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American Journal of Environmental Protection
ISSN (Print): 2328-7241 ISSN (Online): 2328-7233 Website: https://www.sciepub.com/journal/env Editor-in-chief: Mohsen Saeedi, Hyo Choi
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American Journal of Environmental Protection. 2025, 13(1), 1-8
DOI: 10.12691/env-13-1-1
Open AccessArticle

Early-Stage Design Optimization of Primary School Building’s Geometry with Reference to Energy Performance

Zahra Hoseini1, and Seyed Majid Mofidi Shemirani2

1Iran University of Science and Technology, School of Architecture and Environmental Design, Tehran, Iran

2Assistant Professor, Iran University of Science and Technology, School of Architecture and Environmental Design, Tehran, Iran

Pub. Date: February 19, 2025
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Cite this paper:
Zahra Hoseini and Seyed Majid Mofidi Shemirani. Early-Stage Design Optimization of Primary School Building’s Geometry with Reference to Energy Performance. American Journal of Environmental Protection. 2025; 13(1):1-8. doi: 10.12691/env-13-1-1

Abstract

Since the early stages of design have the most important impact on building performance and general decisions regarding the geometry of the building are made at this stage, this article deals with energy optimization in the initial stages of design. This research aims to provide a method to help architects find the proper geometry of the building to reduce energy consumption in the initial design steps. In this article, a parametric generative model, which was created in the Grasshopper plugin environment in Rhino, is used. Here, the determining variables of the building geometry include the orientation, WWR, and the shape composition of the building form, then the Honeybee plugin is used to calculate the Energy Use Intensity (EUI) and find the optimal geometry. In general, in this research, the optimal form of the building mainly has a rectangular or square plan, and the forms with a large contact surface with the surrounding environment have been recognized as inappropriate, in addition to that, the optimal orientation is variable based on two other parameters and is mostly 0 or 15. The WWR for the top models was mostly 20 and in sometimes 30. Generally, in this research, the lowest EUI of 93.18 kWh/m2 and the highest EUI of 125.93 kWh/m2 were reported, which indicates a difference of about 32% in the amount of energy consumption of different geometries for an educational building in this context. The results show that architects can use the method adopted in this article as an effective method to reduce building energy consumption in the early stages of design.

Keywords:
optimization form finding energy consumption early-stage design

Creative CommonsThis work is licensed under a Creative Commons Attribution 4.0 International License. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/

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