Author Contributions
Conceptualization, C.W.; methodology, C.W. and W.S.; software, W.S.; validation, Y.X., C.W. and W.S.; formal analysis, C.W. and W.S.; investigation, C.W., W.S. and G.W.; writing—original draft preparation, W.S. and C.W.; visualization, W.S.; writing—review and editing, C.W., Y.X. and W.S.; supervision C.W. and Y.X.; resources, G.W.; project administration, G.W. and C.W.; funding acquisition C.W. All authors have read and agreed to the published version of the manuscript.
Figure 1.
Two types of close-fitting pile–wall integrated structures (SS). (a) Superimposed structure, and (b) composite structure (CS).
Figure 1.
Two types of close-fitting pile–wall integrated structures (SS). (a) Superimposed structure, and (b) composite structure (CS).
Figure 2.
Section profile of underground structure for model test.
Figure 2.
Section profile of underground structure for model test.
Figure 5.
Modulus of elasticity test. (a) Three-point flexural test, and (b) displacement versus load curve.
Figure 5.
Modulus of elasticity test. (a) Three-point flexural test, and (b) displacement versus load curve.
Figure 6.
Scheme of strain monitoring points (unit: mm). (a) Arrangement of pile strain monitoring points, (b) arrangement of wall strain monitoring points, and (c) overview of strain monitoring sites.
Figure 6.
Scheme of strain monitoring points (unit: mm). (a) Arrangement of pile strain monitoring points, (b) arrangement of wall strain monitoring points, and (c) overview of strain monitoring sites.
Figure 7.
Preparation of model soil. (a) Production of model soil, and (b) preservation of model soil.
Figure 7.
Preparation of model soil. (a) Production of model soil, and (b) preservation of model soil.
Figure 8.
Model structure burial and monitor system installation. (a) Retaining pile model burial, and (b) monitoring system installation and commissioning.
Figure 8.
Model structure burial and monitor system installation. (a) Retaining pile model burial, and (b) monitoring system installation and commissioning.
Figure 9.
Overview of test stages. (a) Test Stage 3, (b) Test Stage 4, (c) Test Stage 7, and (d) Test Stage 8.
Figure 9.
Overview of test stages. (a) Test Stage 3, (b) Test Stage 4, (c) Test Stage 7, and (d) Test Stage 8.
Figure 10.
Lateral deformation of the pile (SS). (a) Lateral deformation of the pile in Test Stages 1 to 4, and (b) lateral deformation of the pile in Test Stages 4 to 8.
Figure 10.
Lateral deformation of the pile (SS). (a) Lateral deformation of the pile in Test Stages 1 to 4, and (b) lateral deformation of the pile in Test Stages 4 to 8.
Figure 11.
Bending moment of the pile (SS). (a) Excavation stage with Stage 4 and (b) basement construction stage.
Figure 11.
Bending moment of the pile (SS). (a) Excavation stage with Stage 4 and (b) basement construction stage.
Figure 12.
Bending moment of the basement wall (SS).
Figure 12.
Bending moment of the basement wall (SS).
Figure 13.
Finite element model. (a) Overview of meshing and (b) calculation profile diagram.
Figure 13.
Finite element model. (a) Overview of meshing and (b) calculation profile diagram.
Figure 14.
FEM modeling of the main underground structure. (a) Superimposed structure (SS) and (b) composite structure (CS).
Figure 14.
FEM modeling of the main underground structure. (a) Superimposed structure (SS) and (b) composite structure (CS).
Figure 15.
Scheme of FE simulation.
Figure 15.
Scheme of FE simulation.
Figure 16.
Lateral deformation of the pile (SS). (a) Excavation stage and (b) basement construction stage.
Figure 16.
Lateral deformation of the pile (SS). (a) Excavation stage and (b) basement construction stage.
Figure 17.
Lateral deformation of the pile comparison of the model test and FEM. (a) Excavation to −10 m and (b) basement serving stage (SS).
Figure 17.
Lateral deformation of the pile comparison of the model test and FEM. (a) Excavation to −10 m and (b) basement serving stage (SS).
Figure 18.
Bending moment of the retaining pile comparison of model test and FEM. (a) Excavation to −10 m and (b) basement serving stage (SS).
Figure 18.
Bending moment of the retaining pile comparison of model test and FEM. (a) Excavation to −10 m and (b) basement serving stage (SS).
Figure 19.
Bending moment of the wall comparison of model test and FEM (SS).
Figure 19.
Bending moment of the wall comparison of model test and FEM (SS).
Figure 20.
Bending moment of integration structures. (a) Bending moment of the pile (SS), (b) bending moment of the pile (CS), (c) bending moment of the basement wall (SS), and (d) bending moment of the basement wall (CS).
Figure 20.
Bending moment of integration structures. (a) Bending moment of the pile (SS), (b) bending moment of the pile (CS), (c) bending moment of the basement wall (SS), and (d) bending moment of the basement wall (CS).
Figure 21.
The conventional design methods of the basement retaining wall. (a) Load diagram of the continuous-beam method (unit: kN), (b) bending moment envelope diagram (unit: kN·m).
Figure 21.
The conventional design methods of the basement retaining wall. (a) Load diagram of the continuous-beam method (unit: kN), (b) bending moment envelope diagram (unit: kN·m).
Figure 22.
Bending moment of the integrated structure with different pile–wall stiffness ratios. (a) Bending moment of the basement wall (SS), (b) bending moment of the basement wall (CS), (c) bending moment of the pile (SS), and (d) bending moment of the pile (CS).
Figure 22.
Bending moment of the integrated structure with different pile–wall stiffness ratios. (a) Bending moment of the basement wall (SS), (b) bending moment of the basement wall (CS), (c) bending moment of the pile (SS), and (d) bending moment of the pile (CS).
Figure 23.
Bending moment of the integrated structure with different horizontal plate stiffnesses. (a) Bending moment of the basement wall (SS), (b) bending moment of the basement wall (CS), (c) bending moment of the retaining pile (SS), and (d) bending moment of the retaining pile (CS).
Figure 23.
Bending moment of the integrated structure with different horizontal plate stiffnesses. (a) Bending moment of the basement wall (SS), (b) bending moment of the basement wall (CS), (c) bending moment of the retaining pile (SS), and (d) bending moment of the retaining pile (CS).
Table 1.
Physical and mechanical parameters of prototype and model soil.
Table 1.
Physical and mechanical parameters of prototype and model soil.
| Unit Weight γ (kN·m−3) | Water Content ω (%) | Compressive Modulus Es (MPa) | c (kPa) | φ (°) |
---|
Prototype | 17.4~19.6 | 20~30 | 4~15 | 0~15 | 15~33 |
Expected | 17.4~19.6 | 20~30 | 0.08~0.3 | 0~0.3 | 15~33 |
Model soil | 18.2 | 20 | 0.33 | 0.1 | 26.2 |
Table 2.
The 1 g model test similitude relationship.
Table 2.
The 1 g model test similitude relationship.
Physical Quantity | Similitude Relationship | Prototype to the Model Ratio (for N = n = 50) |
---|
Acceleration | 1 | 1 |
Linear dimension | n | 50 |
Stress | N = n | 50 |
Deformation | n | 50 |
Bending stiffness | Nn4 | 505 |
Moment | Nn3 | 504 |
Table 3.
Material parameters of the structural similarity model.
Table 3.
Material parameters of the structural similarity model.
Material | Acrylic | PP | PE |
---|
Diameter (mm) | 16 | 16 | 16 |
Elastic modulus E (GPa) | 3.02 | 1.39 | 0.84 |
Table 4.
Similitude ratio of bending structural model.
Table 4.
Similitude ratio of bending structural model.
| Size (mm) | Length (mm) | (MPa·m4) |
---|
Prototypical retaining pile | Φ 800 | 30,000 | 603.18 |
Model retaining pile | Φ 16 | 600 | 2.70 × 10−6 (PE) |
Target similitude ratio | 50 | 50 | 505 |
Practical similitude ratio | 50 | 50 | 46.85 |
Prototypical basement wall | δ 500 | 10,000 (height) | 312.5 |
Model basement wall | δ 6 | 160 | 1.09 × 10−6 (Acrylic) |
Target similitude ratio | 50 | 50 | 505 |
Practical similitude ratio | 83 | 62.5 | 49.25 |
Table 5.
Similitude ratio of the compressive structural model.
Table 5.
Similitude ratio of the compressive structural model.
| Size (mm) | Length (mm) | Compressive Stiffness EsAs·L−1 (MPa·m2·m−1) |
---|
Prototypical inner support | a 800 | 20,000 (section) | 960 |
Model inner support | Φ 16 | 400 | 0.42 (PE) |
Target similitude ratio | 502 | 50 | 502 |
Practical similitude ratio | 502 | 50 | 47.82 |
Prototypical foundation plate | δ 800 | 20,000 (section) | 1200 |
Model foundation plate | δ 16 | 400 | 0.67 (PE) |
Target similitude ratio | 50 | 50 | 502 |
Practical similitude ratio | 50 | 50 | 42.32 |
Prototypical floor plate | δ 200 | 20,000 (section) | 300 |
Model floor plate | δ 2 | 400 | 0.17 (PP) |
Target similitude ratio | 50 | 50 | 502 |
Practical similitude ratio | 100 | 50 | 46.52 |
Table 6.
Soil layer parameters.
Table 6.
Soil layer parameters.
Soil Layer | Unit Weight γ (kN·m−3) | Compressive Modulus Es (MPa) | c (kPa) | φ (°) | μ |
---|
① Mucky silty clay | 17.4 | 3.15 | 10 | 16.5 | 0.32 |
② Mucky clay | 16.8 | 2.30 | 12 | 8.5 | 0.36 |
③1 Silty clay | 17.8 | 4.10 | 15 | 18.5 | 0.33 |
③2 Sandy silt | 18.2 | 11.82 | 4 | 33.5 | 0.32 |
Table 7.
Soil layer parameters of the HSS constitutive model.
Table 7.
Soil layer parameters of the HSS constitutive model.
Soil Layer | (MPa) | (MPa) | (MPa) | m | (MPa) | γ0.7 |
---|
① Mucky silty clay | 2.84 | 3.40 | 22.72 | 0.8 | 72.70 | 2.7 × 10−4 |
② Mucky clay | 2.41 | 2.89 | 19.30 | 0.8 | 54.03 | 2.7 × 10−4 |
③1 Silty clay | 5.74 | 6.89 | 34.45 | 0.8 | 59.58 | 2.7 × 10−4 |
③2 Sandy silt | 5.63 | 6.75 | 33.75 | 0.8 | 118.13 | 2.7 × 10−4 |