Characterization and Performance Analysis of Non-Metallic Oxide Nano-Fluids in Compound Parabolic Trough Solar Collectors

M. Kaleem, Muzaffar Ali, H. Riaz, J. Akhter
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引用次数: 2

Abstract

Solar energy is a viable source to fulfill the energy demands of a solar rich country such as Pakistan. Various types of solar thermal technologies are being used around the world, including flat plate, evacuated tube, and compound parabolic trough collectors. However, the performance of these collectors is strongly influenced by the nature of work fluid. Utilization of nanofluids with high thermal conductivity is a very attractive way to further enhance the performance of solar collectors. Therefore, this study deals with the characterization and thermal performance enhancement of compound parabolic collectors (CPC) by using non-metallic nanofluids such as water-based multi-wall carbon nano tubes (H2O-MWCNT) with a thermal conductivity of 3000 W/m·K. In the current work, multiple tests are performed to analyze the thermal conductivity and stability of nanofluids through thermal analyzer and UV-Vis Spectroscopy, respectively. Test results show that the thermal conductivity of water-based MWCNT nanofluid is 37% higher than water at a concentration of 0.075%. Prepared nanofluids are then employed in CPC, and detailed experimentation is performed by varying the concentration of nanoparticles (0.025, 0.05, 0.075%) and their flow rate (0.015, 0.02 kg/s). Maximum temperature difference of 10.5oC with volumetric concentration of 0.075% is achieved in experimental analysis at flow rate 0.015 kg/s. Thermal efficiency enhancement of 19.37% with volumetric concentration 0.075% is recorded as compared to water at flow rate 0.015 kg/s.
复合抛物面槽太阳能集热器中非金属氧化物纳米流体的表征及性能分析
对于巴基斯坦这样一个太阳能资源丰富的国家来说,太阳能是一种可行的能源。世界各地正在使用各种类型的太阳能热技术,包括平板、真空管和复合抛物面槽集热器。然而,这些收集器的性能受到工作流体性质的强烈影响。利用具有高导热性的纳米流体是进一步提高太阳能集热器性能的一种非常有吸引力的方法。因此,本研究采用导热系数为3000 W/m·K的水基多壁碳纳米管(H2O-MWCNT)等非金属纳米流体对复合抛物型集热器(CPC)进行表征和热性能增强研究。在目前的工作中,通过热分析仪和紫外-可见光谱分别进行了多种测试来分析纳米流体的导热性和稳定性。测试结果表明,在0.075%的浓度下,水基MWCNT纳米流体的导热系数比水高37%。然后将制备好的纳米流体用于CPC,并通过改变纳米颗粒的浓度(0.025、0.05、0.075%)和流速(0.015、0.02 kg/s)进行详细的实验。在流量为0.015 kg/s时,在体积浓度为0.075%时,实验分析的最大温差为10.5oC。与流量为0.015 kg/s的水相比,体积浓度为0.075%时的热效率提高了19.37%。
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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