基于充气结构的太阳能发电救灾帐篷研究

B. Fan, Maoyuan Shi, Jiacheng Pang, Jiangqi Wang, Jianwu Wang
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Introduction In earthquake disasters, clothes and other materials were needed by the victims, and tents that could shelter the wind and rain were more needed in harsh environments [1].On May 12, 2008, a strong earthquake of magnitude 8.0 struck Wenchuan, China, requiring more than 3 million tents were erected in a few days. \"Water Cube\" stadium was the largest membrane structure project in the world at present, which means that domestic research on the materials and fabrication technology of inflatable membranes has gradually matured [2]. Inflatable membrane structure had been widely used in tent field [3]. Disaster relief tents were mainly used for temporary and short-term emergency relief. Most of the fabrics used were PVC or PU coated fabrics with poor air permeability or impermeability, which had poor warmth retention, thermal insulation and air permeability. Comfort was also a difficult problem in the design of tents in disaster areas. The existing disaster relief tents were heavy and inconvenient to transport. At the same time, the construction of disaster relief tents needs cooperation of many people to complete. Wind resistance of tents was mainly studied in the literature of new integral folding frame tent structures [4]; the feasibility of emergency tents and extension services from a spatial perspective were mainly studied in the literature of the design of emergency tents in post-disaster public space [5]; The design and research of inflatable tent [6] could reduce the difficulty of tent construction, and had the characteristics of lightness and convenient transportation. In the early stage of disaster relief, lighting was a big problem. . An inflatable tent with solar power could solve the problems of simple lighting difficulties and fast construction. Structural Design The inflatable structure of the tent was shown in Figure 1. 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The deformation of inflatable column was basically consistent with the deformation of inflatable column after expansion, and the stress at different positions was also consistent with the basic size. The optimum ratio of height to width of arch was obtained to ensure the strength and stability of arch. At the same time, the optimal ratio of long axis to short axis of ellipse with small stress and strain was obtained. The suitable size was chosen to design the overall structure of the inflatable tent. The practical number and distribution mode of solar energy film was formulated, and the solar energy film was combined with tent. Finally, the inflatable structure tent with power generation function for disaster areas was obtained. 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引用次数: 0

摘要

利用ANSYS软件对救灾帐篷局部结构进行了分析。充气柱的变形与膨胀后的变形基本一致,不同位置的应力也与基本尺寸一致。为保证拱的强度和稳定性,确定了拱的最佳高宽比。同时,得到了应力应变较小的椭圆长轴与短轴的最佳配比。选择合适的尺寸设计充气帐篷的整体结构。制定了太阳能膜的实用数量和分布方式,并将太阳能膜与帐篷相结合。最后,获得了灾区具有发电功能的充气结构帐篷。在地震灾害中,灾民需要衣物等物资,在恶劣的环境中更需要能够遮挡风雨的帐篷[1]。2008年5月12日,中国汶川发生里氏8.0级强烈地震,几天内搭建了300多万顶帐篷。“水立方”体育场是目前世界上最大的膜结构工程,这意味着国内对充气膜材料和制作技术的研究已经逐渐成熟[2]。充气膜结构已广泛应用于帐篷领域[3]。救灾帐篷主要用于临时和短期的紧急救援。所用面料多为透气性或不透气性较差的PVC或PU涂层面料,保暖性、隔热性和透气性较差。在灾区帐篷的设计中,舒适性也是一个难题。现有的救灾帐篷很重,不方便运输。同时,救灾帐篷的建设需要很多人的合作才能完成。帐篷的抗风性能研究主要集中在新型整体折叠框架帐篷结构的文献中[4];灾后公共空间应急帐篷设计文献主要从空间角度研究应急帐篷及其延伸服务的可行性[5];充气帐篷的设计与研究[6]可以降低帐篷搭建的难度,并且具有轻便、方便运输的特点。在救灾初期,照明是一个大问题。太阳能充气帐篷可以解决简单的照明困难和快速施工的问题。帐篷的充气结构如图1所示。底部采用椭圆结构,顶部采用拱形结构作为帐篷骨架[7]。帐篷由帐篷内、帐篷外、帐篷骨架四部分组成。帐篷配备了太阳能薄膜,
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Research on Solar Power Generation Disaster Relief Tent Based on Inflatable Structure
The local structure of disaster relief tent was analyzed by ANSYS. The deformation of inflatable column was basically consistent with the deformation of inflatable column after expansion, and the stress at different positions was also consistent with the basic size. The optimum ratio of height to width of arch was obtained to ensure the strength and stability of arch. At the same time, the optimal ratio of long axis to short axis of ellipse with small stress and strain was obtained. The suitable size was chosen to design the overall structure of the inflatable tent. The practical number and distribution mode of solar energy film was formulated, and the solar energy film was combined with tent. Finally, the inflatable structure tent with power generation function for disaster areas was obtained. Introduction In earthquake disasters, clothes and other materials were needed by the victims, and tents that could shelter the wind and rain were more needed in harsh environments [1].On May 12, 2008, a strong earthquake of magnitude 8.0 struck Wenchuan, China, requiring more than 3 million tents were erected in a few days. "Water Cube" stadium was the largest membrane structure project in the world at present, which means that domestic research on the materials and fabrication technology of inflatable membranes has gradually matured [2]. Inflatable membrane structure had been widely used in tent field [3]. Disaster relief tents were mainly used for temporary and short-term emergency relief. Most of the fabrics used were PVC or PU coated fabrics with poor air permeability or impermeability, which had poor warmth retention, thermal insulation and air permeability. Comfort was also a difficult problem in the design of tents in disaster areas. The existing disaster relief tents were heavy and inconvenient to transport. At the same time, the construction of disaster relief tents needs cooperation of many people to complete. Wind resistance of tents was mainly studied in the literature of new integral folding frame tent structures [4]; the feasibility of emergency tents and extension services from a spatial perspective were mainly studied in the literature of the design of emergency tents in post-disaster public space [5]; The design and research of inflatable tent [6] could reduce the difficulty of tent construction, and had the characteristics of lightness and convenient transportation. In the early stage of disaster relief, lighting was a big problem. . An inflatable tent with solar power could solve the problems of simple lighting difficulties and fast construction. Structural Design The inflatable structure of the tent was shown in Figure 1. Elliptical structure was adopted at the bottom and arch structure was used at the top as the tent skeleton [7]. The tent was composed of four parts: inside tent, outside tent and tent skeleton. The tent was equipped with solar power film,
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