This is an open access article distributed under the CC BY 4.0
Volume 19 article 756 pages: 1 - 8
The article touches upon the problem of energy saving and increasing energy efficiency in the construction sector,
which consumes a significant share of the country's energy resources. The issues of rational use of energy resources
with the aspects of energy saving, energy efficiency and, correspondingly, environmental problems are becoming
increasingly important, and their solution has become a strategic task for Kazakhstan. In order to give momentum to
energy saving measures carried out in Kazakhstan, a number of laws, bylaws and programs related to the rational
use of energy resources and energy efficiency have been adopted. To solve this problem, it is planned to carry out
targeted measures to eliminate existing political, legislative, technical and information barriers. A regulatory technical
base is being developed based on the most recent advances of construction science.
1. Kudrevich, O. O. (2018). Energy efficiency as a tool for achieving sustainable development objectives. Proceedings of the IV International Scientific and Practical Conference "Technical Regulation of the Construction Industry in Modern Conditions", 17-21.
2. KAZENERGY Association. (2014). Review of the State Policy of the Republic of Kazakhstan in Energy Saving and Energy Efficiency. Brussels.
3. Office of the President of the Republic of Kazakhstan. (2012). Law of the Republic of Kazakhstan No. 541-IV "On Energy Saving and Energy Efficiency Improvement". https://policy.asiapacificenergy.org/ru/node/135
4. United Nations Development Programme in Kazakhstan. Global Environment Facility. (2015). Why is it profitable to construct energy-efficient buildings? Astana.
5. Tabunshchikov, Yu. A., Malyavina, E. G., & Dionov, S. N. (2015). Mechanical ventilation - a way to comfort and energy saving. Energy Conservation, 3, 5-9.
6. Danilevsky, L. N. (2020). Prospects and directions of development of energy-efficient construction in the Republic of Belarus. Energy Efficiency, Minsk.
7. Gorshkov, A. S., Vatin, N. I., Rymkevich, P. P., Mozhaysky, A. F., & Kydrevich, O. O. (2018). Payback period of investments in energy saving. Magazine of Civil Engineering, 2(78), 65-75. doi: 10.18720/ MCE.78.5
8. United Nations Development Programme and Glob¬al Environment Facility "Energy-efficient design and construction of residential buildings". (2011). Assessment of energy efficiency, accounting and monitoring of energy consumption and greenhouse gas emissions in the residential buildings sector. Astana.
9. Sharipov, R. Zh., & Sabitbek, I. R. (2018). Implementation of the development program of standard technical documents of the Republic of Kazakhstan on the assessment of energy efficiency of buildings. Bulletin of JSC "KazNIISA", 4(80).
10. Directive 2010/31/EU of the European Parliament and of the Council of 19 May 2010 on the energy performance of buildings. https://eur-lex.europa.eu/ legal-content/EN/TXT/?uri=CELEX%3A32010L0031
11. Terekhova, I. A., Danilevsky, L. N., & Terekhov, S. V. (2012). Main issues of designing of energy efficient buildings. Stroitelnaya Gazeta.
12. Danilevsky, L. N. (2013). Recommendations for elimination of a gap between the national standards of energy characteristics and the standards adopted in the EU countries, applied to the newly constructed buildings. Minsk.
13. Tarnagurskiy, A. V. (2016). Justification, recommendations and draft regulations for step-by-step implementation of the energy efficiency certification system for buildings. Minsk.
14. Van Chien, N. (2020). Energy consumption, income, trading openness, and environmental pollution: Testing environmental Kuznets curve hypothesis. Journal of Southwest Jiaotong University, 55(1). doi: 10.35741/issn.0258-27184.108.40.206
15. Ghani, L. A., Mahmood, N. Z., Muhammad, Z., Bahri, S., & Saputra, J. (2019). The Energy Flow for Maize Production: an Application of Material Flow Analysis (MFA) and Giddens Structural Theory. Journal of Southwest Jiaotong University, 54(4). doi: 10.35741/ issn.0258-27220.127.116.11
16. Kuznetsova, E. L., & Makarenko, A. V. (2019). Mathematical model of energy efficiency of mechatronic modules and power sources for prospective mobile objects. Periodico Tche Quimica, 16(32), 529-541.
17. Semin, A. N., Ponkratov, V. V., Levchenko, K. G., Pozdnyaev, A. S., Kuznetsov, N. V., & Lenkova, O. V. (2019). Optimization model for the Russian electric power generation structure to reduce energy intensity of the economy. International Journal of Energy Economics and Policy, 9(3), 379-387. doi: 10.32479/ ijeep.7552
18. Fedotova, O., & Tabekina, O. (2013). Analysis of the current state of Russian enterprises greening. Journal of Contemporary Economics Issues, 1. doi: 10.24194/11301
19. Tabekina, O., & Fedotova, O. (2013). Features of the process of ecologization of Russian enterprises. Journal of Contemporary Economics Issues, 2. doi: 10.24194/21307