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A Comparative and Review Study on Shape and Stress Sensing of Flat/Curved Shell Geometries Using C(0)-Continuous Family of iFEM Elements

In this study, we methodologically compare and review the accuracy and performance of C(0)-continuous flat and curved inverse-shell elements (i.e., iMIN3, iQS4, and iCS8) for inverse finite element method (iFEM) in terms of shape, strain, and stress monitoring, and damage detection on various plane...

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Autores principales: Abdollahzadeh, Mohammad Amin, Kefal, Adnan, Yildiz, Mehmet
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2020
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7411818/
https://www.ncbi.nlm.nih.gov/pubmed/32650375
http://dx.doi.org/10.3390/s20143808
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author Abdollahzadeh, Mohammad Amin
Kefal, Adnan
Yildiz, Mehmet
author_facet Abdollahzadeh, Mohammad Amin
Kefal, Adnan
Yildiz, Mehmet
author_sort Abdollahzadeh, Mohammad Amin
collection PubMed
description In this study, we methodologically compare and review the accuracy and performance of C(0)-continuous flat and curved inverse-shell elements (i.e., iMIN3, iQS4, and iCS8) for inverse finite element method (iFEM) in terms of shape, strain, and stress monitoring, and damage detection on various plane and curved geometries subjected to different loading and constraint conditions. For this purpose, four different benchmark problems are proposed, namely, a tapered plate, a quarter of a cylindrical shell, a stiffened curved plate, and a curved plate with a degraded material region in stiffness, representing a damage. The complexity of these test cases is increased systematically to reveal the advantages and shortcomings of the elements under different sensor density deployments. The reference displacement solutions and strain-sensor data used in the benchmark problems are established numerically, utilizing direct finite element analysis. After performing shape-, strain-, and stress-sensing analyses, the reference solutions are compared to the reconstructed solutions of iMIN3, iQS4, and iCS8 models. For plane geometries with sparse sensor configurations, these three elements provide rather close reconstructed-displacement fields with slightly more accurate stress sensing using iCS8 than when using iMIN3/iQS4. It is demonstrated on the curved geometry that the cross-diagonal meshing of a quadrilateral element pattern (e.g., leading to four iMIN3 elements) improves the accuracy of the displacement reconstruction as compared to a single-diagonal meshing strategy (e.g., two iMIN3 elements in a quad-shape element) utilizing iMIN3 element. Nevertheless, regardless of any geometry, sensor density, and meshing strategy, iQS4 has better shape and stress-sensing than iMIN3. As the complexity of the problem is elevated, the predictive capabilities of iCS8 element become obviously superior to that of flat inverse-shell elements (e.g., iMIN3 and iQS4) in terms of both shape sensing and damage detection. Comprehensively speaking, we envisage that the set of scrupulously selected test cases proposed herein can be reliable benchmarks for testing/validating/comparing for the features of newly developed inverse elements.
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spelling pubmed-74118182020-08-25 A Comparative and Review Study on Shape and Stress Sensing of Flat/Curved Shell Geometries Using C(0)-Continuous Family of iFEM Elements Abdollahzadeh, Mohammad Amin Kefal, Adnan Yildiz, Mehmet Sensors (Basel) Article In this study, we methodologically compare and review the accuracy and performance of C(0)-continuous flat and curved inverse-shell elements (i.e., iMIN3, iQS4, and iCS8) for inverse finite element method (iFEM) in terms of shape, strain, and stress monitoring, and damage detection on various plane and curved geometries subjected to different loading and constraint conditions. For this purpose, four different benchmark problems are proposed, namely, a tapered plate, a quarter of a cylindrical shell, a stiffened curved plate, and a curved plate with a degraded material region in stiffness, representing a damage. The complexity of these test cases is increased systematically to reveal the advantages and shortcomings of the elements under different sensor density deployments. The reference displacement solutions and strain-sensor data used in the benchmark problems are established numerically, utilizing direct finite element analysis. After performing shape-, strain-, and stress-sensing analyses, the reference solutions are compared to the reconstructed solutions of iMIN3, iQS4, and iCS8 models. For plane geometries with sparse sensor configurations, these three elements provide rather close reconstructed-displacement fields with slightly more accurate stress sensing using iCS8 than when using iMIN3/iQS4. It is demonstrated on the curved geometry that the cross-diagonal meshing of a quadrilateral element pattern (e.g., leading to four iMIN3 elements) improves the accuracy of the displacement reconstruction as compared to a single-diagonal meshing strategy (e.g., two iMIN3 elements in a quad-shape element) utilizing iMIN3 element. Nevertheless, regardless of any geometry, sensor density, and meshing strategy, iQS4 has better shape and stress-sensing than iMIN3. As the complexity of the problem is elevated, the predictive capabilities of iCS8 element become obviously superior to that of flat inverse-shell elements (e.g., iMIN3 and iQS4) in terms of both shape sensing and damage detection. Comprehensively speaking, we envisage that the set of scrupulously selected test cases proposed herein can be reliable benchmarks for testing/validating/comparing for the features of newly developed inverse elements. MDPI 2020-07-08 /pmc/articles/PMC7411818/ /pubmed/32650375 http://dx.doi.org/10.3390/s20143808 Text en © 2020 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
Abdollahzadeh, Mohammad Amin
Kefal, Adnan
Yildiz, Mehmet
A Comparative and Review Study on Shape and Stress Sensing of Flat/Curved Shell Geometries Using C(0)-Continuous Family of iFEM Elements
title A Comparative and Review Study on Shape and Stress Sensing of Flat/Curved Shell Geometries Using C(0)-Continuous Family of iFEM Elements
title_full A Comparative and Review Study on Shape and Stress Sensing of Flat/Curved Shell Geometries Using C(0)-Continuous Family of iFEM Elements
title_fullStr A Comparative and Review Study on Shape and Stress Sensing of Flat/Curved Shell Geometries Using C(0)-Continuous Family of iFEM Elements
title_full_unstemmed A Comparative and Review Study on Shape and Stress Sensing of Flat/Curved Shell Geometries Using C(0)-Continuous Family of iFEM Elements
title_short A Comparative and Review Study on Shape and Stress Sensing of Flat/Curved Shell Geometries Using C(0)-Continuous Family of iFEM Elements
title_sort comparative and review study on shape and stress sensing of flat/curved shell geometries using c(0)-continuous family of ifem elements
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7411818/
https://www.ncbi.nlm.nih.gov/pubmed/32650375
http://dx.doi.org/10.3390/s20143808
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