Effect of Quartz Aperture Covers on the Fluid Dynamics and Thermal Efficiency of Falling Particle Receivers

ASME 2019 13th International Conference on Energy Sustainability Pub Date : 2019-12-03 DOI:10.1115/es2019-3910

L. Yue, Brantley Mills, C. Ho

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引用次数: 11

Abstract

Falling particle receivers are an emerging technology for use in concentrating solar power systems. In this work, quartz tubes cut in half to form tube shells (referred to as quartz half-shells) are investigated for use as a full or partial aperture cover to reduce radiative and advective losses from the receiver. A receiver subdomain and surrounding air volume are modeled using ANSYS® Fluent®. The model is used to simulate fluid dynamics and heat transfer for the following cases: (1) open aperture, (2) aperture fully covered by quartz half-shells, and (3) aperture partially covered by quartz half-shells. We compare the percentage of total incident solar power lost due to conduction through the receiver walls, advective losses through the aperture, and radiation exiting out of the aperture. Contrary to expected outcomes, simulation results using the simplified receiver subdomain show that quartz aperture covers can increase radiative losses and, in the partially covered case, also increase advective losses. These increased heat losses are driven by elevated quartz half-shell temperatures and have the potential to be mitigated by active cooling and/or material selection.

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石英孔径罩对落粒接收器流体动力学和热效率的影响

下落粒子接收器是一种用于聚光太阳能发电系统的新兴技术。在这项工作中，石英管被切成两半形成管壳(称为石英半壳)，用于研究用作全部或部分孔径盖，以减少来自接收器的辐射和对流损失。使用ANSYS®Fluent®对接收机子域和周围风量进行建模。利用该模型模拟了以下三种情况下的流体力学和传热情况:(1)开孔、(2)孔被石英半壳完全覆盖、(3)孔被石英半壳部分覆盖。我们比较了通过接收壁传导损失的总入射太阳能的百分比，通过光圈的平流损失，以及从光圈流出的辐射。与预期结果相反，使用简化的接收器子域的模拟结果表明，石英孔径覆盖会增加辐射损失，并且在部分覆盖的情况下，还会增加平流损失。这些增加的热损失是由石英半壳温度升高引起的，并且有可能通过主动冷却和/或材料选择来减轻。

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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ASME 2019 13th International Conference on Energy Sustainability

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