Assessment of the morphological composition of secondary construction waste from destruction
DOI:
https://doi.org/10.26906/znp.2025.65.4214Keywords:
region, secondary construction waste, destruction, morphological composition, recycling, utilization, processing, waste managementAbstract
The issues of post-war reconstruction of territories and settlements that suffered extensive damage as a result of hostilities are considered. Rational design and construction solutions are proposed that allow maximum use of the foundations of destroyed buildings for further reconstruction. It is determined that the planning solutions for the quarter development of industrial cities are imperfect and require updating in accordance with modern principles. A solution that significantly reduces the amount of work involved in dismantling the underground structures of buildings is to use them for the construction of new reconstruction objects. A combined solution is proposed for the joint use of the foundation array of a destroyed building and a monolithic grillage on bored piles. The use of diamond drilling technologies allows for the effective installation of piles in complex, swampy areas. It is proposed to construct the structure in the form of a system of soil foundation, artificial foundation, connected by a system of piles and foundation frames.
References
1. Dvorkin, L. Y., & Myronenko, A. V. (2019). Building materials and products using industrial waste. Rivne: National University of Water and Environmental Engineering.
2. Morkovska, N. H., & Abdelrahem, A. (2019). Recycling of construction waste generated in Ukraine. Municipal Economy of Cities, 147(1), 210–214.
3. Smal, M. V., Dziubynska, O. V., & Shelkovych, O. V. (2017). Global experience of concrete reuse in construction production. Modern Technologies and Methods of Calculations in Construction, 7, 233–238.
4. Popovych, O. R., Zakharko, Y. M., & Malovanyi, M. (2013). Problems of utilization and recycling of construction waste. Bulletin of Lviv Polytechnic National University, 755, 321–324.
5. Khrystych, O. V. (2023). Fine aggregates of asphalt concrete mixtures from recycled construction debris. Modern Technologies, Materials and Structures in Construction, 35(2), 49–55. https://doi.org/10.31649/2311-1429-2023-2-49-55
6. Shuvaiev, A. (2021). Tools for involving construction and demolition waste in the secondary economic cycle in the context of their classification features. Grail of Science, 600–605. https://doi.org/10.36074/grail-of-science.19.11.2021.114
7. Abbas, A., et al. (2006). Environmental benefits of green concrete. In Proceedings of the 2006 IEEE EIC Climate Change Conference (Ottawa, ON, Canada, May 10–12, 2006). https://doi.org/10.1109/EICCCC.2006.277204
8. Abbas, A., Fathifazl, G., Isgor, O. B., Razaqpur, A. G., Fournier, B., & Foo, S. (2011). Creep and drying shrinkage characteristics of concrete produced with coarse recycled concrete aggregate. Cement and Concrete Composites, 33(10), 1026–1037. https://doi.org/10.1016/j.cemconcomp.2011.08.004
9. Abbas, A., Fathifazl, G., Isgor, O. B., Razaqpur, A. G., Fournier, B., & Foo, S. (2009). Durability of recycled aggregate concrete designed with equivalent mortar volume method. Cement and Concrete Composites, 31, 555–563. https://doi.org/10.1016/j.cemconcomp.2009.02.012
10. Husiev, V. O., Smyrnov, A. S., & Nikiforova, T. D. (2022). Use of concrete mixtures based on recycled construction waste products for the construction of buildings using 3D printing technology. In We Will Win – We Will Rebuild! Proceedings of the All-Ukrainian Scientific and Practical Forum (Dnipro, June 29–30, 2022, pp. 40–41).
11. Savytskyi, M., & Smyrnov, A. (2024). Properties of recycled coarse aggregates obtained by crushing concrete waste. Building Structures: Theory and Practice, 14, 19–28. https://doi.org/10.32347/2522-4182.14.2024.19-28
12. Savytskyi, M. V., & Smyrnov, A. S. (2023). Features of using crushed concrete scrap as coarse aggregate for concrete. Ukrainian Journal of Civil Engineering and Architecture, 6(18), 111–117. https://doi.org/10.30838/J.BPSACEA.2312.261223.111.1013
13. Shyshkin, E., Haiko, Y., & Chernonosova, T. (2024). Ways of recycling construction waste during the post-war reconstruction of destroyed cities. Urban Planning and Territorial Planning, 85, 679–697. https://doi.org/10.32347/2076-815x.2024.85.679-697
14. Damaged in UA. (n.d.). Damage assessment. https://damaged.in.ua/damage-assessment
15. Cabinet of Ministers of Ukraine. (2017). On approval of the National Waste Management Strategy in Ukraine until 2030 (Order No. 820-r). https://zakon.rada.gov.ua/laws/show/820-2017-р
16. Cabinet of Ministers of Ukraine. (2019). On the use of production waste in road construction (Order No. 1420-r). https://zakon.rada.gov.ua/laws/show/1420-2019-р
17. Cabinet of Ministers of Ukraine. (2022). Procedure for performing demolition works of facilities damaged or destroyed as a result of emergencies, military actions or terrorist acts (Resolution No. 474). https://zakon.rada.gov.ua/laws/show/474-2022-п
Downloads
Published
Issue
Section
License
Copyright (c) 2025 Dmytro Shvydkyi, Vitaliy Shvets, Kostiantyn Sokolenko, Valeriy Sokolenko
This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.
