Numerical investigation of a humidification-dehumidification desalination system driven by heat pump

•Numerical model of an HDH system driven by heat pump is built and validated.•Influences of critical parameters on system performance are numerically studied.•Estimation of GOR and unit fresh water cost shows competitive system performance.•Numerical correlation for system productivity is regressed...

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Bibliographic Details
Published in:Energy conversion and management 2019-01, Vol.180, p.641-653
Main Authors: Zhang, Yin, Zhang, Huan, Zheng, Wandong, You, Shijun, Wang, Yaran
Format: Article
Language:English
Subjects:
Air flow
Air temperature
Chemical analysis
Cost estimation
Dehumidification
Desalination
Flow rates
Flow velocity
Fresh water
Freshwater environments
Heat
Heat exchangers
Heat pump
Heat pumps
Humidification
Humidification-dehumidification
Mass balance
Mathematical model
Mathematical models
Numerical analysis
Parametric analysis
Plate heat exchangers
Productivity
Regression analysis
Seawater
Water analysis
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Summary:•Numerical model of an HDH system driven by heat pump is built and validated.•Influences of critical parameters on system performance are numerically studied.•Estimation of GOR and unit fresh water cost shows competitive system performance.•Numerical correlation for system productivity is regressed for further predictions. In this paper, a numerical investigation of a humidification-dehumidification (HDH) desalination system driven by heat pump is presented. The presented system consists of heat pump unit, plate heat exchanger, humidifier, first stage dehumidifier and second stage dehumidifier. A mathematical model based on the heat and mass balance equations of each component was built and verified by the experimental results. The effects of several important parameters of air and seawater into the system on system performance were numerically studied. The parametric analysis indicates that the air temperature has insignificant influence on the system yield, the increment of air humidity ratio or seawater flow rate is obviously beneficial for the productivity improvement and the productivity has different trends with increasing seawater temperature. It is also revealed that the productivity firstly increases and then decreases with the increment of air flow rate. Furthermore, gained output ratio (GOR) of the proposed system and the cost of fresh water are estimated. The average values of GOR and cost are 2.532 and 0.0412 USA dollar (USD) per kilogram respectively, which are competitive in comparison with other reported HDH systems. Additionally, a numerical correlation for the system productivity was regressed with an acceptable deviation.
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2018.11.018