Forced Vibration Analysis of Rotating Blades Subjected to Large Deformations: A Numerical Investigation With VIBRANT

Mertol Tufekci

doi:10.1115/SSDM2025-152240

Forced Vibration Analysis of Rotating Blades Subjected to Large Deformations: A Numerical Investigation With VIBRANT

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

Abstract

Rotating blades in aircraft engines and wind turbines are critical components subjected to dynamic loads that can cause significant deformations. Accurate analysis of their forced vibration behaviour under large deformations is essential for ensuring performance and structural integrity. This study utilises the Vibration BehaviouR ANalysis Tool (VIBRANT) to investigate complex nonlinearities in blade systems, including large deformation scenarios. Through academic examples, VIBRANT demonstrates its reliability and capability to model nonlinear behaviours, including modal coupling and resonance phenomena. The analysis explores the influence of parameters such as blade geometry and material type, including metallic alloys (e.g., aluminium and titanium) and composites. Detailed frequency response analyses reveal the importance of accurately modelling interactions between material properties and geometric configurations. Comparative results highlight the impact of design choices on natural frequencies, mode shapes, and damping efficiency. VIBRANT’s ability to handle large deformations, combined with its flexibility and efficiency, positions it as a powerful tool for engineers and researchers. Its user-friendly structure and robust performance make it suitable for designing and optimising rotating blade systems across various industries while maintaining computational efficiency.

Original language	English
Title of host publication	Proceedings of the ASME 2025 Aerospace Structures, Structural Dynamics, and Materials Conference SSDM2025
Place of Publication	USA
Publisher	American Society of Mechanical Engineers (ASME)
Pages	1-10
Number of pages	10
ISBN (Print)	978-0-7918-8875-9
DOIs	https://doi.org/10.1115/SSDM2025-152240
Publication status	Published - 11 Jun 2025
Event	ASME's 3rd Annual Aerospace Structures, Structural Dynamics, and Materials Conference (SSDM) 2025 - The Westin Houston, Memorial City, Houston, United States Duration: 5 May 2025 → 7 May 2025 Conference number: 3 https://event.asme.org/SSDM

Conference

Conference	ASME's 3rd Annual Aerospace Structures, Structural Dynamics, and Materials Conference (SSDM) 2025
Abbreviated title	ASME SSDM 2025
Country/Territory	United States
City	Houston
Period	5/05/25 → 7/05/25
Internet address	https://event.asme.org/SSDM

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10.1115/SSDM2025-152240Licence: Unspecified

Accepted_Manuscript
© 2025 The American Society of Mechanical Engineers (ASME). All rights reserved. This is the accepted manuscript version of an article which has been published in final form at https://doi.org/10.1115/SSDM2025-152240
Accepted author manuscript, 1.95 MBLicence: CC BY

Cite this

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title = "Forced Vibration Analysis of Rotating Blades Subjected to Large Deformations: A Numerical Investigation With VIBRANT",

abstract = "Rotating blades in aircraft engines and wind turbines are critical components subjected to dynamic loads that can cause significant deformations. Accurate analysis of their forced vibration behaviour under large deformations is essential for ensuring performance and structural integrity. This study utilises the Vibration BehaviouR ANalysis Tool (VIBRANT) to investigate complex nonlinearities in blade systems, including large deformation scenarios. Through academic examples, VIBRANT demonstrates its reliability and capability to model nonlinear behaviours, including modal coupling and resonance phenomena. The analysis explores the influence of parameters such as blade geometry and material type, including metallic alloys (e.g., aluminium and titanium) and composites. Detailed frequency response analyses reveal the importance of accurately modelling interactions between material properties and geometric configurations. Comparative results highlight the impact of design choices on natural frequencies, mode shapes, and damping efficiency. VIBRANT{\textquoteright}s ability to handle large deformations, combined with its flexibility and efficiency, positions it as a powerful tool for engineers and researchers. Its user-friendly structure and robust performance make it suitable for designing and optimising rotating blade systems across various industries while maintaining computational efficiency.",

author = "Mertol Tufekci",

note = "{\textcopyright} 2025 The American Society of Mechanical Engineers (ASME). All rights reserved. This is the accepted manuscript version of an article which has been published in final form at https://doi.org/10.1115/SSDM2025-152240; ASME's 3rd Annual Aerospace Structures, Structural Dynamics, and Materials Conference (SSDM) 2025, ASME SSDM 2025 ; Conference date: 05-05-2025 Through 07-05-2025",

year = "2025",

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doi = "10.1115/SSDM2025-152240",

language = "English",

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pages = "1--10",

booktitle = "Proceedings of the ASME 2025 Aerospace Structures, Structural Dynamics, and Materials Conference SSDM2025",

publisher = "American Society of Mechanical Engineers (ASME)",

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Tufekci, M 2025, Forced Vibration Analysis of Rotating Blades Subjected to Large Deformations: A Numerical Investigation With VIBRANT. in Proceedings of the ASME 2025 Aerospace Structures, Structural Dynamics, and Materials Conference SSDM2025., 152240, American Society of Mechanical Engineers (ASME), USA, pp. 1-10, ASME's 3rd Annual Aerospace Structures, Structural Dynamics, and Materials Conference (SSDM) 2025, Houston, Texas, United States, 5/05/25. https://doi.org/10.1115/SSDM2025-152240

Forced Vibration Analysis of Rotating Blades Subjected to Large Deformations: A Numerical Investigation With VIBRANT. / Tufekci, Mertol.
Proceedings of the ASME 2025 Aerospace Structures, Structural Dynamics, and Materials Conference SSDM2025. USA: American Society of Mechanical Engineers (ASME), 2025. p. 1-10 152240.

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

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T1 - Forced Vibration Analysis of Rotating Blades Subjected to Large Deformations: A Numerical Investigation With VIBRANT

AU - Tufekci, Mertol

N1 - Conference code: 3

PY - 2025/6/11

Y1 - 2025/6/11

N2 - Rotating blades in aircraft engines and wind turbines are critical components subjected to dynamic loads that can cause significant deformations. Accurate analysis of their forced vibration behaviour under large deformations is essential for ensuring performance and structural integrity. This study utilises the Vibration BehaviouR ANalysis Tool (VIBRANT) to investigate complex nonlinearities in blade systems, including large deformation scenarios. Through academic examples, VIBRANT demonstrates its reliability and capability to model nonlinear behaviours, including modal coupling and resonance phenomena. The analysis explores the influence of parameters such as blade geometry and material type, including metallic alloys (e.g., aluminium and titanium) and composites. Detailed frequency response analyses reveal the importance of accurately modelling interactions between material properties and geometric configurations. Comparative results highlight the impact of design choices on natural frequencies, mode shapes, and damping efficiency. VIBRANT’s ability to handle large deformations, combined with its flexibility and efficiency, positions it as a powerful tool for engineers and researchers. Its user-friendly structure and robust performance make it suitable for designing and optimising rotating blade systems across various industries while maintaining computational efficiency.

AB - Rotating blades in aircraft engines and wind turbines are critical components subjected to dynamic loads that can cause significant deformations. Accurate analysis of their forced vibration behaviour under large deformations is essential for ensuring performance and structural integrity. This study utilises the Vibration BehaviouR ANalysis Tool (VIBRANT) to investigate complex nonlinearities in blade systems, including large deformation scenarios. Through academic examples, VIBRANT demonstrates its reliability and capability to model nonlinear behaviours, including modal coupling and resonance phenomena. The analysis explores the influence of parameters such as blade geometry and material type, including metallic alloys (e.g., aluminium and titanium) and composites. Detailed frequency response analyses reveal the importance of accurately modelling interactions between material properties and geometric configurations. Comparative results highlight the impact of design choices on natural frequencies, mode shapes, and damping efficiency. VIBRANT’s ability to handle large deformations, combined with its flexibility and efficiency, positions it as a powerful tool for engineers and researchers. Its user-friendly structure and robust performance make it suitable for designing and optimising rotating blade systems across various industries while maintaining computational efficiency.

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M3 - Conference contribution

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BT - Proceedings of the ASME 2025 Aerospace Structures, Structural Dynamics, and Materials Conference SSDM2025

PB - American Society of Mechanical Engineers (ASME)

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Y2 - 5 May 2025 through 7 May 2025

ER -

Forced Vibration Analysis of Rotating Blades Subjected to Large Deformations: A Numerical Investigation With VIBRANT

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