Nonlinear stability analysis and numerical continuation of bifurcations of a rotor supported by floating ring bearings

Amamou, Amira

doi:10.1177/09544062211026340

Cited by 3 publications

(2 citation statements)

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“…The method will be evaluated by comparing its results with the open-source sofware MATCONT [38], which is a numerical contination software based in MATLAB TM , and allows the study of a large range of bifurcations, including equilibria, limit-cycles and period-doubling. This software has been used by other authors to study bifurcations in rotors with fluid-film bearings before, e. g., [36,37,39,40]. In the MATCONT solutions, the full bearing force given by Eq.…”

Section: Resultsmentioning

confidence: 99%

“…In the CSSM, however, no linearization is performed, and the range of validity of the manifolds is in general bigger than in the CMR. This means that one can utilize the CSSM not only to study the Hopf bifurcations, but also the subsequent bifurcation of the limit cycles, which are known to occur in rotors with fluid-film bearings [36,37].…”

Section: Center Spectral Submanifoldmentioning

confidence: 99%

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Bifurcations and limit cycle prediction of rotor systems with fluid-film bearings using Spectral Submanifolds

Mereles

Alves

Cavalca

2023

Preprint

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Many rotating machines utilize a fluid type bearing. Despite their reliability and high load capacity, these bearings often show instabilities due to the interaction between the fluid media and the rotating shaft. These instabilities, known as oil-whirl and oil-whip, occur due to a Hopf bifurcation; being the parameter the shaft speed. Identifying the type of bifurcation, either sub-critical or super-critical, is an important task to determine the safety of the machines near the instability speed. This work presents an approach, labeled Center Spectral Submanifold (CSSM), to obtain limit cycles near Hopf bifurcations of rotors supported on fluid-film bearings. The basis of the method is the obtention of the center manifold of the system, which allows one to assess the type of bifurcation at hand. The CSSM is based on the idea of Spectral Submanifolds (SSMs) and the parameterization method, and it's a powerful tool to analyze the bifurcation of high-dimensional rotor systems. The method is evaluated by comparing its results with an open-source numerical continuation package (MATCONT) in two systems: a simple and a realistic rotor system. The results show that the CSSM can be used reliably to learn if the rotor system presents sub- or super-critical bifurcations, to perform parametric studies with different bearing properties and also to predict the amplitude of the limit cycles.

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Section: Resultsmentioning

confidence: 99%

Section: Center Spectral Submanifoldmentioning

confidence: 99%