ArticleName |
Rock disintegration selectivity control based on the methods of similarity and dimensions in the fracture dynamics |
ArticleAuthorData |
National University of Science and Technology MISIS, Moscow, Russia:
R. K. Khalkechev, Candidate of Physico-Mathematical Sciences K. V. Khalkechev, Doctor of Physico-Mathematical Sciences, Doctor of Engineering Sciences, h_kemal@mail.ru |
Abstract |
This article gives an analysis of geomaterial disintegration by crushing and grinding. These disintegration methods are uncontrollable and, thus, low-selective. To deal with this problem, a new concept of the selective crushing and grinding of geomaterials has been developed, which ensures sharp rise in efficiency of recovery of useful minerals. The scope of the discussion covers the theoretical issues of shaping a cardinally new trend in the mineral processing industry based on technologies of selective disintegration of geomaterials. The constructed mathematical model in the framework of the method of similarity and dimensions in the fracture dynamics allows determining conditions of stable and unstable propagation of cracks. Under stable propagation mode, spacing of cracks is unaltered or reduces. Under unstable propagation scenario, spacing of cracks grows. This offers an opportunity to control spacing of cracks and, as a consequence, selectivity of disintegration. A feature of the developed mathematical model is its generality as it is independent of macroscopic mechanical properties of geomaterials. The generality is supported by its insulation from dimensions of elementary volume. This conditions the model adequacy as the processes of crushing and grinding are not bounded to elementary volumes of geomaterials under treatment. This is achieved by considering crack propagation mechanism as the motion of point and linear defects towards the crack tips, characterized mainly by propagation rate, length and spacing. The computer experimentation shows paths of development in industrial practices of solid mineral disintegration at the concurrent stage and in the future. |
References |
1. Khalkechev R. K., Kashirskiy A. S., Khalkechev K. V. Upravlenie tekhnologiey razrusheniya materialov na osnove matematicheskogo modelirovaniya ustoychivogo i neustoychivogo razvitiya treshchin (Control of materials destruction technology on the basis of mathematical modeling of stable and unstable crack propagation). Gornyy informatsionno-analiticheskiy byulleten = Mining Informational and Analytical Bulletin. 2014. No. 11. pp. 359–366. 2. Khalkechev R. K. Stokhasticheskiy metod opredeleniya elementarnykh obemov kristallicheskikh i kompozitsionnykh geomaterialov (Stochastic method of definition of voluentary units of crystalline and composite geomaterials). Izvestiya Kabardino-Balkarskogo nauchnogo tsentra Rossiyskoy Akademii Nauk = Bulletin of Kabardino-Balkarian Science Center of Russian Academy of Sciences. 2012. No. 2. pp. 38–41. 3. Yunjin H., Guolong C., Weiping C., Zhenjun Y. Simulation of hydraulic fracturing in rock mass using a smeared crack model. Computers and Structures. 2014. Vol. 137. pp. 72–77. 4. Tikhonov N. O., Ivanov A. N. Ore pretreatment reengineering at operating processing plants using high pressure grinding rolls-a promising area of activity (in terms of Erdenet Mining Corporation). Eurasian Mining. Moscow, 2015. Vol. 1. pp. 9–12. 5. Shojaei A., Dahi Taleghani A., Li G. A continuum damage failure model for hydraulic fracturing of porous rocks. International Journal of Plasticity. 2014. Vol. 59. pp. 199–212. 6. Haeri H., Shahriar K., Fatehi Marji M., Moarefvand P. Experimental and numerical study of crack propagation and coalescence in pre-cracked rock-like disks. International Journal of Rock Mechanics and Mining Sciences. 2014. Vol. 67. pp. 20–28. 7. Glagolev V. V., Glagolev L. V., Markin A. A. Stress-strain state of elastoplastic bodies with crack. Acta Mechanica Solida Sinica. 2015. Vol. 28, No. 4. pp. 375–383. 8. Liu T., Cao P., Lin H. Damage and fracture evolution of hydraulic fracturing in compression-shear rock cracks. Theoretical and Applied Fracture Mechanics. 2014. Vol. 74. pp. 55–63. 9. Zhuang X., Chun J., Zhu H. A comparative study on unfilled and filled crack propagation for rock-like brittle material. Theoretical and Applied Fracture Mechanics. 2014. Vol. 72. pp. 110–120. 10. Kumar S., Singh I. V., Mishra B. K. A multigrid coupled (FE-EFG) approach to simulate fatigue crack growth in heterogeneous materials. Theoretical and Applied Fracture Mechanics. 2014. Vol. 72. pp. 121–135. 11. Moustapha M., Beck A. T., Bourinet J.-M. Design-point excitation for crack propagation under narrow-band random loading. International Journal for Uncertainty Quantification. 2013. Vol. 3, Iss. 6. pp. 541–554. 12. Saramak D. Mathematical models of particle size distribution in simulation analysis of highpressure grinding roll operations. Physicochemical Problems of Mineral Processing. 2013. Vol. 49, Iss. 1. pp. 121–131. 13. Caitov V. I. Usloviya podobiya protsessov razrusheniya gornykh porod pri droblenii i izmelchenii (Conditions of likeness of rock destruction processes during grinding and breaking). Gornoe oborudovanie i elektromekhanika = Mining equipment and electromechanics. 2015. No. 1. pp. 25–28. 14. Vasilev P. V. Chislennoe reshenie uravneniya kinetiki dezintegratsii i raskrytiya mineralov polikristallicheskikh chastits (Numerical solution of equation of kinetics of disintegration and opening of polycristalline particle minerals). Nauchnye vedomosti Belgorodskogo gosudarstvennogo universiteta. Seriya: Ekonomika. Informatika = Scientific bulletin of Belgorod State University. Series: Economics. Informatics. 2012. Vol. 22, No. 7-1. pp. 92–100. |