Dissipative structures in the management system of industrial research and production complexes

Introduction. The complexity and ambition of the tasks currently being solved by the construction industry indicate the need for a new interpretation of their formulation, especially with regard to ensuring scientific leadership and technological sovereignty. In this logic, it is possible to consider an industrial scientific and production complex as a system with a dissipative organizational structure. In this regard, the paper provides a definition of dissipative organizational structures, their properties and place in the organizational and economic mechanism of management of an industrial scientific and industrial complex are indicated. The conducted research made it possible to show the prospects for the use of dissipative structures in the construction management system, to formulate recommendations on their formation and functioning.

Materials and methods. The solution of the research tasks involves a systematic approach to the management of industrial scientific and industrial complexes, the use of life cycle theories, logistics of regulatory influences, as well as methods of structural and functional analysis, deduction and induction. The methodological basis, in addition to these research tools, is the scientific foundation formed by domestic and foreign scientists on this issue.

Results. The features of the formation and functioning of management systems of industrial scientific and industrial complexes are established, dissipative organizational structures are terminologically identified, their properties are determined, as well as the possibilities of use in the system of an industrial scientific and industrial complex, the basic provisions of the organizational and economic mechanism of functioning of such complexes based on dissipative structures for which the effectiveness of application is determined, the prospects for the use of dissipative structures in the construction management system, recommendations on their formation and functioning are formulated.

Conclusions. An industrial scientific and production complex can be considered as a system with a dissipative organizational structure. In this case, the main focus of management is not to find the balance of the system, but to ensure development largely due to its self–organization. Such a presentation of the industrial scientific and production complex will contribute to improving its effectiveness.

1. Kolosova E. BIM technologies in investment and construction activities. The results of the NPI discussion club. Geoinfo. 2022; 2:32-35. EDN GAVEVM. (rus.).

2. Khripko T.V. Research of application of information modeling technologies in the construction industry of KNR. Scientific and Technical Volga region Bulletin. 2021; 2:50-52. EDN OWZZEX. (rus.).

3. Khripko T. Mathematical modeling of failure of port control systems. IOP Conference Series : Materials Science and Engineering. 2021; 1030(1):012101. DOI: 10.1088/1757-899X/1030/1/012101

4. Zharov Ya.V. Building information modeling based on block-cluster structure. Rationing and Remuneration of Labor in Construction. 2019; 11:10-14. EDN XTWNSE. (rus.).

5. Zharov Ya.V. Organizational technological design in construction based on an intelligent planning unit. Bulletin of Civil Engineers. 2019; 6(77):193-199. DOI: 10.23968/1999-5571-2019-16-6-193-199. EDN RQXZDJ. (rus.).

6. Kievsky I.L., Argunov S.V., Zharov Ya.V., Yurgaitis A.Yu. Algorithmization of planning, management and information processing systems in construction. Industrial and Civil Engineering. 2022; 11:14-24. DOI: 10.33622/0869-7019.2022.11.14-24. EDN AGNCHY. (rus.).

7. Kochenkova E.M., Denisov A.V. Information modeling in solving environmental protection issues of construction facilities. Actual problems of the construction industry and education — 2022 : collection of reports of the Third National Scientific Conference. 2023; 583-587. EDN BYPLIE. (rus.).

8. Kochenkova E.M. Environmental protection. Features of information modeling at the stages of the high-rise building life cycle. Construction — formation of the living environment : collection of materials of the seminar of young scientists of the XXV International Scientific Conference. 2022; 115-120. EDN XSOQZK. (rus.).

9. Burenin V.S., Ezersky V.A., Monastyrev P.V. Investigation of modern trends in the design of residential buildings in Russia and abroad. Architecture and Time. 2017; 5:2. EDN YMXHRR. (rus.).

10. Silka D., Ermolaev E. Methodological aspects of the new model of building complex. Online journal of Science Studies. 2014; 1(20):34. EDN QIGNGG. (rus.).

11. Simanovich V.M., Ermolaev E.E. Implementation of construction, reconstruction, capital repairs of a capital construction facility. Rationing and Remuneration of Labor in Construction. 2018; 12:4-8. EDN WIDEBF. (rus.).

12. Monastyrev P.V., Evdokimtsev O.V., Gavri-kov V.A., Zelenin G.V. Institute of Architecture, Construction and Transport in the problems of sustainable development of the region. Sustainable development of the region: architecture, construction and transport : materials of the VIII-th International Scientific and Practical Conference. 2021; 46-68. EDN UMONJC. (rus.).

13. Zakharov P.N., Matveev M.Yu., Khizhnyakov D.M. Analysis of approaches to assessing the level of innovation in the development of construction organizations. Innovations in the sectors of the national economy, as a factor in solving socio-economic problems of our time : collection of reports and materials of the IV International Scientific and Practical Conference. 2014; 143-151. EDN TKNHQT. (rus.).

14. Korobko V.I., Kardanskaya N.L., Matveev M.Yu. Philosophical categories of development in management theory. Innovations in the sectors of the national economy, as a factor in solving socio-economic problems of our time : collection of reports and materials of the IV International Scientific and Practical Conference. 2014; 8-14. EDN TKNHEV. (rus.).

15. Sborshchikov S.B. Logistics of regulatory impacts in the investment and construction sector (theory, methodology, practice) : dis. … doc. economics. Moscow, 2012; 361. EDN QGBVJV. (rus.).

16. Sborshchikov S., Lazareva N. Reengineering of construction organizations and reengineering of the construction industry. Russian Engineer. 2022; 3(76):45-47. EDN XWACRC. (rus.).

17. Sborshchikov S.B., Zhuravlev P.A., Lazareva N.V. Project management: engineering and reengineering in construction. Industrial and Civil Engineering. 2023; 12:75-82. DOI: 10.33622/0869-7019.2023.12.75-82. EDN DXYNBS. (rus.).

18. Sborshchikov S.B. Organizational methods of activating scientific, technical and innovative activities in construction based on territorial and sectoral technoparks : dis. … cand. of technical sciences. Moscow, 2000; 167. EDN QDGNYH. (rus.).

19. Lazareva N.V. Cluster model of organization of innovation activity at the corporate level in construction : dis. … cand. of technical sciences. Moscow, 2015; 185. EDN WMNZDJ. (rus.).

20. Lazareva N. Innovative components of sustainable development in construction. MATEC Web of Conferences. 2018; 196:04001. DOI: 10.1051/matecconf/201819604001

21. Leibman D.M. Organizational model of integrated control of the implementation of projects for the construction of technically complex facilities : dis. … cand. of technical sciences. Ivanovo, 2021; 153. EDN FKKPJP. (rus.).

22. Leybman D., Khripko T. Quality assurance program of a nuclear facility. E3S Web of Conferences. 2019; 97:03015. DOI: 10.1051/e3sconf/20199703015

23. Subbotin A.S. Cluster model of the organization of integrated structures in construction (on the example of public-private partnerships) : dis. … cand. of technical sciences. Moscow, 2014; 180. EDN BSJOGH. (rus.).

24. Bahus E.E. Organizational solutions for ensuring the quality of construction of nuclear power facilities : dis. … cand. of technical sciences. Ivanovo, 2021; 176. EDN CPPMBV. (rus.).

25. Ermolayev E.E. Foreign and domestic experience in the use of elements of engineering, outsourcing and outstaffing in the construction industry. Rationing and Remuneration of Labor in Construction. 2019; 4:49-67. EDN LNBLOC. (rus.).

26. Shinkareva G.N., Maslova L.A. Integrated engineering as a way to intensify construction production. Rationing and Remuneration of Labor in Construction. 2018; 3:37-41. EDN QIPUEW. (rus.).

27. Shinkareva G.N. Intensification of construction production through the use of integrated engineering. Rationing and Remuneration of Labor in Construction. 2017; 7:43-46. EDN RAOOYW. (rus.).

28. Shinkareva G.N. Model of engineering scheme of construction organization for life cycle contracts : dis. … cand. of technical sciences. Moscow, 2018; 172. EDN XJZLZQ. (rus.).

29. Malakhov V.I. Strategy of structuring an industrial and construction holding : dis. … cand. of economic sciences. Moscow, 2005; 155. EDN KJZTJW. (rus.).

30. Popkov A.G. Implementation of integrated logistics solutions of the corporation “single customer”: on the example of the construction industry. Economics: Yesterday, Today and Tomorrow. 2022; 12(5-1):324-328. DOI: 10.34670/AR.2022.65.75.026. EDN URUYYR. (rus.).

31. Popkov A.G. Staffing of construction production. New approaches to the formation, functioning, regulation. Technical Regulation. Construction, Design and Surveys. 2011; 8:29-33. EDN ODWQKJ. (rus.).

32. Shumeyko N.M. Concepts of the construction cost estimate. BST: Bulletin of Construction Machinery. 2018; 11(1011):42-45. EDN YMXDRJ. (rus.).

33. Malakhov V.I. Project­resource method — pricings in BIM. BST: Bulletin of Construction Machinery. 2017; 3(991):52-56. EDN XXAUML. (rus.).

34. Zhuravlev P.A. Engineering protection. Required changes in building regulations and regulations. Russian Engineer. 2022; 4(77):44-48. EDN NAFYWT. (rus.).

35. Zhuravlev P., Bachus E., Markova I. Directions of modernization of systems for ensuring the quality of construction of nuclear power facilities. MATEC Web of Conferences. 2018; 251:05039. DOI: 10.1051/matecconf/201825105039

36. Zhuravlev P., Bachus E., Markova I. Nomenclature of works and costs for ensuring the quality of construction products. Identification methods. IOP Conference Series : Materials Science and Engineering. 2019; 661(1):012128. DOI: 10.1088/1757-899X/661/1/012128

37. Yazhlev I.K., Popkov A.G., Belogurova O.A. Problems of regulatory support for the introduction of resource-and energy-saving technologies in urban development. Economics and Entrepreneurship. 2020; 3(116):1000-1002. DOI: 10.34925/EIP.2020.116.3.212. EDN AJSLCW. (rus.).

38. Klyuev V.D., Zaitsev D.A., Zhuravlev P.A. Regulatory framework for the cost assessment of capital repairs of apartment buildings. Management of an Apartment Building. 2015; 1. (rus.).

39. Zhuravlev P.A. Nomenclature of capital construction objects required for resource and technological modeling. Industrial and Civil Engineering. 2020. № 7. С. 52–57. DOI: 10.33622/0869-7019.2020.07.52-57. EDN NVXALL. (rus.).