Reduced order method based on an adaptive formulation and its application to fan blade system with dovetail joints

Jie Yuan; Christoph Schwingshackl; Loic Salles; Chian Wong; Sophoclis Patsias

doi:10.1115/GT2020-14227

Reduced order method based on an adaptive formulation and its application to fan blade system with dovetail joints

Jie Yuan^*, Christoph Schwingshackl, Loic Salles, Chian Wong, Sophoclis Patsias

^*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution book

2 Citations (Scopus)

29 Downloads (Pure)

Abstract

Localized nonlinearities due to the contact friction interfaces are widely present in the aero-engine structures. They can significantly reduce the vibration amplitudes and shift the resonance frequencies away from critical operating speeds, by exploiting the frictional energy dissipation at the contact interface. However, the modelling capability to predict the dynamics of such large-scale systems with these nonlinearities is often impeded by the high computational expense. Component mode synthesis (CMS) based reduced order modelling (ROM) are commonly used to overcome this problem in jointed structures. However, the computational efficiency of these classical ROMs are sometimes limited as their size is proportional to the DOFs of joint interfaces resulting in a full dense matrix. A new ROM based on an adaptive formulation is proposed in this paper to improve the CMS methods for reliable predictions of the dynamics in jointed structures. This new ROM approach is able to adaptively switch the sticking contact nodes off during the online computation leading to a significant size reduction comparing to the CMS based models. The large-scale high fidelity fan blade assembly is used as the case study. The forced response obtained from the novel ROM is compared to the state-of-the-art CMS based Craig-Bampton method. A parametric study is then carried out to assess the influence of the contact parameters on the dynamics of the fan assembly. The feasibility of using this proposed method for nonlinear modal analysis is also characterised.

Original language	English
Title of host publication	Proceedings of the ASME Turbo Expo 2020: Turbomachinery Technical Conference and Exposition
Subtitle of host publication	Structures and Dynamics: Structural Mechanics, Vibration, and Damping; Supercritical CO2
Place of Publication	New York
Publisher	American Society of Mechanical Engineers(ASME)
Chapter	V011T30A004
Number of pages	11
Volume	11
ISBN (Print)	978-0-7918-8423-2
DOIs	https://doi.org/10.1115/GT2020-14227
Publication status	Published - 11 Jan 2021
Externally published	Yes
Event	ASME Turbo Expo 2020: Turbomachinery Technical Conference and Exposition - Virtual, Online Duration: 21 Sept 2020 → 25 Sept 2020 https://event.asme.org/Turbo-Expo-2020

Conference

Conference	ASME Turbo Expo 2020
City	Virtual, Online
Period	21/09/20 → 25/09/20
Internet address	https://event.asme.org/Turbo-Expo-2020

Funding

The authors are grateful to the support of Rolls-Royce plc and Innovate UK through GEMiniDS WP3 project 113088 and EPSRC through SYSDYMATS WP3 project R032793. L. Salles thanks Rolls-Royce plc and the EPSRC for the support under the Prosperity Partnership Grant ”Cornerstone: Mechanical Engineering Science to Enable Aero Propulsion Futures” EP/R004951/1.

Keywords

reduced order method
adaptive formulation
application
fan blade system
dovetail joints

Access to Document

10.1115/GT2020-14227

Yuan-etal-ASMETE-2020-Reduced-order-method-based-on-an-adaptive-formulation-and-its-application-to-fan-blade-systemAccepted author manuscript, 984 KB

Cite this

Yuan, J., Schwingshackl, C., Salles, L., Wong, C., & Patsias, S. (2021). Reduced order method based on an adaptive formulation and its application to fan blade system with dovetail joints. In Proceedings of the ASME Turbo Expo 2020: Turbomachinery Technical Conference and Exposition: Structures and Dynamics: Structural Mechanics, Vibration, and Damping; Supercritical CO2 (Vol. 11). American Society of Mechanical Engineers(ASME). https://doi.org/10.1115/GT2020-14227

Yuan, Jie ; Schwingshackl, Christoph ; Salles, Loic et al. / Reduced order method based on an adaptive formulation and its application to fan blade system with dovetail joints. Proceedings of the ASME Turbo Expo 2020: Turbomachinery Technical Conference and Exposition: Structures and Dynamics: Structural Mechanics, Vibration, and Damping; Supercritical CO2. Vol. 11 New York : American Society of Mechanical Engineers(ASME), 2021.

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title = "Reduced order method based on an adaptive formulation and its application to fan blade system with dovetail joints",

abstract = "Localized nonlinearities due to the contact friction interfaces are widely present in the aero-engine structures. They can significantly reduce the vibration amplitudes and shift the resonance frequencies away from critical operating speeds, by exploiting the frictional energy dissipation at the contact interface. However, the modelling capability to predict the dynamics of such large-scale systems with these nonlinearities is often impeded by the high computational expense. Component mode synthesis (CMS) based reduced order modelling (ROM) are commonly used to overcome this problem in jointed structures. However, the computational efficiency of these classical ROMs are sometimes limited as their size is proportional to the DOFs of joint interfaces resulting in a full dense matrix. A new ROM based on an adaptive formulation is proposed in this paper to improve the CMS methods for reliable predictions of the dynamics in jointed structures. This new ROM approach is able to adaptively switch the sticking contact nodes off during the online computation leading to a significant size reduction comparing to the CMS based models. The large-scale high fidelity fan blade assembly is used as the case study. The forced response obtained from the novel ROM is compared to the state-of-the-art CMS based Craig-Bampton method. A parametric study is then carried out to assess the influence of the contact parameters on the dynamics of the fan assembly. The feasibility of using this proposed method for nonlinear modal analysis is also characterised.",

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author = "Jie Yuan and Christoph Schwingshackl and Loic Salles and Chian Wong and Sophoclis Patsias",

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Yuan, J, Schwingshackl, C, Salles, L, Wong, C & Patsias, S 2021, Reduced order method based on an adaptive formulation and its application to fan blade system with dovetail joints. in Proceedings of the ASME Turbo Expo 2020: Turbomachinery Technical Conference and Exposition: Structures and Dynamics: Structural Mechanics, Vibration, and Damping; Supercritical CO2. vol. 11, American Society of Mechanical Engineers(ASME), New York, ASME Turbo Expo 2020, Virtual, Online, 21/09/20. https://doi.org/10.1115/GT2020-14227

Reduced order method based on an adaptive formulation and its application to fan blade system with dovetail joints. / Yuan, Jie; Schwingshackl, Christoph; Salles, Loic et al.
Proceedings of the ASME Turbo Expo 2020: Turbomachinery Technical Conference and Exposition: Structures and Dynamics: Structural Mechanics, Vibration, and Damping; Supercritical CO2. Vol. 11 New York: American Society of Mechanical Engineers(ASME), 2021.

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution book

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T1 - Reduced order method based on an adaptive formulation and its application to fan blade system with dovetail joints

AU - Yuan, Jie

AU - Schwingshackl, Christoph

AU - Salles, Loic

AU - Wong, Chian

AU - Patsias, Sophoclis

PY - 2021/1/11

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N2 - Localized nonlinearities due to the contact friction interfaces are widely present in the aero-engine structures. They can significantly reduce the vibration amplitudes and shift the resonance frequencies away from critical operating speeds, by exploiting the frictional energy dissipation at the contact interface. However, the modelling capability to predict the dynamics of such large-scale systems with these nonlinearities is often impeded by the high computational expense. Component mode synthesis (CMS) based reduced order modelling (ROM) are commonly used to overcome this problem in jointed structures. However, the computational efficiency of these classical ROMs are sometimes limited as their size is proportional to the DOFs of joint interfaces resulting in a full dense matrix. A new ROM based on an adaptive formulation is proposed in this paper to improve the CMS methods for reliable predictions of the dynamics in jointed structures. This new ROM approach is able to adaptively switch the sticking contact nodes off during the online computation leading to a significant size reduction comparing to the CMS based models. The large-scale high fidelity fan blade assembly is used as the case study. The forced response obtained from the novel ROM is compared to the state-of-the-art CMS based Craig-Bampton method. A parametric study is then carried out to assess the influence of the contact parameters on the dynamics of the fan assembly. The feasibility of using this proposed method for nonlinear modal analysis is also characterised.

AB - Localized nonlinearities due to the contact friction interfaces are widely present in the aero-engine structures. They can significantly reduce the vibration amplitudes and shift the resonance frequencies away from critical operating speeds, by exploiting the frictional energy dissipation at the contact interface. However, the modelling capability to predict the dynamics of such large-scale systems with these nonlinearities is often impeded by the high computational expense. Component mode synthesis (CMS) based reduced order modelling (ROM) are commonly used to overcome this problem in jointed structures. However, the computational efficiency of these classical ROMs are sometimes limited as their size is proportional to the DOFs of joint interfaces resulting in a full dense matrix. A new ROM based on an adaptive formulation is proposed in this paper to improve the CMS methods for reliable predictions of the dynamics in jointed structures. This new ROM approach is able to adaptively switch the sticking contact nodes off during the online computation leading to a significant size reduction comparing to the CMS based models. The large-scale high fidelity fan blade assembly is used as the case study. The forced response obtained from the novel ROM is compared to the state-of-the-art CMS based Craig-Bampton method. A parametric study is then carried out to assess the influence of the contact parameters on the dynamics of the fan assembly. The feasibility of using this proposed method for nonlinear modal analysis is also characterised.

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KW - dovetail joints

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Yuan J, Schwingshackl C, Salles L, Wong C, Patsias S. Reduced order method based on an adaptive formulation and its application to fan blade system with dovetail joints. In Proceedings of the ASME Turbo Expo 2020: Turbomachinery Technical Conference and Exposition: Structures and Dynamics: Structural Mechanics, Vibration, and Damping; Supercritical CO2. Vol. 11. New York: American Society of Mechanical Engineers(ASME). 2021 Epub 2020 Sept 25. doi: 10.1115/GT2020-14227

Reduced order method based on an adaptive formulation and its application to fan blade system with dovetail joints

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