The Potential of Cool Materials Towards Improving Thermal Comfort Conditions Inside Real-urban Hot-humid Microclimate

IF 1.3 Q4 ENVIRONMENTAL STUDIES Environment and Urbanization ASIA Pub Date : 2022-03-01 DOI:10.1177/09754253221083206
Muhammad Zeeshan, Zaib Ali
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引用次数: 1

Abstract

The urban heat island (UHI) phenomenon has become a major concern for city sustainability in the wake of global warming and rapid urbanization. This has resulted in increased heat stress and worsened outdoor thermal comfort in urban microclimates. The study demonstrates that heat stress can be mitigated by reducing air temperature and surface temperature with the integration of cool materials into the urban environment using computational fluid dynamics, under representative climatic conditions. The thermal comfort conditions are examined at pedestrian height and the diverse vertical levels by evaluating two climatic parameters: first, the reduction of ambient air temperature and surface temperature characterizing the mitigation (cooling) intensity, and second, the alteration of airflow velocity. The analysis shows that the proposed intervention can effectively decrease surrounding temperature and promote airflow. Cool materials, when applied simultaneously on both buildings and ground, generate a more pronounced mitigation effect than on only the ground or the buildings as it results in a large reduction of air and surface temperature, that is, of 2°C and 6°C, respectively. For airflow velocity, it is highest for combined cool materials, with maximum effect at the time of highest solar irradiance. The study is expected to inform architects, urban designers and people involved in construction engineering regarding retrofitting mitigation of UHI under representative climatic conditions.
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凉爽材料在改善真实城市湿热小气候中的热舒适条件方面的潜力
随着全球气候变暖和城市化进程的加快,城市热岛现象已成为影响城市可持续发展的一个重要问题。这导致了城市小气候的热应激增加和室外热舒适恶化。研究表明,在具有代表性的气候条件下,通过计算流体动力学将冷材料融入城市环境,降低空气温度和地表温度,可以减轻热应力。通过评估两个气候参数,考察了行人高度和不同垂直高度的热舒适条件:一是环境空气温度和地表温度的降低,表征了缓解(冷却)强度;二是气流速度的变化。分析表明,该干预措施能有效降低周围温度,促进气流。当冷材料同时应用于建筑物和地面时,比仅应用于地面或建筑物产生更显著的减缓效果,因为它可使空气和地面温度大幅降低,即分别降低2°C和6°C。对于气流速度而言,组合冷材料的气流速度最高,在太阳辐照度最高时效果最大。预计这项研究将为建筑师、城市设计师和参与建筑工程的人员提供有关在代表性气候条件下改造缓解热岛热岛的信息。
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来源期刊
Environment and Urbanization ASIA
Environment and Urbanization ASIA ENVIRONMENTAL STUDIES-
CiteScore
2.70
自引率
0.00%
发文量
24
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