Information modelling of water supply and sanitation systems

Introduction. Information modelling technologies are becoming increasingly popular in the design field, taking the process of construction and operation of civil and industrial buildings, linear objects to a new, progressive level. In world practice, digital models of buildings and structures are also created in order to carry out their reconstruction. Russian legislation promotes the transition of the construction industry to the creation of digital information models: roadmaps for the introduction of information modelling technologies, regulatory documents are being created, grants for the development of domestic software are provided. Research objectives: consideration of the general procedure for modelling building water supply and sanitation systems in the Russian BIM Renga system, formulation of recommendations for optimizing design work, review of regulatory documentation in force in Russia in the field of information modelling.

Materials and methods. Theoretical research methods: review and analysis of Russian regulatory documentation in the field of information modelling. Empirical methods included the use of Renga BIM system tools in the preparation of an information model of engineering systems.

Results. The current regulatory documentation in the field of information modelling (codes of rules, state standards, guidelines) is considered. The procedure for modelling the engineering systems of a building (water supply and sewerage) is described with the use of explanatory illustrative material.

Conclusions. The current regulatory documentation in the field of information modelling (codes of practice, state standards, guidelines) is considered. The procedure for modelling the engineering systems of a building (water supply and sewerage) is described with the use of explanatory illustrative material.

1. Brezgin Yu.I., Kuzin V.V. Analysis of the use of information and digital technologies in the implementation of the national project “Housing and urban environment”. Innovative potential of the development of science in the modern world: achievements and innovations : collection of scientific articles based on the materials of the VII International Scientific and Practical Conference. 2022: 61-72. EDN UZSBFC. (rus.).

2. Rinchen S., Banihashemi S., Alkilani S. Driving digital transformation in construction: Strategic insights into building information modelling adoption in developing countries. Project Leadership and Society. 2024; 5:100138. DOI: 10.1016/j.plas.2024.100138

3. Vyrodova I.G., Nikolovsky A.V., Chebotova A.A., Shikhovtsov A.A. Application of BIM technologies in the design of buildings and structures in Krasnodar. Science Prospects. 2022; 2(149):49-52. EDN KZGNGG. (rus.).

4. Peng Y., Au-Yong C.P., Myeda N.E. Knowledge graph of building information modelling (BIM) for facilities management (FM). Automation in Construction. 2024; 165:105492. DOI: 10.1016/j.autcon.2024.105492

5. Grakhov V.P., Kislyakova Yu.G., Mokhna-chev S.A., Simakov N.K. The relevance of digital building construction in industry. Russia and the world: development of civilizations. Innovation and conservatism: finding a balance : materials of the XII international scientific and practical conference. 2022; 88-91. EDN IHQTKL. (rus.).

6. Puerto A., Castañeda K., Sanchez O., Peña C.A., Gutierrez L., Saenz P. Building information modeling and complementary technologies in heritage buildings : а bibliometric analysis. Results in Engineering. 2024; 22:102192. DOI: 10.1016/j.rineng.2024.102192

7. Salova N.N. Evaluation of the economic efficiency of the implementation of BIM technologies on the example of a project organization in construction. Actual Issues of the Modern Economy. 2020; 11:868-880. DOI: 10.34755/IROK.2020.40.92.059. EDN XAYRST. (rus.).

8. Guizar Dena A.J., Garcia Hipola M., Bandera C.F. Optimization testing for the modeling and characterization of three-dimensional elements to enhance interoperability from building information modeling (BIM) to building energy modeling (BEM). Energy and Buildings. 2024; 317:114394. DOI: 10.1016/j.enbuild.2024.114394

9. Uzaev M.A., Uzaeva A.A., Uzaeva A.A. Integrated organizational and technological design of indoor stadiums using BIM technologies. Construction Economy. 2024; 3:252-256. EDN IYWPSL. (rus.).

10. Biswas H.K., Sim T.Y., Lau S.L. Impact of Building Information Modelling and Advanced Technologies in the AEC Industry : а Contemporary Review and Future Directions. Journal of Building Engineering. 2024; 82:108165. DOI: 10.1016/j.jobe.2023.108165

11. Tonconog M.P., Subbotin O.S. Information modeling in the field of architectural design (BIM modeling). Vector of modern science : collection of abstracts based on the materials of the International Scientific and Practical Conference of Students and Young Scientists. 2022; 935-936. EDN REAQVF. (rus.).

12. Abuhussain M.A., Waqar A., Khan A.M., Othman I., Alotaibi B.S., Althoey F. et al. Integrating Buil-ding Information Modeling (BIM) for optimal lifecycle management of complex structures. Structures. 2024; 60:105831. DOI: 10.1016/j.istruc.2023.105831

13. Bueno M., Bosche F. Pre-processing and analysis of building information models for automated geometric quality control. Automation in Construction. 2024; 165:105557. DOI: 10.1016/j.autcon.2024.105557

14. Shaikhutdinova F.F., Araratyan L.S., Pavlova Yu.M. Information modeling of the closure of nuclear power plants. Energy conservation in industry : collection of scientific and practical works. 2023; 180-185. EDN YGFUKN. (rus.).

15. Sheina S.G., Umniakova N.P., Fedorov A.A. Information modeling as the basis for the design of energy-efficient buildings. Proceedings of Higher Educational Institutions. Textile Industry Technology. 2019; 4(382):202-206. EDN VATQQV. (rus.).

16. Carvalho J.P., Bragança L., Mateus R. Automating building sustainability assessment using building information modeling : а case study. Journal of Building Engineering. 2023; 76:107228. DOI: 10.1016/j.jobe.2023.107228

17. Paremain H.W.P., Toll D.G. Heritage building information modeling : a case study of Kasthamandap, Nepal. Proceedings of the Institution of Civil Engineers — Engineering History and Heritage. 2023; 176(1):25-34. DOI: 10.1680/jenhh.21.00103

18. Xiang Y., Mahamadu A.M., Florez-Perez L. Engineering information format utilisation across building design stages : аn exploration of BIM applicability in China. Journal of Building Engineering. 2024; 95:110030. DOI: 10.1016/j.jobe.2024.110030

19. Shin M.H., Lee H.K., Kim H.Y. Benefit–cost analysis of Building Information Modeling (BIM) in a railway site. Sustainability. 2018; 10(11):4303. DOI: 10.4303.10.3390/su10114303

20. Liao L., Teo E.A.L., Chang R., Zhao X. Diffusion of building information modeling in building projects and firms in Singapore. Sustainability. 2020; 12(18):7762. DOI: 10.3390/su12187762