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

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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Constant-Resistance, Rigid, and Flexible Coupling Support Technology for Soft Rock Entrances in Deep Coal Mines:A Case Study in China

Advances in Materials Science and Engineering ◽

10.1155/2020/6212456 ◽

2020 ◽

Vol 2020 ◽

pp. 1-15

Author(s):

Yong Zhang ◽

Chengwei Zhao ◽

Ming Jiang ◽

Jiaxuan Zhang ◽

Chen Chen ◽

...

Keyword(s):

Large Deformation ◽

Support System ◽

Soft Rock ◽

High Strength ◽

Surrounding Rock ◽

Constant Resistance ◽

The Stability ◽

Control Principle ◽

Soft Rock Roadway ◽

Rock Roadway

The stability control of a soft rock roadway is a crucial problem for sustainable utilization of limited coal resources in deep mining practices. To solve it, the soft rock types and failure mechanism of −890 entrance surrounding rock have been analyzed, taking Daqiang Coal Mine of China as an engineering example. The analysis shows that the damage to the surrounding rock was characterized by asymmetry, large deformation, severe damage, and extended durations. The surrounding rock can be divided into high-stress-jointed-strong expansion soft rock based on S-M scanning and mineral analysis. Numerical simulation is used to reproduce the failure process of the original supporting system and analyze the deformation of the surrounding rock, range of plastic zone, and distribution of the stress field. The failure mechanism is thus defined for a deep soft rock roadway. Combined with the above studies, the deformation mechanics of the surrounding rock is summarized as type IABIIABIIIABC. The stability transformation mechanism of the surrounding rock is proposed, based on which the control principle of deformation stability of a surrounding rock is formed. According to the control principle, “high strength support controls the surrounding rock deformation. The large deformation of the flexible support system releases the accumulated energy to the surrounding rock, and long-term deformation of the surrounding rock is controlled by high strength truss support.” Meanwhile, the constant-resistance, rigid, and flexible coupling (CRRFC) support system is proposed. The numerical analysis demonstrated that the CRRFC support system can effectively reinforce the shallow surrounding rock and improve the bearing capacity. Simultaneously, the development of the surrounding rock malignant plastic zone is effectively controlled. The application results show that the large deformation of the roadway can be effectively controlled by the CRRFC support system, which provides applications for similar engineering.

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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.

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Application of Constant Resistance and Large Deformation Anchor Cable in Soft Rock Highway Tunnel

Advances in Civil Engineering ◽

10.1155/2019/4347302 ◽

2019 ◽

Vol 2019 ◽

pp. 1-19 ◽

Cited By ~ 4

Author(s):

Xiaoming Sun ◽

Bo Zhang ◽

Li Gan ◽

Zhigang Tao ◽

Chengwei Zhao

Keyword(s):

Large Deformation ◽

Support System ◽

Field Tests ◽

Soft Rock ◽

Internal Force ◽

Surrounding Rock ◽

Gansu Province ◽

Tunnel Engineering ◽

Anchor Cable ◽

Constant Resistance

Muzhailing Highway Extra-long Tunnel in Lanzhou, Gansu Province, China, belongs to the soft rock tunnel in the extremely high geostress area. During the construction process, large deformation of the soft rock occurred frequently. Taking the no. 2 inclined shaft of Muzhailing tunnel as the research object, an NPR (negative Poisson’s ratio) constant resistance and large deformation anchor cable support system based on high prestress force, constant resistance, and releasing surrounding rock pressure was proposed. The characteristics of the surrounding rock under the steel arch support and NPR anchor cable support were compared and analyzed by using 3DEC software. A series of field tests were conducted in the no. 2 inclined shaft, and the rock strength, displacement of the surrounding rock, deep displacement of the surrounding rock, internal force of steel arch, and axial force of anchor cable were measured to study the application effect of the NPR anchor cable support system in tunnel engineering. Moreover, the 3DEC numerical simulation results were compared with the field test results. The research results show that the application of NPR constant resistance and large deformation anchor cable support system in tunnel engineering has achieved good results, and it plays a significant role in controlling the large deformation of the tunnel surrounding rock.

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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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Study on Deformation Mechanism and Support Measures of Soft Surrounding Rock in Muzhailing Deep Tunnel

Advances in Civil Engineering ◽

10.1155/2020/9367916 ◽

2020 ◽

Vol 2020 ◽

pp. 1-14 ◽

Cited By ~ 1

Author(s):

Zhigang Tao ◽

Jindong Cao ◽

Liu Yang ◽

Aipeng Guo ◽

Ruifeng Huang ◽

...

Keyword(s):

Large Deformation ◽

Support System ◽

Deformation Mechanism ◽

High Stress ◽

Soft Rock ◽

Maximum Principal Stress ◽

Surrounding Rock ◽

Single Type ◽

Deep Tunnel ◽

Support Measures

The deformation of Muzhailing deep tunnel is about 2.3 m in the process of construction, which is difficult to be controlled by the traditional “anchor-grouting integration” support system. This paper deeply analyzes the geological characteristics, rock mechanics characteristics, and surrounding rock failure characteristics of Muzhailing tunnel. The deformation mechanism and the failure of the support system are analyzed through the numerical simulation, theoretical analysis, and field test. The authors propose support measures suitable for Muzhailing tunnel based on the analysis results. The maximum buried depth is 600 m, and the engineering rock mass at the depth has nonlinear physical and mechanical phenomenon. The maximum principal stress of Muzhailing tunnel is 25.7 MPa, which belongs to high-stress joint swelling soft rock tunnel. The NPR cable can achieve large deformation under the condition of constant support resistance. The authors put forward the coupling support mode of “NPR cable + steel arch frame + concrete,” which is based on the idea of transforming the composite deformation mechanism to a single type. The stress concentration appears in the range of 12 m in the surrounding rock circle, and the lateral and vertical stress distributions are relatively symmetrical after the improved support. The circumferential strain of the surrounding rock is greatly reduced, and the range of strain is reduced by 10%. The field monitoring results show that the new support system can well control the large soft rock deformation of Muzhailing tunnel (0.5 m). The support strategy proposed can effectively control the large deformation and promote the formation of new support concept for deep tunnel.

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Study on the Mechanical Behavior of Double Primary Support of Soft Rock Tunnel under High Ground Stresses and Large Deformation

Advances in Civil Engineering ◽

10.1155/2020/8832797 ◽

2020 ◽

Vol 2020 ◽

pp. 1-9

Author(s):

Zhe Liu

Keyword(s):

Mechanical Behavior ◽

Large Deformation ◽

Design Method ◽

Characteristic Curve ◽

Soft Rock ◽

Support Design ◽

Deformation Amount ◽

Secondary Lining ◽

Rock Tunnels ◽

Primary Support

Double primary support structures could effectively solve the problem of large deformation of surrounding rock for soft rock tunnels. However, the mechanical behavior of this new support structure is still incomplete, and the design method should be revised. Based on the theory of energy conversion, this paper analyzes the support characteristic curve of double primary support and puts forward the dynamic design method of double primary support. Considering that the secondary lining can be set after monitoring the deformation amount and deformation rate of the first primary support, its support parameters can be dynamically adjusted according to the actual situation. By applying the double primary support design method in the Maoxian tunnel of Chenglan Railway, the field monitoring results show that the double primary support has a significant effect on the energy release of surrounding rocks, greatly reducing the load acting on the secondary lining and ensuring the safety and reliability of the tunnel structure.

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Judgement Method for Surrounding Rock Stability of Guanjiao Tunnel Based on Catastrophe Theory

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.90-93.2307 ◽

2011 ◽

Vol 90-93 ◽

pp. 2307-2312 ◽

Cited By ~ 2

Author(s):

Wen Jiang Li ◽

Su Min Zhang ◽

Xian Min Han

Keyword(s):

Plastic Strain ◽

Catastrophe Theory ◽

Soft Rock ◽

Surrounding Rock ◽

In Situ Monitoring ◽

Engineering Practice ◽

Stability Of Surrounding Rock ◽

The Stability ◽

Rock Tunnel

The stability judgement of surrounding rock is one of the key jobs in tunnel engineering. Taking the Erlongdong fault bundle section of Guanjiao Tunnel as the background, the stability of surrounding rock during construction of soft rock tunnel was discussed preliminarily. Based on plastic strain catastrophe theory, and combining numerical results and in-situ data, the limit displacements for stability of surrounding rock were analyzed and obtained corresponding to the in-situ monitoring technology. It shows that the limit displacements obtained corresponds to engineering practice primarily. The plastic strain catastrophe theory under unloading condition provides new thought for ground stability of deep soft rock tunnel and can be good guidance and valuable reference to construction decision making and deformation managing of similar tunnels.

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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.

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Analysis on Loose Circle of Surrounding Rock of Large Deformation Soft-Rock Tunnel

Advances in Civil Engineering ◽

10.1155/2020/8842976 ◽

2020 ◽

Vol 2020 ◽

pp. 1-11

Author(s):

Rui Wang ◽

Yiyuan Liu ◽

Xianghui Deng ◽

Yu Zhang ◽

Xiaodong Huang ◽

...

Keyword(s):

Large Deformation ◽

Theoretical Calculations ◽

Rapid Development ◽

Field Tests ◽

Soft Rock ◽

Strength Criterion ◽

Surrounding Rock ◽

Distribution Law ◽

Geological Conditions ◽

Rock Tunnel

With the rapid development of tunnel construction in China, deep buried and long tunnel projects are emerging in areas with complex engineering geological conditions and harsh environment, and thus large deformation of tunnels under conditions of high in situ stress and soft rock becomes increasingly prominent and endangers engineering safety. Therefore, it is of great significance to control the deformation and improve the stability of surrounding rock by analyzing the thickness and distribution law of loose circle according to the unique mechanical properties and failure mechanism of surrounding rock of large deformation soft-rock tunnel. Based on unified strength theory, this paper deduces the radius calculation formula of the loose circle by considering the influence of intermediate principal stress. Furthermore, the theoretical calculations and field tests of the loose circle in the typical sections of grade II and III deformation of Yuntunbao tunnel are carried out, and the thickness and distribution law of loose circle of surrounding rock of large deformation soft-rock tunnel is revealed. The results show that the formula based on the unified strength criterion is applicable for a large deformation tunnel in soft rock.

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Presplitting Blasting the Roof Strata to Control Large Deformation in the Deep Mine Roadway

Advances in Civil Engineering ◽

10.1155/2020/8886991 ◽

2020 ◽

Vol 2020 ◽

pp. 1-15

Author(s):

Chaowen Hu ◽

Xiaojie Yang ◽

Ruifeng Huang ◽

Xingen Ma

Keyword(s):

Large Deformation ◽

Field Tests ◽

Soft Rock ◽

Surrounding Rock ◽

Deep Mine ◽

Mining Depth ◽

Working Face ◽

Support Conditions ◽

Mine Roadways ◽

Roof Strata

As the mining depth increases, under the influence of high ground stress, the surrounding rock of deep mine roadways shows soft rock characteristics. Under the influence of mining disturbance at the working face, large deformation of the roadway has occurred. To control the large deformation of the roadway, many mines have adopted the form of combined support, which has continuously increased the support strength and achieved a certain effect. However, since the stress environment of the surrounding rock of the roadway has not been changed, large deformation of the roadway still occurs in many cases. Based on the theoretical basis of academician Manchao He’s “short cantilever beam by roof cutting,” this paper puts forward the plan of “presplitting blasting + combined support” to control the large deformation of the deep mine roadways. Without changing the original support conditions of the roadway, presplitting blasting the roof strata of the roadway, by cutting off the mechanical connection of the roof strata between the roadway and gob, improves the stress distribution of the roadway to control the large deformation. Through field tests, the results show that after presplitting blasting the roadway roof, the roadway roof subsidence is reduced by 47.9%, the ribs displacement is reduced by 45.7%, and the floor heave volume is reduced by 50.8%. The effect is significant.

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