Efficiency of BIM-technologies application in dismantling of buildings

Introduction. The authors of the paper studied the matter of expediency and efficiency of the use of the technologies of information modelling or building informational modelling (BIM-technologies) during the implementation of investment-and-construction projects. The attention of the authors was concentrated on the stage of dismantling of buildings and structures as well as on management of the waste which is formed at the same time.

Materials and methods. The works by domestic and foreign authors and also the maintenance of the official sites of the construction organizations, the data describing experience of dismantling of buildings, which are contained in printing editions, scientific publications, practical research, Internet, materials of academic-and-research conferences, seminars and forums, publications of Rosstat served as the materials of the research. During preparation of the paper the authors used the system and process approaches, such methods of scientific research as observation, the description, quantitative and statistical analysis, the comparative and comparative analysis.

Results. The authors studied the innovation technologies, which can be introduced in the activities for dismantling of buildings and structures. Domestic and foreign experience of the use of information technologies for dismantling was analyzed, benefits of BIM-technologies were revealed.

Conclusions. As the result of the conducted research the authors made the conclusion, that the implementation of the BIM-technologies in organization activity performing dismantling of buildings and structures allows to gain some positive effects: to reduce terms of works, to reduce their cost, to increase security, to reduce impact of negative factors on an ecological situation and on the comfort of accommodation, to improve waste management. Nevertheless, there are several barriers of introduction and effective use of BIM technologies in the dismantling activity. Thus, the most perspective directions of further researches were formulated.

1. Vasil’eva E., Bizina E. Use of BIM technologies in the house construction in the Russian Federation. Construction and Architecture. 2023; 11(4):37. DOI: 10.29039/2308-0191-2023-11-4-37-37. EDN OMYKEA. (rus.).

2. Ozhgibesova K.E., Mingareeva R.R., Sondueva S.R. Information modeling technologies (TIM) in the construction of the Russian Federation: features of application at various stages of the object’s life cycle. Humanitarian, Socio-economic and Social Sciences. 2021; 11-1:157-159. DOI: 10.23672/t7479-5092-7107-a. EDN YVOGXG. (rus.).

3. Bogdanov A., Zaitsev V., Khalitova K. Application of BIM-technologies during the construction and operation of buildings and structures. E3S Web of Conferences. 2021; 274:06009. DOI: 10.1051/e3sconf/202127406009

4. Aryani Y., Purwana R., Herdiansyah H., Suryabrata J.A. Bridging the gap in green building research: the role of post occupancy evaluation. Urbanism. Architecture. Constructions. 2025; 16(1):27-50.

5. Cheng J.C.P., Ma L.Y.H. A BIM-based system for demolition and renovation waste estimation and planning. Waste Management. 2013; 33(6):1539-1551. DOI: 10.1016/j.wasman.2013.01.001

6. Jayasinghe L.B., Waldmann D. Development of a BIM-Based Web Tool as a Material and Component Bank for a Sustainable Construction Industry. Sustainability. 2020; 12(5):1766. DOI: 10.3390/SU12051766

7. Kresnanto N.C., Ramadhan R.I., Willdan M., Putra P.B.P. BIM’s Contribution as A Sustainable Construction Accelerator. Applied Research on Civil Engineering and Environment (ARCEE). 2023; 4(1):38-52. DOI: 10.32722/ARCEE.V4I01.5333

8. Li C.Z., Zhen Y., Wu H., Chen Z., Xiao B., Tam V.W.Y. The application of BIM in the AECO industry. Journal of Civil Engineering and Management. 2023; 29(3):202-222. DOI: 10.3846/jcem.2023.18076

9. Bakchan A., Faust K.M. Construction waste generation estimates of institutional building projects: Leveraging waste hauling tickets. Waste Management. 2019; 87:301-312. DOI: 10.1016/j.wasman.2019.02.024

10. Guerra B.C., Bakchan A., Leite F., Faust K.M. BIM-based automated construction waste estimation algorithms: The case of concrete and drywall waste streams. Waste Management. 2019; 87:825-832. DOI: 10.1016/j.wasman.2019.03.010

11. Xu J., Shi Y., Xie Y.C., Zhao S.W. A BIM-based construction and demolition waste information management system for greenhouse gas quantification and reduction. Journal of Cleaner Production. 2019; 229:308-324. DOI: 10.1016/j.jclepro.2019.04.158

12. Shilkina S. BIM-technologies in solving the problems of construction waste management. Construction and Architecture. 2023; 11(1):6. DOI: 10.29039/2308-0191-2022-11-1-6-6. EDN IHDUCG. (rus.).

13. Ibe C.N. Implementing BIM Technology for Effective Construction and Demolition Waste Management. 2024 IEEE Conference on Technologies for Sustainability (SusTech). 2024; 204-211. DOI: 10.1109/sustech60925.2024.10553546

14. Liphadzi N.M., Musonda I., Onososen A. The use of building information modelling tools for effective waste management : а systematic review. IOP Conference Series: Earth and Environmental Science. 2022; 1101(6):062001. DOI: 10.1088/1755-1315/1101/6/062001

15. Giel B., Issa R. Return on Investment Analysis of Using Building Information Modeling in Construction. Journal of Computing in Civil Engineering. 2013; 27(5):511-521. DOI: 10.1061/(ASCE)CP.1943-5487.0000164

16. Neelamkavil J., Ahamed S. The Return on Investment from BIM-driven Projects in Construction. 2012. DOI: 10.4224/20374669

17. Hamidi B., Bulbul T., Pearce A., Thabet W. Potential Application of BIM in Cost-Benefit Analysis of Demolition Waste Management. Construction Research Congress 2014. 2014; 279-288. DOI: 10.1061/9780784413517.029

18. Chahrour R., Hafeez M.A., Ahmad A.M., Sulieman H.I., Dawood H., Rodriguez-Trejo S. et al. Cost-benefit analysis of BIM-enabled design clash detection and resolution. Construction Management and Economics. 2021; 39(1):55-72. DOI: 10.1080/01446193.2020.1802768

19. Zou Y., Feng W. Cost optimization in the construction of prefabricated buildings by using BIM and finite element simulation. Soft Computing. 2023; 27(14):10107-10119. DOI: 10.1007/S00500-023-08239-0

20. Liu S., Meng X., Tam C. Building Information Modeling Based Building Design Optimization for Sustainability. Energy and Buildings. 2015; 105:139-153. DOI: 10.1016/j.enbuild.2015.06.037

21. Farnsworth C.B., Beveridge S., Miller K.R., Christofferson J.R. Application, Advantages, and Methods Associated with Using BIM in Commercial Construction. International Journal of Construction Education and Research. 2015; 11(3):218-236. DOI: 10.1080/15578771.2013.865683

22. Wetzel E.M., Thabet W.Y. The use of a BIM-Based Framework to Support Safe Facility Management Processes. Automation in Construction. 2015; 60:12-24. DOI: 10.1016/j.autcon.2015.09.004

23. Avsatthi B. Top 8 BIM Technology Trends That Will Dominate the AEC Industry. AECbytes. 2023. URL: https://www.aecbytes.com/viewpoint/2023/issue_110.html

24. Ge X.J., Livesey P., Wang J., Huang S., He X., Zhang C. Deconstruction waste management through 3d reconstruction and BIM: a case study. Visualization in Engineering. 2017; 5(1). DOI: 10.1186/s40327-017-0050-5

25. Lee H.W., Oh H., Kim Y., Choi K. Quantitative Analysis of Warnings in Building Information Modeling (BIM). Automation in Construction. 2015; 51:23-31. DOI: 10.1016/j.autcon.2014.12.007

26. Lunyakov M.A., Bakrunov Yu.O., Vasilyeva E.Yu. Innovations in carrying out monitoring of the technical equipment of residential buildings at the maintenance stage. Financial Economy. 2022; 4:298-303. EDN OFPVOK. (rus.).

27. Vasilyeva E.Yu., Bolshakov R.A., Kozhukhov L.E., Chizhova A.Yu. Process of implementation of the innovation technologies in the construction organization activity. Financial Management. 2025; 2:12-24. EDN KAEGFF. (rus.).