Heat Exchange Optimization by Adding Baffles to Streaming Duct of Solar Air Collector

Iranian Journal of Energy and Environment Pub Date : 2022-01-01 DOI:10.5829/ijee.2022.13.04.04

Z. Aouissi, F. Chabane, M. Teguia, N. Belghar, N. Moummi, A. Brima

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引用次数: 1

Abstract

This numerical and experimental work aims to improve the heat transfer inside a solar thermal collector. By incorporating rectangular baffles in the middle of the distributed air passing channel at different angles of inclination (  = 90  ,  = 180  ,  = 180  and  = 90  ). That is called the model H. These experiments were carried out in the Biskra region of Algeria in good natural conditions with an average solar radiation approximately constant I= 869 W/m 2 varying from 11:30 to 14:00. After the completion of the experimental investigation, a computational fluid dynamics (CFD) model was created that matches this experimental model with the same experimental boundary conditions. In the numerical study, ANSYS Fluent 18.1 was used to conduct simulations and compare the results of the thermal and hydraulic performance of the collector. It was concluded that the effectiveness of the CFD model, meaning that the theoretical and numerical data were very close to each other for all mass flow rates. As the mass flow increased the heat transfer process increased, while the absorber plate temperature inside the collector for experimental and numerical studies decreased. Addition of baffles increased heat transfer, due to the creation of turbulent flow that leads to crack the dead thermal layers near the absorber plate, which leads to an increase in heat transfer from the absorber plate to the air.

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太阳能集热器流道加挡板优化换热

本文的数值和实验工作旨在改善太阳能集热器内部的传热。通过在分布气流通道中间以不同的倾斜角度(= 90 ，= 180 ，= 180 和= 90 )加装矩形挡板。这些实验是在阿尔及利亚的Biskra地区进行的，在良好的自然条件下，平均太阳辐射大约恒定I= 869 W/m 2，从11:30到14:00变化。实验研究完成后，在相同的实验边界条件下，建立了与该实验模型相匹配的计算流体力学(CFD)模型。在数值研究中，采用ANSYS Fluent 18.1对集热器的热工性能和水力性能进行了模拟和对比。计算结果表明，所建立的CFD模型是有效的，所有质量流量下的理论数据和数值数据非常接近。随着质量流量的增加，传热过程增大，而集热器内部吸收板温度降低，用于实验和数值研究。挡板的增加增加了传热，由于紊流的产生导致吸收板附近的死热层破裂，这导致从吸收板到空气的热量传递增加。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Iranian Journal of Energy and Environment

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