IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0221050
(2011-08-30)
|
등록번호 |
US-8759843
(2014-06-24)
|
발명자
/ 주소 |
- Ramer, David P.
- Rains, Jr., Jack C.
|
출원인 / 주소 |
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
2 인용 특허 :
33 |
초록
▼
An optical/electrical transducer device has housing, formed of a thermally conductive section and an optically transmissive member. The section and member are connected together to form a seal for a vapor tight chamber. Pressure within the chamber configures a working fluid to absorb heat during ope
An optical/electrical transducer device has housing, formed of a thermally conductive section and an optically transmissive member. The section and member are connected together to form a seal for a vapor tight chamber. Pressure within the chamber configures a working fluid to absorb heat during operation of the device, to vaporize at a relatively hot location as it absorbs heat, to transfer heat to and condense at a relatively cold location, and to return as a liquid to the relatively hot location. The transducer device also includes a wicking structure mounted within the chamber to facilitate flow of condensed liquid of the working fluid from the cold location to the hot location. At least a portion of the wicking structure comprises semiconductor nanowires, configured as part of an optical/electrical transducer within the chamber for emitting light through and/or driven by light received via the transmissive member.
대표청구항
▼
1. An optical/electrical transducer apparatus, comprising: a housing having a section that is thermally conductive and a member that is at least partially optically transmissive, the optically transmissive member being connected to the thermally conductive section of the housing to form a seal for a
1. An optical/electrical transducer apparatus, comprising: a housing having a section that is thermally conductive and a member that is at least partially optically transmissive, the optically transmissive member being connected to the thermally conductive section of the housing to form a seal for a vapor tight chamber;a working fluid within the chamber, wherein pressure within the chamber configures the working fluid to absorb heat during operation of the apparatus, to vaporize at a relatively hot location as the working fluid absorbs heat, to transfer heat to and condense at a relatively cold location, and to return as a liquid to the relatively hot location; anda wicking structure mounted within the chamber to facilitate flow of condensed liquid of the working fluid from the cold location to the hot location,at least a portion of the wicking structure in contact with the working fluid comprising semiconductor nanowires configured as an active driven part of an optical/electrical transducer within the chamber and configured to be driven to emit light from within the chamber through and/or to be driven by light received in the chamber via the optically transmissive member. 2. The apparatus of claim 1, wherein a further portion of the wicking structure is comprised of a wick other than semiconductor nanowires. 3. The apparatus of claim 2, wherein the wick of the further portion is at least partially reflective. 4. The apparatus of claim 2, wherein the wick of the further portion comprises metallic nanowires. 5. The apparatus of claim 1, wherein the semiconductor nanowires are configured as at least part of an electrical-to-optical transducer for emitting light via the optically transmissive member of the housing when driven by an electrical current. 6. The apparatus of claim 1, wherein the semiconductor nanowires are configured as at least part of an optical-to-electrical transducer for producing an electrical current in response to light received via the optically transmissive member of the housing. 7. The apparatus of claim 1, wherein the working fluid is electrically conductive for carrying an electrical current to or from at least some of the semiconductor nanowires. 8. The apparatus of claim 1, wherein the housing, the chamber, the working fluid and the wicking structure together form a thermal conductivity and phase transition heat transfer mechanism for transferring heat away from the optical/electrical transducer within the chamber. 9. An optical/electrical transducer apparatus, comprising: a semiconductor transducer including semiconductor nanowires configured to be driven to convert between optical and electrical energy;a housing having a section that is thermally conductive and a member, that is at least partially optically transmissive, the optically transmissive member being connected to the thermally conductive section of the housing to form a seal for a vapor tight chamber formed by the housing,the semiconductor transducer being mounted with at least the semiconductor nanowires within the chamber and configured so as to be driven to emit light from within the chamber or to receive light to drive the semiconductor nanowires in the chamber, via the optically transmissive member;a working fluid within the chamber, wherein pressure within the chamber configures the working fluid to absorb heat from the semiconductor transducer during operation of the apparatus, to vaporize at a relatively hot location at or near the semiconductor nanowires as the working fluid absorbs heat, to transfer heat to and condense at a relatively cold location, and to return as a liquid to the relatively hot location; anda wicking structure mounted within the chamber to facilitate flow of condensed liquid of the working fluid from the cold location to the hot location,wherein the semiconductor nanowires of the semiconductor transducer also are configured as a portion of the wicking structure exposed to the working fluid in the chamber. 10. The apparatus of claim 9, wherein a further portion of the wicking structure is comprised of a wick other than semiconductor nanowires. 11. The apparatus of claim 10, wherein the wick of the further portion is at least partially reflective. 12. The apparatus of claim 10, wherein the wick of the further portion comprises metallic nanowires. 13. The apparatus of claim 9, wherein the transducer having the semiconductor nanowires is configured as an electrical-to-optical transducer for emitting light when driven by an electrical current. 14. The apparatus of claim 9, wherein the transducer having the semiconductor nanowires is configured as an optical-to-electrical transducer for producing an electrical current in response to light. 15. The apparatus of claim 9, wherein the working fluid is electrically conductive for carrying an electrical current to or from at least some of the semiconductor nanowires. 16. The apparatus of claim 9, wherein the housing, the chamber, the working fluid and the wicking structure together form a thermal conductivity and phase transition heat transfer mechanism for transferring heat away from the semiconductor transducer. 17. A device for emitting light, comprising: a semiconductor light emitting device including semiconductor nanowires configured to be driven to emit light in response to an electrical drive current;a housing having a section that is thermally conductive and a member that is at least partially optically transmissive, the optically transmissive member being connected to the thermally conductive section of the housing to form a seal for a vapor tight chamber formed by the housing,the semiconductor light emitting device being mounted with at least the semiconductor nanowires within the chamber so as to be driven to emit light from within the chamber through the optically transmissive member as an output;a working fluid within the chamber, wherein pressure within the chamber configures the working fluid to absorb heat from the semiconductor nanowires during operation of the apparatus, to vaporize at a relatively hot location at or near the semiconductor nanowires as the working fluid absorbs heat, to transfer heat to and condense at a relatively cold location, and to return as a liquid to the relatively hot location; anda wicking structure mounted within the chamber to facilitate flow of condensed liquid of the working fluid from the cold location to the hot location, wherein:the housing, the chamber, the working fluid and the wicking structure together form a thermal conductivity and phase transition heat transfer mechanism for transferring heat away from the semiconductor light emitting device, andthe semiconductor nanowires of the semiconductor light emitting device also are configured as a portion of the wicking structure exposed to the working fluid in the chamber. 18. The device of claim 17, further comprising a heat sink coupled to the cold location of the thermal conductivity and phase transition heat transfer mechanism. 19. A device for producing an electrical signal in response to light, comprising: a semiconductor transducer including semiconductor nanowires configured to be driven in response to received light to produce an electrical current;a housing having a section that is thermally conductive and a member that is at least partially optically transmissive, the optically transmissive member being connected to the thermally conductive section of the housing to form a seal for a vapor tight chamber formed by the housing,the semiconductor light emitting device being mounted with at least the semiconductor nanowires within the chamber and configured so as to receive light in the chamber via the optically transmissive member as an input for processing to drive the semiconductor transducer to produce the electrical current;a working fluid within the chamber, wherein pressure within the chamber configures the working fluid to absorb heat from the semiconductor nanowires during operation of the apparatus, to vaporize at a relatively hot location at or near the semiconductor nanowires as the working fluid absorbs heat, to transfer heat to and condense at a relatively cold location, and to return as a liquid to the relatively hot location; anda wicking structure mounted within the chamber to facilitate flow of condensed liquid of the working fluid from the cold location to the hot location, wherein:the housing, the chamber, the working fluid and the wicking structure together form a thermal conductivity and phase transition heat transfer mechanism for transferring heat away from the semiconductor transducer, andthe semiconductor nanowires of the semiconductor transducer also are configured as a portion of the wicking structure exposed to the working fluid in the chamber. 20. The device of claim 19, further comprising a heat sink coupled to the cold location of the thermal conductivity and phase transition heat transfer mechanism. 21. An optical/electrical transducer apparatus, comprising: a housing having a section that is thermally conductive and a member that is at least partially optically transmissive, the optically transmissive member being connected to the thermally conductive section of the housing to form a seal for a vapor tight chamber;a working fluid within the chamber, wherein pressure within the chamber configures the working fluid to absorb heat during operation of the apparatus, to vaporize at a relatively hot location as the working fluid absorbs heat, to transfer heat to and condense at a relatively cold location, and to return as a liquid to the relatively hot location; anda wicking structure mounted within the chamber to facilitate flow of condensed liquid of the working fluid from the cold location to the hot location,at least a portion of the wicking structure in contact with the working fluid comprising semiconductor nanowires within the chamber formed by the housing,the semiconductor nanowires in contact with the working fluid being configured to operate electrically as at least part of an active optical/electrical transducer to convert between optical and electrical energy and positioned to be driven to emit light from inside the chamber through and/or to be driven by light received in the chamber via the optically transmissive member when operating as part of the optical/electrical transducer. 22. The device of claim 17, wherein each semiconductor nanowire comprises: a first semiconductor of one of two semiconductor types, the first semiconductor forming a core electrically coupled to a conducting base;a second semiconductor of the other of the two semiconductor types, the second semiconductor being exposed to the working fluid in the chamber; anda semiconductor junction or intrinsic region formed between the first and second semiconductors. 23. The device of claim 19, wherein each semiconductor nanowire comprises: a first semiconductor of one of two semiconductor types, the first semiconductor forming a core electrically coupled to a conducting base;a second semiconductor of the other of the two semiconductor types, the second semiconductor being exposed to the working fluid in the chamber; anda semiconductor junction or intrinsic region formed between the first and second semiconductors.
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