Influence of shear plugging in the energy absorbed by thin carbon-fibre laminates subjected to high-velocity impacts

Buitrago, Brenda L.; García-Castillo, Shirley K.; Barbero, Ever J.

doi:10.1016/j.compositesb.2013.01.005

Cited by 25 publications

(11 citation statements)

References 27 publications

(44 reference statements)

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“…If the shear stress exceeds shear plugging strength of the laminate, then failure occurs due to shear plugging. The energy absorbed by the laminate for the formation of shear plug is calculated [21],…”

Section: Energy Absorption In Laminatesmentioning

confidence: 99%

Energy absorption of repaired composite laminates subjected to impact loading

Balaganesan

Khan

2016

Composites Part B: Engineering

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Section: Energy Absorption In Laminatesmentioning

confidence: 99%

Energy absorption of repaired composite laminates subjected to impact loading

Balaganesan

Khan

2016

Composites Part B: Engineering

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“…It was also determined that PU in the p ‐aramid fabrics increased the energy absorption during the puncture test. It appears that PU, a polymer with high toughness, plays a significant role in not only protecting the p ‐aramid fiber from fracturing but also in increasing the energy absorption of the fabric composite by inducing delamination and matrix cracking . The MRF further raised the energy absorption under a magnetic field in the MRF/ p ‐aramid fabric, as well as in the PU‐MRF/ p ‐aramid fabric composite.…”

Section: Resultsmentioning

confidence: 99%

Preparation and properties of a p‐aramid fabric composite impregnated with a magnetorheological fluid for body armor applications

Kang

Hong

Jeong

2013

Polymer Engineering & Sci

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A polyurethane (PU)-magnetorheological fluid (MRF)/ p-aramid fabric composite was fabricated, and its mechanical properties were subsequently investigated. The contribution of the PU-MRF matrix to the impact resistance of the system was then discussed. MRFs consist of stable suspensions of magnetite particles within a carrying fluid. Therefore, when an external magnetic field is applied, the MRFs exhibit drastic and reversible changes in rheological properties as a result of the fieldinduced ordering of the particulate phase. We then attempted to develop new and enhanced bulletproof materials by incorporating MRF and PU in a p-aramid fabric. It was found that when a magnetic field was applied, the mechanical properties of the PU-MRF/p-aramid fabric composite improved. It was also found that adding a PU matrix improves the impact performance of the PU-MRF/ p-aramid fabric composite, relative to a neat p-aramid fabric and a MRF/p-aramid fabric composite with similar areal density. The improved impact performance of the PU-MRF/p-aramid fabric composite appears to be because the PU film and MRF enable different energy absorbing mechanisms, including particle friction, fabric/ matrix debonding, matrix cracking, and delamination, which are not observed in neat p-aramid fabric systems. The findings of this study are thought to be important from a design viewpoint of soft armors. POLYM. ENG. SCI.,

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“…RCC composites are essentially constituted by rayon fibers in carbon matrix, and the more recent ACC (based on PAN-based carbon reinforcements) are gradually replacing RCC structures. Due to their lightweight characteristics and high-temperature strength, general C/C are suitable candidate materials to satisfy the very stringent design requirements of reusable space vehicles and have been used as thermal protection systems (TPS) in airframes subjected to high temperature in hypersonic and reusable launch vehicles like the Space Shuttle [4,5] Although the mechanical and thermal properties of C/C composites are nowadays fairly well understood [6][7][8] and extensive investigations have been performed about the dynamic mechanical properties of "conventional" types of composites (i.e., resin matrix composites) [9][10][11][12][13][14][15][16][17][18][19], the knowledge about the high-speed impact dynamic behavior of C/C composites is still incomplete. Several research groups have studied the effect of the temperature on the dynamic properties and the impact damage at low temperature [20][21][22][23] and cryogenic environment [24,25], but the temperature range usually limited between -150°C and 150°C due to the partial heat resistance capability of common composite materials.…”

Section: Introductionmentioning

confidence: 99%

High velocity impact tests on high temperature carbon-carbon composites

Xie

Meng

Ding

et al. 2016

Composites Part B: Engineering

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General rightsThis document is made available in accordance with publisher policies. Please cite only the published version using the reference above. AbstractThis paper describes the effect of high velocity impact on the structural integrity of advanced carbon-carbon (C/C) composites for high temperature applications. Impact tests have been performed on heated C/C composite samples at high temperature to establish correlations between the mechanical performances of the composites and different impact factors. Two tensile tests were also performed to investigate the residual strength of the high temperature C/C structures with the impact damage. In this work we present two new equations to predict the dimensionless damage areas of the C/C impacted at elevated temperatures. The impact resistance of the C/C composites is affected by the diameter of the projectile, the temperature and thickness of the C/C laminates and -more importantly -by the impact velocity. The residual strength of the damaged C/C composites increased by 47% after heating the samples from 25°C to 1206°C.

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Influence of shear plugging in the energy absorbed by thin carbon-fibre laminates subjected to high-velocity impacts

Cited by 25 publications

References 27 publications

Energy absorption of repaired composite laminates subjected to impact loading

Energy absorption of repaired composite laminates subjected to impact loading

Preparation and properties of a p‐aramid fabric composite impregnated with a magnetorheological fluid for body armor applications

High velocity impact tests on high temperature carbon-carbon composites

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