Envisioning How to Improve Natural Light Flow and Energy Saving in Learning Spaces: A Case Study of an Engineering Drawing Room in a Semi-Desert Area | ||||
| International Design Journal | ||||
| Article 18, Volume 15, Issue 5 - Serial Number 68, September and October 2025, Page 261-274 PDF (1.79 MB) | ||||
| Document Type: Original Article | ||||
| DOI: 10.21608/idj.2025.389352.1339 | ||||
 View on SCiNiTO | ||||
| Authors | ||||
Sherif Ahmed  1; Islam Mohamed Hamed2
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| 1Department of architecture, Faculty of Engineering, High Institute of Engineering-15May, Cairo-15 may, Egypt | ||||
| 2Department of architecture, Faculty of engineering, High Institute of Engineering-15-May,Cairo-15 May, Egypt | ||||
| Abstract | ||||
| This study aims to highlight the importance of focusing on natural lighting in educational spaces, by focusing on increasing visual density and reducing energy consumption, thus contributing to the achievement of development goals. The study focused on the Engineering Drawing Room at the Higher Institute of Arts in 15th of May City, addressing the problem of uneven natural light distribution in the classrooms. A digital panel simulation approach was used using VELUX Daylight Visualizer to study current lighting recommendations and test three scenarios: the current design, increasing window density by 30%, and integrating the Himawari Daylighting System with the removal of pendants. Light distribution was evaluated at ten measurement points under different optional settings. Significant variations in lighting ranges were observed within the indicators, with close indicators and insufficient lighting in areas. Vascular dilation enhances brightness closer to different tissues. In contrast, the Himauri system demonstrated a relative improvement in providing contrasting lighting across the language range, with a mean of 502.1 kd/m² and a minimum of 150 kd/m², while reducing heat gain. The study confirms the limitations of traditional daylighting trends and calls for the development of advanced performance-based solutions that combine architectural and technical requirements. These results provide an effective framework for enhancing the environmental performance of educational buildings, particularly in rehabilitated buildings, and a guide to preferential guidelines for constructing better visual and energy-efficient built environments. | ||||
| Keywords | ||||
| Natural light efficiency; sustainable educational architecture; energy reduction; fiber optics; passive lighting solutions | ||||
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Supplementary Files
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| References | ||||
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