Shading Percentage Effects on Energy Consumption for Bahraini Residential Buildings
Energy consumption is a very important topic these
days especially regarding air conditioning in residential buildings,
since this takes the biggest amount of energy in buildings total
consumption, residential buildings constitute the biggest percentage
of energy consumption in Bahrain.
This research reflects on the effects of shading percentage in
different solar orientations on the energy consumption inside
residential buildings (domestic dwellings).
The research as found that, there are different effects of shading in
changing building orientation:
• 0.69% for the shading percentage 25% when the building is
oriented to the north (0º);
• 18.59% for 75% of shading in north-west orientation
(325º);
• The best effect for shading is in north-west orientation
(315º);
• The less effect for shading was in case of the building
orientation is the north (0º).
1] Yilmaz Z. Evaluation of energy efficient design strategies for different
climatic zones: Comparison of thermal performance of buildings in
temperate-humid and hot-dry climate. Energy and Buildings, 2007, 39,
306-316.
[2] Stoakes, P. J.. Simulation of airflow and heat transfer in buildings. M.Sc.
Thesis, Virginia Polytechnic Institute and State University. 2009.
[3] Srivastava-modi, S. Evaluating the Ability of equest Software to
Simulate Low-energy Buildings in a Cold Climatic Region. Master.
2011.
[4] BMEW. Statistical book 2005, Bahrain Ministry of Electricity & Water
2005.
[5] Justin Shultz, Lucas Witmer, JE_Rey r. S. Brownson, impact of shade
on hvac energy consumption in buildings: a residential case study, The
Pennsylvania State University, 2011.
[6] Mc Pherson, J.R. Simpson, P.J. Peper,.S.E. Maco, Q. Xiao, Municipal
forest benefits and costs in five U.S. cities, Journal of Forestry 2005, 103
411- 416.
[7] Geoffrey H. Donovan , David T. Butry, The value of shade: Estimating
the effect of urban trees on summertime electricity use. Energy and
Buildings, 2009, 41 (662-668).
[8] Matthew A. Jungclaus and Quinn S. Weber , Shading System: Reducing
Home Energy Usage, School of Engineering and Applied Science,
Department of Mechanical Engineering, Automated spectra, may 2012.
[9] Ministry of housing projects and development of dwelling units,
Development of dwelling units, Physical planning directorate, Technical
affairs directorate. July, 1993.
[10] Hong, t., s. K. Chou, et al. "building simulation: an overview of
developments and information sources." building and environment 2000,
35(4): 347-361.
[11] Rallapalli, H. S. A Comparison of Energyplus and eQuest Whole
Building Energy Simulation Results for a Medium Sized Office
Building, Arizona State University, 2010.
[12] Kawamoto, S., Environmentally Conscious Design and Inverse
Manufacturing, 2005. Eco Design. Fourth International Symposium.
2005.
1] Yilmaz Z. Evaluation of energy efficient design strategies for different
climatic zones: Comparison of thermal performance of buildings in
temperate-humid and hot-dry climate. Energy and Buildings, 2007, 39,
306-316.
[2] Stoakes, P. J.. Simulation of airflow and heat transfer in buildings. M.Sc.
Thesis, Virginia Polytechnic Institute and State University. 2009.
[3] Srivastava-modi, S. Evaluating the Ability of equest Software to
Simulate Low-energy Buildings in a Cold Climatic Region. Master.
2011.
[4] BMEW. Statistical book 2005, Bahrain Ministry of Electricity & Water
2005.
[5] Justin Shultz, Lucas Witmer, JE_Rey r. S. Brownson, impact of shade
on hvac energy consumption in buildings: a residential case study, The
Pennsylvania State University, 2011.
[6] Mc Pherson, J.R. Simpson, P.J. Peper,.S.E. Maco, Q. Xiao, Municipal
forest benefits and costs in five U.S. cities, Journal of Forestry 2005, 103
411- 416.
[7] Geoffrey H. Donovan , David T. Butry, The value of shade: Estimating
the effect of urban trees on summertime electricity use. Energy and
Buildings, 2009, 41 (662-668).
[8] Matthew A. Jungclaus and Quinn S. Weber , Shading System: Reducing
Home Energy Usage, School of Engineering and Applied Science,
Department of Mechanical Engineering, Automated spectra, may 2012.
[9] Ministry of housing projects and development of dwelling units,
Development of dwelling units, Physical planning directorate, Technical
affairs directorate. July, 1993.
[10] Hong, t., s. K. Chou, et al. "building simulation: an overview of
developments and information sources." building and environment 2000,
35(4): 347-361.
[11] Rallapalli, H. S. A Comparison of Energyplus and eQuest Whole
Building Energy Simulation Results for a Medium Sized Office
Building, Arizona State University, 2010.
[12] Kawamoto, S., Environmentally Conscious Design and Inverse
Manufacturing, 2005. Eco Design. Fourth International Symposium.
2005.
@article{"International Journal of Architectural, Civil and Construction Sciences:60940", author = "Saad F. Al Nuaimi", title = "Shading Percentage Effects on Energy Consumption for Bahraini Residential Buildings", abstract = "Energy consumption is a very important topic these
days especially regarding air conditioning in residential buildings,
since this takes the biggest amount of energy in buildings total
consumption, residential buildings constitute the biggest percentage
of energy consumption in Bahrain.
This research reflects on the effects of shading percentage in
different solar orientations on the energy consumption inside
residential buildings (domestic dwellings).
The research as found that, there are different effects of shading in
changing building orientation:
• 0.69% for the shading percentage 25% when the building is
oriented to the north (0º);
• 18.59% for 75% of shading in north-west orientation
(325º);
• The best effect for shading is in north-west orientation
(315º);
• The less effect for shading was in case of the building
orientation is the north (0º).", keywords = "Bahraini buildings, Building shading, energy consumption, residential buildings, shading effects.", volume = "6", number = "12", pages = "1104-7", }