Strategic design of wall envelopes for the enhancement of building thermal performance at reduced air-conditioning costs
- Authors
- Saboor, Shaik; Chelliah, Arumugam; Gorantla, Kiran Kumar; Kim, Ki-Hyun; Lee, S. -H.; Shon, Zang Ho; Brown, Richard J. C.
- Issue Date
- Feb-2021
- Publisher
- Academic Press
- Keywords
- Energy-efficient wall design; Attenuation factor; Decrement lag; Annual energy; Life cycle
- Citation
- Environmental Research, v.193, pp 1 - 12
- Pages
- 12
- Indexed
- SCIE
SCOPUS
- Journal Title
- Environmental Research
- Volume
- 193
- Start Page
- 1
- End Page
- 12
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/8011
- DOI
- 10.1016/j.envres.2020.110577
- ISSN
- 0013-9351
1096-0953
- Abstract
- A strategy is proposed for the design of wall envelopes to improve unsteady thermal performance in non -airconditioned buildings and to reduce energy costs in air-conditioned buildings. The thermophysical properties of building materials (e.g., burnt bricks, mud bricks, laterite stone, cinder concrete, and expanded polystyrene) were measured experimentally using a thermal analyzer. A total of 28 combinations for composite walls were designed with expanded polystyrene as an insulation material based on seven criteria and were subjected to 8 different external surface heat transfer coefficients, which were tested for unsteady thermal performance parameters and air-conditioning cost-saving potential. In this paper, unsteady thermal transmittance obtained from admittance method has been employed to compute cost saving potential of air-conditioning for the various wall envelopes. The use of C-H-5 design at a 2 m/s wind speed was found to increase the decrement lag of burnt brick, mud brick, laterite stone, and cinder concrete composite wall envelopes by 48.1%, 49.0%, 59.5%, and 47.0%, respectively, relative to the common wall design (C-H1) in non-air-conditioned buildings. The laterite with a C-H-5 design offers the highest annual energy cost savings (1.71 $/m(2) at 2 m/s), the highest life cycle cost savings (18.32 $/m(2) at 2 m/s), and the lowest payback period (4.03 yrs at 2 m/s) in all tested building materials for airconditioned buildings. The overall results of this study are expected to open new paths to deliver simple design strategies for energy-efficient buildings.
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