TY - JOUR
T1 - Scoping prediction of re-radiated ground-borne noise and vibration near high speed rail lines with variable soils
AU - Connolly, David
AU - Kouroussis, Georges
AU - Woodward, Peter Keith
AU - Giannopoulos, A
AU - Verlinden, Olivier
AU - Forde, Mike C
N1 - EPSRC funded research - EP/H029397/1 & EP/H027262/1
"Additionally, the funding provided by Engineering and Physical Sciences Research Council (EP/H029397/1) and equipment loaned by the Natural Environment Research Council is also greatly appreciated, without which, this research could not have been undertaken."
PY - 2014/11
Y1 - 2014/11
N2 - This paper outlines a vibration prediction tool, ScopeRail, capable of predicting in-door noise and vibration, within structures in close proximity to high speed railway lines. The tool is designed to rapidly predict vibration levels over large track distances, while using historical soil information to increase accuracy. Model results are compared to an alternative, commonly used, scoping model and it is found that ScopeRail offers higher accuracy predictions. This increased accuracy can potentially reduce the cost of vibration environmental impact assessments for new high speed rail lines.To develop the tool, a three-dimensional finite element model is first outlined capable of simulating vibration generation and propagation from high speed rail lines. A vast array of model permutations are computed to assess the effect of each input parameter on absolute ground vibration levels. These relations are analysed using a machine learning approach, resulting in a model that can instantly predict ground vibration levels in the presence of different train speeds and soil profiles. Then a collection of empirical factors are coupled with the model to allow for the prediction of structural vibration and in-door noise in buildings located near high speed lines. Additional factors are also used to enable the prediction of vibrations in the presence of abatement measures (e.g. ballast mats and floating slab tracks) and additional excitation mechanisms (e.g. wheelflats and switches/crossings).
AB - This paper outlines a vibration prediction tool, ScopeRail, capable of predicting in-door noise and vibration, within structures in close proximity to high speed railway lines. The tool is designed to rapidly predict vibration levels over large track distances, while using historical soil information to increase accuracy. Model results are compared to an alternative, commonly used, scoping model and it is found that ScopeRail offers higher accuracy predictions. This increased accuracy can potentially reduce the cost of vibration environmental impact assessments for new high speed rail lines.To develop the tool, a three-dimensional finite element model is first outlined capable of simulating vibration generation and propagation from high speed rail lines. A vast array of model permutations are computed to assess the effect of each input parameter on absolute ground vibration levels. These relations are analysed using a machine learning approach, resulting in a model that can instantly predict ground vibration levels in the presence of different train speeds and soil profiles. Then a collection of empirical factors are coupled with the model to allow for the prediction of structural vibration and in-door noise in buildings located near high speed lines. Additional factors are also used to enable the prediction of vibrations in the presence of abatement measures (e.g. ballast mats and floating slab tracks) and additional excitation mechanisms (e.g. wheelflats and switches/crossings).
KW - Environmental impact assessment (EIA)
KW - High speed rail vibration
KW - High speed train
KW - In-door noise
KW - Initial vibration assessment
KW - ScopeRail
KW - Scoping assessment
KW - Structural vibration
KW - Urban railway
UR - http://www.scopus.com/inward/record.url?scp=84904560859&partnerID=8YFLogxK
U2 - 10.1016/j.soildyn.2014.06.021
DO - 10.1016/j.soildyn.2014.06.021
M3 - Article
AN - SCOPUS:84904560859
SN - 0267-7261
VL - 66
SP - 78
EP - 88
JO - Soil Dynamics and Earthquake Engineering
JF - Soil Dynamics and Earthquake Engineering
ER -