| People | Locations | Statistics |
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| Naji, M. |
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| Motta, Antonella |
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| Aletan, Dirar |
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| Mohamed, Tarek |
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| Ertürk, Emre |
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| Taccardi, Nicola |
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| Kononenko, Denys |
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| Petrov, R. H. | Madrid |
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| Alshaaer, Mazen | Brussels |
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| Bih, L. |
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| Casati, R. |
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| Muller, Hermance |
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| Kočí, Jan | Prague |
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| Šuljagić, Marija |
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| Kalteremidou, Kalliopi-Artemi | Brussels |
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| Azam, Siraj |
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| Ospanova, Alyiya |
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| Blanpain, Bart |
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| Ali, M. A. |
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| Popa, V. |
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| Rančić, M. |
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| Ollier, Nadège |
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| Azevedo, Nuno Monteiro |
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| Landes, Michael |
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| Rignanese, Gian-Marco |
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Trask, Rs
University of Bristol
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (56/56 displayed)
- 2024Raman spectroscopic stress mapping of single high modulus carbon fibre composite fragmentation in compressioncitations
- 2023Examining the quasi-static uniaxial compressive behaviour of commercial high-performance epoxy matricescitations
- 2023Examining the Quasi-Static Uniaxial Compressive Behaviour of Commercial High-Performance Epoxy Matricescitations
- 2022MANUFACTURING OF NOVEL HIERARCHICAL HYBRIDISED COMPOSITES
- 2021A life cycle engineering perspective on biocomposites as a solution for a sustainable recoverycitations
- 2019Compressive behaviour of 3D printed thermoplastic polyurethane honeycombs with graded densitiescitations
- 2018Development of Multi-Dimensional 3D Printed Vascular Networks for Self-Healing Materialscitations
- 2017Effect of fibre orientation on the low velocity impact response of thin Dyneema® composite laminatescitations
- 2016Oblique plies for steering through-thickness delamination migration in fiber-reinforced polymers
- 20163-D printed composites with ultrasonically arranged complex microstructurecitations
- 2015Oblique plies for steering through-thickness delamination migration in fibre reinforced polymers
- 2015Optimisation of epoxy blends for use in extrinsic self-healing fibre-reinforced compositescitations
- 2015Application of a silver-olefin coordination polymer as a catalytic curing agent for self-healing epoxy polymerscitations
- 2015Adaptive and active materials
- 2015The development of novel composite sandwich structures with integrated shock absorbing functionality
- 2015An investigation of in-plane performance of ultrahigh molecular weight polyethylene composites
- 2015Counterpropagating wave acoustic particle manipulation device for the effective manufacture of composite materialscitations
- 2015An experimental demonstration of effective Curved Layer Fused Filament Fabrication utilising a parallel deposition robotcitations
- 2015Additive layer manufacturing of composite components
- 2014Stimuli-triggered self-healing functionality in advanced fibre-reinforced compositescitations
- 2014Embedded catalytic healing agents for the repair of fibre-reinforced composites
- 2014Metal triflates as catalytic curing agents in self-healing fibre reinforced polymer composite materialscitations
- 2014Novel self-healing systems
- 2014Repeated self-healing of microvascular carbon fibre reinforced polymer compositescitations
- 2014Thermal ageing mitigation of frp composites using vascular networks
- 2014Bio-inspired structural bistability employing elastomeric origami for morphing applicationscitations
- 2013Healing of low-velocity impact damage in vascularised compositescitations
- 2012Autonomous stimulus triggered self-healing in smart structural compositescitations
- 2012Inhibiting delaminations in fibre reinforced plastic laminates with dropped plies
- 2012Numerical investigation into failure of laminated composite T-piece specimens under tensile loadingcitations
- 2012Stimuli triggered deployment of bio-inspired self-healing functionality
- 2012X-ray damage characterisation in self-healing fibre reinforced polymerscitations
- 2012Mode i interfacial toughening through discontinuous interleaves for damage suppression and controlcitations
- 2012Predicting self-healing strength recovery using a multi-objective genetic algorithmcitations
- 2011Bioinspired vasculatures for self-healing fibre reinforced polymer composites
- 2011Autonomous self-healing functionality in advanced fibre reinforced polymer composite materials
- 2011Self-healing of an epoxy resin using scandium(III) triflate as a catalytic curing agentcitations
- 2011Stimuli triggered deployment of bio-inspired self-healing functionality
- 2011Mode I interfacial toughening through discontinuous interleaves for damage suppression and controlcitations
- 2011The role of embedded bioinspired vasculature on damage formation in self-healing carbon fibre reinforced compositescitations
- 2011A probabilistic approach for design and certification of self-healing advanced composite structurescitations
- 2011Interactions between propagating cracks and bioinspired self-healing vascules embedded in glass fibre reinforced compositescitations
- 2011Multi-mode self-healing in composite materials using novel chemistry
- 2010Bioinspired engineering study of Plantae vascules for self-healing composite structurescitations
- 2010Characterization and analysis of carbon fibre-reinforced polymer composite laminates with embedded circular vasculaturecitations
- 2009Analytical study of vascular networks for self-healing composite laminates
- 2009Compression after impact assessment of self-healing CFRPcitations
- 2009Biomimicry of plantae vascules in the development of self-healing composite structures
- 2008Self-healing sandwich panelscitations
- 2008Minimum mass vascular networks in multifunctional materialscitations
- 2008Bioinspired self-healing of advanced composite materials
- 2007Bioinspired self-healing of advanced composite structures using hollow glass fibrescitations
- 2007Self-healing composite sandwich structurescitations
- 2007Self-healing of impact damaged CFRP
- 2007Biomimetic planar and branched self-healing networks in composite laminates
- 2006Biomimetic self-healing of advanced composite structures using hollow glass fibrescitations
Places of action
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document
Biomimicry of plantae vascules in the development of self-healing composite structures
Abstract
<p>This paper presents the first investigation into the concept of creating a Plantae inspired vascular network within a fibre reinforced polymer composite laminate which provides an ongoing self-healing functionality but does not incur a mass penalty. Through the application of a 'lost-wax' technique, parallel hollow vascules, similar to 'ray cells' in ring porous hardwoods, were successfully introduced within a carbon fibre reinforced epoxy polymer composite laminate. The influence of single and dual vascules on the surrounding composite fibre architecture (i.e. introduction of fibre waviness and resin rich pockets) was characterised experimentally using a compression-after-impact test methodology. It has been shown that the vascules interact with the impact damage but they do not promote a preferential failure path whether aligned parallel or normal to the host plies. The compressive failure strength was found to be comparable in the baseline orientation and parallel (0°) configurations for both the undamaged and damaged (10J) cases. In the case of the normal (90°) vascule the formation of resin rich pockets does not appear to have degraded the relative compressive performance of the laminate, although intuitively the out-of-plane ply variation would be expected to trigger the early onset of compression failure. The interlaminar tensile strength tests illustrated that although a knockdown in performance occurs as a result of the vascules inclusion (39% for the 90-degree vascule, 43% for the 45-degree vascule and 61% for the inclusion of the aligned vascule), the off-axis vascule (and their associated resin-rich pockets) perform better than the vascules aligned to their host ply. This observation may explain the difference in performance observed in the compression tests where the aligned vascules not damage by the impact event, but in close proximity to the damage site, help alter the stress state ahead of the crack thus initiating earlier failure. In conclusion, the research undertaken here illustrates the positive and negative influences the vascules have on the global compressive failure mode as a minimum-mass self-healing solution. Following this new understanding, better bioinspired composite materials can be designed which harness the inherent damage tolerant capabilities to 'direct' a propagating crack into a predetermined healing feature.</p>