[특허]Micro-fabricated electrokinetic pump with on-frit electrode

Micro-fabricated electrokinetic pump with on-frit electrode 원문보기

IPC분류정보
국가/구분	United States(US) Patent 등록
국제특허분류(IPC7판)	F04F-011/00
출원번호	US-0669495 (2003-09-23)
발명자 / 주소	Kenny,Thomas W. Shook,James Gill Zeng,Shulin Lenehan,Daniel J. Santiago,Juan Lovette,James
출원인 / 주소	Cooligy, Inc.
대리인 / 주소	Haverstock &
인용정보	피인용 횟수 : 17 인용 특허 : 195

초록 ▼

An electroosmotic pump and method of manufacturing thereof. The pump having a porous structure adapted to pump fluid therethrough, the porous structure comprising a first side and a second side, the porous structure having a plurality of fluid channels therethrough, the first side having a first continuous layer of electrically conductive porous material deposited thereon and the second side having a second continuous layer of electrically conductive porous material deposited thereon, the first second layers coupled to a power source, wherein the power source supplies a voltage differential between the first layer and the second layer to drive fluid through the porous structure at a desired flow rate. The continuous layer of electrically conductive porous material is preferably a thin film electrode, although a multi-layered electrode, screen mesh electrode and beaded electrode are alternatively contemplated. The thickness of the continuous layer is in range between and including 200 Angstroms and 10,000 Angstroms.

대표청구항 ▼

What is claimed is: 1. An electroosmotic pump comprising: a. at least one porous structure for pumping fluid therethrough and having an average pore size, the porous structure having a first side and a second side and having a first continuous layer of electrically conductive porous material having a first thickness along an axis parallel to an overall direction of fluid flow disposed on the first side, wherein the first thickness is less than the average pore size and a second continuous layer of electrically conductive porous material having a second thickness along the axis parallel to the overall direction of fluid flow disposed on the second side, wherein the second thickness is less than the average pore size, wherein at least a portion of the porous structure is configured to channel flow therethrough; and b. means for providing electrical voltage to the first layer and the second layer to produce an electrical field therebetween, wherein the means for providing is coupled to the first layer and the second layer. 2. The electroosmotic pump according to claim 1 further comprising means for generating power sufficient to pump fluid through the porous structure at a desired rate, wherein the means for generating is coupled to the means for providing. 3. The electroosmotic pump according to claim 1 wherein the porous structure includes a plurality of fluid channels extending between the first side and the second side. 4. The electroosmotic pump according to claim 1 wherein the first side and the second side are roughened. 5. The electroosmotic pump according to claim 3 wherein the plurality of fluid channels are in a straight parallel configuration. 6. The electroosmotic pump according to claim 3 wherein the plurality of fluid channels are in a non-parallel configuration. 7. The electroosmotic pump according to claim 3 wherein at least two of the plurality of fluid channels are cross connected. 8. The electroosmotic pump according to claim 1 wherein the electrically conductive porous material is disposed as a thin film electrode. 9. The electroosmotic pump according to claim 1 wherein the electrically conductive porous material is disposed as a screen mesh having an appropriate electrically conductivity. 10. The electroosmotic pump according to claim 1 wherein the electrically conductive porous material includes a plurality of conductive beads having a first diameter in contact with one another to pass electrical current. 11. The electroosmotic pump according to claim 10 wherein at least one of the plurality of beads has a second diameter larger than the first diameter. 12. The electroosmotic pump according to claim 1 wherein a predetermined portion of the continuous layer of electrically conductive porous material has a third thickness. 13. The electroosmotic pump according to claim 12 wherein the predetermined portion of the continuous layer is disposed on the surface of the porous structure in one or more desired patterns. 14. The electroosmotic pump according to claim 13 wherein at least one of the desired patterns further comprises a circular shape. 15. The electroosmotic pump according to claim 13 wherein at least one of the desired patterns further comprises a cross-hatched shape. 16. The electroosmotic pump according to claim 13 wherein at least one of the desired patterns further comprises a plurality of parallel lines. 17. The electroosmotic pump according to claim 1 wherein at least a portion of an outer region of the porous structure is made of fused non-porous glass. 18. The electroosmotic pump according to claim 1 wherein the first thickness is within the range between and including 200 Angstroms and 10,000 Angstroms. 19. The electroosmotic pump according to claim 1 wherein the second thickness is within the range between and including 200 Angstroms and 10,000 Angstroms. 20. The electroosmotic pump according to claim 1 wherein the electrically conductive porous material is Platinum. 21. The electroosmotic pump according to claim 1 wherein the electrically conductive porous material is Palladium. 22. The electroosmotic pump according to claim 1 wherein the electrically conductive porous material is Tungsten. 23. The electroosmotic pump according to claim 1 wherein the electrically conductive porous material is Copper. 24. The electroosmotic pump according to claim 1 wherein the electrically conductive porous material is Nickel. 25. The electroosmotic pump according to claim 1 further comprising an adhesion material disposed in between the electrically conductive porous material and the porous structure. 26. The electroosmotic pump according to claim 1 wherein the first layer and the second layer is made of the same electrically conductive porous material. 27. The electroosmotic pump according to claim 1 wherein the first layer and the second layer is made of different electrically conductive porous materials. 28. An electroosmotic porous structure adapted to pump fluid therethrough, the porous structure comprising a first side and a second side, the porous structure having a plurality of fluid channels therethrough, the first side having a first continuous layer of thin film electrode deposited thereon and the second side having a second continuous layer of thin film electrode deposited thereon, the first layer and the second layer coupled to a power source, wherein the power source supplies a voltage differential between the first layer and the second layer to drive fluid through the porous structure at a desired flow rate. 29. The electroosmotic porous structure according to claim 28 wherein the plurality of fluid channels extend from the first side to the second side in a straight parallel configuration. 30. The electroosmotic porous structure according to claim 28 wherein the plurality of fluid channels extend from the first side to the second side in a non-parallel configuration. 31. The electroosmotic porous structure according to claim 28 wherein at least two of the plurality of fluid channels are cross connected. 32. The electroosmotic porous structure according to claim 28 wherein the first layer of electrically conductive porous material is a screen mesh. 33. The electroosmotic porous structure according to claim 28 wherein the electrically conductive porous material further comprises a plurality of conductive beads having a first diameter in contact with one another to pass electrical current. 34. The electroosmotic porous structure according to claim 33 wherein at least one of the plurality of beads has a second diameter larger than the first diameter. 35. The electroosmotic porous structure according to claim 28 wherein a predetermined portion of the continuous layer of electrically conductive porous material has a third thickness. 36. The electroosmotic porous structure according to claim 35 wherein the predetermined portion of the continuous layer is disposed on the surface of the porous structure in one or more desired patterns. 37. The electroosmotic porous structure according to claim 28 wherein at least a portion of an outer region of the porous structure is made of fused non-porous glass. 38. The electroosmotic porous structure according to claim 28 wherein the continuous layer has a thickness within the range between and including 200 Angstroms and 10,000 Angstroms. 39. The electroosmotic porous structure according to claim 28 wherein the electrically conductive porous material is Platinum. 40. The electroosmotic porous structure according to claim 28 wherein the electrically conductive porous material is Palladium. 41. The electroosmotic porous structure according to claim 28 wherein the electrically conductive porous material is Tungsten. 42. The electroosmotic porous structure according to claim 28 wherein the electrically conductive porous material is Nickel. 43. The electroosmotic porous structure according to claim 28 wherein the electrically conductive porous material is Copper. 44. The electroosmotic porous structure according to claim 28 further comprising an adhesion material disposed in between the electrically conductive porous material and the porous structure. 45. An electroosmotic pump comprising: a. at least one porous structure for pumping fluid therethrough, the porous structure having a first side and a second side and having a first continuous layer of electrically conductive porous material having an appropriate first thickness disposed on the first side and a second continuous layer of electrically conductive porous material having a second thickness disposed on the second side wherein at least a portion of the porous structure is configured to channel flow therethrough, and wherein the first side and the second side are roughened; and b. means for providing electrical voltage to the first layer and the second layer to produce an electrical field therebetween, wherein the means for providing is coupled to the first layer and the second layer. 46. An electroosmotic pump comprising: a. at least one porous structure for pumping fluid therethrough, the porous structure having a first side and a second side and having a first continuous layer of electrically conductive porous material having an appropriate first thickness disposed on the first side and a second continuous layer of electrically conductive porous material having a second thickness disposed on the second side wherein at least a portion of the porous structure is configured to channel flow therethrough, and wherein the porous structure includes a plurality of fluid channels extending in a non-parallel configuration between the first side and the second side; and b. means for providing electrical voltage to the first layer and the second layer to produce an electrical field therebetween, wherein the means for providing is coupled to the first layer and the second layer. 47. An electroosmotic pump comprising: a. at least one porous structure for pumping fluid therethrough, the porous structure having a first side and a second side and having a first continuous layer of electrically conductive porous material having an appropriate first thickness disposed on the first side and a second continuous layer of electrically conductive porous material having a second thickness disposed on the second side wherein at least a portion of the porous structure is configured to channel flow therethrough, and wherein the porous structure includes a plurality of fluid channels extending between the first side and the second side, wherein at least two of the plurality of fluid channels are cross connected; and b. means for providing electrical voltage to the first layer and the second layer to produce an electrical field therebetween, wherein the means for providing is coupled to the first layer and the second layer. 48. An electroosmotic pump, comprising: a. a porous structure forming therein a plurality of passages coupling a first set of apertures on a first surface to a second set of apertures on a second surface, wherein at least one of the first set of apertures and the second set of apertures forms a two-dimensional pattern on its surface; b. a first layer of electrically conductive porous material deposited on the first surface and configured so that fluid can pass through the first layer, through the first set of apertures and into the plurality of passages; c. a second layer of electrically conductive porous material deposited on the second surface and configured so that fluid can pass from the plurality of passages through the second set of apertures and through the second layer; and d. means for providing electrical voltage to the first layer and the second layer to produce an electrical field therebetween, wherein the means for providing is coupled to the first layer and the second layer. 49. An electroosmotic porous structure adapted to pump fluid therethrough, the porous structure comprising a first side with a first set of apertures therein and a second side with a second set of apertures therein, the porous structure having a plurality of fluid channels therethrough coupling the first set of apertures to the second set of apertures, the first side having a first continuous layer of electrically conductive porous material deposited thereon so that each of the first set of apertures is surrounded by a continuous structure of electrically conductive porous material and the second side having a second continuous layer of electrically conductive porous material deposited thereon so that each of the second set of apertures is surrounded by a continuous structure of electrically conductive porous material, the first layer and the second layer coupled to a power source, wherein the power source supplies a voltage differential between the first layer and the second layer to drive fluid through the porous structure at a desired flow rate.

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Schwiebert Matthew K. ; Campbell Donald T. ; Heydinger Matthew ; Kraft Robert E. ; Vander Plas Hubert A., Method of bumping substrates by contained paste deposition.
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Hamilton Robin E. ; Kennedy Paul G. ; Ostop John ; Baker Martin L. ; Arlow Gregory A. ; Golombeck John C. ; Fagan ; Jr. Thomas J., Method of extracting heat from a semiconductor body and forming microchannels therein.
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Matthews James A. (Milpitas CA), Method of fabricating a heat exchanger for solid-state electronic devices.
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Matthews James A. (Milpitas CA), Method of fabricating a heat exchanger for solid-state electronic devices.
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Layton Wilber Terry (San Diego CA) Morange Blanquita Ortega (San Diego CA) Torres Angela Marie (Vista CA) Roecker James Andrew (Escondido CA), Method of fabricating an integrated circuit package having a liquid metal-aluminum/copper joint.
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Hsu David S. Y. (Alexandria VA), Method of fabricating sub-half-micron trenches and holes.
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Bezama Raschid J. ; Casey Jon A. ; Pavelka John B. ; Pomerantz Glenn A., Method of forming a multilayer electronic packaging substrate with integral cooling channels.
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Leland John E. ; Ponnappan Rengasamy, Method of making micro channel heat pipe having corrugated fin elements.
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Hoopman Timothy L. (River Falls WI) Krinke Harlan L. (Marine WA), Method of making microchanneled heat exchangers utilizing sacrificial cores.
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Parce John Wallace ; Kopf-Sill Anne R., Methods and apparatus for in situ concentration and/or dilution of materials in microfluidic systems.
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McCormick Randy M. (Santa Clara CA) Rocklin Roy D. (Sunnyvale CA), Methods and apparatus for real-time monitoring, measurement and control of electroosmotic flow.
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Kopf-Sill Anne R., Methods and systems for monitoring and controlling fluid flow rates in microfluidic systems.
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Soane David S. ; Soane Zoya M. ; Hooper Herbert H. ; Amigo M. Goretty Alonso, Methods for fabricating enclosed microchannel structures.
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Dusablon ; Sr. Michael S. (Milton VT) White Eric J. (North Ferrisburg VT), Microcavity structures, fabrication processes, and applications thereof.
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Dusablon ; Sr. Michael S. (Milton VT) White Eric J. (North Ferrisburg VT), Microcavity structures, fabrication processes, and applications thereof.
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Bernhardt Anthony F. (Berkeley CA), Microchannel cooling of face down bonded chips.
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Hamilton Robin E. ; Kennedy Paul G. ; Ostop John ; Baker Martin L. ; Arlow Gregory A. ; Golombeck John C. ; Fagan ; Jr. Thomas J, Microchannel cooling of high power semiconductor devices.
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Hamilton Robin E. (Millersville MD) Kennedy Paul G. (Grasonville MD), Microchannel cooling using aviation fuels for airborne electronics.
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Swift Gregory W. (Los Alamos NM) Migliori Albert (Santa Fe NM) Wheatley John C. (Los Alamos NM), Microchannel crossflow fluid heat exchanger and method for its fabrication.
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Bonde Wayne L. (Livermore CA) Contolini Robert J. (Pleasanton CA), Microchannel heat sink assembly.
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Walpole James N. (Concord MA) Missaggia Leo J. (Milford MA), Microchannel heat sink with alternating flow directions.
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Drost Monte K. ; Wegeng Robert S. ; Friedrich Michele ; Hanna William T. ; Call Charles J. ; Kurath Dean E., Microcomponent assembly for efficient contacting of fluid.
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Fuesser Hans-Juergen,DEX ; Zachai Reinhard,DEX ; Muench Wolfram,DEX ; Gutheit Tim,DEX, Microcooling device and method of making it.
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Weld John David (Succasunna NJ), Microelectronic package with device cooling.
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Weinberg Marc S. (Needham MA), Microfabricated pump.
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Sundberg Steven A. ; Parce J. Wallace ; Chow Calvin Y. H., Microfabricated structures for facilitating fluid introduction into microfluidic devices.
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Arnold Don W. ; Schoeniger Joseph S. ; Cardinale Gregory F., Microfluidic channel fabrication method.
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Michael Knapp ; John Wallace Parce ; Luc J. Bousse ; Anne R. Kopf-Sill, Microfluidic devices and methods for separation.
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Nagle Robert ; Kennedy Colin B., Microfluidic devices and systems incorporating integrated optical elements.
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Dubrow Robert S. ; Kennedy Colin B. ; Bousse Luc J., Microfluidic devices incorporating improved channel geometries.
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Kopf-Sill Anne R. ; Parce John Wallace, Microfluidic systems incorporating varied channel dimensions.
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Lee Abraham P. ; Lemoff Asuncion V., Micromachined magnetohydrodynamic actuators and sensors.
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Hartley Frank T., Micromachined peristaltic pumps.
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Richter Axel (Mnchen DEX), Microminiaturized pump.
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Parce John Wallace, Micropump.
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Parce John Wallace, Micropump.
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Van Lintel Harald,CHX, Micropump.
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van Lintel Harald T. G. (Enschede NLX), Micropump with improved priming.
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Mundinger David C. ; Worland D. Philip, Modular microchannel heat exchanger.
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Benett William J. (Livermore CA) Beach Raymond J. (Livermore CA) Ciarlo Dino R. (Livermore CA), Monolithic microchannel heatsink.
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Tuchinskiy Ley J., Multi-channel structures and processes for making such structures.
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Loo Mike C. (San Jose CA) Vogel Marlin R. (Fremont CA), Multi-chip cooling module and method.
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Chow Calvin Y. H., Multi-layer microfluidic devices.
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Sakamoto Masafumi,JPX, Multi-phase permanent-magnet type electric rotating machine.
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Tauchi Hitoshi,JPX, Multi-stage electronic cooling device.
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Hamilton Robin E. ; Kennedy Paul G. ; Vale Christopher R., Non-mechanical magnetic pump for liquid cooling.
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Frieser Rudolf G. (Poughkeepsie NY) Reeber Morton D. (Shrub Oak NY), Nucleate boiling surface for increasing the heat transfer from a silicon device to a liquid coolant.
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Nazeri Azar, Organic/inorganic composite wicks for caillary pumped loops.
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Zanzucchi Peter J. (Lawrenceville NJ) Cherukuri Satyam C. (Cranbury NJ) McBride Sterling E. (Lawrenceville NJ), Partitioned microelectronic and fluidic device array for clinical diagnostics and chemical synthesis.
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Kenny, Jr., Thomas William; Goodson, Kenneth E.; Santiago, Juan G.; Everett, Jr., George Carl, Power conditioning module.
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Barber, Vernon Alan; Obermaier, Hannsjorg; Patel, Chandrakant D., Power distribution in multi-chip modules.
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Sumberg Andrew J. (Arlington MA), Protection of heat pipes from freeze damage.
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Tam Andrew C. (Saratoga CA) Yeack-Scranton Celia E. (San Jose CA), Pulsed current resistive heating for bonding temperature critical components.
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Beetz ; Jr. Charles P. ; Boerstler Robert W. ; Steinbeck John ; Winn David R., Silicon etching process for making microchannel plates.
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Pace Salvatore J. (Wilmington DE), Silicon semiconductor wafer for analyzing micronic biological samples.
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Cartland William H. (Jupiter FL), Solar heater freeze protection system.
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Andrus Lance ; Fraivillig James ; Barrett Edward ; High Brian, Solderable structures.
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Robert Michael Reese, Solid-state chip cooling by use of microchannel coolant flow.
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Galambos, Paul C.; Okandan, Murat; Montague, Stephen; Smith, James H.; Paul, Phillip H.; Krygowski, Thomas W.; Allen, James J.; Nichols, Christopher A.; Jakubczak, II, Jerome F., Surface-micromachined microfluidic devices.
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Bradley Susan J. (East Hampstead NH), System for bonding a heatsink to a semiconductor chip package.
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Zare Richard N. (Stanford CA) Huang Xiaohua (Mountain View CA) Ohms Jack I. (Palo Alto CA), System for measuring electrokinetic properties and for characterizing electrokinetic separations by monitoring current i.
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Sandhu Bal S. ; Reinhardt Dennis, Thermal sensing circuit.
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Reyzin, Ilya; Bhatti, Mohinder Singh; Ghosh, Debashis; Joshi, Shrikant Mukund, Thermosiphon for electronics cooling with high performance boiling and condensing surfaces.
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Thomas Daniel Lee, Thin, planar heat spreader.
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Woodman John K. (601 Mystic La. Foster City CA 94404), Three dimensional integrated circuit package.
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Woodman John K. (601 Mystic La. Foster City CA 94404), Three dimensional integrated circuit package.
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Larson Ralph I. ; Phillips Richard L., Two phase component cooler.
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Koubek Kevin J. (South Setauket NY) Kosson Robert L. (Massapequa NY) Quadrini John A. (Northport NY), Vapor chamber cooled electronic circuit card.
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Chow Calvin Y. H. ; Parce J. Wallace, Variable control of electroosmotic and/or electrophoretic forces within a fluid-containing structure via electrical forc.
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IPC	Description
A	생활필수품
A62	인명구조; 소방(사다리 E06C)
A62B	인명구조용의 기구, 장치 또는 방법(특히 의료용에 사용되는 밸브 A61M 39/00; 특히 물에서 쓰이는 인명구조 장치 또는 방법 B63C 9/00; 잠수장비 B63C 11/00; 특히 항공기에 쓰는 것, 예. 낙하산, 투출좌석 B64D; 특히 광산에서 쓰이는 구조장치 E21F 11/00)
A62B-1/08	.. 윈치 또는 풀리에 제동기구가 있는 것

내보내기 구분	파일저장 인쇄 메일전송
구성항목	기본정보 상세정보 관리번호, 국가코드, 자료구분, 상태, 출원번호, 출원일자, 공개번호, 공개일자, 등록번호, 등록일자, 발명명칭(한글), 발명명칭(영문), 출원인(한글), 출원인(영문), 출원인코드, 대표IPC 관리번호, 국가코드, 자료구분, 상태, 출원번호, 출원일자, 공개번호, 공개일자, 공고번호, 공고일자, 등록번호, 등록일자, 발명명칭(한글), 발명명칭(영문), 출원인(한글), 출원인(영문), 출원인코드, 대표출원인, 출원인국적, 출원인주소, 발명자, 발명자E, 발명자코드, 발명자주소, 발명자 우편번호, 발명자국적, 대표IPC, IPC코드, 요약, 미국특허분류, 대리인주소, 대리인코드, 대리인(한글), 대리인(영문), 국제공개일자, 국제공개번호, 국제출원일자, 국제출원번호, 우선권, 우선권주장일, 우선권국가, 우선권출원번호, 원출원일자, 원출원번호, 지정국, Citing Patents, Cited Patents
저장형식	Text(ASCII format) Excel format PIAS분석(.xls)
메일정보	받는사람 (필수) @ 보내는사람 (선택) @ 제목 내용 KISTI 검색결과 이메일 서비스
안내	총 건의 자료가 검색되었습니다. 다운받으실 자료의 인덱스를 입력하세요. (1-10,000) 검색결과의 순서대로 최대 10,000건 까지 다운로드가 가능합니다. 데이타가 많을 경우 속도가 느려질 수 있습니다.(최대 2~3분 소요) 다운로드 파일은 UTF-8 형태로 저장됩니다. 파일의 내용이 제대로 보이지 않을실 때는 웹브라우저 상단의 보기 -> 인코딩 -> 자동선택 여부를 확인하십시오. ~ Text(ASCII format) Excel format

연합인증

Micro-fabricated electrokinetic pump with on-frit electrode 원문보기

초록 ▼

대표청구항 ▼

연구과제 타임라인

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이 특허를 인용한 특허 (17)

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연합인증

Micro-fabricated electrokinetic pump with on-frit electrode 원문보기

초록 ▼

대표청구항 ▼

연구과제 타임라인

전체(0) 논문(0) 특허(0) 보고서(0)

전체(0) 논문(0) 특허(0) 보고서(0)

이 특허에 인용된 특허 (195)

이 특허를 인용한 특허 (17)

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