Study on Deformation Law of Subway Construction under Passing Existing Line in Short Distance

With the large-scale development and utilization of underground space projects, the subway-led Rail Transit Project is developing vigorously, and the safety and stability of subway under passing existing projects have become a key issue for the future. In this paper, the deformation law of subway tunnel under the existing track is studied by using the method of ROCSCIENCE software and field measurement, which is based on the construction of a new double-tunnel shield-driven subway tunnel under the existing city of pile rapid track project. In the crossing area, the distance between the top of the tunnel and the pile foundation is 6.2 m and the distance between the tunnel and the existing track surface is 19.6 m. It is required that the settlement of track caused by the new tunnel construction should not exceed 2 mm. The results show that the settlement of the existing track is greatly influenced by the new tunnel without reinforcement and grouting, and the maximum settlement is more than 9.92 mm. The settlement of the existing track can be controlled to 1.93 mm by adjusting the construction parameters of the shield machine and grouting reinforcement at different stages during construction.


Introduction
With the rapid development of urban rail transit, the urban overground and underground transportation network is becoming more and more intensive, and the distance between adjacent buildings is getting closer and closer, which will inevitably cause disturbance to the ground in the process of subway construction, safety, and environmental impacts on adjacent structures. In recent years, there are a lot of projects near the subway, especially the project of the subway passing through the existing project at close range, and many scholars have done a lot of research on the ground stability caused by the subway construction [1][2][3][4]. Lueprasert et al. [5] studied the deformation of the tunnel under crossloading pile-soil-tunnel interaction. Namazi et al. [6] studied the effects of double-tunnel excavation on underground passages. Sirivachiraporn and Phienwej [7] studied the effect of Metro Shield tunneling on nearby buildings. Pan et al. [8] carried out the safety and stability analysis of shield tunnel under the existing subway. Yang et al. [9] studied the effect of Double Line Shield tunnel construction technology on the frame structure. Guan et al. [10] analyzed the influence factors of the double-track tunnel passing through the existing track line in a short distance. Yang et al. [11] studied the effect of shield construction on the settlement of an existing subway tunnel. Zhang et al. [12] carried out the reinforcement optimization design for the Metro Shield tunneling under the existing railway; Lv et al. [13] studied the evaluation and treatment of the subway tunnel passing under the bridge at a short distance; Zhang [14] Studied the construction of a new subway tunnel to pass under the operating subway tunnel at a short distance; Yang and Wang [15] carried out a study on the settlement control of the tunnel passing through the subway station closely; Zhang et al. [16] carried out the deformation analysis of the adjacent Metro Shield tunnel; Liao et al. [17] studied the construction disturbance and control of subway tunnel passing through under the highway for a long distance. Most of the previous studies have investigated the effect of disturbance of a tunnel passing through a subway at a short distance by the numerical simulation [18][19][20][21].
In order to control the deformation of the adjacent buildings in subway construction, grouting has become an effective measure to control the deformation. In order to prevent the floating deformation of the existing structure under the shield excavation, Qi et al. [22] reinforced the soil within the span of the existing tunnel by grouting. Wu et al. [23] studied the effect of full-section grouting parameters on tunnel stability and reinforcement quality. Wu et al. [24] used grouting to reinforce the tunnel with a depth of 9M, the reinforcement effect is good in the range of 2 M, and the deformation and failure can be controlled effectively. Li and Yuan [25] have studied the construction of a shield machine with a diameter less than 7 M, which can effectively control the settlement of the existing tunnel within 15 mm by compensating grouting. Bai et al. [26] established the extension theory model to evaluate the grouting effect of the water-rich sand bed. Zhu et al. [27] studied the effect of grouting rate on formation reinforcement in high-pressure jet grouting. Many scholars have studied the applicable conditions and reinforcement quality of high-pressure jet grouting. [28][29][30][31].
In the past, there was little research on subway tunnel construction under passing the urban rapid rail transit at a large angle. ere is little research on grouting reinforcement in the whole process of large section shield tunnel. Based on the typical example of new large section shield tunnel construction under passing the existing line in a short distance, the whole process of grouting reinforcement in different stages of a new tunnel is simulated by using finite element software. In order to control the settlement deformation of urban fast track subgrade and track, grouting is used in three important construction stages of the tunnel. By analyzing the deformation law of existing railway track and subgrade, and comparing and analyzing the field monitoring data and numerical simulation results, the reliability of the model and the reinforcement effect of grouting reinforcement are verified, which provides a reference for similar projects.

Engineering
Overview. e newly built subway tunnel is a double-tunnel single-track tunnel with a length of 3657 m and the thickness of overburden soil is 17.9 m. e tunnel is constructed by a slurry shield machine with a diameter of 10.9 m, the inner diameter of the tube slice is 9.5 m, the outer diameter of the tube slice is 10.5 m. e newly built subway tunnel runs under the existing track line at the range DK45 + 210 to DK45 + 290. e newly built tunnel cuts through the existing line at a large angle, which increases the cross distance and the construction difficulty. e cross area has high stratum sensitivity and the distance between shield machine and CFG pile is 6.2 m, which brings a severe challenge to construction. e settlement of the tunnel under the existing track is not more than 2 mm; otherwise, if the settlement is exceeded, the fast track will stop automatically. e horizontal and vertical relationship between the new tunnel and the existing track line is shown in Figures 1 and 2.

Engineering Geological Conditions.
ere are miscellaneous fill, silty soil, fine sand, clay soil, and sandy soil in the area where the shield tunnel is located. e main structure of the new tunnel is in clay soil. e vertical relationship between the shield tunnel and the engineering geological conditions is shown in Figure 3.

Test Section
Setting. Before the shield tunneling, a test section of shield construction is set up. e test section mileage is DK45 + 000 ∼ DK45 + 200 and the length is 200 m. e construction parameters and reinforcement measures are optimized and adjusted through the construction of the test section.

Monitoring Point Arrangement.
According to the evaluation report and design requirements, the vertical settlement value of the newly built subway tunnel shield under the existing track cannot be greater than 2 mm. In order to ensure that the construction does not have a significant impact on the existing track, the strata and existing orbits need to be monitored and set an early warning limit. According to the construction requirements, it should monitor the existing track 120 m range of strata, subgrade, and track. e monitoring site layout is shown in Figure 4.

Reinforcement and Repair Scheme.
In order to control the deformation of stratum and building (structure), in addition to adjusting the parameters of shield tunneling, grouting is adopted in different construction stages. According to the whole construction process, grouting reinforcement was carried out in different stages, including ground grouting reinforcement, dynamic compensation grouting, following grouting after passing through, and secondary grouting of tube pieces.

Ground Advance Grouting Reinforcement.
Pregrouting pipe is used to reinforce the ground in the cross area before the shield crossing the existing line. ere are 6 rows and 4 rows of 42 sleeve valves on both sides of the existing line. e sleeve valve tube length is 16-22 m. e grouting distance is 50-100 cm, the grouting speed is 10-100 L/min, and the grouting pressure is controlled at 0.4-1.0 MPa.

Dynamically Compensated Grouting.
e synchronous dynamic compensation grouting should be carried out during the tunneling of the shield machine, which combines the synchronous grouting of the shield machine with the tracking compensation grouting. Cement and water glass double liquid slurry is used for grouting. e grouting pressure should be controlled within 0.5 MPa.

Following Grouting after Passing through.
In order to prevent the settlement of the shield tail, grouting reinforcement should be carried out after the shield machine passes through. e grouting step is 50 ∼ 100 cm and the grouting speed is 10 ∼ 100 l/min. e grouting interval is 24 h with step-back grouting.

Secondary Grouting of Tube Pieces.
e special segments with 25 grouting holes in each ring are selected to reinforce the secondary deep hole grouting in the main influence area of shield tunneling. e length of grouting pipe embedded in the secondary grouting holes of each ring is 3 m.

Numerical Modeling
In order to predict the possible engineering disasters during the construction period, this paper simulates the influence of subway tunnel underpass construction on the stratum and track.
e numerical simulation can provide the scheme design and parameter optimization for the construction, so as to reduce the disturbance and damage of the upper building caused by shield construction.

Model Building.
In combination with the actual situation of this project, the ROCSCIENCE analysis software is selected to establish the numerical model, as shown in Figure 5.

Parameter Selection.
e parameters of each soil layer in the model are selected and confirmed according to the engineering geological survey data. In the numerical model, the soil is considered an ideal elastoplastic material. Hence, the constitutive relationship can be described by the modified Mohr-Coulomb constitutive mode. e soil layer and structure parameters required for the numerical simulation are shown in Table 1. e calculating parameters of structural elements are shown in Table 2.

Construction Procedures.
In order to reduce the influence of the double-tunnel undercrossing on the existing track above, the double-tunnel was excavated by staggered excavation. e left and right tunnels are not constructed at the same time. e left-line tunnel is constructed first, and the right-line tunnel is constructed after the left-line tunnel has passed through the existing line. e construction procedure is shown in Figure 6. According to the numerical simulation analysis before construction, the new double-tunnel tunnel will have great influence if it passes through the existing line completely without any support. e maximum ground settlement reaches 9.89 mm, which exceeds the engineering limit requirement. e maximum horizontal displacement reaches 4.24 mm.

Results and Analysis
When a large-diameter shield machine is used for construction in a shallow depth, it will disturb and destroy the adjacent pile foundation and stratum.
e advance settlement will occur in the front during construction and excavation. e shield machine passing through the intersecting area will cause the deformation and settlement of the rock and soil layer. When the shield passes through, there will be large settlement deformation in the tail of the shield and later period of excavation. e sensitivity of strata in this area is high, and it is easy to produce deformation and failure under construction disturbance. e large angle intersection of the two lines and the increase of the intersection distance cause the complicated alternation of the soil layer structure, which is easy to be deformed and destroyed. ese aspects are the main factors leading to the large deformation in the region. During the construction, reinforcement must be taken to control the deformation of the ground and upper track within 2 mm.  In order to control the deformation of the stratum and superstructure caused by shield construction, we adopted grouting reinforcement measures. By adjusting the attitude of the shield machine and grouting reinforcement in each stage, the deformation and failure of the stratum and superstructure are effectively controlled. e settlement and deformation of the subgrade and track are shown in Figure 9.
As can be seen from Figure 9, the settlement deformation has been effectively controlled by comprehensive measures such as ground reinforcement before shield tunneling, simultaneous grouting during tunneling, grouting around shield tunneling, and adjustment of shield attitude. e settlement deformation of the existing track is 1.93 mm in the shield construction, which is controlled within the construction deformation of 2 mm to meet the construction requirements and ensure that the shield underpass has no influence on the operation of the existing track.    As can be seen from Figures 10 and 11, the left-hand side shield will cause larger ground settlement, with the maximum settlement able to reach 8.46 mm and the influence range mainly about 50 meters from the centerline of the tunnel. When the right line shield goes through, the accumulative settlement will occur, and the maximum settlement depth can reach 9.92 mm. e factors and reasons of ground surface deformation are obtained by shield construction in the test section. ere are five stages of settlement in shield tunneling; they are first settlement, settlement in front of excavation, through settlement, settlement in the gap of shield tail, and later settlement. e settlement time curves produced by the passing of the left and right line shield are shown in Figures 12 and  13. e settlement ratios of the two cross sections are shown in Figures 14 and 15.
According to Figure 12, the main influence area is within 25 m of the middle line, when the left line of the shield passes through the cross section. In this range, the accumulative settlement is larger, especially in the upper position of the centerline of the left line, and the accumulative settlement is close to 8 mm. As can be seen from Figure 13, when the right line passes through the cross section, it will cause secondary disturbance to the left line, resulting in the ground settlement above the left line being greater than the right line. e settlement on the left line is close to 10 mm.
As can be seen from Figure 14, when the left line of the shield passes through the cross section area, the settlement generated is mainly the settlement in front of the development face, the settlement through the settlement, and the settlement in the void of the shield tail. As can be seen from Figure 15, when the right line of the shield passes through the cross section area, the settlement generated is mainly through the settlement and the clearance of the shield tail. e whole process of shield machine crossing the crossing area is the main factor that causes the deformation of stratum and superstructure, so controlling the construction process of shield machine is the main section to ensure the  Advances in Civil Engineering 7 settlement of the upper track and subgrade. We must carry on the reinforcement processing to the shield construction entire process.

Analysis of Grouting Reinforcement
Effect. e influence of shield construction on settlement deformation of track and subgrade is reduced by grouting reinforcement in different stages and links. e settlement time curves produced by the passing of the left and right line shield are shown in Figures 16 and 17. e settlement ratios of the two cross sections are shown in Figures 18 and 19.
As can be seen from Figures 16 and 17, the settlement of the surface and superstructure is controlled within 2 mm by grouting reinforcement and adjusting the parameters of the shield machine in each stage. As can be seen from Figures 18  and 19, when the left and right lines pass through, the settlement deformation is mainly concentrated in the last   Advances in Civil Engineering three stages. In particular, the through settlement and clearance settlement of shield tail are more obvious. By grouting reinforcement, the settlement at the later stage is reduced greatly.
According to the results of numerical simulation and the construction test of the test section, we adjust and optimize the construction scheme. During the construction of subway shield tunneling, the track and subgrade are monitored on

Advances in Civil Engineering
site. e settlement curve of the subgrade and track structure is shown in Figures 20-22.
As can be seen from Figures 20-22, the settlement of subgrade structure and track is less than 2 mm after grouting and other reinforcement measures.
For the influence of the construction of the existing track line, the left tunnel constructed first will have a great influence on the existing line, while the right tunnel constructed later will have a superposition influence, and the right tunnel constructed will have repeated and accumulative settlement. By adjusting the parameters of the shield machine and the synchronous grouting, the settlement deformation of the small distance shield under the existing line can be effectively controlled.

Comparison of Numerical Simulation and Monitoring
Results. In this paper, the influence of shield construction  Advances in Civil Engineering on the deformation of the existing track is studied by numerical simulation and field monitoring. e comparison between numerical simulation and field monitoring is shown in Table 3.
e settlement value and settlement trend of the existing track structure are basically the same as those of the roadbed structure. e maximum settlement of track and subgrade is located directly above the left-line tunnel when the left-line tunnel crosses the cross section. After the construction of left-right line tunnel, the maximum settlement of the track subgrade is 9.92 mm, which is located in the middle of the left-right line tunnel. e maximum settlement of track and subgrade is 1.82 mm by adjusting the attitude of the shield machine and grouting reinforcement in each stage, which meets the construction standards and requirements. e results of numerical simulation and field monitoring are basically consistent with an error of 5.6%. e numerical simulation results can provide a reference for field

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Advances in Civil Engineering construction, parameter adjustment, and optimization of the basis.

Conclusions
By means of numerical analysis and on-site monitoring, the disturbance law of the double-tunnel tunnel passing through the existing track project with small spacing is explored and the settlement deformation of the existing track is effectively controlled by adjusting the parameters of the shield machine and synchronous grouting reinforcement. e main conclusions are as follows: (1) e settlement value and settlement trend of the existing track structure are basically the same as those of the roadbed structure. e maximum settlement of track and subgrade is located directly above the leftline tunnel when the left-line tunnel crosses the cross section. When the double-line tunnel crosses the cross section, the maximum settlement is located in the middle area of the two tunnels. (2) In the process of settlement analysis, the maximum settlement is 9.89 mm by numerical calculation and 9.92 mm by field monitoring. e results are close to each other and the margin of error is 5.6%. e numerical results can provide the design reference for construction.
(3) e construction of a double-line tunnel will produce a superposition effect, and the right-line tunnel will produce a secondary settlement in the left-line tunnel area. An alternative construction of the left and right tunnels can effectively reduce surface settlement. (4) By adjusting the parameters of shield machine and ground grouting reinforcement and dynamically compensating grouting and following the synchronous grouting at different stages after passing through the grouting and the secondary grouting of segments, the settlement deformation can be effectively controlled within 2 mm, and the requirements of the construction can be met.
In future research, pressure and displacement sensors can be installed at the interface of pile and soil to monitor the internal force and displacement of pile foundation. In view of the tunnel construction process, further analysis of the internal force of pile-soil and the displacement will be made.

Data Availability
e data used to support the findings of this study are included within the article.

Conflicts of Interest
e authors declare that there are no conflicts of interest regarding the publication of this paper.  Advances in Civil Engineering 13