Under the modern and complicated urban environment, clarifying the interaction mechanism and mutual influence mechanism between the urban tunnel and the surrounding environment is of considerable significance to the construction and operation of the tunnel. To understand and grasp the excavation-induced disturbance range and mechanism of adjacent pipeline jacking group on surrounding soils, this paper carries out relevant researches. Based on a case history of a three-hole parallel adjacent jacking pipeline in shallow overburden, a field test and assessment are performed. By setting monitoring points around the monitoring section, the earth pressure and water pressure under different buried depths and different spacing are monitored. For further discussion, the general law of soil disturbance around single-hole, double-hole, and three-hole jacking is investigated, the calculation method of lateral disturbance range and overlapping area range of pipe jacking group is deduced, and the degree of soil disturbance is evaluated as well. The results show that there will be different degrees of disturbance superposition in parallel multihole jacking due to the influence of the spacing, and the disturbance intensity is greatly affected by the parallel distance and buried depth.
Pipe jacking technology is an underground pipeline construction method developed after shield tunnel. With its advantages of low comprehensive cost, high construction efficiency, and uninterrupted to urban traffic, it is widely used in municipal pipelines, underground pedestrian passageways, subways, and comprehensive pipe gallery. Due to the use of trenchless excavation technology, the surrounding soils are inevitably disturbed, which will lead to unloading or loading and other complex mechanical behaviors of the soil, resulting in changes in stress and strain of surrounding soils and even endangering the safety of adjacent buildings and underground pipelines, causing a series of environmental geotechnical problems. Therefore, the mechanism of soil disturbance caused by excavation has been the focus of scholars and engineering applications [
Some theoretical research studies, field tests, and laboratory tests on soil disturbance caused by pipe jacking excavation have been conducted, and the corresponding evaluation methods and indicators have been studied as well. During pipe jacking excavation, due to the extrusion of jacking force, cutting shear force of the microtunnel boring machine (MTBM) head, and vibration load, the soils near the working face will have different degrees of disturbance in different areas. Fang et al. proposed the concept of soil disturbance zone division in pipe jacking construction [
Cavity expansion methods in geomechanics are a classic problem, which was widely used in stress-strain problems such as tunnel excavation, bolt support, shaft sinking, and in situ tests such as static CPT [
At present, the research studies on soil disturbance mechanism mainly focus on single pipe jacking or parallel pipe jacking. The research on soil disturbance mechanism and field measurement of adjacent pipe jacking group is scarce. When there are more than two pipes excavating in sequence, what kind of disturbance effect will happen, whether there will be disturbance overlapping, and what is the relationship between the disturbance intensity and the center spacing of pipeline group and buried depth. These are the topics worthy of further study and discussion. Different from the previous researches, the disturbance effect of pipe jacking group adjacent excavation on surrounding soil would pay more attention to the soil disturbance perpendicular to the jacking direction, so the transverse disturbance range of soil will be focused on. Taking a practical three-hole parallel adjacent jacking in the drainage project of Meilan International Airport in Haikou as the engineering background, the disturbance effect of pipe jacking group adjacent excavation on surrounding soil is investigated, which would provide an engineering reference for similar projects.
For the convenience of the problem analysis, we make the following assumptions: (1) the material and section specification of the pipeline segment in the pipe jacking group are identical; (2) the jacking pipes of each hole are excavated in sequence, and the jacking speed is suitable and consistent; (3) the soil is homogeneous isotropic elastic-plastic cohesionless material, and the soil obeys the Mohr–Coulomb yield criterion. And the lateral disturbance range of single-hole excavation, double-hole excavation, three-hole excavation will be analyzed separately.
During single-hole pipe jacking, friction resistance is generated between the shell of MTBM and the surrounding soil, which makes the soil around the shell shear disturbance. At the same time, the horizontal excavation of pipe jacking will cause shear disturbance on the soil in the front of MTBM and excavation unloading on the soil upper front MTBM. Therefore, the horizontal excavation of single-hole pipe jacking will produce soil disturbance in a certain range perpendicular to the jacking direction.
Based on the field measurement and the theory of small hole expansion, the calculation method of the radius of plastic shear disturbance zone is given in the literature [
Mechanical model of cylindrical hole expansion.
Referring to
The soils around the cylindrical hole satisfy the differential equation of stress balance according to the cavity expansion method:
The geometric and physical equations in the elastic region can be expressed as
Combining equations (
According to the basic assumption 3, the soil outside the hole obeys the Mohr–Coulomb criterion without considering the cohesion, and its yield criterion can be expressed as
The stress in the plastic zone satisfies both the differential equation of stress equilibrium and the Mohr-Coulomb criterion. Substituting equation (
In the meanwhile, the soil in elastic zone also satisfies the Mohr–Coulomb criterion, by substituting the yield condition (6) into the stress field equation (
The integral constant
Then, the radial stress in the plastic zone is
Therefore, the radius of the shell shear disturbance zone is
As jacking excavation, soil output, driving machine jacking, and other processes, the pipe jacking excavation will continue to disturb the surrounding soil along a certain angle to the ground. The complete boundary line on both sides will form a junction with the ground; thus, a lateral disturbance area forms, which is shown in Figure
Schematic diagram of lateral disturbance range of single-hole jacking.
According to the limit equilibrium principle, the boundary of the disturbance zone should be tangent to the shear disturbance zone, and the horizontal elevation angle of the boundary line is equal to the active earth pressure angle
Therefore, the range of horizontal disturbance caused by single-hole pipe jacking is
When the second jacking pipe excavates in sequence, the double-hole jacking pipeline will be formed. At this time, the influence of horizontal center spacing should be considered. If the center spacing between two holes is large, the second hole only produces soil disturbance near itself, and its lateral disturbance range is the same as that of single-hole jacking. If the center spacing between two holes is small, disturbance superposition will occur near the junction center of the two holes. Assuming that the center spacing of pipeline is B, it satisfies
The lateral disturbance range of the double hole is shown in Figure
Schematic diagram of lateral disturbance range of double-hole jacking. (a) The center spacing is large in double-hole excavation. (b) The center spacing is small in double-hole excavation.
The lateral disturbance range of the double hole is shown in Figure
When the third hole excavates in parallel, the influence of the lateral disturbance range is the same as that of double-hole jacking, but the jacking position of the third hole should be considered. If the third hole is jacked outside the previous two holes, it is consistent with the superposition effect of double-hole jacking, as shown in Figures
Schematic diagram of lateral disturbance range of three-hole pipeline jacking. (a) The third hole is located on the outside of the previous two holes and the center spacing is large. (b) The third hole is located on the outside of the previous two holes and the center spacing is small. (c) The third hole is located in the middle of the previous two holes and the center spacing is large. (d) The third hole is located in the middle of the previous two holes and the center spacing is small.
To effectively discharge the rainy season precipitation and municipal sewage around Meilan International Airport and the surrounding areas in Haikou, the construction method combining large-diameter adjacent pipe jacking group underground excavation with large-diameter box culvert open excavation is adopted. This project locates outside the red line of Meilan Airport phase II expansion project and passes through the nursery, industrial plants, and urban roads. The aerial view of the project is shown in Figure
Aerial view of the project.
Cross section of pipe jacking group.
Each ring of the jacking pipeline adopts circular prefabricated reinforced concrete segments with a width of 0.32 m. The inner diameter of the segment is 3.5 m and the length is 2.5 m. To effectively bore through the soft soil layer, the MTBM is used in this project, whose whole length is 5.71 m and the outer shell diameter is 4.16 m. In the meanwhile, the grouting system of synchronous grouting at the head and follow-up grouting at the pipe is adopted to ensure the jacking quality.
The strata at the construction site can be divided into three main layers and the soft subsoil is about 13.5 m thick. The water table is located at a depth of 2.3 m below the ground. The basic physical parameters and depth for these soils are given in Table
Main geotechnical parameters of soils at the construction site.
Soil layer | Depths (m) | Water content (%) | Void ratio | Cohesion (kPa) | Internal friction angle (°) |
---|---|---|---|---|---|
①plain fill | 0–3.98 | 30.4 | 0.865 | 27.9 | 16.8 |
②silty clay | 3.98–6.58 | 25.03 | 0.81 | 14.91 | 15.42 |
③coarse sand | 6.58–13.28 | 8 |
The field monitoring contents include the earth pressure and pore water pressure of the soil around the pipe jacking group. According to the site construction and environmental conditions, the monitoring section is arranged at 4 + 368.9 mileage between No. 4 shaft and No. 5 shaft. To investigate the soil disturbance around the pipe jacking group to the greatest extent, seven monitoring holes are set on the monitoring section. Among them, No. 2, No. 4, and No. 6 monitoring holes are located directly above Hole 1, Hole 2, and Hole 3, respectively. No. 3 and No. 5 monitoring holes are located at the middle of the center spacing, and No. 1 and No. 7 monitoring holes are located at the double center spacing of Hole 1 and Hole 3. Two monitoring points are set at No. 2, No. 4, and No. 6 monitoring holes, and five monitoring points are set at No. 1, No. 3, No. 5, and No. 7 monitoring holes. Earth pressure and pore water pressure gauges are arranged above and below at each monitoring point, so there are 7 monitoring holes, 26 monitoring points, and 52 stress gauges in total. The layout of the earth pressure gauge and pore water pressure gauge measuring points is shown in Figure
Distribution map of monitoring points.
Diagram of monitoring elements erection and burying.
JTM-V2000 vibrating wire earth pressure gauge and JTM-V3000 vibrating wire pore water pressure gauge are used as monitoring elements. Its working principle is that the high sensitivity induction membrane produces deflection under the action of load and changes the excited frequency of the metal string of the induction membrane. The load on the earth pressure box and pore water pressure gauge is calculated by using the sensor calibration coefficient. In this project, data acquisition adopts the combination of a 32-channel JTM-MV20A data acquisition box and hand-held JTM-10A vibrating wire sensor reader. JTM-MV20A data acquisition box monitors and records the vibration frequency of the metal string every 6 seconds, and ZLY-V1.0 intelligent acquisition cloud platform management system software transmits data online and monitors the scene.
From Nov. 10 to 21, 2019, Hole 1 passed through the monitoring section. The earth pressure and pore water pressure of No. 1, 2, 3, and 4 monitoring holes at different depths are recorded in Figures
Variation diagram of earth pressure during Hole 1 jacking. (a) Earth pressure of No. 1 monitoring hole. (b) Earth pressure of No. 2 monitoring hole. (c) Earth pressure of No. 3 monitoring hole. (d) Earth pressure of No. 4 monitoring hole.
Variation diagram of pore water pressure during Hole 1 jacking. (a) Pore water pressure of No. 1 monitoring hole. (b) Pore water pressure of No. 2 monitoring hole. (c) Pore water pressure of No. 3 monitoring hole. (d) Pore water pressure of No. 4 monitoring hole.
It can be seen from Figures
From Dec. 27 to 31, 2019, Hole 3 passed through the monitoring section. The earth pressure and pore water pressure of Nos. 4, 5, 6, and 7 monitoring holes at different depths are recorded in Figures
Variation diagram of earth pressure during Hole 3 jacking. (a) Earth pressure of No. 4 monitoring hole. (b) Earth pressure of No. 5 monitoring hole. (c) Earth pressure of No. 6 monitoring hole. (d) Earth pressure of No. 7 monitoring hole.
Variation diagram of pore water pressure during Hole 3 jacking. (a) Pore water pressure of No. 4 monitoring hole. (b) Pore water pressure of No. 5 monitoring hole. (c) Pore water pressure of No. 6 monitoring hole. (d) Pore water pressure of No. 7 monitoring hole.
It can be seen from Figures
From Apr. 10 to 15, 2020, Hole 2 passed through the monitoring section. The earth pressure and pore water pressure of Nos. 2, 3, 4, 5, and 6 monitoring holes at different depths are recorded in Figures
Variation diagram of earth pressure during Hole 2 jacking. (a) Earth pressure of No. 2 monitoring hole. (b) Earth pressure of No. 3 monitoring hole. (c) Earth pressure of No. 4 monitoring hole. (d) Earth pressure of No. 5 monitoring hole. (e) Earth pressure of No. 6 monitoring hole.
Variation diagram of pore water pressure during Hole 2 jacking. (a) Pore water pressure of No. 2 monitoring hole. (b) Pore water pressure of No. 3 monitoring hole. (c) Pore water pressure of No. 4 monitoring hole. (d) Pore water pressure of No. 5 monitoring hole. (e) Pore water pressure of No. 6 monitoring hole.
It can be seen from Figures
From the field test data, it can be seen that when the head of MTBM excavates through the monitoring section in sequence, the stress field of soil around the monitoring section fluctuates in varying degrees with the change of the horizontal jacking distance, and the change laws of soil pressure and pore water pressure are completely consistent. The horizontal jacking distance affect not only the soil disturbance but also the spacing of pipeline group and buried depth. Therefore, it is necessary to deeply analyze the lateral soil disturbance range and the soil disturbance degree of single-hole, double-hole, and three-hole jacking.
In this project, the pipeline group excavates in sequence, and the third hole excavates in the middle of the previous two holes, whose construction sequence is the same as that in Figure
Calculation table of lateral disturbance range and overlapping range.
Jacking sequence | Weighted value of internal friction angle | The horizontal elevation angle of the boundary line (°) | The radius of disturbance zone (m) | Disturbance criteria | Lateral disturbance rang (m) | Overlapping area range (m) |
---|---|---|---|---|---|---|
Hole 1 | 16.8 | 52 | 2.47 | |||
Hole 3 | ||||||
Hole 2 |
Calculation map of lateral disturbance range and overlapping range. (a) Hole 1 excavates. (b) Hole 3 excavates. (c) Hole 2 excavates.
It can be seen from the table and figure that when Hole 1 excavates, its lateral disturbance range is 15.4 m and its disturbance can affect the earth pressure and pore water pressure at No. 1, 2, 3, and 4 monitoring holes, when Hole 3 excavates, its lateral disturbance range is 15.4 m and its disturbance can affect the earth pressure and pore water pressure at Nos. 4, 5, 6, and 7 monitoring holes, and when Hole 2 excavates, disturbance overlapping appears due to the small center spacing, its overlapping area range is 8.08 m, and its disturbance can affect the earth pressure and pore water pressure at Nos. 2, 3, 4, 5, and 6 monitoring holes. And the theoretical calculation results are consistent with the above field test data.
Based on the field test data, with the help of disturbance evaluation method, the disturbance degree of soil can be analyzed [
When the three holes excavate in turn, the monitoring points under the same buried depth are taken to analyze the soil disturbance degree of different lateral spacing, and the results are shown in Figure
Degree of soil disturbance under different lateral spacing. (a) Hole 1 excavates. (b) Hole 3 excavates. (c) Hole 2 excavates.
Take the soil disturbance degree analysis of No. 4 monitoring hole under different buried depths, and the results are shown in Figure
Degree of soil disturbance under different buried depth. (a) Hole 1 excavates. (b) Hole 3 excavates. (c) Hole 2 excavates.
Comparing the soil disturbance degree of monitoring point 3-1 when Hole 1 and Hole 2 excavate through, respectively, the disturbance overlap effect of double-hole jacking can be obtained, and the result is shown in Figure
Analysis chart of double-hole overlap disturbance degree.
It can be seen that, in the double-hole disturbance overlap area, the soil disturbance caused by the second hole is larger than that caused by the first hole, but the disturbance intensity is smaller. This is because the soil structure is more loose when the second hole excavates, and the disturbance caused by the loading and unloading of the soil during jacking is less obvious than that of the original soil before.
Combining theory analysis with field test, the effect of soil disturbance in the vertical direction of pipe jacking group and its interaction are mainly discussed in this paper. Based on the actual project, the following conclusions are obtained: The horizontal jacking of pipe jacking is regarded as the problem of cavity expansion in finite medium in this paper. Based on the cylindrical hole expansion model, the calculation formula of the plastic zone disturbance radius of soil is deduced. Furthermore, according to the limit equilibrium principle, the calculation formula of the transverse disturbance range caused by single-hole jacking construction is established. The influence of center spacing between two holes and the jacking position on the lateral disturbance range of soil in double-hole and three-hole jacking construction is analyzed and discussed. If the center spacing is large, the soil disturbance only occurs around the plastic disturbance area of each pipe. If the center distance is small, the disturbance superposition will occur. The calculation formulas of the critical value of the center spacing and the lateral overlapping area range in double-hole and three-hole jacking are established. The disturbance superposition mechanism of three-hole excavation is the same as that of double-hole excavation, but the influence of jacking position should be considered. When the third hole is located outside the previous two holes, its disturbance superposition effect is the same as that of double-hole excavation. When the third hole is located in the center of the two holes, if the center distance is small, there will be secondary disturbance superposition. The conclusion of theoretical analysis is the same as that of field test, which proves the rationality of theoretical solution effectively. With the help of the pore water pressure measured in the field test, the disturbance degree of the soil during the multihole jacking is further analyzed. From the analysis results, in the case of single-hole, double-hole, and three-hole jacking, the deeper the buried depth and the closer to the pipe, the greater the soil disturbance. At the same time, affected by the soil structure, the disturbance degree of the soil on the top of the pipe jacking is larger than that on the side, and the disturbance degree of the second hole is larger than that of the first hole, but the degree is not as severe as before.
The field data in this paper are collected and sorted by field measurement, which is mainly used to verify the theoretical prediction. All data generated or analyzed during this study are included in this article.
The authors declare that there are no conflicts of interest regarding the publication of this paper.
The authors acknowledge the financial support provided by the National Natural Science Foundation of China (nos. 51874005 and 51778004) and the Science Research Foundation for Young and Middle-Aged Academic Backbones in Anhui University of Science and Technology.