Architecture of underground spaces

L. Brylova, O. Priemets


The use of underground space planning and building of large cities is of paramount importance due to the shortage of urban areas, the constant population growth and a sharp increase in gas content, and traffic in the streets, and insufficient development of urban infrastructure. With the rapid growth of cities and the territories occupied by them, damaging levels of motorization requirements increase speeds while increasing its security problem of maintaining support capital development and the natural environment can be resolved only through broad and systematic development and use of underground spaces. Over the past decades, the development of underground space in many countries of the world has become a developed industry. It solves three main tasks: unloads traffic flows, allows using underground floors to erect high-rise buildings and expand the useful space of the house due to the device of the operated premises

Полный текст:



Afanasyev G. E. Ispol’zovaniye podzemnogo prostranstva gorodov [Using the underground space of cities]. Moscow, Stroyizdat Publ., 2004. 150 p. (In Russ.).

Aziz D., Nawawi A. H., Ariff R. M. ICT Evolution in Facilities Management (FM): Building Information, Modelling (BIM) as the Latest Technology. Procedia — Social and Behavioral Sciences, 2016, vol. 234, рp. 363–371.

Park J. W., Chen J., Choa Y. K. Self-corrective knowledge-based hybrid tracking system using BIM and multimodal sensors. Advanced Engineering Informatics, 2017, vol. 32, pp. 126–138.

Konyukhov D. S. Ispol’zovaniye podzemnogo prostranstva [The use of underground space]. Moscow, Architecture Publ., 2004. 296 p. (In Russ.).

Rossiyskiy natsional’nyy portal RBC [Russian National Portal RBC]. Available at: (In Russ.).

Journal of innovative technologies “Naked science”. Available at: (In Russ.).

Ding L. Y., Zhong B. T., Wu S., Luo H. B. Construction risk knowledge management in BIM using ontology and semantic web technology. Safety Science, 2016, vol. 87, pp. 202–213.

Brylova L. S. Aktual’nost’ ispol’zovaniya podzemnykh prostranstv sovremennykh gorodov [The relevance of the use of underground spaces of modern cities]. Art. Sat “Bulletin of KazGASA”, 2015, vol. 3 (42).

Krinitsky E. V. Informatsionnaya model’ zdaniya [Information model of the building]. AVOK: ventilation, heating, air conditioning, heat supply, and building thermal physics, 2010, vol. 1, pp. 62–65. (In Russ.).

Wikipedia. Available at:

Ginzburg A. V. BІM-tekhnologii na protyazhenii zhiznennogo tsikla stroitel’nogo ob”yekta [ВІМ-technologies throughout the life cycle of a construction object]. Information resources of Russia, 2016, vol. 5 (153), pp. 28–31. (In Russ.).

Golubev G. E. Podzemnaya urbanistika i gorod [Underground urbanist and city]. Moscow, CPI MIKHiS Publ., 2005. 247 p. (In Russ.).

Veretennikov D. Arkhitekturnyy dizayn. Podzemnyy urbanizm [Architectural design. Underground urbanism]. Moscow, Architecture Publ., 2015. 176 p. (In Russ.).

Loevskaya G. G. Informatsionnaya model’ zdaniya [Building information model]. Scientific and Methodological Electronic Journal “Concept”, 2013, vol. 3, pp. 2126–2130. (In Russ.).

Populyarnaya mekhanika [Popular Mechanics]. Available at: (In Russ.).

Zou Y., Kiviniemi A., Jones S. W. A review of risk management through BIM and BIM-related technologies. Safety Science, 2017, vol. 97, pp. 88–98.


  • На текущий момент ссылки отсутствуют.