<p>The current study aims to evaluate the energy performance of library-type buildings considering cold winter and hot summer climate regimes. In order to ascertain the energy performance of the building, a series of shading elements and their orientations were designated as design parameters. BIM-based Revit and DesignBuilder software were used to model, simulate, visualize, and evaluate the energy efficiency of the building. In addition to the current condition of the building, three distinct types of shading elements and eight distinct orientations were considered in the current study. A total of 32 distinct models were thus created and subjected to simulation. By comparing and evaluating the simulation results, a new model was developed by adapting adaptive facade shading elements that will provide optimum energy performance. It has been revealed that this adaptable facade shading element system developed in this direction will save 12.50% in heating load, 15.90% in cooling load and 14.50% in total energy load. In addition, it has been concluded that a 79.79% saving in the initial construction cost can be achieved with this adaptable system proposed to replace the existing facade element, which was built at a cost of $63,903.10 during the construction process.</p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

BIM-BES-based energy performance simulation of library-type buildings considering cold winter/hot summer climate regime with passive strategies

  • Dilek Aybek Özdemir,
  • Gonca Özer Yaman,
  • İbrahim Halil Şeker,
  • Süleyman İpek

摘要

The current study aims to evaluate the energy performance of library-type buildings considering cold winter and hot summer climate regimes. In order to ascertain the energy performance of the building, a series of shading elements and their orientations were designated as design parameters. BIM-based Revit and DesignBuilder software were used to model, simulate, visualize, and evaluate the energy efficiency of the building. In addition to the current condition of the building, three distinct types of shading elements and eight distinct orientations were considered in the current study. A total of 32 distinct models were thus created and subjected to simulation. By comparing and evaluating the simulation results, a new model was developed by adapting adaptive facade shading elements that will provide optimum energy performance. It has been revealed that this adaptable facade shading element system developed in this direction will save 12.50% in heating load, 15.90% in cooling load and 14.50% in total energy load. In addition, it has been concluded that a 79.79% saving in the initial construction cost can be achieved with this adaptable system proposed to replace the existing facade element, which was built at a cost of $63,903.10 during the construction process.