ArticleName |
Magnetic peristaltic pumps for backfill |
ArticleAuthorData |
Saint-Petersburg Mining University, St. Petersburg, Russia:
Vasilyeva M. A., Associate Professor, Candidate of Engineering Sciences, saturn.sun@mail.ru |
Abstract |
The third of the mineral mining companies in the world use systems with backfill. Backfilling is intended to enhance safety, implement ground control, reduce possible losses of minerals, prevent underground fires, or coal and gas outbursts, and to protect objects in residential areas from destruction. In view of the features of backfill mixture components, specificity of flow to filling points and the required backfill quality standards, it is increasingly urgent to have novel technologies for backfill mixture handling. A cardinally new approach to transportation of liquid and viscous media is the use of low-frequency magnetic peristaltic pumps based on the nature likeliness. |
References |
1. Starkov L. I., Zemskov A. N., Kondrashev P. I. Development of machine-assisted potash mining. Perm : PGTU, 2007. 522 p. 2. Aleksandrov V. I., Kibirev V. I. The Kachkanarsky MCC iron ore processing tailings slurry hydraulic transport parameters determination. Obogashchenie Rud. 2018. No. 1. pp. 56-63. DOI: 10.17580/or.2018.01.10 3. Aleksandrov V. I., Kibirev V. I. Estimation of efficiency of hydrotransport pipelines polyurethane coating application in comparison with steel pipelines. Obogashchenie Rud. 2016. No. 2. pp. 51-56. DOI: 10.17580/or.2016.02.07 4. Blekhman I. I., Blekhman L. I., Vaisberg L. A. Vibration overcomes gravity—Nonlinear effects, simple models. Dynamics of Percussion–Vibration (Highly Nonlinear) Systems : Proceedings of XVIII International Symposium Devoted to the 100th Anniversary of Doctor of Engineering Sciences, Professor A. E. Kobrinsky. Moscow, 2015. pp. 64–72. 5. Pushkarev A., Podoprigora N., Dobromirov V. Methods of providing failure-free operation in transport infrastructure objects. Transportation Research Procedia. 2018. No. 36. pp. 634–639. 6. Liss N. Y., Kremcheev E. A., Afanasiadi K. I. Reclamation of salinized land at tailings ponds at ALROSA. Gornyi Zhurnal. 2017. No. 10. pp. 65-69. DOI: 10.17580/gzh.2017.10.14 7. Guide lines for mine flooding safety and protection of undermined objects in mining the Upper Kama potash salt deposit (production procedures). Saint-Petersburg : VNIIG, 2008. 8. Aglyukov Kh. I. Ground control with creation of high-density artificial filling masses. Izvestiya vuzov. Gornyi zhurnal. 2004. No. 5. pp. 9–15. 9. Verkholantseva T. V., Dyagilev R.A. Influence of backfilling on seismic activity in potash mines. GIAB. 2016. No. 12. pp. 222–224. 10. Borzakovsky B. A., Papulov L. M. Backfill operations in the Upper Kama potash mines. Moscow : Nedra, 1994. 234 p. 11. Adushkin A. A., Turuntaev S. V. Stimulated seismicity—induced and triggered. Moscow : IDG RAN, 2015. 364 p. 12. Vasilyeva M. A. An overview of development trends for the pumping equipment of mining and processing enterprises. Obogashchenie Rud. 2019. No. 1. pp. 51-56. DOI: 10.17580/or.2019.01.08 13. Vasilyeva M. A. Perspectives of application of 3D shape memory composite materials for peristaltic transportation of slurries. Key Engineering Materials. 2015. Vol. 685. pp. 291–294. 14. Fuhrer R., Schumacher C. M., Zeltner M., Stark W. J. Soft iron/silicon composite tubes for magnetic peristaltic pumping: Frequency-dependent pressure and volume flow. Advanced Functional Materials. 2013. Vol. 23(31). pp. 3845–3849. 15. Birzvalks Yu. A. Equivalent circuit of the dc pump channel and maximum efficiency pump design. Applied Magnetodynamics: Transactions of the Institute of Physics. Akad. Nauk LatSSR, 1961. 16. Kovalenko A. I., Klimova T. G. Determining the parameters of a synchronous generator with the use of synchronized phasor measurements. Izvestiya vysshikh uchebnykh zavedenii. Elektromekhanika. 2018. No. 1. pp. 20–24. |