| Title: | Uncertainty Quantification of Input Parameters in a 2-D Finite-Element Model for Broken Rotor Bar in an Induction Machine |
| Authors: | Billah, Md Masum Martin, Floran Belahcen, Anouar Balasubramanian, Aswin Vaimann, Toomas Šobra, Jan |
| Citation: | BILLAH, MM. MARTIN, F. BELAHCEN, A. BALASUBRAMANIAN, A. VAIMANN, T. ŠOBRA, J. Uncertainty Quantification of Input Parameters in a 2-D Finite-Element Model for Broken Rotor Bar in an Induction Machine. IEEE TRANSACTIONS ON MAGNETICS, 2022, roč. 58, č. 9, s. 1-4. ISSN: 0018-9464 |
| Issue Date: | 2022 |
| Publisher: | IEEE |
| Document type: | článek article |
| URI: | 2-s2.0-85132516281 http://hdl.handle.net/11025/49743 |
| ISSN: | 0018-9464 |
| Keywords in different language: | broken rotor bar (BRB);finite-element (FE) model;forward uncertainty propagation;polynomial chaos expansion (PCE);sobol sensitivity analysis |
| Abstract: | In this article, a forward uncertainty propagation method is presented for a 2-D finite-element (FE) model in an induction machine. This method is applied to quantify the uncertainty of input parameters, for example, dimensions and material properties, and demonstrate their variability effect on harmonics related to the broken rotor bar (BRB) faults. To show the most influential input parameters in the case of BRB harmonics, a global sensitivity analysis is performed from the polynomial chaos expansion (PCE) approximation of the FE model. The results of this study indicate that BRB harmonics are highly sensitive to stator inner diameter, rotor outer diameter, rotor bar conductivity, and core materials. Moreover, the combined variability of these sensitive input parameters can attenuate the amplitude of the BRB harmonics 30%–90% compared to the simulation results at nominal values of input parameters and closely match with measurement results. |
| Abstract in different language: | In this article, a forward uncertainty propagation method is presented for a 2-D finite-element (FE) model in an induction machine. This method is applied to quantify the uncertainty of input parameters, for example, dimensions and material properties, and demonstrate their variability effect on harmonics related to the broken rotor bar (BRB) faults. To show the most influential input parameters in the case of BRB harmonics, a global sensitivity analysis is performed from the polynomial chaos expansion (PCE) approximation of the FE model. The results of this study indicate that BRB harmonics are highly sensitive to stator inner diameter, rotor outer diameter, rotor bar conductivity, and core materials. Moreover, the combined variability of these sensitive input parameters can attenuate the amplitude of the BRB harmonics 30%–90% compared to the simulation results at nominal values of input parameters and closely match with measurement results. |
| Rights: | © Creative Commons Attribution 4.0 License |
| Appears in Collections: | Články / Articles (KEV) OBD |
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| File | Size | Format | |
|---|---|---|---|
| Sobra_Uncertainty_Quantification.pdf | 1,11 MB | Adobe PDF | View/Open |
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