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Irradiation Analysis of Tensile Membrane Structures for Building-Integrated Photovoltaics

机译:建筑一体化光伏用拉膜结构辐照分析

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A dynamic development in building-integrated photovoltaics (BIPVs) has been observed in recent years. One of the manifestations of this trend is the integration of photovoltaic cells with tensile membrane structures, including canopies. Such solutions bring mutual benefits-the roofs provide a potentially large area for the application of photovoltaic cells while contributing to the improvement of the energy efficiency of the building. However, what is lacking is thorough research on the most favourable photovoltaic cell exposure within these roofs. This paper investigates the optimal position of photovoltaic cells in terms of energy gains related to exposure to solar radiation. Hypar geometries were simulated as the most characteristic of tensile membrane roofs and, simultaneously, the least obvious in the research context. Simulations were performed for 54 roof samples with the following geometric variables: roof height (1.0, 3.0 m) and membrane prestress (1:3, 1:1, 3:1). The research was conducted for three roof orientations defined by azimuth angles of 0, 22.5, and 45 degrees and three geographic locations, Oslo, Vienna, and Lisbon, representing Northern, Central, and Southern Europe, respectively. The Sofistik and Rhino + Ladybug software were used to create models and simulations. The study results show significant differences in the roof irradiation and, consequently, the optimal location of BIPVs depending on the above variables. Generally, it is the curvature that is the most important variable-less curved roofs are more irradiated and thus more suitable for BIPVs. Prestress and the azimuth angle are of lesser significance, but defining the optimal use of a BIPV depends on the adopted scenario regarding the percentage of membrane coverage with PVs-other recommendations concern the strategy of total or partial roof coverage with PV cells. The difference between optimally and incorrectly designed roofs may amount to a 50 electricity gain from PV cells.
机译:近年来,建筑一体化光伏(BIPV)出现了动态发展。这种趋势的表现之一是光伏电池与拉伸膜结构(包括檐篷)的集成。这样的解决方案带来了互惠互利——屋顶为光伏电池的应用提供了潜在的大面积,同时有助于提高建筑物的能源效率。然而,缺乏的是对这些屋顶内最有利的光伏电池暴露的彻底研究。本文研究了光伏电池在与暴露于太阳辐射相关的能量增益方面的最佳位置。Hypar 几何形状被模拟为拉伸膜屋顶最具特征的几何形状,同时也是研究环境中最不明显的几何形状。对 54 个屋顶样品进行了模拟,具有以下几何变量:屋顶高度 (1.0, 3.0 m) 和膜预应力 (1:3, 1:1, 3:1)。该研究针对三个屋顶方向进行,方位角分别为 0、22.5 和 45 度,以及奥斯陆、维也纳和里斯本这三个地理位置。Sofistik 和 Rhino + Ladybug 软件用于创建模型和模拟。研究结果显示,根据上述变量,屋顶辐照存在显著差异,因此BIPV的最佳位置也存在显著差异。一般来说,曲率是最重要的——无变弧形屋顶的辐照性更强,因此更适合BIPV。预应力和方位角的意义较小,但定义BIPV的最佳使用取决于所采用的关于PV膜覆盖百分比的情景 - 其他建议涉及PV电池全部或部分屋顶覆盖的策略。最佳和错误设计的屋顶之间的差异可能相当于光伏电池的50%的电力增益。

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