Discrete Geometric Models for Estimating the Degree of Shading in Solar Energy

Geometry & Graphics Pub Date : 2019-04-08 DOI:10.12737/ARTICLE_5C9202D8D821B0.81468033

Л. Маркин, L. Markin

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引用次数: 7

Abstract

Geometric simulation and its software for estimating the efficiency of deployment of solar panels on spacecraft and solar concentrators on the ground are considered in this work. Both the physical and mathematical set up of the problem for estimating the energy efficiency of solar panels, taking into account their shading both by each other and by other elements of a space station has been described in this paper. It has been shown that the known methods for mechanization and automation of such calculations are focused on objects of relatively simple geometric shapes (such as buildings), and are inefficient for objects of complex and diverse geometric shape, characteristic both for spacecraft themselves and their solar panels. Therefore, to solve this problem, a receptor (voxel) geometric model digitizing the computational space has been chosen. The receptor model’s uniqueness is that comparing the values of receptor codes allows easy determine the intersection of objects. Has been described a developed receptor geometric model for estimating the effective area of solar panels, taking into account their shading when the object (for example, a spacecraft) is illuminated by a flow of solar energy from a given direction. The essential difference between the developed receptor geometric model and the classical one is that the former is multiform, i.e. uses not the 2-digit code (0 and 1), but the 4-digit one (0, 1, 2 and 3). Has been demonstrated a software implementation of the described geometric model in C#, and a graphical shell developed for this problem, allowing see the obtained results’ numerical values. Have been provided examples of its implementation in solving of practical problems. The results of verification for the described receptor geometric model have been demonstrated. All this allows speak about efficiency of using receptor geometric models both in singular computation calculations and for creating the appropriate algorithmic, mathematical support and software for the corresponding CAD systems.

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估算太阳能遮阳程度的离散几何模型

本文研究了航天器上太阳能板和地面太阳能聚光器布置效率的几何模拟及其软件。本文描述了估算太阳能电池板能量效率问题的物理和数学设置，同时考虑了它们彼此之间和空间站其他元素的阴影。已经表明，这种计算的机械化和自动化的已知方法集中在相对简单的几何形状的物体上(如建筑物)，而对于复杂和多种几何形状的物体效率低下，这是航天器本身及其太阳能电池板的特点。因此，为了解决这一问题，选择了一种将计算空间数字化的受体(体素)几何模型。受体模型的独特之处在于，比较受体代码的值可以很容易地确定对象的交集。已经描述了一种用于估计太阳能电池板有效面积的成熟的受体几何模型，该模型考虑了当物体(例如航天器)被来自给定方向的太阳能流照射时它们的阴影。所开发的受体几何模型与经典模型的本质区别在于前者是多形式的，即不使用2位数代码(0和1)，而是使用4位数代码(0、1、2和3)。本文在c#中演示了所描述的几何模型的软件实现，并为此问题开发了图形shell，可以看到所得到的结果的数值。并给出了在解决实际问题中应用该方法的实例。对所描述的受体几何模型的验证结果已被证明。所有这些都说明了在奇异计算和为相应的CAD系统创建适当的算法、数学支持和软件时使用受体几何模型的效率。

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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Geometry & Graphics

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