Analysis of Forming Limits in Sheet Metal Forming with Pattern Recognition Methods. Part 1: Characterization of Onset of Necking and Expert Evaluation
In automotive manufacturing, high strength materials, and aluminum alloys are widely used to address the requirement of ensuring a lightweight car body and correspondingly, reducing pollution. In this context of complexity of materials and structures, an optimized process design with finite element...
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| Published in | Materials Vol. 11; no. 9; p. 1495 |
|---|---|
| Main Authors | , , , |
| Format | Journal Article |
| Language | English |
| Published |
Switzerland
MDPI AG
21.08.2018
MDPI |
| Subjects | |
| Online Access | Get full text |
| ISSN | 1996-1944 1996-1944 |
| DOI | 10.3390/ma11091495 |
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| Abstract | In automotive manufacturing, high strength materials, and aluminum alloys are widely used to address the requirement of ensuring a lightweight car body and correspondingly, reducing pollution. In this context of complexity of materials and structures, an optimized process design with finite element analyses (FEA) is mandatory, as well as a correct definition of the material forming limits. For this purpose, in sheet metal forming, the forming limit curve (FLC) is used. The FLC is defined by the onset of necking. The standard evaluation method according to DIN EN ISO 12004-2 is based on the cross-section method and assumes that the failure occurs due to a clear localized necking. However, this approach has its limitations, specifically in the case of brittle materials that do not exhibit a distinct necking phase. To overcome this challenge, a pattern recognition-based evaluation is proposed. Although pattern recognition and machine learning techniques have been widely employed in the medical field, few studies have investigated them in the context of analyzing metal sheet forming limits. The application of pattern recognition in metal forming is subject to the exact definition of the forming behaviors. Thereby, it is challenging to relate patterns on the strain distribution during Nakajima tests with the onset of necking for the FLC determination. Thus, the first approach was based on the crack evaluation, since this class is well-defined. However, of substantial interest is the evaluation of the general material instabilities that precede failure. Therefore, in the present study, the analysis of the material behavior during stretching is conducted in order to characterize instability classes. The results of Nakajima tests are investigated using an optical measurement system. A conventional pattern recognition approach based on texture features, considering the outcomes of expert interviews for the definition of classes is used for the FLC determination. Moreover, an analysis of the validity of the supervised learning is conducted. The results show a good prediction of the onset of necking, even for high strength materials with a recall of up to 92%. Some deviations are observed in the determination of the diffuse necking. The discrepancies of the different experts’ prognoses highlight the user-dependency of the FLC, suggesting further investigations with an data-driven approach, could be beneficial. |
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| AbstractList | In automotive manufacturing, high strength materials, and aluminum alloys are widely used to address the requirement of ensuring a lightweight car body and correspondingly, reducing pollution. In this context of complexity of materials and structures, an optimized process design with finite element analyses (FEA) is mandatory, as well as a correct definition of the material forming limits. For this purpose, in sheet metal forming, the forming limit curve (FLC) is used. The FLC is defined by the onset of necking. The standard evaluation method according to DIN EN ISO 12004-2 is based on the cross-section method and assumes that the failure occurs due to a clear localized necking. However, this approach has its limitations, specifically in the case of brittle materials that do not exhibit a distinct necking phase. To overcome this challenge, a pattern recognition-based evaluation is proposed. Although pattern recognition and machine learning techniques have been widely employed in the medical field, few studies have investigated them in the context of analyzing metal sheet forming limits. The application of pattern recognition in metal forming is subject to the exact definition of the forming behaviors. Thereby, it is challenging to relate patterns on the strain distribution during Nakajima tests with the onset of necking for the FLC determination. Thus, the first approach was based on the crack evaluation, since this class is well-defined. However, of substantial interest is the evaluation of the general material instabilities that precede failure. Therefore, in the present study, the analysis of the material behavior during stretching is conducted in order to characterize instability classes. The results of Nakajima tests are investigated using an optical measurement system. A conventional pattern recognition approach based on texture features, considering the outcomes of expert interviews for the definition of classes is used for the FLC determination. Moreover, an analysis of the validity of the supervised learning is conducted. The results show a good prediction of the onset of necking, even for high strength materials with a recall of up to 92%. Some deviations are observed in the determination of the diffuse necking. The discrepancies of the different experts' prognoses highlight the user-dependency of the FLC, suggesting further investigations with an data-driven approach, could be beneficial.In automotive manufacturing, high strength materials, and aluminum alloys are widely used to address the requirement of ensuring a lightweight car body and correspondingly, reducing pollution. In this context of complexity of materials and structures, an optimized process design with finite element analyses (FEA) is mandatory, as well as a correct definition of the material forming limits. For this purpose, in sheet metal forming, the forming limit curve (FLC) is used. The FLC is defined by the onset of necking. The standard evaluation method according to DIN EN ISO 12004-2 is based on the cross-section method and assumes that the failure occurs due to a clear localized necking. However, this approach has its limitations, specifically in the case of brittle materials that do not exhibit a distinct necking phase. To overcome this challenge, a pattern recognition-based evaluation is proposed. Although pattern recognition and machine learning techniques have been widely employed in the medical field, few studies have investigated them in the context of analyzing metal sheet forming limits. The application of pattern recognition in metal forming is subject to the exact definition of the forming behaviors. Thereby, it is challenging to relate patterns on the strain distribution during Nakajima tests with the onset of necking for the FLC determination. Thus, the first approach was based on the crack evaluation, since this class is well-defined. However, of substantial interest is the evaluation of the general material instabilities that precede failure. Therefore, in the present study, the analysis of the material behavior during stretching is conducted in order to characterize instability classes. The results of Nakajima tests are investigated using an optical measurement system. A conventional pattern recognition approach based on texture features, considering the outcomes of expert interviews for the definition of classes is used for the FLC determination. Moreover, an analysis of the validity of the supervised learning is conducted. The results show a good prediction of the onset of necking, even for high strength materials with a recall of up to 92%. Some deviations are observed in the determination of the diffuse necking. The discrepancies of the different experts' prognoses highlight the user-dependency of the FLC, suggesting further investigations with an data-driven approach, could be beneficial. In automotive manufacturing, high strength materials, and aluminum alloys are widely used to address the requirement of ensuring a lightweight car body and correspondingly, reducing pollution. In this context of complexity of materials and structures, an optimized process design with finite element analyses (FEA) is mandatory, as well as a correct definition of the material forming limits. For this purpose, in sheet metal forming, the forming limit curve (FLC) is used. The FLC is defined by the onset of necking. The standard evaluation method according to DIN EN ISO 12004-2 is based on the cross-section method and assumes that the failure occurs due to a clear localized necking. However, this approach has its limitations, specifically in the case of brittle materials that do not exhibit a distinct necking phase. To overcome this challenge, a pattern recognition-based evaluation is proposed. Although pattern recognition and machine learning techniques have been widely employed in the medical field, few studies have investigated them in the context of analyzing metal sheet forming limits. The application of pattern recognition in metal forming is subject to the exact definition of the forming behaviors. Thereby, it is challenging to relate patterns on the strain distribution during Nakajima tests with the onset of necking for the FLC determination. Thus, the first approach was based on the crack evaluation, since this class is well-defined. However, of substantial interest is the evaluation of the general material instabilities that precede failure. Therefore, in the present study, the analysis of the material behavior during stretching is conducted in order to characterize instability classes. The results of Nakajima tests are investigated using an optical measurement system. A conventional pattern recognition approach based on texture features, considering the outcomes of expert interviews for the definition of classes is used for the FLC determination. Moreover, an analysis of the validity of the supervised learning is conducted. The results show a good prediction of the onset of necking, even for high strength materials with a recall of up to 92%. Some deviations are observed in the determination of the diffuse necking. The discrepancies of the different experts’ prognoses highlight the user-dependency of the FLC, suggesting further investigations with an data-driven approach, could be beneficial. |
| Author | Affronti, Emanuela Merklein, Marion Jaremenko, Christian Maier, Andreas |
| AuthorAffiliation | 2 Pattern Recognition Lab, Friedrich-Alexander-Universität Erlangen-Nürnberg Martensstr. 3, 91058 Erlangen, Germany; andreas.maier@fau.de 1 Institute of Manufacturing Technology, Friedrich-Alexander-Universität Erlangen-Nürnberg Egerlandstr. 13, 91058 Erlangen, Germany; marion.merklein@fau.de |
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| Cites_doi | 10.1007/s12289-010-1012-9 10.1016/j.proeng.2017.04.015 10.23919/MVA.2017.7986814 10.1007/BF02325092 10.1016/0031-3203(95)00067-4 10.1016/j.mechmat.2009.08.003 10.4028/www.scientific.net/KEM.639.333 10.5959/eimj.v7i1.281 10.1023/A:1010933404324 10.1177/001316447303300309 10.1007/978-3-662-54345-0_70 10.1007/978-3-642-47517-7 10.1016/j.patcog.2009.08.017 10.1007/978-3-662-46224-9_82 10.1088/1757-899X/418/1/012047 10.1109/TPAMI.2002.1017623 10.21437/SLaTE.2011-35 |
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| Copyright | 2018 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/). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License. 2018 by the authors. 2018 |
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| Keywords | sheet metal forming machine learning forming limit curve pattern recognition |
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| References | ref_14 ref_12 ref_10 Affronti (ref_13) 2017; 183 ref_19 ref_18 ref_17 Ojala (ref_22) 2002; 24 Merklein (ref_11) 2015; 639 ref_15 Ojala (ref_21) 1996; 29 Bragard (ref_5) 1972; 33 Fleiss (ref_26) 1973; 33 Volk (ref_9) 2011; 4 Breiman (ref_25) 2001; 45 ref_24 Chu (ref_6) 1985; 25 ref_20 Guo (ref_23) 2010; 43 ref_1 ref_3 Marciniak (ref_4) 1965; 17 ref_2 ref_8 Tasan (ref_16) 2009; 41 ref_7 |
| References_xml | – ident: ref_7 – volume: 17 start-page: 577 year: 1965 ident: ref_4 article-title: Stability of Plastics Shells under Tension with Kinematic Boundary Condition publication-title: Arch. Mech. – volume: 4 start-page: 339 year: 2011 ident: ref_9 article-title: New Algorithm for a robust user-independent evaluation of beginning instability for the experimental FLC determination publication-title: Int. J. Mater. Form. doi: 10.1007/s12289-010-1012-9 – ident: ref_3 – volume: 33 start-page: 53 year: 1972 ident: ref_5 article-title: Simplified Technique to Determine the FLD on the Onset of Necking publication-title: C. R. M. – ident: ref_24 – volume: 183 start-page: 83 year: 2017 ident: ref_13 article-title: Metallographic Analysis of Nakajima Tests for the Evaluation of the Failure Developments publication-title: Procedia Eng. doi: 10.1016/j.proeng.2017.04.015 – ident: ref_15 doi: 10.23919/MVA.2017.7986814 – volume: 25 start-page: 232 year: 1985 ident: ref_6 article-title: Applications of digital-image-correlation techniques to experimental mechanics publication-title: Exp. Mech. doi: 10.1007/BF02325092 – volume: 29 start-page: 51 year: 1996 ident: ref_21 article-title: A comparative study of texture measures with classification based on featured distributions publication-title: Pattern Recognit. doi: 10.1016/0031-3203(95)00067-4 – ident: ref_1 – volume: 41 start-page: 1264 year: 2009 ident: ref_16 article-title: Experimental analysis of strain path dependent ductile damage mechanics and forming limits publication-title: Mech. Mater. doi: 10.1016/j.mechmat.2009.08.003 – volume: 639 start-page: 333 year: 2015 ident: ref_11 article-title: A New Approach to the Evaluation of Forming Limits in Sheet Metal Forming publication-title: Key Eng. Mater. doi: 10.4028/www.scientific.net/KEM.639.333 – ident: ref_17 doi: 10.5959/eimj.v7i1.281 – volume: 45 start-page: 5 year: 2001 ident: ref_25 article-title: Random forests publication-title: Mach. Learn. doi: 10.1023/A:1010933404324 – volume: 33 start-page: 613 year: 1973 ident: ref_26 article-title: The Equivalence of Weighted Kappa and the Intraclass Correlation Coefficient as Measures of Reliability publication-title: Educ. Psychol. Meas. doi: 10.1177/001316447303300309 – ident: ref_8 – ident: ref_2 – ident: ref_19 doi: 10.1007/978-3-662-54345-0_70 – ident: ref_10 – ident: ref_12 doi: 10.1007/978-3-642-47517-7 – volume: 43 start-page: 706 year: 2010 ident: ref_23 article-title: Rotation invariant texture classification using LBP variance (LBPV) with global matching publication-title: Pattern Recognit. doi: 10.1016/j.patcog.2009.08.017 – ident: ref_18 doi: 10.1007/978-3-662-46224-9_82 – ident: ref_14 doi: 10.1088/1757-899X/418/1/012047 – volume: 24 start-page: 971 year: 2002 ident: ref_22 article-title: Multiresolution gray-scale and rotation invariant texture classification with local binary patterns publication-title: IEEE Trans. Pattern Anal. Mach. Intell. doi: 10.1109/TPAMI.2002.1017623 – ident: ref_20 doi: 10.21437/SLaTE.2011-35 |
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| SubjectTerms | Aluminum base alloys Automotive bodies Brittle materials Classification Context Crack initiation Design optimization Evaluation Failure analysis Finite element method Forming limit diagrams Geometry High strength alloys Machine learning Measurement techniques Metal forming Metal sheets Methods Optical measurement Pattern recognition Steel Strain distribution Texture recognition Weight reduction |
| Title | Analysis of Forming Limits in Sheet Metal Forming with Pattern Recognition Methods. Part 1: Characterization of Onset of Necking and Expert Evaluation |
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