S. McKown scite author profile

The rapid manufacturing process of selective laser melting has been used to produce a series of stainless steel 316L microlattice structures. Laser power and laser exposure time are the two processing parameters used for manufacturing the lattice structures and, therefore, control the quality and mechanical properties of microlattice parts. An evaluation of the lattice material was undertaken by manufacturing a range of struts, representative of the individual trusses of the microlattices, as well as, microlattice block structures. Low laser powers were shown to result in significantly lower strand strengths due to the presence of inclusions of unmelted powder in the strut cross-sections. Higher laser powers resulted in struts that were near to full density as the measured strengths were comparable to the bulk 316L values. Uniaxial compression tests on microlattice blocks highlighted the effect of manufacturing parameters on the mechanical properties of these structures and a linear relationship was found between the plateau stress and elastic modulus relative to the measured relative density.

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The quasi-static and blast loading response of lattice structures

McKown

Shen

Brookes

et al. 2008

International Journal of Impact Engineering

306

114

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Drop weight impact behaviour of sandwich panels with metallic micro lattice cores

Mines

Tsopanos

Shen

et al. 2013

International Journal of Impact Engineering

204

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The Mechanical Properties of Sandwich Structures Based on Metal Lattice Architectures

Shen

McKown

Tsopanos

et al. 2009

Jnl of Sandwich Structures & Materials

129

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A range of metallic lattice structures were manufactured using the selective laser melting (SLM) rapid prototyping technique. The lattices were based assemblies of repeating unit-cells with their strands oriented at 0°, ±45°, and 90° to the vertical when viewed from the front. Mechanical tests on the strands and the lattice blocks showed that these systems exhibit a high level of reproducibility in terms of their basic mechanical properties. An examination of the compression failure mechanisms showed that the [±45°] and [±45°, 90°] lattices failed in bending and stretching modes of failure, whereas the [0°, ±45°] lattices failed as a result of buckling of the vertical pillars. Sandwich structures were manufactured by binding woven carbon-fiber reinforced plastic to the lattice structures. Subsequent three-point bend tests on these structures identified the principal failure mechanisms under flexural loading conditions. Here, cell crushing, hinge rotation, and gross plastic deformation in the strands were observed directly under the point of loading. Low-velocity impact tests were conducted on the sandwich beams and a simple energy-balance model was used to understand how energy is absorbed by the sandwich structures. The model suggests that the majority of the incident energy of the projectile was absorbed in indentation effects, predominantly in the core material, directly under the steel indenter.

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Impact of aircraft rubber tyre fragments on aluminium alloy plates: I—Experimental

Mines

McKown

Birch

2007

International Journal of Impact Engineering

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S. McKown

The Influence of Processing Parameters on the Mechanical Properties of Selectively Laser Melted Stainless Steel Microlattice Structures

The quasi-static and blast loading response of lattice structures

Drop weight impact behaviour of sandwich panels with metallic micro lattice cores

The Mechanical Properties of Sandwich Structures Based on Metal Lattice Architectures

Impact of aircraft rubber tyre fragments on aluminium alloy plates: I—Experimental

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