Application of sorption heat pumps for increasing of new power sources efficiency

• Autorzy: Vasiliev L. , Filatova O. , Tsitovich A.
• Języki publikacji: EN

Abstrakty

EN

In the 21st century the way to increase the efficiency of new sources of energy is directly related with extended exploration of renewable energy. This modern tendency ensures the fuel economy needs to be realized with nature protection. The increasing of new power sources efficiency (cogeneration, trigeneration systems, fuel cells, photovoltaic systems) can be performed by application of solid sorption heat pumps, regrigerators, heat and cold accumulators, heat transformers, natural gas and hydrogen storage systems and efficient heat exchangers.

Słowa kluczowe

EN

fuel cells; heat exchangers; heat pumps; sorbent materials; trigeneration

PL

heat pipes; ogniwo paliwowe; pompa ciepła; rurki ciepła; sorbent; trójkogeneracja; wymiennik ciepła

• Wydawca: Wydawnictwo Instytutu Maszyn Przepływowych PAN ; Komitet Termodynamiki i Spalania PAN
• Czasopismo: Archives of Thermodynamics
• Rocznik: 2010
• Tom: Vol. 31, no. 2
• Strony: 21--43
• Opis fizyczny: Bibliogr. 37 poz.,Fot., rys., tab., wykr

Twórcy

autor

Vasiliev L.

autor

Filatova O.

autor

Tsitovich A.

• Luikov Heat and Mass Transfer Institute, National Academy of Sciences of Belarus, P. Brovka 15, Minsk 220072, Belarus,

Bibliografia

• 1. SIMANDER G.R.: Fuel cell technology for natural gas. E.V.A. - The Austrian Energy.
• 2. ARISTOV Y.I., VASILIEV L.L., NAKORYAKOV V.E.: Chemical and sorption heat engines: state of the art development prospects in the Russian Federation and the Republic of Belarus. J. Eng. Physics & Thermophysics 81(2008)1, 17-47.
• 3. VASILIEV L., NIKANPOUR D., ANTUKH A., SNELSON K., VASILIEV L., JR. LEBRU A.: Multisalt-carbon chemical cooler for space applications. J. Eng. Physics & Thermophysics 72(1999), 595-600.
• 4. LEPINASSE E., MARION M., GOETZ V.: Cooling storage with resorption process. Application to a box temperature control. Appl. Therm. Eng. 21(2001), 1251-1263.
• 5. VASILIEV L.L., GULKO N.V., KHAUSTOV V.M.: Solid adsorption refrigerators with active carbon-acetone and carbon-ethanol pairs. Solid Sorption Refrigeration Symposium, Paris 1992.
• 6. VASILIEV L.L., MISHKINIS D.A., ANTUKH A.A., VASILIEC L.L., JR.: A solar and electrical solid sorption refrigerator. Int. L. Thermal Sci. 38(1999), 220-227.
• 7. VASILIEV L.L., MISHKINIS D.A., ANTUKH A.A., VASILIEV L.L., JR.: a solar-gas solid sorption refrigerator. J. Adsorption 7(2001), s149-161.
• 8. RALDOW W.M.: WENTWORTH W.E.: Chemical heat pumps - a basic thermodynamic analysis. Solar Energy, 23(1979), 75-79.
• 9. WONGGSUWAN W., KUMAR S., NEVEU P., MEUNIER F.: Review of chemical hest pump technology and applications. Appl. Therm. Eng. 21(2001), 1489-1519.
• 10. POELSTRA S., HAIJE W.G., DIJKSTRA J.W.: Techno-economic feasibility of high-temperature high-lift chemical heat pumps for upgrading industrial waste heat. Appl. Therm. Eng. 22(2002), 1619-1630.
• 11. MEUNIER F.: Second law analysis of a solid adsorption heat pump operating on reversible cascade cycles: application to the zeolite-water pair. Heat Recovery Systems 5(1985), 133-141.
• 12. TOZER R.M., JAMES I.W.: Fundamental thermodynamics of ideal absorption cycles. Int. J. Refrig. 20(1997)2, 120-135.
• 13. EL-SHARKWARY I.I., KUWAHARA K., SAHA B.B., KOYAMA S., NG K.C.: Experimental investigation on adsorption of ethanol onto activated carbon fibers for possible application in adsorption cooling system. Appl. Therm. Eng. 26(2006), 859-865.
• 14. SHARKAWY I.I., SAHA B.B., KOYAMA S., HE L., NG K.C., YAP C.: Experimental investigation on activated carbon-ethanol pair for solar powered adsorption cooling applications. In. J. Refrig. 31(2008), 1407-1413.
• 15. LU Y.Z., WANG R.Z., ZHANG M., JIANGZHOU S.: Adsorption cold storage system with zeolite-water working pair used for locomotive air conditioning. Energy Conversion & Management 44(2003), 1733-1743.
• 16. WANG L.W., WANG R.Z., WU J.Y., WANG K.: Compound adsorbent for adsorption ice maker on fishing boats. Int. J. Refrig. 27(2004), 401-408.
• 17. LAMBERT M.A., JONES B.J.: Review of Regenerative Adsorption Heat Pumps. J. Thermophysics & Heat Transfer 19(2005)4, 471-493.
• 18. VASILIEV L., KANONCHIK L., ANTUKH A., KULAKOV A., ROSIN I.: Waste Heat Driven Solid Sorption Coolers. SAE Technical Paper 941580, 1994.
• 19. VASILIEV L.L., MISHKINIS D.A., VASILIEV L.L. JR.: Complex compound/ammonia coolers. SAE Technical Paper Series 961462, 26th Int. Conf. on Environmental Systems, Monterey 1996.
• 20. VASILIEV L.L., KANONCHIK L.E., ANTUKII A.A., KULAKOV A.G.: NAX zeolite carbon fiber and CaCl2 ammonia reactors for heat pumps and refrigerators. J. Adsorption 2(1996), 311-316.
• 21. NEVEU P., CASTAING J.: Solid-gas chemical heat pumps: field of application and performance of the internal heat of reaction recovery process. Heat Recov. Syst. CHP 13(1993), 233-251.
• 22. CRITOPH R.E.: Performance limitations of adsorption cycles for solar cooling. Solar Energy 41(1988), 21-31.
• 23. WANG R.Z.: Adsorption refrigeration research in Shanghai Jiao Tong University. Renew Sust Energy Rev. 5(2001), 1-37.
• 24. SAHA B.B., KOYAMA S., KASHIWAGI T., AKISAWA A., NG K.C., CHUA H.T.: Waste heat driven dual-mode, multi-stage, multi-bed regenerative adsorption system. Int. J. Refrig. 26(2003), 749-757.
• 25. ARISTOV YU.I., GLAZNEV I.S., FRENI A., RESTUCCIA G.: Kinetics of water sorption on SWS-1L (calcium chloride confined to mesoporous silica gel): Influence of grain size and temperature, Chem. Eng. Sci. 61(2006), 1453-1458.
• 26. MAURAN S., LAHMIDI H., GOETZ V.: Solar heating and cooling by a thermochemical-process. First experiments of a prototype storing 60 kWh by a solid/gas reaction. Solar Energy 82(2008), 623-636.
• 27. LI T.X., WANG R.Z., WANG L.W., LU Z.S., CHEN C.J.: Performance study of a highefficient multifunction heat pipe type adsorption ice making system with novel mass and heat recovery processes. Int. J. Therm. Sci. 46(2007), 1267-1274.
• 28. VASILIEV L.L., ANTUKH A.A., MAZIUK V.V., KULAKOV A.G., RABETSKY M.I., VASILIEV L.L. JR., OH SE MIN: Miniature heat pipes, experimental analysis and software. Proc. of the 12th Int. Heat Pipe Conf., Moscow - Kostroma, May 19-24, 2002.
• 29. SPINNER B., STITOU D., GRINI P.G.: Cascading Sorption Machines: New Concepts for the Power Control of Solid-Gas Thermochemical Systems. Towards Sustainable Technologies, Proc. of the 1996 Absorption Heat Pump Conf., Montreal, Sept. 17-20, 1996, Vol. 2, 531-538.
• 30. VASILIEV L.L., MISHKINIS D.A., ANTUKH A.A., KULAKOV A.G., VASILIEV L.L. JR.: Multisalt-carbon portable chemical heat pump. Proc. of the Int. Sorption Heat Pump Conf., Changhai, China, Sept. 24-27, 2002, 463-468.
• 31. MEUNIER F.: Solid sorption heat powered cycles for cooling and heat pumping applications. Appl. Therm. Eng. 18(1998), 715-729.
• 32. LEPINASSE E., GOETZ V., CROZAT G.: Modelling and experimental investigation of anew type of thermochemical transformer based on the coupling of two solid-gas reactions. Chem. Eng. Proc. 33(1994), 125-134.
• 33. CHOI H.K., NEVEU P., SPINNER B.: System modeling and parameter effects on designand performance of ammonia based thermochemical transformer. Proc. Int. Absorption Heat Pump Conf., Montreal 1996.
• 34. GOETZ V., SPINNER B., LEPINASSE E.: A solid-gas thermochemical cooling system using BaCl2 and NiCl2. Energy, 22(1997), 46-58.
• 35. VASILIEV L.L., MISHKINIS D.A., ANTUKH A.A., KULAKOV A.G.: Resorption heat pump. Appl. Therm. Eng. 24(2004), 1893-1903.
• 36. AIDOUN Z., TERNAN M.: Salt impregnated carbon fibres as the reactive medium in a chemical heat pump: the NH3-CoCl2 system. Appl. Therm. Eng. 22(2002), 1163-1173.
• 37. AIDOUN Z., TERNAN M.: The synthesis reaction in a chemical heat pump reactor filled with chloride salt impregnated carbon fibres: NH3-CoCl2 system. Appl. Therm. Eng. 22(2002), 1943-1954.