$\require{mediawiki-texvc}$
  • 검색어에 아래의 연산자를 사용하시면 더 정확한 검색결과를 얻을 수 있습니다.
  • 검색연산자
검색연산자 기능 검색시 예
() 우선순위가 가장 높은 연산자 예1) (나노 (기계 | machine))
공백 두 개의 검색어(식)을 모두 포함하고 있는 문서 검색 예1) (나노 기계)
예2) 나노 장영실
| 두 개의 검색어(식) 중 하나 이상 포함하고 있는 문서 검색 예1) (줄기세포 | 면역)
예2) 줄기세포 | 장영실
! NOT 이후에 있는 검색어가 포함된 문서는 제외 예1) (황금 !백금)
예2) !image
* 검색어의 *란에 0개 이상의 임의의 문자가 포함된 문서 검색 예) semi*
"" 따옴표 내의 구문과 완전히 일치하는 문서만 검색 예) "Transform and Quantization"

과학기술 지식인프라 ScienceON

상세검색 다국어 입력
도움말도움말
쳇봇 이모티콘
안녕하세요!
ScienceON 챗봇입니다.
궁금한 것은 저에게 물어봐주세요.

특허 상세정보

MyON담기
내보내기

High efficiency natural gas engine driven cooling system

국가/구분 United States(US) Patent 등록
국제특허분류(IPC7판) F01K-023/10   
미국특허분류(USC) 60/618
출원번호 US-0944537 (1992-09-14)
발명자 / 주소
인용정보 피인용 횟수 : 32  인용 특허 : 0
초록

A method for recovering and utilizing residual waste heat energy normally rejected into the atmosphere from a combined direct expansion refrigeration system driven by a natural gas or internal combustion engine, wherein the waste heat energy rejected from the condenser of the refrigeration system is combined with the heat energy rejected from the engine block cooling fluid and the exhaust gas stream and recovered by a refrigerant power fluid to drive a vapor power expander and co-generate auxiliary electric power.

대표
청구항

In combination with a natural gas fueled engine driven liquid chiller system having a refrigerant vapor compressor, a refrigerant evaporator and a refrigerant condenser, wherein the improvement allows waste heat energy from an engine cooling fluid, an engine exhaust gas stream, and from the refrigerant condenser of said chiller system to be recovered and utilized to co-generate electric power, the improvement which comprises; a natural gas fueled engine having an exhaust gas heat exchanger to exchange heat between the exhaust gas stream and the engine co...

이 특허를 인용한 특허 피인용횟수: 32

  1. Filippone, Claudio. Air-conditioning systems and related methods. USP2009087574870.
  2. Taylor, Dwayne Robert. Condenser, radiator, and fan module with Rankine cycle fan. USP2012128327654.
  3. Bartosch, Stephan; Berger, Jürgen; Bausch, Christian. Drive train of a motor vehicle with a compressed-air system. USP2013018359860.
  4. Bartosch, Stephan; Berger, Jürgen. Drive train, in particular vehicle drive train. USP2014108857181.
  5. Togawa, Kazuhiro; Takemura, Kazuhito. Engine exhaust heat recovering apparatus. USP2005076913068.
  6. Myers, Scott R.; Miller, Robert. Fluid flow in a fluid expansion system. USP2014098839622.
  7. Myers, Scott R.; Huber, David J.. Generating energy from fluid expansion. USP2014068739538.
  8. Huber, David J. Hybrid gas turbine and internal combustion engine. USP2012038141360.
  9. Hanna, William Thompson; Anson, Donald; Stickford, Jr., George Henry; Coll, John Gordon. Integrated micro combined heat and power system. USP2003076598397.
  10. Hans Otto Mieth DE; Peter Thomsen DE; Marcus Gunther DE. METHOD OF HEAT TRANSFORMATION FOR GENERATING HEATING MEDIA WITH OPERATIONALLY NECESSARY TEMPERATURE FROM PARTLY COLD AND PARTLY HOT HEAT LOSS OF LIQUID-COOLED INTERNAL COMBUSTION PISTON ENGINES AND D. USP2002116484501.
  11. Close, Cameron. Mass management system for a supercritical working fluid circuit. USP20180910077683.
  12. Filippone, Claudio. Miniaturized waste heat engine. USP2015089097205.
  13. Filippone, Claudio. Miniaturized waste heat engine. USP2004056729137.
  14. Filippone,Claudio. Miniaturized waste heat engine. USP2008107430865.
  15. Minemi, Masahiko; Miura, Hiroyuki; Yoshida, Kazuo; Miyao, Masakatsu. Rankine cycle device of internal combustion engine. USP2005066910333.
  16. Myers, Scott R.; Miller, Robert. Recovering heat energy. USP2012048146360.
  17. Heinbokel, Bernd; Haaf, Siegfried. Refrigerating system and method for refrigerating. USP2012118316654.
  18. Faka, Solomon Aladja. Regasification of LNG using dehumidified air. USP2013128607580.
  19. Olson Gregg ; Gover Benjamin. Single core dual circuit heat exchange system. USP2000096124644.
  20. Watson,David B.; Sorge,Gregory W.. System and method of use of expansion engine to increase overall fuel efficiency. USP2007097272932.
  21. Primlani, Indru J.. System and method of waste heat recovery and utilization. USP2011027891186.
  22. Uno,Keiichi; Asa,Hironori; Inaba,Atsushi; Yamanaka,Takashi; Yoshida,Hideji; Ogawa,Hiroshi. System utilizing waste heat of internal combustion engine. USP2007027181919.
  23. Smith, J. Walter. Systems and methods for thermal management in a gas turbine powerplant. USP2013098534044.
  24. Jobson,Edward. Thermal energy recovery device. USP2006127152407.
  25. Pesce, John; Pesce, David. Thermo-electric engine. USP2013018353160.
  26. Motakef, Abbas; Feher, Peter. Turbine inlet air heat pump-type system. USP2016109470149.
  27. Morris, John Michael; Sealy, Mark Edwards Byers. Vehicle waste heat recovery system. USP2018049932863.
  28. Endoh, Tsuneo; Komatsu, Haruhiko; Minemi, Masahiko; Baba, Tsuyoshi; Honma, Kensuke. Waste heat recovery device for internal combustion engine. USP2004056732525.
  29. Xu, James Jun; Scharl, Albert Andreas; Blumber, Eric Joseph; Imani, Shamim. Waste heat recovery system generator encapsulation. USP2015059024460.
  30. Xu, James Jun; Scharl, Albert Andreas; Blumber, Eric Joseph. Waste heat recovery system generator varnishing. USP2015049018778.
  31. Hamada,Shinichi; Sasaki,Minoru; Inaba,Atsushi. Waste heat recovery system of heat source, with Rankine cycle. USP2008117454910.
  32. Xu, James Jun; Scharl, Albert Andreas; Imani, Shamim. Waste heat recovery systems. USP2015038984884.

IPC 상위 출원인