Pipe jacking construction is a commonly employed trenchless technique for laying underground pipes in urban areas. However, the conventional support structure for pipe jacking shafts poses challenges, including difficulty in reserving pipe jacking holes, susceptibility to tilting, low bearing capacity, and the potential for failure during construction. Taking the 5# pipe jacking shaft of the pipe jacking construction for diverting the Yellow River through the river at Niukouyu in Zhengzhou City as the research background, investigates the soil settle deformation around the working shaft and the mechanical response law of the supporting structure during the shortdistance, long-distance and second long-distance pipe jacking construction by combining the practical engineering field test and finite element numerical simulation, and carries out a sensitivity analysis on the main design parameters affecting the stability of the supporting structure through orthogonal test. The findings reveal that during the second pipe jacking construction, stress and deformation of the supporting structure are higher than those observed in the first pipe jacking. Notably, support piles and waist beams at the entrance of the pipe jacking experience greater force, and the back and side walls undergo increased force and deformation in the later stages of pipe jacking, and support pile spacing is the main control factor affecting the mechanical performance of the novel support structure. The study concludes that monitoring and protection measures should be reinforced, particularly in areas prone to failure and damage during construction. The insights gained from this research can serve as a reference for designing, optimizing, and safely monitoring novel assembled pipe jacking shaft support structures.

To investigate the effect of fluid -solid coupling on the seismic performance of underground structures in watersaturated soil, a comparison study is conducted in this paper on three-dimensional (3D) nonlinear seismic behavior of a 3 -story 3 -bay subway station obtained using two different finite element methods (FEM), i.e., the generally used simplified method with equivalent single-phase soil model and a newly developed 3D numerical approach capable of considering the dynamic behavior of saturated two-phase media. A 3D user -defined element embedded in ABAQUS is first introduced to simulate saturated soil's dynamic fluid -solid coupling effect. Then, more essential demonstrations are presented for establishing and validating the two FEM. Based on the two methods with and without incorporating fluid -solid interaction, 3D nonlinear seismic response analysis is performed on the subway station considering three different input seismic waves. Discussions are conducted in terms of accelerations, lateral displacements, inter -story drift ratios, rotation of columns, damage characteristics, and internal forces, based on which the limitations of the simplified method are quantitatively interpreted. The results show that neglecting the fluid -solid coupling effect can bring about conservative evaluations of the seismic behavior of underground structures in saturated soil. The effect of fluid -solid coupling on the seismic performance of underground structures is quite sensitive to the peak ground acceleration. It is significant to consider the fluid -solid coupling effect during the performance -based seismic design of underground structures enclosed in saturated soil to gain realistic seismic responses, especially for those subjected to major earthquakes.