The data driven surrogate model based dynamic design of aero-engine fan systems
The data driven surrogate model based dynamic design of aero-engine fan systems
High cycle fatigue failures of fan blade systems due to vibrational loads are of great concern in the design of aero engines, where energy dissipation by the relative frictional motion in the dovetail joints provides the main damping to mitigate the vibrations. The performance of such a frictional damping can be enhanced by suitable coatings. However, the analysis and design of coated joint roots of gas turbine fan blades are computationally expensive due to strong contact friction nonlinearities and also complex physics involved in the dovetail. In this study, a data driven surrogate model, known as the Nonlinear in Parameter AutoRegressive with eXegenous input (NP-ARX) model, is introduced to circumvent the difficulties in the analysis and design of fan systems. The NP-ARX model is a linear input-output model, where the model coefficients are nonlinear functions of the design parameters of interest, such that the Frequency Response Function (FRF) can be directly obtained and used in the system analysis and design. A simplified fan bladed disc system is considered as the test case. The results show that by using the data driven surrogate model, an efficient and accurate design of aero-engine fan systems can be achieved. The approach is expected to be extended to solve the analysis and design problems of many other complex systems.
Zhu, Yun-Peng
363c26ba-f671-48f6-a771-26bf881d0d1a
Yuan, Jie
4bcf9ce8-3af4-4009-9cd0-067521894797
Lang, Z.Q.
dec658e4-f38f-43fc-b094-f68c43be3105
Schwingshackl, C.W.
9516c9c5-f9bb-4741-b530-9fe477c90473
Salles, Loic
7c9f2690-2631-4f32-9c2f-07659cf3f19c
Kadirkamanathan, V.
f4332f52-32d4-45c2-9de7-2bb5623a39ff
October 2021
Zhu, Yun-Peng
363c26ba-f671-48f6-a771-26bf881d0d1a
Yuan, Jie
4bcf9ce8-3af4-4009-9cd0-067521894797
Lang, Z.Q.
dec658e4-f38f-43fc-b094-f68c43be3105
Schwingshackl, C.W.
9516c9c5-f9bb-4741-b530-9fe477c90473
Salles, Loic
7c9f2690-2631-4f32-9c2f-07659cf3f19c
Kadirkamanathan, V.
f4332f52-32d4-45c2-9de7-2bb5623a39ff
Zhu, Yun-Peng, Yuan, Jie, Lang, Z.Q., Schwingshackl, C.W., Salles, Loic and Kadirkamanathan, V.
(2021)
The data driven surrogate model based dynamic design of aero-engine fan systems.
Journal of Engineering for Gas Turbines and Power, 143 (10), [101006].
(doi:10.1115/1.4049504).
Abstract
High cycle fatigue failures of fan blade systems due to vibrational loads are of great concern in the design of aero engines, where energy dissipation by the relative frictional motion in the dovetail joints provides the main damping to mitigate the vibrations. The performance of such a frictional damping can be enhanced by suitable coatings. However, the analysis and design of coated joint roots of gas turbine fan blades are computationally expensive due to strong contact friction nonlinearities and also complex physics involved in the dovetail. In this study, a data driven surrogate model, known as the Nonlinear in Parameter AutoRegressive with eXegenous input (NP-ARX) model, is introduced to circumvent the difficulties in the analysis and design of fan systems. The NP-ARX model is a linear input-output model, where the model coefficients are nonlinear functions of the design parameters of interest, such that the Frequency Response Function (FRF) can be directly obtained and used in the system analysis and design. A simplified fan bladed disc system is considered as the test case. The results show that by using the data driven surrogate model, an efficient and accurate design of aero-engine fan systems can be achieved. The approach is expected to be extended to solve the analysis and design problems of many other complex systems.
Text
FMANU-GTP-20-1487
- Accepted Manuscript
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e-pub ahead of print date: 9 August 2021
Published date: October 2021
Identifiers
Local EPrints ID: 478870
URI: http://eprints.soton.ac.uk/id/eprint/478870
ISSN: 0742-4795
PURE UUID: 766a5be3-19d7-426c-99ed-9d9f36c779b4
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Date deposited: 12 Jul 2023 16:30
Last modified: 17 Mar 2024 04:20
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Author:
Yun-Peng Zhu
Author:
Jie Yuan
Author:
Z.Q. Lang
Author:
C.W. Schwingshackl
Author:
Loic Salles
Author:
V. Kadirkamanathan
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