Research and Evaluation of Coal Mine Ventilation Management

[1] Puchkov L.A., 1993 Aerodynamics of underground workings. Publishing house of the Moscow State Mining University, 266 p. (In Russ.). Search in Google Scholar

[2] Lapshin A.A., Lapshin A.E., Lyashenko V.I., 2016 Improving safety and labor protection in deep mines with chamber systems with hardening backfill of the worked-out space. Labor safety in industry № 6.- P.29-34. (In Russ.). Search in Google Scholar

[3] Semin M.A., Levin L.Yu, 2019 Stability of air flows in mine ventilation networks. Process Safety and Environmental Protection. 20 February 2019. Vol. 124 (Cover date: April 2019) pp. 167-171. DOI: 10.1016/j.psep.2019.02.006. Search in Google Scholar

[4] Thakur P.I., 2019 Underground Coal Mine Atmosphere. Advanced Mine Ventilation. Respirable Coal Dust, Combustible Gas and Mine Fire Control. pp. 3-16. DOI: 10.1016/B978-0-08-100457-9.00001-8. Search in Google Scholar

[5] Cheng L., Guo H., Lin H., 2021 Evolutionary model of coal mine safety system based on multi-agent modeling. Process Safety and Environmental Protection. Vol. 147, March 2021, pp. 1193-1200. DOI: 10.1016/j.psep.2021.01.046. Search in Google Scholar

[6] Makarov V.I., Belov S.V., Mutalapova N.V., 2019 Dynamics of mine ventilation modes of coal mines. Mining information and analytical bulletin (scientific and technical journal). Issue 12. Volume 16. 2009. P. 341-348. (In Russ.). Search in Google Scholar

[7] Esterhuizen G. S., Gearhart D. F., Klemetti T., Dougherty H., Dyke M., 2019 Analysis of gateroad stability at two longwall mines based on field monitoring results and numerical model analysis. International Journal of Mining Science and Technology. Vol. 29, Issue 1, January 2019, pp. 35-43. DOI: 10.1016/j.ijmst.2018.11.021. Search in Google Scholar

[8] Wang K., Jiang Sh., Wu Zh., Shao H., Zhang W., Pei X., Cui Ch., 2017 Intelligent safety adjustment of branch airflow volume during ventilation-on-demand changes in coal mines. Process Safety and Environmental Protection. Vol. 111, October 2017, pp. 491-506. DOI: 10.1016/j.psep.2017.08.024. Search in Google Scholar

[9] Gamiy, Yu., Kostenko, V., Zavialova, O., Kostenko, T., & Zhurbynskyi, D., 2020 Identifying sources of coal spontaneous heating in mine workings using aerogas control automatic systems. Mining of Mineral Deposits, 14(1), 120-127. https://doi.org/10.33271/mining14.01.120 Search in Google Scholar

[10] Shahani, N.M., Sajid, M.J., Zheng, X., Jiskani, I.M., Brohi, M.A., Ali, M., Ullah, B., & Qureshi, A.R., 2019 Fault tree analysis and prevention strategies for gas explosion in underground coal mines of Pakistan. Mining of Mineral Deposits, 13(4), 121-128. https://doi.org/10.33271/mining13.04.121 Search in Google Scholar

[11] Qiao W., 2021 Analysis and measurement of multifactor risk in underground coal mine accidents based on coupling theory. Reliability Engineering & System Safety. Volume 208, April 2021, 107433. DOI: 10.1016/j.ress.2021.107433. Search in Google Scholar

[12] Zhang L., Zhou G., Ma Yu, Jing B., Sun B., Han F., He M., Chen Xu., 2021 Numerical analysis on spatial distribution for concentration and particle size of particulate pollutants in dust environment at fully mechanized coal mining face. Powder Technology. Volume 383, May 2021, pp. 143-158. DOI: 10.1016/j.powtec.2021.01.039. Search in Google Scholar

[13] Mashintsov E.A., Kotlerevskaya L.V., Krinichnaya N.A., 2014 Ventilation control in a coal mine // Bulletin of the Tula State University. Technical science. No. 7. pp. 188-195. (In Russ.). Search in Google Scholar

[14] Skopintseva O.V., Balovtsev S.V., 2013 On the question of assessing the aerological risk for various ventilation schemes of excavating areas of coal mines. Scientific Bulletin of the Moscow State Mining University. No. 1. pp. 87-100. (In Russ.). Search in Google Scholar

[15] Kaledina N.O., 2011 Substantiation of the parameters of ventilation systems of high-performance coal mines. Mining information and analytical bulletin (scientific and technical journal). No. 7. pp. 261-271. (In Russ.). Search in Google Scholar

[16] Bakhvalov L.A., Barannikova I.V., Agabubaev A.T., 2017 Analysis of modern automatic ventilation control systems. Mining information and analytical bulletin (scientific and technical journal). No. 7. pp. 22-28. (In Russ.). Search in Google Scholar

[17] Kosterenko V.N., 2011 Mathematical modeling of non-stationary ventilation processes in coal mines. Dissertation for the degree of candidate of physical and mathematical sciences / Tomsk State University. Tomsk, (In Russ.). Search in Google Scholar

[18] Vasenin I.M., Shrager E.R., Krainov A.Yu., Paleev D.Yu., Lukashov O.Yu., Kosterenko V.N., 2011 Mathematical modeling of non-stationary ventilation processes in the network of coal mine workings. Computer Research and Modeling. T. 3. No. 2. pp. 155-163. (In Russ.). Search in Google Scholar

[19] Mashintsov E.A., Kotlerevskaya L.V., Krinichnaya N.A. 2014 Ventilation control in a coal mine // Bulletin of the Tula State University. Technical science. No. 7. pp. 188-195. Search in Google Scholar

[20] Kharik E.K., Astanin A.V., 2011 Numerical study of ventilation of a coal mine in a three-dimensional setting. Bulletin of Nizhegorodskogo universiteta im. N.I. Lobachevsky. 2011. No. 4-5. pp. 2567-2569. (In Russ.). Search in Google Scholar

[21] Klyuev R.V., Bosikov I.I., Mayer A.V., Gavrina O.A., 2020 Comprehensive analysis of the effective technologies application to increase sustainable development of the natural-technical system. Sustainable Development of Mountain Territories. 2020, №2, pp. 283-290. DOI: 10.21177/1998-4502-2020-12-2-283-290. Search in Google Scholar

[22] Klyuev R.V., Bosikov I.I., Egorova E.V., Gavrina O.A., 2020 Assessment of mining-geological and mining technical conditions of the Severny pit with the use of mathematical models. Sustainable Development of Mountain Territories. 2020, №3, pp. 418-427. DOI: 10.21177/1998-4502-2020-12-3-418-427. Search in Google Scholar

[23] Sjöström S., Klintenäs E., Johansson P., Nyqvist J., 2020 Optimized model-based control of main mine ventilation air flows with minimized energy consumption. International Journal of Mining Science and Technology. Volume 30, Issue 4, July 2020, pp. 533-539. DOI: 10.1016/j.ijmst.2020.05.016. Search in Google Scholar

[24] Klyuev R., Bosikov I., Gavrina O., Madaeva M., Sokolov A., 2021 Improving the energy efficiency of technological equipment at mining enterprises. In: Murgul V., Pukhkal V. (eds) International Scientific Conference Energy Management of Municipal Facilities and Sustainable Energy Technologies EMMFT 2019. EMMFT 2019. Advances in Intelligent Systems and Computing, vol 1258, pp. 262-271, Springer, Cham. https://doi.org/10.1007/978-3-030-57450-5_24. Search in Google Scholar

[25] Nazarenko M.V., Nazarenko V.M., Lyashenko V.I., 2018 Development of geoinformation provision of mining operations. Chernaya metallurgiya. Byulleten nauchnotechnicheskoj i ekonomicheskoj informacii = Ferrous Metallurgy. Bulletin of Scientific, Technical and Economic Information, 2018, no. 7, pp. 11–22. (In Russ.) Search in Google Scholar

[26] Rudko G.I., Netskiy O.V., Nazarenko M.V., 2018 Geoinformation technologies for geological and economic assessment of genus of bark copalina (using GIS K– MINE®). GEOINFORMATIKA, No. 3 (67), 14-24. (in Ukrainian) Search in Google Scholar

[27] Gurin A.A., Shapovalov V.A., Lyashenko V.I., 2021 Improving the safety of aspiration and ventilation systems by cleaning air ducts. Labor safety in industry. No. 1. pp. 40-45. (In Russ.) Search in Google Scholar

[28] Gurin A.A., Shapovalov V.A., Lapshin A.E., Lyashenko V.I., 2022 Increasing the safety and efficiency of cleaning settled dust in the premises of mining and processing enterprises. Labor safety in industry. No. 2, pp 50–57. DOI: 10.24000/0409-2961-2022-2-50-57. (In Russ.) Search in Google Scholar

[29] Lozynskyi, V., Saik, P., Petlovanyi, M., Sai, K., & Malanchuk, Y., 2018 Analytical Research of the Stress-Deformed State in the Rock Massif around Faulting. International Journal of Engineering Research in Africa, 35, 77-88. https://doi.org/10.4028/www.scientific.net/jera.35.77. Search in Google Scholar

[30] Hapich, H., Andrieiev, V., Kovalenko, V., & Makarova, T., 2022 The analysis of spatial distribution of artificial reservoirs as anthropogenic fragmentation elements of rivers in the Dnipropetrovsk Region, Ukraine. Journal of Water and Land Development, 53(IV-VI), 80-85. https://doi.org/10.24425/jwld.2022.140783 Search in Google Scholar