Optimization of Wall Thickness Based on a Comprehensive Evaluation Index of Thermal Mass and Insulation

Yu, Shen-Wei; Hao, Shimeng; Mu, Jun; Tian, Dongwei

doi:10.3390/su14031143

Cited by 8 publications

(1 citation statement)

References 21 publications

(26 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Moreover, even though their time lag and decrement factor were not the same, insulation positions resembled yearly loads and ideal insulation thickness. Yu, S et al (2022) conducted theoretical research to investigate the link between wall insulation and thermal mass and find a balance between wall thermal performance and energy consumption. Using five different materials with varying thicknesses and climates, tracking and analyzing the effects of 4 factors: heat transfer coefficient, thermal inertia index, attenuation degree, and delay time.…”

Section: Literature Reviewmentioning

confidence: 99%

Energy efficiency of a house in Mediterranean region: insulation and glazing impact

Jaouaf,

Bensaad,

Dorbane

2024

J. Eng. Exact Sci.

View full text Add to dashboard Cite

The insulation of a building's envelope is critical for reducing energy consumption, enhancing indoor thermal comfort, and achieving sustainable development goals. This theoretical work focused on the energy and thermal aspect of insulators and glazing to determine the optimal thermal insulation and the best glazing for the building envelope in the Mediterranean region where the province of Ain Temouchent, Algeria, was taken in this study. This study evaluated the effectiveness of insulation materials, which are expanded polystyrene, glass wool, rock wool, and wood fiber of varying thicknesses, and glazing in the Algerian market. The TRNSYS 17 software is used to simulate the building's behavior. The study finds that wood fiber insulation with a 9 cm thickness provides the best thermal performance, resulting in a 26% reduction in energy costs compared to 3cm of expanded polystyrene. Furthermore, upgrading from single to double glazing can reduce heating and cooling costs by 23% and 10%, respectively, demonstrating the importance of proper insulation and glazing in achieving energy efficiency, and enhancing indoor thermal comfort for occupants. In conclusion, this study provides valuable findings for designing energy-efficient buildings with optimal thermal insulation and glazing. Future research should explore broader factors affecting building performance, such as the long-term performance and durability of materials in varying climates and building designs, as well as the impact of occupancy and building orientation. Although the study acknowledges its limited examination of factors and options, it still provides valuable insights into building performance with insulation and glazing.

show abstract

Section: Literature Reviewmentioning

confidence: 99%