2018
DOI: 10.3390/jmse6020038
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Peridynamic Analysis of Marine Composites under Shock Loads by Considering Thermomechanical Coupling Effects

Abstract: Nowadays, composite materials have been increasingly used in marine structures because of their high performance properties. During their service time, they may be exposed to extreme loading conditions such as underwater explosions. Temperature changes induced by pure mechanical shock loadings cannot to be neglected especially when smart composite materials are employed for condition monitoring of critical systems in a marine structure. Considering this fact, both the thermal loading effect on deformation and … Show more

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Cited by 15 publications
(1 citation statement)
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“…The authors noted the comparative difficulty in predicting brittle composite failure as opposed to ductile deformation of metal components. The systems that have been modelled include: (i) sandwich panels under blast load [263,264] (the authors ignored certain complex phenomena such as small amplitude, high frequency oscillations); (ii) numerical modelling of a complete submarine hull subject to stand-off explosion [265,266], and (iii) a peridynamic thermomechanical model of shock-loaded marine composites [267].…”
Section: Underwater Loadingmentioning
confidence: 99%
“…The authors noted the comparative difficulty in predicting brittle composite failure as opposed to ductile deformation of metal components. The systems that have been modelled include: (i) sandwich panels under blast load [263,264] (the authors ignored certain complex phenomena such as small amplitude, high frequency oscillations); (ii) numerical modelling of a complete submarine hull subject to stand-off explosion [265,266], and (iii) a peridynamic thermomechanical model of shock-loaded marine composites [267].…”
Section: Underwater Loadingmentioning
confidence: 99%