Experimental and Computational Approach for Jet Noise Mitigation by Mixing Control Devices

Tanaka, Nozomi; Oishi, Tsutomu; Ooba, Yoshinori; Enomoto, Shunji; Yamamoto, Kazuomi; Ishii, Tatsuya

doi:10.1115/gt2011-45200

Cited by 3 publications

(1 citation statement)

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“…A notch, a small dent formed at the nozzle exit, has been studied under collaboration between JAXA and IHI. [10][11][12] A revised type of notched nozzle proved to suppress the jet mixing noise and the higher-frequency noise even along the side. A microjet is also an attractive active suppressor.…”

Section: Introductionmentioning

confidence: 99%

Overview of Jet Noise Measurement at JAXA

Ishii

Yamamoto

Nagai

et al. 2014

AEROSPACE TECHNOLOGY JAPAN

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This paper describes jet noise measurement recently conducted at the Japan Aerospace Exploration Agency (JAXA). Measurement techniques with regard to jet noise are of great importance for better understanding the noise generation mechanism and evaluating noise suppression characteristics of jet noise suppressors. As jet noise is influenced by the flow structure behind the nozzle, noise-related measurement should be done from various points of view. In attempting to satisfy these requirements, JAXA focused on three aspects of jet noise-related measurement: 1) the far-field sound properties, which the nozzle and subsequent jet provide; 2) the near-field sound sources formed primarily by the aerodynamic process; and 3) the flow profiles such as pressure and temperature distributions behind the nozzle or engine.

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Section: Introductionmentioning

confidence: 99%

Overview of Jet Noise Measurement at JAXA

Ishii

Yamamoto

Nagai

et al. 2014

AEROSPACE TECHNOLOGY JAPAN

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Computational Study of Noise Reduction in CFM56-5B Using Core Nozzle Chevrons

Arshad

Andrew

Blumbergs

2020

2020 11th International Conference on Mechanical and Aerospace Engineering (ICMAE)

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Jet mixing noise suppression by means of a claw mixer: Revision of the nail configuration to improve the high-frequency acoustic property

Ishii¹,

Enomoto²,

Nakamura

et al. 2014

JFST

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Jet powered aircraft radiate a substantial amount of noise around airports. Among several noise sources of the aircraft, high-speed jet behind the nozzles of jet engines generates strong sound through mixing process of jet with the surrounding flow. One of the effective measures against the jet mixing noise is to control the flow field so as to weaken shear in the jet plume. The authors have proposed a claw mixer as a retractable mixing control device. The claw, composed of half-edged nails, is placed at the nozzle end. In the preliminary noise test using a jet engine, the nails with a configuration of 60° inclination relative to jet and a 30% penetration provided sufficient noise reduction in the downstream of jet. However, this configuration of nails resulted in increase of additional noise at higher frequencies. To improve this acoustic property, this study attempted to redesign the nail configurations with a help of large eddy simulation. The revised nail configurations, e.g., shallower inclination and less penetration of the nails, suggested less turbulent kinetic energy at higher frequency and thus less additional noise increase to the lateral of jet. The subsequent scale-model test on the revised claw mixer confirmed suppression in both broadband peak noise and the higher-frequency noise.

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Experimental and Computational Approach for Jet Noise Mitigation by Mixing Control Devices

Cited by 3 publications

References 0 publications

Overview of Jet Noise Measurement at JAXA

Overview of Jet Noise Measurement at JAXA

Computational Study of Noise Reduction in CFM56-5B Using Core Nozzle Chevrons

Jet mixing noise suppression by means of a claw mixer: Revision of the nail configuration to improve the high-frequency acoustic property

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