DOI: 10.18503/1995-2732-2024-22-1-143-155
Abstract
The paper is devoted to processes of selective destruction of brittle materials, in particular rocks, for example, during their beneficiation. It has been shown that the most important aspect in the study on crushing of brittle rocks due to the interaction between crusher actuators and the crushed material is cracking. It has been shown that by applying conventional methods of mechanical crushing, the rock destruction is not selective due to the difference of the structure and physical and mechanical properties of crushed materials, and, therefore, heterogeneous scenarios of forming micro- and macro-crack geometry in the fracture center. Since the majority of production companies are mostly interested in quality control of the fractional composition of finished crushed products, the researchers focus on the solution to providing controlled opening of “defects” in various crushed rocks. For this purpose, the paper demonstrates a new method of the size reduction of brittle materials. When using such method, a complex controlled vibration impact is introduced in the zone of material destruction as forced amplitude-modulated vibrations of the working body of the hammer crusher to increase the geometric bulk homogeneity of the resulting crumbs by simultaneous formation of a branched network of deep and surface cracks. Then the specific example shows how the mentioned complex vibration displacements of the crusher working body are formed and how it is possible to significantly expand the area of crack formation in the crushed material as a result of changing the parameters. Using computer modeling in the LSTC LS-Dyna software complex on the Tornado SUSU supercomputer, the researchers clearly show efficiency of increasing the area of cracking during vibration crushing of rocks in comparison with conventional methods without vibration. Efficiency of the new method is also confirmed by full-scale experiments conducted with an experimental crusher. This approach to cracking control will contribute to achieving quasi-homogeneity of the dispersed product at the same time.
Keywords
modeling, cracking, dispersion, brittle materials, combined vibration drives, homogeneity control
For citation
Sergeev Yu.S., Platov S.I., Guzeev V.I., Sergeev S.V., Puzankov M.S. Computer Modeling of a New Method of Controlled Cracking During Dimensional Crushing of Brittle Materials. Vestnik Magnitogorskogo Gosudarstvennogo Tekhnicheskogo Universiteta im. G.I. Nosova [Vestnik of Nosov Magnitogorsk State Technical University]. 2024, vol. 22, no. 1, pp. 143-155. https://doi.org/10.18503/1995-2732-2024-22-1-143-155
1. Gorlov I.V., Mitusov P.E., Belyaev A.M. Analysis of the soft rock crushing process. Ugol [Coal]. 2022;(6):44-47. (In Russ.) DOI: 10.18796/0041-5790-2022-6-44-47
2. Krasnov G.D., Koporulina E.V., Krasnov A.N., Chikhladze V.V. Assessment of selectivity of mineral complex crushing. Gornyi informatsionno-analiti-cheskii byulleten [Mining Informational and Analytical Bulletin]. 2013;(2):86-97. (In Russ.)
3. Basyrov I.I., Bardovskiy A.D. An innovative crushing method and design of the vertical roll crusher for crushing rock masses. Gornyi informatsionno-analiticheskii byulleten [Mining Informational and Analytical Bulletin]. 2020;(2):121-129. (In Russ.) DOI: 10.25018/0236-1493-2020-2-0-121-129
4. Makarov P.V., Eremin M.O. A model of fracture of brittle and quasi-brittle materials and geological environment. Fizicheskaya mezomekhanika [Physical Mesomechanics]. 2013;16(1):5-26. (In Russ.) DOI: 10.24411/ 1683-805X-2013-00032
5. Stefanov Yu.P. Some features of numerical modeling of elastic-brittle-plastic materials behavior. Fizicheskaya mezomekhanika [Physical Mesomechanics]. 2005;8(3):129-142. (In Russ.)
6. Simonov P.S. Experimental study on rock crushing by a single impact. Gornyi informatsionno-analiticheskii byulleten [Mining Informational and Analytical Bulletin]. 2020;(1):71-79. (In Russ.) DOI: 10.25018/0236-1493-2020-1-0-71-79
7. Altshul G.M., Guskov A.M., Panovko G.Ya. Modeling of interaction between processed rocks and a vibrating jaw crusher. Problemy mashinostroeniya i nadezhnosti mashin [Problems of Mechanical Engineering and Reliability of Machines]. 2021;(1):33. (In Russ.) DOI: 10.31857/S0235711921010053
8. Bartolomey M.L., Trufanov N.A. Applying the Ansys package for studying a building deformation factoring into cracking. Vestnik Permskogo gosudarstvennogo tekhnicheskogo universiteta [Bulletin of Perm State Technical University]. 2009;(1):15-20. (In Russ.)
9. Burago N.G. Modeling of elastoplastic body fracture. Vychislitelnaya mekhanika sploshnykh sred [Computational Mechanics of Continuous Media]. 2008;4(4):5-20. (In Russ.)
10. Pershin G.D., Ulyakov M.S., Pshenichnaya E.G., Gabbasov B.M. An energy method for calculating the productivity of diamond wire saws in the extraction of facing stones. Vestnik Magnitogorskogo gosudarstvennogo tekhnicheskogo universiteta im. G.I. Nosova [Vestnik of Nosov Magnitogorsk State Technical University]. 2016;14(2):18-24. (In Russ.) DOI: 10.18503/ 1995-2732-2016-14-2-18-24
11. Kuzbakov Zh.I., Pershin G.D., Kolga A.D. Study on vibrations of the drive device of a jaw crusher. Vestnik Magnitogorskogo gosudarstvennogo tekhnicheskogo universiteta im. G.I. Nosova [Vestnik of Nosov Magnitogorsk State Technical University]. 2017;15(4):73-80. (In Russ.) DOI: 10.18503/1995-2732-2017-15-4-73-80
12. Sergeev S.V., Sergeev Yu.S., Dyakonov A.A., Gordeev E.N. Improving geometric homogeneity of particles crushed using vibrational drive with modulating properties in machine for crushing brittle materials. Journal of Advanced Research in Dynamical and Control Systems. 2018;10(13):2411-2422
13. Sergeev Yu.S., Sergeev S.V., Gordeev E.N., Kononistov A.V., Karpov G.E. Sposob izmelcheniya khrupkikh materialov [Method of crushing brittle materials]. Patent RU, no. 2732619, 2020.
14. Sergeev Yu.S., Sandalov V.M., Karpov G.E. Modeling of switched reluctance electric vibration drive with adaptive control. 2018 International Russian Automation Conference, RusAutoCon 2018. Sochi, 2018. DOI: 10.1109/RUSAUTOCON.2018.8501749
15. Sergeev Yu.S., Sergeev S.V. et al. Sposob vozbuzhdeniya kolebaniy [Method of vibration excitation]. Patent RU, no. 2533743, 2014.
16. Shah Q.H., Hamdani A. The damage of unconfined granite edge due to the impact of varying stiffness projectiles. International Journal of Impact Engineering. 2013;59:11-17. DOI: 10.1016/j.ijimpeng.2013.03.004