The side-wall cooling liner in a gas turbine combustor serves main purposes—heat transfer and emission control. Additionally, it functions as a passive damper to attenuate thermoacoustic instabilities. The perforations in the liner mainly convert acoustic energy into kinetic energy through vortex shedding at the orifice rims. In the previous decades, several analytical and semi-empirical models have been proposed to predict the acoustic damping of the perforated liner. In the current study, a few of the models are considered to embody the transfer matrix method (TMM) for analyzing the acoustic dissipation in a concentric tube resonator with a perforated element and validated against experimental data in the literature. All models are shown to quantitatively appropriately predict the acoustic behavior under high bias flow velocity conditions. Then, the models are applied to maximize the damping performance in a realistic gas turbine combustor, which is under development. It is found that the ratio of the bias flow Mach number to the porosity can be used as a design guideline in choosing the optimal combination of the number and diameter of perforations in terms of acoustic damping.
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December 2018
Research-Article
Design of Acoustic Liner in Small Gas Turbine Combustor Using One-Dimensional Impedance Models
Daesik Kim,
Daesik Kim
School of Mechanical and
Automotive Engineering,
Gangneung-Wonju National University,
150 Namwon-ro, Wonju 26403,
Gangwon, South Korea
e-mail: dkim@gwnu.ac.kr
Automotive Engineering,
Gangneung-Wonju National University,
150 Namwon-ro, Wonju 26403,
Gangwon, South Korea
e-mail: dkim@gwnu.ac.kr
Search for other works by this author on:
Seungchai Jung,
Seungchai Jung
Gas Turbine Development Team,
Hanwha Aerospace R&D Center,
471 Pangyo, Bundang, Seongnam 13521,
Gyeonggi, South Korea
Hanwha Aerospace R&D Center,
471 Pangyo, Bundang, Seongnam 13521,
Gyeonggi, South Korea
Search for other works by this author on:
Heeho Park
Heeho Park
Gas Turbine Development Team,
Hanwha Aerospace R&D Center,
471 Pangyo, Bundang, Seongnam 13521,
Gyeonggi, South Korea
Hanwha Aerospace R&D Center,
471 Pangyo, Bundang, Seongnam 13521,
Gyeonggi, South Korea
Search for other works by this author on:
Daesik Kim
School of Mechanical and
Automotive Engineering,
Gangneung-Wonju National University,
150 Namwon-ro, Wonju 26403,
Gangwon, South Korea
e-mail: dkim@gwnu.ac.kr
Automotive Engineering,
Gangneung-Wonju National University,
150 Namwon-ro, Wonju 26403,
Gangwon, South Korea
e-mail: dkim@gwnu.ac.kr
Seungchai Jung
Gas Turbine Development Team,
Hanwha Aerospace R&D Center,
471 Pangyo, Bundang, Seongnam 13521,
Gyeonggi, South Korea
Hanwha Aerospace R&D Center,
471 Pangyo, Bundang, Seongnam 13521,
Gyeonggi, South Korea
Heeho Park
Gas Turbine Development Team,
Hanwha Aerospace R&D Center,
471 Pangyo, Bundang, Seongnam 13521,
Gyeonggi, South Korea
Hanwha Aerospace R&D Center,
471 Pangyo, Bundang, Seongnam 13521,
Gyeonggi, South Korea
1Corresponding author.
Contributed by the Combustion and Fuels Committee of ASME for publication in the JOURNAL OF ENGINEERING FOR GAS TURBINES AND POWER. Manuscript received February 23, 2018; final manuscript received June 27, 2018; published online August 20, 2018. Assoc. Editor: Riccardo Da Soghe.
J. Eng. Gas Turbines Power. Dec 2018, 140(12): 121505 (11 pages)
Published Online: August 20, 2018
Article history
Received:
February 23, 2018
Revised:
June 27, 2018
Citation
Kim, D., Jung, S., and Park, H. (August 20, 2018). "Design of Acoustic Liner in Small Gas Turbine Combustor Using One-Dimensional Impedance Models." ASME. J. Eng. Gas Turbines Power. December 2018; 140(12): 121505. https://doi.org/10.1115/1.4040765
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