Abstract
The Energy Performance of Building Directive obligated all European countries to reduce the energy requirements of buildings while simultaneously improving indoor environment quality. Any such improvements not only enhance the health of the occupants and their productivity, but also provide further economic benefits at the national level. Accomplishing this task requires a method that allows building professionals to resolve conflicts between visual and thermal comfort, energy demands, and life-cycle costs. To overcome these conflicts, this study exploits the incorporation of building information modelling (BIM), the design of experiments as an optimization algorithm, and the analytical hierarchy process (AHP) into a multi-criteria decision-making method. Any such incorporation can (i) create constructive communication between building professionals, such as architects, engineers, and energy experts; (ii) allow the analysis of the performance of multiple construction solutions with respect to visual and thermal comfort, energy demand, and life-cycle costs; and (iii) help to select a trade-off solution, thereby making a suitable decision. Three types of energy-efficient windows, and five types of ground floors, roofs, and external wall constructions were considered as optimization variables. The incorporation of several methods allowed the analysis of the performance of 375 construction solutions based on a combination of optimization variables, and helped to select a trade-off solution. The results showed the strength of incorporation for analyzing big-data through the intelligent use of BIM and a simulation in the field of the built environment, energy, and costs. However, when applying AHP, the results are strongly contingent on pairwise comparisons.
Highlights
The Energy Performance of Building Directive (EPBD) obligated all European countries to ensure that nearly-zero-energy codes were the norm for the construction of new buildings while fulfilling the minimum indoor comfort requirements at the national level [1]
The first part of the results describes the variation in the criteria among 375 construction solutions, while the second part presents and compares the trade-off construction solutions found while applying analytical hierarchy process (AHP)
The incorporation of building information modeling, experimental design, and an analytical hierarchy process allowed the analysis of the performance of 375 construction solutions, and the selection of a solution based on a trade-off among visual comfort, thermal comfort, energy demand, and life-cycle costs
Summary
The Energy Performance of Building Directive (EPBD) obligated all European countries to ensure that nearly-zero-energy codes were the norm for the construction of new buildings while fulfilling the minimum indoor comfort requirements at the national level [1]. A simultaneous decrease in energy demand and costs, while improving the indoor environmental quality, requires constructive communication between building professionals At this point, Building Information Modelling (BIM) provides a useful platform for sharing information, which streamlines communications and coordinates collaboration between building professionals, including architects, engineers, and energy experts [9,10]. Rahmani Asl, Stoupine, Zarrinmehr and Yan [10] developed a framework based on the incorporation of BIM and an optimization algorithm They validated the framework by selecting a construction solution based on a trade-off between visual comfort and energy demand for a single detached dwelling in the U.S Sandberg, Mukkavaara, Shadram and Olofsson [14] exploited a combination of BIM and an optimization algorithm to select a construction solution based on a trade-off between total energy demand and life-cycle costs for a multifamily residential dwelling in Sweden
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