In sheet metal production the quality of a cut is determined by the quality of the cut edge and is of crucial importance. One parameter affecting the quality of the cut edge surface is its roughness. In order to determine the roughness, the depth information is required. The common methods for acquiring depth information are very time consuming and therefore not suitable for a quick roughness evaluation. We present a method for a quick roughness evaluation by means of 2D image processing. It is shown that, given a proper dataset, a convolutional neural network can be trained to identify image features that correlate highly with the roughness of the edge surface and learn how to weight these features correctly. This makes the neural network capable of providing a quick and accurate statement about the roughness of the edge surface based on an image.
In sheet metal production the quality of a cut determines the conditions for a possible postprocessing. Considering the roughness as a parameter for assessing the quality of the cut edge, different techniques have been developed that use texture analysis and convolutional neural networks. All methods available require the use of appropriate equipment and work only in fixed light conditions. In order to discover new applications in the contexts of Industry 4.0, there is a necessity to go beyond their intrinsic limits as camera types and light condition while ensuring the same level of performance. Taking into account the strong increase of the smartphones features in recent years and the fact that their performance in some respect is now comparable to that of a PC with a middle-range mirrorless camera, it is no longer utopian to think of a new out-of-the-box use of these devices that employs the capability in a new way and in a new context. Therefore, we present a method that uses a mobile device with a camera to guarantee images of sufficient quality that can be used for further processing in order to determine the quality of the metal sheet edge. After the image acquisition of the sheet metal edge in real condition of use, the method uses a trained deep neural network to identify the sheet metal edge present in the picture. After the segmentation a no-reference image quality algorithm provides an image quality index, in terms of blurriness, for the image region of the cut edge. This way it is possible for the further evaluation of the cut edge to only consider image data that satisfies a specific quality, ignoring all the parts of the picture with a bad image quality.
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