Enhancement of the Potential of Exterior Louvre Shadings for Internal Daylight Distribution and Space Visual Quality in Isfahan City, Iran

Esfandiari, Akram; Neshat Safavi, Seyed Hossein; Touran Poshti, Fahimeh; Majidihatkehlouei, Sahar; Haghani, Mahsa; Hosseini, Sayed Behshid

doi:10.22034/bagh.2024.418024.5458

Enhancement of the Potential of Exterior Louvre Shadings for Internal Daylight Distribution and Space Visual Quality in Isfahan City, Iran

https://doi.org/10.22034/bagh.2024.418024.5458

Volume 21, Issue 133
July 2024

Pages 5-20

The Monthly Scientific Journal of Bagh-e Nazar

Document Type : Original Research Article

Authors

Akram Esfandiari ¹

Seyed Hossein Neshat Safavi ²

Fahimeh Touran Poshti ³

Sahar Majidihatkehlouei ¹

Mahsa Haghani ¹

Sayed Behshid Hosseini ⁴

¹ Lecturer, Department of Architecture, Faculty of Architecture and Urbanism, Technical and Vocational University (TVU), Tehran, Iran.

² Researcher, Architectural Engineering Department, Architecture and Urbanism Faculty, Imam Khomeini International University, Qazvin, Iran.

³ Lecturer, Department of Architecture, Faculty of Architecture and Urbanism, Art University, Iran, Tehran.

⁴ Professor, Department of Architecture, Faculty of Architecture and Urbanism, Art University, Iran, Tehran.

Abstract

Problem statement: The importance of visual comfort in buildings lies in its profound impact on the well-being and productivity of occupants. This architectural aspect would be more noticeable in educational space which can be achieved through utilizing appropriate daylight strategies. Shading elements can be utilized to enhance visual quality and optimize daylight distribution, leading to a more pleasant and productive environment for occupants.
Research objective: This research focuses on examining the physical properties of slats for external horizontal louvres for four façade orientations of an educational case study with a north-south direction in Esfahan City, Iran to enhance the daylight and space visual comfort performance.
Research method: The daylight factor and visual quality metrics, namely the Maximum radial line and the Isovist area are investigated as research objectives. Also, the reflection coefficient of materials louvre slats, the depth of slats, and the distance between them are considered independent variables. The literature studies were scrutinized and field measurements by Lux Meter, climate analysis by Climate Consultant 5. 4 software as well and computer simulations via Relux and Isovist tool on depth map software were utilized to investigate the set research objectives.
Conclusion: The results indicate that advising a specific design of louvre shading parameters for each façade orientation is recommended for a particular climate. Additionally, materials with an 80 percent reflectivity coefficient are deemed suitable to achieve a balance between daylight factor distribution and visual quality metrics for building occupants.

Keywords

Educational Space

Daylight Factor

Visual Quality

Shading Element

Relux Lighting Software

Isovist Tool

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