Control Technology and Application for Surrounding Rock Deformation in T-Junction Area of Gob-Side Entry Retaining

Chang Liang Han; Nong Zhang; Bao Yu Li

doi:10.4028/www.scientific.net/AMR.838-841.1873

Paper Titles

Analysis of Down Resistance of the Measuring and Adjusting Apparatus in Lubricator of Oilfield Injector
p.1856

Numerical Modeling of the Influence Scope of Marine Oil Spill with Wind-Driven
p.1861

The Management of Crude Oil Handover Mouth and Discusses the Problems of the International Standard
p.1865

Review and Outlook on Technologies for Developing PetroChina Low-Permeability Reservoirs
p.1869

Control Technology and Application for Surrounding Rock Deformation in T-Junction Area of Gob-Side Entry Retaining
p.1873

Application of Loose Blasting in Fully-Mechanized Coal Face Crossing Faults
p.1880

Strength Assessments of Concrete-Filled Steel Tubular Support of Soft Rock Roadway
p.1884

The Patterns of Management and Utilization of Landslips and Corresponding Landscape Ecological Reconstruction in the Coal Mine Area in China
p.1891

Simulation of Microwave Activation Effect of Coal Gangue by ANSYS
p.1898

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 838-841Control Technology and Application for Surrounding...

Control Technology and Application for Surrounding Rock Deformation in T-Junction Area of Gob-Side Entry Retaining

Abstract:

On the bases of theoretic analysis, numerical simulation, and project practice, stress distribution of surrounding rock and movement characteristics of roof strata in T-junction area of gob-side entry were analyzed. Besides, control technology in T-junction area was proposed after indicating deformation characteristics of different stages in gob-side entry. Results show that there is an inclined block in T-junction area after fracture of main roof and the period when the block is tending to stability is a critical stage of pressure appearance for gob-side entry. Further, three stress zones: in-situ stress zone, abutment pressure zone and low stress zone appear in both strike and dip of mining panel and enhanced support of gob-side entry before excavation should keep away from the abutment pressure zone, which also indicates that deep bolting support can exert the bearing capacity of deep rock mass. Additionally, the whole procedure of surrounding rock deformation can be divided into four stages and deformation in gob-side entry is larger than that of entry excavation, which means that efficient support design should be taken into account. Ultimately, district control technologies for surrounding rock of gob-side entry in back zone, filling zone, and front zone are proposed and it showed a good adaption in project practice of coalmine.

You might also be interested in these eBooks

Civil, Structural and Environmental Engineering

View Preview

Info:

Periodical:

Advanced Materials Research (Volumes 838-841)

Pages:

1873-1879

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.838-841.1873

Citation:

Cite this paper

Online since:

November 2013

Authors:

Chang Liang Han*, Nong Zhang, Bao Yu Li

Keywords:

Abutment Pressure, District Control Technologies, Enhanced Support, Gob-Side Entry Retaining, T-Junction

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] L. Yuan: Theory and practice of integrated pillarless coal production and methane extraction in multiseams of low permeability (China Coal Industry Publishing House, China 2008). (In Chinese).

Google Scholar

[2] H. H Sun, B. L Zhao: Theory and practice of gob-side entry retaining (China Coal Industry Publishing House, China 1993). (In Chinese).

Google Scholar

[3] N. Zhang, L. Yuan, C.L. Han, J.H. Xue and J.G. Kan: Safety Science, Vol. 50(2012) No. 4, p.593.

Google Scholar

[4] L. Yuan: Journal of China Coal Society, Vol. 33(2008) No. 8, p.898. (In Chinese).

Google Scholar

[5] L. Yuan, H. Guo, B.T. Shen, Q.D. Qu and J.H. Xue: Journal of China Coal Society, Vol. 36(2011) No. 3, p.357. (In Chinese).

Google Scholar

[6] M. Tu, L. Yuan, X.X. Miao, Z.G. Liu, N.Z. Xu and B.J. Fu: Coal Science and Technology, Vol. 41(2013) No. 1, p.40. (In Chinese).

Google Scholar

[7] T.Y. Qi, Y.G. Guo and C.J. Hou: Journal of China Coal Society, Vol. 24(1999) No. 3, p.256. (In Chinese).

Google Scholar

[8] Y. Chen, J.B. Bai, T.L. Zhu, S. Yan, S.H. Zhao and X.C. Li: Rock and Soil Mechanics, Vol. 33(2012) No. 5, p.1427. (In Chinese).

Google Scholar

[9] J.H. Xue, C. L Han: Journal of Mining & Safety Engineering, Vol. 29(2012) No. 4, p.466. (In Chinese).

Google Scholar

[10] M.G. Qian, P.W. Shi and J.L. Xu: Mine pressure and strata control. (China University of Mining and Technology Press, China 2010). (In Chinese).

Google Scholar

[11] J.A. Wang, D.Z. Li, X.C. Sang: Rock Mechanics and Rock Engineering, Vol. 45(2012) No. 4, p.533. (In Chinese).

Google Scholar

[12] M.G. Qian, X.X. Miao: Chinese Journal of Rock Mechanical and Engineering, Vol. 14(1995) No. 2, p.97. (In Chinese).

Google Scholar