Öz
Due to the increasing environmental awareness, the tendency to develop sustainable buildings has also increased interest in using renewable energy or energy-efficient technologies in recent years. Integrating a photobioreactor, an innovative building element on the façade, has received attention as an alternative approach to renewable energy systems for its potential to reduce the carbon footprint and energy consumption of a building without compromising thermal and visual comfort. This study aims to improve the performance of the building by using a façade integrated photobioreactor system. Implementing photobioreactors on the building façades raises the following benefits a) regulating the indoor temperature swings and improving thermal comfort, b) blocking the excess daylight thanks to the increasing concentration during the algae growth, c) reducing the energy consumption of the building, and d) producing energy from the harvested biomass (algae). The photobioreactor is integrated on the south façade of an existing office building in Izmir and comprises two glasses and a growth medium of photosynthesizing microalgae between the glasses. The method is simulation-based optimization that maximizes useful daylight illuminance and minimizes thermal comfort violation and energy use intensity. The performance of the existing building was compared with two photobioreactor alternatives. Rhino Grasshopper software with the Octopus plugin was used for the optimization study. The optimization results show that the photobioreactor integrated façade system performed better than the currently used one. The photobioreactor integrated façade can reduce the number of uncomfortable hours during the year. For the investigated photobioreactor configurations, there was no significant difference between 100% photobioreactor façade and 80% photobioreactor façade, except for partial improvement in daylight illumination.
Anahtar Kelimeler
multi-objective optimization microalgae photobioreactor building performance thermal-visual comfort
Destekleyen Kurum
TÜRKİYE BİLİMSEL VE TEKNOLOJİK ARAŞTIRMA KURUMU (TÜBİTAK)
Proje Numarası
218M580
Teşekkür
The Scientific and Technological Research Council of Turkey (TÜBİTAK) supported this work through research project 218M580.
Kaynakça
- [1] Zhao J, Du Y. Multi-objective optimization design for windows and shading configuration considering energy consumption and thermal comfort: A case study for office building in different climatic regions of China. Sol Energy 2020; 206; 997-1017.
- [2] Kim KH. A feasibility study of an algae façade system. In: Proceedings of international conference on sustainable building Asia (SB13): 8–10 July 2013, Seoul, South Korea. pp. 333-341.
- [3] Decker M, Hahn G, Harris LM. Bio-Enabled Façade Systems Managing Complexity of Life through Emergent Technologies. In Herneoja A, Österlund T, Markkanen P, editors, Complexity & Simplicity - Proceedings of the 34th eCAADe Conference - Volume 1: 22-26 August 2016, University of Oulu, Oulu, Finland. pp. 603-612.
- [4] Lo Verso VRM, Javadi MHS, Pagliolico S, Carbonaro C, Sassi G. Photobioreactors as a Dynamic Shading System Conceived for an Outdoor Workspace of the State Library of Queensland in Brisbane: Study of Daylighting Performances. J Daylighting 2019; 6; 148-168.
- [5] Cervera Sardá R, Vicente CA. Case Studies on the Architectural Integration of Photobioreactors in Building Façades. In: Pacheco Torgal F, Buratti C, Kalaiselvam S, Granqvist CG, Ivanov V, editors, Nano and Biotech Based Materials for Energy Building Efficiency. Cham: Springer, 2016. pp. 457-484.
- [6] Negev E, Yezioro A, Polikovsky M, Krobos A, Cory J, Shashua-Bar L, Golberg A. Algae window for reducing energy consumption of building structures in the Mediterranean city of Tel-Aviv, Israel, Energy Build 2019; 204; 109460. [7] Köktürk G, Yaman Y, Tokuç A. Parametric analysis of the effect of a biomass producing facade element on energy, lighting and thermal comfort in Ankara climate. EKSEN Dokuz Eylül Üniversitesi Mimarlık Fakültesi Dergisi 2022; 3(1); 20-33. (article in Turkish with an abstract in English)
- [8] ASHRAE Technical Report American society of heating, ventilating, and air conditioning engineers [ASHRAE] guideline 14. Measurement of energy and demand savings 2014.
- [9] Acar U, Kaska O, Tokgoz N. Multi-objective optimization of building envelope components at the preliminary design stage for residential buildings in Turkey. J Build Eng 2021; 42; 102499.
- [10] Goia F. Search for the optimal window-to-wall ratio in office buildings in different European climates and the implications on total energy saving potential. Sol Energy 2016; 132; 467–492.
- [11] Badeche M, Bouchahm Y. Design optimization criteria for windows providing low energy demand in office buildings in Algeria. Environmental and Sustainability Indicators 2020; 6; 100024.
Öz
Proje Numarası
218M580
Kaynakça
- [1] Zhao J, Du Y. Multi-objective optimization design for windows and shading configuration considering energy consumption and thermal comfort: A case study for office building in different climatic regions of China. Sol Energy 2020; 206; 997-1017.
- [2] Kim KH. A feasibility study of an algae façade system. In: Proceedings of international conference on sustainable building Asia (SB13): 8–10 July 2013, Seoul, South Korea. pp. 333-341.
- [3] Decker M, Hahn G, Harris LM. Bio-Enabled Façade Systems Managing Complexity of Life through Emergent Technologies. In Herneoja A, Österlund T, Markkanen P, editors, Complexity & Simplicity - Proceedings of the 34th eCAADe Conference - Volume 1: 22-26 August 2016, University of Oulu, Oulu, Finland. pp. 603-612.
- [4] Lo Verso VRM, Javadi MHS, Pagliolico S, Carbonaro C, Sassi G. Photobioreactors as a Dynamic Shading System Conceived for an Outdoor Workspace of the State Library of Queensland in Brisbane: Study of Daylighting Performances. J Daylighting 2019; 6; 148-168.
- [5] Cervera Sardá R, Vicente CA. Case Studies on the Architectural Integration of Photobioreactors in Building Façades. In: Pacheco Torgal F, Buratti C, Kalaiselvam S, Granqvist CG, Ivanov V, editors, Nano and Biotech Based Materials for Energy Building Efficiency. Cham: Springer, 2016. pp. 457-484.
- [6] Negev E, Yezioro A, Polikovsky M, Krobos A, Cory J, Shashua-Bar L, Golberg A. Algae window for reducing energy consumption of building structures in the Mediterranean city of Tel-Aviv, Israel, Energy Build 2019; 204; 109460. [7] Köktürk G, Yaman Y, Tokuç A. Parametric analysis of the effect of a biomass producing facade element on energy, lighting and thermal comfort in Ankara climate. EKSEN Dokuz Eylül Üniversitesi Mimarlık Fakültesi Dergisi 2022; 3(1); 20-33. (article in Turkish with an abstract in English)
- [8] ASHRAE Technical Report American society of heating, ventilating, and air conditioning engineers [ASHRAE] guideline 14. Measurement of energy and demand savings 2014.
- [9] Acar U, Kaska O, Tokgoz N. Multi-objective optimization of building envelope components at the preliminary design stage for residential buildings in Turkey. J Build Eng 2021; 42; 102499.
- [10] Goia F. Search for the optimal window-to-wall ratio in office buildings in different European climates and the implications on total energy saving potential. Sol Energy 2016; 132; 467–492.
- [11] Badeche M, Bouchahm Y. Design optimization criteria for windows providing low energy demand in office buildings in Algeria. Environmental and Sustainability Indicators 2020; 6; 100024.
Ayrıntılar
| Birincil Dil | İngilizce |
|---|---|
| Konular | Mühendislik |
| Bölüm | Makaleler |
| Yazarlar | |
| Proje Numarası | 218M580 |
| Yayımlanma Tarihi | 23 Aralık 2022 |
| Yayımlandığı Sayı | Yıl 2022 - Vol.23 - 16th DDAS (MSTAS) Special Issue -2022 |