Dynamic Model for Hydro-Turbine Generator Units Based on a Database Method for Guide Bearings

Xu, Yong; Li, Zhaohui; Lai, Xide

doi:10.1155/2013/426849

Cited by 17 publications

(17 citation statements)

References 11 publications

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“…The second way used a linear model, where the journal bearing dynamic coefficients were determined under the operating conditions that provide the highest coincidence between the characteristic frequencies of both linear and nonlinear models. Xu et al [19] also used a nonlinear model, reducing the processing time by means of a database containing the journal bearings forces calculated previously for the several possible operating conditions.…”

Section: Remarks On Lhg Modelsmentioning

confidence: 99%

“…In most of the references, the journal bearing dynamic coefficients were obtained using Reynolds bearing model, solving Reynolds equation by the Finite Difference Method (FDM). Nevertheless, Xu et al [19] used the Bently-Muszynska bearing model [22] and Wang et al [23] solved Reynolds equation using an approximated analytical solution through the Variable Separation Method. LHG shafts are modeled using Bernoulli beam element [11] or Timoshenko beam element [19].…”

Section: Remarks On Lhg Modelsmentioning

confidence: 99%

“…Nevertheless, Xu et al [19] used the Bently-Muszynska bearing model [22] and Wang et al [23] solved Reynolds equation using an approximated analytical solution through the Variable Separation Method. LHG shafts are modeled using Bernoulli beam element [11] or Timoshenko beam element [19]. The Finite Element Method (FEM) was used in many of the recent articles, while the Transfer Matrix Method (TMM) is encountered in some older references [14,24].…”

Section: Remarks On Lhg Modelsmentioning

confidence: 99%

See 2 more Smart Citations

Using Simplified Models to Assist Fault Detection and Diagnosis in Large Hydrogenerators

Brito

Machado

Neto

2017

International Journal of Rotating Machinery

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Based on experimental evidence collected in a set of twenty 700 MW hydrogenerators, this article shows that the operating conditions of large hydrogenerators journal bearings may have unpredictable and significant changes, without apparent reasons. These changes prevent the accurate determination of bearing dynamic coefficients and make the prediction of these machines dynamic behavior unfeasible, even using refined models. This makes it difficult to differentiate the normal changes in hydrogenerators dynamics from the changes created by a fault event. To overcome such difficulty, this article proposes a back-to-basics step, the using of simplified mathematical models to assist hydrogenerators vibration monitoring and exemplifies this proposal by modeling a 700 MW hydrogenerator. A first model estimates the influence of changes in bearing operating conditions in the bearing stiffnesses, considering only the hydrodynamic effects of an isoviscous oil film with linear thickness distribution. A second model simulates hydrogenerators dynamics using only 10 degrees of freedom, giving the monitored vibrations as outputs, under normal operating conditions or in the presence of a fault. This article shows that simplified models may give satisfactory results when bearing operating conditions are properly determined, results comparable to those obtained by more refined models or by measurements in the modeled hydrogenerator.

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Section: Remarks On Lhg Modelsmentioning

confidence: 99%

Section: Remarks On Lhg Modelsmentioning

confidence: 99%

Section: Remarks On Lhg Modelsmentioning

confidence: 99%

See 1 more Smart Citation

Using Simplified Models to Assist Fault Detection and Diagnosis in Large Hydrogenerators

Brito

Machado

Neto

2017

International Journal of Rotating Machinery

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“…The physical models are often used to analyze the phenomenon and the characteristics of the faults of the HTG to obtain the principles of the faults. [14] presented a dynamic model for radial vibration of hydro turbine generator units to assist the machine health monitoring. A finite element (FE) rotor dynamic model of radial vibration taking account of operating conditions is proposed to deal with the complex boundary conditions and exciting forces.…”

Section: A Physical Modelsmentioning

confidence: 99%

A Review on Data-driven Predictive Maintenance Approach for Hydro Turbines/Generators

Wang¹,

Wang²,

Li³

2016

Proceedings of the 6th International Workshop of Advanced Manufacturing and Automation

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Abstract-Hydroelectricity as a renewable energy to respond the increasing population and environment crisis is widely used in the world. With the Hydro Turbines/Generators (HTG) being more and more complicated, the maintenance play a more and more important role in the production management in the hydro power plant. Many researches had concentrated on the predictive maintenance for the HTG in recent years. From the perspective of data-driven, this paper reviews and summarizes the key techniques regarding data acquisition, data processing, data analysis and data mining for the predictive maintenance of HTG. Especially, it place emphasis on the data-driven models for the diagnostics and prognostics. Finally, the paper concludes the current practices and presents a future research work.

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“…However, as we all know, the hydroturbine regulating system is integration of hydraulic, mechanical, and electrical parts. This complex composition makes it a strong coupling, nonlinear, and nonminimum phase system [10][11][12]. So the integer-order model may not be suitable for perfectly describing the hydroturbine regulating system.…”

Section: Introductionmentioning

confidence: 99%

Robust Fuzzy Control for Fractional-Order Uncertain Hydroturbine Regulating System with Random Disturbances

Zhang

Wang

2016

Mathematical Problems in Engineering

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The robust fuzzy control for fractional-order hydroturbine regulating system is studied in this paper. First, the more practical fractional-order hydroturbine regulating system with uncertain parameters and random disturbances is presented. Then, on the basis of interval matrix theory and fractional-order stability theorem, a fuzzy control method is proposed for fractional-order hydroturbine regulating system, and the stability condition is expressed as a group of linear matrix inequalities. Furthermore, the proposed method has good robustness which can process external random disturbances and uncertain parameters. Finally, the validity and superiority are proved by the numerical simulations.

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Dynamic Model for Hydro-Turbine Generator Units Based on a Database Method for Guide Bearings

Cited by 17 publications

References 11 publications

Using Simplified Models to Assist Fault Detection and Diagnosis in Large Hydrogenerators

Using Simplified Models to Assist Fault Detection and Diagnosis in Large Hydrogenerators

A Review on Data-driven Predictive Maintenance Approach for Hydro Turbines/Generators

Robust Fuzzy Control for Fractional-Order Uncertain Hydroturbine Regulating System with Random Disturbances

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