Source: http://nvngu.in.ua/index.php/en/home/1644-engcat/archive/2018/contents-5-2018/solid-state-physics-mineral-processing/4570-synergetic-model-of-the-wave-abrasive-fatigue-wear-of-rubber-lining-in-the-ball-tube-mills
Timestamp: 2019-04-20 22:43:50+00:00

Document:
Purpose. To develop a synergetic model and, on its basis, a theory of wave abrasive-fatigue wear of rubber lining in the ball mills; to confirm fidelity of the analytical model by industrial test results.
Methodology. A comprehensive approach was used, which included analytical studies and extensive industrial tests of different ball mills.
Findings. On the basis of the designed synergetic model and the Polya-Velikanov equations, mathematical equations were formulated, with the help of which it is possible to describe a pattern of wave abrasive-fatigue wear of rubber lining; on the basis of the theory of deterministic chaos, key regularities were identified in the wave motion of inputs inside the tube of the mill; correctness of the analytical model was confirmed by results of industrial tests, which are presented herein.
Originality. An original synergetic model was developed and, on its basis, a theory of the wave abrasive-fatigue wear of rubber lining in the ball mills was created. Key regularities of wave motion of inputs inside the tube of the mill were identified.
Practical value. On the basis of analytical calculations, the Wave-type rubber linings were designed and implemented, which are currently competitive at the world market. On the basis of the lining, a new energy- and resource-saving technology of mineral disintegration in the ball-tube ore-grinding mills was created and implemented into industry.
1. Kalashnikov,V. A., Golovko, L. G. and Afanasiev, E. S., 2016. The rubber lining system of ball drum mills. Obogaschenie rud, 1(361), pp. 60–63. DOI: 10.17580/or.2016.01.10.
2. Maliarov, P. V., 2017. On the design of combined lining of ball mills. Obogaschenie rud, 3(369), pp. 10–14. DOI: 10.17580/or.2017.03.02.
3. Dyrda, V. I., Kalashnikov, V. A. and Khmel, I. V., 2014. Energy-saving ES-technology of disintegration of ores in ball mills with rubber lining. Chernaya metallurgiya: Byul. in-ta Chermetinformatsiya, 2(1370), pp. 22–26.
4. Іliyin, S. R., Samusia, V. І., Іliyina, І. S. and Іliyina, S. S., 2016. Influence of dynamic processes in mine hoists on safety exploitation of shafts with broken geometry, Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu, 3, pp. 48‒53.
5. Maliarov, P. V., 2014. Physical aspects of grinding mineral raw materials in ball mill mills. In: Theses of the Conference “Progressive methods of enrichment and complex processing of natural and man-made minerals (Paksin Scientific Conference 2014)”, Almaty, Kazakhstan, 16‒19 September 2014 [online], pp. 601–604. Available at: <https://elibrary.ru/item.asp?id=23629108> [Acce­ssed 15 June 2017].
6. Kopchenkov, V. G., 2016. Mechanisms of wear of elastomers by direct impact of abrasive particles. Trenie i iznos, 37/1, рр. 70–76.
7. Mwanga, A., Parian, M., Lamberg, P. and Rosenkranz, J., 2017. Comminution modeling using mineralogical properties of iron ores. Minerals Engineering, 111, рр. 182–197. DOI:10.1016/j.mineng.2017.06.017.
8. Khopunov, E. A., 2014. Analysis of the causes of low efficiency of processes of destruction of minerals. Sovremennaia tekhnika i tekhnologii [online], 10, Available at: <http://technology.snauka.ru/2014/10/4690> [Acce­ssed 3 May 2017].
9. Nastoiashchii, V. A. and Yatcun, V. V., 2017. Comparative assessment of wear resistance of steel and rubber coatings of surfaces of structures of enterprises of the mining and metallurgical complex under impact loads. Vіsnik Odeskoi derzhavnoi akademіi budіvnitctva ta arkhіtekturi, 67, pp. 43‒47. Available at: <http://nbuv.gov.ua/UJRN/Vodaba_2017_67_10> [Accessed 11 January 2018].

References: V. 
 V. 
 V. 
 V. 
 V. 
 V.