Quasi-Gaussian Multibeam Solar Laser Station for a Megawatt Solar Furnace

Journal of Solar Energy Research Updates Pub Date : 2021-03-22 DOI:10.31875/2410-2199.2021.08.02

Hugo Costa, Joana Almeida, Dawei Liang, Bruno D. Tibúrcio, Dario Garcia, Miguel Catela, Claudia R. Vistas

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引用次数: 3

Abstract

An alternative multirod solar side-pumping concept for the production of multiple quasi-Gaussian beams is proposed. This scheme was based on the One-Megawatt solar furnace in Odeillo, France, which collected and concentrated the solar light into a multilayered pyramidal pumping cavity placed at the focal zone. Each layer was comprised of a square array of four laser heads, each composed of a biconic surface that reflected the solar rays towards a Nd:YAG rod fixed inside a fused silica flow tube. A pyramidal reflector was placed inside the pumping cavity to close it and maximize the harness of solar energy. Compared to the previous multibeam solar laser station design for the same solar furnace, considerable alleviation of thermal lensing effects was achieved with the present approach, allowing the improvement of the laser beam quality factors and, consequently, the possibility of a 32-laser-beam generation, each with a quasi-Gaussian profile. For this case, 9.44 kW total laser power was calculated. Additionally, 20.01 kW total multimode laser power was numerically determined, which corresponds to a 10.93 W/m2 collection efficiency and a 2.0% solar-to-laser power conversion efficiency.

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兆瓦级太阳能炉准高斯多波束太阳能激光站

提出了一种可替代的多杆太阳侧泵概念，用于产生多个准高斯光束。该方案基于法国Odeillo的1兆瓦太阳能炉，该炉收集并将太阳能集中到放置在焦点区域的多层金字塔泵腔中。每一层由四个激光头组成的正方形阵列组成，每个激光头由一个双曲面组成，该曲面将太阳光线反射到固定在熔融硅流管内的Nd:YAG棒上。在泵腔内放置了一个金字塔形反射器，以关闭泵腔并最大限度地利用太阳能。与先前相同太阳炉的多光束太阳能激光站设计相比，本方法大大减轻了热透镜效应，从而改善了激光束质量因素，从而有可能产生32束激光，每束激光都具有准高斯分布。在这种情况下，激光总功率计算为9.44 kW。此外，通过数值计算确定了20.01 kW的总多模激光功率，对应于10.93 W/m2的收集效率和2.0%的太阳能-激光功率转换效率。

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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Journal of Solar Energy Research Updates

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