A frequency domain model for analysing vibrations in large-scale integrated building–bridge structures induced by running trains

Zhang, Xun; Ruan, Linghui; Zhao, Yu; Zhou, Xiaogang; Li, Xiaozhen

doi:10.1177/0954409719841793

Cited by 13 publications

(5 citation statements)

References 23 publications

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“…An increasing number of rail transit lines are being constructed close to densely inhabited districts around the world, resulting in significant noise problems. 1–4 This work considered a long-span steel-truss cable-stayed bridge that is close to residential buildings, and the distance between them is less than 5 m. One of the primary noise sources, known as steel bridge-borne noise, occurs when vibrations due to moving train loads are transferred onto a bridge structure, which subsequently radiates sound. 5,6 An elastomer mat, which has an effective vibration reduction characteristic, is commonly used in track structures, 7–10 but not as often for long-span steel-truss cable-stayed bridges.…”

Section: Introductionmentioning

confidence: 99%

Reduction of vibration and noise in rail transit steel bridges using elastomer mats: Numerical analysis and experimental validation

Zhang

Cao

Ruan

et al. 2020

Proceedings of the Institution of Mechanical Engineers, Part F:

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The noise radiating from a steel bridge can be much greater than the pass-by noise levels of trains at-grade. This is attributed to a special phenomenon known as the steel bridge-borne noise, which occurs when shocks and vibrations due to moving train loads are transferred onto the bridge. To investigate the effectiveness of elastomer mats for reducing vibration and noise in rail transit steel bridges, a frequency domain prediction model is established and calibrated through a field experiment. In this model, the train and track interactions were investigated analytically, and the receptance technique was introduced to determine the force transmitted from a multi-layer track structure to the bridge deck. The local vibrations of the bridge components were solved numerically using a hybrid shell/beam finite element model based on a harmonic response analysis. The bridge vibrations were regarded as the source of noise radiation by considering each bridge component as a rectangular flat plate noise source. There was good agreement between the calculated and measured results in terms of both the magnitude and frequency dependence. The mechanisms of vibration transmission and noise radiation were investigated using numerical simulations. In addition, the vibration and noise reduction effects are discussed by numerically comparing a track system with and without an elastomer mat.

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Section: Introductionmentioning

confidence: 99%

Reduction of vibration and noise in rail transit steel bridges using elastomer mats: Numerical analysis and experimental validation

Zhang

Cao

Ruan

et al. 2020

Proceedings of the Institution of Mechanical Engineers, Part F:

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“…The difference between the two is whether the vibrations propagate primarily in the soil. The representative buildings of the first type include integrated station-bridge structures [42][43][44][45], buildings with carriageways inside [46,47], and railway overtrack buildings [48][49][50], among others. Their common characteristic in structural construction is that the track or carriageway is rigidly connected to the structure, and the vibration is primarily propagated within the structure.…”

Section: Vehicle Load Modelmentioning

confidence: 99%

Structural Vibration Comfort: A Review of Recent Developments

Xie,

Hua

2024

Buildings

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With continuous improvements in the social economy and living standards of individuals, the vibration comfort of building structures has gradually been emphasized by academic and engineering communities, such as vehicle-induced vibrations in buildings near traffic, human-induced vibrations in large-span structures, wind-induced vibrations in super-high-rise buildings, and machinery-induced structural vibrations. Comfort-based structural analysis is distinct from traditional safety-based structural analysis, and its theoretical systems and unified guidelines have not yet been established. This paper reviews recent research on structural vibration comfort, including major load categories and their impacts, comfort-based structural analysis, evaluation methods, and vibration-mitigation measures. By presenting the shortcomings of the existing research, potential topics for future study are suggested.

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“…It offers various advantages, such as saving land for development and providing passengers with zero-distance interchange. This system combines the bridge and upper station structure, altering their transmission mechanism and dynamic characteristics [1][2][3][4]. The lower pile foundation requires relatively high forces, particularly under earthquake conditions.…”

Section: Introductionmentioning

confidence: 99%

Experimental study of the seismic performance of pile groups with integrated building-bridge structure in liquefiable soils: a case study

KONG,

ZHOU,

et al. 2024

Preprint

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The integrated building-bridge structure system exemplifies integrated railway stations in China and has emerged as a new structural approach in recent years. This paper presents a case study on large shaking table tests that explore various seismic responses of a pile group system based on the Kunming South Railway Station. The study focused on the dynamic characteristics of the soil and pile-superstructure. Findings indicate that the pile damage is primarily on the side facing the direction of vibration, with the middle pile experiencing greater damage than the corner pile. Hysteresis is observed in the growth of pore pressure ratio during the liquefaction of saturated soils. Both the bending moment and ground pressure on the pile increase with the degree of liquefaction. The greatest pile bending moment occurs at the interface between liquefied and non-liquefied soil layers. During seismic activity, side piles facing the vibration direction experience increased seismic surcharge loads, while the center piles experience smaller loads due to the isolation effect of the side piles.

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A frequency domain model for analysing vibrations in large-scale integrated building–bridge structures induced by running trains

Cited by 13 publications

References 23 publications

Reduction of vibration and noise in rail transit steel bridges using elastomer mats: Numerical analysis and experimental validation

Reduction of vibration and noise in rail transit steel bridges using elastomer mats: Numerical analysis and experimental validation

Structural Vibration Comfort: A Review of Recent Developments

Experimental study of the seismic performance of pile groups with integrated building-bridge structure in liquefiable soils: a case study

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