LOW CARBON ARCHITECTURAL DESIGN

Şaziye Balku; Filiz Koçyiğit

Research Article

LOW CARBON ARCHITECTURAL DESIGN

Year 2018, Volume: 31 Issue: 1, 13 - 23, 01.03.2018

Abstract

Tendency towards sustainable energy resources
is increasing and leading engineers and architects make joint efforts.
Renewable energy potential present in nature can be used more efficiently so
that while energy consumption is reducing, rate of energy gain, on the other
hand, increases by architectural design methods. A sailing club in Gölbaşı,
Ankara is designed as a low carbon building for optimum usage of solar and wind
energy. It can be concluded using an energy efficient architectural design for
a building before its construction makes it possible to meet the electrical and
heat energy requirements at minimum cost and environmental friendly.

Keywords

Energy efficient design, trombe wall

References

Bulut, Y. M., Yıldız, Z., “Comparing Energy Demand Estimation Using Various Statistical Methods: The Case of Turkey”, GU J Sci 29(2):237-244 (2016).
Fırat, S., “Application of Efficient & Renewable Energy Technologies in Low Cost Buildings and Construction”, J Polytechnic Vol: 17 No: 1 (Special Issue) 1-2, (2014).
Sassi P. “Strategies for Sustainable Architecture”, p.238, New York: Taylor& Francis INC. (2006).
Marszal, A. J. & Heisenberg, P. “A Literature Review of Zero Energy Buildings (ZEB) Definitions”, Aalborg: Department of Civil Engineering, Aalborg University, (DCE Technical Reports; No. 78) (2009).
Konters, J, “Planning for Solar Buildings in Urban Environments”, Doctoral Thesis, Lund University, Department of Architecture and Built Environment, Lund, Sweden. (2015),
TS EN ISO 13790 “Energy performance of buildings - Calculation of energy use for space heating and cooling”. https://www.iso.org/obp/ui/#iso:std:iso:13790:ed-2:v1:en.
Ruiz-Pardo, A., Dominguez, S.A., and Fernandez J.A.S. “Revision of the trombe wall calculation method proposed by UNE-EN ISO 13790”, Energy and Building 42, 763-773 (2010).
Yılmaz, Z. and Kundakçı, A. B., “An approach for energy conscious renovation of residential buildings in İstanbul by Trombe wall system”, Building and Environment 43, 508-517 (2008).
Y. Yıldız, “Impacts of Climate Change on Heating and Cooling Loads in Residential Buildings” GU J Sci 29(1):27-34 (2016).
Jiang, B. Ji J., Yi Hua, “The influence of PV coverage ratio on thermal performance of photovoltaiv-trombe wall”. Renew Energy 33 (2008) 2491-2498
Yunez-Cano A., Gonzales-Huerta R. de G., Tufino-Velazquez M., Barbosa R., B. Escobar, “Solar-hydrogen hybrid system integrated to a sustainable house in Mexico”, Int J Hydrogen Energy 41(2016) 19539-19545.
Munchi A. Sampath W., “CdTe Photovoltaics for Sustainable Electricity Generation”, J Electronic Materials, 45 (9) 2016.
http://www.ankara.climatemps.com/
Renewable Energy General Directorate. http://www.eie.gov.tr/MyCalculator/pages/ 6.aspx
Scherer, H.F., Pasamontes M., Guzman J.L. Alvarez, J.D., Normey-Rico, “Efficient building energy management using distributed model predictive control”, J Process Control (24) 740-749(2014).
Energy Efficient Architectural Design, Atılım University LAP Project ATÜ-LAP-C-1516-01 (2015-2016).
Incropera, F.P., Dewitt, D.P., Bergman, T. L., and Lavine, A.S., “Principles of Heat and Mass Transfer”, Seventh Edition, Wiley. Singapure, (2013).
Çengel, A. Y. “Heat and Mass Transfer. A Practical Approach”, Third Edition, Mc-Graw Hill, (2007) New York.
Turkish Republic Ministry of Forest and Water Affairs, Meteorology General Directorate, Global solar radiation and temperature measurements (2012).
The Mathworks. The language of technical computing, www.mathworks.com. (03.03.2016).

Year 2018, Volume: 31 Issue: 1, 13 - 23, 01.03.2018

Şaziye Balku Filiz Koçyiğit

Abstract

References

Bulut, Y. M., Yıldız, Z., “Comparing Energy Demand Estimation Using Various Statistical Methods: The Case of Turkey”, GU J Sci 29(2):237-244 (2016).
Fırat, S., “Application of Efficient & Renewable Energy Technologies in Low Cost Buildings and Construction”, J Polytechnic Vol: 17 No: 1 (Special Issue) 1-2, (2014).
Sassi P. “Strategies for Sustainable Architecture”, p.238, New York: Taylor& Francis INC. (2006).
Marszal, A. J. & Heisenberg, P. “A Literature Review of Zero Energy Buildings (ZEB) Definitions”, Aalborg: Department of Civil Engineering, Aalborg University, (DCE Technical Reports; No. 78) (2009).
Konters, J, “Planning for Solar Buildings in Urban Environments”, Doctoral Thesis, Lund University, Department of Architecture and Built Environment, Lund, Sweden. (2015),
TS EN ISO 13790 “Energy performance of buildings - Calculation of energy use for space heating and cooling”. https://www.iso.org/obp/ui/#iso:std:iso:13790:ed-2:v1:en.
Ruiz-Pardo, A., Dominguez, S.A., and Fernandez J.A.S. “Revision of the trombe wall calculation method proposed by UNE-EN ISO 13790”, Energy and Building 42, 763-773 (2010).
Yılmaz, Z. and Kundakçı, A. B., “An approach for energy conscious renovation of residential buildings in İstanbul by Trombe wall system”, Building and Environment 43, 508-517 (2008).
Y. Yıldız, “Impacts of Climate Change on Heating and Cooling Loads in Residential Buildings” GU J Sci 29(1):27-34 (2016).
Jiang, B. Ji J., Yi Hua, “The influence of PV coverage ratio on thermal performance of photovoltaiv-trombe wall”. Renew Energy 33 (2008) 2491-2498
Yunez-Cano A., Gonzales-Huerta R. de G., Tufino-Velazquez M., Barbosa R., B. Escobar, “Solar-hydrogen hybrid system integrated to a sustainable house in Mexico”, Int J Hydrogen Energy 41(2016) 19539-19545.
Munchi A. Sampath W., “CdTe Photovoltaics for Sustainable Electricity Generation”, J Electronic Materials, 45 (9) 2016.
http://www.ankara.climatemps.com/
Renewable Energy General Directorate. http://www.eie.gov.tr/MyCalculator/pages/ 6.aspx
Scherer, H.F., Pasamontes M., Guzman J.L. Alvarez, J.D., Normey-Rico, “Efficient building energy management using distributed model predictive control”, J Process Control (24) 740-749(2014).
Energy Efficient Architectural Design, Atılım University LAP Project ATÜ-LAP-C-1516-01 (2015-2016).
Incropera, F.P., Dewitt, D.P., Bergman, T. L., and Lavine, A.S., “Principles of Heat and Mass Transfer”, Seventh Edition, Wiley. Singapure, (2013).
Çengel, A. Y. “Heat and Mass Transfer. A Practical Approach”, Third Edition, Mc-Graw Hill, (2007) New York.
Turkish Republic Ministry of Forest and Water Affairs, Meteorology General Directorate, Global solar radiation and temperature measurements (2012).
The Mathworks. The language of technical computing, www.mathworks.com. (03.03.2016).

There are 20 citations in total.

Details

Journal Section	Architecture & City and Urban Planning
Authors	Şaziye Balku Filiz Koçyiğit
Publication Date	March 1, 2018
Published in Issue	Year 2018 Volume: 31 Issue: 1

Cite

APA	Balku, Ş., & Koçyiğit, F. (2018). LOW CARBON ARCHITECTURAL DESIGN. Gazi University Journal of Science, 31(1), 13-23.
AMA	Balku Ş, Koçyiğit F. LOW CARBON ARCHITECTURAL DESIGN. Gazi University Journal of Science. March 2018;31(1):13-23.
Chicago	Balku, Şaziye, and Filiz Koçyiğit. “LOW CARBON ARCHITECTURAL DESIGN”. Gazi University Journal of Science 31, no. 1 (March 2018): 13-23.
EndNote	Balku Ş, Koçyiğit F (March 1, 2018) LOW CARBON ARCHITECTURAL DESIGN. Gazi University Journal of Science 31 1 13–23.
IEEE	Ş. Balku and F. Koçyiğit, “LOW CARBON ARCHITECTURAL DESIGN”, Gazi University Journal of Science, vol. 31, no. 1, pp. 13–23, 2018.
ISNAD	Balku, Şaziye - Koçyiğit, Filiz. “LOW CARBON ARCHITECTURAL DESIGN”. Gazi University Journal of Science 31/1 (March 2018), 13-23.
JAMA	Balku Ş, Koçyiğit F. LOW CARBON ARCHITECTURAL DESIGN. Gazi University Journal of Science. 2018;31:13–23.
MLA	Balku, Şaziye and Filiz Koçyiğit. “LOW CARBON ARCHITECTURAL DESIGN”. Gazi University Journal of Science, vol. 31, no. 1, 2018, pp. 13-23.
Vancouver	Balku Ş, Koçyiğit F. LOW CARBON ARCHITECTURAL DESIGN. Gazi University Journal of Science. 2018;31(1):13-2.