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The paper presents a new method of determining the energy consumption for vibratory crushing. Using the laboratory vibratory jaw crusher with kinematic actuation of the jaws, the study of determining power consumption while crushing limestone and diabase was conducted. During the study, electrical energy used on the crushing process was measured as a function of changing design and kinematic parameters of the vibratory crusher, i.e.: jaws stroke, the outlet gap size and frequency of jaws vibration. The article presents program of the research, the laboratory test stand of the vibratory jaw crusher KW 40/1 and the test results. Comparing the theoretical crushing energy requirements, determined by the Bond hypothesis, with the values measured during tests a large differences were observed. Using the Bond hypothesis the Vibratory Work Indexes were determined for the tested materials. Their values are higher than limestone and diabase Work Indexes available in the known literatures. The explanation may be greater amount of energy transferred to the material during vibratory crushing, which results in much higher efficiency of the crushing process.
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Czasopismo
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Tom
Strony
287--294
Opis fizyczny
Bibliogr. 14 poz., rys., tab.
Twórcy
Bibliografia
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- 8. Mazur M.: Examination of quartzite and diabase vibratory crushing. Materials of Polish Conference of Young Scientists, Kraków, vol. 5, p. 93-101, 2010.
- 9. Mazur M.: Research of crushing efficiency in vibratory jaw crushers, Doctoral thesis, AGH University of Science and Technology, Unpublished, 2017.
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- 11. Mendyka P., Kotwica K., Stopka G., Gospodarczyk P.: Innovative roadheader mining head with asymmetrical disc tools. International multidisciplinary scientific geoconference: science and technologies in geology, exploration and mining: 30 June-6 July, 2016, Albena, Bulgaria: conference proceedings. Vol. 2, Exploration and mining, mineral processing. - Sofia: STEF92 Technology Ltd., cop. 2016, s.489-496, 2016.
- 12. Sidor J., Mazur M.: Comparative studies of vibratory crushing process performed in jaw crushers, Ceramic Materials, ISSN: 1505-1269. t. 67 nr 1, p. 62-66, 2015.
- 13. Tomach, P.: The process model of the vibratory mill including the impact of the milling process-intensifying element [in Polish]. Przemysł Chemiczny, ISSN 0033-2496, Vol. 96 No. 12, pp. 2467-2470, 2017a.
- 14. Tomach, P.: Study of intensification of the milling process in the vibratory mill [in Polish]. Przemysł Chemiczny, ISSN 0033-2496, Vol. 96 No. 9, pp. 1893-1897, 2017b.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-27fb5d7a-7f57-4516-b2b4-b4ba11aee2f5