Rapid Fatigue Characterization via Infrared Thermography of AM-CM Composites

Nithinkumar Manoharan; Pharindra Pathak; Suhasini Gururaja; Vipin Kumar; Uday Vaidya

doi:10.1007/978-3-031-50470-9_8

Rapid Fatigue Characterization via Infrared Thermography of AM-CM Composites

Nithinkumar Manoharan, Pharindra Pathak, Suhasini Gururaja, Vipin Kumar, Uday Vaidya

Composites Innovation

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

4 Scopus citations

Abstract

A direct correlation exists between the microstructure of a composite (defect distribution, residual stresses, fiber geometry, and orientation) and the global composite mechanical behavior. Manufacturing processes govern the composite microstructure characteristics; thus, rapid process–microstructure–performance relationships must be established for emergent materials and manufacturing processes. In this chapter, a preform was manufactured via a modified Additive Manufacturing followed by Compression Molding (AM-CM) process with carbon fiber (CF) filled acrylonitrile butadiene styrene (ABS). The AM-CM plates were prepared with varying process parameters yielding distinct composite microstructures with varying porosity and fiber orientations. Micro-computed tomography has been used to characterize the microstructure of these composites. Preliminary mechanical testing (static) was conducted to ascertain these composites’ static strength and stiffness properties. The current chapter strives to correlate the microstructure of these composites with their fatigue performance using rapid infrared thermography (IRT). A typical “staircase” loading has been adopted for IRT-based fatigue testing via self-heating. The stabilized temperature versus applied maximum stress profile plots yields a bi-linear curve indicating a pseudo-fatigue limit of each composite configuration. This bi-linear curve, coupled with stiffness degradation plots, can map composite microstructure with its fatigue performance. The approach outlined will provide a basis for rapidly characterizing and inserting emergent materials and manufacturing processes in fatigue-critical applications.

Original language	English
Title of host publication	Challenges in Mechanics of Biological Systems and Materials, Thermomechanics and Infrared Imaging, Time Dependent Materials and Residual Stress, Volume 2 - Proceedings of the 2023 Annual Conference and Exposition on Experimental and Applied Mechanics
Editors	Christian Franck, Karen Kasza, Jon Estrada, Rosa De Finis, Geir Ólafsson, Suhasini Gururaja, Jevan Furmanski, Aaron Forster, Pavan Kolluru, Mike Prime, Tom Berfield, Cahit Aydiner
Publisher	Springer
Pages	53-58
Number of pages	6
ISBN (Print)	9783031504693
DOIs	https://doi.org/10.1007/978-3-031-50470-9_8
State	Published - 2024
Event	SEM Annual Conference and Exposition on Experimental and Applied Mechanics, 2023 - Orlando, United States Duration: Jun 5 2023 → Jun 8 2023

Publication series

Name	Conference Proceedings of the Society for Experimental Mechanics Series
ISSN (Print)	2191-5644
ISSN (Electronic)	2191-5652

Conference

Conference	SEM Annual Conference and Exposition on Experimental and Applied Mechanics, 2023
Country/Territory	United States
City	Orlando
Period	06/5/23 → 06/8/23

Keywords

AM-CM composites
Fatigue limit
Infrared thermography
Self-heating

Access to Document

10.1007/978-3-031-50470-9_8

Cite this

Manoharan, N., Pathak, P., Gururaja, S., Kumar, V., & Vaidya, U. (2024). Rapid Fatigue Characterization via Infrared Thermography of AM-CM Composites. In C. Franck, K. Kasza, J. Estrada, R. De Finis, G. Ólafsson, S. Gururaja, J. Furmanski, A. Forster, P. Kolluru, M. Prime, T. Berfield, & C. Aydiner (Eds.), Challenges in Mechanics of Biological Systems and Materials, Thermomechanics and Infrared Imaging, Time Dependent Materials and Residual Stress, Volume 2 - Proceedings of the 2023 Annual Conference and Exposition on Experimental and Applied Mechanics (pp. 53-58). (Conference Proceedings of the Society for Experimental Mechanics Series). Springer. https://doi.org/10.1007/978-3-031-50470-9_8

Manoharan, Nithinkumar ; Pathak, Pharindra ; Gururaja, Suhasini et al. / Rapid Fatigue Characterization via Infrared Thermography of AM-CM Composites. Challenges in Mechanics of Biological Systems and Materials, Thermomechanics and Infrared Imaging, Time Dependent Materials and Residual Stress, Volume 2 - Proceedings of the 2023 Annual Conference and Exposition on Experimental and Applied Mechanics. editor / Christian Franck ; Karen Kasza ; Jon Estrada ; Rosa De Finis ; Geir Ólafsson ; Suhasini Gururaja ; Jevan Furmanski ; Aaron Forster ; Pavan Kolluru ; Mike Prime ; Tom Berfield ; Cahit Aydiner. Springer, 2024. pp. 53-58 (Conference Proceedings of the Society for Experimental Mechanics Series).

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title = "Rapid Fatigue Characterization via Infrared Thermography of AM-CM Composites",

abstract = "A direct correlation exists between the microstructure of a composite (defect distribution, residual stresses, fiber geometry, and orientation) and the global composite mechanical behavior. Manufacturing processes govern the composite microstructure characteristics; thus, rapid process–microstructure–performance relationships must be established for emergent materials and manufacturing processes. In this chapter, a preform was manufactured via a modified Additive Manufacturing followed by Compression Molding (AM-CM) process with carbon fiber (CF) filled acrylonitrile butadiene styrene (ABS). The AM-CM plates were prepared with varying process parameters yielding distinct composite microstructures with varying porosity and fiber orientations. Micro-computed tomography has been used to characterize the microstructure of these composites. Preliminary mechanical testing (static) was conducted to ascertain these composites{\textquoteright} static strength and stiffness properties. The current chapter strives to correlate the microstructure of these composites with their fatigue performance using rapid infrared thermography (IRT). A typical “staircase” loading has been adopted for IRT-based fatigue testing via self-heating. The stabilized temperature versus applied maximum stress profile plots yields a bi-linear curve indicating a pseudo-fatigue limit of each composite configuration. This bi-linear curve, coupled with stiffness degradation plots, can map composite microstructure with its fatigue performance. The approach outlined will provide a basis for rapidly characterizing and inserting emergent materials and manufacturing processes in fatigue-critical applications.",

keywords = "AM-CM composites, Fatigue limit, Infrared thermography, Self-heating",

author = "Nithinkumar Manoharan and Pharindra Pathak and Suhasini Gururaja and Vipin Kumar and Uday Vaidya",

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year = "2024",

doi = "10.1007/978-3-031-50470-9_8",

language = "English",

isbn = "9783031504693",

series = "Conference Proceedings of the Society for Experimental Mechanics Series",

publisher = "Springer",

pages = "53--58",

editor = "Christian Franck and Karen Kasza and Jon Estrada and {De Finis}, Rosa and Geir {\'O}lafsson and Suhasini Gururaja and Jevan Furmanski and Aaron Forster and Pavan Kolluru and Mike Prime and Tom Berfield and Cahit Aydiner",

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Manoharan, N, Pathak, P, Gururaja, S, Kumar, V & Vaidya, U 2024, Rapid Fatigue Characterization via Infrared Thermography of AM-CM Composites. in C Franck, K Kasza, J Estrada, R De Finis, G Ólafsson, S Gururaja, J Furmanski, A Forster, P Kolluru, M Prime, T Berfield & C Aydiner (eds), Challenges in Mechanics of Biological Systems and Materials, Thermomechanics and Infrared Imaging, Time Dependent Materials and Residual Stress, Volume 2 - Proceedings of the 2023 Annual Conference and Exposition on Experimental and Applied Mechanics. Conference Proceedings of the Society for Experimental Mechanics Series, Springer, pp. 53-58, SEM Annual Conference and Exposition on Experimental and Applied Mechanics, 2023, Orlando, United States, 06/5/23. https://doi.org/10.1007/978-3-031-50470-9_8

Rapid Fatigue Characterization via Infrared Thermography of AM-CM Composites. / Manoharan, Nithinkumar; Pathak, Pharindra; Gururaja, Suhasini et al.
Challenges in Mechanics of Biological Systems and Materials, Thermomechanics and Infrared Imaging, Time Dependent Materials and Residual Stress, Volume 2 - Proceedings of the 2023 Annual Conference and Exposition on Experimental and Applied Mechanics. ed. / Christian Franck; Karen Kasza; Jon Estrada; Rosa De Finis; Geir Ólafsson; Suhasini Gururaja; Jevan Furmanski; Aaron Forster; Pavan Kolluru; Mike Prime; Tom Berfield; Cahit Aydiner. Springer, 2024. p. 53-58 (Conference Proceedings of the Society for Experimental Mechanics Series).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Gururaja, Suhasini

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N1 - Publisher Copyright: © The Society for Experimental Mechanics, Inc. 2024.

PY - 2024

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N2 - A direct correlation exists between the microstructure of a composite (defect distribution, residual stresses, fiber geometry, and orientation) and the global composite mechanical behavior. Manufacturing processes govern the composite microstructure characteristics; thus, rapid process–microstructure–performance relationships must be established for emergent materials and manufacturing processes. In this chapter, a preform was manufactured via a modified Additive Manufacturing followed by Compression Molding (AM-CM) process with carbon fiber (CF) filled acrylonitrile butadiene styrene (ABS). The AM-CM plates were prepared with varying process parameters yielding distinct composite microstructures with varying porosity and fiber orientations. Micro-computed tomography has been used to characterize the microstructure of these composites. Preliminary mechanical testing (static) was conducted to ascertain these composites’ static strength and stiffness properties. The current chapter strives to correlate the microstructure of these composites with their fatigue performance using rapid infrared thermography (IRT). A typical “staircase” loading has been adopted for IRT-based fatigue testing via self-heating. The stabilized temperature versus applied maximum stress profile plots yields a bi-linear curve indicating a pseudo-fatigue limit of each composite configuration. This bi-linear curve, coupled with stiffness degradation plots, can map composite microstructure with its fatigue performance. The approach outlined will provide a basis for rapidly characterizing and inserting emergent materials and manufacturing processes in fatigue-critical applications.

AB - A direct correlation exists between the microstructure of a composite (defect distribution, residual stresses, fiber geometry, and orientation) and the global composite mechanical behavior. Manufacturing processes govern the composite microstructure characteristics; thus, rapid process–microstructure–performance relationships must be established for emergent materials and manufacturing processes. In this chapter, a preform was manufactured via a modified Additive Manufacturing followed by Compression Molding (AM-CM) process with carbon fiber (CF) filled acrylonitrile butadiene styrene (ABS). The AM-CM plates were prepared with varying process parameters yielding distinct composite microstructures with varying porosity and fiber orientations. Micro-computed tomography has been used to characterize the microstructure of these composites. Preliminary mechanical testing (static) was conducted to ascertain these composites’ static strength and stiffness properties. The current chapter strives to correlate the microstructure of these composites with their fatigue performance using rapid infrared thermography (IRT). A typical “staircase” loading has been adopted for IRT-based fatigue testing via self-heating. The stabilized temperature versus applied maximum stress profile plots yields a bi-linear curve indicating a pseudo-fatigue limit of each composite configuration. This bi-linear curve, coupled with stiffness degradation plots, can map composite microstructure with its fatigue performance. The approach outlined will provide a basis for rapidly characterizing and inserting emergent materials and manufacturing processes in fatigue-critical applications.

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Manoharan N, Pathak P, Gururaja S, Kumar V, Vaidya U. Rapid Fatigue Characterization via Infrared Thermography of AM-CM Composites. In Franck C, Kasza K, Estrada J, De Finis R, Ólafsson G, Gururaja S, Furmanski J, Forster A, Kolluru P, Prime M, Berfield T, Aydiner C, editors, Challenges in Mechanics of Biological Systems and Materials, Thermomechanics and Infrared Imaging, Time Dependent Materials and Residual Stress, Volume 2 - Proceedings of the 2023 Annual Conference and Exposition on Experimental and Applied Mechanics. Springer. 2024. p. 53-58. (Conference Proceedings of the Society for Experimental Mechanics Series). doi: 10.1007/978-3-031-50470-9_8

Rapid Fatigue Characterization via Infrared Thermography of AM-CM Composites

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Keywords

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