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

Yang, Jinping; Jing, Hang; Li, Peizhen

doi:10.1002/tal.1785

Cited by 15 publications

(3 citation statements)

References 43 publications

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“…However, there are many influencing factors, such as the stiffness of the silo, the height-todiameter ratio, the physical properties of the storage materials, the vibration frequency, the friction between the stock and the silo wall, etc. [31][32][33][34]. At present, the evaluation of the quality coefficient is not very accurate.…”

Section: Introductionmentioning

confidence: 99%

The Dynamic Behavior of Silos with Grain-like Material during Earthquakes

Duan

Yang

2023

Sustainability

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Grain security is an important guarantee for sustainable development. However, the dynamic behavior of silos containing grain-like material is not well understood. The effective mass and dynamic effects are the key parameters for the assessment of the silo–bulk material system during earthquakes. Herein, on the basis of the Janssen continuum model, it is proposed that the seismic energy is entirely dissipated by the interactions between the materials and the silo and the materials themselves. The seismic inertia forces among storage materials were introduced, and dynamic equilibrium equations considering the vibrations of storage materials were established. Theoretical solutions for the horizontal forces exerted and the effective mass of the silo–bulk material system during earthquakes are proposed. It is worth noting that the additional stress on the side wall proposed in this work is related to the depth, silo radius, storage density, internal friction coefficient, lateral pressure coefficient, and seismic acceleration. In addition, the effective mass coefficient is negatively correlated with the external friction coefficient, the lateral pressure coefficient, and horizontal seismic acceleration under a storage vibration state. A narrower silo (i.e., with a larger height–diameter ratio) has a low effective mass coefficient. The results from our method are in good agreement with those attained using experimental data, which demonstrates the accuracy and universality of the proposed formulations.

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Section: Introductionmentioning

confidence: 99%

The Dynamic Behavior of Silos with Grain-like Material during Earthquakes

Duan

Yang

2023

Sustainability

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“…Furthermore, to ensure that cast-in-place reinforced concrete underground silos are more sustainable [39][40][41][42][43]-that is, have better waterproof and moisture-proof performance and provide better protection for grain storage, as examined in this study [44][45][46][47]-it is necessary to carry out waterproof research on concrete structures [48][49][50]. Apay et al [51] investigated the influence of waterproof and water-repellent admixtures on the permeability and compressive strength of concrete.…”

Section: Introductionmentioning

confidence: 99%

Experimental and Numerical Investigation of Plastic–Concrete Waterproof Walls of an Underground Granary Subject to Combined Bending Moment and Water Pressure

et al. 2022

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To investigate the mechanical properties of plastic–concrete silo walls in practice, the mechanical properties and failure mechanism under the combined bending moment and water pressure were analyzed through the uniform loading test, water pressure test, and numerical analysis. The influence of the connecting plate spacing, radius, and the waterproof plate thickness on the water pressure-bearing capacity were analyzed. The test results show that the chemical adhesive force exists between the waterproof plate and concrete and can resist 20 kPa. The displacement and strain of the waterproof plate increases significantly with the increment in water pressure. When the water pressure reached 85 kPa, the specimen was damaged due to shear failure. The established numerical model was validated by the test results. The numerical analysis results show that the specimen failure mainly depends on the bolt strength when the thickness of the waterproof plate is greater than 14 mm or the radius of the connecting plate is greater than 60 mm. The relation between the design parameters and the water pressure-bearing capacity was proposed. Compared with the waterproof plate thickness, the connecting plate spacing and radius have greater influence on the water pressure-bearing capacity.

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“…The modal characteristics of the global soil‐superstructure system have been changed. [ 1 ] The fundamental period and damping ratio may noticeably and accordingly increase because of the flexibility of the soil and the energy dissipated through the soil, respectively. [ 2 ] A threshold period exists above which the high‐frequency component dominates the structural response.…”

Section: Introductionmentioning

confidence: 99%

Data‐driven identification and modeling of earthquake‐excited building structures regarding soil‐structure interaction

Gong

Shan

et al. 2020

Structural Design Tall Build

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Data-driven identification and modeling of the integrated soil-structure interaction (SSI) structure system are significantly important for real-world structures subjected to earthquakes in various engineering disciplines. The representative mechanical modeling for the overall system with SSI effect is firstly presented, and the differential evolution algorithm is introduced for model-based iterative identification on physical parameters including stiffness and damping coefficients. The performance and reliability of the proposed methodology are systematically investigated through a numerical model-based parametric study. Incorporation of the model selection, the incomplete measurement and noise effect on the proposed method is revealed and discussed subsequently. Then, the present method is experimentally investigated and validated using two illustrative examples, corresponding to a 12-story large-scale structural model and a nine-story real-world building structure. The performance in terms of feasible estimation and reliable prediction by using the optimally identified physical model is demonstrated through the time history comparison of measurable acceleration responses in different seismic events.

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

Cited by 15 publications

References 43 publications

The Dynamic Behavior of Silos with Grain-like Material during Earthquakes

The Dynamic Behavior of Silos with Grain-like Material during Earthquakes

Experimental and Numerical Investigation of Plastic–Concrete Waterproof Walls of an Underground Granary Subject to Combined Bending Moment and Water Pressure

Data‐driven identification and modeling of earthquake‐excited building structures regarding soil‐structure interaction

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