$Methodology for DIC-based evaluation of the fracture behaviour of solder materials under monotonic and creep loadings$

Methodology for DIC-based evaluation of the fracture behaviour of solder materials under monotonic and creep loadings

•DIC-based evaluation of fracture parameters of lead-free solder.•Identification of appropriate constitutive laws for monotonic and creep behaviours.•Fitting procedure using measured displacement field for evaluation of SIF.•Domain integrals based on DIC data points used for evaluations of J and C(t...

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Veröffentlicht in:	Engineering fracture mechanics 2020-11, Vol.239, p.107285, Article 107285
Hauptverfasser:	Benabou, L., Nguyen-Van, T.A., Tao, Q.B., Le, V.N., Ould Ouali, M., Nguyen-Xuan, H.
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Creep (materials) DIC measurements Digital imaging Domain integrals Electronic packaging Engineering Sciences Evaluation Finite element method High temperature Lead free Materials Parameter identification Parameter uncertainty Rupture Solders Stress intensity factors Viscoplasticity
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creator	Benabou, L. Nguyen-Van, T.A. Tao, Q.B. Le, V.N. Ould Ouali, M. Nguyen-Xuan, H.
description	•DIC-based evaluation of fracture parameters of lead-free solder.•Identification of appropriate constitutive laws for monotonic and creep behaviours.•Fitting procedure using measured displacement field for evaluation of SIF.•Domain integrals based on DIC data points used for evaluations of J and C(t)•Methodology capabilities and shortcomings are discussed in relation to FEM results. New lead-free solder alloys for electronic packaging contain doping elements conferring upon them improved properties in terms of ease of processibility and strength under high temperature operation conditions. Studies on their resistance to quasi-static rupture remain however relatively limited. In this work, the SAC-based solder alloy, known as InnoLot, is considered and its rupture under monotonic and creep loadings is investigated experimentally and numerically. The Digital Image Correlation (DIC) technique is employed to evaluate the stress intensity factor, as well as the J- and C(t)-integrals, from full-field measurements on notched specimens. The numerical formulations of the theoretical concepts for computation of the physical fracture quantities are provided in the framework of the DIC algorithm. Results derived from the DIC experiments are compared with predictions given by finite element models, and good agreement is found in general. The observed discrepancies can be explained by lack of resolution of the optical setup measurements in the infinitesimal strain regime or by uncertainty associated with the identified material parameters used in the evaluation of stresses from the acquired strains.
doi_str_mv	10.1016/j.engfracmech.2020.107285
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New lead-free solder alloys for electronic packaging contain doping elements conferring upon them improved properties in terms of ease of processibility and strength under high temperature operation conditions. Studies on their resistance to quasi-static rupture remain however relatively limited. In this work, the SAC-based solder alloy, known as InnoLot, is considered and its rupture under monotonic and creep loadings is investigated experimentally and numerically. The Digital Image Correlation (DIC) technique is employed to evaluate the stress intensity factor, as well as the J- and C(t)-integrals, from full-field measurements on notched specimens. The numerical formulations of the theoretical concepts for computation of the physical fracture quantities are provided in the framework of the DIC algorithm. Results derived from the DIC experiments are compared with predictions given by finite element models, and good agreement is found in general. 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New lead-free solder alloys for electronic packaging contain doping elements conferring upon them improved properties in terms of ease of processibility and strength under high temperature operation conditions. Studies on their resistance to quasi-static rupture remain however relatively limited. In this work, the SAC-based solder alloy, known as InnoLot, is considered and its rupture under monotonic and creep loadings is investigated experimentally and numerically. The Digital Image Correlation (DIC) technique is employed to evaluate the stress intensity factor, as well as the J- and C(t)-integrals, from full-field measurements on notched specimens. The numerical formulations of the theoretical concepts for computation of the physical fracture quantities are provided in the framework of the DIC algorithm. Results derived from the DIC experiments are compared with predictions given by finite element models, and good agreement is found in general. 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subjects	Algorithms Creep (materials) DIC measurements Digital imaging Domain integrals Electronic packaging Engineering Sciences Evaluation Finite element method High temperature Lead free Materials Parameter identification Parameter uncertainty Rupture Solders Stress intensity factors Viscoplasticity
title	Methodology for DIC-based evaluation of the fracture behaviour of solder materials under monotonic and creep loadings
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