Building information modelling (BIM) is the first step towards the implementation of the industrial revolution 4.0, in which virtual reality and digital twins are key elements. At present, buildings are responsible for 40% of the energy consumption in Europe and, so, there is a growing interest in reducing their energy use. In this context, proper interoperability between BIM and building energy model (BEM) is paramount for integrating the digital world into the construction sector and, therefore, increasing competitiveness by saving costs. This paper evaluates whether there is an automated or semi-automated BIM to BEM workflow that could improve the building design process. For this purpose, a residential building and a warehouse are constructed using the same BIM authoring tool (Revit), where two open schemas were used: green building extensible markup language (gbXML) and industry foundation classes (IFC). These transfer files were imported into software compatible with the EnergyPlus engine—Design Builder, Open Studio, and CYPETHERM HE—in which simulations were performed. Our results showed that the energy models were built up to 7.50% smaller than in the BIM and with missing elements in their thermal envelope. Nevertheless, the materials were properly transferred to gbXML and IFC formats. Moreover, the simulation results revealed a huge difference in values between the models generated by the open schemas, in the range of 6 to 900 times. Overall, we conclude that there exists a semi-automated workflow from BIM to BEM which does not work well for big and complex buildings, as they present major problems when creating the energy model. Furthermore, most of the issues encountered in BEM were errors in the transfer of BIM data to gbXML and IFC files. Therefore, we emphasise the need to improve compatibility between BIM and model exchange formats by their developers, in order to promote BIM–BEM interoperability.
Los autores del artículo trabajan en la integración de la termoelectricidad en fachadas desde el año 2009. El objeto de este artículo es revisar las posibilidades que esta tecnología ofrece para su incorporación como sistema de climatización de edificios, centrándose en la descripción y análisis del comportamiento del último prototipo realizado dentro de un proyecto de investigación. Para ello, se describen los criterios de diseño y los componentes necesarios para su montaje, aspectos en los que ha tenido especial importancia la reducción del puente térmico respecto a prototipos anteriores. Se explica la metodología experimental seguida, los ensayos realizados, y se analizan críticamente los resultados. Las conclusiones plantean mejoras y recomendaciones para implementar en futuros desarrollos.
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