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An investigation into high-speed train interior noise with operational transfer path analysis method

Muxiao Li, Ziwei Zhu, Tiesong Deng, Xiaozhen Sheng

2021Railway Engineering Science19 citationsDOIOpen Access PDF

Abstract

Abstract Passengers' demands for riding comfort have been getting higher and higher as the high-speed railway develops. Scientific methods to analyze the interior noise of the high-speed train are needed and the operational transfer path analysis (OTPA) method provides a theoretical basis and guidance for the noise control of the train and overcomes the shortcomings of the traditional method, which has high test efficiency and can be carried out during the working state of the targeted machine. The OTPA model is established from the aspects of "path reference point-target point" and "sound source reference point-target point". As for the mechanism of the noise transmission path, an assumption is made that the direct sound propagation is ignored, and the symmetric sound source and the symmetric path are merged. Using the operational test data and the OTPA method, combined with the results of spherical array sound source identification, the path contribution and sound source contribution of the interior noise are analyzed, respectively, from aspects of the total value and spectrum. The results show that the OTPA conforms to the calculation results of the spherical array sound source identification. At low speed, the contribution of the floor path and the contribution of the bogie sources are dominant. When the speed is greater than 300 km/h, the contribution of the roof path is dominant. Moreover, for the carriage with a pantograph, the lifted pantograph is an obvious source. The noise from the exterior sources of the train transfer into the interior mainly through the form of structural excitation, and the contribution of air excitation is non-significant. Certain analyses of train parts provide guides for the interior noise control.

Topics & Concepts

PantographNoise (video)Computer scienceAcousticsPath (computing)Transmission (telecommunications)Noise controlSound transmission classPoint (geometry)EngineeringNoise reductionTelecommunicationsMathematicsPhysicsArtificial intelligenceMechanical engineeringProgramming languageImage (mathematics)GeometryVehicle Noise and Vibration ControlNoise Effects and ManagementAcoustic Wave Phenomena Research