Low-Computational-Cost Hybrid FEM-Analytical Induction Machine Model for the Diagnosis of Rotor Eccentricity, Based on Sparse Identification Techniques and Trigonometric Interpolation.

Carla Terron-Santiago,Javier Martinez-Roman,Angel Sapena-Bano,Ruben Puche-Panadero

doi:10.3390/s21216963

Carla Terron-Santiago, Javier Martinez-Roman + Show 2 more

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https://doi.org/10.3390/s21216963

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Journal: Sensors	Publication Date: Oct 20, 2021
Citations: 4	License type: CC BY 4.0

Affiliation: Universitat Politècnica de València

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Since it is not efficient to physically study many machine failures, models of faulty induction machines (IMs) have attracted a rising interest. These models must be accurate enough to include fault effects and must be computed with relatively low resources to reproduce different fault scenarios. Moreover, they should run in real time to develop online condition-monitoring (CM) systems. Hybrid finite element method (FEM)-analytical models have been recently proposed for fault diagnosis purposes since they keep good accuracy, which is widely accepted, and they can run in real-time simulators. However, these models still require the full simulation of the FEM model to compute the parameters of the analytical model for each faulty scenario with its corresponding computing needs. To address these drawbacks (large computing power and memory resources requirements) this paper proposes sparse identification techniques in combination with the trigonometric interpolation polynomial for the computation of IM model parameters. The proposed model keeps accuracy similar to a FEM model at a much lower computational effort, which could contribute to the development and to the testing of condition-monitoring systems. This approach has been applied to develop an IM model under static eccentricity conditions, but this may extend to other fault types.

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IntroductionOne of the most common electrical machines in industry is induction machines (IMs)
One of the most common electrical machines in industry is induction machines (IMs).These machines play an important role in the safe and efficient operation of various types of industrial applications due to their numerous strengths, such as simplicity, ruggedness and high reliability, at relatively low cost
This paper proposes the use of the sparse identification and trigonometric interpolation polynomial to minimize the number of finite element method (FEM) simulations required to develop a hybrid FEM-analytical model of a faulty IM

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Introduction

One of the most common electrical machines in industry is induction machines (IMs) These machines play an important role in the safe and efficient operation of various types of industrial applications due to their numerous strengths, such as simplicity, ruggedness and high reliability, at relatively low cost. They are not free from faults that may lead to unexpected failures, causing large economic losses. Much has been proposed in the technical literature for condition-monitoring (CM) systems, the stator current being one of the most widely used due to its low requirements. Not much hardware (only a current clamp is needed) and low software resources are required [2].

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