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Very fine crushing of hard and very hard materials, to product of particle size less than 2-4 mm at feed particle size of 50-200 mm, requires a very large energy inputs. This is mainly because of the need for at least three or even four degrees of crushing, containing: jaw, cone or impact crushers. One of the methods of reducing the amount of energy expended on the crushing process is reducing the number of crushers in technological line. By replacing a large number of less effective crushers with fewer machines but characterized by higher crushing efficiency we can gain considerable savings in investment and operating costs. This is possible by using crushers capable of obtaining much greater degrees of fragmentation than the aforementioned, that is vibratory crushers. The paper includes the systematic of currently used vibratory crushers, their mechanical diagrams, descriptions of the construction and operation, and basic technical parameters as well as examples of crushing technological lines utilizing vibratory crushers.
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28--36
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Bibliogr. 12 poz., rys.
Twórcy
Bibliografia
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- 2. Mekhanobr, (1993): Drobno-izmielczitielnoje masziny. Materials of Mekhanobr-Technogen, Sankt Petersburg.
- 3. Gospodarczyk P., Kotwica K., Stopka G., (2013): A new generation mining head with disc tool of complex trajectory, Archives of Mining Sciences - Archiwum Górnictwa, vol. 58 t. 4 pp. 985-1006.
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- 5. Mazur M., (2010): Examination of quartzite and diabase vibratory crushing. Materials of Polish Conference of Young Scientists, Kraków, vol. 5, pp. 93-101.
- 6. Mendyka P., Kotwica K., Stopka G., Gospodarczyk P., (2016): Innovative roadheader mining head with asymmetrical disc tools. International multidisciplinary scientific geoconference: Science and technologies in geology, exploration and mining: 30 June-6 July, Albena, Bulgaria conference proceedings. Vol. 2, Exploration and mining, mineral processing. - Sofia: STEF92 Technology Ltd., cop. pp. 489-496, 2016.
- 7. Sidor J., (2008): Preliminary investigations of industrial line of mechanical processing of ceramic wastes for recycling. Polish Journal of Environmental Studies. vol. 17, pp. 507-510.
- 8. Sidor J., (1997): Development of vibratory crushers design. Maszyny Górnicze, vol. 77, pp. 30-37.
- 9. Sidor J., (2006): Badania procesu bardzo drobnego kruszenia odpadów produkcyjnych ceramiki sanitarnej w kruszarce wibracyjnej. Monografie Wydz. Inżynierii Mechanicznej i Robotyki AGH Kraków, vol. 32, p. 277-286.
- 10. Sidor J., Feliks J., (2015): Vibratory granulators, Przemysł Chemiczny, t. 94, nr 5, pp. 767-770.
- 11. Tomach, P., (2017a): 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.
- 12. Tomach, P., (2017b): 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.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-1a94adbc-9abd-46a1-b607-0de62dfea2f4