Introduction: The active implementation of digital technologies in various fields, including in the construction industry, leads to the development of technological platforms to sell multiple products. The study examines the prerequisites for the formation of an organizational and technological platform for monolithic construction using pneumatic formwork, which is a set of material and labor resources and organizational and technological solutions that, through their consolidation with modern digital technologies, allow the implementation of construction projects with specified technical and economic requirements. This study aims to systematize various production and construction solutions, presenting them as a unified organizational and technological system that allows for achieving optimal criteria for construction products. Materials and methods: The factors ensuring its effectiveness were selected and systematized to form an organizational and technological platform. A complex system decomposition is presented at three levels of a hierarchical matrix using the analysis of hierarchies. The level of the stages of the life cycle of buildings and structures is taken as the basis, followed by the level of components of the areas of activity that form the platform's effective formation. At the last, lower level, some factors ensure its effective formation. The analysis of the totality of material and labor resources and organizational and technological solutions that make up the platform for constructing monolithic buildings and structures using pneumatic formwork systems was carried out. Results: For an adequate analytical description, it is proposed to use the a priori ranking method, which makes it possible to decompose the indicated factors influencing the effectiveness of the formation of an organizational and technological platform and to obtain specific criteria and alternatives inherent in the construction of monolithic buildings and structures on pneumatic formwork. The detailed development of an analytical apparatus for obtaining an integral assessment will be the subject of further research. Conclusions: The organizational and technological platform for monolithic construction using pneumatic formwork is an innovative tool for interaction between all participants in implementing such projects, aimed at successfully achieving construction design indicators in terms of time and cost and ensuring the required level of reliability and safety of the constructed facility. The novelty of the proposed approach is determined by the combined consideration of material, technological, organizational, and managerial solutions within a single platform to increase the efficiency of construction product production processes.

 

Doi: 10.28991/CEJ-2023-09-11-010

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Organizational and Technological Platform; Monolithic Construction Technologies; Pneumatic Formwork; A Priori Ranking; Dispersed Reinforcement; Basal-fiber Reinforced Concrete; Construction Control; Major Repairs.

Mishchenko, V. Y., Kazakov, D. A., Tkachenko, A. N., & Kazakova, E. D. (2022). Prospects for the Integrated Development of Pneumatic Technologies in Construction. Construction Manufacturing, 4(4), 114–121. doi:10.54950/26585340_2022_4_114.

Li, Y., Shang, Y., Wan, X., Jiao, Z., & Yu, T. (2022). Design and experiment on light weight hydraulic cylinder made of carbon fiber reinforced polymer. Composite Structures, 291, 115564. doi:10.1016/j.compstruct.2022.115564.

Kazakov, D., Tkachenko, A., Arzumanov, A., Bolotskikh, L., & Mishchenko, A. (2021). Development of technology for the construction of heat-efficient monolithic vaults from basalt fiber concrete. E3S Web of Conferences, 258, 09041. doi:10.1051/e3sconf/202125809041.

Timirgaleeva R.R., Grishin I.Yu. “Justification of the structure of the organizational and technological platform of the industry ecosystem of the digital economy”. Scientific Bulletin: Finance, Banks, Investments, 4 (49). 179–185.

Gusakova, E. A., & Pavlov, A. S. (2020). Project management in large-scale construction: development of approaches in the conditions of digitalization. IOP Conference Series: Materials Science and Engineering, 953, 012079. doi:10.1088/1757-899x/953/1/012079.

Simionova, N., Simionov, R., & Sinyak, N. (2021). Assessment of the project management system in the context of the implementation of large–scale projects: approaches and indicators. Real Estate: Economics, Management, 3, 30–34. doi:10.22337/2073-8412-2021-3-30-34.

Sukhorukov, A. I., Kameneva, N. A., Shuhong, G., & Eroshkin, S. Yu. (2018). Sustainable Management of Radiation-Hazardous Construction Projects. 2018 Eleventh International Conference “Management of Large-Scale System Development” (MLSD), Moscow, Russia. doi:10.1109/mlsd.2018.8551826.

Frolova, K. A., & Shestakov, A. V. (2014). Models for Managing the Structural Parameters of Complex Project Systems. The Way of Science, 35.

Zavadskas, E. K., Vilutienė, T., Turskis, Z., & Šaparauskas, J. (2014). Multi-criteria analysis of Projects’ performance in construction. Archives of Civil and Mechanical Engineering, 14, 114-121. doi:10.1016/j.acme.2013.07.006.

Lapidus, A. A. (2022). Organizational and technological platform of construction. Vestnik MGSU, 17(4), 516–524. doi:10.22227/1997-0935.2022.4.516-524.

Lapidus, A. A. (2022). Formation of Organizational and Technological Platforms in Construction. Construction Manufacturing, 1, 2–6. doi:10.54950/26585340_2022_1_2.

Lapidus, A., Kuzhin, M., & Shesterikova, I. (2020). Construction project organizational and technological parameters analysis. IOP Conference Series: Materials Science and Engineering, 869(7), 072047. doi:10.1088/1757-899x/869/7/072047.

Kuzina, O. (2022). Conceptual Digital Organizational and Technological Model Scenarios at the Construction Organization Project. Building Life-cycle Management. Information Systems and Technologies, Lecture Notes in Civil Engineering, 231, Springer, Cham, Switzerland. doi:10.1007/978-3-030-96206-7_17.

Moustafa, N., Adi, E., Turnbull, B., & Hu, J. (2018). A New Threat Intelligence Scheme for Safeguarding Industry 4.0 Systems. IEEE Access, 6, 32910–32924. doi:10.1109/ACCESS.2018.2844794.

Sung, T. K. (2018). Industry 4.0: A Korea perspective. Technological Forecasting and Social Change, 132, 40–45. doi:10.1016/j.techfore.2017.11.005.

Marcon, P., Zezulka, F., Vesely, I., Szabo, Z., Roubal, Z., Sajdl, O., Gescheidtova, E., & Dohnal, P. (2017). Communication technology for industry 4.0. Progress in Electromagnetics Research Symposium, 1694–1697. doi:10.1109/PIERS.2017.8262021.

Lapidus, A. A. (2014). Efficiency potential of management and technical solutions for a construction object. Vestnik MGSU, 1, 175–180. doi:10.22227/1997-0935.2014.1.175-180.

Ovchinnikov, A. N., & Lapidus, A. A. (2021). Methodological Basis for Formation the Organizational and Management Model of Customer Activity in Implementation at Large-Scale Investment and Construction Project. Construction Manufacturing, 1, 2–6. doi:10.54950/26585340_2021_1_2.

Lapidus, A.A. (2016). Formation of an integral potential of organizational and technological solutions through the decomposition of the main elements of a construction project. Vestnik MGSU, 12, 114–123. doi:10.22227/1997-0935.2016.12.114-123.

Tarasov, R. V., Makarova, L. V., & Bakhtulova, K. M. (2014). Assessment of the importance of factors by the method of a priori ranking. Modern Scientific Research and Innovations, 4(1), 33181.

Chernukhina, G. N. (2017). Modern management technologies in the digital economy. Bulletin of the Academy, 4, 24-28.

Tarasov R.V., Makarova L.V., & Bakhtulova K.M. (2014). Assessment of the significance of factors by the method of a priori ranking. Modern Scientific Research and Innovation, No. 4. Part 1.

Mitina A.O., Kazakov D. A. (2020). Technologies for the installation of monolithic structures made of concrete on heat-efficient aggregates. Construction and real estate of the Voronezh State Technical University. Construction and Real Estate, 1(5), 44-53.

Kazakov D.A., Ovcharenko A.S., Mitina A.O., & Kazakova E.D. (2020). To The Question of Technology of the Device of Monolithic Constructions from Concrete on Heat-Efficient Fillers. Construction and Real Estate, 5(1), 44-52. (In Russian).

Kazakov D.A., Kravchenko M.S. (2019). Advantages of using basalt fiber reinforced concrete in construction. Scientific Bulletin of the Voronezh State University of Architecture and Civil Engineering. Student and Science, 1(8), 33-37.

Otto, F., & Trostel, R. (1967). Pneumatic Building Structures. Design and Calculation of Structures from Cables, Nets. Stroiizdat, Moscow, Russia.

Kazakov D.A., Tkachenko A.N. (2006). Method for the erection of wavy monolithic vaults and formwork for its implementation. Patentee: Federal State Budgetary Educational Institution of Higher Education "Voronezh State Technical University" (RU) No. 10. Pat. No. 2615202 Russian Federation. IPC E04G 11/04 (2006.01).

Maslikhova, L. I., Hahulina, N. B., Sambulov, N. I., & Akimova, S. V. (2020). Analysis and Comparison of Technologies of Survey of Buildings and Structures for the Purpose of Obtaining a 3D Model. IOP Conference Series: Materials Science and Engineering, 753(3), 32061. doi:10.1088/1757-899X/753/3/032061.

Melkumov V. N., Tkachenko A. N., Kazakov D. A., Khakhulina N. B. (2015). Prospects for the use of geodetic methods for monitoring the deformations of pneumatic formwork. Scientific Bulletin of the Voronezh State University of Architecture and Civil Engineering. Construction and Architecture, 1(37) 51-58.

Sklyar V. A. (2017). Organization and mathematical planning of experiments. Publishing solutions, Moscow, Russia.

Lu, Y., Li, Y., Skibniewski, M., Wu, Z., Wang, R., & Le, Y. (2015). Information and communication technology applications in architecture, engineering, and construction organizations: A 15-year review. Journal of Management in Engineering, 31(1), A4014010. doi:10.1061/(ASCE)ME.1943-5479.0000319.