Maksym Kononenko1, Oleh Khomenko2, Ihor Kovalenko3, Inna Myronova4, Andrii Kosenko1
1Department of the Transport systems and energy-mechanical complexes, Dnipro university of technology, 19 Yavornytskoho Ave., Dnipro, 49005, Ukraine
2Department of Mining Engineering and Education, Dnipro university of technology, 19 Yavornytskoho Ave., Dnipro, 49005, Ukraine
3Department of Technology of Inorganic Substances and Ecology, Ukrainian State University of Chemical Technology, 8 Gagarin Ave., Dnipro, 49005, Ukraine
4Department of Ecology and Environmental protection technologies, Dnipro University of technology, 19 Yavornytskoho Ave., Dnipro, 49005, Ukraine
Dnipro University of Technology
Textbook – 252 pages
https://doi.org/10.33271/DUT.006
Full text (.pdf)
ABSTRACT
The monograph is devoted to solving the scientific problem of geomechanics of creating underground infrastructure during ore mining using emulsion explosives based on the established patterns of the formation of crush zones, intensive grinding and cracking around the charging cavity formed in a rock mass as a result of the explosion, as well as changes in the density and detonation velocity of emulsion explosives along the length of the charge column, formed at different angles of inclination of the wells. The established patterns form the basis of methods for calculating the parameters of drilling and blasting for creating underground infrastructure during ore mining, as well as calculating the performance of both emulsion and other industrial explosives based on the degree of detonation velocity.
The monograph is intended for a wide range of engineering and technical workers, mining engineers, research and design organizations. Can be used in the educational process of institutions of higher and secondary vocational education when teaching disciplines in mining.
Keywords: rock mass, emulsion explosive, charging cavity, zone of intensive grinding, emulsion explosive density, detonation velocity, line of least resistance
REFERENCES
1. Khomenko, O.Ye., Kononenko, M.M., Vladyko, O.B., & Maltsev, D.V. (2011). Hirnychorudna sprava Ukrainy v merezhi Internet. Dnipropetrovsk : DVNZ «NHU».
2. Khomenko, O., Kononenko, M., & Lyashenko, V. (2019). Safe Mining of Granites at the Manganese Ore Deposits of Ukraine. Occupational Safety in Industry, 1, 53–61. https://doi.org/10.24000/0409-2961-2019-1-53-61
3. Mineralni resursy Ukrainy (2018). Kyiv: Derzhavne naukovo-vyrobnyche pidpryiemstvo «Derzhavnyi informatsiinyi heolohichnyi fond Ukrainy».
4. Kosenko, A., Khomenko, O., & Kononenko, M. (2023). The latest technologies for sublevel caving in iron ore mining. https://doi.org/10.33271/dut.003
5. Kononenko, M., Khomenko, O., & Astafiev, D. (2017). New Сlassification of Ore Deposits Mining Methods. Advanced Engineering Forum, 25, 71–79. https://doi.org/10.4028/www.scientific.net/aef.25.71
6. Kononenko M., Khomenko O., & Astafiev D. (2017). New classification of ore deposits mining methods. In Energy efficiency and energy saving 2017 (p. 24). Dnipro: NMU.
7. Khomenko, O.E. (2007). Usovershenstvovanie tekhnologii dobychi zheleznykh rud iz okhrannykh tselikov: monografiya. Dnepropetrovsk : NGU.
8. Khomenko, O.E. (2016). Geoenergektika podzemnoy razrabotki rudnykh mestorozhdeniy. Dnepropetrovsk : NGU.
9. Khomenko, O., & Kononenko, M. (2018). Safe Development of the Decorative Jaspilites in the Energetically Disturbed Massifs. Occupational Safety in Industry, 8, 15–23. https://doi.org/10.24000/0409-2961-2018-8-15-23
10. Liadenko, T.V. (2019). Analiz stanu realizatsii orhanizatsiino-ekonomichnoho mekhanizmu marketynhu zalizorudnykh pidpryiemstv Ukrainy. Ekonomika ta derzhava, (5), 111–117.
11. Khomenko, O.Ye. ta in. (2013). Pidzemni hirnychi ustanovky ta obladnannia. Vol. 1. Ulan-Bator.
12. Khomenko, O.E., Kononenko, M.N., & Maltsev, D.V. (2011). Gornoe oborudovanie dlya podzemnoy razrabotki rudnykh mestorozhdeniy. Dnepropetrovsk: NGU.
13. Rimarchuk, B.I., Sedunova, G.T., & Grishchenko, T.S. (2014). Puti snizheniya intensivnosti seysmicheskikh kolebaniy na prilegayushchey territorii pri massovykh vzryvakh na sh. im. Ordzhonikidze. Vіsnik Krivorіzkogo natsіonalnogo unіversitetu, 36, 172–174.
14. Khomenko, O.E., & Kononenko, M.N. (2010). Tekhnologiya krepleniya vyrabotok dlya kamernykh sistem razrabotki s zakladkoy. Dnepropetrovsk : NGU.
15. Guang, Wang Xu (1994). Emulsion explosives. Beijing: Metallurgical Industry Press.
16. Kolganov, E.V., & Sosnin, V.A. (2009). Emulsionnye promyshlennye vzryvchatye veshchestva. Sostavy i svoystva. GosNII «Kristall».
17. Kovalenko, I.L., & Kiyashchenko, D.V. (2015). Tekhnologiya modifitsirovaniya agrarnoy ammiachnoy selitry v proizvodstve energokondensirovannykh sistem. Science and education a new dimension. Natural and technical sciences, 3(8(73)), 107–110.
18. Kovalenko, I.L., & Kuprin, V.P. (2013). Fiziko-khimicheskiy podkhod k razrabotke prosteyshikh vzryvchatykh veshchestv dlya podzemnykh rabot. Vysokoenergeticheskie sistemy, protsessy i ikh modeli, 189–198.
19. Kantor, V.Kh. (2007). Novaya tekhnika i tekhnologiya izgotovleniya promyshlennykh vzryvchatykh veshchestv s termoobrabotkoy granulirovannoy ammiachnoy selitry. Vzryvnoe delo, 98/55, 181–191.
20. Efremov, E.I., Rimarchuk, B.I., & Shvartser, V.Ya. (2006). Sovershenstvovanie prosteyshikh vzryvchatykh smesey na osnove ammiachnoy selitry i nefteproduktov. Vіsnik KDPU, 2(37), 81–84.
21. Kuprin, V.P., & Kovalenko, I.L. (2012). Rozrobka i vprovadzhennia emulsiinykh vybukhovykh rechovyn na kar’ierakh Ukrainy. Dnipropetrovsk: DVNZ UDKhTU.
22. Brovko, D.V., Khvorost, V.V., Sergeev, S.S., & Prylepskyш, A. M. (2018). Study of efficiency of emulsion explosives utilization under the underground conditions of the Kryvyi Rih iron-ore basin. Jornal of Kryvyi Rih National University, 46, 81–85. https://doi.org/10.31721/2306-5451-2018-1-46-81-85
23. Ishchenko, M.I., Klimenko, V.A., Krysin, R.S., Savchenko, M.V., Kuprin, V.P., Novinskii, V.V., & Kuprin, O.V. (2005). Emulsiina vybukhova rechovyna Ukrainit-PP-1. Patent No 52403, Ukraine.
24. Krysin, R.S., Dziubienko, S.A., Novinskii, V.V., Ishchenko, M.I., Piven, V.O., Savchenko, M.V., Kuprin, V.P., Kuprin, O.V., Klimenko, V.A., & Kliamko, A.S. (2005). Emulsiina vybukhova rechovyna Ukrainit-PP-2. Patent No 74500, Ukraine.
25. Kuprin, V.P., Ishchenko, M.I., Kuprin, O.V., & Savchenko, M.V.. (2009). Emulsiina vybukhova rechovyna «Ukrainit-PP-2B». Patent No 41672, Ukraine.
26. Kovalenko, I.L., Kuprin, A.V., Dovban, L.V., & Teplitskaya, A.G. (2008). Vliyanie nitratov kaltsiya i natriya na fiziko-khimicheskie svoystva ammiachnoy selitry i ee rastvorov. Voprosy khimii i khim. tekhnologii, 2, 247–251.
27. Kuprin, O.V., Rykov, S.V., Kuprin, V.P., & Savchenko, M.V. (2011). Patronovana emulsiina vybukhova rechovyna «Ukrainit-P». Patent No 63689, Ukraine.
28. Zubko, S.A., Russkikh, V.V., Yavorskiy, A.V., & Yavorskaya, E.A. (2013). Vnedrenie smesitelno-zaryadnoy i dostavochnoy tekhniki dlya emulsionnogo vzryvchatogo veshchestva «Ukrainit» na gornodobyvayushchikh predpriyatiyakh Ukrainy. Geotekhnіchna mekhanіka, 111, 37–48.
29. Savchenko, M.V., Koliesaiev, M.B., Nebohin, V.Z., & Onopriienko, Ye.P. (2012). Pnevmonasos-zariadnyk emulsiinykh vybukhovykh rechovyn ZEP-10. Patent No 67340, Ukraine.
30. Karapa, I.A., Zubko, A.M., Nebohin, V.Z., & Koliesaiev, M.B. (2011). Zariadnyk emulsiinykh vybukhovykh rechovyn ZEP-15. Patent No 62192, Ukraine.
31. Kovalenko, I.L., Stupnik, N.I., Korolenko, M.K., Poltorashchenko, S.P., Karapa, I.A., Kiyashchenko, D.V., & Nebogin, V.Z. (2016). Osobennosti tekhnologii formirovaniya skvazhinnykh zaryadov emulsionnymi VV Ukrainit v podzemnykh usloviyakh. Vіsnik Krivorіzkogo natsіonalnogo unіversitetu, 41, 3–6.
32. Melnik, V.B., Sakharov, A.N., & Braunshteyn, A.A. (2013). Podzemnaya dobycha rudy v OAO «Apatit». Sovremennoe sostoyanie i perspektivy. Globus (Geologiya i biznes), 5(29), 14–21.
33. Sosnin, V.A., Morozov, K.E., & Korunov, V.N. (2014). Tekhnologicheskie osobennosti polucheniya EVV dlya zaryazhaniya i vzryvaniya v podzemnykh vyrabotkakh. Vzryvnoe delo, 111/68, 267–273.
34. Korolenko, M.K., Stupnik, N.I., Kovalenko, I.L., Poltorashchenko, S.P., & Karapa, I.A. (2016). Zaryazhanie skvazhin nalivnymi emulsionnymi VV marki Ukrainit v podzemnykh usloviyakh. Іnformatsіyniy byuleten Ukraїnskoї spіlki іnzhenerіv-pіdrivnikіv, 4(32), 5–11.
35. Kiiashchenko, D.V., Serhiienko, I.D., Kuprin, V.P., Savchenko, M.V., Rakhimov, R.Kh., & Dziubienko, S.A. (2012). Aparat otrymannia emulsii dlia emulsiinoi vybukhovoi rechovyny. Patent No 69553, Ukraine.
36. Kovalenko, I.L., Kuprin, V.P., & Kiyaschenko, D.V. (2015). Energycondensed packaged systems. Composition, production, properties. Odes'kyi Politechnichnyi Universytet. Pratsi, 1(45), 164–170.
37. Lyashenko, V.I., Nebogin, V.Z., & Shkarin, V.V. (2015). Povyshenie bezopasnosti proizvodstva vzryvnykh rabot s pomoshchyu emulsionnykh vzryvchatykh veshchestv na shakhtakh. Bezopasnost truda v promyshlennosti, 7, 28–32.
38. Lyashenko, V.I., Nebogin, V.Z., & Shkarin, V.V. (2016). Povyshenie effektivnosti proizvodstva vzryvnykh rabot na shakhtakh Ukrainy. Marksheyderiya i nedropolzovanie, 3, 14–22.
39. Lyashenko, V.I., Golik, V.I., Komashchenko, V.I., & Nebogin, V.Z. (2018). Povyshenie effektivnosti proizvodstva vzryvnykh rabot s pomoshchyu emulsionnykh vzryvchatykh veshchestv na shakhtakh. Vzryvnoe delo, 119/76, 143–163.
40. Khomenko, O., Kononenko, M., & Kosenko, A. (2022). Processes of underground mining of ore deposits. Dnipro University of Technology. https://doi.org/10.33271/dut.002
41. Andreev, B.N., & Sergeev, S.S. (2016). Sovershenstvovanie parametrov burovzryvnykh rabot pri prokhodke gorizontalnykh vyrabotok glubokimi zakhodkami na shakhtakh Krivorozhskogo baseyna. Visnyk Kryvorizkoho natsionalnoho universytetu, 43, 21–25.
42. Andreev, B.N., & Sergeev, S.S. (2016). Obosnovanie parametrov tekhnologii prokhodki protyazhennykh gorizontalnykh vyrabotok s ispolzovaniem vysokoproizvoditelnykh prokhodcheskikh kompleksov. Visnyk Kremenchutskoho natsionalnoho universytetu im. Mykhaila Ostrohradskoho, 4, 48–53.
43. Poltorashchenko, S.P., Mohylievskyi, O.L., Khyvrenko, O.Ya., & Savytskyi, O.O. (2019). Vyznachennia ratsionalnykh parametriv BPR pry zastosuvanni emulsiinoi vybukhovoi rechovyny «Ukrainit PP-2» v pidzemnykh umovakh PrAT «ZZRK». Informatsiinyi biuleten Ukrainskoi spilky inzheneriv-pidryvnykiv, 1(37), 13–16.
44. Martynov, V.K. (1987). Proektirovanie i raschet sistem razrabotki rudnykh mestorozhdeniy. Kiev-Donetsk: Vishcha shk. Golovnoe izd-vo.
45. Kozyrev, S.A., & Fattakhov, E.I. (2007). Avtomatizirovannoe proektirovanie burovzryvnykh rabot pri provedenii gornykh vyrabotok. Gornyy informatsionno-analiticheskiy byulleten (nauchno-tekhnicheskiy zhurnal), 6(2), 105–113.
46. Kozyrev, S.A., & Fattakhov, E.I. (2007). Sistema avtomatizirovannogo proektirovaniya burovzryvnykh rabot dlya prokhodki gornykh vyrabotok v OAO «Apatit». Gornyy zhurnal, 4, 73–74.
47. Russkikh, V.V., Gayday, A.A., & Dotsenko, V.I. (2013). Proektirovanie ochistnykh rabot na ZAO «Zaporozhskiĭ zhelezorudnyy kombinat» s primeneniem imitatsionnogo modelirovaniya. Zbirnyk naukovykh prats NHU, 40, 41–46.
48. Kutuzov, B.N. (1988). Vzryvnye raboty. Nedra.
49. Protodyakonov, M.M. (1926). Materialy dlya urochnogo polozheniya gornykh rabot. Prokhodka vyrabotok. Izdanie TsK gornorabochikh SSSR.
50. Mangush, S.K., & Fisun, A.P. 2003. Spravochnik po burovzryvnym rabotam na podzemnykh gornykh razrabotkakh.
51. Drukovanyy, M.F. i dr. (1976). Spravochnik po burovzryvnym rabotam. Nedra.
52. Martynov, V.K., & Fedko, M.B. (2008). Rozrakhunky osnovnykh vyrobnychykh operatsii, protsesiv ta system rozrobky rudnykh rodovyshch. Kryvyi Rih: Vydavnychyi tsentr KTU.
53. Pokrovskiy, N.M. (1977). Tekhnologiya stroitelstva podzemnykh sooruzheniy i shakht. Tekhnologiya sooruzheniya gorizontalnykh gornykh vyrabotok i tonneley. Nedra.
54. Mindeli, E.O. (1960). Burovzryvnye raboty pri provedenii gornykh vyrabotok. Gosgortekhizdat.
55. Mindeli, E.O. (1974). Razrushenie gornykh porod. Nedra.
56. Taranov, P.Ya. (1964). Burovzryvnye raboty. Nedra.
57. Taranov, P.Ya., Guzd, A.G. (1976). Razrushenie gornykh porod vzryvom. Nedra.
58. Langefors, U., & Kilstrem, B. (1968). Sovremennaya tekhnika vzryvnoy otboyki gornykh porod. Nedra.
59. Borisov, S.S. (1988). Gornoe delo. Nedra.
60. Roginskiy, V.M. (1987). Provedenie gorno-razvedochnykh vyrabotok. Nedra.
61. Shekhurdin, V.K. (1985). Gornye raboty, provedenie i kreplenie gornykh vyrabotok. Nedra.
62. Shekhurdin, V.K., Nesmotryaev, V.I., & Fedorenko, P.I. (1987). Gornoe delo. Nedra.
63. Kutuzov, B.N., & Andrievskiy, A.P. (2002). Novaya teoriya i novye tekhnologii razrusheniya gornykh porod udlinennymi zaryadami vzryvchatykh veshchestv. Nauka.
64. Vokhmin, S.A., Kurchin, G.S., Kirsanov, A.K., & Deryagin, P.A. (2014). Metodika rascheta parametrov burovzryvnykh rabot pri prokhodke gorizontalnykh i naklonnykh gornykh vyrabotok. Vestnik Magnitogorskogo gosudarstvennogo tekhnicheskogo universiteta im. G.I. Nosova, 4(48), 5–9.
65. Vokhmin, S.A., Kurchin, G.S., & Kirsanov, A.K. (2016). Raschet skorosti detonatsii dlya ammiachno-selitrennykh vzryvchatykh veshchestv. Marksheyderiya i nedropolzovanie, 4(84), 36–38.
66. Kurchin, G.S., Vokhmin, S.A., Kirsanov, A.K., Shigin, A.O., & Shigina, A.A. (2015). Calculation methodology of blasting and explosion operations' parameters for construction of horizontal and inclined excavations. International Journal of Applied Engineering Research, 10(15), 35897–35906.
67. Avdeev, F.A., Baron, V.L., Gurov, M.V., & Kantor, V.Kh. (1986). Normativnyy spravochnik po burovzryvnym rabotam. Nedra.
68. Erofeev, I.E. (1977). Povyshenie effektivnosti burovzryvnykh rabot na rudnikakh. Nedra.
69. Baron, L.I., Vasilyev, G.A., & Dokuchaev, M.M. (1981). Vzryvnye raboty. Nedra.
70. Baranov, A.O. (1993). Proektirovanie tekhnologicheskikh skhem i protsessov podzemnoy dobychi rud. Nedra.
71. Baranov, A.O. (1985). Raschet parametrov tekhnologicheskikh protsessov podzemnoy dobychi rud. Nedra.
72. Mindeli, E.O., Salganik, V.A., & Vorotelyak, G.A. (1977). Metody i sredstva vzryvnoy otboyki rudy. Nedra.
73. Kutuzov, B.N. i dr. (1974). Proektirovanie vzryvnykh rabot. Nedra.
74. Dubynin, N.G., & Ryabchenko, E.P. (1972). Otboyka rudy zaryadami skvazhin razlichnogo diametra. Nauka.
75. Vorotelyak, G.A. i dr. (1977). Instruktivno-metodicheskie ukazaniya po vyboru ratsionalnykh parametrov burovzryvnykh rabot pri podzemnoy ochistnoy vyemke na shakhtakh Krivorozhskogo basseyna i ZZhRK. Krivoy Rog: NIGRI.
76. Kaplenko, Yu.P. (1982). Metodicheskie ukazaniya po raschetu parametrov burovzryvnykh rabot. Krivoy Rog : KGRI.
77. Kaplenko, Yu.P. (1977). Instruktsiya po vyboru parametrov BVR pri otboyke rudy glubokimi skvazhinami. Krivoy Rog : KGRI.
78. Martynov, V.K. (1987). Proektirovanie i raschet sistem razrabotki rudnykh mesto-rozhdeniy. Kiev; Donetsk: Vishcha shkola.
79. Drukovannyy, M.F., Kuts, V.S., & Ilin, V.I. (1980). Upravlenie deystviem vzryva skvazhinnykh zaryadov na karyerakh. Nedra.
80. Kazakov, N.N. (1975). Vzryvnaya otboyka rud skvazhinnymi zaryadami. Nedra.
81. Komir, V.M., Kuznetsov, V.M., Vorobyev, V.V., & Chebenko, V.N. (1988). Povyshenie effektivnosti deystviya vzryva v tverdoy srede. Nedra.
82. Efremov, E.I., & Petrenko, V.D. (1984). Mekhanika vzryvnogo razrusheniya porod razlichnoy struktury. Kiev: Nauk. Dumka.
83. Sukhanov, A.F. i dr. (1962). Burovzryvnye raboty. Gosgortekhizdat.
84. Sukhanov, A.F. (1950). Teoriya deystviya zaryada v porode. Alma-Ata: izd-vo AN KazSSR.
85. Sukhanov, A.F., & Kutuzov, B.N. (1963). Sovremennyy uroven tekhniki burovzryvnykh rabot i razrusheniya gornykh porod. MGI.
86. Lavrentyev, M.A., Kuznetsov, V.M., & Sher, E.N. (1960). O napravlennom metanii grunta pri pomoshchi VV. Problemy mekhaniki i teoreticheskoy fiziki, 4, 49–50.
87. Vlasov, O.E. (1957). Osnovy teorii deystviya vzryva. VIA.
88. Smirnov, S.A., & Vlasov, O.E. (1962). Osnovy rascheta drobleniya gornykh porod vzryvom. Izd-vo AN SSSR.
89. Demidyuk, G.P. (1956). O mekhanizme deystviya vzryva i svoystva vzryvchatykh veshchestv. Vzryvnoe delo, 45/2, 20–35.
90. Demidyuk, G.P. (1962). Sovremennye teoreticheskie predstavleniya o deystvii vzryva v srede. Burovzryvnye raboty v gornoy promyshlennosti, 223–240.
91. Belyaev, A.F., & Sadovskiy, M.A. (1952). O prirode fugasnogo i brizantnogo deystviya vzryva. Fizika vzryva, 1, 3–19.
92. Mosinets, V.N. (1976). Drobyashchee i seysmicheskoe deystvie vzryva v gornykh porodakh. Nedra.
93. Anistratov, Yu.I. (1996). Energeticheskaya teoriya rascheta tekhnologii otkrytykh gornykh rabot. Gornyy informatsionno-analiticheskiy byulleten (nauchno-tekhnicheskiy zhurnal), 3, 20–29.
94. Anistratov, Yu.I. (2005). Tekhnologicheskie potoki na karyerakh: energeticheskaya teoriya otkrytykh gornykh rabot. Globus.
95. Anistratov, Yu.I., Anistratov, K.Yu., & Shchadov, M.I. (2010). Spravochnik po otkrytym gornym rabotam. NTTs «Gornoe delo».
96. Pokrovskiy, G.I., & Fedorov, I.S. (1957). Deystvie udara i vzryva v deformiruemykh. Gosstroyizdat.
97. Pokrovskiy, G.I. (1980). Vzryv. Nedra.
98. Melnikov, N.V. (1957). Razvitie gornoy nauki v oblasti otkrytoy razrabotki mestorozhdeniy v SSSR. Ugletekhizdat.
99. Khanukaev, A.N. (1958). O fizicheskoy sushchnosti protsessa razrusheniya gornykh porod vzryvom. Voprosy teorii razrusheniya gornykh porod deystviem vzryva, 7–43.
100. Khanukaev, A.N. (1962). Energiya voln napryazheniy pri razrushenii porod vzryvom. Gosgortekhizdat.
101. Drukovanyy, M.F. (1973). Metody upravleniya vzryvom na karyerakh. Nedra.
102. Baum, F.A., Orlenko, L.P., & Stanyukovich, K.P. (1975). Fizika vzryva. Nauka.
103. Baum, F.A. (1963). Protsess razrusheniya gornykh porod vzryvom. Vzryvnoe delo, 52/9, 262–285.
104. Baron, L.I., Dokuchaev, M.L., Vasilyev, G.A., & Doronichev, L.P. (1960). Vzryvnye raboty v gornorudnoy promyshlennosti. Gosgortekhizdat.
105. Kutter, H.K. (1972). Failure Mechanism of Jointed Rock. Rock Mechanics, 95–109. https://doi.org/10.1007/978-3-7091-4109-0_6
106. Efremov, E.I., Kravtsov, V.S., Myachina, N.I., & Petrenko, V.D. (1987). Razrushenie gornykh porod energiey vzryva. Kiev: Naukova dumka.
107. Rzhevskiy, V.V., & Novik, G.Ya. (1984). Osnovy fiziki gornykh porod. Nedra.
108. Mosinets, V.N., & Gorbacheva, N.P. (1972). A seismological method of determining the parameters of the zones of deformation of rock by blasting. Soviet Mining Science, 8(6), 640–647. https://doi.org/10.1007/bf02497586
109. Saharan, M.R., & Mitri, H.S. (2007). Numerical Procedure for Dynamic Simulation of Discrete Fractures Due to Blasting. Rock Mechanics and Rock Engineering, 41(5), 641–670. https://doi.org/10.1007/s00603-007-0136-9
110. Bilokon, V.P., Olkhovskiy, A.K., & Belokon, M.P. (1974). Raschet velichiny linii naimenshego soprotivleniya pri skvazhinnoy otboyke gornykh porod na zhelezorudnykh karyerakh. Mekhanika i razrushenie gornykh porod, 2, 230–236.
111. Drukovanyi, M.F., Kravtsov, V.S., Chernyavskii, Yu.E., Shelenok, V.V., Reva, N.P., & Zver’kov, S.N. (1976). Calculation of fracture zones created by exploding cylindrical charges in ledge rocks. Soviet Mining Science, 12(3), 292–295. https://doi.org/10.1007/bf02594873
112. Rakishev, B.R. (1983). Prognozirovanie tekhnologicheskikh parametrov vzorvannykh porod na karyerakh. Alma-Ata: Nauka.
113. Rakishev, B.R. (2010). Opredelenie razmerov zon razrusheniya v massive porod pri skvazhinnykh zaryadakh drobleniya. Vzryvnoe delo, 103/60, 53–65.
114. Grebenyuka, V.A., Pyzhyanova, Ya.S., & Erofeeva, I.E. (1983). Spravochnik po gornorudnomu delu. Nedra.
115. Efremov, E.I., Petrenko, V.D., & Pastukhov, A.I. (1990). Prognozirovanie drobleniya gornykh massivov vzryvom. Kiev: Naukova dumka.
116. Adushkin, V.V., & Spivak, A.A. (1993). Geomekhanika krupnomasshtabnykh vzryvov. Nedra.
117. Szuladzinski, G. (1993). Response of rock medium to explosive borehole pressure. In Proceedings of the Fourth International Symposium on Rock Fragmentation by Blasting-Fragblast-4 (pp. 17–2). Vienna (Austria).
118. Kexin, D. (1995). Maintenance of roadways in soft rock by roadway-rib destress blasting. China Coal Society, 20(3), 311–316.
119. Kryukov, G.M., & Kosargin, A.P. (1998). Zakonomernosti formirovaniya zon melkodispersnogo drobleniya i radialnogo treshchinoobrazovaniya pri kamufletnom vzryve sosredotochennogo zaryada v kvaziodnorodnoy srede. Vzryvnoe delo, 91/48, 75–81.
120. Andrievskiy, A.P., & Kutuzov, B.N. (1998). Zakonomernost formirovaniya zon smyatiya i treshchinoobrazovaniya pri vozdeystvii na skalnyy massiv energiey vzryva udlinennogo zaryada. Otkrytie No 81/82.
121. Djordjevic, N. (1999). Two-component of blast fragmentation. In Proceedings of the sixth international symposium on rock fragmentation by blasting-fragblast (pp. 213–219). Johannesburg, South Africa.
122. Kanchibotla, S.S., Valery, W., & Morrell, S. (1999). Modelling fines in blast fragmentation and its impact on crushing and grinding. In Explo ’99: A conference on rock breaking (pp. 137–144). Kalgoorlie: The Australasian Institute of Mining and Metallurgy.
123. Persson, P.A., Holmberg, R., & Lee, J. (1993). Rock Blasting and Explosives Engineering. Boca Raton, Fla.: CRC Press.
124. Esen, S., Onederra, I., & Bilgin, H. A. (2003). Modelling the size of the crushed zone around a blasthole. International Journal of Rock Mechanics and Mining Sciences, 40(4), 485–495. https://doi.org/10.1016/s1365-1609(03)00018-2
125. Onederra, I., Esen, S., & Jankovic, A. (2004). Estimation of fines generated by blasting – applications for the mining and quarrying industries. Mining Technology, 113(4), 237–247. https://doi.org/10.1179/037178404225006191
126. Chun-rui, L., Li-jun, K., Qing-xing, Q., De-bing, M., Quan-ming, L., & Gang, X. (2009). The numerical analysis of borehole blasting and application in coal mine roof-weaken. Procedia Earth and Planetary Science, 1(1), 451–459. https://doi.org/10.1016/j.proeps.2009.09.072
127. Kuznetsov, V.A. (2010). Obosnovanie tekhnologii burovzryvnykh rabot v karyerakh i otkrytykh gorno-stroitelnykh vyrabotkakh na osnove deformatsionnogo zonirovaniya vzryvaemykh ustupov. Gornyy informatsionno-analiticheskiy byulleten, 6, 396–398.
128. Iverson, S.R., Hustrulid, W.A., & Johnson, J.C. (2013). A new perimeter control blast design concept for underground metal/nonmetal drifting applications. U.S. Department of Health and Human Services, Public Health Service, Centers for Disease Control and Prevention, National Institute for Occupational Safety and Health. https://doi.org/10.26616/nioshpub2013129
129. Torbica, S., & Lapcevic, V. (2014). Rock breakage by explosives. European International Journal of Science and Technology, 3(2), 96–104.
130. Torbica, S., & Lapčević, V. (2015). Estimating extent and properties of blast-damaged zone around underground excavations. Rem: Revista Escola de Minas, 68(4), 441–453. https://doi.org/10.1590/0370-44672015680062
131. Sukhanov, A.F., & Kutuzov, B.N. (1983). Razrushenie gornykh porod vzryvom. Nedra.
132. Rodionov, V.N., Sizov, I.A., & Tsvetkov, V.M. (1968). Issledovanie razvitiya polosti pri kamufletnom vzryve. Vzryvnoe delo, 64/21, 5–24.
133. Rodionov, V.N., Adushkin, V.V., Kostyuchenko, V.N. i dr. (1971). Mekhanicheskiy effekt podzemnogo vzryva. Nedra.
134. Yukhanson, K., & Person, P. (1973). Detonatsiya vzryvchatykh veshchestv. Mir.
135. Darkov, A.V., & Shpiro, G.S. (1989). Soprotivlenie materialov. Vyssh. shk.
136. Fesik, S.P. (1982). Spravochnik po soprotivleniyu materialov. Kiev: Budіvelnik.
137. Drukovannyy, M.F., & Komir, V.M. (1965). Mekhanizm razrushenii gornykh porod vzryvom i upravlenie im. Vzryvnoe delo, 57/14, 13–26.
138. Belokon, M.P. (1991). Analiticheskoe opredelenie ratsionalnykh parametrov burovzryvnykh rabot. Povyshenie effektivnosti razrusheniya gornykh porod, 42–48.
139. Samul, V.I. (1982). Osnovy teorii uprugosti i plastichnosti. Vysshaya shkola.
140. Shashenko, A.N., Surgay, N.S., & Parchevskiy, L.Ya. (1994). Metody teorii veroyatnostey v geomekhanike. Kiev: Tekhnіka.
141. Shashenko, O.M., Tulub, S.B., & Sdvyzhkova, O.O. (2002). Deiaki zadachi statystychnoi heomekhaniky. Kyiv: Univer. vyd-vo «Pulsary».
142. Shashenko, A.N., & Pustovoytenko, V.P. (2004). Mekhanika gornykh porod. Kiev: Noviy druk.
143. Lavrinenko, V.F., & Lysak, V.I. (1977). Metod opredeleniya nachalnogo napryazhennogo sostoyaniya massivov skalnykh gornykh porod. Razrabotka rudnykh mestorozhdeniy, 24, 16–20.
144. Lavrinenko, V.F. (1978). Fizicheskie protsessy, formiruyushchie napryazhennoe sostoyanie massivov porod. Izv. vuzov. Gornyy zhurnal, 10, 50–54.
145. Lavrinenko, V.F., & Lysak, V.I. (1979). Termodinamicheskiy metod rascheta nachalnykh napryazheniy v massivakh porod i ego ispolzovanie pri reshenii prakticheskikh zadach. Napryazhenno-deformirovannoe sostoyanie i ustoychivost skalnykh sklonov i bortov karyerov, 204–212.
146. Lavrinenko, V.F., & Lysak, V.I. (1980). Napryazhennoe sostoyanie i fizicheskie svoystva porod v zonakh razgruzki vokrug gornykh vyrabotok. Izv. vuzov. Gornyy zhurnal, 10, 29–32.
147. Lavrinenko, V.F., & Lysak, V.I. (1981). Raschet ustoychivoy formy vyrabotki dlya glubokikh gorizontov zhelezorudnykh shakht. Razrabotka rudnykh mestorozhdeniy, 32, 13–18.
148. Lavrinenko, V.F. (1982). Usloviya ravnovesiya napryazheniy v netronutom massive. Izv. vuzov. Gornyy zhurnal, 6, 17–22.
149. Lavrinenko, V.F., & Lysak, V.I. (1985). Formirovanie poley napryazheniy vokrug ochistnykh i podgotovitelnykh vyrabotok. Razrabotka rudnykh mestorozhdeniy, 40, 14–20.
150. Lavrinenko, V.F. (1986). Preobrazovanie energii i formirovanie poley napryazheniy v massive vokrug vyrabotki. Izv. vuzov. Gornyy zhurnal, 4, 5–11.
151. Lavrinenko, V.F., & Lysak, V.I. (1993). Fizicheskie protsessy v massive porod pri narushenii ravnovesiya. Izv. vuzov. Gornyy zhurnal, 1, 1–6.
152. Khomenko O.Y. (2012). Implementation of energy method in study of zonal disintegration of rocks. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, 4, 44–54.
153. Vladyko O., Kononenko M., & Khomenko O. (2012). Imitating modeling stability of mine workings. Geomechanical Processes during Underground Mining, 147–150. https://doi.org/10.1201/b13157-27
154. Khomenko O., Kononenko M., & Petlyovanyy M. (2014). Investigation of stress-strain state of rock massif around the secondary chambers. Progressive Technologies of Coal, Coalbed Methane, and Ores Mining, 253–258. https://doi.org/10.1201/b17547-43
155. Khomenko, O., Kononenko, M., & Petlovanyi, M. (2015). Analytical modeling of the backfill massif deformations around the chamber with mining depth increase. New Developments in Mining Engineering 2015, 265–269. https://doi.org/10.1201/b19901-47
156. Khomenko, O., Kononenko, M., & Netecha, M. (2016). Industrial research into massif zonal fragmentation around mine workings. Mining of Mineral Deposits, 10(1), 50–56. https://doi.org/10.15407/mining10.01.050
157. Khomenko, O., Kononenko, M., & Danylchenko, M. (2016). Modeling of bearing massif condition during chamber mining of ore deposits. Mining of Mineral Deposits, 10(2), 40–47. https://doi.org/10.15407/mining10.02.040
158. Kononenko, M., Khomenko, O., Sudakov, A., Drobot, S., & Lkhagva, T. (2016). Numerical modelling of massif zonal structuring around underground working. Mining of Mineral Deposits, 10(3), 101–106. https://doi.org/10.15407/mining10.03.101
159. Khomenko, O.E., Kononenko, M.N., & Dronov, A.P. (2016). Laboratornye issledovaniya zonalnogo strukturirovaniya massiva vokrug gornykh vyrabotok. Fiziko-tekhnicheskie problemy gornogo proizvodstva, 18, 103–111.
160. Khomenko, O., Kononenko, M., & Astafiev, D. (2017). Effectiveness of Geo-Energy Usage during Underground Mining of Deposits. Advanced Engineering Forum, 22, 100–106. https://doi.org/10.4028/www.scientific.net/aef.22.100
161. Khomenko, O.Ye., Sudakov, A.K., Malanchuk, Z.R., & Malanchuk, Ye.Z. (2017). Principles of rock pressure energy usage during underground mining of deposits. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, 2, 35–43.
162. Khomenko, O.E., & Lyashenko, V.I. (2017). Geoenergetic fundamentals of ore deposits underground mining. Izvestiya vysshikh uchebnykh zavedenii. Gornyi zhurnal, 8, 10–18.
163. Khomenko, O.E., & Kononenko, M.N. (2017). Tekhnologii dobychi kamnesamotsvetnogo syrya v usloviyakh energeticheskogo narusheniya nedr. Fiziko-tekhnicheskie problemy gornogo proizvodstva, 19, 131–141.
164. Khomenko, O.Ye., & Kononenko, M.M. (2017). Fenomen kapsuliuvannia pidzemnoi vyrobky: vyiavlennia, modeliuvannia, vykorystannia. Zbirnyk naukovykh prats NHU, 52, 166–177.
165. Khomenko, O., Kononenko, M., Kovalenko, I., & Astafiev, D. (2018). Self-regulating roof-bolting with the rock pressure energy use. E3S Web of Conferences, 60, 00009. https://doi.org/10.1051/e3sconf/20186000009
166. Khomenko, O.E., Kononenko, M.N., & Lyashenko, V.I. (2018). Evolyutsiya printsipov podderzhaniya podzemnykh vyrabotok. Zbіrnik naukovikh prats NGU, 53, 113–127.
167. Khomenko, O., Kononenko, M., & Bilegsaikhan, J. (2018). Classification of Theories about Rock Pressure. Solid State Phenomena, 277, 157–167. https://doi.org/10.4028/www.scientific.net/ssp.277.157
168. Lavrinenko, V.F. (1992). Upravlenie sostoyaniem massiva gornykh porod pri podzemnoy razrabotke mestorozhdeniy. Kiev: UMK VO.
169. Khomenko O., & Kononenko M. (2018). Geo-energetics of Ukrainian Shield. In Physical & Chemical Geotechnologies (pp. 65–66). Dnipro: DUT.
170. Khomenko, O. Ye., & Kononenko, M. M. (2019). Geo-energetics of Ukrainian crystalline shield. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, 3. https://doi.org/10.29202/nvngu/2019-3/3
171. Shashenko, A.N., Sdvizhkova, E.A., & Kuzhel, S.V. (2004). Masshtabnyy effekt v gornykh porodakh. Donetsk: Nord-Press.
172. Kononenko, M., Khomenko, O., Sadovenko, I., & Sobolev, V. (2023). Mathematical simulation of rock mass destruction zones by explosion. Collection of Research Papers of the National Mining University, 72, 40–52. https://doi.org/10.33271/crpnmu/72.040
173. Fisenko, G.L. (1965). Ustoychivost bortov karyerov i otvalov. Nedra.
174. Rats, M.V. (1973). Strukturnye modeli v inzhenernoy geologii. Nedra.
175. Mosinets, V.N., & Abramov, A.V. (1982). Razrushenie treshchinovatykh i narushennykh gornykh porod. Nedra.
176. Andrievskiy, A.P., & Zuev, A.E. (2013). Metodika opredeleniya parametrov vzryvaniya shpurovykh i skvazhinnykh zaryadov, pozvolyayushchikh isklyuchit perebur i minimizirovat vykhod negabarita. Sovremennye problemy nauki i obrazovaniya, 2, 1–6.
177. Kononenko, M., & Khomenko, O. (2021). New theory for the rock mass destruction by blasting. Mining of Mineral Deposits, 15(2), 111–123. https://doi.org/10.33271/mining15.02.111
178. Kononenko, M., & Khomenko, O. (2020). New theory of rock massif fragmentation by using explosion energy. In Physical & Chemical Geotechnologies (pp. 29–30). Dnipro: DUT.
179. Kononenko, M., & Khomenko, O. (2021). Mathematic simulation for the rock mass destruction by blasting. In Physical and Chemical Geotechnologies (pp. 27–37). Dnipro: DUT. https://doi.org/10.15407/pcgt.21.05
180. Kononenko, M., & Khomenko, O. (2021). Modeliuvannia zon zmynannia ta podribnennia masyvu porid pid diieiu enerhii vybukhu. In Ukrainskyi hirnychyi forum – 2021 (pp. 53–64). Dnipro: RVK NTU «DP».
181. Bate, K.Yu. (2010). Metody konechnykh elementov. Fizmatlit.
182. Bate, K., & Vilson, E. (1982). Chislennye metody analiza i metod konechnykh elementov. Stroyizdat.
183. Zenkevich, O. (1975). Metod konechnykh elementov v tekhnike. Mir.
184. Gallager, R. (1984). Metod konechnykh elementov. Osnovy. Mir.
185. Segerlind, L. (1979). Primenenie metoda konechnykh elementov. Mir.
186. Fedorova, N.N., Valger, S.A., Danilov, M.N., & Zakharova, Yu.V. (2017). Osnovy raboty v ANSYS 17. DMK Press.
187. Mukhutdinov, A.R., & Efimov, M.G. (2018). Osnovy primeneniya ANSYS Autodyn dlya resheniya zadach modelirovaniya bystroprotekayushchikh protsessov. Izd-vo KNITU.
188. Belyaev, N.M. (1962). Soprotivlenie materialov. Fizmatgiz.
189. Alyamovskiy, A.A. (2012). SolidWorks Simulation. Kak reshat prakticheskie zadachi. BKhV-Peterburg.
190. Alyamovskiy, A.A. (2015). SolidWorks Simulation. Inzhenernyy analiz dlya professionalov: zadachi, metody, rekomendatsii. DMK Press.
191. Volchkov, V.M., Kozhanova, T.E., & Styazhin, V.N. (2019). Modelirovanie fizicheskikh protsessov v SolidWorks Simulation. VolgGTU.
192. Tarikov, G.P., & Belskiy, A.T. (2012). Prikladnaya mekhanika. GGTU im. P.O. Sukhogo.
193. Kononenko, M., Khomenko, O., Sadovenko, I., Sobolev, V., Pazynich, Y., & Smoliński, A. (2023). Managing the rock mass destruction under the explosion. Journal of Sustainable Mining, 22(3), 240–247. https://doi.org/10.46873/2300-3960.1391
194. Terpigorev, A.M. (1961). Spravochnik po gornorudnomu delu. Podzemnye raboty. Gosudarstvennoe nauchno-tekhnicheskoe izdatelstvo literatury po gornomu delu.
195. Kononenko, M., Khomenko, O., & Kosenko, A. (2022). Numerical simulation of the line of least resistanceduring the explosion of charges. Collection of Research Papers of the National Mining University, 69, 43–57. https://doi.org/10.33271/crpnmu/69.043
196. Brown G.I. (1998). The Big Bang: A History of Explosives. Sutton: Stroud, UK.
197. Kholodenko, T., Ustimenko, Y., Pidkamenna, L., & Pavlychenko, A. (2015). Technical, economic and environmental aspects of the use of emulsion explosives by ERA brand in underground and surface mining. New Developments in Mining Engineering 2015, 211–219. https://doi.org/10.1201/b19901-38
198. Kholodenko T., Ustimenko Y., Pidkamenna L., & Pavlychenko A. (2014). Ecological safety of emulsion explosives use at mining enterprises. Progressive Technologies of Coal, Coalbed Methane, and Ores Mining, 255–260. https://doi.org/10.1201/b17547-45
199. Khomenko O., Kononenko M., & Myronova I. (2013). Blasting works technology to decrease an emission of harmful matters into the mine atmosphere. Annual Scientific-Technical Colletion – Mining of Mineral Deposits. 231–235. https://doi.org/10.1201/b16354-43
200. Myronova, I. (2015). The level of atmospheric pollution around the iron-ore mine. New Developments in Mining Engineering 2015, 193–197. https://doi.org/10.1201/b19901-35
201. Mironova I., & Borysovs’ka O. (2014). Defining the parameters of the atmospheric air for iron ore mines. Progressive Technologies of Coal, Coalbed Methane, and Ores Mining, 333–339. https://doi.org/10.1201/b17547-57
202. Khomenko, O.Ye., Kononenko, M.M., Myronova, I.G., & Sudakov, A.K. (2018). Increasing ecological safety during underground mining of iron-ore deposits. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, 2, 29–38. https://doi.org/10.29202/nvngu/2018-2/3
203. Khomenko, O., Kononenko, M., & Savchenko, M. (2018). Technology of underground mining of ore deposits. Dnipro University of Technology. https://doi.org/10.33271/dut.001
204. Nebohin, V.Z. Stupnik, M.I., Kovalenko, I.L., Korolenko, M.K, Poltorashchenko, S.P., Karapa, I.A., Shevchyk, D.V., & Kiiashchenko, D.V. (2019). Rozrobka innovatsiinykh pryrodooshchadnykh tekhnolohii vydobutku ta yikh kompleksne vprovadzhennia na zalizorudnykh shakhtakh Ukrainy. Informatsiinyi biuleten Ukrainskoi spilky inzheneriv-pidryvnykiv, 1(37), 3–9.
205. Kalinichenko, V.O., Stupnik, M.I., & Fedko, M.B. (2019). Vyznachennia parametriv pidzemnoi rozrobky rudnykh rodovyshch. Kryvyi Rih: KNU.
206. Zhuchenko, E.I., Ioffe, V.B., Kukib, B.N., Sundukov, I.Yu., & Overchenko, M.N. (2002). Primenenie EVV sensibilizirovannykh metodom gazogeneratsii v glubokikh skvazhinakh. Bezopasnost truda v promyshlennosti, 11, 30–32.
207. Fokin, V.A. (2007). Raspredelenie plotnosti emulsionnykh vzryvchatykh veshchestv po vysote kolonki skvazhinnogo zaryada. Izvestiya vysshikh uchebnykh zavedeniy. Gornyy zhurnal, 3, 89–95.
208. Ilyakhin, S.V., & Maslov, I.Yu. (2012). Plotnost emulsionnykh vzryvchatykh veshchestv (EVV) s khimicheskoy gazogeneratsiey, soderzhashchikh sukhuyu fazu, i EVV, sensibilizirovannykh penopolistirolom, po vysote skvazhinnogo zaryada. Gornyy informatsionno-analiticheskiy byulleten (nauchno-tekhnicheskiy zhurnal), S4-15, 3–11.
209. Bragin, P.A., Gorinov, S.A., Maslov, I.Yu., Ilyakhin, S.V., & Overchenko M.N. (2015). O raspredelenii plotnosti v zaryadakh emulsionnogo vzryvchatogo veshchestva, sensibilizirovannogo gazovymi porami. Gornyy informatsionno-analiticheskiy byulleten (nauchno-tekhnicheskiy zhurnal, S5-20, 3–20.
210. Sinitsyn, V.A., Menshikov, P.V., & Shemenev, V.G. (2016). Matematicheskaya model opredeleniya plotnosti i stepeni aeratsii po dline skvazhinnogo zaryada emulsionnykh vzryvchatykh veshchestv na primere Nitronita E-70. Uspekhi sovremennogo estestvoznaniya, 8, 205–210.
211. Deribas, A.A., & Reshetnyak, A. (2003). Issledovanie vliyaniya dobavok v vide polykh mikrosfer na skorost detonatsii razlichnykh kondensirovannykh vzryvchatykh veshchestv. In Fizicheskie problemy razrusheniya gornykh porod (pp. 151–154). Abaza. Nauka.
212. Zhuchenko, E.I., Ioffe, V.B., Kukib, B.N., Sundukov, I.Yu., & Overchenko, M.N. (2003). Zaryazhanie glubokikh skvazhin emulsionnymi VV sibiritami na razrezakh Kuzbassa. In Fizicheskie problemy razrusheniya gornykh porod (pp. 154–158). Abaza. Nauka.
213. Sosnin, V.A., & Kolganov, E.V. (2004). Issledovanie detonatsionnykh protsessov emulsionnykh vzryvchatykh veshchestv. Vzryvnoe delo, 94/5, 181–195.
214. Sosnin, V.A., Mezheritskiy, S.E., Pechenev, Yu.G., Mikhaylyukova, A.I., & Sevastyanov, A.B. (2016). Osobennosti mekhanizma detonatsii emulsionnykh vzryvchatykh veshchestv. Vestnik Kazanskogo tekhnologicheskogo universiteta, 19(19), 28–33.
215. Mertuszka, P., Fuławka, K., Pytlik, M., & Szastok, M. (2019). The influence of temperature on the detonation velocity of selected emulsion explosives. Journal of Energetic Materials, 38(3), 336–347. https://doi.org/10.1080/07370652.2019.1702739
216. Mertuszka, P., & Kramarczyk, B. (2018). The Impact of Time on the Detonation Capacity of Bulk Emulsion Explosives based on Emulinit 8L. Propellants, Explosives, Pyrotechnics, 43(8), 799–804. Portico. https://doi.org/10.1002/prep.201800062
217. Mertuszka, P., Cenian, B., Kramarczyk, B., & Pytel, W. (2018). Influence of Explosive Charge Diameter on the Detonation Velocity Based on Emulinit 7L and 8L Bulk Emulsion Explosives. Central European Journal of Energetic Materials, 15(2), 351–363. https://doi.org/10.22211/cejem/78090
218. Kononenko, M.M., Khomenko, O.Y., Kovalenko, I.L., & Savchenko, M.V. (2021). Control of density and velocity of emulsion explosives detonation for ore breaking. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, 2, 69–75. https://doi.org/10.33271/nvngu/2021-2/069
219. Kononenko, M., Khomenko, O., Kovalenko, I., & Myronova, I. (2022). Examination of density and detonation velocity of emulsion explosives. Collection of Research Papers of the National Mining University, 68, 43–57. https://doi.org/10.33271/crpnmu/68.043
220. Andreev, K.K., & Belyaev, A.F. (1960). Teoriya vzryvchatykh veshchestv. Oborongiz.
221. Kuk, M.A. (1980). Nauka o promyshlennykh vzryvchatykh veshchestvakh. Nedra.
222. Kukib, B.N., Ioffe, V.B., Zhuchenko, E.I., & Frolov, A.B. (2007). O kriteriyakh otsenki otnositelnoy rabotosposobnosti promyshlennykh vzryvchatykh veshchestv. Gornyy informatsionno-analiticheskiy byulleten, S8, 127–137.
223. Arkhipov, V.A., & Sinogina, E.S. (2008). Gorenie i vzryvy. Opasnost i analiz posledstviy. TGPU.
224. Blanc, J.-P., & Thiard, R.L. (1984). L’energie des explosifs. Explosifs, 37(1), 97–110.
225. Symanovych, H.A., Khomenko, O.Ye., & Kononenko, M.M. (2014). Ruinuvannia hirskykh porid vybukhom. Dnipropetrovsk: NHU.
226. Dubnov, L.V., Bakharevich, N.S., & Romanov, A.I. (1988). Promyshlennye vzryvchatye veshchestva. Nedra.
227. Ugolnikov, V.K., & Simonov, P.S. (2007). Opredelenie perevodnykh koeffitsientov pri raschete ekvivalentnykh zaryadov drobleniya. Vestnik MGTU im. G.I. Nosova, 4, 14–17.
228. Afanasenkov, A.N. (2004). O rabotosposobnosti vzryvchatykh veshchestv. Metod Trautslya. Fizika goreniya i vzryva, 40(1), 132–139.
229. Afanasenkov, A.N. (2002). O rabotosposobnosti VV. Metod Trautslya. Problemy vzryvnogo dela, 1, 114–122.
230. Kutuzov B.N. i dr. (1988). Spravochnik vzryvnika. Nedra.
231. Belyaev, A.F. (1968). Gorenie, detonatsiya i rabota vzryva kondensirovannykh sistem. Nauka.
232. Kuznetsov, V.M., & Shatsukevich, A.F. (1978). O rabotosposobnosti vzryvchatykh veshchestv. Fizika goreniya i vzryva, 2, 120–125.
233. Kuznetsov, V.M., & Shatsukevich, A.F. (1983). Parametry istochnika i effektivnost vzryva v grunte. Fizika goreniya i vzryva, 6, 58–65.
234. Johansson, C.H., & Langefors, U. (1972). Methods of physical characterization of explosives. In Proc. of the 36th Intern. Congress on Industrial Chemistry (p. 610). Brussels.
235. Afanasenkov, A.N., Kotova, L.I., & Kukib, B.N. (2001). O rabotosposobnosti promyshlennykh vzryvchatykh veshchestv. Fizika goreniya i vzryva, 37(3), 115–125.
236. Pupkov, V.V., Maslov, I.Yu., Sivenkov, V.I., Kutin, N.G., & Gavrshov, N.I. (2005). Nekotorye rekomendatsii po profilaktike i preduprezhdeniyu neschastnykh sluchaev pri provedenii promyshlennykh ispytaniy novykh vzryvchatykh materialov. Vzryvnoe delo, 95/52, 183–191.
237. Guang, Wang Xu. (1994). Emulsion explosives. Beijing : Metallurgical Industry Press.
238. Kononenko, M., Khomenko, O., Savchenko, M., & Kovalenko, I. (2019). Method for calculation of drilling-and-blasting operations parameters for emulsion explosives. Mining of Mineral Deposits, 13(3), 22–30. https://doi.org/10.33271/mining13.03.022
239. Kononenko, M.M., Kovalenko, I.L., & Khomenko O.Ye. (2018). Enerhetychnyi pidkhid do vprovadzhennia suchasnykh nitratnykh enerhokondensovanykh system. In Suchasni enerhoekolohichni tekhnolohii (p. 203). Dnipro, DVNZ UDKhTU.
240. Kononenko, M., Khomenko, O., Kovalenko, I., & Kosenko, A. Determination of the performance of industrial explosives by the degree of realization of the detonation rate. In Physical & Chemical Geotechnologies – 2022 (pp. 25–33). Dnipro: DUT. https://doi.org/10.15407/pcgt.22.04
241. Kononenko, M., Khomenko, O., Kovalenko, I., Kosenko, A., Zahorodnii, R., & Dychkovskyi, R. (2023). Determining the performance of explosives for blasting management. Rudarsko-Geološko-Naftni Zbornik, 38(3), 19–28. https://doi.org/10.17794/rgn.2023.3.2
242. Kozyrev, S.A., Vlasova, E.A., & Sokolov, A.V. (2020). Estimation of factual energetics of emulsion explosives by experimental detonation velocity test data. Gornyi Zhurnal, 9, 47–53. https://doi.org/10.17580/gzh.2020.09.06
243. Gorinov, S.A. (2020). Initsiirovanie i detonatsiya emulsionnykh vzryvchatykh veshchestv. String.
244. Khomenko O., Kononenko M., & Lyashenko V. (2020). Research of technologies and technical means for drilling and blasting of horizontal mine workings. Mine surveying and subsurface use, 110(6), 45–52.
245. Khomenko, O.E., Rudakov, D.V., & Kononenko, M.N. (2011). Avtomatizatsiya proektirovaniya pasportov burovzryvnykh rabot putem optimizatsii razmeshcheniya shpurov. In Forum gіrnykіv-2011 (pp. 39–43). Dnіpropetrovsk: RVK DVNZ «NGU».
246. Khomenko, O., Rudakov, D., & Kononenko, M. (2011). Automation of drill and blast design. Technical and Geoinformational Systems in Mining, 271–275. https://doi.org/10.1201/b11586-45
247. Kononenko, M., Khomenko, O., & Myronova, I. (2018). Parameters of drilling-and-blasting operations for the use emulsion explosives. In Physical & Chemical Geotechnologies (pp. 39–40). Dnipro : DUT, P. .
248. Lyashenko, V.I., Khomenko, O.E., & Kononenko, M.N. (2021). Substantiation of parameters of mine working drivage with blasting technique and cleaning charges in advance cutting holes. Mining Science and Technology, 5(4), 336–348. https://doi.org/10.17073/2500-0632-2020-4-336-348
249. Salganik, V.A. i dr. (2010). Instruktivno-metodicheskie ukazaniya reglamentiruyushchie poryadok sostavleniya, soglasovaniya i utverzhdeniya pasportov burovzryvnykh rabot na prokhodku gorizontalnykh, vertikalnykh vyrabotok i vypolneniya sboek vyrabotok. Krivoy Rog: GP «NIGRI».
250. Kononenko, M.M., & Nechyt, O.V. (2020). Rational parameters of drilling-and-blasting operations at mine workings construction in the conditions of PJSC “Zaporizskyi iron-ore plant”. Fiziko-Tehničeskie Problemy Gornogo Proizvodstva, 22, 46–56. https://doi.org/10.37101/ftpgp22.01.004
251. Khomenko, O., Kononenko, M., Myronova, I., & Savchenko, M. (2019). Application of the emulsion explosives in the tunnels construction. E3S Web of Conferences, 123, 01039. https://doi.org/10.1051/e3sconf/201912301039
252. Kononenko, M., Khomenko, O., & Korobka, Ye. (2021). Parameters of drilling-and-blasting operations for mine workings construction. Fiziko-Tehničeskie Problemy Gornogo Proizvodstva, 23, 54–71. https://doi.org/10.37101/ftpgp23.01.004
253. Kononenko, M., Khomenko, O., & Kosenko, A. (2023). New method for determining parameters of drilling and blasting for horizontal and inclined mine workings. Collection of Research Papers of the National Mining University, 73, 16–32. https://doi.org/10.33271/crpnmu/73.016
254. Kononenko, M., Khomenko, O., Cabana, E., Mirek, A., Dyczko, A., Prostański, D., & Dychkovskyi, R. (2023). Using the methods to calculate parameters of drilling and blasting operations for emulsion explosives. ActaMontanisticaSlovaca, 28(3), 655–667. https://doi.org/10.46544/ams.v28i3.10
255. Khomenko, O., Kononenko, M., & Danylchenko, M. (2016). Do obgruntuvannia parametriv pidhotovky zapasiv rud pry kamernykh systemakh rozrobky. In Shkola pidzemnoi rozrobky (pp. 85–86). Berdiansk.
256. Kononenko, M., & Danylchenko, M. (2016). Udoskonalennia pidhotovchykh robit pry kamernykh systemakh rozrobky. In Innovatsiinyi rozvytok hirnychodobuvnoi haluzi (p. 102). Kryvyi Rih.
257. Chirkov, Yu.I., & Chernenko, A.R. (1985). Podzemnaya razrabotka moshchnykh zhelezorudnykh mestorozhdeniy. Nedra.
258. Khomenko, O.E., Kononenko, M.N., & Lyashenko, V.I. (2021). Improvement of Safety for the Underground Vertical Workings. Occupational Safety in Industry, 2, 41–48. https://doi.org/10.24000/0409-2961-2021-2-41-48
259. Fedorenko, P.I., Melnikova, I.E., Chepurnoy, V.I., & Lyash, S.I. (2015). O vozmozhnostyakh snizheniya trudovykh energo- i resursozatrat pri podgotovke blokov k ochistnym rabotam. Zbirnyk naukovykh prats Naukovo-doslidnoho hirnychorudnoho instytutu Derzhavnoho vyshchoho navchalnoho zakladu Kryvorizkyi natsionalnyi universytet, 55, 152–156.
260. Fedorenko, P.I., Chepurnoy, V.I., & Lyash, S.I. (2016). Analiz sostoyaniya prokhodki vosstayushchikh vyrabotok pri podgotovke na shakhtakh Krivbassa blokov k ochistnoy vyemke. Zbirnyk naukovykh prats Naukovo-doslidnoho hirnychorudnoho instytutu Derzhavnoho vyshchoho navchalnoho zakladu Kryvorizkyi natsionalnyi universytet, 56, 103–108.
261. Usatyy, V.Yu., Kistrin, S.G., & Bliznyukov, V.G. (2001). Prokhodka vosstayushchikh gornykh vyrabotok v usloviyakh ZAO «Zaporozhskiy ZhRK». Sbornik nauchnykh trudov GNIGRI, 64–71.
262. Usatyy, V.Yu., Kistrin, S.G., & Usatyy, V.V. (2001). Obosnovanie sposoba provedeniya vosstayushchikh gornykh vyrabotok pri sistemakh razrabotki vysokimi kamerami. Naukoviy vіsnyk NGAU, 3, 18–21.
263. Milekhin, G.G. (2004). Vskrytie i podgotovka rudnykh mestorozhdeniy. Izd-vo MGTU.
264. Tipovye pasporta burovzryvnykh rabot pri prokhodke podetazhnykh vyrabotok (1974). Krivoy Rog: NIGRI.
265. Tipovye pasporta burovzryvnykh rabot na prokhodku gornykh vyrabotok v usloviyakh ZZhRK. (1985). Krivoy Rog: NIGRI.
266. Kononenko, M., Khomenko, O., & Kosenko, A. (2022). Rational parameters of drilling-and-blasting operations for rise working. Physical and Technical Problems of Mining Production, 24, 15–31. https://doi.org/10.37101/ftpgp24.01.002
267. Khomenko, O.Ye., Kononenko, M.M., & Maltsev, D.V. (2005). Ohliad svitovoho rynku burovoi ta navantazhuvalnoi tekhniky dlia rozrobky rudnykh rodovyshch. Naukovyi visnyk NHU, 12, 5–7.
268. Khomenko, O.Ye., Kononenko, M.M., & Dolhyi, O.A. (2006). Dosvid vykorystannia burovoho, navantazhuvalnoho ta dopomizhnoho obladnannia na rudnykh shakhtakh svitu. Naukovyi visnyk NHU, 1, 18–21.
269. Khomenko, O.Ye., Kononenko, M.M., Khorolskyi, A.O., & TOV «IST-FORT». Komp’iuterna prohrama «Prohrama pobudovy pasportu buropidryvnykh robit «Ukrainit – prokhodka». Svidotstvo pro reiestratsiiu avtorskoho prava na tvir No 98464, Ukraina.
270. Kononenko, M., Khomenko, O., & Kosenko, A. (2022). Improvement of the current methodology for calculating the parameters of drilling and blasting on the explosive force. Collection of Research Papers of the National Mining University, 71, 62–72. https://doi.org/10.33271/crpnmu/71.062
271. Pravyla bezpeky pid chas povodzhennia z vybukhovymy materialamy promyslovoho pryznachennia. (2013). Kyiv: Normatyv.
272. Kononenko, M.M., Khomenko, O.Ye., & Myronova, I.H. (2013). Sposib vydobuvannia korysnykh kopalyn buropidryvnym metodom. Patent No 101217, Ukraine.
273. Khomenko, O.Ye., Kononenko, M.M., Myronova, I.H., & Maltsev, D.V. Sposib vydobuvannia korysnykh kopalyn buropidryvnym metodom. Patent No 108639, Ukraine.
274. Khomenko, O., Kononenko, M., Myronova, I., Kovalenko, I., Cabana, Edgar Cáceres, & Dychkovskyi, R. (2023). Technology for increasing the level of environmental safety of iron ore mines with use of emulsion explosives. Mining Machines, 41(1), 48–57. https://doi.org/10.32056/KOMAG2023.1.5
275. Khomenko, O., Kononenko, M., & Myronova, I. (2017). Ecological and technological aspects of iron-ore underground mining. Mining of Mineral Deposits, 11(2), 59–67. https://doi.org/10.15407/mining11.02.059
276. Khomenko, O.Ye., Kononenko, M.M., & TOV «IST-FORT» (2022). Komp’iuterna prohrama «Prohrama pobudovy proektu pidsikannia zapasiv rudy u blotsi «Ukrainit – pidsichka». Svidotstvo pro reiestratsiiu avtorskoho prava na tvir No 110658, Ukraina.
277. Kononenko, M.M., Khomenko, O.Ye., & Usatyi, V.Yu. (2013). Vybir i rozrakhunok system pidzemnoi rozrobky rudnykh rodovyshch. Dnipropetrovsk: NHU.
278. Vladyko A.B., Kononenko M.N., & Litvinyuk E.A. (2012). Imitatsionnoe modelirovanie raboty prokhodcheskogo oborudovaniya pri provedenii gornykh vyrabotok. In Shkola pіdzemnoi rozrobky (pp. 284–293). Dnіpropetrovsk: NGU.
279. Gorovaya, A.I., Mironova, I.G., Kononenko, M.N., & Pavlichenko, A.V. (2014). Tekhnologiya povysheniya ekologicheskoy bezopasnosti pri dobyche zheleznykh rud podzemnym sposobom. Dnepropetrovsk: Litograf.
280. Khomenko, O.E., Kononenko, M.N., Mironova, I.G., & Yurchenko, K.O. (2017). Puti snizheniya tekhnogennoy nagruzki na gornodobyvayushchie regiony Ukrainy. Zbіrnyk naukovykh prats NGU, 51, 77–83.
281. Khomenko, O.Ye., Kononenko, M.M., & Myronova, I.H. (2018). Ekolohichna bezpeka vydobuvannia zaliznykh rud. In Shkola pidzemnoi rozrobky (pp. 79–80). Berdiansk.
282. Mironova, I.G., Khomenko, O.E., & Kononenko, M.N. (2018). Snizhenie ekologicheskoy opasnosti dobychi rud v Ukraine. In Resursovosproizvodyashchie, malootkhodnye i prirodookhrannye tekhnologii osvoeniya nedr (pp. 49–51). Aktau: KGUTI im. Sh. Esenova.
283. OND-86. «Metodika rascheta kontsentratsiy v atmosfernom vozdukhe vrednykh veshchestv, soderzhashchikhsya v vybrosakh promyshlennykh predpriyatiy». (1987). Gidrometeoizdat.
284. Metodychni rekomendatsii MR 2.2.12-142-2007. «Otsinka ryzyku dlia zdorov’ia naselennia vid zabrudnennia atmosfernoho povitria». (2007). Kyiv.
285. Kononenko, M., Khomenko, O., Myronova, I., & Kovalenko, I. (2022). Economic and environmental aspects of using mining equipment and emulsion explosives for ore mining. Mining Machines, 40(2), 88–97. https://doi.org/10.32056/KOMAG2022.2.4
286. Kononenko, M., Khomenko, O., Myronova, I., & Kovalenko, I. (2022). Economical-ecological efficiency of usingemulsion explosive in underground ore mining. Collection of Research Papers of the National Mining University, 70, 22–35. https://doi.org/10.33271/crpnmu/70.022