Study of the Stability Control of the Rock Surrounding Double-Key Strata Recovery Roadways in Shallow Seams

The stability control of the rock surrounding recovery roadways guarantees the safety of the extraction of equipment. Roof falling and support crushing are prone to occur in double-key strata (DKS) faces in shallow seams during the extraction of equipment. Therefore, this paper focuses on the stability control of the rock surrounding DKS recovery roadways by combining field observations, theoretical analysis, and numerical simulations. First, pressure relief technology, which can effectively release the accumulated rock pressure in the roof, is introduced according to the periodic weighting characteristics of DKS roofs. A reasonable application scope and the applicable conditions for pressure relief technology are given. Considering the influence of the eroded area on the roof structure, two roof mechanics models of DKS are established. The calculation results show that the yield load of the support in the eroded area is low. A scheme for strengthening the support with individual hydraulic props is proposed, and then, the support design of the recovery roadway is improved based on the time effects of fracture development. The width of the recovery roadway and supporting parameters is redesigned according to engineering experience. Finally, constitutive models of the support and compacted rock mass in the gob are developed with FLAC3D software to simulate the failure characteristics of the surrounding rock during pressure relief and equipment extraction. The surrounding rock control effects of two support designs and three extraction schemes are comprehensively evaluated. The results show that the surrounding rock control effect of Scheme 1, which combines improved support design and the bidirectional extraction of equipment, is the best. Engineering application results show that Scheme 1 realizes the safe extraction of equipment. The research results can provide a reference and experience for use in the stability control of rock surrounding recovery roadways in shallow seams.

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Study of the Stability Control of Rock Surrounding Longwall Recovery Roadways in Shallow Seams

Shock and Vibration ◽

10.1155/2020/2962819 ◽

2020 ◽

Vol 2020 ◽

pp. 1-22

Author(s):

Cheng Zhu ◽

Yong Yuan ◽

Zhongshun Chen ◽

Chaogui Meng ◽

Shengzhi Wang

Keyword(s):

Rock Pressure ◽

Coal Mine ◽

Stability Control ◽

Control Effect ◽

Support Design ◽

Key Strata ◽

Key Stratum ◽

Discriminative Approach ◽

The Stability ◽

Working Resistance

The rock pressure appearance of longwall faces in shallow seams is generally violent, and roofs and supports are susceptible to damage during equipment extraction. Stability control of the rock surrounding longwall recovery roadways allows safe and rapid equipment extraction. Herein, via theoretical analysis, numerical simulations, and field observations, the stability control of the rock surrounding recovery roadways is studied to ensure the release of the accumulated rock pressure on the roof, the working resistance of the supports and the reasonableness of the recovery roadway support design. Pressure-relief technology is introduced to release the accumulated rock pressure before equipment extraction, and a discriminative approach is proposed to determine the breaking and articulated forms of key strata and broken blocks, respectively. On this basis, mechanical models of roof instability are established based on four key stratum structures in the overburden of shallow seams. Methods for calculating a reasonable working resistance for supports are discussed. Finally, Liangshuijing Coal Mine and Fengjiata Coal Mine are taken as research objects to evaluate the roof stability of recovery roadways based on observations of weighting characteristics. The support working resistances and reasonable recovery roadway widths under three key stratum structures are determined. Considering the time effect of plastic zone development, the support design of recovery roadways is optimized. FLAC2D software simulates the surrounding rock control effect of two support designs, and roof subsidence curves are obtained. The results show that the key to equipment extraction in shallow seams is to ensure that supports have reasonable working resistances and to improve the support of recovery roadways. The results provide a reference for the selection and extraction of supports in shallow seam faces.

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Study on the Instability Characteristics and Bolt Support in Deep Mining Roadways Based on the Surrounding Rock Stability Index: Example of Pansan Coal Mine

Advances in Civil Engineering ◽

10.1155/2020/8855335 ◽

2020 ◽

Vol 2020 ◽

pp. 1-16 ◽

Cited By ~ 1

Author(s):

Jucai Chang ◽

Kai He ◽

Zhiqiang Yin ◽

Wanfeng Li ◽

Shihui Li ◽

...

Keyword(s):

Coal Mine ◽

Stability Index ◽

Surrounding Rock ◽

Full Length ◽

Control Effect ◽

Support Design ◽

Rock Stability ◽

Working Face ◽

The Stability ◽

Bolt Support

In view of the influence of mining stress on the stability of the surrounding rock of inclined roof mining roadways in deep mines, the surrounding rock stability index is defined and solved based on the rock strength criterion and the stress distribution. The mining roadway of the 17102(3) working face of the Pansan Coal Mine is used as the engineering background and example. The surrounding rock’ stabilities under the conditions of no support and bolt support are analyzed according to the surrounding rock’s stability index and the deformation data. The results show that the areas of low wall and high wall instability are 1.68 m2 and 2.12 m2, respectively, and the low wall is more stable than the high wall; the areas of the roof and floor instability are 0.33 m2 and 0.35 m2, respectively, and the roof and floor are more stable than the two sides. During mining, the area of instability greatly increases at first, then decreases to 0, and reaches a maximum value at the peak of the abutment pressure. The stability of the surrounding rock decreases first and then increases. Compared with the end anchoring bolt support, the full-length anchoring bolt support reduces the area of instability to a greater extent, and the full-length anchoring bolt support effect is better. The surrounding rock in the end anchoring zone and the full-length anchoring zone began to deform significantly at 200 m and 150 m from the working face, respectively. This indicates that the control effect of the full-length anchoring bolt support is better and verifies the rationality of the surrounding rock stability index to describe the instability characteristics. This research method can provide a theoretical reference for analysis of the stability characteristics and support design of different cross-section roadways.

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Stability Control of a Goaf-Side Roadway under the Mining Disturbance of an Adjacent Coal Working Face in an Underground Mine

Sustainability ◽

10.3390/su11226398 ◽

2019 ◽

Vol 11 (22) ◽

pp. 6398

Author(s):

Houqiang Yang ◽

Changliang Han ◽

Nong Zhang ◽

Changlun Sun ◽

Dongjiang Pan ◽

...

Keyword(s):

Stress Distribution ◽

Stability Control ◽

Surrounding Rock ◽

Engineering Practice ◽

Key Strata ◽

Coal Recovery ◽

Working Face ◽

Underground Coal Mines ◽

Mining Disturbance ◽

The Stability

Goaf-side roadway driving could not only notably reduce the loss of coal resources and improve the coal recovery rates, but also greatly mitigate the imbalance between excavation speed and production needs, which are able to prolong the service life of the mine and are pivotal to sustainable and efficient development of underground coal mines. However, it is difficult to control the stability of the goaf-side roadway, especially under mining disturbance of another adjacent coal working face. In order to control the stability of the goaf-side roadway, Haulageway 1513 in the Xinyi Coal Mine of China, under mining disturbance, theoretical analysis, numerical simulation, and engineering practice were carried out to reveal the mechanism of overburden key strata fracture, stress distribution, and deformation characteristics of the surrounding rock of the goaf-side roadway due to mining disturbance. Results showed that some key strata above Goaf 1512 did not fracture due to the influence of the strata caving angles. However, these key strata would fracture and break into rock blocks when suffering from mining disturbance of the adjacent coal working face, which changed the stress distribution and increased the deformations of the surrounding rock of the goaf-side roadway. The combined techniques of pressure relief and bolt support were proposed and carried out to control the stability of the goaf-side roadway. Engineering practice indicated that the maximum deformations of the roof and sidewall-to-sidewall were 220 mm and 470 mm, respectively. The deformations of the goaf-side roadway under mining disturbance were efficiently controlled.

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Stability Analysis of Roadway Groups under Multi-Mining Disturbances

Applied Sciences ◽

10.3390/app11177953 ◽

2021 ◽

Vol 11 (17) ◽

pp. 7953

Author(s):

Yuantian Sun ◽

Ruiyang Bi ◽

Qingliang Chang ◽

Reza Taherdangkoo ◽

Junfei Zhang ◽

...

Keyword(s):

Coal Mining ◽

Coal Pillar ◽

Stability Control ◽

Surrounding Rock ◽

Key Strata ◽

Working Face ◽

Roadway Stability ◽

Mining Disturbance ◽

Mining Face ◽

The Stability

The roadway stability has been regarded as the main challenging issue for safety and productivity of deep underground coal mines, particularly where roadways are affected by coal mining activities. This study investigates the −740 m main roadway in the Jining No. 2 Coal Mine to provide a theoretical basis for the stability control of the main deep roadway affected by disturbances of adjacent working activities. Field surveys, theoretical analyses, and numerical simulations are used to reveal mechanisms of the coal mining disturbance. The field survey shows that the deformation of roadway increases when the work face advances near the roadway group. Long working face mining causes the key strata to collapse based on the key strata theory and then disturbs the adjacent roadway group. When the working face is 100 m away from the stop-mining line, the roadway group is affected by the mining face, and the width roadway protection coal pillar is determined to be about 100 m. Flac3D simulations prove the accuracy of the theoretical result. Through reinforcement and support measures for the main roadway, the overall strength of the surrounding rock is enhanced, the stability of the surrounding rock of the roadway is guaranteed, and the safe production of the mine is maintained.

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Effects of High-Pretension Support System on Soft Rock Large Deformation of Perpendicularly Crossing Tunnels

Advances in Civil Engineering ◽

10.1155/2020/6669120 ◽

2020 ◽

Vol 2020 ◽

pp. 1-18

Author(s):

Li Gan ◽

Ma Weibin ◽

Tian Siming ◽

Zhou Wenhao

Keyword(s):

Theoretical Analysis ◽

Large Deformation ◽

Support System ◽

Control Mechanism ◽

Three Dimensional ◽

Soft Rock ◽

Surrounding Rock ◽

Control Effect ◽

Support Design ◽

The Stability

The control mechanism of prestressed support system is studied by means of three-dimensional discrete element numerical simulation, theoretical analysis, and field measurement. The actual project is selected to analyze, and the control effect is demonstrated. The theoretical analysis results show that the prestressed support can improve the self-bearing capacity of surrounding rock, which is conducive to the stability of the surrounding rock. The numerical calculation shows that, under the control of the long and short cables, the prestress can spread effectively and form two bearing arches. The deformation is difficult to control, which is in the arch crown and the arch shoulder of the tunnel intersection. However, the deformation of the surrounding rock decreases with the increase of prestress. Through the analysis of the measured results, it shows that the pretension support design scheme can effectively control the large deformation of the surrounding rock.

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Deformation Rules for Surrounding Rock in Directional Weakening of End Roofs of Thin Bedrocks and Ultrathick Seams

Advances in Civil Engineering ◽

10.1155/2020/8882374 ◽

2020 ◽

Vol 2020 ◽

pp. 1-12

Author(s):

Fei Liu ◽

Zhanguo Ma ◽

Yongsheng Han ◽

Zhimin Huang

Keyword(s):

Abutment Pressure ◽

Main Roof ◽

Stability Control ◽

Surrounding Rock ◽

Western China ◽

Resource Exploitation ◽

Failure Characteristics ◽

Key Strata ◽

Working Face ◽

Geological Conditions

With the deployment of China’s energy strategy in the western regions, complex geological mining conditions such as thin bedrock and ultrathick seams in western China have caused a series of problems such as serious deformation of the surrounding rock at the ends of the working face and the increase in the lead abutment pressure of the roadways; the research on end roof deformation in the resource exploitation in western China has become one of the great demands of the industry. Based on the failure characteristics of rock mass, relying on the actual mining geological conditions of a coal mine in Inner Mongolia, the failure characteristics of the overlying rock strata under the influence of mining were simulated and analyzed using similar material simulation experiment, which intuitively reproduced the failure and deformation processes of the immediate roof, main roof, and key strata and revealed the mechanical mechanism of the directional weakening of the end roof. It is of great significance for the stability control of the surrounding rock at the end of the fully mechanized caving face in the thin bedrocks and ultrathick seams, reducing the abutment pressure of gate roadway and controlling the spontaneous combustion of residual coal in the goaf.

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Coal Seam Roadway Bolt Support Design Method Based on the Supporting Theory of Broken Rock Zone

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.734-737.535 ◽

2013 ◽

Vol 734-737 ◽

pp. 535-539

Author(s):

Hai Yuan Liu ◽

Zhi Gang Wang ◽

Ji Li ◽

Lang Bai

Keyword(s):

Theoretical Foundation ◽

Design Method ◽

Field Application ◽

Surrounding Rock ◽

Support Design ◽

Roadway Support ◽

The Stability ◽

Comprehensive Classification ◽

Classification Index ◽

Surrounding Rock Deformation

broken rock zone is the main reason for the convergence of surrounding rock deformation, and its thickness not only is a reflection of many factors which influence the stability of surrounding rock, but also is the results of the interaction of many factors, a comprehensive classification index. Roadway support design based on classification result of broken rock zone, has a solid theoretical foundation, and the field application effect is remarkable.

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Analysis of Seepage Field of Highway Tunnel Excavation by Finite Difference Method

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.638-640.798 ◽

2014 ◽

Vol 638-640 ◽

pp. 798-803

Author(s):

Yong Tao Zhang

Keyword(s):

Finite Difference ◽

Circulatory System ◽

Surrounding Rock ◽

Design Parameters ◽

Seepage Field ◽

Tunnel Excavation ◽

Highway Tunnel ◽

Geological Conditions ◽

Fracture Development ◽

The Stability

As the excavation of tunnels, there are new channels of the groundwater drainage. The original supply of the circulatory system has been destroyed. The effects of groundwater to rock mass of surrounding rock are aggravated. In this paper, combined with a new highway tunnel project, the model is built according to the design parameters and the site engineering geological conditions of the tunnel. The fluid-structure interaction module of the finite difference software FLAC3D is used for the research on tunnel excavation. The distribution of seepage field, the stability of surrounding rock and rock deformation under saturated conditions during the tunnel excavation have been analyzed. The simulation results have certain guiding meaning on fracture development, the stability design of tunnels in water-rich stratum and the design and construction of anti-drainage.

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Research on Fully Mechanized Coal Face Hydraulic Support Selection Based on the Testing Principle of Floor Specific Pressure

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.217-218.1637 ◽

2011 ◽

Vol 217-218 ◽

pp. 1637-1640

Author(s):

Nian Jie Ma ◽

Guo Dong Zhao ◽

Chun Lei Ju ◽

Wei Jiang ◽

Chong Li

Keyword(s):

Design Optimization ◽

Surrounding Rock ◽

Mechanical Parameters ◽

Specific Pressure ◽

Crucial Point ◽

Coal Face ◽

Hydraulic Support ◽

Support Design ◽

Pressure Testing ◽

Surrounding Rock Control

Interaction between coal face hydraulic support and floor is the crucial point for surrounding rock control in coal face and hydraulic support design optimization. Based on the principle of floor specific pressure testing, mechanized coal face hydraulic support parameters are tracked and such mechanical parameters as allowable specific pressure of floor strata are measured, in accordance with which this paper studies on the surrounding rock control in coal face and hydraulic support selection in fully mechanized coal face.

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Support design of main retracement passage in fully mechanised coal mining face based on numerical simulation

Applied Mathematics and Nonlinear Sciences ◽

10.2478/amns.2021.1.00059 ◽

2021 ◽

Vol 0 (0) ◽

Author(s):

Yalong Li ◽

Mohanad Ahmed Almalki ◽

Cheng Li

Keyword(s):

Numerical Simulation ◽

Coal Mine ◽

Surrounding Rock ◽

Control Measures ◽

Coal Face ◽

Support Design ◽

Working Face ◽

Surrounding Rock Control ◽

Mining Face ◽

Mining Pressure

Abstract For the comprehensive mechanised coal mining technology, the support design of the main withdrawal passage in the working face is an important link to achieve high yield and efficiency. Due to the impact of mining, the roof movement of the withdrawal passage is obvious, the displacement of the coal body will increase significantly, and it is easy to cause roof caving and serious lamination problems, and even lead to collapse accidents, which will affect the normal production of the mine. In this paper, the mining pressure development law of the main withdrawal passage support under the influence of dynamic pressure is designed, the most favourable roof failure form of the withdrawal passage is determined, and the action mechanism and applicable conditions of different mining pressure control measures are studied. The pressure appearance and stress distribution in the final mining stage of fully mechanised coal face are studied by numerical simulation. The deformation and failure characteristics and control measures of roof overburden in the last mining stage of fully mechanised coal face are analysed theoretically. Due to the fact that periodic pressure should be avoided as far as possible after the full-mechanised mining face is connected with the retracement passage, some auxiliary measures such as mining height control and forced roof blasting are put forward on this basis. The relative parameters of the main supporting forms are calculated. The main retracement of a fully mechanised working face in a coal mine channel is put forward to spread the surrounding rock grouting reinforcement, reinforcing roof, and help support and improve the bolt anchoring force, the main design retracement retracement channels in the channel near the return air along the trough for supporting reinforcing surrounding rock control optimisation measures, such as through the numerical simulation analysis, the optimisation measures for coal mine fully mechanised working face of surrounding rock is feasible. Numerical simulation results also show that the surrounding rock control of fully mechanised working face of coal mine design improvements, its main retreat channel under the roof subsidence, cribbing shrank significantly lower, and closer, to better control the deformation of surrounding rock, achieved significant effect, to ensure the safety of coal mine main retracement channel of fully mechanised working face support.

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