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EQUIPMENT AND MATERIALS
Название Analysis of operation features of sizing screen with parametric excitation
DOI 10.17580/em.2021.01.12
Автор Bardovskiy A. D., Gorbatyuk S. M., Gerasimova A. A., Basyrov I. I.
Информация об авторе

College of Environmentally Sound Technologies and Engineering, NUST MISIS, Moscow, Russia:

Bardovskiy A. D., Professor, Doctor of Engineering Sciences
Gorbatyuk S. M., Head of Process Equipment Engineering Department, Professor, Doctor of Engineering Sciences, sgor02@mail.ru
Gerasimova A. A., Associate Professor, Candidate of Engineering Sciences
Basyrov I. I., Assistant at Process Equipment Engineering Department

Реферат

The article presents the studies into the operation of a sizing screen with parametric excitation of the sifting surface. The nonlinear differential equation describes the motion of the sifting surface. Solution of this equation with regard to the factor of nonlinear elasticity determines the amplitude of steady-state lateral vibrations of the sieve. The probability of particle pass through the sieve mesh during vibration shear flow of particles along the sifting surface with continuous tossing is determined. The derived relations allow finding the required length of the sifting surface for sizing particles at the preset fidelity, as well as the time-variable mesh sizes with regard to tension and bending. The change in the sieve deformation versus the shift angle between the longitudinal and lateral vibrations is found. The value of relative deformation during parametric vibrations grows linearly with an increasing angle of phase shift between the longitudinal and lateral vibrations, and arrives at the maximum at the phase shift angle of π/2. The mathematical relations describing conditions of mesh emptying and removal of stuck grains are presented. The testing data on sizing of wet limestone aggregates 5 mm in size on the sieve with parametric excitation of the sifting surface are given. It is found that in the beginning of sizing, the sifting surface is chocked at the test points with limiting size grains due to insufficient displacement of opposite mesh walls. Later on, the open space of the screen is stabilized. Efficiency of self-cleaning of the sifting surface is estimated in terms of the screening surface loss versus operation conditions and time of screening.

Ключевые слова Sizing screen, parametric excitation, sieve vibration amplitude, process, probability, sieve length, mesh sizes, sieve self-cleaning
Библиографический список

1. Morozov V. I. Estimate of sifting surfaces of shaking screens for dry sizing of nonmetal waste with natural moisture content at open pit mines. GIAB. 1998. No. 4. pp. 49–54.
2. Bardovskii A. D., Gerasimova A. A., Keropyan A. M., Bibikow P. Ya. Influence of the mechanical characteristics of harp screen material on screening process. Izvestiya vuzov, Chernaya metallurgiya. 2018. No. 9(1). pp. 678–682. DOI: 10.17073/0368-0797-2018-9-678-682
3. Starikovskiy P. P. Design validation of sizing screens with parametric excitation for wet carbonate material separation. Candidate of Engineering Sciences Dissertation. Мoscow : MGI, 1989. 147 p.
4. Kharitonov A. O., Bibikov P. Ya., Verzhanskiy P. M., Voronin B. V. Classification of pressing machines for separation of weak rocks. Modern scientific knowledge: theory, methodology, practice : Collected papers. Smolensk, 2016. pp. 72–73.
5. Sivachenko L. A., Dobrovolsky Yu. K. History of development of grinding engineering and its up-to-date level. Vestnik Belorussko-Rossiyskogo universiteta. 2012. No. 4(37). pp. 69-76.
6. Bibikov P. Ya., Bardovskiy A. D., Mitusov P. E., Kalakutskiy A. V. Design in addition shredder classifier for processing weak rocks. GIAB. 2015. No 8. pp. 166–170.
7. Bardovsky A. D., Gerasimova A. A. Analysis of drive mechanism of side-to-side moving flexible blade. GIAB. 2019. No. 7. pp. 132–139. DOI: 10.25018/0236-1493-2019-07-0-132-139
8. Shapoval A. N., Shapoval A. A. Development of the unit for multi-stage vibration drawing of metal products. Tsvetnye Metally. 2002. No. 4. pp. 77-82.
9. Kartavyy N. G. Grinding and sizing equipment for waste processing at open pit nonmetal mines. Nauchnye shkoly MGGU. 2008. Vol. 2. pp. 318–325.
10. Naumova M., Basyrov I., Aliev K. Reengineering of the ore preparation production process in the context of Almalyk MMC JSC. MATEC Web of Conferences. 2018. 01030. DOI: 10.1051/matecconf/201822401030
11. Bratan S., Roshchupkin S. Synthesis of lunberger stochastic observer for estimation of the grinding operation state. MATEC Web of Conferences. 2018. Vol. 224. 01133. DOI: 10.1051/matecconf/201822401133
12. Lyashenko V. I., Dyatchin V. Z., Franchuk V. P. Engineering and commissioning of vibrating screeners–feeders for the mining industry. Chernaya metallurgiya. 2014. No. 5. pp. 72–80.
13. Mamonov S. V., Tsipin E. F., Bratygin E. V. Conditions of self cleaning of the screen surface for thin hydraulic screening. Izvestiya vuzov. Gornyy zhurnal. 2014. No. 5. pp. 106–111.
14. Fomin A. A., Gusev V. G., Sattarova Z. G. Geometrical errors of surfaces milled with convex and concave profile tools. Solid State Phenomena. 2018. Vol. 284. pp 281–288.
15. Bardovsky A. D., Gerasimova A. A., Basyrov I. I. Study of Oscillating Process of Harp Screens. Lecture Notes in Mechanical Engineering. Springer. 2019. pp 133-139.
16. Gorbatyuk S. M., KeropyanA. M., Bibikov P. Ya. Assessing Parameters of the Accelerator Disk of a Centrifugal Mill Taking into Account Features of Particle Motion on the Disk Surface. Journal of Friction and Wear. 2018. Vol. 39, No. 4. pp. 326–329.
17. Jain C. V., Panchve D. P. Design and development of Cam operated multiple vibrating screening machine. International Journal of Emerging Technology and Advanced Engineering. 2016. Vol. 6, Iss. 2. pp. 78–80.
18. Wills B. A., Finch J. A. Wills’ mineral processing technology. Elsevier, 2015. 512 p.
19. Zhang B., Zhu G., Lv B., Yan G. A novel and effective method for coal slime reduction of thermal coal processing. Journal of Cleaner Production. 2018. Vol. 198. pp. 19–23.
20. Gupta A., Yan D. Mineral processing design and operations. An introduction. 2nd ed. Elsevier, 2016. 882 p.
21. Roshchupkin S., Kharchenko A. Method of building dynamic relations, estimating product and grinding circle shape deviations. MATEC Web of Conferences. 2018. Vol. 224. 01001. DOI: 10.1051/matecconf/201822401001
22. Slobodyanik T. M., Balakhnina E. E. Dynamics of elementary differential composed of elastic bodies. GIAB. 2019. No. 9. pp. 204–210.
23. Starikovskiy P. P. Amplitudes of parametric vibrations of screeners made of elastic materials. Equipment for Integrated Use of Mineral Products : Collected Papers. Мoscow, 1987. pp. 67–71.
24. Kartavyy N. G., Starikovskiy P. P., Pushpakbaev B. T., Kafanov L. S. Separation of granular materials on sieves with parametric excitation. Promyshlennost stroitelnykh materialov Moskvy. 1986. No. 4. pp. 11–14.

Полный текст статьи Analysis of operation features of sizing screen with parametric excitation
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