Abstract
There is a distinct lack of building design literature specific to the Central Asian region. This perhaps, could be one of the reasons for insignificant improvements in new building design and construction, even despite huge investment in the construction of new buildings in, for example, Astana, Kazakhstan. The absence of low-energy building design guidelines could lead to adverse internal conditions and skyrocketing energy bills. In the present context, low-energy buildings refer to buildings that are inherently low-energy consuming by careful passive design, by utilizing intelligent building technologies to automate building services, by minimizing wastage of energy, and by incorporating renewable technologies for its energy supply. This paper focuses on the low-energy design of buildings for harsh weather conditions that prevail in Astana, Kazakhstan. The main aspects of low-energy design are critically discussed. A case study for Dostar residential complex in Astana is presented. Computational fluid dynamics (CFD) analysis is used to demonstrate the effect of important aspects of passive design, such as building orientation, configuration, and envelope on energy efficiency and wind comfort in Dostar residential complex in Astana. The results indicated that there is a considerable influence of low-energy building design on energy efficiency, wind comfort, and safety. Based on the findings of this study, it is suggested that a multiple buildings configuration (a box-shaped form in this case) rather than a single-standing building should be considered while designing future housing developments in Kazakhstan.
Similar content being viewed by others
References
Al Anzi, A., Seo, D., & Krarti, M. (2009). Impact of building shape on the thermal performance of office buildings in Kuwait. Energy Conversion and Management, 50(3), 822–828. doi:10.1016/j.enconman.2008.09.033.
Baker, N. M. W., & Taleb, A. M. (2002). The application of the inclined window method for passive cooling in buildings. Architectural Science Review, 45, 51–55.
Baskaran, A., & Kashen, A. (1996). Investigation of air flow around buildings using computational fluid dynamics technique. Engineering Structures, 18(11), 861–875.
Blocken, B., Stathopoulus, T., Carmeliet, J., & Hensen, J. (2011). Application of CFD in building performance simulation for outdoor environment: an overview. Journal of Building Performance Simulation, 4(2), 157–184.
CNK. (2006). Construction norms of Kazakhstan (CNK) 2.04-21-2004*. Energy Consumption and Thermal Protection of Residential (Civil) Buildings.
CNRK. (2010).Construction climatology. Construction Norms and Regulations of Kazakhstan (CNRK) 2.04-01-2010 (СНиПРК 2.04-01-2010).
Durgin, F. H., & Chock, A. W. (1982). Pedestrian wind levels: a brief review. Journal of the Structural Division ASCE, 108, 1751–1767.
E-vesti.kz. (2012). Security measures in the operation of elevators. Accessed 18 Jan 2014.
Haase, M., & Amato, A. (2008). An investigation of the potential for natural ventilation and building orientation to achieve thermal comfort in warm and humid climates. Solar Energy, 83, 389–399.
Hachem, C., Athienitis, A., & Fazio, P. (2011). Parametric investigation of geometric form effects on solar potential of housing units. Solar Energy, 85, 1864–1877.
Haupt, S., Kunz, R., Peltier, L., & Dreyer, J. (2010). Computational fluid dynamics coupled with thermal impact model for building design. Journal of Computers, 5(10), 1552–1559.
Lawson, T. V., & Penwarden, A. D. (1975). The effects of wind on people in the vicinity of building. 4th Int.Conf. Wind Effects on Buildings and Structures. Heathrow.
Levolux. (2007). Sight lighting. http://www.levolux.com/ Accessed 25 Jan 2014.
Ling, C. S., Ahmad, M. H., & Ossen, D. R. (2007). The effect of geometric shape and building orientation on minimizing solar insolation on high-rise buildings in hot humid climate. Journal of Construction in Developing Countries, 12(1), 27–38.
Littlefield, T., Moore, T., Thomas, P., & Kennedy, E. (2009). Energy efficient building design and construction practices. Frankfort: Legislative Research Commission.
Nikolayev, V. А. (1999). Landscapes of Asian steppes. Moscow State University.
OldKurier. (2012). Astana established to amaze. http://old.kurier.lt/?r=25&a=5602 Accessed 19 Feb 2014.
Pogoda.ru. (2014). Climate of Astana http://www.pogoda.ru.net/climate/35188.htm. Accessed 10 Jan 2014.
Pullekat, R., Badr, A., & Al-Zubaidy, S. (2012). Designing for higher standard of energy efficiency: experience from United Arab Emirates. 1st Intl Conference on Scientific Support for Housing & Municipal Spheres, Housing & Utilities Science & Technology Center, Astana, Kazakhstan, 26–27 October, pp. 15–24.
Roth, K., Lawrence, T., & Brodrick, J. (2007). Double skin façades. ASHRAE Journal, 49, 70–73.
RRCAP. (2007). Industrial pollution, part 2, p. 71, http://rrcap.unep.org/reports/soe/sa_part2_3.pdf Accessed 15 Jan 2014.
Stevanović, S. (2013). Optimization of passive solar design strategies: a review. Renewable and Sustainable Energy Reviews, 25, 177–196.
Straube, J. (2008). Building science insights. BSI-006: can highly glazed building facades be green? www.buildingscience.com/documents/insights/bsi-006-can-fully-glazed-curtaiwalls-be-green. Accessed 20 Feb 2014.
Time.kz. (2012). Rich people also get cold. http://www.time.kz/index.php?module=news&newsid=25783. Accessed 13 Jan 2014.
Trend.az. (2011). Energy. http://en.trend.az/business/energy/1924964.html Accessed 18 Jan 2014.
UNDP. (2013). Energy efficient design and construction of residential buildings. http://www.kz.undp.org/content/kazakhstan/en/home/operations/projects/environment_and_energy/energy-efficient-design-and-construction-of-residential-building/ Accessed 17 Jan 2014.
USDoE. (2008). US Department of Energy. Overview. http://www.eia.gov/oiaf/aeo/overview.html Accessed 13 Feb 2014.
Wise, A. F. E. (1970). Wind effects due to groups of buildings. Royal Society Symposium, Architectural Aerodynamics, London.
Zhai, Z. (2006). Application of computational fluid dynamics in building design: aspects and trends. Indoor and Built Environment, 15, 305–313.
Acknowledgments
The authors would like to thank the “BI Group” Construction Company for making available data on building complexes.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Tokbolat, S., Al-Zubaidy, S. & Badr, A. Low-energy design for future housing developments in Kazakhstan: a case study. Energy Efficiency 9, 211–222 (2016). https://doi.org/10.1007/s12053-015-9358-y
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s12053-015-9358-y