Increasing productivity of vibration hopper loaders by installation planetary vibrodrive with kinematically unbalanced masses
( Pp. 77-83)
More about authors
Zakirov Rodion G.
Cand. Sci. (Eng.); associate professor at the Department of Engineering, Technology and Construction
South Ural State University
Chelyabinsk, Russian Federation Nekrutov Vladivir G. Cand. Sci. (Eng.); associate professor at the Department of Engineering, Technology and Construction
South Ural State University
Chelyabinsk, Russian Federation
South Ural State University
Chelyabinsk, Russian Federation Nekrutov Vladivir G. Cand. Sci. (Eng.); associate professor at the Department of Engineering, Technology and Construction
South Ural State University
Chelyabinsk, Russian Federation
Abstract:
Introduction. The article considers the application of planetary vibration motor with kinematically unbalanced masses with a wide range of adjustable parameters of the operating body oscillations in vibration hopper loaders. Materials and methods. The method of oscillation generation allows adjusting the oscillation frequency and amplitude and at the same time synchronization of oscillatory movements of two working bodies is provided. The authors conducted the analysis of existing design solutions for the problem of control over oscillatory process parameters in vibration hopper loaders. Regulation of the frequency and amplitude of oscillations, and, consequently, associated with them, the speed of movement and the driving force of the working bodies is possible by changing the combination of kinematic, geometric and force parameters by planetary vibration motor with kinematically unbalanced masses. Regulation of kinematic and power parameters can be carried out automatically. They provide theoretical justification for the planetary vibration motor with kinematically unbalanced masses application in flexible industrial systems to improve the flexibility and operation efficiency of vibration hopper loaders. Experimental research. Further, the authors describe the experimental research of the developed designs for such vibration hopper loaders with planetary vibration motor with kinematically unbalanced masses. There search results are provided in comparison with the existing design options. The results of oscillatory processes, presented show the principal possibilities of the considered vibration drives in relation to the control over actuating device oscillation parameters. Conclusions. The optimal parameters and methods for the control over the designed vibration hopper loaders have been found out. They help to substantially improve the system flexibility, expand technological opportunities of hopper loaders and obtain a significant technical & economic effect in the area of flexible production.
How to Cite:
Zakirov R.G., Nekrutov V.G., (2021), INCREASING PRODUCTIVITY OF VIBRATION HOPPER LOADERS BY INSTALLATION PLANETARY VIBRODRIVE WITH KINEMATICALLY UNBALANCED MASSES. Computational Nanotechnology, 1 => 77-83.
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Vyong K.CH., Kovrigina I.V., Eliseev S.V. i dr. Tekhnologicheskie vibratsionnye mashiny - novye podkhody v otsenke i korrektirovke dinamicheskikh sostoyaniy. CH. I // Vestnik Irkutskogo gosudarstvennogo tekhnicheskogo universiteta. 2019. T. 23. № 1 (144). S. 16-27.
Wirtz M. Advanced vibration technology innovations for coal screening // XVIII International Coal Preparation Congress / V. Litvinenko (ed.). Springer, 2016. Pp. 931-934. DOI: 10.1007/978-3-319-40943-6 145.
Filimonikhin G.B., YAtsun V.V. Sposob vozbuzhdeniya dvukhchastotnykh vibratsiy passivnymi avtobalansirami // Vostochno-evropeyskiy zhurnal peredovykh tekhnologiy. 2015. T. 4. № 7 (76). S. 9-14.
Gobozov S.F., Dzhioev V.K. Puti razvitiya elektrovibratsionnykh mashin // Nauka, tekhnika i obrazovanie. 2018. № 6 (47). S. 45-49.
Wei Liu, Ming Su. Study on the kinematics synchronization of three axis inertial vibration exciter // Design, Manufacturing and Mechatronics. 2017. Pp. 244-259. DOI: 10.1142/9789813208322 0029.
Yujia Li, Tao Ren, Jinnan Zhang, Minghong Zhang. Synchronization of two eccentric rotors driven by one motor with two flexible couplings in a spatial vibration system. Mathematical Problems in Engineering. 2019. Article ID 2969687. 13 p. DOI: 10.1155/2019/2969687.
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Vasil ev A.M., Bredikhin S.A., Andreev V.K. Vliyanie nachal noy fazirovki debalansov v tsentrobezhnom vibrovozbuditele na kharakteristiki zakona kolebaniy silovogo faktora // Nauchnyy zhurnal NIU ITMO. Seriya: Protsessy i apparaty pishchevykh proizvodstv. 2019. № 1 (39). S. 27-35.
Afanas ev A.I., Suslov D.N. Otsenka energeticheskoy effektivnosti vibrovozbuditeley rezonansnykh vibrotransportnykh mashin // Gornyy informatsionno-analiticheskiy byulleten (Nauchno-tekhnicheskiy zhurnal). 2018. № 1. S. 126-132.
Blekhman I.I., Blekhman L.I., YAroshevich N.P. K dinamike privoda vibratsionnykh mashin s inertsionnym vozbuzhdeniem // Obogashchenie rud. 2017. № 4 (370). S. 49-53.
Vyong K.CH. Novye vozmozhnosti izmeneniya dinamicheskikh sostoyaniy vibratsionnykh tekhnologicheskikh mashin // Sistemy. Metody. Tekhnologii. 2018. № 2 (38). S. 25-31.
Lakirev S.G., KHil kevich YA.M., Sergeev S.V. A.s. 1664412 SSSR, MKI3B 06 B 1/15. Sposob vozbuzhdeniya krugovykh kolebaniy i ustroystvo dlya ego osushchestvleniya. № 4414912/24-28; zayavl. 24.04.88; opubl. 23.07.91. Byul. № 27. 10 s.; il.
Tupolskikh T.I., Gucheva N.V., Kirishiev O.R. Simulation of the process of movement of bulk material in a vibrating conveyor-mixer // MATEC Web of Conferences. 2018. No. 224. P. 05021. DOI: 10.1051/matecconf/201822405021.
Popescu D.I. Study of particle motion on a helical vibrating surface // Applied Mechanics and Materials. 2016. Vol. 823. Pp. 13-16. DOI: 10.4028/www.scientific.net/AMM.823.13.
Sergeev S.V., Reshetnikov B.A., Zakirov R.G. Vibratsionnye rotornye privody mashin. CHelyabinsk.: Izd-vo YUUrGU, 2007. 240 s.
Nguen KHoa Bin. Sovershenstvovanie vibratsionnykh avtomaticheskikh zagruzochnykh ustroystv: Avtoref. dis.. kand. tekhn. nauk: 05.02.02. Tula. 2007. 20 s.
Zakirov R.G. Modelirovanie kolebatel nykh protsessov v planetarnykh vibroprivodakh s kinematicheski neuravnoveshennoy massoy. // Nauchno-tekhnicheskiy vestnik Bryanskogo gosudarstvennogo universiteta. 2019. № 2. S. 164-173.
Keywords:
vibration generator, vibrodrive, hopper loaders, oscillation parameters.
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