{"title":"基于 BIM 的屋顶和外墙绿色建筑构件参数化能耗分析","authors":"","doi":"10.1016/j.nxsust.2024.100078","DOIUrl":null,"url":null,"abstract":"<div><div>Buildings are distinguished by their high energy demand over their lifespan. Iimproving energy efficiency in buildings necessitates mitigating the operation energy performance by evaluating more sustainable building components such as green infrastructures. The novelty herein is to conduct a BIM-based parametric energy analysis of green building components for the roofs and facades, taking into consideration the climate classification and orientation of the building. The proposed framework of this study uses Autodesk Revit software and Autodesk Green Building Studio as BIM tools, and Minitab software as a parametric analysis tool to estimate the energy performance of several alternative components based on Energy Use Intensity (EUI) and Annual Peak Demand (APD). A case study of a residential building is examined in four cities within different climate zones in Brazil; Rio de Janeiro (climate zone 08), Macaé (climate zone 05), Petrópolis (climate zone 03), and Nova Friburgo (climate zone 02). The base model design of components of the building includes a reinforced concrete roof and ceramic masonry façade. The utilized alternatives are roof components (i.e. green roofs and expanded clay roofs), and green façade. This work insight using green façade for all elevations and green roofs to enhance energy efficiency in terms of EUI by (10,17 %) in Rio de Janeiro, (6,67 %) in Macaé, (11,43 %) in Pertópolis, and (16,43 %) in Nova Friburgo. While the efficiency in terms of APD would be about (28,07 %) in Rio de Janeiro, (22,79 %) in Macaé, (21,67 %) in Pertópolis, and (12,58 %) in Nova Friburgo. When the construction project is designed to install a green façade to the main elevation only, this work recommends using green roofs rather than the expanded clay roof or the base model design roofs to increase energy efficiency in such types of buildings. This work contributes to integrating green building components into building designs to improve energy efficiency and empower decision-making and sustainability in buildings.</div></div>","PeriodicalId":100960,"journal":{"name":"Next Sustainability","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2024-10-07","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"BIM-based parametric energy analysis of green building components for the roofs and facades\",\"authors\":\"\",\"doi\":\"10.1016/j.nxsust.2024.100078\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><div>Buildings are distinguished by their high energy demand over their lifespan. Iimproving energy efficiency in buildings necessitates mitigating the operation energy performance by evaluating more sustainable building components such as green infrastructures. The novelty herein is to conduct a BIM-based parametric energy analysis of green building components for the roofs and facades, taking into consideration the climate classification and orientation of the building. The proposed framework of this study uses Autodesk Revit software and Autodesk Green Building Studio as BIM tools, and Minitab software as a parametric analysis tool to estimate the energy performance of several alternative components based on Energy Use Intensity (EUI) and Annual Peak Demand (APD). A case study of a residential building is examined in four cities within different climate zones in Brazil; Rio de Janeiro (climate zone 08), Macaé (climate zone 05), Petrópolis (climate zone 03), and Nova Friburgo (climate zone 02). The base model design of components of the building includes a reinforced concrete roof and ceramic masonry façade. The utilized alternatives are roof components (i.e. green roofs and expanded clay roofs), and green façade. This work insight using green façade for all elevations and green roofs to enhance energy efficiency in terms of EUI by (10,17 %) in Rio de Janeiro, (6,67 %) in Macaé, (11,43 %) in Pertópolis, and (16,43 %) in Nova Friburgo. While the efficiency in terms of APD would be about (28,07 %) in Rio de Janeiro, (22,79 %) in Macaé, (21,67 %) in Pertópolis, and (12,58 %) in Nova Friburgo. When the construction project is designed to install a green façade to the main elevation only, this work recommends using green roofs rather than the expanded clay roof or the base model design roofs to increase energy efficiency in such types of buildings. 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引用次数: 0
摘要
建筑物的显著特点是在其生命周期内对能源的需求量很大。要提高建筑物的能效,就必须通过评估更具可持续性的建筑组件(如绿色基础设施)来降低运行能耗。本文的新颖之处在于对屋顶和外墙的绿色建筑构件进行基于 BIM 的参数化能源分析,同时考虑到气候分类和建筑物的朝向。本研究提出的框架使用 Autodesk Revit 软件和 Autodesk Green Building Studio 作为 BIM 工具,并使用 Minitab 软件作为参数分析工具,根据能源使用强度(EUI)和年峰值需求(APD)估算几种可选构件的能源性能。在巴西不同气候区的四个城市(里约热内卢(气候区 08)、马卡埃(气候区 05)、彼得罗波利斯(气候区 03)和新弗里堡戈(气候区 02))进行了住宅楼案例研究。建筑组件的基础模型设计包括钢筋混凝土屋顶和陶瓷砌体外墙。采用的替代方案是屋顶组件(即绿色屋顶和膨胀粘土屋顶)和绿色外墙。这项研究发现,在所有立面使用绿色外墙和绿色屋顶可提高里约热内卢的能源效率,在 EUI 方面提高了(10.17%),在马卡埃提高了(6.67%),在佩尔托波利斯提高了(11.43%),在新弗里堡提高了(16.43%)。里约热内卢的年发电量效率约为(28.07 %),马卡埃约为(22.79 %),佩尔托波利斯约为(21.67 %),新弗里堡约为(12.58 %)。当建筑项目仅在主立面设计安装绿色立面时,这项工作建议使用绿色屋顶,而不是膨胀粘土屋顶或基础模型设计屋顶,以提高此类建筑的能源效率。这项工作有助于将绿色建筑组件融入建筑设计中,以提高能源效率,增强建筑的决策能力和可持续性。
BIM-based parametric energy analysis of green building components for the roofs and facades
Buildings are distinguished by their high energy demand over their lifespan. Iimproving energy efficiency in buildings necessitates mitigating the operation energy performance by evaluating more sustainable building components such as green infrastructures. The novelty herein is to conduct a BIM-based parametric energy analysis of green building components for the roofs and facades, taking into consideration the climate classification and orientation of the building. The proposed framework of this study uses Autodesk Revit software and Autodesk Green Building Studio as BIM tools, and Minitab software as a parametric analysis tool to estimate the energy performance of several alternative components based on Energy Use Intensity (EUI) and Annual Peak Demand (APD). A case study of a residential building is examined in four cities within different climate zones in Brazil; Rio de Janeiro (climate zone 08), Macaé (climate zone 05), Petrópolis (climate zone 03), and Nova Friburgo (climate zone 02). The base model design of components of the building includes a reinforced concrete roof and ceramic masonry façade. The utilized alternatives are roof components (i.e. green roofs and expanded clay roofs), and green façade. This work insight using green façade for all elevations and green roofs to enhance energy efficiency in terms of EUI by (10,17 %) in Rio de Janeiro, (6,67 %) in Macaé, (11,43 %) in Pertópolis, and (16,43 %) in Nova Friburgo. While the efficiency in terms of APD would be about (28,07 %) in Rio de Janeiro, (22,79 %) in Macaé, (21,67 %) in Pertópolis, and (12,58 %) in Nova Friburgo. When the construction project is designed to install a green façade to the main elevation only, this work recommends using green roofs rather than the expanded clay roof or the base model design roofs to increase energy efficiency in such types of buildings. This work contributes to integrating green building components into building designs to improve energy efficiency and empower decision-making and sustainability in buildings.
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