The intersection of damage evaluation of fiber-reinforced composite materials with machine learning: A review

Nelon, Christopher; Myers, Oliver; Hall, Asha

doi:10.1177/00219983211037048

Cited by 15 publications

(3 citation statements)

References 169 publications

(282 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Finally, the machine/deep learning-based surrogate/predictive models can be used for process simulations [155][156][157] as well as for failure predictions in diagnostic and prognostic maintenance [158][159][160] . Using the data provided by a set of pressure sensors, Zhu et al 161 implemented a neural network model for the prediction of flow-front patterns at any impregnation time.…”

Section: The Meta-verse Of Composites Manufacturingmentioning

confidence: 99%

Graphene nanoparticles as data generating digital materials in industry 4.0

Ali

Irfan

Khan

et al. 2023

Sci Rep

View full text Add to dashboard Cite

One of the potential applications of 2D materials is to enhance multi-functionality of structures and components used in aerospace, automotive, civil and defense industries. These multi-functional attributes include sensing, energy storage, EMI shielding and property enhancement. In this article, we have explored the potential of using graphene and its variants as data generating sensory elements in Industry 4.0. We have presented a complete roadmap to cover three emerging technologies i.e. advance materials, artificial intelligence and block-chain technology. The utility of 2D materials such as graphene nanoparticles is yet to be explored as an interface for digitalization of a modern smart factory i.e. “factory-of-the-future”. In this article, we have explored how 2D material enhanced composites can act as an interface between physical and cyber spaces. An overview of employing graphene-based smart embedded sensors at various stages of composites manufacturing processes and their application in real-time structural health monitoring is presented. The technical challenges associated with interfacing graphene-based sensing networks with digital space are discussed. Additionally, an overview of the integration of associated tools such as artificial intelligence, machine learning and block-chain technology with graphene-based devices and structures is also presented.

show abstract

Section: The Meta-verse Of Composites Manufacturingmentioning

confidence: 99%

Graphene nanoparticles as data generating digital materials in industry 4.0

Ali

Irfan

Khan

et al. 2023

Sci Rep

View full text Add to dashboard Cite

show abstract

“…The damage mechanisms are affected by parameters such as fiber type, matrix type, type of reinforcement structure (unidirectional, mat, fabric, braiding), laminate stacking sequence, environmental conditions (mainly temperature and moisture absorption), loading conditions (stress ratio R, cycling frequency), and boundary conditions. 21 Researchers predicted damage with fatigue life models, 22 phenomenological models based on residual stiffness [23][24][25][26][27][28][29][30] and residual strength, [31][32][33][34][35] and progressive damage models [36][37][38][39][40] to characterize fatigue life for a wide range of test conditions. There have been different damage identification techniques Figure 1.…”

Section: Introductionmentioning

confidence: 99%

Fatigue performance evaluation of bistable composites at different combinations of loading and environmental conditions

Chowdhury,

Li,

Myers

2023

Journal of Composite Materials

Self Cite

View full text Add to dashboard Cite

Bistable composite laminates have large-scale applications in morphing and energy-harvesting structures, but their fatigue performance remains largely unexplored. This study investigates the stiffness and damage progression and evaluates bistable performance to develop protocols for long-term applications. We analyze the effects of displacement-controlled fully reversible high cycle fatigue-loading on stiffness, damage, curvature, and snap-through load in the out-of-plane loading direction at eight different combinations of parameters with frequency from 1 to 10 Hz, two boundary conditions, and temperature from 22°C to 150°C up to 3 to 10 million cycles. Stiffness and damage evolution analysis demonstrate the first two stages in out-of-plane fatigue loading. The study proposes a damage definition in terms of load adapting with two fatigue damage models: (1) Shiri Model and (2) Wu Model, while both models exhibit reasonable accuracy in predicting damage for the first two stages despite deviating at the final cycle due to assuming this cycle as the final failure cycle. Of the two models, the Shiri model provided a smaller range of model parameter values, 0.22 and 0.43, for parameters p and q, respectively, which reflects adjustability to different test conditions by maintaining a moderate range. Specimens encountered no final failure by fiber breakage and did not lose bistability for any combination. Curvature and snap-through load measurements have not substantially changed due to fatigue loading. These findings confirm application protocols with a broad range of parameters for which the laminates can operate without significant fatigue damage and maintain their bistable performance for an infinite lifetime.

show abstract

“…In other words, the US Army's future aerospace vehicles need to be able to ''feel'' damage at a microscopic scale to warn, adapt, and survive in tactical situations. This paper explores a novel and sustainable methodology for Non-Destructive Evaluation (NDE) of CFRP interphase with implications to act as a data source for Structural Health Monitoring (SHM) machine learning schemes (Farrar and Worden, 2013;Nelon et al, 2022). Potential use cases for this work include but are not limited to NDE for condition-based maintenance, non-contact strain/stress sensing, and real-time composite SHM.…”

Section: Introductionmentioning

confidence: 99%

Non-contact embedded sensing by Magnetostrictive Carbon Fiber Reinforced Polymer (MagCFRP): A smart material for early inter-lamina localized damage detection

Williams,

Coatney,

Hall

et al. 2023

Journal of Intelligent Material Systems and Structures

Self Cite

View full text Add to dashboard Cite

Although failure mechanics and plasticity of composite materials is a relatively new and volatile field, it has been long realized in the composite materials community that a composite’s true integrity lies in the constituents’ interfacial health. Composite materials allow scientists and engineers to design structural architectures with directional stress, strain, and thermal fields in mind while simultaneously reducing the system’s overall weight. While there are advantages to using composite materials like carbon fiber reinforced polymers (CFRPs), designing and implementing long-term sustainable aerospace structures out of CFRPs is bottlenecked by the brittle catastrophic failure mechanism high strength carbon composites exhibit. As the demand for these materials in critical loading regimes increases, it is paramount that scientists and engineers understand how CFRPs will behave in real-time and in predictive models for load profiles. This research’s motivation comes from the US Army’s future vertical lift vehicle initiative to transition from interval-based maintenance to condition-based maintenance (CDB). This paper explores a real-time, non-contact, and non-destructive evaluation (NDE) method for composite materials by performing localized magnetic flux scans (32 mm2 field of view) of CFRP embedded with Terfenol-D ([Formula: see text] microns in diameter), a magnetostrictive material. For Magnetostrictive Carbon Fiber Reinforced Polymer (MagCFRP) elastic regime testing, there was an observed localized magnetic flux gradient of more than 5 mT (4%) with a reversible flux of 100%. For MagCFRP elastic-plastic regime testing, a localized magnetic flux gradient of more than 3 mT (2%) with a reversible flux of only 25% was observed. Terfenol-D embedded CRFPs have shown promising results for detecting instantaneous stress and strain levels and detecting deviations in inter-lamina residual stress after critical loading. Acoustic emission (AE), Digital Image Correlation (DIC), and X-ray computed tomography (CT) scanning were used to validate the observed results.

show abstract

The intersection of damage evaluation of fiber-reinforced composite materials with machine learning: A review

Cited by 15 publications

References 169 publications

Graphene nanoparticles as data generating digital materials in industry 4.0

Graphene nanoparticles as data generating digital materials in industry 4.0

Fatigue performance evaluation of bistable composites at different combinations of loading and environmental conditions

Non-contact embedded sensing by Magnetostrictive Carbon Fiber Reinforced Polymer (MagCFRP): A smart material for early inter-lamina localized damage detection

Contact Info

Product

Resources

About