Large‐scale shaking table test on pile‐soil‐structure interaction on soft soils

Yang, Jinping; Li, Peizhen; Lü, Xilin

doi:10.1002/tal.1679

Cited by 27 publications

(15 citation statements)

References 41 publications

(41 reference statements)

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“…The results of the pile bending moment demonstrate that the pile at the middle of first row P2 had a significantly higher bending moment than the other instrumented piles, because the pile P2 shared more load and it was influenced by the shadowing effect. The shadow effect was also found in other researches [47][48].…”

Section: Bending Moment Results and Discussionsupporting

confidence: 70%

Effect of soil-pile-structure interaction on seismic behaviour of nuclear power station via shaking table tests

et al. 2021

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Section: Bending Moment Results and Discussionsupporting

confidence: 70%

Effect of soil-pile-structure interaction on seismic behaviour of nuclear power station via shaking table tests

et al. 2021

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“…The section of single pile is 75 × 75 mm, and the length is 2 m. All of the physical quantities are scaled using similitude formulas derived from the Buckingham π theorem. [34] In the SSI shaking table tests, a laminar shear box is designed to reduce the undesirable boundary effects, as presented in Figure 1. The net size of the shear box is 4,500 × 3,500 × 3,000 mm (length × width × height).…”

Section: Test Designmentioning

confidence: 99%

Dynamic characteristics and viscous dampers design for pile‐soil‐structure system

Yang

Jing

2020

Structural Design Tall Build

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Summary A series of large‐scale shaking table tests are conducted on tall buildings with and without energy dissipation devices on soft soils in pile group foundations, representing pile‐soil‐structure interaction (PSSI) system and the corresponding fixed‐base situations. The superstructure is a 12‐story reinforced concrete (RC) frame. The dynamic characteristics of the test models show that the frequencies decrease and the damping ratio increase in PSSI system by comparison with the fixed‐base structures. The mode shapes of PSSI system are different from that under fixed‐base condition, and the mode shapes of structure without dampers change greater than that with energy dissipation devices under various white noises. An improved method for structural dynamic characteristics, considering the impedance function of piles, is developed to address the issue of modal parameters with PSSI effect. In addition, the structural dynamic parameters of the large‐scale shaking table tests are identified using the modification method and other regulation methods, demonstrating that the improved approach is highly accurate and effective. Subsequently, a design procedure for viscous dampers of structures with PSSI effect is presented based on the dynamic characteristics of the system. Finally, the dynamic responses of the structure with viscous dampers in the practical engineering are decreased effectively, indicating the good performance of designed viscous dampers. The numerical results also show that the damping efficiency of interstory drift is larger than the acceleration and interstory shear force. Therefore, the improved modal parameters method, validated through a series large‐scale shaking table tests, is applicable for identifying dynamic characteristics of pile‐soil‐structure with energy dissipation devices system. The design procedure of viscous dampers, proved by a reinforced concrete frame structure located on a practical Shanghai soft site, can be employed to design the viscous dampers considering seismic PSSI effect.

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“…Shear-type steel frame structure is one of the most common engineering structures. In order to make the designed structure safer and more economical, a lot of theoretical research [1,2] and experimental research [3,4] have been carried out. When the stiffness of the beam is much greater than that of the column, this type of structure can be simplified into a lumped mass shear model.…”

Section: Introductionmentioning

confidence: 99%

High Precision Identification Method of Mass and Stiffness Matrix for Shear-Type Frame Test Model

2023

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In the direct method of identifying the physical parameters of the shear-type frame structures through the frequencies and modes from the experimental modal analysis (EMA), the accuracy of the lumped mass depends on the initial mass, while the identified mass matrix and stiffness matrix are prone to generate some matrix elements without any physical meaning. In this paper, based on the natural frequencies and modes obtained from the EMA, an iterative constrained optimization solution for correcting mass matrix and a least squares solution for the lateral stiffness are proposed. The method takes the total mass of the test model as the constraint condition and develops an iterative correction method for the lumped mass, which is independent of the initial lumped mass. When the measured modes are exact, the iterative solution converges to the exact solution. On this basis, the least squares calculation equation of the lateral stiffness is established according to the natural frequencies and modes. Taking the numerical model of a 3-story steel frame structure as an example, the influence of errors of measured modes on the identification accuracy is investigated. Then, a 2-story steel frame test model is used to identify the mass matrix and stiffness matrix under three different counterweights. Numerical and experimental results show that the proposed method has good accuracy and stability, and the identified mass matrix and stiffness matrix have clear physical significance.

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Large‐scale shaking table test on pile‐soil‐structure interaction on soft soils

Cited by 27 publications

References 41 publications

Effect of soil-pile-structure interaction on seismic behaviour of nuclear power station via shaking table tests

Effect of soil-pile-structure interaction on seismic behaviour of nuclear power station via shaking table tests

Dynamic characteristics and viscous dampers design for pile‐soil‐structure system

High Precision Identification Method of Mass and Stiffness Matrix for Shear-Type Frame Test Model

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