Experiment verified simulation study of the operating sequences on the performance of adsorption cooling system

Ka Chung Chan; Chi Yan Tso; Christopher Y.H. Chao; Chi Li Wu

doi:10.1007/s12273-015-0218-7

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Research Article

Experiment verified simulation study of the operating sequences on the performance of adsorption cooling system

Ka Chung Chan^¹, Chi Yan Tso^¹, Christopher Y.H. Chao^¹(

), Chi Li Wu^{²^,³}

1Department of Mechanical and Aerospace Engineering, The Hong Kong University of Science and Technology (HKUST), Hong Kong, China

2Fok Ying Tung Graduate School, The Hong Kong University of Science and Technology (HKUST), Hong Kong, China

3Guangzhou HKUST Fok Ying Tung Research Institute, Guangzhou 511485, China

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Abstract

In this study, simulation was conducted to investigate the effect of heat recovery, mass recovery, pre-heating and pre-cooling processes and their combinations on the system performance of a double-bed adsorption cooling system. The model developed consists of pressure variations and detailed compressible flow with flow resistance, which other similar studies had not taken into consideration, thus a detailed simulation of mass recovery, and pre-heating and pre-cooling processes is included in this study. A double-bed adsorption cooling system with silica gel and water as adsorbent-adsorbate pair was built for verifying the simulation models. Based on the simulation results, it was found that the basic cycle provided a COP and SCP of 0.20 and 57.6 W/kg, respectively. By conducting heat recovery for 30 seconds, the COP was increased by 20% to 0.24 compared to the basic cycle. The SCP was also increased to 66.4 W/kg, a 15% increase. The major advantage through conducting the mass recovery is in the SCP, whereby it was increased by 40% to 80.8W/kg. Additionally, performing only the pre-heating and pre-cooling process can also bring some benefits to the system. Therefore, for adsorption cooling systems that cannot carry out the mass recovery and/or heat recovery cycles, performing pre-heating and pre-cooling process only is recommended. This not only can reduce the cost, but also simplify the control program of the systems. Moreover, mass recovery followed by pre-heating and pre-cooling cycle is highly preferred when the SCP is the optimization target, since the SCP was hugely increased by 41% to 81.4 W/kg.

Keywords

simulation adsorption cooling system heat and mass recovery operation sequence

References

A Akahira, KCA Alam, Y Hamamoto, A Akisawa, T Kashiwagi (2004). Mass recovery adsorption refrigeration cycle-improving cooling capacity. International Journal of Refrigeration, 27: 225-234.

Crossref Google Scholar

A Akahira, KCA Alam, Y Hamamoto, A Akisawa, T Kashiwagi (2005). Experimental investigation of mass recovery adsorption refrigeration cycle. International Journal of Refrigeration, 28: 565-572.

Crossref Google Scholar

KC Chan, CYH Chao, GN Sze-To, KS Hui (2012). Performance predictions for a new zeolite 13X/CaCl2 composite adsorbent for adsorption cooling systems. International Journal of Heat and Mass Transfer, 55: 3214-3224.

Crossref Google Scholar

HT Chua, KC Ng, A Malek, T Kashiwagi, A Akisawa, BB Saha (1999). Modeling the performance of two-bed, sillica gel-water adsorption chillers. International Journal of Refrigeration, 22: 194-204.

Crossref Google Scholar

HT Chua, KC Ng, W Wang, C Yap, XL Wang (2004). Transient modeling of a two-bed silica gel-water adsorption chiller. International Journal of Heat and Mass Transfer, 47: 659-669.

Crossref Google Scholar

JA Dean, NA Lange (1999). Lange's Handbook of Chemistry. New York: McGraw-Hill.

KC Leong, Y Liu (2004). Numerical modeling of combined heat and mass transfer in the adsorbent bed of a zeolite/water cooling system. Applied Thermal Engineering, 24: 2359-2374.

Crossref Google Scholar

KC Leong, Y Liu (2006). System performance of a combined heat and mass recovery adsorption cooling cycle: A parametric study. International Journal of Heat and Mass Transfer, 49: 2703-2711.

Crossref Google Scholar

YL Liu, RZ Wang, ZZ Xia (2005). Experimental study on a continuous adsorption water chiller with novel design. International Journal of Refrigeration, 28: 218-230.

Crossref Google Scholar

G Maggio, A Freni, G Restuccia (2006). A dynamic model of heat and mass transfer in a double-bed adsorption machine with internal heat recovery. International Journal of Refrigeration, 29: 589-600.

Crossref Google Scholar

BR Munson, DF Young, TH Okiishi (2006). Fundamentals of Fluid Mechanics, 5th edn. New York: John Wiley & Sons.

KC Ng, X Wang, YS Lim, BB Saha, A Chakarborty, S Koyama, A Akisawac, T Kashiwagi (2006). Experimental study on performance improvement of a four-bed adsorption chiller by using heat and mass recovery. International Journal of Heat and Mass Transfer, 49: 3343-3348.

Crossref Google Scholar

M Pons (1997). Analysis of the adsorption cycles with thermal regeneration based on the entropic mean temperatures. Applied Thermal Engineering, 17: 615-627.

Crossref Google Scholar

TF Qu, RZ Wang, W Wang (2001). Study on heat and mass recovery in adsorption refrigeration cycles. Applied Thermal Engineering, 21: 439-452.

Crossref Google Scholar

BB Saha, S Koyama, T Kashiwagi, A Akisawa, KC Ng, HT Chua (2003). Waste heat driven dual-mode, multi-stage, multi-bed regenerative adsorption system. International Journal of Refrigeration, 26: 749-757.

Crossref Google Scholar

A Sakoda, M Suzuki (1984). Fundamental study on solar powered adsorption cooling system. Journal of Chemical Engineering of Japan, 17: 52-57.

Crossref Google Scholar

CY Tso, CYH Chao (2012). Activated carbon, silica-gel and calcium chloride composite adsorbents for energy efficient solar adsorption cooling and dehumidification systems. International Journal of Refrigeration, 35: 1626-1638.

Crossref Google Scholar

CY Tso, CYH Chao, SC Fu (2012). Performance analysis of a waste heat driven activated carbon based composite adsorbent-water adsorption chiller using simulation model. International Journal of Heat and Mass Transfer, 55: 7596-7610.

Crossref Google Scholar

CY Tso, SC Fu, CYH Chao (2014). Modeling a solar-powered double bed novel composite adsorbent (silica activated carbon/CaCl2)-water adsorption chiller. Building Simulation, 7: 185-196.

Crossref Google Scholar

DC Wang, ZZ Xia, JY Wu, RZ Wang, H Zhai, WD Dou (2005a). Study of a novel silica gel-water adsorption chiller. Part I. Design and performance prediction. International Journal of Refrigeration, 28: 1073-1083.

Crossref Google Scholar

RZ Wang (2001). Performance improvement of adsorption cooling by heat and mass recovery operation. International Journal of Refrigeration, 24: 602-611.

Crossref Google Scholar

X Wang, HT Chua, KC Ng (2005b). Experimental investigation of silica gel-water adsorption chillers with and without a passive heat recovery scheme. International Journal of Refrigeration, 28: 756-765.

Crossref Google Scholar

X Wang, KC Ng, A Chakarborty, BB Saha (2007). How heat and mass recovery strategies impact the performance of adsorption desalination plant: theory and experiments. Heat Transfer Engineering, 28: 147-153.

Crossref Google Scholar

LZ Zhang, L Wang (1997). Performance estimation of an adsorption cooling system for automobile waste heat recovery. Applied Thermal Engineering, 17: 1127-1139.

Crossref Google Scholar

LZ Zhang (2000). A three-dimensional non-equilibrium model for an intermittent adsorption cooling system. Solar Energy, 69: 27-35.

Crossref Google Scholar

Building Simulation

Volume 8 Issue 3,
June 2015

Pages 255-269

DOI: 10.1007/s12273-015-0218-7

Cite this article:

Chan KC, Tso CY, Chao CY, et al. Experiment verified simulation study of the operating sequences on the performance of adsorption cooling system. Building Simulation, 2015, 8(3): 255-269. https://doi.org/10.1007/s12273-015-0218-7

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Received: 10 November 2014

Revised: 06 January 2015

Accepted: 16 February 2015

Published: 17 March 2015