Analysing the Daylighting Performance of the Main Prayer-hall in the Great Mosque of Hama, Syria

Q2 Energy

Journal of Daylighting Pub Date : 2023-11-25 DOI:10.15627/jd.2023.14

Salam Jijakli, Sundous M. B. Jijakli

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引用次数: 0

Abstract

Daylighting and solar availability at urban scale has come to play a crucial role in the perception of discomfort conditions for people, both in outdoor and indoor spaces, and on the energy consumption of buildings. Daylighting and solar analyses are typically done separately. The paper presents a novel method, called the ‘sunlight-daylight signature’ (SDS), which allows the qualitative analysis of urban settings with respect to sunlight and daylight. The method can be used to classify different urban settings in terms of daylight/sunlight access or to test new development proposals by referring to existing locations and confirm whether a certain daylight quality is met. The SDS relies on a new analysis tool, called ‘sunlight-daylight wedge’ (SDW), which combines obstruction (through the vertical sky component VSC) and sunlight access (through the annual probable sunlight hours PASH and the winter probable sunlight hours PWSH). The orientation of the façade at each point is also included as it will affect the times of the day when the sun-hours from PASH and PWSH occur, thus affecting the character of the corresponding sunlight. The SDS approach is based on a clustering technique to subdivide large datasets (in this case, daylight data points across entire cities or major urban areas) into smaller groups, using machine learning by way of the k-medoids clustering technique. This is used to derive typical daylight and sunlight scenarios representing groups of data points with similar conditions. Additional data is included to account for urban density and daylight availability in public areas. Final output of the clustering process consists of a map showing areas with the same daylight signature (SDS), which means areas with the same sunlight and daylight conditions. The SDS can be useful for urban planners and building practitioners to predict the access to both daylight and sunlight of large urban settings to optimize comfort for people and energy usage.

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分析叙利亚哈马大清真寺主祈祷大厅的采光性能

城市范围内的日照和太阳能可用性对人们在室外和室内的不适感以及建筑物的能耗起着至关重要的作用。日照和太阳能分析通常是分开进行的。本文提出了一种名为 "日照-日光特征"（SDS）的新方法，可以对城市环境中的日照和日光进行定性分析。该方法可用于对不同的城市环境进行日光/日照访问分类，或通过参考现有地点来测试新的开发提案，并确认是否满足一定的日照质量要求。SDS 依赖于一种新的分析工具，称为 "日照-日光楔"（SDW），它将阻挡（通过垂直天空分量 VSC）和日照获取（通过全年可能日照时数 PASH 和冬季可能日照时数 PWSH）结合在一起。每个点的外墙朝向也包括在内，因为它会影响一天中出现 PASH 和 PWSH 日照时数的时间，从而影响相应的日照特征。SDS 方法以聚类技术为基础，通过 K-medoids 聚类技术，利用机器学习将大型数据集（此处为整个城市或主要城区的日照数据点）细分为更小的组。这样就得出了典型的日光和日照情景，代表了具有相似条件的数据点组。此外，还包括其他数据，以考虑城市密度和公共区域的日照可用性。聚类过程的最终输出包括一张地图，显示具有相同日照特征（SDS）的区域，即具有相同日照和日照条件的区域。SDS 可帮助城市规划者和建筑从业人员预测大型城市环境中的日光和日照情况，从而优化人们的舒适度和能源使用。

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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来源期刊

Journal of Daylighting Energy-Renewable Energy, Sustainability and the Environment

CiteScore

4.00

自引率

0.00%

发文量

审稿时长

10 weeks

期刊介绍： Journal of Daylighting is an international journal devoted to investigations of daylighting in buildings. It is the leading journal that publishes original research on all aspects of solar energy and lighting. Areas of special interest for this journal include, but are not limited to, the following: -Daylighting systems -Lighting simulation -Lighting designs -Luminaires -Lighting metrology and light quality -Lighting control -Building physics - lighting -Building energy modeling -Energy efficient buildings -Zero-energy buildings -Indoor environment quality -Sustainable solar energy systems -Application of solar energy sources in buildings -Photovoltaics systems -Building-integrated photovoltaics -Concentrator technology -Concentrator photovoltaic -Solar thermal