Русский
English
Identification of needs for production resources during repairs, restoration and reconstruction strongly relies on administrative and engineering solutions. The scope of problems, addressed by these projects, encompasses limited production and non-production resources, as well as unpredictable external risks, or ambiguous initial information about construction facilities. Today all available decision-making principles, underlying the long-term planning of capital repairs and reconstruction of civil buildings, disregard a great number of production-related and administrative factors. Advanced design software and applications, developed on the basis of various mathematical principles, used to describe construction technologies and processes, facilitate decision making by specialists responsible for the implementation of such projects. In this case, principal factors include optimal labour costs and guaranteed quality. The article outlines basic decision-making principles underlying a program of capital repairs or reconstruction of civil buildings in operation. These principles are based on computing the potential of administrative and engineering solutions. Scientific research, conducted in the process of drafting this article, encompasses the analysis of various production-related factors characteristic of production processes, including capital repairs and reconstruction. These factors are represented as a system of linguistic data flow that specifies term sets and membership functions for each condition. Most significant factors are the technical condition of permanent buildings and structures, the attitude of consumers to the subject of the study, and its operation period starting upon completion of earlier repair or reconstruction, as well as the serviceability of internal and external engineering systems. As a result of scientific research, the authors developed and tested a new method used to identify the need for construction and installation work performed within the framework of capital repairs or renovation. The novel method includes specific requirements that apply to the scope of work and the sequence of its implementation.
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[2] Shesterikova Y., Bidov T. Assessing the impact of a comprehensive engineering survey on the efficiency of a construction project. AIP Conference Proceedings. 2023. 2936 (1). 020008. DOI.org/10.1063/5.0178526
[3] Shesterikova Y., Bidov T., Fatullaev R., Elnikova D. Evaluating the impact of a comprehensive technical building survey using a cultural heritage site as an example. International Journal of Engineering Trends and Technology. 2023. 71 (6). P. 1 – 7. Crossref, https://doi.org/10.14445/22315381/IJETT-V71I6P201
[4] Miklashevsky A.A. Proper technical condition and requirements for major and current repairs. International Journal of Applied Sciences and Technologies Integral. 2020. 3. P. 17.
[5] Semenov A.S. Organization of capital repairs of buildings based on a systematic approach. Bulletin of Belgorod State Technological University named after. V.G. Shukhov. 2016. P. 64 – 66.
[6] Oleinik P.P. Arrangement of construction work. Saratov, 2019. 599 p.
[7] Aleksanin A.V. Promising directions of development of construction process. Scientific Review. 2015. 10. P. 378 – 381.
[8] Lapidus A.A. Potential for the effectiveness of administrative and engineering solutions of a construction project. 2014. P. 175 – 180.
[9] Lapidus A.A., Govorukha P.A. Administrative and engineering potential of enclosing structures of multi-storey residential buildings. Economics, Management and Organization of Construction. 2015. 4. P. 143 – 149.
[10] Volkova L.V. The influence of probabilistic conditions on administrative and engineering solutions in the construction of residential buildings. Bulletin of Civil Engineers. 2015. 4 (51). P. 87 – 95.
[11] Abramyan S.G., Klyuev S.V., Emelyanova O.E., Oganesyan O.V., Chereshnev L.I., Akopyan G.O., Petrosian R.O. Improving reinforced concrete column strengthening techniques for reconstruction projects using composite jacketing formworks. Construction Materials and Products. 2023. 6 (5). 1. https://doi.org/10.58224/2618-7183-2023-6-5-1
[12] Gansen E.V., Lapidus A.A. A fuzzy inference system for assessing the need for major repairs and reconstruction based on the potential of administrative engineering solutions. Components of Scientific and Technological Progress. 2021. 11 (65). P. 16 – 22.
[13] Lapidus A., Khubaev A., Bidov T. Regression analysis of the calculation of the organizational and technological potential for the production of cold weather concreting. IOP Conference Series: Materials Science and Engineering. 5 Giai Phong Road, Hanoi, 2020. P. 072033. DOI 10.1088/1757-899X/869/7/072033
[14] Vaisman S.M., Bayburin A.Kh. Development of administrative and engineering solutions in construction using information modeling technologies (TIM). Bulletin of SUSU. Construction and Architecture Series. 2016. 16 (4). P. 21 – 28. DOI: 10.14529/build160404
[15] Lapidus A.A., Makarov A.N. Formation of administrative and engineering potential for the production of roofing structures for residential multi-storey buildings. Vestnik MGSU. 2015. 8. P. 150 – 160.
[16] Shesterikova Y., Koroteeva M., Bidov T., Fatullaev R.. Influence of the results of verification calculations of the building on the comprehensive examination and determination of the technical condition of the bearing structures of the building. International Journal of Engineering Trends and Technology. 2023. 71 (6). P. 134 – 140. Crossref, DOI: https://doi.org/10.14445/22315381/IJETT-V71I6P216
[17] Ganzen E.V. Research of the response surface of the integral potential of capital repairs and reconstruction of public buildings in the fuzzy inference system. Construction Materials and Products. 2022. 5 (2). P. 35 – 42. https://doi.org/10.58224/2618-7183-2022-5-2-35-42
[18] Sarvut T.O. Circumpolar aspect in the development of urban environment organization in Russian cities. Construction Materials and Products. 2023. 6 (5). 8. DOI: 10.58224/2618-7183-2023-6-5-8
[19] Cordon O., Herrera F.A. General study on genetic fuzzy systems. Genetic algorithms in engineering and computer science. 1995. P. 33 – 57.
[20] Froese T.M. The impact of emerging information technology on project management for construction. Automation in Construction. Aug. 2010. 19(5). P. 531 –538.
[21] Jones K., Sharp M. A new performance-based process model for built asset maintenance. Facilities, 2007. 25 (13/14). P. 525 – 535.
[22] Mitropoulos P., Howell G. A. Renovation Projects: Design process problems and improvement mechanisms. ASCE Journal of Management in Engineering. 2002. 18 (4). P. 179 – 185.
[23] Mubarak S. Construction project scheduling and control. New Jersey. Hoboken, John Wiley & Sons, Ins. 2010. 478 p.
[24] Topchiy D.V., Shatrova А.I. Formation of a basic management strategy for a construction organization in the implementation of projects of redevelopment of major urban areas. International Journal of Mechanical Engineering and Technology. 2018. 9(4). P. 539 – 547.
[25] Waheed Z., Fernie S. Knowledge based facilities management. Facilities. 2009. 27 (7/8). P. 258 – 266.
Lapidus A.A., Topchiy D.V., Kuzmina T.K., Bolshakova P.V., Ganzen E.V. Development of a method to identify the need for capital repairs and renovation of administrative buildings. Construction Materials and Products. 2024. 7 (6). 9. https://doi.org/10.58224/2618-7183-2024-7-6-9