Analysis of Resilience of Ventilative Cooling Technologies in a Case Study Building

iCRBE Procedia Pub Date : 2020-09-28 DOI:10.32438/icrbe.202041

A. Sengupta, M. Steeman, H. Breesch

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引用次数: 2

Abstract

Buildings globally are subjected to climate change and heatwaves, causing a risk of overheating and increasing energy use for cooling. Low- energy cooling solutions such as night cooling are promising to realize energy reduction and climate goals. Apart from energy performances, resilience is gaining importance in assessing the performance of the building and its systems. Resilience is defined as “an ability to withstand disruptions caused by extreme weather events, man-made disasters, power failure, change in use and atypical conditions; and to maintain capacity to adapt, learn and transform.” However, there is a clear lack of Resilience indicators specific for low energy cooling technologies. In this paper, the resilience of the night cooling in a residential building in Belgium is assessed for two external events: heat wave and shading failure. This paper shows the first attempt of a resilience indicator for night cooling as the effect on the shock of solar shading failure, heat wave or combination of both. It take 3.4 days to bring down the temperature below 25?, in case of shading failure and heatwaves compared to 9 hours in the reference case. Further research is needed to determine resilience indicators as a performance criteria of low-energy cooling systems.

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以某建筑为例，分析通风冷却技术的弹性

全球的建筑都受到气候变化和热浪的影响，造成了过热的风险，并增加了冷却的能源消耗。低能耗的冷却解决方案，如夜间冷却，有望实现节能和气候目标。除了能源性能，弹性在评估建筑及其系统的性能方面也越来越重要。弹性被定义为“承受极端天气事件、人为灾害、电力故障、使用变化和非典型情况造成的中断的能力;并保持适应、学习和转型的能力。”然而，目前明显缺乏针对低能耗冷却技术的弹性指标。在本文中，评估了比利时住宅建筑的夜间冷却弹性两个外部事件:热浪和遮阳失效。本文首次尝试将弹性指标作为夜间冷却对遮阳失效、热浪或两者结合的冲击的影响。把温度降到25度以下需要3.4天。，在遮阳失败和热浪的情况下，与参考情况下的9小时相比。需要进一步的研究来确定弹性指标作为低能耗冷却系统的性能标准。

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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iCRBE Procedia

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