References
- 1. Sadovsky, M.A. (1952). The Mechanical Action of Air Shock Waves of Explosion According to Experimental Studies: Physics of Explosion. Moscow: Publishing of Academy of Sciences of the USSR.
- 2. Baum, F.A., Orlenko, L.P., Stanyukovich, K.P., Chelyshev, V.P., & Schechter, B.I. (1975). Physics of the Explosion. Moscow: Science.
- 3. Sidorenko, V.L., & Azarov, S.I. (2008). Calculation of the effects of explosive shock waves on a person during an explosion in the stock of ammunition. Systems of Armament and Military Equipment, 1, 70–73.
- 4. Vadulina, N.V., Achivakova, L.R., Salimov, A.O., Abdrakhmanova, K.N., & Abdullin R.S. (2017). Insuring safety pneumatest of the pipeline. Oil and Gas Business, 4, 109–124. DOI: http://dx.doi.org/10.17122/ogbus-2017-4-109-124
- 5. Minnullin, I.P., Fomin, N.F., & Nechaev, E.A. (2010). Mine-explosive defeats – the global problem of humanity. Medicine of Catastrophes, 2, 34–36.
- 6. Shapovalov, V.M., & Samokhvalov, I.M. (2012). Explosive injuries due to man-made disasters and terrorist acts. War-Medical Journal, 1, 25–33.
- 7. Kaptsov, V.A., Kulbacinskiy, V.V., Bazaz’yan, A.G., Romanov, V.V., & Semenchukov, A.V. (2010). Probable injuries and specifics of preparedness planning for and management of acts of terrorism on railways. Medicine of Catastrophes, 1, 15–18.
- 8. Shapovalov, V.M., Samokhvalov, I.M., & Lytaev, S.A. (2012). Amazing factors, mechano-pathogenesis, clinical manifestations of explosive damage of peacetime. Quality Management in the Sphere of Health Care and Social Development, 3, 46–51.
- 9. Chernozubenko A.V., Kuprinenko, A.N., & Bisyk, S.P. (2014). Study of damaging factors sap mine explosive devices on the human body. Systems of Armament and Military Equipment, 2, 39–44.
- 10. Ivanitski, A., & Petriko, H. (2014). Assessment of consequences of impact of emergency explosion of fuel-air mixture on a person. Bulletin of the Command-Engineering Institute of the Ministry of Emergencies of the Republic of Belarus, 1(19), 67–72.
- 11. Kriuchkova, A.S., Arzhavkina, L.G., Zhekalov, A.N., Protasov, O.V., & Chernyavskiy, E.A. (2015). Influence of blast wind injury of minor and medium severity on physical efficiency and behavioral reactions in animals. Herald of the Russian Military Medical Academy, 1(49), 169–172.
- 12. Luchko, I.A., Remez, N.S., & Luchko, A.I. (2010). Wave processes in soil massifs during explosions of new blended explosives. Bulletin of NTUU “KPI”. Series “Mining”, 19, 24–25.
- 13. Luchko, I.A., Remez, N.S., & Luchko, A.I. (2011). Mathematical modeling of the explosion in soils and rocks. Kyiv: NTUU “KPI”.
- 14. Remez, N.S., Luchko, I.A., & Luchko, A.I. (2006). Efficiency of application of new non-destructive explosives at consolidation of soil bases. SRI of Building Constructions, 64, 296–301.
- 15. Vorobiov, V.D., & Tverda, O.Y. (2012). Justification of the criterion for selecting a safe and effective type of explosives in mass explosions in quarries. Problems of Labor Protection in Ukraine, 22, 56–64.
- 16. Remez, N., Dychko, A., Kraychuk, S., Ostapchuk, N., & Yevtieieva, L. (2018). Simulation of seismic explosion waves with underground pipe interaction. Journal of Physics and Engineering, 3, 27–33. DOI: http://dx.doi.org/10.2478/lpts-2018-001110.2478/lpts-2018-0011
- 17. Remez, N., Dychko, A., & Yevtieieva, L. (2018). Stress-deformed state of soil at the explosion of cylindrical charge of new industrial mixed explosives. Development of Scientific Foundations of Resource-Saving Technologies of Mineral Mining and Processing (pp. 105–125). Sofia: Publishing House St.Ivan Rilski.
- 18. Remez, N., Dychko, A., Kraychuk, S., & Ostapchuk, N. (2018). Interaction of seismicexplosive waves with underground and surface structures. Resources and Resource-Saving Technologies in Mineral Mining and Processing (pp. 291–310). Petroşani, Romania: UNIVERSITAS Publishing.
- 19. Isayenko, V.M., Vovk, O.O., Zaychenko, S.V., Remez N.S., & Vovk, O.O. (2018). Methods of Forecasting and Monitoring of Technogenic Dynamic Processes in the Extraterritorial Territories. Kyiv: NAU.
- 20. Guselskikov, Y.O., Vylokhin, S.A., & Ponikarov, S.I. (2014). Study of effective parameters of an air shock wave. Bulletin of the Kazan Technological University, 9, 81–83.