Bilal, MühenadMühenadBilalPodishetti, RanadheerRanadheerPodishettiKoval, LeonidLeonidKovalGaafar, Mahmoud AbdelazizMahmoud AbdelazizGaafarGroßmann, DanielDanielGroßmannBregulla, MarkusMarkusBregulla2024-10-282024-10-282024-09-05IEEE Access 12: 124282-124297 (2024)https://hdl.handle.net/11420/49829Ensuring cutting tools are in optimal condition is essential for achieving peak machining performance, given their direct impact on both workpiece quality and process efficiency. However, accurately assessing wear on end mills, especially those with complex geometries, pose a significant challenge due to their reflective surfaces and varied wear patterns. Presented here is a novel method that addresses this challenge by employing a customized illumination unit in conjunction with a convolutional neural network (CNN) for end mill wear analysis. This innovative approach involves utilizing the specially designed illumination unit to capture high-quality images, enabling precise examination of material wear on helically shaped end mills. Notably, this method is tailored to illuminate reflective surfaces and represents a pioneering application in the realm of wear testing.We validate the viability of this approach by employing CNN-based models to segment wear on complex-shaped end mills coated with titanium carbonitride (TiCN) and titanium nitride (TiN). We achieved remarkable mean Intersection over Union (mIoU) results in wear detection on a test dataset: 0.99 for tool segmentation, 0.78 for abnormal wear, and 0.71 for normal wear segmentation.en2169-35362024124282124297IEEEhttps://creativecommons.org/licenses/by-nc-nd/4.0/convolutional neural networkCutting toolsend millshelical geometriesillumination sourcemachining performancematerial wearreflective surfaceswear analysiswear segmentationTechnology::621: Applied PhysicsComputer Science, Information and General Works::004: Computer SciencesJournal Article10.15480/882.1357710.1109/ACCESS.2024.345469210.15480/882.13577Journal Article