D.M. White scite author profile

D.M. White

5Publications

142Citation Statements Received

18Citation Statements Given

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142

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Hypervelocity impact on CFRP: Testing, material modelling, and numerical simulation

Wicklein

Ryan

White³

et al. 2008

International Journal of Impact Engineering

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This paper describes the derivation and validation of a numerical material model that predicts the highly dynamic behaviour of CFRP (carbon fibre reinforced plastic) under hypervelocity impact. CFRP is widely used in satellites as face sheet material in CFRP-Al/HC sandwich structures (HC = honeycomb), that can be exposed to space debris. A review of CFRP-Al/HC structures typically used in space was performed. Based on this review, a representative structure in terms of materials and geometry was selected for study in the work described here. An experimental procedure for the characterisation of composite materials is documented in [1]. The test results from the CFRP of the current study allow for the derivation of an experimentally based orthotropic continuum material model data set that is capable of predicting the mechanical behaviour of CFRP under hypervelocity impact. Such a data set was not previously available. In [2] an orthotropic material data set was used for modelling HVI on AFRP (aramid fibre reinforced plastic), which shows relatively high deformability before failure. The enhancements of the modelling approaches in [1] and [3] necessary to model brittle CFRP are specified. An experimental hypervelocity impact campaign was performed at two different two stage light gas guns which encompassed both normal and oblique impacts for a range of impact velocities and projectile diameters. Validation of the numerical model is provided through comparison with the experimental results. For that purpose measurements of the visible damage of the face sheets and of the HC core are conducted. In addition, the numerically predicted damage within the CFRP is compared to the delamination areas found in ultrasonic scans.

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Hypervelocity impact damage prediction in composites: Part I—material model and characterisation

Clegg¹,

White²,

Riedel

et al. 2006

International Journal of Impact Engineering

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Hypervelocity impact damage prediction in composites: Part II—experimental investigations and simulations

Riedel

Nahme

White³

et al. 2006

International Journal of Impact Engineering

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Multi-layer insulation material models suitable for hypervelocity impact simulations

White¹,

Wicklein

Clegg³

et al. 2008

International Journal of Impact Engineering

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Advanced numerical models and material characterisation techniques for composite materials subject to impact and shock wave loading

Clegg¹,

White²,

Hayhurst³

et al. 2003

J. Phys. IV France

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The development and validation of an advanced material model for orthotropic materials, such as fibre reinforced composites, is described. The model is specifically designed to facilitate the numerical simulation of impact and shock wave propagation through orthotropic materials and the prediction of subsequent material damage. Initial development of the model concentrated on correctly representing shock wave propagation in composite materials under high and hypervelocity impact conditions. This work has now been extended to further concentrate on the development of improved numerical models and material characterisation techniques for the prediction of damage, including residual strength, in fibre reinforced composite materials. The work is focussed on Kevlar-epoxy however materials such as CFRP are also being considered. The paper describes our most recent activities in relation to the implementation of advanced material modelling options in this area. These enable refined non-liner directional characteristics of composite materials to be modelled, in addition to the correct thermodynamic response under shock wave loading. The numerical work is backed by an extensive experimental programme covering a wide range of static and dynamic tests to facilitate derivation of model input data and to validate the predicted material response. Finally, the capability of the developing composite material model is discussed in relation to a hypervelocity impact problem

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D.M. White

Hypervelocity impact on CFRP: Testing, material modelling, and numerical simulation

Hypervelocity impact damage prediction in composites: Part I—material model and characterisation

Hypervelocity impact damage prediction in composites: Part II—experimental investigations and simulations

Multi-layer insulation material models suitable for hypervelocity impact simulations

Advanced numerical models and material characterisation techniques for composite materials subject to impact and shock wave loading

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