Direct Absorption Solar Collector: An Experimental Investigation of Al2O3-H2O Nanofluid over the Flat Plate at Different Tilt Angles, and Mass-Flow Rates

New Energy Exploitation and Application Pub Date : 2024-02-29 DOI:10.54963/neea.v3i1.214

Lalit Jyani, Shivangi Sharma, Kailash Chaudhary, Kamlesh Purohit

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Abstract

The escalating demand for solar thermal energy, coupled with the current inefficiencies in existing systems, underscores the critical need for innovative advancements in thermal storage solar collectors. The efficiency of solar collectors relies not solely on design effectiveness but also on the thermophysical properties, such as heat capacity and thermal conductivity, inherent in the working fluid. This study investigates a novel solar collector with a gross area of 0.36 m2, operating on the principle of direct absorption. Experimental investigations were done at various tilt angles (15°, 20°, and 30°) with respect to the horizontal, considering different flow rates and nanofluid settlement within the base fluids. The use of Al2O3 nanoparticles into the base fluid as water, exhibits significant positive effects on the thermophysical properties of the nanofluids, with a volume concentration of 0.003%. The efficiency of the solar collector was calculated across three mass flow rates (0.5, 1, and 1.33 L/min) at each tilt angle. Notably, the study reveals that the efficiency peaks at a 15° tilt due to an optimal flow configuration for maximum energy harvest across all three mass flow rates. Increasing the mass flow rate yields efficiency increments for all tilt angles (15°, 20°, and 30°), with 1 L/min emerging as the optimal mass-flow rate in most cases. This research not only addresses the immediate need for improved solar thermal technologies but also aligns with global sustainability goals, contributing to the IEA Net Zero Emissions initiative and supporting UN Sustainable Development Goals 7, 9, and 11. The paper also includes a critical literature review on the use of nanofluids in solar thermal collectors to improve thermo-physical properties and enhance solar efficiency. Additionally, the key findings regarding the influence and tilt angle on solar efficiency are discussed.

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直接吸收太阳能集热器：不同倾斜角度和质量流量下平板上的 Al2O3-H2O 纳米流体的实验研究

对太阳能热能不断增长的需求，加上现有系统效率低下的现状，凸显了对创新性太阳能集热器的迫切需要。太阳能集热器的效率不仅取决于设计的有效性，还取决于工作流体固有的热物理性质，如热容量和热传导率。本研究调查了一种总面积为 0.36 平方米的新型太阳能集热器，其工作原理是直接吸收。实验研究是在相对于水平面的不同倾斜角度（15°、20° 和 30°）下进行的，并考虑了不同的流速和纳米流体在基础流体中的沉降情况。在水基流体中加入 Al2O3 纳米粒子对纳米流体的热物理性质有显著的积极影响，其体积浓度为 0.003%。在每个倾斜角度下，计算了三种质量流量（0.5、1 和 1.33 升/分钟）下太阳能集热器的效率。值得注意的是，研究表明，在 15° 倾角时，效率达到峰值，这是因为在所有三种质量流量下，最佳流量配置都能实现最大能量收集。在所有倾斜角度（15°、20° 和 30°）下，增加质量流量都能提高效率，在大多数情况下，1 升/分钟是最佳质量流量。这项研究不仅满足了对改进太阳能热技术的迫切需求，而且符合全球可持续发展目标，有助于实现国际能源机构的净零排放倡议，并支持联合国可持续发展目标 7、9 和 11。本文还对纳米流体在太阳能集热器中的应用进行了重要的文献综述，以改善热物理性质并提高太阳能效率。此外，还讨论了有关倾斜角度对太阳能效率影响的主要发现。

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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New Energy Exploitation and Application

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