A Study on Generation of Noise by High-Speed Pulsating Jets
This paper describes the noise generation in an exhaust system of a reciprocating engine and focuses on the noise generated by shock/vortex interaction. The pulsating flow through the exhaust pipe consists of the compression and expansion wave, shock wave being generated by the non-linearity of the compression wave at its head. The jet noise is produced when the pulsating flow is discharged from the pipe end into atmosphere. The numerical simulation based on a finite difference method and experiment were made, the result of both of them being compared. First, the flow field in the pipe was obtained to easily discuss the characteristic of the pulsating jet in terms of the pressure history in the pipe. The jet structure was visualized by using schlieren and shadowgraph techniques. Sound pressure measurements at various locations were made in order to survey the directivity of the noise. The comparison between the result of numerical calculation and experiment showed a good agreement. A noise source related to shock/vortex interaction was confirmed by the numerical study clearly. Keywords: compressible flow, pulsating jet, shock/vortex interaction, noise generation. 1. Introduction Reciprocating engine has been used in many industrial applications such as automobile, airplane, vessel, and so on. Automobile is a representative of these. It is well-known that flow through the exhaust pipe of a reciprocating engine is high-speed and pulsating. Periodic opening and shutting of the exhaust valve produce the flow pulsation in the exhaust pipe. It has been concluded by many studies (Blair and Goulburn, 1967; Blair and Arbuckle, 1970) that shock wave is formed as compression wave generated by opening of the valve propagates downstream along the pipe. The shock wave becomes dominant noise source when it is discharged into atmosphere. However, Endo and Iwamoto (1999) pointed out the existence of another noise which appears in the flow field behind the discharged shock wave....