A Proposal for Desert House Design in Egypt Using Passive Ground Cooling Techniques
Abstract
An area less than 5.5% of Egyptian territory is where most of Egypt‘s population lives in. A narrow strip of land forms the Nile Valley and Delta sector.
The National Project for Desert Hinterlands is one of the urban projects targeting rehabilitation of the poor in alternative villages in the near desert to stop urban sprawl over agricultural land and decrease the congestion in the old habitats. Low cost energy efficient houses are the aim of the architect in similar projects taking in consideration the high electricity consumption of Egypt’s residential sector.
Based on a literature review, this paper presents a proposal for designing desert dwellings that accommodates the hot dry climate by incorporating passive elements and using stabilized earth blocks as a local building material. Furthermore, simulation is used to test alternative proposals. The results show that an underground constructed house with a sunken courtyard incorporating an Earth to Air Heat Exchanger System (EAHE) can reduce between 42-72% of energy consumption used to achieve thermal comfort compared to contemporary desert housing projects.
Keywords
Full Text:
PDFReferences
H. Farrouh, H. and A Lubna. “Passive and hybrid techniques for low cost energy efficient housing in hot dry climate,” Azhar University Magazine, Egypt, vol. 11, no. 41, pp. 1265-1274, 2016.
The Egyptian Electricity Holding Company Annual Report 2009/2010, Egyptian Electricity Holding Company, Cairo, Egypt, 2010, pp. 1-48.
M. Ali. “Modelling the performance of horizontal heat exchanger of ground-coupled heat pump systems with Egyptian conditions,” University of Manchester, 2013.
M.G. Salim. “Selection of groundwater sites in Egypt, using geographic information systems, for desalination by solar energy in order to reduce greenhouse gases,” Journal of Advanced Research, vol. 3, no. 1, pp. 11–19, 2012
D. Banks. An Introduction to Thermogeology: Ground Source Heating and Cooling. Wiley-Blackwell, 2012.
A.J. Anselm. “Passive annual heat storage principles in earth sheltered housing, a supplementary energy saving system in residential housing,” Energy and Buildings, vol. 40, no. 7 pp. 1214–1219, 2008.
B. Hoyle. Low Energy Building Engineering. 1st ed., The English Press, 2011, pp. 114-125.
B. Rudofsky. Architecture Without Architects. Doubleday & Company, 1964.
A. Jideofor. “Earth shelters; A review of energy conservation properties in Earth sheltered housing,” Energy Conservation, pp.127, 2012
C. von Dronkelaar. Underground Buildings. Thesis / University Of Technology Eindhoven, 2013.
A.A. Al-Temeemi, and D.J Harris. “The generation of subsurface temperature profiles for Kuwait,” Energy and Buildings, vol. 33, no. 8, pp. 837–841, 2001
A.S. Alkaff, et al. “A review of underground building towards thermal energy efficiency and sustainable development,” Renewable and Sustainable Energy Reviews, vol. 60, pp. 692–713, 2016.
S. Baggs, at al. “Australian earth-covered building,” NSW University Press, 1991, Kensington.
A.A. Al-Temeemi and D.J. Harris. “A guideline for assessing the suitability of earth-sheltered mass-housing in hot-arid climates,” Energy and Buildings, vol. 36, no. 3, pp. 251–260, 2004.
R. A. Behr. Suitable Thin Shell Structural Configurations for Earth Sheltered Housing. PhD. Thesis, Texas Tech University, 1982.
P. Carpenter. “‘Sod It’: an introduction to earth sheltered development in England and Wales,” British Earth Sheltering Association, "Sod It": an Introduction to Earth Sheltered Development in England and Wales, 1994.
T.A. Bligh. “Comparison of energy consumption in earth covered vs. non-earth covered buildings,” in Proceedings of the Conference on Alternatives in Energy Conservation, National Science Foundation, 1975.
G. Golany. Earth-Sheltered Habitat: History, Architecture and Urban Design. Van Nostrand, 1983.
A.A. Al-Mumin. “Suitability of sunken courtyards in the desert climate of Kuwait,” Energy and Buildings, vol. 33, no. 2, pp. 103–111, 2001.
National Renewable Energy Laboratory (Nrel). “Earth-sheltered houses,” Energy Efficiency and Renewable Energy Clearinghouse, 1997.
H. Wallbaum, et al. “Indicator based sustainability assessment tool for affordable housing construction technologies,” Ecological Indicators, vol. 18, pp. 353–364, 2012.
T. Akmal, et al. “Rice-straw based cement brick microclimatic thermal impact assessment in Cairo, Egypt,” Proceedings of the World Renewable Energy Congress â Sweden, 8â 13 May, 2011, Linkà Ping, Sweden, 2011.
M. El-Kabbany. Alternative Building Materials and Components for Affordable Housing in Egypt: Towards Improved Competitiveness of Modern Earth Construction, MSc. Thesis, Ain Shams University, Egypt, 2013.
A.M. Bauchard, ed. "Compressed stabilized earth blocks,” Auroville Earth Institute Newsletter, pp.3, 2012.
S. Attia, et al. “Architect friendly: A comparison of ten different building performance simulation tools," 11th IBPSA Building Simulation Conference. Glasgow, Scotland, 2009.
D.B. Crawley, et al. “Energy plus: Creating a new-generation building energy simulation program,” Energy and Buildings, vol. 33, no. 4, pp. 319–331, 2001.
A.A. Al-Temeemi and D.J. Harris. “The effect of earth-contact on heat transfer through a wall in Kuwait,” Energy and Buildings, vol. 35, no. 4, pp. 399–404, 2003.
K.H. Lee and R. Strand. “Implementation of an earth tube system into energy plus program,” Energy and Buildings, vol. 40, 2006.
A. Sansui. “Low energy ground cooling system for buildings in hot and humid Malaysia,” De Montfort University, Malaysia, 2012.
M. Santamouris, et al. “Use of buried pipes for energy conservation in cooling of agricultural greenhouses,” Solar Energy, vol. 55, no. 2, pp. 111–124, 1995.
V. Bansal and J. Mathur. “Performance enhancement of earth air tunnel heat exchanger using evaporative cooling,” International Journal of Low-Carbon Technologies, vol. 4, pp 150-158, 2009.
G. Mihalakakou, et al. “Parametric prediction of the buried pipes cooling potential for passive cooling applications,” Solar Energy, vol. 55, pp. 151-234, 1995.
A.K. Misra, et al. “Design and performance evaluation of low cost earth to air heat exchanger model suitable for small buildings in arid and semi-arid regions,” KSCE Journal of Civil Engineering, vol. 19, no. 4, pp. 853–856, 2014.
D.Y. Goswami and K.M. Biseli. Use of Underground Air Tunnels for Heating and Cooling Agricultural and Residential Buildings. Fact Sheet EES 78, pp. 1-4., Florida Energy Extension Service, University of Florida, 1993. infohouse.p2ric.org/ref/08/07683.pdf&p=DevEx,5066.1.
T. Choudhury and A.K. Misra. “Minimizing changing climate impact on buildings using easily and economically feasible earth to air heat exchanger technique,” Mitigation and Adaptation Strategies for Global Change, vol. 19, no. 7, pp. 947–954, 2013.
J. Pfafferott. “Evaluation of earth-to-air heat exchangers with a standardised method to calculate energy efficiency,” Energy and Buildings, vol. 35, no. 10, pp. 971–983, 2003.
N.M. Thanu, et al. “An experimental study of the thermal performance of an earth-air-pipe system in single pass mode,” Solar Energy, vol. 71, no. 6, pp. 353–364, 2001.
M.D. Paepe and A. Janssens. “Thermo-hydraulic design of earth-air heat exchangers,” Energy and Buildings, vol. 35, no. 4, pp. 389–397, 2003.
M. Maerefat and A.P. Haghighi. “Passive cooling of buildings by using integrated earth to air heat exchanger and solar chimney,” Renewable Energy, vol. 35, no. 10, pp. 2316–2324, 2010.
A.H. Poshtiri, et al. “Feasibility study on using solar chimney and earth-to-air heat exchanger for natural heating of buildings,” Proceedings of the World Renewable Energy Congress â Sweden, 8â13 May, 2011, LinkÃPing, Sweden, 2011.
H. Hammadi and A. Mohammed. “Application of earth tube heat exchanger and solar chimney for natural cooling system in Basrah City,” Journal for Engineering Sciences, pp. 23–32, 2014.
M.S. Hassan and I.M. El-Moghasy. “Space conditioning by pipe-air cooler buried in earth,” First Conference of the Egyptian Combustion Society, 1989.
M.O. Ali. “Development of design factors for spiral ground heat exchanger in heat pump applications,” Al-Minia University, Al-Minia University, 2005, p. 29.
S. Moustafa, et al. “Arid soil temperature model,” Solar Energy, vol. 27, no. 1, pp. 83–88, 1981.
M. Derradji and M. Aiche. “Modeling the soil surface temperature for natural cooling of buildings in hot climates,” Procedia Computer Science, vol. 32, pp. 615-621, 2014.
H.B.J. Derbel and O. Kanoun. “Investigation of the ground thermal potential in Tunisia focused towards heating and cooling applications,” Applied Thermal Engineering, vol. 30, no. 10, pp. 1091–1100, 2010.
F. Al-Ajmi, et al. “The cooling potential of Earthâ air heat exchangers for domestic buildings in a desert climate,” Building and Environment, vol. 41, no. 3, pp. 235–244, 2006.
Sharan, et al. “Soil Temperatures Regime at Ahmedabad.” EconPapers, 2 Nov. 2002, econpapers.repec.org/RePEc:iim:iimawp:wp00050.
A.O. Ogunlela. “Modeling soil temperature variations,” Journal of Agricultural Research and Development, vol. 2, no. 1, pp. 100-109, 2009.
A. Gouda. “Using of geothermal energy in heating and cooling of agricultural structures,” Benha University, 2010.
D.L. Nofzigerd. “Soil temperature changes with time and depth theory.” Http://Soilphysics.Okstate.Edu/Software/Soiltemperature/Document.Pdf, 2003.
Editor in chief: A.M. Bauchard. “Compressed stabilized earth blocks,” Auroville Earth Institute, India, 2012.
DOI: http://dx.doi.org/10.21622/resd.2018.04.1.021
Refbacks
- There are currently no refbacks.
Copyright (c) 2017 Lubna Amer
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.
Renewable Energy and Sustainable Development
E-ISSN: 2356-8569
P-ISSN: 2356-8518
Published by:
Academy Publishing Center (APC)
Arab Academy for Science, Technology and Maritime Transport (AASTMT)
Alexandria, Egypt