Experimental analysis of an adsorption refrigerator with mass and heat-pipe heat recovery process

Energy Conversion and Management

Volumn 53, Issue 1, 2012, Pages 291-297

  Lu, Z S ^a   Wang, L W ^a   Wang, R Z ^a  

^a SHANGHAI JIAO TONG UNIVERSITY   (China)

Author keywords

Combined mass heat recovery; Heat pipe type; Orifice sets; Refrigerator; Solid sorption

Indexed keywords

ADSORPTION PERFORMANCE; ADSORPTION REFRIGERATION SYSTEM; ADSORPTION REFRIGERATOR; AMMONIA ADSORPTION; COEFFICIENT OF PERFORMANCE; COMBINED MASS-HEAT RECOVERY; COMPOUND ADSORBENT; CYCLE TIME; DIFFERENT MASS; EXPERIMENTAL ANALYSIS; EXPERIMENTAL DATA; EXPERIMENTAL PROTOTYPE; HEAT PIPE TYPE ADSORPTION; MASS RECOVERY; OPERATING CONDITION; RECOVERY PROCESS; SOLID SORPTION; SPECIFIC COOLING POWER; THERMOSTATIC EXPANSION VALVES;

ACTIVATED CARBON; ADSORBENTS; CALCIUM CHLORIDE; ENERGY CONVERSION; GAS ADSORPTION; HEAT PIPES; ORIFICES; PHASE CHANGE MATERIALS; RECOVERY; REFRIGERATION; REFRIGERATORS; SOLAR ENERGY; SORPTION; WASTE HEAT;

WASTE HEAT UTILIZATION;

EID: 80053504889     PISSN: 01968904     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.enconman.2011.09.009     Document Type: Article

References (37)

1. B.B. Saha, S. Koyama, T. Kashiwagi, A. Akisawa, K.C. Ng, and H.T. Chua Waste heat driven dual-mode multi-stage multi-bed regenerative adsorption system Int J Refrig 26 7 2003 749 757
2. B.B. Saha, I.I. Sharkawy, S. Koyama, J.B. Lee, and K. Kuwahara Waste heat driven multi-bed adsorption chiller: heat exchangers overall thermal conductance on chiller performance Heat Transfer Eng 28 5 2006 80 87
3. R.Z. Wang, J.Y. Wu, Y.J. Dai, Z.S. Jiang, and W. Wang Adsorption refrigeration (in Chinese) 2002 China Machine Press p. 1-3
4. W. Wang, T.F. Qu, and R.Z. Wang Influence of degree of mass recovery and heat regeneration on adsorption refrigeration cycles Energy Convers Manage 43 2002 733 741 (Pubitemid 34040851)
5. R.E. Critoph Forced convection adsorption cycles Appl Therm Eng 18 1998 799 807 (Pubitemid 128674602)
6. S. Szarzynski, Y. Feng, and M. Pons Study of different internal vapor transports for adsorption cycles with heat regeneration Int J Refrig 20 6 1997 390 401 (Pubitemid 127402500)
7. N. Douss, and F. Meunier Experimental study of cascading adsorbing cycle Chem Eng Sci 44 1989 225 235
8. Z.C. Tan, and R.Z. Wang Investigation on double effect hybrid cycle of adsorption refrigeration J Sol Energy 2 1998 156 160
9. M. Pons, and F. Poyelle Adsorptive machines with advanced cycles for heat pumping or cooling applications Int J Refrig 22 1999 27 37
10. Miles DJ. Analysis and design of a solid adsorption heat driven heat pump. PhD Thesis: Georgia Institute of Technology; 1989.
11. Poyelle F, Guilleminot JJ, Meunier F. Experimental test of a gas fired adsorptive air conditioning system. in: International absorption heat pump conference, Montreal; 1996. p. 221-229.
12. L.L. Vasiliev, L.E. Kanonchik, A.A. Antukh, A.G. Kulakov, and V.K. Kulikovsky Waste heat driven solid sorption coolers containing heat pipes for thermo control Adsorption 1 1995 303 312
13. Z.S. Lu, R.Z. Wang, L.W. Wang, and C.J. Chen Performance analysis of an adsorption refrigerator using activated carbon in a compound adsorbent Carbon 44 2006 747 752 (Pubitemid 41821850)
14. L.W. Wang, R.Z. Wang, Z.S. Lu, Y.X. Xu, and J.Y. Wu Split heat pipe type compound adsorption ice making unit for fishing boats Int J Refrig 29 3 2006 456 468
15. Wu JY. Performance analysis and experiments on a heat regenerative adsorption air condition/heat pump. PhD Thesis: Shanghai Jiao Tong University; 2000.
16. K. Abraham, M.P. Maiya, and M.S. Srinivasa Performance analysis of a single stage four bed metal hydride cooling system, part A: influence of mass recovery Int J Therm Sci 42 2003 71 77 (Pubitemid 36153429)
17. K. Abraham, M.P. Maiya, and M.S. Srinivasa Performance analysis of a single stage four bed metal hydride cooling system, part B: influence of heat recovery Int J Therm Sci 42 2003 79 84 (Pubitemid 36153430)
18. T.F. Qu, R.Z. Wang, and W. Wang Study on heat and mass recovery in adsorption refrigeration cycles Appl Therm Eng 21 2001 439 452 (Pubitemid 32071571)
19. R.Z. Wang Performance improvement of adsorption cooling by heat and mass recovery operation Int J Refrig 24 2001 602 611 (Pubitemid 32780349)
20. M. Pons, and Y. Feng Characteristic parameters of adsorptive refrigeration cycles with thermal regeneration Appl Therm Eng 17 3 1997 289 298 (Pubitemid 127421844)
21. Zanife T, Meunier F, Chalfen JB. Adsorptive refrigeration (activated carbon-methanol): mass recovery cycle. in: International congress of refrigeration, August; 1991. p. 1041-1046.
22. Y. Hamamotoa, K.C.A. Alamb, A. Akisawab, and T. Kashiwagi Performance evaluation of a two-stage adsorption refrigeration cycle with different mass ratio Int J Refrig 28 2005 344 352 (Pubitemid 40245974)
23. K. Abraham, M.P. Maiya, and S.S. Murthy Performance analysis of a single stage four bed metal hydride cooling system, part C: influence of combined heat and mass recovery Int J Therm Sci 42 2003 1021 1027 (Pubitemid 37244357)
24. H.T. Chua, K.C. Ng, and A. Malek Modeling the performance of two-bed, silica gel-water adsorption chillers Int J Refrig 22 1999 194 204
25. X. Wang, and K.C. Ng Experimental investigation of an adsorption desalination plant using low-temperature waste heat Appl Therm Eng 25 17-18 2005 2780 2789 (Pubitemid 41162493)
26. H.T. Chua, K.C. Ng, and W. Wang Transient modeling of a two-bed silica gel-water adsorption chiller Int J Heat Mass Transfer 47 2004 659 669 (Pubitemid 37396188)
27. X. Wang, and H.T. Chua Two bed silica gel-water adsorption chillers: an effectual lumped parameter model Int J Refrig 30 8 2007 1417 1426 (Pubitemid 350184131)
28. X. Wang, and H.T. Chua A comparative evaluation of different heat-recovery schemes as applied to a two-bed adsorption chiller Int J Heat Mass Transfer 50 2007 433 443 (Pubitemid 44881033)
29. K.C. Ng, X. Wang, and Y.S. Lin Experimental study of performance improvement of a four-bed adsorption chiller by using heat-and-mass recovery Int J Heat Mass Transfer 49 19-20 2006 3343 3348 (Pubitemid 43946927)
30. X. Wang, H.T. Chua, and K.C. Ng Experimental investigation of a multi-bed adsorption chiller with a passive heat recovery system Int J Refrig 28 5 2005 756 765 (Pubitemid 40774082)
31. 2 and expanded graphite Energy Convers Manage 52 2011 1501 1506
32. C.J. Chen, R.Z. Wang, and L.W. Wang Studies on cycle characteristics and application of split heat pipe adsorption ice maker Energy Convers Manage 48 2007 1106 1112 (Pubitemid 46283132)
33. L.X. Gong, R.Z. Wang, and Z.Z. Xia Design and performance prediction of a new generation adsorption chiller using composite adsorbent Energy Convers Manage 52 6 2011 2345 2350
34. G.Z. Yang, Z.Z. Xia, and R.Z. Wang Research on a compact adsorption room air conditioner Energy Convers Manage 47 2006 2167 2177
35. Y.Z. Lu, R.Z. Wang, and M.S. Zhang Adsorption cold storage system with zeolite-water working pair used for locomotive air conditioning Energy Convers Manage 44 2003 1733 1743
36. J.Y. Wu, R.Z. Wang, and Y.X. Xu Dynamic analysis of heat recovery process for a continuous heat recovery adsorption heat pump Energy Convers Manage 43 2002 2201 2211 (Pubitemid 34732265)
37. D.C. Wang, and J.Y. Wu Influence of intermittent heat source on adsorption ice maker using waste heat Energy Convers Manage 46 2005 985 998