Kevin Kerrigan scite author profile

Characterization of the damage induced by machining of fibre-reinforced composites is usually performed by measuring surface roughness. Contact-based surface profilometers are the most used equipment in industry; however, it has been found that there are performance limitations which may result when used to measure machined heterogeneous composite surfaces. In this research, surface roughness is characterised using a commercial non-contact optical method, and compared with a conventional stylus profilometer. Unidirectional and multidirectional carbon fibre laminates were edge trimmed and slot milled. The variation in surface roughness was compared using different tool types, fibre orientations and cutting parameters. Surface damage and cutting mechanisms were assessed by using scanning electron microscope images, and the suitability of roughness parameters were also analysed including: Sa, Skewness and Kurtosis. Using the optical system allowed accurate roughness calculation of individual plies on a multidirectional laminate with different fibre orientations. The research has also shown that the optical system, including the use of areal roughness parameters, can increase the accuracy of roughness measurement for machined fibrous composite surfaces and is less sensitive to measurement position than the stylus.

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An Integrated Telemetric Thermocouple Sensor for Process Monitoring of CFRP Milling Operations

Kerrigan

Thil²,

Hewison³

et al. 2012

Procedia CIRP

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Effects of machine stiffness and cutting tool design on the surface quality and flexural strength of edge trimmed carbon fibre reinforced polymers

Ashworth

Fairclough

Takikawa

et al. 2019

Composites Part A: Applied Science and Manufacturing

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A 2 2 full factorial design of experiment is used to investigate the effects of two machining platforms (5axis elevated gantry versus 6-axis articulated robotic system) and two cutting tool designs (burr versus herringbone) on surface metrics and flexural strength of a 14 ply T300 2x2 carbon fibre reinforced polymer.A range of areal metrics were considered to characterise the surface with S al and S tdi best able to represent differences due to the choice of robotic system or overhead gantry. The robotic system produces coupons with flexural strengths up to 26% higher than the overhead gantry. The choice of tool has a less significant effect however machine-tool interactions do play a role in the flexural strength.Analysis using scanning electron microscopy shows that defects may be obscured by smeared matrix which may contribute to overall flexural strength differences.

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Kevin Kerrigan

Abrasive Water Jet Machining of Multidirectional CFRP Laminates

An optical method for measuring surface roughness of machined carbon fibre-reinforced plastic composites

An Integrated Telemetric Thermocouple Sensor for Process Monitoring of CFRP Milling Operations

Effects of machine stiffness and cutting tool design on the surface quality and flexural strength of edge trimmed carbon fibre reinforced polymers

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