Influence of Nonlinear Shear Modulus Change of Elastomeric Shell of a Composite Tractive Element with a Damaged Structure on its Stress State

Belmas, Ivan; Kolosov, Dmytro; Onyshchenko, Serhii; Bilous, Olena; Tantsura, Hanna

doi:10.29227/IM-2023-01-18

Artykuł - szczegóły

Tytuł artykułu

Influence of Nonlinear Shear Modulus Change of Elastomeric Shell of a Composite Tractive Element with a Damaged Structure on its Stress State

Autorzy

Belmas Ivan , Kolosov Dmytro , Onyshchenko Serhii , Bilous Olena , Tantsura Hanna

Treść / Zawartość

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Identyfikatory

DOI

10.29227/IM-2023-01-18

Warianty tytułu

Badanie wpływu kompensacji na stabilność górotworu oraz jakość wydobywanej rudy

Języki publikacji

Abstrakty

Purpose. Determination of a dependency of a stress state for composite elastomer-cable tractive element with a broken structure on a nonlinear dependency of shear modulus on deformations in the elastomeric shell. Methods. Analytical solution of a model of a composite tractive element with disturbed structure and a deformation-dependent shear modulus of an elastomeric shell. Findings. Algorithm for determining a stress state of a composite tractive element with broken structure and a deformation-dependent shear modulus. Scientific novelty. Character of dependency for a stress state of a composite tractive element on a nonlinear dependency of shear modulus on deformations. Practical significance. A possibility to determine the dependency of a stress state of a composite elastomer-cable tractive element on a nonlinear shear modulus. Scientific novelty. Character of dependency for a stress state of a composite tractive element on a nonlinear dependency of shear modulus on deformations. Practical significance. A possibility to determine the dependency of a stress state of a composite elastomer-cable tractive element on a nonlinear shear modulus allows considering the effect of this phenomenon on the tractive element strength and ensures an increase of its operational safety.

Artykuł przedstawia studium i analizę funkcjonalną wymagań światowego przemysłu metalurgicznego co do jakości rud żelaza w podziemnych kopalniach Ukrainy. Stwierdzono zależności wpływu kształtu i parametrów przestrzeni kompensacyjnych na ich stateczność i wskaźniki jakości rudy. Udowodniono, że komora wyrównawcza w kształcie trapezu pionowego charakteryzuje się największą stabilnością i jest stabilna w zakresie wszystkich rozważanych głębokości, nawet w rudach o twardości 3–5 punktów. Mniejszą stateczność wykazuje komora kompensacji pionowej o kształcie sklepionym z niewielkimi spadkami w przyczółku sklepienia komory w rudach o twardości 3–5 punktów na głębokości 2000 m. Komora z opadami o rożnym natężeniu występuje w dolnej części nachylonych odsłonięć namiotu w rudach o twardości 3–5 punktów na głębokości 1750 m lub większej. Pomieszczenie kompensacji poziomej ma najmniejszą stateczność; spadki występują w rudach o twardości 3–5 punktów na głębokości 1400 m, a na głębokościach 1750–2000 m pozostają stabilne tylko w rudach twardszych. Stwierdzono, że zastosowanie komór kompensacyjnych o dużej stabilności umożliwia osiągnięcie ich maksymalnej objętości, zwiększenie ilości wydobywanej czystej rudy, zmniejszenie jej rozrzedzenia, poprawę jakości wydobywanej masy rudy, a co za tym idzie, wzrost jej ceny i konkurencyjności rynkowej.

Słowa kluczowe

mineral resources mining lifting and transporting complexes damaged structure elastomeric shell stress state analytical solution

surowce mineralne kompleksy wydobywcze wyciągowe i transportowe kompozytowy element trakcyjny uszkodzona konstrukcja powłoka elastomerowa stan naprężeń rozwiązanie analityczne

Wydawca

Polskie Towarzystwo Przeróbki Kopalin

Czasopismo

Inżynieria Mineralna

Rocznik

2023

Tom

no. 1

Strony

147--154

Opis fizyczny

Bibliogr. 40 poz., rys.

Twórcy

autor

Belmas Ivan

evolyuta@gmail.com

Dniprovsk State Technical University, 2 Dniprobudivska str., 51900, Kamianske, Ukraine

https://orcid.org/0000-0003-2112-0303

autor

Kolosov Dmytro

Dnipro University of Technology, 19 Dmytra Yavornytskoho ave., 49005, Dnipro,

https://orcid.org/0000-0003-0585-5908

autor

Onyshchenko Serhii

Dnipro University of Technology, 19 Dmytra Yavornytskoho ave., 49005, Dnipro,

https://orcid.org/0000-0002-5709-7021

autor

Bilous Olena

Dniprovsk State Technical University, 2 Dniprobudivska str., 51900, Kamianske, Ukraine

https://orcid.org/0000-0001-6398-8843

autor

Tantsura Hanna

Dniprovsk State Technical University, 2 Dniprobudivska str., 51900, Kamianske, Ukraine

https://orcid.org/0000-0002-8672-1153

Bibliografia

1. Moldabayev, S.K., Adamchuk, A.A., Toktarov, A.A., Aben, Y. & Shustov, O.O. (2020). Approbation of the technology of efficient application of excavator-automobile complexes in the deep open mines. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, (4), pp. 30-38. DOI: 10.33271/nvngu/2020-4/030
2. Pysmennyi, S., Fedko, M., Shvaher, N. & Chukharev, S. (2020). Mining of rich iron ore deposits of complex structure under the conditions of rock pressure development. E3S Web of Conferences, 2020, 201, 01022. DOI: 10.1051/ e3sconf/202020101022
3. Tytov, O., Haddad, J. & Sukhariev, V. (2019). Modelling of mined rock thin layer disintegration taking into consideration its properties changing during compaction. E3S Web of Conferences, 109, 00105. DOI:10.1051/e3sconf/ 201910900105
4. Shustov, O.O., Haddad, J.S., Adamchuk, A.A., Rastsvietaiev, V.O. & Cherniaiev, O.V. (2019). Improving the Construction of Mechanized Complexes for Reloading Points while Developing Deep Open Pits. Journal of Mining Science, 2019, 55(6), pp. 946-953. DOI: 10.1134/S1062739119066332
5. Bondarenko, A.O., Haddad, J.S., Tytov, O.O. & Alfaqs, F. (2021). Complex for processing of rubble wastes of stone dressing. International Review of Mechanical Engineering, 15(1), pp. 44-50. DOI: 10.15866/ireme.v15i1.20205
6. Peremetchyk, A., Kulikovska, O., Shvaher, N., Chukharev, S., Fedorenko, S., Moraru, R. & Panayotov, V. (2022). Predictive geometrization of grade indices of an iron-ore deposit. Mining of Mineral Deposits, 16(3), pp. 67-77. DOI: 10.33271/mining16.03.067
7. Kovalevska, І., Samusia, V., Kolosov, D., Snihur V. & Pysmenkova , T. (2020). Stability of the overworked slightly metamorphosed massif around mine working. Mining of Mineral Deposits, 14(2), 43-52. DOI: 10.33271/mining14.02.043
8. Sotskov, V., Dereviahina, N., & Malanchuk, L. (2019). Analysis of operation parameters of partial backfilling in the context of selective coal mining. Mining of Mineral Deposits, 13(4), 129-138. DOI: 10.33271/mining13.04.129
9. Shvaher, N., Komisarenko, T., Chukharev, S. & Panova, S. (2019). Annual production enhancement at deep mining. E3S Web of Conferences, 123, art. no. 01043. DOI: 10.1051/e3sconf/201912301043
10. Naumov, V., Zhamanbayev, B., Agabekova, D., Zhanbirov, Z. & Taran, I. (2021). Fuzzy-logic approach to estimate the passengers' preference when choosing a bus line within the public transport system. Communications - Scientific Letters of the University of Žilina, 23(3), pp. A150-A157. DOI:10.26552/com.C.2021.3.A150-A157
11. Kravets, V., Samusia, V., Kolosov, D., Bas, K. & Onyshchenko, S. (2020). Discrete mathematical model of travelling wave of conveyor transport. II International Conference Essays of Mining Science and Practic, Vol. 168. DOI: 10.1051/e3sconf/202016800030
12. Shpachuk, V., Chuprynin, A., Daleka, V. & Suprun, T. (2020). Simulation of impact interaction of rail transport carriage in a Butt Roughness Zone. Scientific Journal of Silesian University of Technology. Series Transport, 106, pp. 141-152. DOI:10.20858/sjsutst.2020.106.12
13. Sladkowski, A.V., Kyrychenko, Y.O., Kogut, P.I., Samusya, V.I. & Kolosov, D.L. (2019). Innovative designs of pumping deep-water hydrolifts based on progressive multiphase non-equilibrium models. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, (2), pp. 51-57. DOI: 10.29202/nvngu/2019-2/6
14. Bondarenko, A.O., Malіarenko, P.О., Zapara, Ye. & Bliskun, S.P. (2020). Testing of the complex for gravitational washing of sand. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, (5), 26-32. DOI: 10.33271/nvngu/ 2020-5/026
15. Shpachuk, V.P., Zasiadko, M.A. & Dudko, V.V. (2018). Investigation of stress-strain state of packet node connection in spatial vibration shakers. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, (3), 74-79. DOI: 10.29202/ nvngu/2018-3/12
16. Bazhenov, V.A., Gulyar, A.I., Piskunov, S.O. & Shkryl, A.A. (2006). Life assessment for a gas turbine blade under creep conditions based on continuum fracture mechanics. Strength of Materials, 38(4), pp. 392-397.
17. Bazhenov, V.A., Gulyar, A.I., Piskunov, S.O. & Shkryl, A.A. (2008). Gas turbine blade service life assessment with account of fracture stage. Strength of Materials, 2008, 40(5), pp. 518-524.
18. Vynohradov, B.V., Samusya, V.I. & Kolosov, D.L. (2019). Limitation of oscillations of vibrating machines during start-up and shutdown. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, (1), pp. 69-75. DOI: 10.29202/ nvngu/2019-1/6
19. Chigirinsky, V., Naumenko, O. (2020). Invariant Differential Generalizations in Problems of the Elasticity Theory As Applied to Polar Coordinates. Eastern-European Journal of Enterprise Technologies, 5(7 (107)), 56-73. DOI: 10.15587/1729-4061.2020.213476
20. Marasova, D., Ambriško, Ľ., Andrejiova, M. & Grinčova, A. (2017). Examination of the process of damaging the top covering layer of a conveyor belt applying the FEM. Journal of the International Measurement Confederation, (112), 47-52. DOI:10.1016/j.measurement.2017.08.016
21. Belmas, I., Kogut, P., Kolosov, D., Samusia, V. & Onyshchenko, S. (2019). Rigidity of elastic shell of rubber-cable belt during displacement of cables relatively to drum. International Conference Essays of Mining Science and Practice, Vol. 109, 00005. DOI: 10.1051/e3sconf/201910900005
22. Blazej, R., Jurdziak, L., Kirjanow-Blazej, A. et al. (2021). Identification of damage development in the core of steel cord belts with the diagnostic system. Sci Rep 11, 12349. DOI: 10.1038/s41598-021-91538-z
23. Webb, C., Sikorska, J., Khan, R., & Hodkiewicz, M. (2020). Developing and evaluating predictive conveyor belt wear models. Data-Centric Engineering, 1, E3. DOI: 10.1017/dce.2020.1
24. Pang, Y., Lodewijks, G. (2006). A Novel Embedded Conductive Detection System for Intelligent Conveyor Belt Monitoring. 2006 IEEE International Conference on Service Operations and Logistics, and Informatics, SOLI 2006. 803-808. DOI: 10.1109/SOLI.2006.328958
25. Volohovskiy, V.Yu., Radin, V.P., & Rudyak, M.B. (2010). Concentration of loads in cables and a bearing ability of rubber-cable conveyor belts with breakages. MPEI Vestnik, (5), 5-12.
26. Bel'mas, I.V. (1993). Stress state of rubber-rope tapes during their random damages. Problemy Prochnosti i Nadezhnos'ti Mashin, 1993, (6), pp. 45-48.
27. Ropay V.A. (2016) Shakhtnyye uravnoveshivayushchiye kanaty : monograph [Mining balancing ropes]. Dnipropetrovsk : National Mining University. 263 p.
28. Levchenya, Zh.B. (2004). Increase of reliability of butt-joint connections of conveyor belts at mining enterprises: PhD dissertation: 05.05.06.
29. Kolosov, L.V., Bel'mas, I.V. (1981). Use of electrical models for investigating composites. Mechanics of Composite Materials, 1981, 17(1), pp. 115-119.
30. Zade, D.S. (2013). Numerical method of determining effective characteristics of unidirectional reinforced composites. Bulletin NTU “KhPI”, (58), 71-77.
31. Song, W. Shang, W. and Li, X. (2009). Finite element analysis of steel cord conveyor belt splice. International Technology and Innovation Conference 2009 (ITIC 2009), Xi'an, China, pp. 1-6. DOI: 10.1049/cp.2009.1415
32. Li X., Long, X., Shen, Z. & Miao, Z.Ch. (2019). Analysis of Strength Factors of Steel Cord Conveyor Belt Splices Based on the FEM. Advances in Materials Science and Engineering, Volume 2019, ID 6926413. DOI: 10.1155/2019/6926413
33. Fedorko, G., Molnar, V., Michalik, P., Dovica, M., Kelemenova, T. & Toth, T. (2018). Failure analysis of conveyor belt samples under tensile load. Journal of Industrial Textiles. 48. 152808371876377. DOI: 10.1177/1528083718763776
34. Andrejiova, M., Grincova, A. & Marasova, D. (2019). Failure analysis of the rubber-textile conveyor belts using classification models. Engineering Failure Analysis. 101. 407-417. DOI: 10.1016/j.engfailanal.2019.04.001
35. Belmas I.V., Kolosov D.L., Kolosov A.L. & Onyshchenko S.V. (2018). Stress-strain state of rubber-cable tractive element of tubular shape. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, (2), pp. 60-69. DOI: 10.29202/ nvngu/2018-2/5
36. Kirjanow-Błażej, A., Błażej, R. Jurdziak, L. & Kozłowski, T. (2017). Core damage increase assessment in the conveyor belt with steel cords. Diagnostyka. 18. 93-98.
37. Romek D., Ulbrich D., Selech J., Kowalczyk J. & Wlad R. (2021). Assessment of Padding Elements Wear of Belt Conveyors Working in Combination of Rubber-Quartz-Metal Condition. Materials (Basel). Aug 2;14(15):4323. DOI: 10.3390/ma14154323
38. Yao Y., Zhang B. (2020). Influence of the elastic modulus of a conveyor belt on the power allocation of multi-drive conveyors. PLoS One. Jul 7; 15(7):e0235768. DOI: 10.1371/journal.pone.0235768
39. Zabolotny, K.S., Panchenko, E.V. & Zhupiev, A.L. (2011). Teoriya mnogosloynoy namotki rezinotrosovogo kanata [Theory of multilayer rubber-cable rope winding]. Dnipropetrovsk: NGU.
40. Haddad, J.S., Denyshchenko, O., Kolosov, D., Bartashevskyi, S., Rastsvietaiev, V., & Cherniaiev, O. (2021). Reducing Wear of the Mine Ropeways Components Basing Upon the Studies of Their Contact Interaction. Archives of Mining Sciences, 66(4), 579-594. DOI: 10.24425/ams.2021.139598

Uwagi

Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu „Społeczna odpowiedzialność nauki” - moduł: Popularyzacja nauki i promocja sportu (2022-2023)

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-02dc6c2c-7e2a-4c82-b445-8e66a5ff2a22