Numerical Investigation of the Effect of various High-Speed Train Roof Configurations on Aerodynamic Noise

Kim, Hogun; Hu, Zhiwei; Thompson, D.J.

doi:10.2514/6.2019-2645

Cited by 2 publications

(3 citation statements)

References 17 publications

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“…More detail of the flow characteristics including Q-criterion, time-averaged velocity 2 D contour and surface pressure fluctuations over pantographs and recess have been presented by Kim et al. 38…”

Section: Aerodynamic Resultsmentioning

confidence: 99%

Effect of different typical high speed train pantograph recess configurations on aerodynamic noise

Kim

Thompson

2020

Proceedings of the Institution of Mechanical Engineers, Part F:

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For high-speed trains, the aerodynamic noise becomes an essential consideration in the train design. The pantograph and pantograph recess are recognised as important sources of aerodynamic noise. This paper studies the flow characteristics and noise contributions of three typical high-speed train roof configurations, namely a cavity, a ramped cavity and a flat roof with side insulation plates. The Improved Delayed Detached-Eddy Simulation approach is used for the flow calculations and the Ffowcs Williams & Hawkings aeroacoustic analogy is used for far-field acoustic predictions. Simulations are presented for a simplified train body at 1/10 scale and 300 km/h with these three roof configurations. In each case, two simplified pantographs (one retracted and one raised) are located on the roof. Analysis of the flow fields obtained from numerical simulations clearly shows the influence of the train roof configuration on the flow behaviour, including flow separations, reattachment and vortex shedding, which are potential noise sources. A highly unsteady flow occurs downstream when the train roof has a cavity or ramped cavity due to flow separation at the cavity trailing edge, while vortical flow is generated by the side insulation plates. For the ramped cavity configuration, moderately large pressure fluctuations appear on the cavity outside walls in the upstream region due to unsteady flow from the upstream edge of the plate. The raised pantograph, roof cavity, and ramped cavity are identified as the dominant noise sources. When the retracted pantograph is located in the ramped roof cavity, its noise contribution is less important. Furthermore, the insulation plates also generate tonal components in the noise spectra. Of the three configurations considered, the roof cavity configuration radiates the least noise at the side receiver in terms of A-weighted level.

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Section: Aerodynamic Resultsmentioning

confidence: 99%

Effect of different typical high speed train pantograph recess configurations on aerodynamic noise

Kim

Thompson

2020

Proceedings of the Institution of Mechanical Engineers, Part F:

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“…In ground vehicles, due to the increase in speed and the reduction of the powertrain noise (especially in electric cars), aerodynamic noise is becoming an important reason of discomfort for passengers and many studies have lately been devoted to this issue. For instance, [8] studied the noise generated by different train roof configurations where the noise is dominated by the pantograph, the roof cavity and the insulation plates. In the automotive industry, a large amount of work has been done regarding the noise generated by the air flow around side mirrors, either as parts of a generic vehicle model [9,10] or as simplifications of an isolated side mirror in form of a half cylinder or a hemisphere [11,12].…”

Section: Introductionmentioning

confidence: 99%

“…8 shows the 1000 Hz and the 4000 Hz 1/3 octaves radiated by the side mirror to the side window and Figure4.9 the same 1/3 octaves radiated by the A-pillar to the side window and windshield. In this case, the noise radiated by the side mirror dominates the excitation of the side window for nearly 4.…”

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confidence: 99%

Computational aeroacoustics in the automotive industry

Martín Navarrete

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The acoustic field inside a car cabin for low driving speeds is dominated by the engine or the tire noise. However, for mid to high velocities, the noise generated by the interaction of the car with the external air becomes more relevant. The flow separation from the A-pillar or the side mirror generates strong pressure fluctuations which results in acoustic waves propagated to the interior via excitation of the side window or the windshield. At each point of the flow field domain, the pressure is composed by the hydrodynamic pressure and the acoustic pressure. For typical car speeds, the Mach number is so low that the fluctuations of the compressible part of the flow are much smaller than those of the incompressible part but their characteristic lengths and convection velocities have a higher correlation with the bending waves of the windows of the vehicle. As a consequence, it is usually accepted that the major part of the interior noise in the car cabin is generated by the compressible part of the external flow field arriving to the transmission surfaces. The present thesis is focused on the research of a suitable computational methodology that enables to obtain the acoustic pressure near the transmission surfaces. To this aim, an extensive review of the most popular methods of Computational Aeroacoustics is carried out in order to understand the physical mechanisms of sound generated by a fluid in motion around a solid body and the mathematical models that describe it based on the up-to-date available literature. Due to its simplicity, efficiency and usefulness, the so-called 'acoustic analogy' proposed by Curle as an extension of the theory developed by James Lighthill is chosen to evaluate the acoustic pressure of the cases of study within this dissertation. n particular, among all the different components of a vehicle the flow pattern and acoustic performance of very wide open cavities have been deeply analysed due to its common presence in any type of vehicle design for soiling management or manufacturing restrictions. This configuration is known to be the cause of conspicuous acoustic problems such as whistles due to the well defined tonal noise known in the literature as Rossiter modes. The flow nature of this phenomena as well as its radiating pattern and response to different geometrical modifications are addressed in this work. A particular feature of this configuration is the oscillatory mode: shear layer mode (SL) or wake mode (WM). For the parameters considered in the present dissertation it is seen that while in SL the flow shows a two-dimensional behaviour, in WM the flow is three-dimensional, resulting in significantly different sound sources. The computation of the acoustic pressure is done using Curle's formulation evaluated as a post-process of an unsteady incompressible three-dimensional Navier-Stokes solution and compared with the results obtained with Direct Simulation (DS). It is found that DS and Curle's analogy are in good agreement except in the wake area, where quadrupole acoustic sources are present. Regarding the evaluation of the passive noise control techniques, the results show that the modifications on the trailing edge are the most effective to control the flow. They allow to reduce the pressure fluctuations produced by the recirculation confined inside the cavity and the abrupt ejection of the flow at the trailing edge. As a consequence, the overall sound pressure level can be decreased up to 9dB. Once the model has been validated for an isolated geometry, the application of the same method is extended for a real car geometry. The acoustic radiation to the side window and windshield of a side mirror and A-pillar of a vehicle is shown as an example of the potential of this procedure for aeroacoustic analysis and optimisation of a vehicle straight from the drawing table. El campo acústico dentro de la cabina de un automóvil para velocidades de conducción bajas está dominado por el motor o el ruido de los neumáticos. Sin embargo, para velocidades medias-altas, el ruido generado por la interacción del automóvil con el aire exterior se vuelve más relevante. La separación del flujo del montante A o del retrovisor genera fuertes fluctuaciones de presión originando ondas acústicas que se propagan al interior del vehículo mediante la excitación de la ventana lateral o el parabrisas. En cada punto del dominio, la presión está compuesta por la presión hidrodinámica (es decir, la parte incompresible del flujo) y la presión acústica (es decir, el campo acústico causado por la parte compresible del flujo). Para las velocidades típicas de un automóvil, el número de Mach es tan bajo que las fluctuaciones de la parte compresible son mucho menores que las de la parte incompresible, sin embargo, sus longitudes características y velocidades de convección tienen una correlación más alta con las ondas de flexión de las ventanas del vehículo. Como consecuencia, es generalmente aceptado que la mayor parte del ruido interior en la cabina del automóvil es generado por la presión acústica que llega a las superficies de transmisión. Esta tesis se centra en la búsqueda de una metodología computacional adecuada que permita obtener la presión acústica cerca de las superficies de transmisión. Para ello se lleva a cabo una extensa revisión de los métodos más populares en Aeroacústica Computacional con el fin de comprender los mecanismos físicos del sonido generado por un fluido en movimiento alrededor de un cuerpo sólido y los modelos matemáticos que lo describen. Por su sencillez, eficacia y utilidad, se ha escogido la analogía acústica propuesta por Curle como extensión de la teoría desarrollada por James Lighthill para evaluar la presión acústica de los casos de estudio en la presente tesis. Entre los diferentes componentes de un vehículo, el patrón de flujo y el comportamiento acústico de las cavidades se han analizado en profundidad debido a su habitual presencia en los diseños de automóviles. Se sabe que esta configuración es la causa de problemas acústicos como los silbidos conocidos en la literatura como modos de Rossiter. La naturaleza de flujo de este fenómeno, así como su patrón de radiación y respuesta a diferentes modificaciones geométricas son abordados en esta disertación Una característica particular de esta configuración es el modo de oscilación: SL o WM. Para los parámetros considerados en la presente tesis, se observa que mientras en SL el flujo muestra un comportamiento bidimensional, en WM el flujo es tridimensional, lo que resulta en fuentes de sonido significativamente diferentes. El cálculo de la presión acústica se realiza utilizando la formulación de Curle evaluada como un posproceso de la resolución de las ecuaciones incompresibles de Navier-Stokes y se compara con los resultados obtenidos con la Simulación Directa (DS). Ambas soluciones ofrecen resultados similares excepto en el área de la estela, donde están presentes las fuentes acústicas de cuadrupolo. En cuanto a la evaluación de las técnicas de control pasivo de ruido, los resultados muestran que las modificaciones en la arista de salida son las más efectivas para controlar el flujo ya que permiten reducir las fluctuaciones de presión producidas por la recirculación confinada en el interior de la cavidad y la expulsión brusca del flujo. Como consecuencia, el nivel de presión acústica se puede reducir hasta 9 dB. Una vez validado el modelo para una geometría aislada, se amplía la aplicación del mismo método para una geometría de coche real. La radiación acústica hacia la ventana lateral y el parabrisas de un retrovisor y del montante A se muestra como ejemplo del potencial de este procedimiento para el análisis aeroacústico y la optimización de un vehículo directamente desde la mesa de dibujo.

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Numerical Investigation of the Effect of various High-Speed Train Roof Configurations on Aerodynamic Noise

Cited by 2 publications

References 17 publications

Effect of different typical high speed train pantograph recess configurations on aerodynamic noise

Effect of different typical high speed train pantograph recess configurations on aerodynamic noise

Computational aeroacoustics in the automotive industry

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