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Experimental data-driven uncertainty quantification for the dynamic fracture toughness of particulate polymer composites

Experimental data-driven uncertainty quantification for the dynamic fracture toughness of particulate polymer composites
Experimental data-driven uncertainty quantification for the dynamic fracture toughness of particulate polymer composites

This paper presents an experimental investigation supported by data-driven approaches concerning the influence of critical stochastic effects on the dynamic fracture toughness of glass-filled epoxy composites using a computationally efficient framework of uncertainty quantification. Three different shapes of glass particles are considered including rod, spherical and flaky shapes with coupled stochastic variations in aspect ratio, dynamic elastic modulus and volume fraction. An artificial neural network based surrogate assisted Monte Carlo simulation is carried out here in conjunction with advanced experimental techniques like digital image correlation and scanning electron microscopy to quantify the uncertainty and sensitivity associated with the dynamic fracture toughness of composites in terms of stress intensity factor under dynamic impact. The study reveals that the pre-crack initiation time regime shows the most prominent effect of uncertainty. Additionally, rod shape and the aspect ratio are the most sensitive filler type and input parameter respectively for characterizing dynamic fracture toughness. Here the quantitative results based on large-scale data-driven approaches convincingly demonstrate using a computational mapping between the stochastic input and output parameter spaces that the effect of uncertainty gets pronounced significantly while propagating from the compound source level to the impact responses. Such outcomes based on experimental data essentially bring us to the realization that quantification of uncertainty is of utmost importance for developing a reliable and practically relevant inclusive analysis and design framework for the dynamic fracture of particulate composites. With limited literature available on the determination of fracture toughness considering inertial effects, the present work demonstrates a novel and insightful experimental approach for uncertainty quantification and sensitivity analysis of dynamic fracture toughness of particulate polymer composites based on surrogate modeling.

ANN assisted stochastic experimental characterization of composites, Sensitivity analysis of particulate composites, Stochastic dynamic fracture toughness, Uncertainty quantification in dynamic fracture
0013-7944
Sharma, A.
4e51a336-8732-4682-8831-59d26ac247f5
Mukhopadhyay, T.
2ae18ab0-7477-40ac-ae22-76face7be475
Kushvaha, V.
f37c711a-cfbc-42f2-8a4a-79a84af9596a
Sharma, A.
4e51a336-8732-4682-8831-59d26ac247f5
Mukhopadhyay, T.
2ae18ab0-7477-40ac-ae22-76face7be475
Kushvaha, V.
f37c711a-cfbc-42f2-8a4a-79a84af9596a

Sharma, A., Mukhopadhyay, T. and Kushvaha, V. (2022) Experimental data-driven uncertainty quantification for the dynamic fracture toughness of particulate polymer composites. Engineering Fracture Mechanics, 273, [108724]. (doi:10.1016/j.engfracmech.2022.108724).

Record type: Article

Abstract

This paper presents an experimental investigation supported by data-driven approaches concerning the influence of critical stochastic effects on the dynamic fracture toughness of glass-filled epoxy composites using a computationally efficient framework of uncertainty quantification. Three different shapes of glass particles are considered including rod, spherical and flaky shapes with coupled stochastic variations in aspect ratio, dynamic elastic modulus and volume fraction. An artificial neural network based surrogate assisted Monte Carlo simulation is carried out here in conjunction with advanced experimental techniques like digital image correlation and scanning electron microscopy to quantify the uncertainty and sensitivity associated with the dynamic fracture toughness of composites in terms of stress intensity factor under dynamic impact. The study reveals that the pre-crack initiation time regime shows the most prominent effect of uncertainty. Additionally, rod shape and the aspect ratio are the most sensitive filler type and input parameter respectively for characterizing dynamic fracture toughness. Here the quantitative results based on large-scale data-driven approaches convincingly demonstrate using a computational mapping between the stochastic input and output parameter spaces that the effect of uncertainty gets pronounced significantly while propagating from the compound source level to the impact responses. Such outcomes based on experimental data essentially bring us to the realization that quantification of uncertainty is of utmost importance for developing a reliable and practically relevant inclusive analysis and design framework for the dynamic fracture of particulate composites. With limited literature available on the determination of fracture toughness considering inertial effects, the present work demonstrates a novel and insightful experimental approach for uncertainty quantification and sensitivity analysis of dynamic fracture toughness of particulate polymer composites based on surrogate modeling.

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More information

Accepted/In Press date: 10 August 2022
Published date: 1 October 2022
Additional Information: Funding Information: AS and VK would like to acknowledge the financial support received from DST‐SERBSRG/2020/000997. TM would like to acknowledge the support received through the Science and Engineering Research Board (Grant no. SRG/2020/001398), India. Publisher Copyright: © 2022 Elsevier Ltd
Keywords: ANN assisted stochastic experimental characterization of composites, Sensitivity analysis of particulate composites, Stochastic dynamic fracture toughness, Uncertainty quantification in dynamic fracture

Identifiers

Local EPrints ID: 483916
URI: http://eprints.soton.ac.uk/id/eprint/483916
DOI: doi:10.1016/j.engfracmech.2022.108724
ISSN: 0013-7944
PURE UUID: 53125969-f35e-4234-9c82-cada98ad1f64
ORCID for T. Mukhopadhyay: ORCID iD orcid.org/0000-0002-0778-6515

Catalogue record

Date deposited: 07 Nov 2023 18:26
Last modified: 18 Mar 2024 04:10

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Contributors

Author: A. Sharma
Author: T. Mukhopadhyay ORCID iD
Author: V. Kushvaha

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