Emily Rolfe scite author profile

Emily Rolfe

5Publications

32Citation Statements Received

25Citation Statements Given

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Imperial College London

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Failure analysis using X-ray computed tomography of composite sandwich panels subjected to full-scale blast loading

Rolfe

Kelly

Arora

et al. 2017

Composites Part B: Engineering

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The tailorable mechanical properties and high strength-to-weight ratios of composite sandwich panels make them of interest to the commercial marine and naval sector, however, further investigation into their blast resilience is required. The experiments performed in this study aimed to identify whether alterations to the composite skins or core of a sandwich panel can yield improved blast resilience both in air and underwater. Underwater blast loads using 1.28 kg TNT equivalent charge at a stand-off distance of 1 m were performed on four different composite sandwich panels. Results revealed that implementing a stepwise graded density foam core, with increasing density away from the blast, reduces the deflection of the panel and damage sustained. Furthermore, the skin material affects the extent of panel deflection and damage, the lower strain to failure of carbon-fibre reinforced polymer (CFRP) skins reduces deflection but increases skin debonding. A further two panels were subjected to a 100 kg TNT air blast loading at a 15 m stand-off to compare the effect of a graded density core and the results support the underwater blast results. Future modelling of these experiments will aid the design process and should aim to include material damage mechanisms to identify the most suitable skins

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Blast Performance of Composite Sandwich Structures

Dear

Rolfe

Kelly

et al. 2017

Procedia Engineering

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High Velocity Impact and Blast Loading of Composite Sandwich Panels with Novel Carbon and Glass Construction

Rolfe

Kaboglu

Quinn

et al. 2018

J. dynamic behavior mater.

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This research investigates whether the layup order of the carbon-fibre/glass-fibre skins in hybrid composite sandwich panels has an effect on impact response. Composite sandwich panels with carbon-fibre/glass-fibre hybrid skins were subjected to impact at velocities of 75 ± 3 and 90 ± 3 m s −1. Measurements of the sandwich panels were made using high-speed 3D digital image correlation (DIC), and post-impact damage was assessed by sectioning the sandwich panels. It was concluded that the introduction of glass-fibre layers into carbon-fibre laminate skins reduces brittle failure compared to a sandwich panel with carbon-fibre reinforced polymer skins alone. Furthermore, if the impact surface is known, it would be beneficial to select an asymmetrical panel such as Hybrid-(GCFGC) utilising glass-fibre layers in compression and carbon-fibre layers in tension. This hybrid sandwich panel achieves a specific deflection of 0.322 mm kg −1 m 2 and specific strain of 0.077% kg −1 m 2 under an impact velocity of 75 ± 3 m s −1. However, if the impact surface is not known, selection of a panel with a symmetric yet more dispersed hybridisation would be effective. By distributing the different fibre layers more evenly within the skin, less surface and core damage is achieved. The distributed hybrid investigated in this research, Hybrid-(GCGFGCG), achieved a specific deflection of 0.394 mm kg −1 m 2 and specific strain of 0.085% kg −1 m 2 under an impact velocity of 75 ± 3 m s −1. Blast loading was performed on a large scale version of Hybrid-(GCFGC) and it exhibited a maximum deflection of 75 mm following a similar deflection profile to those observed for the impact experiments.

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Full-Scale Air and Underwater-Blast Loading of Composite Sandwich Panels

Arora

Rolfe

Kelly

et al. 2017

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Underwater blast loading of partially submerged sandwich composite materials in relation to air blast loading response

Rolfe

Quinn

Irven

et al. 2020

International Journal of Lightweight Materials and Manufacture

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Emily Rolfe

Failure analysis using X-ray computed tomography of composite sandwich panels subjected to full-scale blast loading

Blast Performance of Composite Sandwich Structures

High Velocity Impact and Blast Loading of Composite Sandwich Panels with Novel Carbon and Glass Construction

Full-Scale Air and Underwater-Blast Loading of Composite Sandwich Panels

Underwater blast loading of partially submerged sandwich composite materials in relation to air blast loading response

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