Research on the Transmission of Stresses by Roof Cutting near Gob Rocks

Zhibiao Guo; Haohao Wang; Zimin Ma; Pengfei Wang; Xiaohui Kuai; Xianzhe Zhang

doi:10.3390/en14051237

Research on the Transmission of Stresses by Roof Cutting near Gob Rocks

Energies ◽

10.3390/en14051237 ◽

2021 ◽

Vol 14 (5) ◽

pp. 1237

Author(s):

Zhibiao Guo ◽

Haohao Wang ◽

Zimin Ma ◽

Pengfei Wang ◽

Xiaohui Kuai ◽

...

Keyword(s):

Early Stage ◽

Pressure Coefficient ◽

Influence Factors ◽

Stress Transfer ◽

Main Roof ◽

Surrounding Rock ◽

Pressure Relief ◽

Rock Structure ◽

Immediate Roof ◽

The Stability

Pressure relief for roadways retained by roof cutting is essentially caused by stress transfer. In this paper, the stress transfer mechanism of 16011 tail entry with roof cutting in Zhaogu No.1 coal mine is studied from the following two aspects: the change of the tail entry surrounding the rock structure and the interaction between the roadway surrounding rock and supporting structures. It is found by numerical simulation that roof cutting can significantly reduce the magnitude of roadway roof stress, transferring the concentrated stress induced by excavation and mining away from the roadway, and forming an obvious triangle pressure relief area in front of the working face. In the early stage after mining, most of the overburden load is transferred downward through the immediate roof of the roadway. With the movement of overlying strata, the stress, initially transferred to the immediate roof strata, is gradually transferred to the gob, and the calculation formula and influence factors of the transferred stress are derived. In addition, through the establishment of the mechanical model and theoretical calculation of the key rock block of the main roof, the roadside support resistance required to ensure the stability of the main roof block is determined. The field monitoring shows that the lateral pressure coefficient of the roadside caved rocks is 0.36 and the constant resistance and large deformation anchor cable (CRLDAC) and the roadway temporary support play roles of conduction and control in the process of stress transfer, and effectively ensure the stability of surrounding rock during the service life of the retained gob-side entry by roof cutting (RGERC).

Stability Analysis of the Entry in a New Mining Approach Influenced by Roof Fracture Position

Sustainability ◽

10.3390/su11226349 ◽

2019 ◽

Vol 11 (22) ◽

pp. 6349

Author(s):

Jun Yang ◽

Hongyu Wang ◽

Yajun Wang ◽

Binhui Liu ◽

Shilin Hou ◽

...

Keyword(s):

Coal Pillar ◽

Main Roof ◽

Surrounding Rock ◽

Fracture Position ◽

Solid Coal ◽

Rock Structure ◽

Temporary Support ◽

Coal Wall ◽

Pillar Mining ◽

The Stability

Non-coal pillar mining with roadway formed automatically (RFANM) is a new mining approach, which demonstrates revolutionary significance because it does not require making roadway before mining and coal pillar retaining. In order to explore the stability of the surrounding rock structure in RFANM, the deformation of the surrounding rock was theoretically analyzed and simulated based on three different fracture positions of the main roof. It was concluded that reasonable control of temporary support strength in roadway is of great importance to control the deformation of the entry. The deformation process of surrounding rock under different fracture positions in RFANM was simulated by using the Universal Discrete Element Code (UDEC). The results of the numerical simulation showed that the main roof was fractured at the solid coal side or gob side; the deformation of the roadway was small. The fracture condition of the main roof at the gob side required a higher effect of roof slitting or temporary support from the roadway. Through drilling and peeping at the retained roadway, it was judged that the main roof was broken inside the coal wall. Field monitoring results revealed that the deformation of the roadway can be effectively controlled.

The segmental subsidence structure with immediate roof of gob side entry retaining in backfill mining

Energy Exploration & Exploitation ◽

10.1177/0144598721996540 ◽

2021 ◽

pp. 014459872199654

Author(s):

Xin-yuan Zhao ◽

Xin-wang Li ◽

Ke Yang ◽

Zhen Wei ◽

Qiang Fu

Keyword(s):

Mechanical Model ◽

Surrounding Rock ◽

Extreme Conditions ◽

Structure Characteristics ◽

Rock Structure ◽

Immediate Roof ◽

Backfill Mining ◽

The Difference ◽

The Stability ◽

Supporting Force

When gob side entry retaining is carried out in backfill mining, the roof will show different subsidence morphology due to the difference of compactness and supporting force of the backfill body at different positions. This paper analyzed the immediate roof subsidence structure under two extreme conditions, constructed the roof segmented subsidence structure and the mechanical model of roadside backfill body, and used FLAC3D software to investigate the roof migration and the force law of the roadside backfill body under the conditions of different goaf backfilled rates, different width and strength of roadside backfill body. Finally, the backfill practice of a mine in Shandong Province of China is taken as an example for analysis. The results show that the segmented subsidence structure of the immediate roof is related to the mechanical properties of the roadside backfill body and the goaf backfill body. When the backfilled rate of goaf decreases from 95% to 70%, the width of roadside backfill body decreases from 5 m to 1 m, and the elastic modulus decreases from 10 GPa to 0.5 GPa, the greater difference in the subsidence and inclination of the immediate roof on both sides of the roadside backfill body is, the more obvious the segmented subsidence structure characteristics of the immediate roof are, and the greater force on the roadside backfill body will be, the more unfavorable it is to maintain the stability of the roadway surrounding rock and the roadway backfill body. Therefore, when gob side entry retaining is carried out in backfill mining, the surrounding rock structure and the force on roadside backfill body should be considered comprehensively.

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

Advances in Civil Engineering ◽

10.1155/2019/9801637 ◽

2019 ◽

Vol 2019 ◽

pp. 1-21 ◽

Cited By ~ 2

Author(s):

Cheng Zhu ◽

Yong Yuan ◽

Zhongshun Chen ◽

Zhiheng Liu ◽

Chaofeng Yuan

Keyword(s):

Engineering Application ◽

Stability Control ◽

Surrounding Rock ◽

Control Effect ◽

Pressure Relief ◽

Support Design ◽

Key Strata ◽

Fracture Development ◽

Surrounding Rock Control ◽

The Stability

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.

Numerical Simulation on Large Deformation of Weak Rock Mass Tunnel Under High Geostress

MATEC Web of Conferences ◽

10.1051/matecconf/201817503025 ◽

2018 ◽

Vol 175 ◽

pp. 03025

Author(s):

Feng Zhou ◽

Hongjian Jiang ◽

Xiaorui Wang

Keyword(s):

Rock Mass ◽

Large Deformation ◽

Lateral Pressure ◽

Simulation Analysis ◽

Pressure Coefficient ◽

Surrounding Rock ◽

Analog Simulation ◽

Lateral Pressure Coefficient ◽

High Geostress ◽

The Stability

The problem about the stability of tunnel surrounding rock is always an important research object of geotechnical engineering, and the right or wrong of the result from stability analysis on surrounding rock is related to success or failure of an underground project. In order to study the deformation rules of weak surrounding rock along with lateral pressure coefficient and burying depth varying under high geostress and discuss the dynamic variation trend of surrounding rock, the paper based on the application of finite difference software of FLAC3D, which can describe large deformation character of rock mass, analog simulation analysis of surrounding rock typical section of the class II was proceeded. Some conclusions were drawn as follows: (1) when burying depth is invariable, the displacements of tunnel surrounding rock have a trend of increasing first and then decreasing along with increasing of lateral pressure coefficient. The floor heave is the most sensitive to change of lateral pressure coefficient. The horizontal convergence takes second place. The vault subsidence is feeblish to change of lateral pressure coefficient. (2) The displacements of tunnel surrounding rock have some extend increase along with increasing of burying depth. The research conclusions are very effective in analyzing the stability of surrounding rock of Yunling tunnel. These are going to be a reference to tunnel supporting design and construction.

Surrounding Rock Movement of Steeply Dipping Coal Seam Using Backfill Mining

Shock and Vibration ◽

10.1155/2021/5574563 ◽

2021 ◽

Vol 2021 ◽

pp. 1-17

Author(s):

Wenyu Lv ◽

Kai Guo ◽

Jianhao Yu ◽

Xufeng Du ◽

Kun Feng

Keyword(s):

Numerical Simulation ◽

Coal Seam ◽

Surrounding Rock ◽

Maximum Deflection ◽

Coal Seams ◽

Physical Similarity ◽

Working Face ◽

Rock Structure ◽

Backfill Mining ◽

The Stability

The movement of the overlying strata in steeply dipping coal seams is complex, and the deformation of roof rock beam is obvious. In general, the backfill mining method can improve the stability of the surrounding rock effectively. In this study, the 645 working face of the tested mine is used as a prototype to establish the mechanical model of the inclined roof beam using the sloping flexible shield support backfilling method in a steeply dipping coal seam, and the deflection equation is derived to obtain the roof damage structure and the maximum deflection position of the roof beam. Finally, numerical simulation and physical similarity simulation experiments are carried out to study the stability of the surrounding rock structure under backfilling mining in steeply dipping coal seams. The results show the following: (1) With the support of the gangue filling body, the inclined roof beam has smaller roof subsidence, and the maximum deflection position moves to the upper part of working face. (2) With the increase of the stope height, the stress and displacement field of the surrounding rock using the backfilling method show an asymmetrical distribution, the movement, deformation, and failure increase slowly, and the increase of the strain is relatively stable. Compared with the caving method, the range and degree of the surrounding rock disturbed by the mining stress are lower. The results of numerical simulation and physical similarity simulation experiment are generally consistent with the theoretically derived results. Overall, this study can provide theoretical basis for the safe and efficient production of steeply dipping coal seams.

Comparative Study on Two Types of Nonpillar Mining Techniques by Roof Cutting and by Filling Artificial Materials

Advances in Civil Engineering ◽

10.1155/2019/5267240 ◽

2019 ◽

Vol 2019 ◽

pp. 1-15 ◽

Cited By ~ 3

Author(s):

Enze Zhen ◽

Yubing Gao ◽

Yajun Wang ◽

Siming Wang

Keyword(s):

Numerical Simulation ◽

High Efficiency ◽

Simulation Analysis ◽

Surrounding Rock ◽

Support Pressure ◽

Hydraulic Support ◽

Pressure Relief ◽

Rock Structure ◽

Coal Pillars ◽

Peak Value

Gob-side entry retaining is an environmentally friendly nonpillar mining technology with high efficiency and safety. With the continuous exploration of the gob-side entry retained by filling (GERF) with roadside supports, the GERF has enabled nonpillar mining. However, dense roadside supports or filled artificial pillars become subject to the pressure of roof pressure instead of coal pillars, which causes problems. Recently, an original innovative gob-side entry retaining technology by roof cutting and pressure relief (RCPR) was developed and extensively implemented in China’s coal production. The gob-side entry formed by different retaining methods has exhibited some differences in the strata behaviors and the results of retained roadways. Via industrial case and numerical simulation, this study explored the influence of entry retaining methods on the results of the entry retained. The results indicate that the total deformation of the surrounding rock of the GERF is larger and more severe; the convergence between the roof and floor and the entry sides displacement is 885 mm and 216 mm, respectively; the hydraulic support pressure near the retained entry is larger; and the peak value is 38.7 MPa. The deformation of the surrounding rock by RCPR is relatively small; the convergence between the roof and the floor and the entry sides displacement is 351 mm and 166 mm, respectively; the hydraulic support pressure near the retained entry is weakened to a certain extent; the peak value is 32.2 MPa; and the peak pressure is reduced by 16.8% compared with the GERF. A numerical simulation analysis reveals the following findings: RCPR changes the surrounding rock structure of a gob-side entry, optimizes the surrounding rock stress environment, and belongs to active pressure-relief entry retaining; the GERF does not adjust the surrounding rock structure of a gob-side entry and belongs to passive pressure-resistance entry retaining; and the surrounding rock of a gob-side entry is significantly affected by pressure. These two methods of gob-side entry retaining have different effects on the surrounding rock of the entry retained. This study can contribute to an exploration of the strata behaviors and the results of a retained roadway by the GERF or RCPR method.

Numerical Investigation into Rockburst Proneness of Deep-Buried Tunnels with Arch-Shaped Wall

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.250-253.1192 ◽

2011 ◽

Vol 250-253 ◽

pp. 1192-1195

Author(s):

Xin Yu Wang ◽

Zhu Shan Shao ◽

Yu Ming Cui

Keyword(s):

Lateral Pressure ◽

Pressure Coefficient ◽

Surrounding Rock ◽

Tarim River ◽

Tarim River Basin ◽

Rock Stress ◽

Factors Affecting ◽

Tunnel Design ◽

The Stability ◽

Surrounding Rock Stress

During the construction of the deep-buried tunnels, high surrounding rock stress and the rockburst are the important factors affecting the stability of surrounding rock. Xiabandi hydraulic engineering is the key project in Tarim River basin. Due to the deep buried excavation, rockburst is particularly prominent and should be received adequate attention. According to the rockburst practice during construction, numerical analysis is adopted to study the stress characteristics along depth with the same lateral pressure coefficient. Furthermore, the rockburst tendency along the tunnel with different burying depth is investigated. The conclusion is of great value to guide the rockburst control during the tunnel design and construction.

Research on Supporting Technology of Roadway Driving along Next Goaf of Second Mining Strip Pillar

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.446-449.1657 ◽

2012 ◽

Vol 446-449 ◽

pp. 1657-1660

Author(s):

Wei Dong Lv ◽

Nan Nan Zhao

Keyword(s):

Abutment Pressure ◽

High Strength ◽

Main Roof ◽

Surrounding Rock ◽

Control Effect ◽

General Stability ◽

High Strength Bolt ◽

Mining Face ◽

The Stability ◽

Surrounding Rock Deformation

For roadway driving along next goaf of strip pillar second mining, being influenced by the abutment pressure of previous coal mining face and main roof breaking rotary deformation, the surrounding rock deformation is serious and the control effect of ordinary bolt supporting on the general stability of roadway driving along next goaf is poorer. According to the concrete geological and technique condition of the 2351 second mining strip pillar in Daizhuang Colliery, adopting the united support pattern combined high strength bolt of levorotatory continuous thread and anchor of low relaxation prestress, the safety of the roadway can be ensured and the stability of the roadway surrounding rocks can be improved. It is of significant reference meaning for bolting support of roadway driving along next goaf of second mining strip pillar under similar condition.

Numerical Simulation of Stress Arching Effect in Horizontally Layered Jointed Rock Mass

Symmetry ◽

10.3390/sym13071138 ◽

2021 ◽

Vol 13 (7) ◽

pp. 1138

Author(s):

Xiao Huang ◽

Huaining Ruan ◽

Chong Shi ◽

Yang Kong

Keyword(s):

Rock Mass ◽

Pressure Coefficient ◽

Jointed Rock ◽

Jointed Rock Mass ◽

Surrounding Rock ◽

Beam Structure ◽

Underground Engineering ◽

Joint Spacing ◽

Arching Effect ◽

The Stability

Stress arching effect during the excavation of broken surrounding rock in underground engineering has an important influence on the stability of surrounding rock after underground excavation. To determine the stress arching effect in horizontally layered jointed rock mass, the stress arching characteristics of surrounding rock mass after excavation is analyzed in this study by using a series of numerical tests. The formation mechanism of stress arch is revealed through a comparison of the stress characteristics of a voussoir beam structure and theoretical analysis of multi-block mechanical relationship of jointed rock mass. The method for determining the boundaries of a stress arching zone is proposed, and the influence of various factors on a stress arch is further discussed. Results show that after the excavation of horizontally layered jointed rock mass, the stress arch bunch (SAB) is formed in the lower strata above the cavern, and the global stress arch (GSA) is formed in the higher strata, both of which are symmetrical arch stress patterns. The SAB is the mechanical manifestation of the voussoir beam structure formed by several low-level sandstone layers, and the GSA is caused by the uneven displacement between blocks. Compared with the GSA, the SAB is more sensitive to various influencing factors. The extent of stress arching zone decreases with the increase of an internal friction angle of the joint, lateral pressure coefficient, and overburden depth. In addition, the joint spacing of rock strata is conducive to the development of a stress arch. Results can provide technical support for deformation control and the stability analysis of broken surrounding rock in underground engineering.

A Numerical Study of Underground Cavern Stability by Geostress Characteristics

Shock and Vibration ◽

10.1155/2016/3768453 ◽

2016 ◽

Vol 2016 ◽

pp. 1-13

Author(s):

Xiao-Jing Li ◽

Li-Ge Wang ◽

Wei-Min Yang

Keyword(s):

Numerical Study ◽

Pressure Coefficient ◽

Side Wall ◽

Surrounding Rock ◽

High Mountain ◽

Burial Depth ◽

Underground Cavern ◽

Rock Cavern ◽

The Stability ◽

Cavern Stability

The stability of underground cavities is of increasing importance considering the predominant cavity locations built up in high mountain and canyon environments. Such cavity locations are characterized by a high initial in situ stress, which results in brittle fracture and deformation of the surrounding rock during cavity construction. This paper presents a numerical study of underground cavern stability considering four factors, namely, mechanical property of surrounding rock, cavern burial depth, lateral pressure coefficient in horizontal direction, and the angle included between plant longitudinal axis and horizontal principal stress. Analytical methods including the key point displacement in side wall, plastic zone volume, and splitting fracture volume are used to characterize the stability of underground cavern. A modified formula to predict side wall displacement is proposed based on prior work, which is applicable to 3D computation model by taking horizontal geostress in two directions into account. Eventually, the optimal layout of underground cavern is put forward under different conditions of geostress field.