Refrigerant desorption characteristics in solid adsorption refrigeration system

doi:10.11949/j.issn.0438-1157.20160843

Abstract

Abstract:

A single-bed adsorption refrigeration experimental system with the working-pair of activated carbon-methyl alcohol was built.And investigations on the effect of desorption temperature and desorption time on the desorption amount of refrigerant in cylindrical adsorption tube were conducted.The desorption temperature was set at 84, 89 and 94℃, and the desorption was last for 4, 5, 6 and 7 h, respectively.The experimental results indicate that desorption temperature, desorption time and the desorption amount of refrigerant had significant effect on the refrigeration recycling performance of the adsorption refrigeration system.The minimum coefficient of performance(COP) of 0.053 was achieved when the heating resource temperature was maintained at 84℃ and the heating time was 4 h.The maximum COP of 0.19 was achieved when the desorption temperature was maintained at 94℃ and desorption time was 6 h.Consequently, 94℃ and 6 h were recommended as the optimal desorption temperature and desorption time.If the desorption time was continuously increased to be more than 6 h, the increasing rate of desorption amount would be less than that of energy consumption, then COP will consequently decrease.

Key words: adsorption refrigeration, activated carbon-methyl alcohol, desorption amount, COP, adsorption, desorption

摘要：

搭建了以活性炭-甲醇为工质对的单床吸附式制冷实验系统，对圆柱形吸附管内的吸附剂在不同解吸温度和不同解吸时间条件下的解吸量进行实验研究。解吸温度分别为84、89、94℃，解吸时间分别为4、5、6、7 h。实验结果表明，解吸温度、解吸时间和制冷剂的解吸量对吸附式制冷系统制冷循环性能有着重要影响。在热源温度为84℃加热时间4 h时，系统的制冷性能系数COP最小为0.053。系统在解吸温度为94℃，解吸时间为6 h时，系统的制冷性能系数COP最大为0.19，此时的解吸温度和解吸时间为最佳解吸温度和解吸时间。继续增加解吸时间，解吸量的增长率小于耗能的增长率，COP减小。

关键词: 吸附式制冷, 活性炭-甲醇, 解吸量, COP, 吸附, 解吸

CLC Number:

TK511⁺.3

LIU Jiaxing, JI Xu, LI Ming, LI Haili, FAN Rongkang, XU Qiangqiang. Refrigerant desorption characteristics in solid adsorption refrigeration system[J]. CIESC Journal, 2017, 68(1): 336-344.

刘佳星, 季旭, 李明, 李海丽, 范荣康, 许强强. 固体吸附式制冷系统制冷剂的解吸特性[J]. 化工学报, 2017, 68(1): 336-344.

References 27

[1]	WANG D C, ZHANG J P, YANG Q R, et al. Study of adsorption characteristics in silica gel-water adsorption refrigeration[J]. Applied Energy, 2014, 113:734-741.
[2]	CHOUDHURY B, SAHA B B, CHATTERJEE P K, et al. An overview of developments in adsorption refrigeration systems towards a sustainable way of cooling[J]. Applied Energy, 2013, 104:554-567.
[3]	KARAMANIS D, VARDOULAKIS E. Application of zeolitic materials prepared from fly ash to water vapor adsorption for solar cooling[J]. Applied Energy, 2012, 97:334-339.
[4]	VOYIATZIS E, PALYVOS J A, MARKATOS N C, et al. Heat-exchanger design and switching-frequency effects on the performance of a continuous type solar adsorption chiller[J]. Applied Energy, 2008, 85:1237-1250.
[5]	MWUNIER F. Solid sorption heat powered cycles for cooling and heat pumping applications[J]. Applied Thermal Energy, 1998, 18:715-729.
[6]	AMIR S, MAJID B. Assessment of adsorber bed designs in waste heat driven adsorption cooling systems for vehicle air conditioning and refrigeration[J]. Renewable and Sustainable Energy Reviews, 2014, 30:440-451.
[7]	WANG R Z, LI M, XU Y X, et al. An energy efficient hybrid system of solar powered water heater and adsorption ice maker[J]. Solar Energy, 2000, 68(2):189-195.
[8]	JU X, LI M, FAN J Q, et al. Structure optimization and performance experiments of a solar-powered finned-tube adsorption refrigeration system[J]. Applied Energy, 2014, 113:1293-1300.
[9]	WANG L W, METCALF S J, CRITOPH R E, et al. Development of thermal conductive consolidated activated carbon for adsorption refrigeration[J]. Carbon, 2012, 50:977-986.
[10]	HEADLEY O S, KOTHDIWALA A F, MCDOOM I A, et al. Charcoal-methanol adsorption refrigerator powered by a compound parabolic concentrating solar collector[J]. Solar Energy, 1994, 53:191-197.
[11]	SUMATHY K, LI Z F. Experiments with solar-powered adsorption icemaker[J]. Renewable Energy, 1998, 16:704-707.
[12]	LI Z F, SUMATHY K. A solar powered ice-maker with the solid adsorption pair of activated carbon and methanol[J]. International Journal of Energy Research, 1999, 23:517-527.
[13]	BOUBAKRI A. A new conception of an adsorptive solar-powered ice maker[J]. Renewable Energy, 2003, 28:831-842.
[14]	HILDBRAND C, DIND P, PONS M, et al. A new solar powered adsorption refrigerator with high performance[J]. Solar Energy, 2004, 77(3):311-318.
[15]	FADAR A E, MIMET A, PÉREZ-GARCÍA M, et al. Modelling and performance study of a continuous adsorption refrigeration system driven by parabolic trough solar collector[J]. Solar Energy, 2009, 83:850-861.
[16]	HONG S W, AHN S H, KWON O K, et al. Optimization of a fin-tube type adsorption chiller by design of experiment[J]. International Journal of Refrigeration, 2015, 49:49-56.
[17]	MITSUHIRO K, TAKESHI U, RYO F, et al. Cooling output performance of a prototype adsorption heat pump with fin-type silica gel tube module[J]. Applied Thermal Engineering, 2008, 28:87-93.
[18]	LI M, WANG R Z, XU Y X, et al. Experimental study on dynamic performance analysis of a flat-plate solar solid-adsorption refrigeration for ice maker[J]. Renewable Energy, 2002, 27:211-221.
[19]	LI T X, WANG R Z, WANG L W, et al. Study on the heat transfer and sorption characteristics of a consolidated composite sorbent for solar-powered thermos chemical cooling systems[J]. Solar Energy, 2009, 83:1742-1755.
[20]	KHATTAB N M. A novel solar-powered adsorption refrigeration module[J]. Applied Thermal Engineering, 2004, 24:2747-2760.
[21]	KIPLAGAT J K, WANG R Z, OLIVEIRA R G, et al. Lithium chloride-expanded graphite composite sorbent for solar powered ice maker[J]. Solar Energy, 2010, 84:1587-1594.
[22]	WANG R Z, XU Y X, WU J Y, et al. Research on a combined adsorption heating and cooling system[J]. Applied Thermal Engineering, 2002, 22:603-617.
[23]	WANG J, WANG L W, LUO W L, et al. Experimental study of a two-stage adsorption freezing machine driven by low temperature heat source[J]. International Journal of Refrigeration, 2013, 36:1029-1036.
[24]	KHATTAB N M. Simulation and optimization of a novel solar-powered adsorption refrigeration module[J]. Solar Energy, 2006, 80:823-833.
[25]	KHAIRUL H, BIDYUT S B, ANUTOSH C, et al. Performance evaluation of combined adsorption refrigeration cycles[J]. International Journal of Refrigeration, 2011, 34:129-137.
[26]	SONG X B, JI X, LI M, et al. Effect of desorption parameters on performance of solar water-bath solid adsorption ice-making system[J]. Applied Thermal Engineering, 2015, 89:316-322.
[27]	TMAINOT-TELTO Z, CRITOPH R E. Adsorption refrigerator using monolithic carbon-ammonia pair[J]. International Journal of Refrigeration, 1997, 20(2):146-155.