CoolSkin

Andreas Greiner, O. Böckmann, S. Weber, M. Ostermann, M. Schaefer
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引用次数: 0

摘要

本文研究了基于封闭吸附的可持续太阳能冷却系统集成中立面设计和施工的依赖关系。提出的工作重点是可能的设计变体的膜面一体化吸附器。介绍了吸附冷却的原理,并在此基础上研究了吸附冷却的结构选择。这是建设性的和可视化的。对于每一种变化,总结了太阳能的增益并相互比较。一个功能设计的吸附器,类似于平板收集器,作为修改的参考和起点。为能源评价提供了比较价值。这种修改仅限于吸收器的可见表面。太阳能吸附板的质地发生了变化,使用的玻璃被ETFE缓冲垫和新型ETFE真空板取代。最后,将太阳能模拟结果集成到更高级别的系统模拟中,以评估由此产生的制冷量增益。结果表明,该系统每安装平方米吸附剂表面可产生100瓦以上的电能。此外,由于几何形状和材料的变化,与参考情况相比,在一天中的特定时间可以获得更高的太阳能增益。然而,这些修改总是导致总冷却功率的降低。综上所述,模拟结果表明,设计灵活性是可能的,但目前所研究的设计变体与单一功能设计的吸附器相比,冷却能力较低。
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CoolSkin
The article investigates the dependencies of façade design and construction in the integration of a sustainable solar-powered cooling system based on closed adsorption. The presented work focuses on the possible design variants of the envelope surface of the façade -integrated adsorber. The principle of adsorption cooling is presented and, based on this, architectural options for façade integration are investigated. This is done both constructively and visually. For each variant, the solar gains are summed up and compared with each other. A functionally designed adsorber, similar to a flat plate collector, serves as a reference and starting point for the modifications. It provides the comparative value for the energy evaluation. The modification is limited to the visible surface of the absorber. The texture of the solar adsorbing sheet was changed and the glazing used was replaced by ETFE cushions and by a novel ETFE vacuum panel. Finally, the solar simulation results were integrated into the higher-level system simulation to evaluate the resulting gain in cooling capacity. The results show that the system could generate more than 100 W per installed square metre of adsorber façade. Furthermore, higher solar gains compared to the reference case can be obtained at particular times of the day due to geometry and material changes. However, the modifications always lead to a reduction of the total cooling power. In conclusion, the simulation results reveal that design flexibility is possible, but currently the studied design variants have a lower cooling capacity compared to the solely functionally designed adsorber.
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来源期刊
Journal of Facade Design and Engineering
Journal of Facade Design and Engineering Engineering-Architecture
CiteScore
1.90
自引率
0.00%
发文量
3
审稿时长
12 weeks
期刊介绍: The Journal of Facade Design and Engineering presents new research results and new proven practice in the field of facade design and engineering. The goal is to improve building technologies, as well as process management and architectural design. This journal is a valuable resource for professionals and academics involved in the design and engineering of building envelopes, including the following disciplines: Architecture Façade Engineering Climate Design Building Services Integration Building Physics Façade Design and Construction Management Novel Material Applications. The journal will be directed at the scientific community, but it will also feature papers that focus on the dissemination of science into practice and industrial innovations. In this way, readers explore the interaction between scientific developments, technical considerations and management issues.
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