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Pasif Güneş Enerjili Havalandırma Yöntemi Olarak Güneş Bacasının Binalarda Kullanımının Örnekler Üzerinden İrdelenmesi

Year 2023, , 624 - 644, 20.12.2023
https://doi.org/10.47495/okufbed.1281430

Abstract

Basit ve pratik bir pasif güneş enerjili havalandırma ve soğutma sistemi olarak güneş bacaları; işletme maliyetinin azlığı, enerji gereksiniminin sıfıra yakın oluşu ve karbondioksit emisyonuna olumlu katkısı nedeniyle hem ticari binalarda hem de konutlarda ısı yükünü azaltmak, doğal serinletme, havalandırma veya ısıtma sağlamak adına büyük ilgi görmektedir. Bu çalışmada pasif güneş enerjili sistemler ile ilgili kısa bir bilgi verildikten sonra pasif havalandırma ve mekân ısıtmasında kullanılan güneş bacalarının binalardaki kullanım yöntemlerine dair bilgiler verilmiş çalışma prensibi, katmanları ve sınıflandırılması detaylı olarak anlatılmıştır. Son olarak pasif havalandırma ve serinletme amacıyla güneş bacası kullanımları üzerine yapılmış örnekler incelenerek değerlendirilmiştir.

Supporting Institution

Dokuz Eylül Üniversitesi Bilimsel Araştırma Projeleri Koordinasyon Birimi

Project Number

2020.KB.FEN.012

Thanks

Bu çalışma Dokuz Eylül Üniversitesi Bilimsel Araştırma Projeleri Koordinasyon Birimi tarafından 2020.KB.FEN.012 nolu proje kapsamında desteklenmiştir.

References

  • Abdeen A., Serageldin AA., Ibrahim MG., El-Zafarany A., Ookawara S., Murata R. Solar chimney optimization for enhancing thermal comfort in Egypt: An experimental and numerical study. Solar Energy 2019; 180: 524-536.
  • Awbi HB. Ventilation of buildings (Second ed.). Spon Press 2003. Londra.
  • Bassiouny R., Korah, NS. Effect of solar chimney inclination angle on space flow pattern and ventilation rate. Energy and Buildings 2009; 41(2): 190-196.
  • Bevilacqua P., Benevento F., Bruno R., Arcuri N. Are trombe walls suitable passive systems for the reduction of the yearly building energy requirements?. Energy 2019; 185: 554-566.
  • Boero A., Agyenim F. Modeling and simulation of a small-scale solar-powered absorption cooling system in three cities with a tropical climate. International Journal of Low-Carbon Technologies 2020; 15(1): 1-16.
  • Bong CPC., Lim LY., Ho WS., Lim JS., Klemeš JJ., Towprayoon S., Lee CT. A review on the global warming potential of cleaner composting and mitigation strategies. Journal of Cleaner Production 2017; 146: 149-157.
  • British Petroleum, bp Statistical Review of World Energy 2022; 71st edition, BP 2022. Londra.
  • Charvat P., Jicha M., Stetina J. Solar chimneys for residential ventilation. Ventilation and Retrofitting 2004; 19.
  • Cabeza LF., Chàfer M. Technological options and strategies towards zero energy buildings contributing to climate change mitigation: A systematic review. Energy and Buildings 2020; 219: 110009.
  • Cuce E., Cuce PM., Carlucci S., Sen H., Sudhakar K., Hasanuzzaman M., Daneshazarian R. Solar chimney power plants: A review of the concepts, designs and performances. Sustainability 2022; 14(3): 1450.
  • Dickinson EW. Solar energy technology handbook. CRC Press 2018.
  • Dimoudi A. Solar chimneys in buildings-The state of the art. Advances in Building Energy Research 2009; 3(1): 21-44.
  • Duy TN., Pham HTT. CFD based investigation on the performance of solar chimney for room natural ventilation. AIP Conference Proceedings 2021; 2420(1): 020027.
  • Goel M., Verma VS., Tripathi NG. Solar cooling technologies. In Solar Energy (pp. 107-116). Springer 2022. Singapore.
  • Godoy-Vaca L., Almaguer M., Martínez J., Lobato A., Palme M. Analysis of solar chimneys in different climate zones-case of social housing in Ecuador. In IOP Conference Series: Materials Science and Engineering 2017; 245(7): 072045.
  • Guo P., Li T., Xu B., Xu X., Li J. Questions and current understanding about solar chimney power plant: A review. Energy Conversion and Management 2019; 182: 21-33.
  • Harris DJ., Helwig N. Solar chimney and building ventilation. Applied Energy 2007; 84(2): 135-146.
  • Hayat MB., Ali D., Monyake KC., Alagha L., Ahmed N. Solar energy-A look into power generation, challenges, and a solar‐powered future. International Journal of Energy Research 2019; 43(3): 1049-1067.
  • IEA. The future of cooling, IEA 2018. Paris.
  • Karimi MS., Fazelpour F., Rosen MA., Shams M. Comparative study of solar-powered underfloor heating system performance in distinctive climates. Renewable Energy 2019; 130: 524-535.
  • Khanal R., Lei C. An experimental investigation of an inclined passive wall solar chimney for natural ventilation. Solar Energy 2014; 107: 461-474.
  • Khosravi M., Fazelpour F., Rosen MA. Improved application of a solar chimney concept in a two-story building: An enhanced geometry through a numerical approach. Renewable Energy 2019; 143: 569-585.
  • Leng PC., Ahmad MH., Ossen DR., Hamid M. Towards sustainable architecture: The effect of the solar chimney material on thermal performance based on CFD simulation. International Conference on Sustainable Urban Design for Liveable Cities, 2014, Malezya.
  • Lotfabadi P. Analyzing passive solar strategies in the case of high-rise building. Renewable and Sustainable Energy Reviews 2015; 52: 1340-1353.

Examination of the Use of Solar Chimney as a Passive Solar Energy Ventilation Method in Buildings through Case Studies

Year 2023, , 624 - 644, 20.12.2023
https://doi.org/10.47495/okufbed.1281430

Abstract

As a simple and practical passive solar ventilation and cooling system, solar chimneys attract intensive attention because of their low operating cost, near zero energy requirement and positive contribution to carbon dioxide emissions, ability to reduce heat load in both commercial buildings and residential and providing natural cooling, ventilation or heating. In this study, after giving a brief overview of passive solar systems, information about the use of solar chimneys used for passive ventilation and space heating in buildings is given and detailed information is given about the working principle of solar chimneys, their layers and classification. Finally, the examples studied on the use of solar chimneys for passive ventilation and cooling of the space were examined and discussed

Project Number

2020.KB.FEN.012

References

  • Abdeen A., Serageldin AA., Ibrahim MG., El-Zafarany A., Ookawara S., Murata R. Solar chimney optimization for enhancing thermal comfort in Egypt: An experimental and numerical study. Solar Energy 2019; 180: 524-536.
  • Awbi HB. Ventilation of buildings (Second ed.). Spon Press 2003. Londra.
  • Bassiouny R., Korah, NS. Effect of solar chimney inclination angle on space flow pattern and ventilation rate. Energy and Buildings 2009; 41(2): 190-196.
  • Bevilacqua P., Benevento F., Bruno R., Arcuri N. Are trombe walls suitable passive systems for the reduction of the yearly building energy requirements?. Energy 2019; 185: 554-566.
  • Boero A., Agyenim F. Modeling and simulation of a small-scale solar-powered absorption cooling system in three cities with a tropical climate. International Journal of Low-Carbon Technologies 2020; 15(1): 1-16.
  • Bong CPC., Lim LY., Ho WS., Lim JS., Klemeš JJ., Towprayoon S., Lee CT. A review on the global warming potential of cleaner composting and mitigation strategies. Journal of Cleaner Production 2017; 146: 149-157.
  • British Petroleum, bp Statistical Review of World Energy 2022; 71st edition, BP 2022. Londra.
  • Charvat P., Jicha M., Stetina J. Solar chimneys for residential ventilation. Ventilation and Retrofitting 2004; 19.
  • Cabeza LF., Chàfer M. Technological options and strategies towards zero energy buildings contributing to climate change mitigation: A systematic review. Energy and Buildings 2020; 219: 110009.
  • Cuce E., Cuce PM., Carlucci S., Sen H., Sudhakar K., Hasanuzzaman M., Daneshazarian R. Solar chimney power plants: A review of the concepts, designs and performances. Sustainability 2022; 14(3): 1450.
  • Dickinson EW. Solar energy technology handbook. CRC Press 2018.
  • Dimoudi A. Solar chimneys in buildings-The state of the art. Advances in Building Energy Research 2009; 3(1): 21-44.
  • Duy TN., Pham HTT. CFD based investigation on the performance of solar chimney for room natural ventilation. AIP Conference Proceedings 2021; 2420(1): 020027.
  • Goel M., Verma VS., Tripathi NG. Solar cooling technologies. In Solar Energy (pp. 107-116). Springer 2022. Singapore.
  • Godoy-Vaca L., Almaguer M., Martínez J., Lobato A., Palme M. Analysis of solar chimneys in different climate zones-case of social housing in Ecuador. In IOP Conference Series: Materials Science and Engineering 2017; 245(7): 072045.
  • Guo P., Li T., Xu B., Xu X., Li J. Questions and current understanding about solar chimney power plant: A review. Energy Conversion and Management 2019; 182: 21-33.
  • Harris DJ., Helwig N. Solar chimney and building ventilation. Applied Energy 2007; 84(2): 135-146.
  • Hayat MB., Ali D., Monyake KC., Alagha L., Ahmed N. Solar energy-A look into power generation, challenges, and a solar‐powered future. International Journal of Energy Research 2019; 43(3): 1049-1067.
  • IEA. The future of cooling, IEA 2018. Paris.
  • Karimi MS., Fazelpour F., Rosen MA., Shams M. Comparative study of solar-powered underfloor heating system performance in distinctive climates. Renewable Energy 2019; 130: 524-535.
  • Khanal R., Lei C. An experimental investigation of an inclined passive wall solar chimney for natural ventilation. Solar Energy 2014; 107: 461-474.
  • Khosravi M., Fazelpour F., Rosen MA. Improved application of a solar chimney concept in a two-story building: An enhanced geometry through a numerical approach. Renewable Energy 2019; 143: 569-585.
  • Leng PC., Ahmad MH., Ossen DR., Hamid M. Towards sustainable architecture: The effect of the solar chimney material on thermal performance based on CFD simulation. International Conference on Sustainable Urban Design for Liveable Cities, 2014, Malezya.
  • Lotfabadi P. Analyzing passive solar strategies in the case of high-rise building. Renewable and Sustainable Energy Reviews 2015; 52: 1340-1353.
There are 24 citations in total.

Details

Primary Language Turkish
Subjects Engineering
Journal Section REVIEWS
Authors

Okay Gönülol

Müjde Altın 0000-0001-6948-9463

Koray Ulgen 0000-0002-9560-1727

Project Number 2020.KB.FEN.012
Publication Date December 20, 2023
Submission Date April 11, 2023
Acceptance Date September 19, 2023
Published in Issue Year 2023

Cite

APA Gönülol, O., Altın, M., & Ulgen, K. (2023). Pasif Güneş Enerjili Havalandırma Yöntemi Olarak Güneş Bacasının Binalarda Kullanımının Örnekler Üzerinden İrdelenmesi. Osmaniye Korkut Ata Üniversitesi Fen Bilimleri Enstitüsü Dergisi, 6(Ek Sayı), 624-644. https://doi.org/10.47495/okufbed.1281430
AMA Gönülol O, Altın M, Ulgen K. Pasif Güneş Enerjili Havalandırma Yöntemi Olarak Güneş Bacasının Binalarda Kullanımının Örnekler Üzerinden İrdelenmesi. Osmaniye Korkut Ata University Journal of The Institute of Science and Techno. December 2023;6(Ek Sayı):624-644. doi:10.47495/okufbed.1281430
Chicago Gönülol, Okay, Müjde Altın, and Koray Ulgen. “Pasif Güneş Enerjili Havalandırma Yöntemi Olarak Güneş Bacasının Binalarda Kullanımının Örnekler Üzerinden İrdelenmesi”. Osmaniye Korkut Ata Üniversitesi Fen Bilimleri Enstitüsü Dergisi 6, no. Ek Sayı (December 2023): 624-44. https://doi.org/10.47495/okufbed.1281430.
EndNote Gönülol O, Altın M, Ulgen K (December 1, 2023) Pasif Güneş Enerjili Havalandırma Yöntemi Olarak Güneş Bacasının Binalarda Kullanımının Örnekler Üzerinden İrdelenmesi. Osmaniye Korkut Ata Üniversitesi Fen Bilimleri Enstitüsü Dergisi 6 Ek Sayı 624–644.
IEEE O. Gönülol, M. Altın, and K. Ulgen, “Pasif Güneş Enerjili Havalandırma Yöntemi Olarak Güneş Bacasının Binalarda Kullanımının Örnekler Üzerinden İrdelenmesi”, Osmaniye Korkut Ata University Journal of The Institute of Science and Techno, vol. 6, no. Ek Sayı, pp. 624–644, 2023, doi: 10.47495/okufbed.1281430.
ISNAD Gönülol, Okay et al. “Pasif Güneş Enerjili Havalandırma Yöntemi Olarak Güneş Bacasının Binalarda Kullanımının Örnekler Üzerinden İrdelenmesi”. Osmaniye Korkut Ata Üniversitesi Fen Bilimleri Enstitüsü Dergisi 6/Ek Sayı (December 2023), 624-644. https://doi.org/10.47495/okufbed.1281430.
JAMA Gönülol O, Altın M, Ulgen K. Pasif Güneş Enerjili Havalandırma Yöntemi Olarak Güneş Bacasının Binalarda Kullanımının Örnekler Üzerinden İrdelenmesi. Osmaniye Korkut Ata University Journal of The Institute of Science and Techno. 2023;6:624–644.
MLA Gönülol, Okay et al. “Pasif Güneş Enerjili Havalandırma Yöntemi Olarak Güneş Bacasının Binalarda Kullanımının Örnekler Üzerinden İrdelenmesi”. Osmaniye Korkut Ata Üniversitesi Fen Bilimleri Enstitüsü Dergisi, vol. 6, no. Ek Sayı, 2023, pp. 624-4, doi:10.47495/okufbed.1281430.
Vancouver Gönülol O, Altın M, Ulgen K. Pasif Güneş Enerjili Havalandırma Yöntemi Olarak Güneş Bacasının Binalarda Kullanımının Örnekler Üzerinden İrdelenmesi. Osmaniye Korkut Ata University Journal of The Institute of Science and Techno. 2023;6(Ek Sayı):624-4.

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