layers. Other embodiments include a storage container including a container structure that may be at least partially formed from such MLI composite materials, and methods of using such MLI composite materials.
대표청구항▼
1. A multi-layer insulation (MLI) composite material, comprising: a first thermally-reflective layer;a second thermally-reflective layer spaced from the first thermally-reflective layer, at least one of the first or second thermally-reflective layers including bandgap material that is reflective to
1. A multi-layer insulation (MLI) composite material, comprising: a first thermally-reflective layer;a second thermally-reflective layer spaced from the first thermally-reflective layer, at least one of the first or second thermally-reflective layers including bandgap material that is reflective to infrared electromagnetic radiation and transmissive to at least one of visible electromagnetic radiation or radio-frequency electromagnetic radiation, wherein the bandgap material includes at least one of a photonic crystal, a semiconductor material that exhibits an electronic bandgap, or a material that exhibits both an electronic bandgap and at least one photonic bandgap; anda region between the first and second thermally-reflective layers that impedes heat conduction between the first and second thermally-reflective layers, wherein the region is at least partially evacuated or includes at least one of a low thermal conductivity aerogel, a low thermal conductivity foam, or a low thermal conductivity mass of fibers. 2. The MLI composite material of claim 1, wherein the first and second thermally-reflective layers are transmissive to the visible electromagnetic radiation over at least part of the visible wavelength spectrum. 3. The MLI composite material of claim 1, wherein the first and second thermally-reflective layers are transmissive to the radio-frequency electromagnetic radiation over at least part of the radio-frequency wavelength spectrum. 4. The MLI composite material of claim 1, wherein the bandgap material includes at least one photonic crystal that is reflective to the infrared electromagnetic radiation over a range of wavelengths. 5. The MLI composite material of claim 1, wherein the at least one photonic crystal includes a one-dimensional photonic crystal, a two-dimensional photonic crystal, or a three-dimensional photonic crystal. 6. The MLI composite material of claim 5, wherein the at least one photonic crystal includes a one-dimensional photonic crystal that is reflective to the infrared electromagnetic radiation regardless of a wavevector of the infrared electromagnetic radiation. 7. The MLI composite material of claim 1, wherein the first thermally-reflective layer includes the bandgap material, the bandgap material being a first bandgap material reflective to infrared electromagnetic radiation over a first range of wavelengths; andthe second thermally reflective layer includes a second bandgap material reflective to infrared electromagnetic radiation over a second range of wavelengths. 8. The MLI composite material of claim 1, wherein the bandgap material includes: a first bandgap material that is reflective to infrared electromagnetic radiation over a first range of wavelengths; anda second bandgap material that is reflective to infrared electromagnetic radiation over a second range of wavelengths, wherein the first range of wavelengths and the second range of wavelengths are different. 9. The MLI composite material of claim 1, wherein the bandgap material includes at least one semiconductor material having an electronic bandgap with a magnitude such that the at least one semiconductor material reflects the infrared electromagnetic radiation over a range of wavelengths. 10. The MLI composite material of claim 1, wherein the first and second thermally-reflective layers are spaced from each other by an electrostatic repulsive force. 11. The MLI composite material of claim 1, wherein the first and second thermally-reflective layers are spaced from each other by a magnetic repulsive force. 12. The MLI composite material of claim 1, wherein at least one of the first or second thermally-reflective layers includes a substrate on which the bandgap material is disposed. 13. The MLI composite material of claim 12, wherein the substrate comprises an inorganic substrate. 14. The MLI composite material of claim 12, wherein the substrate comprises a flexible, polymeric substrate. 15. The MLI composite material of claim 1, wherein the bandgap material is reflective to the infrared electromagnetic radiation over a range of wavelengths. 16. The MLI composite material of claim 15, wherein the range of wavelengths is between about 1 μm to about 15 μm. 17. The MLI composite material of claim 16, wherein the range of wavelengths is about 8 μm to about 12 μm. 18. The MLI composite material of claim 1, further comprising at least one additional layer spaced from the second thermally-reflective layer and including an additional bandgap material reflective to electromagnetic radiation that falls outside of the infrared electromagnetic radiation spectrum; and a second region between the second thermally-reflective layer and at least one additional layer that impedes heat conduction between the second thermally-reflective layer and the at least one additional layer. 19. A storage container, comprising: a container structure defining at least one storage chamber, the container structure configured to allow ingress of an object into the at least one storage chamber and egress of the object from the at least one storage chamber, the container structure including multi-layer insulation (MLI) composite material having at least one thermally reflective layer including bandgap material that is reflective to infrared electromagnetic radiation, wherein the bandgap material includes at least one of a photonic crystal, a semiconductor material that exhibits an electronic bandgap, or a material that exhibits both an electronic bandgap and at least one photonic bandgap. 20. The storage container of claim 19, wherein the at least one thermally-reflective layer is transmissive to visible electromagnetic radiation over at least part of the visible wavelength spectrum. 21. The storage container of claim 19, wherein the at least one thermally-reflective layer is transmissive to radio-frequency electromagnetic radiation over at least part of the radio-frequency wavelength spectrum, and further comprising: a first device located within the container structure, the first device being configured to communicate via one or more radio-frequency signals with at least one second device that is external to the container structure. 22. The storage container of claim 19, wherein the at least one photonic crystal includes a one-dimensional photonic crystal, a two-dimensional photonic crystal, or a three-dimensional photonic crystal. 23. The storage container of claim 22, wherein the at least one photonic crystal includes a one-dimensional photonic crystal that is reflective to the infrared electromagnetic radiation regardless of a wavevector of the infrared electromagnetic radiation. 24. The storage container of claim 19, wherein the at least one thermally-reflective layer of the MLI composite material includes: a first thermally-reflective layer including the bandgap material, the bandgap material being a first bandgap material reflective to infrared electromagnetic radiation over a first range of wavelengths; anda second thermally-reflective layer including a second bandgap material reflective to infrared electromagnetic radiation over a second range of wavelengths. 25. The storage container of claim 19, wherein the bandgap material includes: a first bandgap material that is reflective to infrared electromagnetic radiation over a first range of wavelengths; anda second bandgap material that is reflective to infrared electromagnetic radiation over a second range of wavelengths, wherein the first range of wavelengths and the second range of wavelengths are different. 26. The storage container of claim 19, wherein the bandgap material of the at least one thermally-reflective layer includes at least one semiconductor material having an electronic bandgap with a magnitude such that the at least one semiconductor material reflects the infrared electromagnetic radiation over a range of wavelengths. 27. The storage container of claim 19, wherein the at least one thermally-reflective layer includes first and second thermally-reflective layers spaced from each other by an electrostatic repulsive force. 28. The storage container of claim 19, wherein the at least one thermally-reflective layer includes first and second thermally-reflective layers spaced from each other by a magnetic repulsive force. 29. The storage container of claim 19, wherein the at least one thermally-reflective layer includes: a first thermally-reflective layer;a second thermally-reflective layer spaced from the first thermally-reflective layer; anda region between the first and second thermally-reflective layers that impedes heat conduction therebetween. 30. The storage container of claim 29, wherein the region includes at least one low-thermal conductivity material selected from the group consisting of an aerogel, a foam, and a mass of fibers. 31. The storage container of claim 19, wherein the at least one thermally-reflective layer includes a substrate on which the bandgap material is disposed. 32. The storage container of claim 31, wherein the substrate comprises an inorganic substrate. 33. The storage container of claim 31, wherein the substrate comprises a flexible, polymeric substrate. 34. The storage container of claim 19, wherein the MLI composite material includes at least another thermally-reflective layer that is reflective to electromagnetic radiation that can damage a biological substance positioned within the at least one storage chamber. 35. The storage container of claim 19, wherein the bandgap material of the at least one thermally-reflective layer is reflective to the infrared electromagnetic radiation over a range of wavelengths. 36. The storage container of claim 35, wherein the range of wavelengths is between about 1 μm to about 15 μm. 37. The storage container of claim 36, wherein the range of wavelengths is about 8 μm to about 12 μm. 38. The storage container of claim 19, wherein the MLI composite material forms at least part of a window in the container structure for viewing an object positioned in the at least one storage chamber. 39. The storage container of claim 19, wherein the MLI composite material forms at least part of a window in the container structure for radio-frequency communication with an object positioned in the at least one storage chamber. 40. The storage container of claim 19, wherein the MLI composite material forms at least a portion of the container structure. 41. The storage container of claim 19, wherein the container structure includes: a receptacle; anda lid configured to be attached to the receptacle. 42. The storage container of claim 19, wherein the container structure includes one or more interlocks configured to provide controllable egress of an object stored in the at least one storage chamber.
Owen, Donald R.; Kravitz, David C.; Brassil, John; Brockbank, Kelvin G. M.; Burroughs, Andrew; Isaacs, Dickon; Steibel, Dennis; Fraser, Richard; Harris, Stanley; Schein, Douglas, Apparatus and method for maintaining and/or restoring viability of organs.
Leonard Ronald J. (Ann Arbor MI) Lindsay Erin J. (Manchester MI) Maurer David B. (Ann Arbor MI) Viitala Daniel W. (Ann Arbor MI), Blood oxygenation system and reservoir and method of manufacture.
Blom Anders (Gllivare SEX) Gustavsson Jarl (Hakkas SEX), Device for wrapping and welding under vacuum, used in the manufacture of a thermally insulated container.
Epstein Arthur J. (Bexley OH) Roe Mitchell G. (Franklin TN) Ginder John M. (Plymouth MI) Hajiseyedjavadi Hamid (Palmdale CA) Joo Jinsoo (Columbus OH), Electromagnetic radiation absorbers and modulators comprising polyaniline.
Bronshtein, Victor; Bracken, Kevin R.; Livers, Ronnie K.; Williams, David R., Industrial scale barrier technology for preservation of sensitive biological materials.
Kral Stephen F. (Madison WI) Barclay John A. (Madison WI) Claybaker Peter (Madison WI) Jaeger Steven R. (Madison WI), Magnetic refrigeration apparatus for He II production.
Boffito Claudio (Milan ITX) Barosi Aldo (Milan ITX) Figini Alessandro (Milan ITX), Non-evaporable ternary gettering alloy and method of use for the sorption of water, water vapor and other gases.
Bogue, William; Cook, III, Grant O.; Lomasney, Gary M.; Parkos, Joseph; Kling, Colin J.; Watson, Charles R., Erosion and wear protection for composites and plated polymers.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.