Research Article
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Year 2021, , 7 - 12, 01.06.2021
https://doi.org/10.36222/ejt.893985

Abstract

References

  • Edwards, B., Naboni, E., Green buildings pay: Design, productivity and ecology, London, 2013
  • Loftness, V., Hakkinen, B., Adan, O., Nevalainen, A. (2007). Elements that contribute to healthy building design, Environmental Health Perspectives, 115, 965-970. Doi: 10.1289/ehp.8988.
  • Capeluto, I.G., (2010). The influence of the urban environment on the availability of daylighting in office buildings in Israel, Building and Environment, 38, 745-752. Doi: 10.1016/s0360-1323(02)00238-x.
  • Rubeis, T., Muttillo M., Pantoli L., Nardi, I., Leone I., Stornelli V., Ambrosini D., (2017). A first approach to universal daylight and occupancy control system for any lamps: Simulated case in an academic classroom, Energy Build, 152, 24-39. Doi: 10.1016/j.enbuild.2017.07.025.
  • Annual Energy Outlook, U.S. Energy Information Administration (EIA), USA, 2012
  • Nasrollahi N., Shokri E., (2016). Daylight illuminance in urban environments for visual comfort and energy performance, Renewable and Sustainable Energy Reviews, 66, 861-874. Doi: 10.1016/j.rser.2016.08.052.
  • Marks, F.M., (2013). Letter to the Editors: Lighting for Different Healthcare Settings, Health Environments Research and Design Journal, 6, no. 3, pp., 166-168. Doi: 10.1177/193758671300600314.
  • Lim, G.H., Hirning, M.B., Keumala, N., Ghafar, N.A., (2017). Daylight performance and user’s visual appraisal for green building offices in Malaysia, Energy and Build, 141, 175-185. Doi: 10.1016/j.enbuild.2017.02.028.
  • Uygun, E., Görgülü, S., (2016). Daylight simulation performance comparison of DIALux and RELUX Illumination simulation programs, The Journal of Graduate School of Natural and Applied Sciences of Mehmet Akif Ersoy University, S1, 1-8.
  • Çetin, F., Gümüş, B., Özbudak, Y., (2003). Ergonomic evaluation of lighting characteristics, 2nd National Lighting Symposium and Exhibition, Diyarbakır, 20-23.
  • Rea, M.S., (2002). Light-much more than vision, proceedings of light and human health: EPRI/LRO, 5th International Lighting Symposium, Palo Alto, CA, 1–15.
  • Badia, P., Myers, B., Boecker, M., Culpepper, J., Harsh, J.R., (1991). Bright light effects on body temperature, EEG and behavior, Physiology and Behavior, 50, 583–588. Doi: 10.1016/0031-9384(91)90549-4.
  • Lewy, A.J., Wehr, T.A., Goodwin, F.K., Newsome, D.A., Markey, S.P., (1980). Light suppresses melatonin secretion in humans, Science, 210, 1267–1269. Doi: 10.1126/science.7434030.
  • Bommel, W., (2005). CIE and the way of putting ‘lighting and health’ into daily lighting practice, Proceeding Book of Lux Europa, 10th European Lighting Conference, Berlin, 25-26.
  • Matusiak, B., (2010). Daylight design for healthy learning environments, Professional Lighting Design, Turkey, 33, 72-76.
  • ***, U.S., Green Building Council, https://www.usgbc.org/credits/healthcare/v4-draft/eqc-0
  • Aydınlı, S., Rosemann, A., (2000). A new lighting scheme that combines natural and artificial lights with heliostats and light transmitters, 3rd National Lighting Congress, Istanbul, 36-43.
  • Yapar, T., Energy Saving with Lighting Automation, Master Thesis, Yıldız Teknik University, Istanbul, 2007
  • Lam, W. M., Sunlighting as formgiver for architecture, New York, 1986
  • Willis, C., (1995). Form Follows Finance: Skyscrapers and Skylines in New York and Chicago, Princeton Architectural Press, New York. Doi: 10.2307/3116168.
  • Guzowski, M., Daylighting for Sustainable Design, McGraw-Hill, USA, 2010
  • Yüksek, I., Karadayı, T.T., (2017). Energy-Efficient building design in the context of building life cycle, Energy Efficient Buildings. Doi: 10.5772/66670.
  • ***, Wikoda, Natural sunlight to your home, http://wikoda.com
  • ***, eSolar energy news, Wikoda, http://www.esolarenergynews.com/p/wikodas-sunflower.html
  • Brown, G.Z., Dekay, M., (2001). Sun, wind and light, Architectural Design Strategies, John Willey and Sons Inc., USA, 222-223.
  • ***, Building Physics Expertise Applications, http://www.yfu.com/yazilar/mim65-mayis.pdf
  • Erel, B., A research on new technologies developed in the field of lighting with natural daylight, Master Thesis, Istanbul Teknik University, Istanbul, 2004
  • ***, NOAA, Solar Position Calculator, https://www.esrl.noaa.gov/gmd/grad/solcalc
  • Weidtman, G., Considerations in the selection of solar energy controlled reflected glass in curtain wall, 1999
  • Wang, Z., Tan, Y.K., (2013). Illumination control of LED systems based on neural network model and energy optimization algorithm, Energy and Buildings, 62, 514-521. Doi: 10.1016/j.enbuild.2013.03.029.
  • Sozen, A., Arcaklioglu, E., Ozalp, M., Kanit, E., (2005). Solar-energy potential in Turkey. Applied Energy, 80, 367-381. Doi: 10.1016/j.apenergy.2004.06.001.
  • ***, Heliostat Design Concepts, http://www.redrok.com/concept.htm

INVESTIGATION OF HOME TYPE HELIOSTAT SYSTEMS DAYLIGHTING PERFORMANCE WITH LIGHTING SIMULATION METHOD

Year 2021, , 7 - 12, 01.06.2021
https://doi.org/10.36222/ejt.893985

Abstract

Solar energy, which is an unlimited, costless and clean type of energy, is often preferred in architecture also as in all other areas. Today, all new technologies are made by focusing on solar energy. The main objective of lighting design in buildings is, to minimize energy consumption by keeping health and visual comfort at a high level. In this study, a home type heliostat system which is one of the modern and economic heliostat systems was introduced and its properties are listed. Based on the features of home type heliostat systems, all components of the system are modeled in a 3 Dimension stereolithography format. The daylighting performance of the home type heliostat systems was observed with the lighting simulation method. DIALux lighting design software was used in the study. The results show that the home type heliostat systems can successfully transfer natural light into the building in a simulation environment created by modeling and contribute to lux values.

References

  • Edwards, B., Naboni, E., Green buildings pay: Design, productivity and ecology, London, 2013
  • Loftness, V., Hakkinen, B., Adan, O., Nevalainen, A. (2007). Elements that contribute to healthy building design, Environmental Health Perspectives, 115, 965-970. Doi: 10.1289/ehp.8988.
  • Capeluto, I.G., (2010). The influence of the urban environment on the availability of daylighting in office buildings in Israel, Building and Environment, 38, 745-752. Doi: 10.1016/s0360-1323(02)00238-x.
  • Rubeis, T., Muttillo M., Pantoli L., Nardi, I., Leone I., Stornelli V., Ambrosini D., (2017). A first approach to universal daylight and occupancy control system for any lamps: Simulated case in an academic classroom, Energy Build, 152, 24-39. Doi: 10.1016/j.enbuild.2017.07.025.
  • Annual Energy Outlook, U.S. Energy Information Administration (EIA), USA, 2012
  • Nasrollahi N., Shokri E., (2016). Daylight illuminance in urban environments for visual comfort and energy performance, Renewable and Sustainable Energy Reviews, 66, 861-874. Doi: 10.1016/j.rser.2016.08.052.
  • Marks, F.M., (2013). Letter to the Editors: Lighting for Different Healthcare Settings, Health Environments Research and Design Journal, 6, no. 3, pp., 166-168. Doi: 10.1177/193758671300600314.
  • Lim, G.H., Hirning, M.B., Keumala, N., Ghafar, N.A., (2017). Daylight performance and user’s visual appraisal for green building offices in Malaysia, Energy and Build, 141, 175-185. Doi: 10.1016/j.enbuild.2017.02.028.
  • Uygun, E., Görgülü, S., (2016). Daylight simulation performance comparison of DIALux and RELUX Illumination simulation programs, The Journal of Graduate School of Natural and Applied Sciences of Mehmet Akif Ersoy University, S1, 1-8.
  • Çetin, F., Gümüş, B., Özbudak, Y., (2003). Ergonomic evaluation of lighting characteristics, 2nd National Lighting Symposium and Exhibition, Diyarbakır, 20-23.
  • Rea, M.S., (2002). Light-much more than vision, proceedings of light and human health: EPRI/LRO, 5th International Lighting Symposium, Palo Alto, CA, 1–15.
  • Badia, P., Myers, B., Boecker, M., Culpepper, J., Harsh, J.R., (1991). Bright light effects on body temperature, EEG and behavior, Physiology and Behavior, 50, 583–588. Doi: 10.1016/0031-9384(91)90549-4.
  • Lewy, A.J., Wehr, T.A., Goodwin, F.K., Newsome, D.A., Markey, S.P., (1980). Light suppresses melatonin secretion in humans, Science, 210, 1267–1269. Doi: 10.1126/science.7434030.
  • Bommel, W., (2005). CIE and the way of putting ‘lighting and health’ into daily lighting practice, Proceeding Book of Lux Europa, 10th European Lighting Conference, Berlin, 25-26.
  • Matusiak, B., (2010). Daylight design for healthy learning environments, Professional Lighting Design, Turkey, 33, 72-76.
  • ***, U.S., Green Building Council, https://www.usgbc.org/credits/healthcare/v4-draft/eqc-0
  • Aydınlı, S., Rosemann, A., (2000). A new lighting scheme that combines natural and artificial lights with heliostats and light transmitters, 3rd National Lighting Congress, Istanbul, 36-43.
  • Yapar, T., Energy Saving with Lighting Automation, Master Thesis, Yıldız Teknik University, Istanbul, 2007
  • Lam, W. M., Sunlighting as formgiver for architecture, New York, 1986
  • Willis, C., (1995). Form Follows Finance: Skyscrapers and Skylines in New York and Chicago, Princeton Architectural Press, New York. Doi: 10.2307/3116168.
  • Guzowski, M., Daylighting for Sustainable Design, McGraw-Hill, USA, 2010
  • Yüksek, I., Karadayı, T.T., (2017). Energy-Efficient building design in the context of building life cycle, Energy Efficient Buildings. Doi: 10.5772/66670.
  • ***, Wikoda, Natural sunlight to your home, http://wikoda.com
  • ***, eSolar energy news, Wikoda, http://www.esolarenergynews.com/p/wikodas-sunflower.html
  • Brown, G.Z., Dekay, M., (2001). Sun, wind and light, Architectural Design Strategies, John Willey and Sons Inc., USA, 222-223.
  • ***, Building Physics Expertise Applications, http://www.yfu.com/yazilar/mim65-mayis.pdf
  • Erel, B., A research on new technologies developed in the field of lighting with natural daylight, Master Thesis, Istanbul Teknik University, Istanbul, 2004
  • ***, NOAA, Solar Position Calculator, https://www.esrl.noaa.gov/gmd/grad/solcalc
  • Weidtman, G., Considerations in the selection of solar energy controlled reflected glass in curtain wall, 1999
  • Wang, Z., Tan, Y.K., (2013). Illumination control of LED systems based on neural network model and energy optimization algorithm, Energy and Buildings, 62, 514-521. Doi: 10.1016/j.enbuild.2013.03.029.
  • Sozen, A., Arcaklioglu, E., Ozalp, M., Kanit, E., (2005). Solar-energy potential in Turkey. Applied Energy, 80, 367-381. Doi: 10.1016/j.apenergy.2004.06.001.
  • ***, Heliostat Design Concepts, http://www.redrok.com/concept.htm
There are 32 citations in total.

Details

Primary Language English
Journal Section Research Article
Authors

Emre Uygun 0000-0003-3792-1922

Sertaç Görgülü 0000-0002-8394-5362

Publication Date June 1, 2021
Published in Issue Year 2021

Cite

APA Uygun, E., & Görgülü, S. (2021). INVESTIGATION OF HOME TYPE HELIOSTAT SYSTEMS DAYLIGHTING PERFORMANCE WITH LIGHTING SIMULATION METHOD. European Journal of Technique (EJT), 11(1), 7-12. https://doi.org/10.36222/ejt.893985

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