Flutter analysis of blisks with friction ring dampers
Flutter analysis of blisks with friction ring dampers
Aeroelastic flutter is a phenomenon when blades experience an aeroelastic self-excitation from the surrounding air resulting in the full destruction of aero-engines. It poses a big challenge for aero-engine bladed-disks design, especially for integrally bladed-disks (blisks). The lack of friction interfaces in blisks drastically reduces structural damping making them more likely to experience aeroelastic flutter. One of the most effective approaches to improve the damping in a blisk is the use of friction ring dampers. This paper presents a numerical study to investigate the effects of friction ring dampers on the aeroelastic stability of blisks. A lumped parameter model is used to represent the blisk with a ring damper. Aeroelastic self-excitations are simply represented by Van der Pol oscillators. The frictional contact between the blisk and ring damper is modelled by using Jenkins elements. Nonlinear modal analysis is used to compute the nonlinear dynamic response of the system. The results show that the friction ring damper can significantly reduce the risk of flutter and the amplitude of flutter induced limit cycle oscillations for a blisk by increasing the structural damping, especially at a high modal amplitude. The study also shows that the nonlinear modal analysis can efficiently identify the flutter boundary of such a strongly dissipated nonlinear system.
Global Power & Propulsion Society
Sun, Yekai
181c2a74-70e7-40ba-a016-664fb87dd74f
Yuan, Jie
4bcf9ce8-3af4-4009-9cd0-067521894797
Salles, Loïc
7c9f2690-2631-4f32-9c2f-07659cf3f19c
20 October 2021
Sun, Yekai
181c2a74-70e7-40ba-a016-664fb87dd74f
Yuan, Jie
4bcf9ce8-3af4-4009-9cd0-067521894797
Salles, Loïc
7c9f2690-2631-4f32-9c2f-07659cf3f19c
Sun, Yekai, Yuan, Jie and Salles, Loïc
(2021)
Flutter analysis of blisks with friction ring dampers.
In,
Proceedings of the Global Power & Propulsion Society 2021.
(Global Power and Propulsion Society Proceedings)
Global Power and Propulsion Society International Technical Conference (18/10/21 - 20/10/21)
Global Power & Propulsion Society.
Record type:
Book Section
Abstract
Aeroelastic flutter is a phenomenon when blades experience an aeroelastic self-excitation from the surrounding air resulting in the full destruction of aero-engines. It poses a big challenge for aero-engine bladed-disks design, especially for integrally bladed-disks (blisks). The lack of friction interfaces in blisks drastically reduces structural damping making them more likely to experience aeroelastic flutter. One of the most effective approaches to improve the damping in a blisk is the use of friction ring dampers. This paper presents a numerical study to investigate the effects of friction ring dampers on the aeroelastic stability of blisks. A lumped parameter model is used to represent the blisk with a ring damper. Aeroelastic self-excitations are simply represented by Van der Pol oscillators. The frictional contact between the blisk and ring damper is modelled by using Jenkins elements. Nonlinear modal analysis is used to compute the nonlinear dynamic response of the system. The results show that the friction ring damper can significantly reduce the risk of flutter and the amplitude of flutter induced limit cycle oscillations for a blisk by increasing the structural damping, especially at a high modal amplitude. The study also shows that the nonlinear modal analysis can efficiently identify the flutter boundary of such a strongly dissipated nonlinear system.
Text
GPPS-TC-2021-0042-YSUN
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Published date: 20 October 2021
Venue - Dates:
Global Power and Propulsion Society International Technical Conference, , Xi'an, China, 2021-10-18 - 2021-10-20
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Local EPrints ID: 479402
URI: http://eprints.soton.ac.uk/id/eprint/479402
PURE UUID: 7a921247-9ff0-4e6a-8c52-97b801486b6e
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Date deposited: 21 Jul 2023 16:32
Last modified: 17 Mar 2024 04:20
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Contributors
Author:
Yekai Sun
Author:
Jie Yuan
Author:
Loïc Salles
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