RELIABILITY OF CONSTRUCTIONAL PRODUCTION LINE

Vladimir Viktorovich Bredikhin; Natalia  Bredikhina

doi:10.5937/jaes0-28674

Vladimir Viktorovich Bredikhin Southwest State University, Department of Expertise and Real Estate Management, Mining Engineering, Kursk, Russia
Natalia Bredikhina Southwest State University, Department of Expertise and Real Estate Management, Mining Engineering, Kursk, Russia

DOI: https://doi.org/10.5937/jaes0-28674

Keywords: construction, constructional production line, reliability, reliability characteristics of constructional production line, reliability factors of constructional production line

Abstract

The article discusses the most important quantitative characteristics of the reliability of constructional production line. The reliability of constructional production line, in the general case, is understood as its property to maintain its parameters in permissible, predetermined limits. One of the main parameters of constructional production line is its intensity. In addition, intensity is one of the main indicators characterizing the efficiency of the production line. Generally speaking, efficiency serves as a measure of system productivity taking into account the external environment. Therefore, in a particular case, the reliability of constructional production line can be understood as the stability of its intensity.

References

Bredikhin V. V. (2012). Management of organizational and economic reliability of urban development. Proceedings of Southwest University, №3, 76-82.

Bredikhin V. V. (2012). Analysis of existing methods for solving the problem of reproduction of residential real estate objects. SWSU, Kursk.

Bredikhin V. V., Shleyenko A. V., Bredikhina N. V.(2016) Development of the production and technical potential of the construction. SWSU, Kursk.

A. A. Lapidus, A. N. Makarov. (2017). Fuzzy model of development process organization. Proceedings of Universities. Investments. Constructions. Real estate. Vol.7, №1, 59-68.

Sadi A., Sadiq A. (2006). Causes of delay in large construction projects. Journal Project Management. Vol. 24, №4, 349-357.

A. A. Lapidus, A. O. Fel’dman. (2015). Valuation of organizational and technological capacity of a building project formed on the basis of informational flows. Vestnik MGSU. №11, 193-200.

Morozenko Andrey Aleksandrovich, KrasovskiyDmitriyViktorovich. (2016). Management of investment-construction projects basing on the matrix of key events. Vestnik MGSU. №11, 105-113. DOI: 10.22227/1997-0935.2016.11.105-113

Lapidus A. A., Abramov I. L. (2019). Systemic integrated approach to evaluating the resource potential of a construction company as a bidder. IOP CONFERENCE SERIES: MATERIALS SCIENCE AND ENGINEERING, 3rd World Multidisciplinary Civil Engineering, Architecture, Urban Planning Symposium (WMCAUS 2018), p. 052079 DOI: 10.1088/1757-899X/603/5/052079

Abramov I. L., Lapidus A. A. (2018). Formation of production structural units within a construction company using the systemic integrated method when implementing high-rise development projects. E3S WEB OF CONFERENCES, p. 03066

Lapidus A., Abramov I. (2020). An assessment tool for impacts of construction performance indicators on the targeted sustainability of a company. IOP CONFERENCE SERIES: MATERIALS SCIENCE AND ENGINEERING. International Science and Technology Conference "FarEastCon 2019". p. 042089. DOI: 10.1088/1757-899X/753/4/042089

Pakhomova Y. G., Bredikhina N. V.(2016) Probabilistic laws of destruction of a construction line. Proceedings of Southwest University, № 6, 35 - 40.

Bredikhin V. V. (2012). Problems of managing the organizational and economic reliability of urban development. Real estate: economics and management, № 2, 23 - 26.

Bovteev, S., Kanyukova, S., Okrepilov, V., & Rezvaia, A. [2016]. Construction work tasks duration: New method of estimation and quality control. Journal of Applied Engineering Science, 14(1), 121-127.

Harris R. A., Scott S. UK practice in dealing with claims for delay. Engineering Construction & Architectural Management. 2001. T. 8. №5-6. C. 317-324.

Kremer N. SH. (2016). Probability theory and mathematical statistics. Yuniti, Moscow.

Kolmogorov A. N., Fomin S. V. (1976). Elements of function theory and functional analysis. Nauka, Moscow.

Graboviy P. G. (2018). Organization of real estate construction and development. Part 1: Construction organization. ASV, IIA «Prosveshcheniye», Moscow.

Viktorovich, B. V., Vladimirovna, B. N., & Yurievna, A. I. [2019]. Analysis of the development process of the territorial productive and technological potential of the region's construction organizations. Journal of Applied Engineering Science, 17(3), 395-399.

Viktorovich, B. V., Bredikhina, N., & Ezerskiy, V. [2020]. Modeling of property management process at territorial level. Journal of Applied Engineering Science, 18(2), 257-261.

Vladimirovna-Bredikhina, N. [2017]. Basic principles of production-and-technical potential capacity formation in the construction industry of a region. Journal of Applied Engineering Science, 15(4), 495-497.

Grabovy P., Orlov A. (2018) Management of the LCC considering industrial construction life cycle contracts. MATEC Web of Conferences.VI International Scientific Conference “Integration, Partnership and Innovation in Construction Science and Education” (IPICSE-2018), p. 05019.DOI:10.1051/matecconf/201825105019

Baronin S.A., Kulakov K.J. (2018) Modeling total cost of ownership residential real estate in the life cycles of buildings. International Journal of Civil Engendering and Technology. .Vol. 9, № 10, 1140 – 1148.