Istrazivanja i projektovanja za privreduJournal of Applied Engineering Science


DOI: 10.5937/jaes15-14656 
This is an open access article distributed under the CC BY-NC-ND 4.0 terms and conditions. 
Creative Commons License

Volume 15 article 442 pages: 282 - 287

Natalia Vladimirovna Bakaeva
Southwest State University, Kursk, Russia

Aleksandr Vitalyevich Kalaydo
Southwest State University, Kursk, Russia

The estimate of radiation safety in existing buildings by indoor radon levels measuring requires considerable time and financial costs, at stage of the constructions design it is not possible generally. So the prediction of radon concentrations in new and existing buildings on the basis of mathematical modeling is the actual problem. The semi-empirical model of radon levels prediction in the aboveground apartments presents in the paper. The model structure is the result of theoretical studies of soil gas transport mechanism in a porous media and the empirical constants determined based on the radiation monitoring results of the buildings and territory of the University.

View article

Sidelnikova O.P. Radiation-environmental aspects in the construction of buildings // Biosphere compatibility: people, region, technology, 2013. – No. 2. – Pp. 65-69.

Mironchik A. F. The natural radioactive substances in the atmosphere and indoor air of the living space of the Belarus Republic // The Journal of Belarusian-Russian University, 2007 – No. 4 (17). – Pp. 162-171.

Didenko P.I. The radon influence on the Ukraine population of Ukraine // BC and civil protection, 2012. – No. 4. – Pp. 60-67.

Klinskaya E.O., Christoforov N.K. The radon concentrations in indoor air of the Jewish Autonomous region // Radiation Hygiene, 2012. – Vol. 5. – No. 1. – Pp. 20-24.

Kormanovskaya T.A. Dose natural radiation population of the Siberian Federal District // The MANEB Journal in the Omsk region, 2013. – No. 3. – Pp. 13-16.

Gulabyants L.A. Radon Hazard: Terms, Criteria, Signs // ANRI, 2013. – No. 1. – Pp. 12-14

IAEA SAFETY STANDARDS for protecting people and the environment. Protection of the Public against Exposure Indoors due to Natural Sources of Radiation. Draft Safety Guide No. DS421. – Vienna, April 2012. – 92 p.

Gulabyants, L.A., Livshits M.I., Medvedev S.V. The Measurement of Radon Impact on Underground Building Envelope // The Academy, 2016. – No. 1. – Pp. 122-128.

Herman O.A. Scientific substantiation of radon measures for buildings located on territories of Ukraine with high radon levels: dis…kand. biol. sciences: 14.02.01 / O.A. Herman. – Kiev, 2016. – 136 p.

Gulabyants L.A. Guide the radon protection design of the residential and public buildings. – Moscow: FEN-SCIENCE, 2013. – 52 p

T. Diallо, B. Collignan, F. Allard. 2D Semiempirical models for predicting the entry of soil gas pollutants into buildings // Building and Environment, Vol. 85, (2015). Pp. 1-16.

Kohl T., F. Medici, L. Rybach. Numerical simulation of radon transport from subsurface to buildings // Journal of Applied Geophysics, No. 31 (1994). PP. 145-152.

Belensov P.E., Kuznetsov P.I. The Method for determining the radon rate and the air exchange rate in the apartments // ANRI, 1996. – No. 1. – Pp. 23-25.

Yarmoshenko I.V., Zhukovsky M.V., Ekidin A.N. The Modeling of radon entry in dwellings // ANRI, 1999. – No. 4. – Pp. 17-26