The natural cooling of energy-efficient buildings using latent heat thermal energy storage (LHTES) that is integrated into the building services makes possible energy savings and improved thermal comfort. In this article, studies of the free-cooling potential for different climatic locations are presented. Six cities from around Europe with a wide range of climatic conditions were selected. The size of the LHTES was optimized on the basis of the calculated cooling degree-hours. First, we analysed the influence of the width of the phase change temperature range and determined the optimal melting temperature of the phase change material (PCM). Then, the optimal LHTES was selected, based on the ratio of the mass of the PCM and the volume flow rate of air ventilating the building. We found that the optimum PCM has a melting temperature that is approximately equal to the average ambient air temperature in the hottest month, and that the free-cooling potential is proportional to the average daily amplitude of the ambient air's temperature swings. For all the analysed climatic conditions the PCM with a wider phase change temperature range (12 K) was found to be the most efficient. The optimal size of the LHTES for the free cooling of buildings is between 1 and 1.5 kg of PCM per m~3/h of fresh ventilation air.
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机译:使用集成到建筑物服务中的潜热热能存储(LHTES)对节能建筑进行自然冷却,可以节省能源并提高热舒适度。本文介绍了不同气候位置的自然冷却潜能。选择了来自欧洲各地六个气候条件广泛的六个城市。 LHTES的尺寸是根据计算的冷却小时数来优化的。首先,我们分析了相变温度范围宽度的影响,并确定了相变材料(PCM)的最佳熔化温度。然后,基于PCM的质量与建筑物通风的风量之比,选择最佳的LHTES。我们发现最佳PCM的熔化温度大约等于最热月份的平均环境空气温度,而自然冷却的潜力与环境空气温度波动的每日平均幅度成正比。对于所有分析的气候条件,相变温度范围(12 K)较宽的PCM是最有效的。用于建筑物自然冷却的LHTES的最佳尺寸为每m〜3 / h新鲜通风空气1到1.5 kg PCM。
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