Experimental investigation of absorption in upward and downward flow of NH3-CO2-H2O in a mini-channel heat exchanger

•NH3-CO2-H2O shows an increase in heat transfer of up to 5% compared to NH3- H2O.•The mixture should be on the tube side of mini-channel heat exchangers.•Vertical absorption in downward flow is significantly better than absorption in upward flow.•For NH3-CO2-H2O the absorber should be designed to pr...

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Published inInternational journal of heat and mass transfer Vol. 152; p. 119483
Main Authors Gudjonsdottir, V., Shi, L., Infante Ferreira, C.A.
Format Journal Article
LanguageEnglish
Published Oxford Elsevier Ltd 01.05.2020
Elsevier BV
Subjects
Absorption
Ammonia
Carbon dioxide
Configurations
Energy requirements
Heat exchangers
Heat pumps
Heat pumps NH3-CO2-H2O NH3-H2O absorption mini-channel heat exchanger
Heat transfer
Heat transfer coefficients
Mass flow
Pumping
Tubes
PHX
CHX
LMTD
CRHPs
MCGP
Heat pumps NH3-CO2-H2O NH3-H2O absorption mini-channel heat exchanger
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Summary:•NH3-CO2-H2O shows an increase in heat transfer of up to 5% compared to NH3- H2O.•The mixture should be on the tube side of mini-channel heat exchangers.•Vertical absorption in downward flow is significantly better than absorption in upward flow.•For NH3-CO2-H2O the absorber should be designed to prevent accumulation of CO2. Heat pumps can drastically reduce energy requirements in industry. Operating a compression resorption heat pump with an NH3-CO2-H2O mixture has been identified as a promising option that can have an increased performance compared to only NH3-H2O. In this paper an important process of the heat pump cycle is investigated: The absorption process. A mini-channel heat exchanger with 116 tubes of inside diameter of 0.5 mm is used for this purpose. For the NH3-H2O experiments overall heat transfer coefficients of 2.7–6 kW/(m2K) were reached for mixture mass flows of 0.71–2.5 kg/h. For the NH3-CO2-H2O mixture pumping instabilities limited the operating range which resulted in higher pressures and higher mixture mass flows compared to NH3-H2O. The overall heat transfer coefficients were lower in the case of the added CO2, with the maximum of 3 kW/(m2K) corresponding to a mixture mass flow of 4.2 kg/h. However, an increase in heat transfer of approximately 5% was reached with the added CO2 which is beneficial for heat pump applications. Additionally, limited research has been conducted on absorption in upward versus downward flow and, therefore, these two configurations have also been tested in the mini-channel heat exchanger. Even though the pumping instabilities vanished with absorption in upward flow it was confirmed that absorption in downward flow with the mixture on the tube side is the most beneficial configuration for absorption of ammonia in NH3-CO2-H2O or NH3-H2O in a mini-channel heat exchanger. The performance increased by approximately 10% with absorption in downward flow.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2020.119483