Relation of the infrasound characteristics and the continuous steel bridge vibration modes generated by the vibration of moving heavy trucks

Fukada, Saiji; Hama, Hirokazu; Usui, Kimihisa

doi:10.1007/bf03325797

Cited by 9 publications

(5 citation statements)

References 12 publications

(24 reference statements)

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“…Hdwever, the analysis done in the paper assurnes significance since the sound generated in ihis frequency range belongs to the category ofinfrasound occurring in the frequency range of O-20 Hz. Vibration of bridges due to the passage oftrains is one ofthe sources ofthis low frequency infrasound, People living near the bridge can feel the infrasound which causes mental and physical discomfort (Saiji et al,, 2012). Also, the yibration ofbuildings due to the propagation efthese Iow frequency waves through the ground has beerr a serious problern faced by the residerits living nearby.…”

Section: Forced Responses: Analytical and Numerical Methodsmentioning

confidence: 99%

3A25 Vibro-acoustic behaviour of a non-uniform beam traversed by a moving point load(The 12th International Conference on Motion and Vibration Control)

Kumar

Sujatha

Shankar

2014

MoViC

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Mbro-acoustic behaviour of a non-uniform beam of $inusoidally varying height, traversed by a single point load, is investigated in this paper. A method to reduce the vibration responses and sound power radiation by a uniform beam by modifying it into a non-uniform one having the fimdarnenta1 mode shape of a uniform beam, without adding ar removing any mass, is presented for the fust time. The significance of this type of non-uniform beam is that, it has the same shape as the first mode of a simply supported uniform beam which contributes predominantly to the vibration response due to moving load excitation. Since a closed form solution is net possible in this case, finite element method is used to forrnulate the equations of motion of the . beam in matrix form. Ihe forced response of the beam is calculated numerically using central difference methed with appropriate time steps. The vibration responses are compared with that of a uniform beam having the same mass and material properties, The sound power radiated by the beam is calculated using Rayleigh integral with the assumption that it is vibrating in an infinite baMe. Nlelocity responses obtained from finite element method are used to determine the sound power radiated by the bearn. Radiated sound power, for different speeds ofthe moving load, is calculated and compared wnh that of a uniform beam. Ihe paper aims at predicting the influence of geometry on the vibration and sound radiation characteristics of a simply supported beam subjected to a single moving concentrated load. The results show that by changing the shape ofa uniform beam to a sinusoidal one, the vibration response and sound power radiation can be considerably reduced. This, being a numerical method, can predict the vibro-acoustic response of any non-uniform beam to moving load exeitation,The present analysis, though 1imited to a single moving Ioad, can be extended to a series of loads and thus the vibration and acoustic responses ofa bridge due to passage oftrains can be predicted. 1(el,worcts : Moving load, Nonuniform bearn, Vibroacoustics, Sound radiation, Railway bridge, Dynamic response, Finite element method, infrasound

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Section: Forced Responses: Analytical and Numerical Methodsmentioning

confidence: 99%

3A25 Vibro-acoustic behaviour of a non-uniform beam traversed by a moving point load(The 12th International Conference on Motion and Vibration Control)

Kumar

Sujatha

Shankar

2014

MoViC

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“…Similarly, the mid spans (P1 -P2) of both the eastbound and the westbound bridges share the same band level at a frequency of 12.5 Hz. A comparison of the 1/3 octave band frequencies with the reference values for complaints about rattling sounds and complaints of mental and physical discomfort by the Japanese Ministry of Environment [6] is shown in the same figures. Although this rattling sound curve is only defined beginning from 5 Hz, the levels measured in Houses A and B appear to be larger than the rattling sound curve defined by the Japanese Ministry of Environment for frequencies of 2.5 -4.0 Hz.…”

Section: Open Access Jepmentioning

confidence: 98%

“…In general, the dynamic response of a bridge is influenced by the running speed [1], vehicle load [2], and suspension system [3] of the truck; truck's lane position on the bridge [1]; road surface roughness [4]; and bridge dynamics by the matching of the bridge's and the truck's natural frequencies [5]. In particular, the infrasound radiated from the bridge is related to the frequencies of the bridge vibration, truck suspension spring vibration, and tire spring vibration [6].…”

Section: Introductionmentioning

confidence: 99%

“…Conventional trucks with a rear leaf suspension [6,7] have frequencies of about 3.0 Hz; furthermore, their tire spring vibration frequencies are 10 -20 Hz. When the frequency of the truck's vibration (suspension spring vibration or tire spring vibration) and that of the bridge's vibration are similar, there is likely to be a rise in complaints from nearby residents about rattling soundsowing to the truck's suspension spring vibration, which has a frequency of about 3.0 Hz-and/or mental and physical discomfort-owing to the truck's tire spring vibration, which has a frequency of 10 -20 Hz [6].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Investigation of Infrasound Radiated from Highway Bridge Owing to Moving Truck

Fukada¹,

Okada²,

Hama³

et al. 2013

JEP

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Several complaints arose from houses near an object bridge about rattling sounds caused by infrasound, a low-frequency noise in the 0 -20 Hz frequency range. In Japan, conventional trucks with a rear leaf suspension have vibration frequencies of about 3.0 Hz; furthermore, their tire spring vibration frequency is 10 -20 Hz. Infrasound is radiated from the bridge owing to the truck's suspension spring vibration and/or tire spring vibration. In this study, the bridge vibrations were investigated using test trucks or conventional trucks to determine the cause of rattling sounds. It was found that the truck's spring vibration caused excessive bending vibration in the object bridge; this in turn was transmitted to nearby houses as infrasound. Various preventive measures for infrasound were then considered, and their effectiveness was investigated through a simulation of the dynamic response using a running truck. The difference between each measure's effectiveness as obtained by a comparison with each simulation's result provided a clear picture about the infrasound reduction methods in consideration of both construction cost and working difficulty.

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“…When a truck crosses a bridge with long wavelength road roughness, bridges with 30-40m spans vibrated significantly by resonating with the leaf suspension spring vibration [2][3] caused by long wavelength road roughness. On the other hand, when a truck passes over a bridge's expansion joint with a short wavelength road roughness, the tire spring vibration [4] of the truck is significantly generated by the road roughness. Moreover, damage to the bridge deck and environmental vibration problems, such as infrasound [5][6] and ground vibration [7], occurred as a result of the impact force [8] of the tire spring vibration.…”

Section: Introductionmentioning

confidence: 99%

Proposition of Estimation Method for Repairing the Roughness in Expansion Joints of Expressway Bridges

Fukada¹,

Matsumoto²,

Tadakazu³

et al. 2012

AMM

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When a truck passes on the expansion joint of an expressway bridge, the tire spring vibration of the truck is generated by short wavelength road roughness. Moreover, environmental vibration problems, such as infrasound and ground vibration, occur as a result of the impact force of the tire spring vibration. Then, IRI_10 analysis using a quarter car model was carried out using short wavelength road roughness in the expansion joints of Japanese expressways. This study proposed the IRI_10 value '7 mm/m' and an estimation method for repairing short wavelength road roughness.

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Relation of the infrasound characteristics and the continuous steel bridge vibration modes generated by the vibration of moving heavy trucks

Cited by 9 publications

References 12 publications

3A25 Vibro-acoustic behaviour of a non-uniform beam traversed by a moving point load(The 12th International Conference on Motion and Vibration Control)

3A25 Vibro-acoustic behaviour of a non-uniform beam traversed by a moving point load(The 12th International Conference on Motion and Vibration Control)

Investigation of Infrasound Radiated from Highway Bridge Owing to Moving Truck

Proposition of Estimation Method for Repairing the Roughness in Expansion Joints of Expressway Bridges

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