Effects of a Nonabsorbable Gas on Interfacial Heat and Mass Transfer for the Entrance Region of a Falling Film Absorber-Reference-Cited by-同舟云学术

Effects of a Nonabsorbable Gas on Interfacial Heat and Mass Transfer for the Entrance Region of a Falling Film Absorber

Published:1996-02-01 Issue:1 Volume:118 Page:45-49
ISSN:0199-6231
Container-title:Journal of Solar Energy Engineering
language:en
Short-container-title:

Author:

Ameel T. A.¹,Habib H. M.²,Wood B. D.³

Affiliation:

1. Department of Mechanical and Industrial Engineering, Lousiana Tech University, Ruston, LA 71272

2. El-Menoufia University, Shebin, El-Kom, Egypt

3. Mechanical and Aerospace Engineering, Center for Energy Systems Research, College of Engineering and Applied Sciences, Arizona State University, Tempe, AZ 85287-5806

Abstract

An analytical solution is presented for the effect of air (nonabsorbable gas) on the heat and mass transfer rates during the absorption of water vapor (absorbate) by a falling laminar film of aqueous lithium bromide (absorbent), an important process in a proposed open-cycle solar absorption cooling system. The analysis was restricted to the entrance region where an analytical solution is possible. The model consists of a falling film of aqueous lithium bromide flowing down a vertical wall which is kept at uniform temperature. The liquid film is in contact with a gas consisting of a mixture of water vapor and air. The gas phase is moving under the influence of the drag from the falling liquid film. The governing equations are written with a set of interfacial and boundary conditions and solved analytically for the two phases. Heat and mass transfer results are presented for a range of uniform inlet air concentrations. It was found that the concentration of the nonabsorbable gas increases sharply at the liquid gas interface. The absorption of the absorbate in the entrance region showed a continuous reduction with an increase in the amount of air.

Publisher

ASME International

Subject

Energy Engineering and Power Technology,Renewable Energy, Sustainability and the Environment

Link

http://asmedigitalcollection.asme.org/solarenergyengineering/article-pdf/118/1/45/5711891/45_1.pdf

Reference8 articles.

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2. Collier R. K. , 1979, “The Analysis and Simulation of an Open Cycle Absorption Refrigeration System,” Solar Energy, Vol. 23, pp. 357–366.

3. Grossman, G., 1987, “Simulation and Analysis of High Efficiency Absorption System for Solar Cooling: Part IV Film Absorption Heat and Mass Transfer in the Presence of the Non-Condensables,” Final Report for DOE Contract, DEAC03- 85SF15894, Technion-Israel Institute of Technology.

4. Haselden G. G. , and MalatyS. A., 1959, “Heat and Mass Transfer Accompanying the Absorption of Ammonia in Water,” Trans. Inst. Chem. Engrs., Vol. 37, p. 137137.

5. Kakabaev A. , and KhandurdyevA., 1969, “Absorption Solar Refrigeration Unit with Open Regeneration of Solution,” Geliotekhnika, Vol. 5, No. 4, pp. 69–72.

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