Evaluation of Torsional Oscillations in Paper Machine Sections

Valenzuela, M. Aníbal; Bentley, J.M.; Lorenz, Robert D.

doi:10.1109/tia.2005.844383

Cited by 107 publications

(46 citation statements)

References 5 publications

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“…Interaction has been observed in a range of systems, for example sub-synchronous resonance in land based power generation [7,8] causing early fatigue of mechanical components [9], challenges for wind power generation [10,11] causing gearbox failure [12], unpredicted faults in industrial processes such as mills [13], excessive vibration in electric and hybrid-electric vehicle drivetrains [2,14] increasing wear [4], and wave induced instability in marine propulsion systems [15]. Methods for mitigating electro-mechanical interaction include minimising gearbox backlash [16], control scheme disturbance rejection [17] and repositioning of resonant modes through design [18]. However, the aero generator application discussed in this paper is particularly challenging.…”

Section: Introductionmentioning

confidence: 99%

Analysis of Electromechanical Interaction in Aircraft Generator Systems

Feehally

Damian

Apsley

2016

IEEE Trans. on Ind. Applicat.

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Abstract-The supply of electrical power is usually achieved by a generator, driven from a prime mover, by some form of mechanical drivetrain. Such an electro-mechanical system will have natural resonant modes in both the electrical and mechanical subsystems. The electrical generator provides a coupling between the subsystems, transferring not only useful power but also disturbances between electrical and mechanical domains: these disturbances may excite resonances resulting in cross-domain (electro-mechanical) interaction. This can lead to lifetime reduction in the mechanical components and instability in the electrical network, resulting in poor reliability for the wider system, and potentially catastrophic component failure. Electro-mechanical interaction is particularly critical in power generation systems onboard aircraft, because the generator is driven by a gas turbine via an inherently low-stiffness drive train. It is then critical to identify electro-mechanical interaction at the design stage so that these issues can be avoided. However, predicting the occurrence of interaction, through simulation, is challenging, requiring multi-domain models, operating with different time scales. This paper analyses an aircraft auxiliary power offtake to produce a reduced-order mechanical drivetrain model, allowing the modal frequencies to be predicted and crossdomain interactions to be modelled. A purpose-built electromechanical test platform is used to validate the model and demonstrate how electrical disturbances are passed through the generator to the mechanical system and affect the electrical network. Future research will use the test bed to demonstrate strategies for avoiding or suppressing unwanted interactions.

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Section: Introductionmentioning

confidence: 99%

Analysis of Electromechanical Interaction in Aircraft Generator Systems

Feehally

Damian

Apsley

2016

IEEE Trans. on Ind. Applicat.

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“…Also the performance of the machines used in textile industry is reduced by the non-ideal characteristics of the shaft (Beineke et al, 1997), (Wertz et al, 1999). An analogous problem appears in the paper machine sections (Valenzuela et al, 2005) and in modern servo-drives (Vukosovic & Stojic, 1998), (O'Sullivan et al, 2007), (Shen & Tsai, 2006). Moreover, torsional vibrations decrease the performance of the robot arms (Ferretti et al, 2004), (Huang & Chen, 2004).…”

Section: Introductionmentioning

confidence: 75%

Adaptive Control of the Electrical Drives with the Elastic Coupling using Kalman Filter

Szabat¹,

Orłowska-Kowalska²

2009

Adaptive Control

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“…This simplified approach has been used in different industrial applications [6][7][8]. Vibration suppression and high speed response control in motion control system is an important problem in industry applications [9][10][11]. Control problems of a multi-mass system is especially difficult when not all system variables are measurable, which happens very often in industrial applications [12,13].…”

Section: Introductionmentioning

confidence: 99%

Controller Design for Three-Mass Resonant System Based on Polynomial Method

Shahgholian¹

2017

IJSTS

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Abstract:The mechanical system in the industrial electrical drives can be modelled by a multi-mass system. Torsional vibration suppression and attainment of robustness in motion control systems is a requisite in industry applications. In this paper, the system that is three-mass system is considered. A speed control method based on polynomial method introduced to imple-mentation of torsional vibration is proposed. The effectiveness of the proposed controller is demonstrated by transfer function analysis and simulation results. The simulation results show that the proposed controller improves dynamic performance and suppresses torsional vibration of three-mass resonant system.

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Evaluation of Torsional Oscillations in Paper Machine Sections

Cited by 107 publications

References 5 publications

Analysis of Electromechanical Interaction in Aircraft Generator Systems

Analysis of Electromechanical Interaction in Aircraft Generator Systems

Adaptive Control of the Electrical Drives with the Elastic Coupling using Kalman Filter

Controller Design for Three-Mass Resonant System Based on Polynomial Method

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