Control of the breathing mechanism of a cracked rotor by using electro-magnetic actuator: numerical study

Morais, Tobias; Steffen, Valder; Mahfoud, Jarir

doi:10.1590/s1679-78252012000500004

Cited by 17 publications

(10 citation statements)

References 12 publications

(13 reference statements)

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“…is determined experimentally using a methodology proposed by [15]. The nominal gap is given by and is the gap due to the vibration of the rotor at the position of the electromagnetic actuator.…”

Section: Electromagnetic Actuatormentioning

confidence: 99%

“…The EMA uses the same principle of AMB, but only in terms of lateral contactless forces, since EMA is not used to support the rotor. The use of EMA results normally in a hybrid bearing [15]. There are many applications of EMA in AVC, such as the control of light structures [16], the attenuation of the oil whip instability effect to flexible hydrodynamically supported rotors [17], and the vibration attenuation using a tilting-pad journal bearing [18].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Numerical and Experimental Modal Control of Flexible Rotor Using Electromagnetic Actuator

Koroishi

Borges

Cavalini

et al. 2014

Mathematical Problems in Engineering

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The present work is dedicated to active modal control applied to flexible rotors. The effectiveness of the corresponding techniques for controlling a flexible rotor is tested numerically and experimentally. Two different approaches are used to determine the appropriate controllers. The first uses the linear quadratic regulator and the second approach is the fuzzy modal control. This paper is focused on the electromagnetic actuator, which in this case is part of a hybrid bearing. Due to numerical reasons it was necessary to reduce the size of the model of the rotating system so that the design of the controllers and estimator could be performed. The role of the Kalman estimator in the present contribution is to estimate the modal states of the system and to determine the displacement of the rotor at the position of the hybrid bearing. Finally, numerical and experimental results demonstrate the success of the methodology conveyed.

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Section: Electromagnetic Actuatormentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Numerical and Experimental Modal Control of Flexible Rotor Using Electromagnetic Actuator

Koroishi

Borges

Cavalini

et al. 2014

Mathematical Problems in Engineering

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“…For computational purposes, the finite element method is used to discretize the structure so that the energies calculated are concentrated at the nodal points. Shape functions are used to connect the nodal points (Morais et al, 2010). In this model, 4 degrees of freedom per node are taken into account, namely two displacements ( u and w ) and the cross-section rotations about axes x and z (denoted by w y     and u y     , respectively).…”

Section: Modeling Of Flexible Rotorsmentioning

confidence: 99%

Uncertainty analysis of flexible rotors considering fuzzy parameters and fuzzy-random parameters

Lara-Molina

Koroishi

Steffen

2015

Lat. Am. j. solids struct.

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The components of flexible rotors are subjected to uncertainties. The main sources of uncertainties include the variation of mechanical properties. This contribution aims at analyzing the dynamics of flexible rotors under uncertain parameters modeled as fuzzy and fuzzy random variables. The uncertainty analysis encompasses the modeling of uncertain parameters and the numerical simulation of the corresponding flexible rotor model by using an approach based on fuzzy dynamic analysis. The numerical simulation is accomplished by mapping the fuzzy parameters of the deterministic flexible rotor model. Thereby, the flexible rotor is modeled by using both the Fuzzy Finite Element Method and the Fuzzy Stochastic Finite Element Method. Numerical simulations illustrate the methodology conveyed in terms of orbits and frequency response functions subject to uncertain parameters.

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“…Cavalini and his coworkers [33] used Timoshenko shaft elements in a finite element model of a flexible rotor, which they updated using their proposed technique [34]. Morais et al [35] developed a numerical model of a rotor using the Timoshenko beam and controlled its dynamic behavior through electromagnetic actuation. Timoshenko beam theory is used by Dakel et al [36] to study the behavior of rotors mounted on hydrodynamic journal bearing subjected to rigid support movement.…”

Section: Introductionmentioning

confidence: 99%

A shaft finite element for analysis of viscoelastic tapered Timoshenko rotors

Bhowmick

Ganguly²,

Neogy

et al. 2019

J Braz. Soc. Mech. Sci. Eng.

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Finite element modeling of thick rotor (deep rotor) requires the use of the Timoshenko element, which takes care of shear deformation. Modeling a rotor whose cross section varies can be done using uniform stepped cylindrical elements, but the number of elements required for the converged results is enormous. Further modeling of doubly tapered rotors and rotors with sharp changes in taper angle using such methods become difficult and does not appear feasible that is why the formulation of conical rotor elements is necessary. The complexity in formulations arises due to the presence of the shear parameter in the denominator. Till now, in the literature of the Timoshenko rotor, geometric properties are taken to be linearly varying; the shear parameter is the approximation of average values of two end nodes. On the other hand, the modeling of damping in rotors becomes essential as it controls the stability limit. The present paper develops three different viscoelastic tapered rotor elements using the Maxwell-Wiechert model. While the first element (VTRE 1) uses the average shear parameter, the second element (VTRE 2) uses a higher degree polynomial to approximate the shear parameter. While the first two-rotor elements are solid, the third element (VTRE 3) is hollow. Results show that viscoelastic tapered elements provide better results with the lesser number of elements. For the rotor with a large taper angle, VTRE 2 performs better than VTRE 1. Further modeling of the hollow tapered rotor with a linear variation of taper angle and discontinuities at definite points is not possible by the use of uniform elements. Modeling such a rotor using VTRE 3 is rendered simple. Practical usage of such rotors further enhances the importance of the present work.

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Control of the breathing mechanism of a cracked rotor by using electro-magnetic actuator: numerical study

Cited by 17 publications

References 12 publications

Numerical and Experimental Modal Control of Flexible Rotor Using Electromagnetic Actuator

Numerical and Experimental Modal Control of Flexible Rotor Using Electromagnetic Actuator

Uncertainty analysis of flexible rotors considering fuzzy parameters and fuzzy-random parameters

A shaft finite element for analysis of viscoelastic tapered Timoshenko rotors

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