Net zero energy residential architecture in hot-humid climate regions: Design principles and feasibility analysis
Abstract
This study presents the development of a Net Zero Energy Building (NZEB) design guide specifically tailored for new buildings to be constructed in Turkey’s hot-humid climate zone, along with analyses and evaluations regarding the functioning of this guide. Within the scope of the study, a design guideline for NZEBs was created by establishing design decision steps involving passive design strategies, passive systems, active systems, and energy generation systems specific to the hot-humid climate zone. Antalya, a city located within this climatic region, was selected as the case study area. Based on the design decision steps outlined in the guide, a detached single-family residence was designed, and energy simulation analyses were conducted using the DesignBuilder software to evaluate the efficiency of the proposed systems. As a result of these evaluations, the most energy-efficient system for each parameter was selected, thereby minimizing the building’s energy demand while ensuring the necessary indoor comfort conditions. In the final stage, photovoltaic panels were installed on the roof of the building to meet the remaining energy demand through solar energy, achieving compliance with the NZEB standard.
Keywords
References
- [1] IEA (International Energy Agency). Energy efficiency 2021 – analysis and outlooks to 2030. International Energy Agency, Paris, France, 2021.
- [2] Attia S, Gratia E, Herde AD, Hensen J. Simulation-based decision support tool for early stages of zero-energy building design. Energy and Buildings 2012; 49: 2–15.
- [3] Olgyay V. Design with climate: bioclimatic approach to architectural regionalism. Princeton University Press, Princeton, NJ, US, 2015.
- [4] Szokolay SV. Introduction to architectural science: the basis of sustainable design. Architectural Press, Oxford, UK, 2008.
- [5] Hyde R. Climate responsive design: a study of buildings in moderate and hot humid climates. Taylor & Francis, London, UK, 2000.
- [6] Steemers K. Energy and the city: density, buildings and transport. Energy and Buildings 2003; 35: 3–14.
- [7] Givoni B. Climate considerations in building and urban design. John Wiley & Sons, New York, US, 1998.
- [8] Barnett L, Barnett M. The passivhaus handbook: a practical guide to constructing and retrofitting energy-efficient homes. Green Books, Totnes, UK, 2017.
Details
Primary Language
English
Subjects
Energy
Journal Section
Research Article
Publication Date
June 30, 2026
Submission Date
March 14, 2026
Acceptance Date
June 3, 2026
Published in Issue
Year 2026 Volume: 11 Number: 2