Study on the Face Stability of a Metro Tunnel in a Silty Clay Layer Constructed Using the Full-Face Method
Abstract
:1. Introduction
2. Displacement Mechanism of the Soft Soil in Full-Face Excavation
2.1. Model Establishment and Parameter Selection
2.2. Calculation Condition
2.3. Analysis of Calculation Results
2.3.1. Influence Range of Full-Face Excavation
2.3.2. Extrusion Displacement of Tunnel Face
2.3.3. Settlement Displacement of the Tunnel Vault
2.3.4. Surface Settlement Displacement
2.3.5. The Influence of Different Support Times on Tunnel Displacement
- (1)
- Reinforcement of advanced core soil can reduce tunnel displacement (face extrusion displacement, pre-convergence, convergence) and surface displacement. The displacement of advanced core soil is the main cause of tunnel displacement. After excavation, extrusion displacement occurs in the advanced core soil, which leads to the pre-convergence of the tunnel, and the pre-convergence of the tunnel leads to a significant increase in the convergence displacement of the tunnel.
- (2)
- There are two ways to control the displacement of the advanced core soil: One is to employ pre-reinforcement measures (use of full section grouting, glass fiber anchors) to improve the physical and mechanical parameters. The second is to shorten the displacement time of the advanced core soil. Closing the initial support in time will reduce the exposure time of the tunnel face.
- (1)
- The advanced core soil is composed of temporary surrounding rock, which is broken after maintaining a short period of stability. Therefore, the reinforcement of advanced core soil should not be too strong, as otherwise it will increase the construction energy consumption and reduce the construction efficiency. It is necessary to study the best construction parameters for pre-reinforcement measures.
- (2)
- Construction techniques for quick closing of the initial support.
3. Parameter Analysis of Advanced Core Soil Reinforced by Glass Fiber Anchors
3.1. Reinforcement Density of the Tunnel Face
3.1.1. Experiment on the Strengthening Effect of the Glass Fiber Anchor
- (1)
- Purpose of the experiment
- (2)
- Test materials and parameters
- (3)
- Comparative experimental design
- (4)
- Test process is shown in Figure 11.
- (5)
- Analysis of test results
3.1.2. Numerical Calculation of the Installation Density of the Glass Fiber Anchor
3.2. Longitudinal Reinforcement Length and Lap Length of the Glass Fiber Anchor
4. Rapid Closure Technology of the Initial Support
5. Conclusions
- (1)
- The influence of full-face excavation of a metro tunnel on surrounding rock can be categorized with regard to the hemispherical main area of influence and the transverse “heart” secondary area of influence, in which the radius of the main area of influence was 1.2–2.3 m. These values can be used as a reference with regard to the lap radius of the advanced reinforcement material on the tunnel face. The shortest influence range of the “heart” secondary area of influence was 6–9 m (about 1–1.5 times of the tunnel diameter) in front of the tunnel face.
- (2)
- The displacement of advanced core soil is the main cause of tunnel displacement. By increasing the strength of advanced core soil (E, C, Φ) or reducing the displacement time of the tunnel face, the tunnel displacement and surface displacement can be greatly reduced. For example, if the stress release rate of surrounding rock changes from 0.8 and 0.2 to 0.4, 0.3, and 0.3, the settlement displacement of the vault can be reduced by 85.6%, and the pre-convergence displacement can be reduced by 224.5%.
- (3)
- The test results showed that a glass fiber anchor rod injected with double slurry can lead to cylindrical reinforcement with a diameter of 14 cm in silty clay. The pull-out force of a single glass fiber anchor is about 31.58 kN. When the installation spacing is less than 1 m, the pull-out force of glass fiber anchor will appear, and couples with the amplification effect.
- (4)
- When using glass fiber anchors to reinforce the advanced core soil, it is more reasonable to choose the upper sparse and lower dense reinforcement method (where the reinforcement density of the upper-half section is 1.5 × 1.5 m and the reinforcement density of the lower-half section is 1.0 × 1.0 m). This can not only reduce the material cost, but also shorten the construction time of the reinforcement tunnel face.
- (5)
- The use of prefabricated initial supports represents a development trend in tunnel support construction technology in the future. This type of support can quickly be closed to provide support resistance, and the bearing mode is thus changed from line support to face support.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
- Wang, M.S. Construction method of shallow buried excavation in Beijing Metro. Chin. J. Rock Mech. Eng. 1989, 1, 52–62. [Google Scholar]
- Tan, Z.S. Construction concepts and key technologies for tunnel and underground engineering—A celebration of main academic thoughts and achievements of Academician WANG Mengshu. Hazard Control Tunn. Undergr. Eng. 2019, 1, 1–6. [Google Scholar]
- Lunardi, P.; Barla, G. Full face excavation in difficult ground. Geomech. Tunn. 2014, 7. [Google Scholar] [CrossRef]
- Lunardi, P. Evolution of Design and Construction Approaches in the Field of Tunnelling: The Results of Applying ADECO-RS When Constructing Large Underground Works in Urban Areas. Procedia Eng. 2016, 165. [Google Scholar] [CrossRef]
- Prisco, C.; Flessati, L.; Frigerio, G.; Castellanza, R.; Caruso, M.; Galli, A.; Lunardi, P. Experimental investigation of the time-dependent response of unreinforced and reinforced tunnel faces in cohesive soils. Acta Geotech. 2018, 13. [Google Scholar] [CrossRef]
- Horn, M. Horizontaler Erddruck auf senkrechte Abschlussflahen von Tunneln. In Landeskonferenz der Ungarischen Tiefbauindustrie; Deutsche überarbeitung STUVA: Düsseldorf, Germany, 1961. [Google Scholar]
- Jancsecz, S.; Steiner, W. Face support for a large mix-shield in heterogeneous ground conditions. In Tunnelling’94; Springer: Boston, MA, USA, 1994; pp. 531–550. [Google Scholar]
- Li, H.Y. Stability analysis of shallow tunnel face under pure clay condition. J. Rail. Sci. Eng. 2020, 17, 3150–3156. [Google Scholar]
- Chen, Z.; He, P.; Yan, D.M.; Gao, H.J.; Nie, A.X. Upper limit analysis of stability limit of tunnel face under advanced support. Rock Soil Mech. 2019, 40, 2154–2162. [Google Scholar]
- An, Y.L.; Li, J.H.; Cao, Q.; Yue, J. Influence of footage on stability of tunnel face based on limit analysis. J. Rai. Sci. Eng. 2019, 16, 443–449. [Google Scholar]
- Du, J.; Mei, Z.R.; Fu, L.L.; Chen, Y.C. Study on face stability of shallow tunnel with weak surrounding rock based on strength reduction method. Mod. Tunn. Technol. 2020, 57, 51–57. [Google Scholar]
- Wang, X.Y.; Li, K.; Wang, L.J.; Zheng, W.H.; Wang, X.D. Study on limit support pressure of tunnel face in soft surrounding rock. J. China Rail. Soc. 2019, 41, 110–117. [Google Scholar]
- Duan, L.Y. Study on Displacement Law of New Tunnel Passing through Existing Subway Structure in Beijing Area. Master’s Thesis, Beijing Jiaotong University, Beijing, China, 2017. [Google Scholar]
- Zhao, K. Study on Optimization of Metro Station and Bridge Crossing Scheme. Master’s Thesis, Beijing Jianzhu University, Beijing, China, 2018. [Google Scholar]
- Ke, C.J. Analysis on Displacement Characteristics of Urban Tunnel Undercrossing Existing Lines with Different Structures. Master’s Thesis, Beijing Jiaotong University, Beijing, China, 2018. [Google Scholar]
- Tao, L.J.; Tian, Z.W.; Che, Y.W.; Chen, X. Micro displacement control technology of mining method tunnel under existing shield tunnel. Rail. Eng. 2017, 5, 67–70. [Google Scholar]
- Yang, Z.-Y.; Jiang, Y.S.; Yan, Z.G. Analysis on Settlement Law of shield tunneling under metro operation. J. Xi’an Univ. Sci. Technol. 2014, 34, 268–273. [Google Scholar]
- Wang, S.M. Study on Risk Control Measures for Shield Tunneling under Existing Subway in Beijing. Master’s Thesis, Beijing Jiaotong University, Beijing, China, 2014. [Google Scholar]
- Hou, G.Y.; Liu, H.Y.; Li, J.J.; Gao, R.Z.; Wang, Q.; Zhang, M.D. Numerical analysis of subway tunnel construction process based on excavation unloading effect. J. Rock Mech. Eng. 2013, 32, 2915–2924. [Google Scholar]
- Zhang, J.W.; Mei, Z.R. Study on strengthening mechanism of tunnel face strengthened by fully bonded bolt. Tunn. Constr. 2010, 30, 161–165. [Google Scholar]
Number | Metro Name | Tunnel Depth/(m) | Geological Conditions | Engineering Features | Construction Method |
---|---|---|---|---|---|
1 | Tunnel from An Deli North Street to Gulou Street of line 8 | 18 | Silty clay, silty fine sand | Underpass at Gulou Street Station (line 2) | Shield method |
2 | Tunnel from Mu Xiyuan south to the Da Hongmen section of line 8 | 23.7 | Sandy cobble | Underpass at line 10 | Step method |
3 | Tunnel from Futong to the Wangjing section of line 14 | 17.8 | Silty clay | Underpass at the tunnel between Wangjing and Wangjing West (line 15) | Shield method |
4 | Tunnel from Jiu Longshan to Da Wang Road of line 14 | 26.5 | Silt, medium-coarse sand | Underpass at the tunnel from Dawang Road to Sihui (line 1) | Shield method |
5 | Tunnel from National Library to Er Ligou of line 16 | 18.7 | Sandy pebble and silty clay | Underpass at metro lines 4 and 9 | Step method |
6 | Tunnel from Yu Yuantan East Gate Station to Mu Xidi Station of line 16 | 20~23 | Conglomerate and mudstone | Underpass at the municipal rainwater pipeline | Step method |
7 | Interval tunnel of Ci Qu Station of line 17 | 16 | Clay silt and silt | Underpass at the power and communication pipelines | Step method |
8 | West extension interval of the airport line | 13.7 | Silty clay, silty fine sand | Underpass at Dongzhimen Station (line 2) | Cavern-pile method |
9 | Tunnel from Qinghe Station to Shang Qingqiao Station | 8.5~23.2 | Fine sand, silt and pebble | Underpass at the municipal pipeline | Shield method |
Stratum | Compression Modulus/MPa | Poisson’s Ratio μ | C/kPa | Φ/° | γ/kN/m3 |
---|---|---|---|---|---|
Silty clay | 7 | 0.4 | 20 | 15 | 19.8 |
Name | Thickness/(m) | Density/kg/m3 | Elastic Modulus/GPa | Poisson’s Ratio μ |
---|---|---|---|---|
Initial support | 0.25 | 2481.3 | 24.2 | 0.2 |
Condition | Description |
---|---|
1 | Without pre-restraint and pre-support measures, the stress release rate values of the surrounding rock were 0.8 and 0.2, respectively. |
2 | Reinforcing the core soil, the stress release rates of the surrounding rock were 0.8 and 0.2, respectively. For grade-IV surrounding rock, the E, u, C, and φ values were 2 GPa, 0.32, 450 kPa, and 33°, respectively |
3 | By changing the stress release rate of surrounding rock to simulate different initial support times, the stress release rate values of the surrounding rock were 0.8 and 0.2, or 0.4, 0.3 and 0.3. |
Name | Elastic Modulus/GPa | Diameter/mm | Tensile Strength/MPa | Shear Strength/MPa |
---|---|---|---|---|
Glass fiber anchor | 40 | 25 | 700 | 150 |
Group Number | Pull out Resistance/kN | Average Value/kN | ||
---|---|---|---|---|
A | A1 | 27.54 | 25.42 | |
A2 | 25.32 | |||
A3 | 26.41 | |||
B | B1 | 31.75 | 31.58 | |
B2 | 32.43 | |||
B3 | 30.57 | |||
C | C1 | C1-1 | 41.11 | 41.55 |
C1-2 | 40.32 | |||
C1-3 | 39.86 | |||
C1-4 | 44.90 | |||
C2 | C2-1 | 37.58 | 38.47 | |
C2-2 | 38.86 | |||
C2-3 | 37.63 | |||
C2-4 | 93.79 | |||
C3 | C3-1 | 32.16 | 30.91 | |
C3-2 | 31.58 | |||
C3-3 | 28.67 | |||
C3-4 | 31.21 |
Condition | Description |
---|---|
1 | Uniform reinforcement, density of 1.0 × 1.0 m, 28 pieces in total |
2 | Non-uniform reinforcement. The upper half section reinforcement density was 1.5 × 1.5 m with 4 pieces; the lower half section reinforcement density was 1.0 × 1.0 m with 18 pieces. Total: 22 pieces. |
3 | Uniform reinforcement, density of 1.5 × 1.5 m. Total: 17 pieces. |
Condition | Description |
---|---|
1 | The reinforcement length is 30.5 m and the remaining length is 0.5 m. |
2 | The reinforcement length is 31 m and the remaining length is 1.0 m. |
3 | The reinforcement length is 31.5 m and the remaining length is 1.5 m. |
4 | The reinforcement length is 32 m and the remaining length is 2 m. |
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Zhang, Z.; Huang, M.; Yu, C.; Fu, X. Study on the Face Stability of a Metro Tunnel in a Silty Clay Layer Constructed Using the Full-Face Method. Symmetry 2021, 13, 1069. https://doi.org/10.3390/sym13061069
Zhang Z, Huang M, Yu C, Fu X. Study on the Face Stability of a Metro Tunnel in a Silty Clay Layer Constructed Using the Full-Face Method. Symmetry. 2021; 13(6):1069. https://doi.org/10.3390/sym13061069
Chicago/Turabian StyleZhang, Zhien, Mingli Huang, Chunbo Yu, and Xiaojian Fu. 2021. "Study on the Face Stability of a Metro Tunnel in a Silty Clay Layer Constructed Using the Full-Face Method" Symmetry 13, no. 6: 1069. https://doi.org/10.3390/sym13061069
APA StyleZhang, Z., Huang, M., Yu, C., & Fu, X. (2021). Study on the Face Stability of a Metro Tunnel in a Silty Clay Layer Constructed Using the Full-Face Method. Symmetry, 13(6), 1069. https://doi.org/10.3390/sym13061069