M. Iragi scite author profile

Taking advantage of an extended design and manufacturing space for composites, the technology of Fused Filament Fabrication (FFF) of continuous fibre-reinforced thermoplastics shows great potential for the production of the next generation of lightweight structural parts. This novel process is very much under development, and knowledge of the mechanical behaviour of the resulting 3D-printed materials is still limited. In this work, the intra-and inter-laminar behaviours of carbon fibre/polyamide printed laminates were extensively characterised to determine ply elastic and strength properties, as well as interface strength and fracture characteristics. Moreover, the effects of eventual production defects on these properties were analysed, putting in evidence some of the present shortcomings of the FFF process. Such defects include non-homogeneous fibre distribution, large amounts of intra-and interlaminar voids, and weak interlayer bonding, which are likely to be due to insufficient thermo-mechanical consolidation of the material during the FFF process, and have significant influence on the matrix-dominated mechanical properties. As a result, the transverse and interlaminar properties were found to be lower than those obtained through Hot Compression Moulding of an equivalent material. Besides highlighting possible process improvements, the mechanical characterisation carried out in this work promises a significant

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An approach to analyse the factors behind the micromechanical response of 3D-printed composites

Pascual-González

Iragi

Fernández

et al. 2020

Composites Part B: Engineering

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Design, manufacturing and testing of 3D printed variable-stiffness laminates for improved open-hole tensile behaviour

Iragi

Pascual-González

Esnaola

et al. 2023

Additive Manufacturing

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Quasi-static and dynamic crush behaviour of 3D printed thin-walled profiles reinforced with continuous carbon and glass fibres

Morales

Esnaola

Iragi

et al. 2021

Composites Part B: Engineering

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Over-3D printing of continuous carbon fibre composites on organo-sheet substrates

Morales

Esnaola

Iragi

et al. 2019

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M. Iragi

Ply and interlaminar behaviours of 3D printed continuous carbon fibre-reinforced thermoplastic laminates; effects of processing conditions and microstructure

An approach to analyse the factors behind the micromechanical response of 3D-printed composites

Design, manufacturing and testing of 3D printed variable-stiffness laminates for improved open-hole tensile behaviour

Quasi-static and dynamic crush behaviour of 3D printed thin-walled profiles reinforced with continuous carbon and glass fibres

Over-3D printing of continuous carbon fibre composites on organo-sheet substrates

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