Geokhod Propel Effort Mathematical Model

M.Yu. Blaschuk; A.A. Dronov; D.A. Miheev

doi:10.4028/www.scientific.net/AMM.770.391

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 770Geokhod Propel Effort Mathematical Model

Geokhod Propel Effort Mathematical Model

Abstract:

A mathematical model for calculating geokhod propel efforts is developed. Effect of geokhod transmission design on power parameters is considered as well as geokhod advance speed in subsurface. This mathematical model is developed for a two-section geokhod being combined with any type of working body and transmission.

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Periodical:

Applied Mechanics and Materials (Volume 770)

Pages:

391-396

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.770.391

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Online since:

June 2015

Authors:

M.Yu. Blaschuk*, A.A. Dronov, D.A. Miheev

Keywords:

Geokhod, Mathematical Model, Propel Efforts, Transmission

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* - Corresponding Author

References

[1] V.V. Aksenov, Scientific foundation for geo-winch mining technology and design of helical-rotary units, Dr. tech. sci. diss., IC SB RAS., Kemerovo, (2004).

Google Scholar

[2] V.V. Aksenov, A.B. Efremenkov, Geo-winch technology and geokhods: scientific and innovative approach to mineral extracting and development of underground space. 2 (2009) 26-29.

Google Scholar

[3] V.V. Aksenov, A.B. Efremenkov, V.U. Sadovets, V.Y. Timofeev, M.Y. Blaschuk, V.Y. Beglyakov, Requirements for geokhod basic systems, J. Mining informational and analytical bulletin. 10 (2009) 107-118.

Google Scholar

[4] A.B. Efremenkov, V.V. Aksenov, M.Y. Blaschuk, V.Y. Timofeev, Geokhod transmission requirements, J. Mining Journal. 8 (2009) 101-103.

Google Scholar

[5] V.V. Aksenov, A.B. Efremenkov, V.Y. Beglyakov, M.Y. Blaschuk, V.Y. Timofeev, A.V. Sapozhkova, Geokhod basic systems requirements, J. Mining Equipment and Electrical Engineering. 5 (2009) 3-7.

Google Scholar

[6] V.V. Aksenov, A.B. Efremenkov, V. Yu. Beglykov, Effect of relative distance between ledges on stress-strain state of rock face, J. Applied Mechanics and Materials. 379 (2013) 16-19.

DOI: 10.4028/www.scientific.net/amm.379.16

Google Scholar