Simulation of an adsorption refrigeration system with heat and mass recovery processes

doi:10.11949/j.issn.0438-1157.20161413

Abstract

Abstract:

Using heat and mass recovery processes is a common way to improve system performance in the field of adsorption refrigeration.In this paper, an adsorption refrigeration system with serial heat recovery and mass recovery-like processes has been numerical studied and its dynamic simulation was made.Mathematical models of main components (including the evaporator which works as reservoir)are built, based on the characteristics of heat transfer in three layers.Simulation results indicate that when cooling time increases, coefficient of performance (COP) monotonically increases but specific cooling power (SCP) monotonically decreases.When heat time increases, both COP and SCP increase first and then drop and the optimal heat recovery time is 10 s.Both COP and SCP reduce while mass recovery time enlarges, meaning that the mass recovery does not make any improvement on system performance.When temperatures of hot water and chilled water increase and temperature of cooling water decreases, both COP and SCP rise.The curves of SCP vs hot water temperature, COP vs cooling water temperature and SCP vs cooling water temperature are nearly linear.The curve of COP vs hot water temperature is quadric.

Key words: heat and mass recovery, adsorption, refrigeration, dynamic simulation, heat transfer in three layers, model

摘要：

吸附式制冷常采用回热回质循环来提升系统性能。研究了一种采用串联回热和类回质方式的回热回质循环吸附式制冷系统，并对其进行仿真。系统的主要部件（含作为储液器的蒸发器）采用3层换热法建立数学模型。仿真结果表明，随着制冷时间的延长，系统性能系数（COP）单调增大，单位质量制冷量（SCP）单调减小。随着回热时间的延长，COP和SCP是先增大后减小，最佳的回热时间为10 s。随着回质时间的延长，COP和SCP波动性下降，回质过程未提高系统性能。COP和SCP随着热水、冷冻水温度的升高以及冷却水温度的下降而增大。热水温度对SCP以及冷冻水、冷却水温度对COP和SCP的影响，呈现线性变化，而热水温度对COP的影响呈现二次变化。

关键词: 回热回质, 吸附, 制冷, 动态仿真, 3层换热, 模型

CLC Number:

TB61

PAN Quanwen, WANG Ruzhu. Simulation of an adsorption refrigeration system with heat and mass recovery processes[J]. CIESC Journal, 2016, 67(S2): 262-268.

潘权稳, 王如竹. 一种回热回质循环吸附式制冷系统的仿真[J]. 化工学报, 2016, 67(S2): 262-268.

References 20

[1]	WANG R Z,OLIVEIRA R G.Adsorption refrigeration-an efficient way to make good use of waste heat and solar energy[J]. Prog.Energ.Combust,2006,32(4):424-458.
[2]	齐朝晖,汤广发,李定宇,等.基于余热回收的三效冷环吸附式制冷系统的系统分析和试验研究[J]. 流体机械,2002,30(5):4. QI C H,TANG G F,LI D Y,et al.System analysis and experimental research of a tri-couple cycle adsorption refrigeration for waste heat recovery[J]. Fluid Machinery,2002,30(5):4.
[3]	WANG R Z,WU J Y,XU Y X,et al. Experiment on a continuous heat regenerative adsorption refrigerator using spiral plate heat exchanger as adsorbers[J]. Appl.Therm.Eng.,1998,18(1/2):13-23.
[4]	TCHERNEV D I,EMERSON D T.High-efficiency regenerative zeolite heat pump[J]. ASHRAE Trans.,1988,94(2):2024-2032.
[5]	QU T F,WANG R Z,WANG W.Study on heat and mass recovery in adsorption refrigeration cycles[J]. Appl. Therm.Eng.,2001,21(4):439-452.
[6]	WANG R Z.Performance improvement of adsorption cooling by heat and mass recovery operation[J]. Int.J.Refrig.,2001,24(7):602-611.
[7]	AKAHIRA A,ALAM K C A,HAMAMOTO Y,et al. Mass recovery adsorption refrigeration cycle-improving cooling capacity[J]. Int.J.Refrig.,2004,27(3):225-234.
[8]	LIU Y L,WANG R Z,XIA Z Z.Experimental performance of a silica gel-water adsorption chiller[J]. Appl. Therm.Eng.,2005,25(2/3):359-375.
[9]	NG K C,WANG X,LIM Y S,et al.Experimental study on performance improvement of a four-bed adsorption chiller by using heat and mass recovery[J]. Int.J.Heat Mass.Tran.,2006,49(19/20):3343-3348.
[10]	ALAM K C A,KHAN M Z I,UYUN A S,et al. Experimental study of a low temperature heat driven re-heat two-stage adsorption chiller[J]. Appl.Therm.Eng.,2007,27(10):1686-1692.
[11]	CHANG W S,WANG C C,SHIEH C C.Design and performance of a solar-powered heating and cooling system using silica gel/water adsorption chiller[J]. Appl. Therm.Eng.,2009,29(10):2100-2105.
[12]	CHEN C J,WANG R Z,XIA Z Z,et al.Study on a compact silica gel-water adsorption chiller without vacuum valves:design and experimental study[J]. Appl.Energ.,2010,87(8):2673-2681.
[13]	LU Z S,WANG R Z.Study of the new composite adsorbent of salt LiCl/silica gel-methanol used in an innovative adsorption cooling machine driven by low temperature heat source[J]. Renew.Energ.,2014,63:445-451.
[14]	WIRAJATI I G A B,AKISAWA A,UEDA Y,et al. Experimental investigation of a reheating two-stage adsorption chiller applying fixed chilled water outlet conditions[J]. Heat Transf.Res.,2015,46(3):293-309.
[15]	李廷贤,王如竹,王丽伟,等.基于多功能热管的高效吸附式制冰机组回质回热实验研究[J]. 化工学报,2007,58(05):1104-1109. LI T X,WANG R Z,WANG L W,et al.Experimental study on mass and heat recovery of a highly efficient multi-function heat pipe type adsorption ice making system[J]. Journal of Chemical Industry and Engineering (China),2007,58(5):1104-1109.
[16]	PAN Q W,WANG R Z,WANG L W.Comparison of different kinds of heat recoveries applied in adsorption refrigeration system[J]. Int.J.Refrig.,2015,55:37-48.
[17]	SAKODA A,SUZUKI M.Fundamental study on solar powered adsorption cooling system[J]. J.Chem.Eng.Jpn.,1984,17(1):52-57.
[18]	SAHA B B,BOELMAN E C,KASHIWAGI T.Computer simulation of a silica gel-water adsorption refrigeration cycle-the influence of operating conditions on cooling output and COP[J]. ASHRAE Trans.,1995,101(2):348-357.
[19]	王德昌.硅胶-水吸附式制冷机研制与吸附式制冷变热源特性研究[D]. 上海:上海交通大学,2005. WANG D C.Development of a silica gel-water adsorption chiller and study of the characteristics of adsorption system driven by variable heat source[D]. Shanghai:Shanghai Jiao Tong University,2005.
[20]	PAN Q W,WANG R Z,WANG L W,et al.Design and experimental study of a silica gel-water adsorption chiller with modular adsorbers[J]. Int.J.Refrig.,2016,67:336-344.