BIM Technologies as a Tool in Effective Implementation of the Construction Programs in the Arctic Zone

BIM is the rapidly growing technology of information support in design, development, construction and operation of various facilities. In terms of its capabilities to take into account various risk characteristics and the influence of components under study, this information model makes it possible at a higher qualitative level to justify economic and technological decisions during construction in the Arctic zone and to maintain a particular facility entire life cycle. This model is best suited to be introduced in this complex high-risk construction area. BIM technology makes it possible to operate with the most detailed information, when making investment decisions difficult under conditions of building in the Arctic zone. Systemic integration of the BIM technology capabilities with models of the geoinformation systems' geodynamic risks and technologies ensures design, construction and maintenance of modern buildings and facilities at the fundamentally new level of quality and safety assurance, as well as to monitor stability and safety thereof in relation to the Arctic conditions. Mathematical model of the deformation energy migration is presented to evaluate geodynamic stability in the construction areas. It is advisable to take into account geodynamic factors in information simulation using the mathematical model that describes construction area in the form of a system of nodes and of the geological medium tectonic fault abnormalities connecting them and represented in the aggregate in the form of the Kolmogorov system of differential equations

References

[1] Svetlakov V.I., Mokhov A.I. A model of cycle of complex development of the territory. Naukovedenie, 2012, no. 2 (in Russ.). DOI: http://dx.doi.org/10.15862/68EVN614

[2] Mokhov A.I. Modeli modernizatsii promyshlennykh predpriyatiy. V: Innovatsionnye protsessy v rossiyskoy ekonomike [Modernization models of industrial enterprises. In: Innovation Processes in the Russian Economy]. Moscow, Nauchnyy konsul’tant Publ., 2016.

[3] Chto takoe BIM [What is BIM]? opinionbuilders.com: website (in Russ.). Available at: http://opinionbuilders.com/ru/bim (accessed: 21.11.2019).

[4] Chulkov V.O., ed. Infografiya. Kurs lektsiy [Infography. Lection course]. Moscow, MISI Publ., 1991.

[5] Kosorukov Yu.D., Fateev A., Svetlakov V.I., et al. Resources BIM technologies to expand notions of complex objects capitalization. Russian Journal of Resources, Conservation and Recycling, 2015, no. 1 (in Russ.). DOI: http://dx.doi.org/10.15862/03RRO115

[6] Minaev V.A., Mokhov A.I., Faddeev A.O. System integration of BIM-technologies and geodynamic risks models in construction industry. Upravlenie razvitiem territorii, 2016, no. 1, pp. 54--58 (in Russ.).

[7] MChS prognoziruet risk obrusheniya zdaniy v 8 okrugakh Rossii v 2016 godu (in Russ.). Available at: https://ria.ru/20151228/1350569298.html (accessed: 21.11.2019).

[8] Bondar’ V.A., Minaev V.A., Faddeev A.O., eds. Modelirovanie geodinamicheskikh riskov v chrezvychaynykh situatsiyakh [Modeling of geodynamic risks in emergency situations]. Khabarovsk, Izd-vo DVYuI MVD Rossii Publ., 2014.

[9] Minaev V.A., Topolsky N.G., Faddeev A.O., et al. Building without disasters: the registration of geodynamic risks. Tekhnologii tekhnosfernoy bezopasnosti [Technology of Technosphere Safety], 2014, no. 2 (54) (in Russ.). Available at: http://agps-2006.narod.ru/ttb/2014-2/24-02-14.ttb.pdf

[10] Minaev V.A., Faddeev A.O., Abramova A.V. Fracture sites tectonic model of estimating geodynamic stability of territorial systems. Problemy upravleniya riskami v tekhnosfere, 2014, no. 1, pp. 90--99 (in Russ.).

[11] Minaev V.A., Faddeev A.O., Popov A.N., et al. Generalized probabilistic model to estimate the geodynamic stability of territories. Tekhnologii tekhnosfernoy bezopasnosti [Technology of Technosphere Safety], 2013, no. 5 (51) (in Russ.). Available at: http://agps-2006.narod.ru/ttb/2013-5/17-05-13.ttb.pdf

[12] Minaev V.A., Faddeev A.O., Danilov R.M. Mathematical modeling of risks with geodynamic origin. Spetstekhnika i svyaz, 2011, no. 1, pp. 48--52 (in Russ.).

[13] Minaev V.A., Faddeev A.O. Geoecological risk modeling. Spetstekhnika i svyaz, 2009, no. 2, pp. 24--30 (in Russ.).

[14] Mokhov A.I. Sistemotekhnika i kompleksotekhnika stroitel’nogo pereustroystva. V: Pereustroystvo. Organizatsionno-antropotekhnicheskaya nadezhnost’ stroitel’stva [System engineering and complex engineering of building reconstruction. In: Reconstruction. Organizational and Anthropotechnical Construction Reliability]. Moscow, SvR-ARGUS Publ., 2005, pp. 129--163 (in Russ.).

[15] Ob utverzhdenii Plana poetapnogo vnedreniya tekhnologiy informatsionnogo modelirovaniya v oblasti promyshlennogo i grazhdanskogo stroitel’stva [On approval of the Plan for phased implementation of information modeling technologies in industrial and civil construction field]. minstroyrf.gov.ru: website (in Russ.). Available at: https://minstroyrf.gov.ru/upload/iblock/383/prikaz-926pr.pdf (accessed: 21.11.2019).