Abstract
The rising demand for lower noise emissions of car ancillary units due to electrification and higher customer expectations regarding driving comfort results in the need for more silent car components. Hydraulic driven car components in particular are often identified as a major source of noise in the system. Therefore, it is mandatory to investigate the noise sources inside the hydraulic system. In this work, a combined CFD-FEM approach is applied to estimate the flow-induced noise radiation of a mechanically driven transmission pump. To achieve this goal, the mapping procedure to hand over the pressure field from the CFD to the FEM mesh must be valid. For this purpose, the error during the mapping process is evaluated and different parameters, which influence the mapping results, are analyzed. Additionally, the impact of the time step size and the length of the time signal on the frequency resolution of the force signal is investigated to get an appropriate excitation force for the vibroacoustic simulation. Subsequently, a force analysis and a structural FEM simulation are performed to identify which flow phenomenon contributes most to the excitation of the pump housing. Specific locations in the pump with high loads are pointed out. In a final step, the results of the vibroacoustic model are compared to acceleration and sound pressure level measurements of the pump performed in a hemi-anechoic room.
Highlights
Automated car transmissions have high demands of power, reliability, low fuel consumption and low noise emissions
Fluid is conveyed from the suction port, through the inlet (1) and the injector (2), to the delivery port and the outlet (3) by a set of pressure sealed displacement chambers (7)
The displacement chamber disconnects from the suction port and is neither connected to the suction nor to the delivery port (5)
Summary
Automated car transmissions have high demands of power, reliability, low fuel consumption and low noise emissions. Fluid is conveyed from the suction port, through the inlet (1) and the injector (2), to the delivery port and the outlet (3) by a set of pressure sealed displacement chambers (7) These chambers are formed by the static cam ring part (A), the static inner pump surfaces, the rotating rotor (B) and by the vanes (C), which are able to slide in and out of the rotor in radial direction. There is no study to predict the fluid induced vibrations and noise radiation of a rotary vane pump using a 3D-CFD model in combination with a FEM/BEM-based model. For this purpose, in this work the flow in the pump is analyzed using a 3D-CFD simulation model build up in the commercial software STAR-CCM+. This can lead to an error due to the mapping and the mapping process needs to be validated
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