Collector factor in a solar chimney power plant: CFD analysis for the pilot plant in Manzanares

Q3 Earth and Planetary Sciences

Energetika Pub Date : 2023-01-26 DOI:10.6001/energetika.v68i1.4856

E. Cuce, Harun Sen, Pinar Mert Cuce

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引用次数: 0

Abstract

Solar chimneys are popular systems for their simple structures and clean energy generation. Thanks to its semi-permeable structure, the collector, one of the system’s basic elements, transfers solar radiation to the system. As a result of the heating of the system air under the collector by the solar radiation passing through the collector, it is directed to the high chimney in the collector centre. During the upward movement of the system air, it converts its energy into electricity via a turbine. Due to its large structure, estimating the amount of energy entering the collector system creates a great cost. The ideal size for the collector is therefore important. This study offers a recommendation for the ideal collector size for the pilot plant in Manzanares in terms of collector size and power output. While 59 kW power output is obtained with the system with a collector radius of 122 m in the reference case, it is observed that the power output increases by 78% when the collector radius is increased to 170 m and the collector area is doubled. The ratio of the ideal collector radius to the reference size for the pilot plant should be in the range of 1–1.5.

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太阳能烟囱电厂的集热器系数:曼萨纳雷斯试验电厂的CFD分析

太阳能烟囱由于其简单的结构和清洁的能源发电而成为流行的系统。由于其半透明结构，收集器是系统的基本元件之一，可以将太阳辐射转移到系统中。由于通过收集器的太阳辐射对收集器下方的系统空气进行加热，空气被引导到收集器中心的高烟囱。在系统空气向上运动的过程中，它通过涡轮机将能量转化为电力。由于其庞大的结构，估计进入收集器系统的能量会产生巨大的成本。因此，收集器的理想尺寸非常重要。本研究为曼扎纳雷斯中试工厂的理想集电器尺寸提供了集电器尺寸和功率输出方面的建议。虽然在参考情况下，收集器半径为122m的系统获得了59kW的功率输出，但可以观察到，当收集器半径增加到170m并且收集器面积增加一倍时，功率输出增加了78%。中试装置的理想收集器半径与参考尺寸之比应在1–1.5的范围内。

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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来源期刊

Energetika Energy-Energy Engineering and Power Technology

CiteScore

2.10

自引率

0.00%

发文量

期刊介绍： The journal publishes original scientific, review and problem papers in the following fields: power engineering economics, modelling of energy systems, their management and optimization, target systems, environmental impacts of power engineering objects, nuclear energetics, its safety, radioactive waste disposal, renewable power sources, power engineering metrology, thermal physics, aerohydrodynamics, plasma technologies, combustion processes, hydrogen energetics, material studies and technologies, hydrology, hydroenergetics. All papers are reviewed. Information is presented on the defended theses, various conferences, reviews, etc.