Articles | Open Access | DOI: https://doi.org/10.37547/tajas/Volume07Issue03-05A

Energy Efficiency and Integration of Renewable Energy Sources in Architectural Design: Techno-Economic Possibilities of Azerbaijan

Karimli Tofig Rafig , TKProject Azerbaijan, Baku, 1005

Abstract

This article analyzes the technical and economic feasibility of integrating energy-efficient solutions and renewable energy sources (RES) into architectural design in Azerbaijan. The study begins by examining the current state of Azerbaijan's energy sector, which is heavily reliant on natural gas-fired thermal power plants, despite having substantial solar and wind energy potential. The primary aim is to identify optimal strategies for designing energy-efficient buildings in Azerbaijan, considering climatic conditions, available technologies, and economic factors. The methodology involves a multi-faceted approach: a review of passive and active energy efficiency strategies applicable to architectural design (including volumetric planning, natural lighting/ventilation, thermal insulation, shading, efficient HVAC, heat recovery, and Building Management Systems (BMS)); an assessment of Azerbaijan's solar and wind energy potential; and a multi-criteria SWOT analysis. Results indicate a significant, untapped potential for solar (23,000 MW) and wind (3,000 MW onshore, 157 GW offshore) energy in Azerbaijan. The SWOT analysis highlights the strong government support and favorable climate as major strengths, while acknowledging the current low RES penetration and a shortage of skilled professionals as weaknesses. Opportunities include declining global RES technology costs and a growing demand for "green" buildings. Threats include competition from the established fossil fuel sector and potential climate risks. The main conclusion is that integrating RES and energy-efficient design is not only technically feasible but also strategically vital for Azerbaijan's sustainable development, energy security, and environmental protection. Recommendations are formulated to develop an effective strategy for RES integration, focusing on supportive policies, capacity building, financial incentives, and public awareness campaigns. The findings contribute to the field of sustainable architecture by providing a context-specific analysis and practical guidance for architects, engineers, and policymakers in Azerbaijan and similar regions transitioning to a low-carbon energy future. The study's limitations include the reliance on publicly available data and the dynamic nature of energy policy, which requires ongoing monitoring and adaptation of strategies. The practical implications emphasize the need for updated building codes, training programs, and financial mechanisms to promote widespread adoption of energy-efficient and RES-integrated building designs.

Keywords

renewable energy sources, energy efficiency, architectural design, sustainable construction, SWOT analysis

References

Diakaki, C.; Grigoroudis, E.; Kolokotsa, D. Towards a Multi-Objective Optimization Approach for Improving Energy Efficiency in Buildings. Energy and Buildings, 40(9), 1747–1754, 2008. DOI: 10.1016/j.enbuild.2008.03.002

Report.az. WB is Ready to Provide Financial Support to Improve Energy Efficiency of Buildings in Azerbaijan. Report.az. https://report.az/ru/energetika/vb-gotov-okazat-finansovuyu-podderzhku-dlya-povysheniya-energoeffektivnosti-zdanij-v-azerbajdzhane/ (accessed Dec 5, 2024).

Official website of the President of the Republic of Azerbaijan. Ilham Aliyev Took Part in the Opening of the 220-Kilovolt Agdash Electrical Substation. President.az. https://president.az/ru/articles/view/11626 (accessed Dec 5, 2024).

Day.Az. "Azerenergy" Plans to Expand Electricity Exports. Day.Az. https://news.day.az/economy/1418775.html (accessed Dec 5, 2024).

Day.Az. The Khizi-Absheron Wind Farm Will Become the Largest in Azerbaijan. Day.Az. https://news.day.az/economy/1426479.html (accessed Dec 5, 2024).

Day.Az. New Programs Related to "Green" Energy Will Be Implemented in Azerbaijan. Day.Az. https://news.day.az/economy/1472612.html (accessed Dec 5, 2024).

EES EAEC. Energy Profile of Azerbaijan. EES EAEC. https://www.eeseaec.org/energeticeskij-profil-azerbajdzana (accessed Dec 5, 2024).

Ministry of Energy of the Republic of Azerbaijan. Report of the Ministry of Energy of the Republic of Azerbaijan for 2021. Ministry of Energy of the Republic of Azerbaijan. https://minenergy.gov.az/uploads/Hesabatlar/illik/Hesabat_2021.pdf (accessed Dec 5, 2024).

Ministry of Energy of the Republic of Azerbaijan. Report of the Ministry of Energy of the Republic of Azerbaijan for 2022. Ministry of Energy of the Republic of Azerbaijan. https://minenergy.gov.az/uploads/Hesabatlar/son%20son-Hesabat%20NK%202022_v7.pdf (accessed Dec 5, 2024).

Day.Az. Project for Transition to "Green" Energy Will Also Affect the Social Sphere. Day.Az. https://news.day.az/economy/1418784.html (accessed Dec 5, 2024).

President.az. Ilham Aliyev Attended the Plenary Session on the Signing of the Agreement on Strategic Partnership in the Field of Green Energy in Bucharest. President.az. https://president.az/ru/articles/view/58221 (accessed Dec 5, 2024).

IRENA. Renewable Power Generation Costs in 2020. IRENA. https://www.irena.org/publications/2021/Jun/Renewable-Power-Costs-in-2020 (accessed Dec 5, 2024).

Day.Az. Azerbaijan, Georgia, Romania and Hungary Will Sign an Agreement on "Green" Energy. Day.Az. https://news.day.az/economy/1520162.html (accessed Dec 5, 2024).

Day.Az. The Foundation Stone Laying Ceremony of the Shafag Solar Power Plant Took Place. Day.Az. https://news.day.az/economy/1706416.html (accessed Dec 5, 2024).

Day.Az. Azerbaijan and Turkey Signed an Agreement on the Restoration of 5 Small Hydropower Plants. Day.Az. https://news.day.az/economy/1625443.html (accessed Dec 5, 2024).

President.az. Ilham Aliyev Attended the Groundbreaking Ceremony of the Khizi-Absheron Wind Farm. President.az. https://president.az/ru/articles/view/55248 (accessed Dec 5, 2024).

President.az. Ilham Aliyev Inaugurated the Jahangirbeyli and Sarygyshlag Hydropower Plants of AzerEnergy OJSC. President.az. https://president.az/ru/articles/view/65891 (accessed Dec 5, 2024).

Bajcinovci, B.; Jerliu, F. Achieving Energy Efficiency in Accordance with Bioclimatic Architecture Principles. Rigas Tehniskas Universitates Zinatniskie Raksti, 18, 54, 2016. (No DOI found, and journal may not have volume/issue numbers in the same way as Western journals)

Ameur, M.; Kharbouch, Y.; Mimet, A. Optimization of Passive Design Features for a Naturally Ventilated Residential Building According to the Bioclimatic Architecture Concept and Considering the Northern Morocco Climate. In Building Simulation; Tsinghua University Press: 2020; Vol. 13, pp 677–689. DOI: 10.1007/s12273-019-0590-y

Latha, H.; Patil, S.; Kini, P. G. Influence of Architectural Space Layout and Building Perimeter on the Energy Performance of Buildings: A Systematic Literature Review. International Journal of Energy and Environmental Engineering, 14(3), 431–474, 2023. DOI: 10.1007/s40095-023-00538-8

Tzoulis, A. Performance Assessment of Building Energy Modelling Programs and Control Optimization of Thermally Activated Building Systems. PhD Thesis, 2014. (No DOI found, format adapted for thesis)

Al Ka’bi, A. H. Comparison of Energy Simulation Applications Used in Green Building. Annals of Telecommunications, 75(7), 271–290, 2020. DOI: 10.1007/s12243-019-00738-9

Salgado-Conrado, L.; Lopez-Montelongo, A.; Alvarez-Macias, C.; Hernadez-Jaquez, J. Review of Heliodon Developments and Computational Tools for Building Shadow Analysis. Buildings, 12(5), 627, 2022. DOI: 10.3390/buildings12050627

Mandalaki, M.; Tsoutsos, T. Solar Shading Systems: Design, Performance, and Integrated Photovoltaics; Springer: Berlin/Heidelberg, Germany, 2020. DOI: 10.1007/978-3-030-29746-3

Gherri, B. Assessment of Daylight Performance in Buildings: Methods and Design Strategies; WIT press: 2015. (No DOI found, format for book)

Mangkuto, R. A.; Rohmah, M.; Asri, A. D. Design Optimization for Window Size, Orientation, and Wall Reflectance with Regard to Various Daylight Metrics and Lighting Energy Demand: A Case Study of Buildings in the Tropics. Applied Energy, 164, 211–219, 2016. DOI: 10.1016/j.apenergy.2015.10.181

Gilvaei, Z. M.; Poshtiri, A. H.; Akbarpoor, A. M. A Novel Passive System for Providing Natural Ventilation and Passive Cooling: Evaluating Thermal Comfort and Building Energy. Renewable Energy, 198, 463–483, 2022. DOI: 10.1016/j.renene.2022.08.061

Mariano-Hernández, D.; Hernández-Callejo, L.; Zorita-Lamadrid, A.; Duque-Pérez, O.; García, F. S. A Review of Strategies for Building Energy Management System: Model Predictive Control, Demand Side Management, Optimization, and Fault Detect & Diagnosis. Journal of Building Engineering, 33, 101642, 2021. DOI: 10.1016/j.jobe.2020.101642

Olatunde, T. M.; Okwandu, A. C.; Akande, D. O.; Sikhakhane, Z. Q. Review of Energy-Efficient HVAC Technologies for Sustainable Buildings. International Journal of Science and Technology Research Archive, 6(02), 12–20, 2024. (No DOI found, best effort for journal format)

Kudela, L.; Špiláček, M.; Pospíšil, J. Influence of Control Strategy on Seasonal Coefficient of Performance for a Heat Pump with Low-Temperature Heat Storage in the Geographical Conditions of Central Europe. Energy, 234, 121276, 2021. DOI: 10.1016/j.energy.2021.121276

Salhein, K.; Kobus, C. J.; Zohdy, M. Control of Heat Transfer in a Vertical Ground Heat Exchanger for a Geothermal Heat Pump System. Energies, 15(14), 5300, 2022. DOI: 10.3390/en15145300

Hosseini, S. E.; Wahid, M. A. Hydrogen from Solar Energy, a Clean Energy Carrier from a Sustainable Source of Energy. International Journal of Energy Research, 44(6), 4110–4131, 2020. DOI: 10.1002/er.5027

Garg, R. B.; Singh, G. Energy-Efficient Design Strategies for Buildings: Lessons from High-Performance Buildings. In Handbook of Digital Innovation, Transformation, and Sustainable Development in a Post-Pandemic Era; CRC Press: 2025; pp 185–211. DOI: 10.1201/9781003441453-11

Zhang, C.; Pomianowski, M.; Heiselberg, P. K.; Yu, T. A Review of Integrated Radiant Heating/Cooling with Ventilation Systems-Thermal Comfort and Indoor Air Quality. Energy and Buildings, 223, 110158, 2020. DOI: 10.1016/j.enbuild.2020.110158

Picallo-Perez, A.; Sala-Lizarraga, J. M.; Odriozola-Maritorena, M.; Hidalgo-Betanzos, J. M.; Gomez-Arriaran, I. Ventilation of Buildings with Heat Recovery Systems: Thorough Energy and Exergy Analysis for Indoor Thermal Wellness. Journal of Building Engineering, 39, 102255, 2021. DOI: 10.1016/j.jobe.2021.102255

Zocchi, G.; Hosseini, M.; Triantafyllidis, G. Exploring the Synergy of Advanced Lighting Controls, Building Information Modelling and Internet of Things for Sustainable and Energy-Efficient Buildings: A Systematic Literature Review. Sustainability, 16(24), 10937, 2024. DOI: 10.3390/su162410937

Martirano, L.; Ruvio, A.; Manganelli, M.; Lettina, F.; Venditti, A.; Zori, G. High-Efficiency Lighting Systems with Advanced Controls. IEEE Transactions on Industry Applications, 57(4), 3406–3415, 2021. DOI: 10.1109/TIA.2021.3074293

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Karimli Tofig Rafig. (2025). Energy Efficiency and Integration of Renewable Energy Sources in Architectural Design: Techno-Economic Possibilities of Azerbaijan. The American Journal of Applied Sciences, 7(03), 27–44. https://doi.org/10.37547/tajas/Volume07Issue03-05A