Investigation of train-induced vibration and noise from a steel-concrete composite railway bridge using a hybrid finite element-statistical energy analysis method

Investigation of train-induced vibration and noise from a steel-concrete composite railway bridge using a hybrid finite element-statistical energy analysis method

In this study a hybrid finite element-statistical energy analysis (FE-SEA) method is used to investigate the structure-borne noise of a steel-concrete composite railway bridge. The rail is represented by an infinite Timoshenko beam connected to the sleepers which are regarded as finite Timoshenko be...

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Veröffentlicht in:Journal of sound and vibration 2020-04, Vol.471, p.115197, Article 115197
Hauptverfasser: Liu, Quanmin, Thompson, David J., Xu, Peipei, Feng, Qingsong, Li, Xiaozhen
Format: Artikel
Sprache:eng
Schlagworte:
Beams (structural)
Bridges
Composite bridge
Concrete
Equations of motion
Fasteners
Finite element analysis
Finite element method
Geometrical attenuation
Girders
Hybrid FE-SEA method
Noise
Noise levels
Railroad ballast
Railroad ties
Railroads
Railway bridges
Railway networks
Sound contribution
Springs (elastic)
Statistical energy analysis
Steel structures
Stiffness
Structure borne noise
Timoshenko beams
Vibration
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creator Liu, Quanmin
Thompson, David J.
Xu, Peipei
Feng, Qingsong
Li, Xiaozhen
description In this study a hybrid finite element-statistical energy analysis (FE-SEA) method is used to investigate the structure-borne noise of a steel-concrete composite railway bridge. The rail is represented by an infinite Timoshenko beam connected to the sleepers which are regarded as finite Timoshenko beams supported in ballast. The fasteners and ballast are simplified as a series of springs with complex stiffness. This model allows the receptance of the track to be determined. The wheel-rail forces are computed in the frequency domain from the contact-filtered roughness and the receptances of the wheel, track, and contact. The forces transmitted to the bridge are determined by substituting the wheel-rail forces into the equation of motion for the track. This model could also be applied to a slab track mounted on a bridge. A hybrid FE-SEA method is introduced in which FE is used to model the concrete deck and SEA is used to model the steel girders. This enables the computation of the vibration and noise of the composite railway bridge. The proposed method is verified by comparing its predictions with field measurements. The structure-borne noise level of the bridge is found to increase with train speed v by approximately 20lg(v). It is shown that the adjacent spans in a multi-span bridge can be ignored in deriving the bridge-borne noise at receiver points in the middle of the main span, provided that the distance to the track centreline is less than 0.3 times the length of the main span.
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The rail is represented by an infinite Timoshenko beam connected to the sleepers which are regarded as finite Timoshenko beams supported in ballast. The fasteners and ballast are simplified as a series of springs with complex stiffness. This model allows the receptance of the track to be determined. The wheel-rail forces are computed in the frequency domain from the contact-filtered roughness and the receptances of the wheel, track, and contact. The forces transmitted to the bridge are determined by substituting the wheel-rail forces into the equation of motion for the track. This model could also be applied to a slab track mounted on a bridge. A hybrid FE-SEA method is introduced in which FE is used to model the concrete deck and SEA is used to model the steel girders. This enables the computation of the vibration and noise of the composite railway bridge. The proposed method is verified by comparing its predictions with field measurements. The structure-borne noise level of the bridge is found to increase with train speed v by approximately 20lg(v). It is shown that the adjacent spans in a multi-span bridge can be ignored in deriving the bridge-borne noise at receiver points in the middle of the main span, provided that the distance to the track centreline is less than 0.3 times the length of the main span.</description><identifier>ISSN: 0022-460X</identifier><identifier>EISSN: 1095-8568</identifier><identifier>DOI: 10.1016/j.jsv.2020.115197</identifier><language>eng</language><publisher>Amsterdam: Elsevier Ltd</publisher><subject>Beams (structural) ; Bridges ; Composite bridge ; Concrete ; Equations of motion ; Fasteners ; Finite element analysis ; Finite element method ; Geometrical attenuation ; Girders ; Hybrid FE-SEA method ; Noise ; Noise levels ; Railroad ballast ; Railroad ties ; Railroads ; Railway bridges ; Railway networks ; Sound contribution ; Springs (elastic) ; Statistical energy analysis ; Steel structures ; Stiffness ; Structure borne noise ; Timoshenko beams ; Vibration</subject><ispartof>Journal of sound and vibration, 2020-04, Vol.471, p.115197, Article 115197</ispartof><rights>2020 Elsevier Ltd</rights><rights>Copyright Elsevier Science Ltd. 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The rail is represented by an infinite Timoshenko beam connected to the sleepers which are regarded as finite Timoshenko beams supported in ballast. The fasteners and ballast are simplified as a series of springs with complex stiffness. This model allows the receptance of the track to be determined. The wheel-rail forces are computed in the frequency domain from the contact-filtered roughness and the receptances of the wheel, track, and contact. The forces transmitted to the bridge are determined by substituting the wheel-rail forces into the equation of motion for the track. This model could also be applied to a slab track mounted on a bridge. A hybrid FE-SEA method is introduced in which FE is used to model the concrete deck and SEA is used to model the steel girders. This enables the computation of the vibration and noise of the composite railway bridge. The proposed method is verified by comparing its predictions with field measurements. The structure-borne noise level of the bridge is found to increase with train speed v by approximately 20lg(v). 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The structure-borne noise level of the bridge is found to increase with train speed v by approximately 20lg(v). It is shown that the adjacent spans in a multi-span bridge can be ignored in deriving the bridge-borne noise at receiver points in the middle of the main span, provided that the distance to the track centreline is less than 0.3 times the length of the main span.</abstract><cop>Amsterdam</cop><pub>Elsevier Ltd</pub><doi>10.1016/j.jsv.2020.115197</doi><oa>free_for_read</oa></addata></record>
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subjects Beams (structural)
Bridges
Composite bridge
Concrete
Equations of motion
Fasteners
Finite element analysis
Finite element method
Geometrical attenuation
Girders
Hybrid FE-SEA method
Noise
Noise levels
Railroad ballast
Railroad ties
Railroads
Railway bridges
Railway networks
Sound contribution
Springs (elastic)
Statistical energy analysis
Steel structures
Stiffness
Structure borne noise
Timoshenko beams
Vibration
title Investigation of train-induced vibration and noise from a steel-concrete composite railway bridge using a hybrid finite element-statistical energy analysis method
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