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contributor authorR. Yang
contributor authorP.-L. Wang
date accessioned2017-05-08T23:57:42Z
date available2017-05-08T23:57:42Z
date copyrightNovember, 1998
date issued1998
identifier issn0199-6231
identifier otherJSEEDO-28280#253_1.pdf
identifier urihttp://yetl.yabesh.ir/yetl/handle/yetl/121065
description abstractExperimental study of a double-glazed forced-convection solar collector/regenerator for absorption solar cooling is presented. The south facing experimental solar collector/ regenerator with 10 deg slope is located at Kaohsiung, Taiwan at 120°18′ E longitude and 22°34′ N latitude. The size of the collector is 1 m wide and 7 m long with an effective regeneration area of 0.9 m by 6 m. Previous study for single-glazed forced-convection solar collector/regenerator operated at the same location has shown to have a best day-average efficiency of 17 percent. In order to raise the system performance, a double-glazed collector/regenerator is constructed such that air can be preheated in the upper channel flow. The preheated air is then conducted into the lower channel where it contacts with the film flow of solar heated lithium-chloride solution and regenerates the solution by carrying out the evaporated water vapor. The preheated air has lower relative humidity but the same humidity ratio since it is sensibly heated. Therefore, the regeneration driving potential is increased. The present study shows that the best day-average efficiency can reach 20 percent which increases the feasibility of the open-cycle absorption solar cooling system. Effects of controlling parameters on the collector/regenerator performance are studied, and heat and mass transfer correlations are also presented for design purposes.
publisherThe American Society of Mechanical Engineers (ASME)
titleExperimental Study for a Double-Glazed Forced-Flow Solar Collector/Regenerator
typeJournal Paper
journal volume120
journal issue4
journal titleJournal of Solar Energy Engineering
identifier doi10.1115/1.2888128
journal fristpage253
journal lastpage259
identifier eissn1528-8986
keywordsFlow (Dynamics)
keywordsSolar collectors
keywordsSolar energy
keywordsForced convection
keywordsAbsorption
keywordsFoundry coatings
keywordsChannel flow
keywordsDesign
keywordsHeat
keywordsWater vapor
keywordsMass transfer
keywordsCooling
keywordsChannels (Hydraulic engineering)
keywordsCooling systems
keywordsCycles
keywordsFilm flow AND Lithium
treeJournal of Solar Energy Engineering:;1998:;volume( 120 ):;issue: 004
contenttypeFulltext


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