Study of the Position of Sound Sources in a Turbulent Jet Using Nozzles of Different Configurations

Abstract: The aim of this work is to study the position of dominant sound sources in a small-scale turbulent jet using the beamforming method. Two nozzles of equivalent diameter and different geometric configurations (conical and chevron) were used to create different initial conditions for the outflow. Based on the analysis of the results obtained, it can be concluded that they are in good agreement with the well-known concepts of the physics of noise generation processes by turbulent jets: higher-frequency sources are… Show more

“…The most common direction of work for further reduction of jet noise is to change the design of engine exhaust devices, leading to a change in the conditions of jet outflows and their mixing with the environment. Such methods include slot-shaped (rectangular), chevron, bevelled and lobed nozzles [1][2][3][4][5][6]. The most common are chevron nozzles, which have triangular teeth along the nozzle edge.…”

“…This leads to the fact that the sound sources are distributed inside the jet. A change in the nozzle shape leads to a transformation of the jet flow structure itself and can lead to a change in the distribution of sound sources of a given object [4,8]. This information is especially important for the development of shielding computational models.…”

Localization of Noise Sources in Jets Flowing from Lobed Nozzles

“…The most common direction of work for further reduction of jet noise is to change the design of engine exhaust devices, leading to a change in the conditions of jet outflows and their mixing with the environment. Such methods include slot-shaped (rectangular), chevron, bevelled and lobed nozzles [1][2][3][4][5][6]. The most common are chevron nozzles, which have triangular teeth along the nozzle edge.…”

“…This leads to the fact that the sound sources are distributed inside the jet. A change in the nozzle shape leads to a transformation of the jet flow structure itself and can lead to a change in the distribution of sound sources of a given object [4,8]. This information is especially important for the development of shielding computational models.…”

Localization of Noise Sources in Jets Flowing from Lobed Nozzles

Multipole transfer matrix model-based sparse Bayesian learning approach for sound source identification

Study of the Acoustic and Aerodynamic Characteristics of Lobed Nozzles