Abstract
This paper deals on artificial intelligence (AI) application for the estimation of kerf geometry and hole diameters for laser micro-cutting and laser micro-drilling operations. To this aim laser cutting and laser drilling operation were performed on NIMONIC 263 superalloy sheet, 0.38 mm in nominal thickness, by way of a 100 W fibre laser in modulated wave regime. Linear cuts and holes (by trepanning) were performed fixing the average power at 80 W and changing the pulse duration, the cutting speed, the focus depth and the laser path (the latter only for the drilling operations). Kerf width and the holed diameter, at the upper and downsides, were measured by digital microscopy. Different artificial neural networks (ANNs) were developed and tested to predict the kerf widths and the diameters (at the upper and downside). Two ANNs were addressed to the linear cutting process modelling; also, two further ANNs were developed for micro-drilling on the base of the linear cutting process features. The networks were trained with a subset of data containing the process conditions and the kerf/hole geometry. The ANN test was performed with the remaining data. The results show that ANNs can model the cut and hole geometry as a function of the process parameters. Moreover, the ANN trained with kerf geometry is more efficient. Therefore, a functional correlation between the kerf geometries achievable in the linear cutting process and micro-drilling was assessed.
Highlights
Manufacturing processes for material processing extensively apply laser technologies [1] due to some peculiar features of these methods such as precision, flexibility, low thermal impact on substrates and elevated productivity
The results show how it is possible to find a functional correlation between the kerf geometries achievable in linear cutting process and micro-drilling
In the latter configuration, the heat spreading inside the hole section gives a continuous thermal contribution that enlarges the kerf geometry
Summary
Manufacturing processes for material processing extensively apply laser technologies [1] due to some peculiar features of these methods such as precision, flexibility, low thermal impact on substrates and elevated productivity. These characteristics are critical, especially for all those sectors with tight quality requirements in terms of tolerances and metallurgical characteristics when no burr and recast layer are allowed. Electrical discharge machining (EDM) represents state-ofthe art in micro-drilling systems. The kerf geometry evaluation of linear cuts is easier than micro-drilling characterization, since the latter requires the observation of the hole just in the middle
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