Energy Equipment and Systems

Energy Equipment and Systems

Investigating the effect of diamond-shape turbulator in optimal design of flat plate solar collector

Document Type : Research Paper

Authors
Mohammad Shafiey Dehaj 1
Hassan Hajabdollahi 1
Farzaneh Hajabdollahi 2
1 Department of Mechanical Engineering, Vali-e-Asr University of Rafsanjan, Rafsanjan, Iran
2 Department of Mechanical Engineering, University of Colorado Denver, 1200 Larimer street, Colorado, 80217, U.S.A
10.22059/ees.2024.2037664.1476
Abstract
Operation of flat plate solar collector (FPSC) at the optimal point with maximum efficiency is very significant. Therefore, the optimum design of FPSC considering a diamond-shape turbulator (DST) is investigated. Six design parameters associated with the FPSC as well as two parameters for DST, including cone angle and tail length ratio, are considered as eight decision variables. Then, optimization is performed by selecting thermal efficiency and total annual cost (TAC) as objective functions and their results are assessed with the optimum design of a collector with plain tube. The results show that better thermos-economic results is found by the application of DST compared with a plain tube for an efficiency higher than 0.5566 while the use of a plain tube is more beneficial for an efficiency lower than 0.5566. Optimization is also performed for the higher electricity price and results reveal that in some higher electricity prices, the use of tube with DST is not beneficial for the all range of efficiency compared with plain tube. The results showed that the lower thickness of the bottom insulator is necessary for the model of DST in contrast to the plain tube. The higher cone angle and lower tail length ratio lead to the higher collector efficiency.
Keywords
Flat Plate Collector
Diamond-Shape Turbulator
Plain Tube
Thermo-Economic Pptimization
Pareto Front

Subjects

 

 

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