AbstractAbout AuthorsReferences
An innovative technology of passive assembly of prefabricated elements in the system of volume-block housing construction is proposed, which will make it possible to create a building with the maximum possible energy-efficient design due to using elements, such as hinges, to accelerate the installation of prefabricated elements. This technology can also solve a serious problem in the housing sector in countries such as Iraq, Syria, Iran. The results show that it is possible to reduce the number of technological processes in some cases by half, which leads to a reduction in labor costs and time. This method helps to speed up the process of installing elements on the construction site by reducing the number of operations. The installation method of the VBC construction system was developed with the aim of reducing energy costs and machine intensity, due to the use of passive mounting elements in the construction process.
S.A. SYCHEV1, Doctor of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.);
G.M. BADIN3, Doctor of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.);
ABASS Agadeer А.1,2, postgraduate (This email address is being protected from spambots. You need JavaScript enabled to view it.);
AL-HABEEB Ahmed A.1, postgraduate, (This email address is being protected from spambots. You need JavaScript enabled to view it.)
G.M. BADIN3, Doctor of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.);
ABASS Agadeer А.1,2, postgraduate (This email address is being protected from spambots. You need JavaScript enabled to view it.);
AL-HABEEB Ahmed A.1, postgraduate, (This email address is being protected from spambots. You need JavaScript enabled to view it.)
1 Ural Federal University named after the First President of Russia B.N. Yeltsin” (19, Mira Street, Yekaterinburg, Sverdlovsk oblast 620002, Russian Federation)
2 University of Diyala (Diyala city, 32001, Iraq)
3 Russian Academy of Architecture and Construction Sciences (19, Noviy Arbat Street, Moscow, 127025, Russian Federation)
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4. Олейник П.П. Индустриально-мобильные методы возведения предприятий, зданий и сооружений. М.: АСВ, 2021. 488 с.
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10. Matic D., Calzada J.R., Todorovic M.S., Eri´с M., Babin M. Cost-effective energy refurbishment of prefabricated buildings in Serbia. In cost-effective energy efficient building retrofitting. Woodhead Publishing. 2017. No. 10, pp. 455–487. DOI: https://doi.org/10.1016/B978-0-08-101128-7.00016-2.
11. Gunawardena T., Karunaratne R., Mendis P., Ngo T. Prefabricated construction technologies for the future of Sri Lanka’s construction industry. In Proceedings of the 7th International Conference on Sustainable Built Environment (ICSBE). Kandy, Sri Lanka. 2016, pp. 16–18.
12. Сычёв С.А., Бадьин Г.М. Технологии строительства и реконструкции энергоэффективных зданий. СПб.: БХВ-Петербург, 2017. 464 c.
12. Sychev S.A., Bad’in G.M. Tekhnologii stroitel’stva i rekonstruktsii ehnergoehffektivnykh zdanii [Technologies of construction and reconstruction of energy-efficient buildings]. Saint Petersburg: BHV-Peterburg. 2017. 464 p.
13. Вильман Ю.А. Совершенствование технологий сборки конструкций многоэтажных домов // Вестник ВолгГАСУ. 2013. № 4 (29). С. 21–27.
13. Vil’man Yu.A. Improvement of technologies for assembling structures of multi-storey buildings. Vestnik VolGGASU. 2013. No. 4 (29), pp. 21–27. (In Russian).
14. Gallo P., Romano R., Belardi E. Smart Green Prefabrication: Sustainability Performances of Industrialized Building Technologies. Sustainability. 2021. No. 13 (9), p. 4701. DOI: https://doi.org/10.3390/su13094701
1. Sychev S.A. Assessment of the manufacturability of installation of buildings and structures from factory-ready modules. Global’nyi nauchnyi potentsial. 2015. No. 9, pp. 37–41. (In Russian).
2. Waheeb R.A., Andersen B.S. Causes of Problems in Post-Disaster Emergency Re-Construction Projects–Iraq as a Case Study. Public Works Management & Policy. 2022. Vol. 27 (1), pp. 61–97. DOI: https://doi.org/10.1177/1087724X21990034
3. Сычёв С.А. Основы строительного производства и технические инновации. СПб.: СПбГАСУ, 2015. 147 с.
3. Sychev S.A. Osnovy stroitel’nogo proizvodstva i tekhnicheskie innovatsii: uchebnoe posobie [Fundamentals of construction production and technical innovations]. Saint Petrsburg: SPBGASU. 2015. 147 p.
4. Олейник П.П. Индустриально-мобильные методы возведения предприятий, зданий и сооружений. М.: АСВ, 2021. 488 с.
4. Oleinik P.P. Industrial’no-mobil’nye metody vozvedeniya predpriyatii, zdanii i sooruzhenii [Industrial-mobile methods of construction of enterprises, buildings and structures]. Moskow: ASV. 2021. 488 p.
5. Ибрагим И.Ф. Анализ конструктивных и организационно-технологических решений домостроения в Ираке и в России // Вестник науки и творчества. 2017. № 5 (31). С. 33–36.
5. Ibragim I.F. Analysis of constructive and organizational-technological solutions of housing construction in Iraq and in Russia. Vestnik Nauki i Tvorchestva. 2017. No. 5 (31), pp. 33–36. (In Russian).
6. Жигулина А.Ю., Мизюряев С.А. Объемно-блочное домостроение как вариант решения жилищной проблемы. В кн.: Традиции и инновации в строительстве и архитектуре. Строительные технологии. 2015. № 2. С. 124–128.
6. Zhigulina A.Yu., Mizyuryaev S.A. Ob»emno-blochnoe domostroenie kak variant resheniya zhilishchnoi problem. V kn.: Traditsii i innovatsii v stroitel’stve i arkhitekture. [Stroitel’nye tekhnologii. Volumetric-block housing construction as a solution to the housing problem. In the book: Traditions and Innovations in Construction and Architecture. Construction technologies]. 2015. No. 2, pp. 124–128. (In Russian).
7. Сычёв С.А. Технологические принципы ускоренного домостроения, перспектива автоматизированной и роботизированной сборки зданий // Промышленное и гражданское строительство. 2016. № 3. С. 66–70.
7. Sychev S.A. Technological principles of accelerated housing construction, the prospect of automated and robotic assembly of buildings. Promyshlennoe i grazhdanskoe stroitel’stvo. 2016. No. 3, pp. 66–70. (In Russian).
8. Navaratnam S., Ngo T., Gunawardena T., Henderson D. Performance review of prefabricated building systems and future research in Australia. Buildings. 2019. No. 2, p. 38. DOI: https://doi.org/10.3390/buildings9020038
9. Сычев С.А., Бадьин Г.М. Интерактивный строительный проект по методу настройки на основе BIM-технологий для скоростного модульного строительства // Архитектура и машиностроение. 2016. № 4. С. 36–41.
9. Sychev S.A., Bad’in G.M. Interactive construction project by the method of customization based on BIM technologies for high-speed modular construction. Arkhitektura i mashinostroenie. 2016. No. 4, pp. 36–41. (In Russian).
10. Matic D., Calzada J.R., Todorovic M.S., Eri´с M., Babin M. Cost-effective energy refurbishment of prefabricated buildings in Serbia. In cost-effective energy efficient building retrofitting. Woodhead Publishing. 2017. No. 10, pp. 455–487. DOI: https://doi.org/10.1016/B978-0-08-101128-7.00016-2.
11. Gunawardena T., Karunaratne R., Mendis P., Ngo T. Prefabricated construction technologies for the future of Sri Lanka’s construction industry. In Proceedings of the 7th International Conference on Sustainable Built Environment (ICSBE). Kandy, Sri Lanka. 2016, pp. 16–18.
12. Сычёв С.А., Бадьин Г.М. Технологии строительства и реконструкции энергоэффективных зданий. СПб.: БХВ-Петербург, 2017. 464 c.
12. Sychev S.A., Bad’in G.M. Tekhnologii stroitel’stva i rekonstruktsii ehnergoehffektivnykh zdanii [Technologies of construction and reconstruction of energy-efficient buildings]. Saint Petersburg: BHV-Peterburg. 2017. 464 p.
13. Вильман Ю.А. Совершенствование технологий сборки конструкций многоэтажных домов // Вестник ВолгГАСУ. 2013. № 4 (29). С. 21–27.
13. Vil’man Yu.A. Improvement of technologies for assembling structures of multi-storey buildings. Vestnik VolGGASU. 2013. No. 4 (29), pp. 21–27. (In Russian).
14. Gallo P., Romano R., Belardi E. Smart Green Prefabrication: Sustainability Performances of Industrialized Building Technologies. Sustainability. 2021. No. 13 (9), p. 4701. DOI: https://doi.org/10.3390/su13094701
For citation: Sychev S.A., Badin G.M., Abass Agadeer A., Al-Habeeb Ahmed A. Passive methods of mounting elements of volume-block housing construction in conditions of limited energy resources. Zhilishchnoe Stroitel’stvo [Housing Construction]. 2022. No. 10, pp. 27–32. (In Russian). DOI: https://doi.org/10.31659/0044-4472-2022-10-27-32