Effect of Wall, Roof, and Window-to-Wall Ratio on the Cooling and Heating Load of a Building in India

Asim Ahmad; Om Prakash; L. S. Brar; Kashif Irshad; S. M.Mozammil Hasnain; Prabhu Paramasivam; Abinet Gosaye Ayanie

doi:10.1002/ese3.2066

Effect of Wall, Roof, and Window-to-Wall Ratio on the Cooling and Heating Load of a Building in India

Asim Ahmad, Om Prakash, L. S. Brar, Kashif Irshad, S. M.Mozammil Hasnain^*, Prabhu Paramasivam^*, Abinet Gosaye Ayanie^*

^*Corresponding author for this work

Interdisciplinary Research Center for Sustainable Energy Systems

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

This study examines the impact of various combinations of walls, roofs, and window-to-wall ratios (WWRs) on the cooling and heating loads of residential buildings in India's composite climatic zone. Utilizing EnergyPlus and eQuest simulations, the thermal performance of three building types is analyzed across 32 cases involving two types of walls (W1, W2), roofs (R1, R2), and WWRs of 10%, 20%, 30%, and 40%. The results indicate that Case 29 (W2 R2 N2 WWR1), characterized by a north-facing orientation, square-shaped design, and a 10% WWR, achieves the lowest cooling and heating loads among all configurations. Specifically, in Building 1, this configuration reduces cooling loads by 26.0% (from 204 to 151 kBTU/h) and heating loads by 28.6% (from 224 to 160 kBTU/h) compared to the highest load scenario, Case 4 (W1 R1 N1 WWR4, west-facing orientation, square-shaped design, and 40% WWR). Similar trends are observed for Buildings 2 and 3. These findings underscore the critical role of optimizing building envelope parameters, particularly orientation, shape, and WWR, in achieving significant energy savings. The insights provided by this study can aid architects, engineers, and policymakers in designing energy-efficient residential buildings.

Original language	English
Pages (from-to)	1255-1279
Number of pages	25
Journal	Energy Science and Engineering
Volume	13
Issue number	3
DOIs	https://doi.org/10.1002/ese3.2066
State	Published - Mar 2025

Bibliographical note

Publisher Copyright:
© 2025 The Author(s). Energy Science & Engineering published by Society of Chemical Industry and John Wiley & Sons Ltd.

Keywords

building envelope
energy efficiency
heating and cooling loads
solar energy
window-to-wall ratio

ASJC Scopus subject areas

Safety, Risk, Reliability and Quality
General Energy

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1002/ese3.2066

Cite this

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title = "Effect of Wall, Roof, and Window-to-Wall Ratio on the Cooling and Heating Load of a Building in India",

abstract = "This study examines the impact of various combinations of walls, roofs, and window-to-wall ratios (WWRs) on the cooling and heating loads of residential buildings in India's composite climatic zone. Utilizing EnergyPlus and eQuest simulations, the thermal performance of three building types is analyzed across 32 cases involving two types of walls (W1, W2), roofs (R1, R2), and WWRs of 10\%, 20\%, 30\%, and 40\%. The results indicate that Case 29 (W2 R2 N2 WWR1), characterized by a north-facing orientation, square-shaped design, and a 10\% WWR, achieves the lowest cooling and heating loads among all configurations. Specifically, in Building 1, this configuration reduces cooling loads by 26.0\% (from 204 to 151 kBTU/h) and heating loads by 28.6\% (from 224 to 160 kBTU/h) compared to the highest load scenario, Case 4 (W1 R1 N1 WWR4, west-facing orientation, square-shaped design, and 40\% WWR). Similar trends are observed for Buildings 2 and 3. These findings underscore the critical role of optimizing building envelope parameters, particularly orientation, shape, and WWR, in achieving significant energy savings. The insights provided by this study can aid architects, engineers, and policymakers in designing energy-efficient residential buildings.",

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author = "Asim Ahmad and Om Prakash and Brar, \{L. S.\} and Kashif Irshad and Hasnain, \{S. M.Mozammil\} and Prabhu Paramasivam and Ayanie, \{Abinet Gosaye\}",

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AU - Prakash, Om

AU - Brar, L. S.

AU - Irshad, Kashif

AU - Hasnain, S. M.Mozammil

AU - Paramasivam, Prabhu

AU - Ayanie, Abinet Gosaye

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AB - This study examines the impact of various combinations of walls, roofs, and window-to-wall ratios (WWRs) on the cooling and heating loads of residential buildings in India's composite climatic zone. Utilizing EnergyPlus and eQuest simulations, the thermal performance of three building types is analyzed across 32 cases involving two types of walls (W1, W2), roofs (R1, R2), and WWRs of 10%, 20%, 30%, and 40%. The results indicate that Case 29 (W2 R2 N2 WWR1), characterized by a north-facing orientation, square-shaped design, and a 10% WWR, achieves the lowest cooling and heating loads among all configurations. Specifically, in Building 1, this configuration reduces cooling loads by 26.0% (from 204 to 151 kBTU/h) and heating loads by 28.6% (from 224 to 160 kBTU/h) compared to the highest load scenario, Case 4 (W1 R1 N1 WWR4, west-facing orientation, square-shaped design, and 40% WWR). Similar trends are observed for Buildings 2 and 3. These findings underscore the critical role of optimizing building envelope parameters, particularly orientation, shape, and WWR, in achieving significant energy savings. The insights provided by this study can aid architects, engineers, and policymakers in designing energy-efficient residential buildings.

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Effect of Wall, Roof, and Window-to-Wall Ratio on the Cooling and Heating Load of a Building in India

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

UN SDGs

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