Abstract
The manufacturing industry is continuously researching and developing strategies and solutions to increase product quality and to decrease production time and costs. The approach is always targeting more automated, traceable, and supervised production, minimizing the impact of the human factor. In the automotive industry, the Electronic Control Unit (ECU) manufacturing ends with complex testing, the End-of-Line (EoL) products being afterwards sent to client companies. This paper proposes an image-processing-based low-cost fault detection (IP-LC-FD) solution for the EoL ECUs, aiming for high-quality and fast detection. The IP-LC-FD solution approaches the problem of determining, on the manufacturing line, the correct mounting of the pins in the locations of each connector of the ECU module, respectively, other defects as missing or extra pins, damaged clips, or surface cracks. The IP-LC-FD system is a hardware–software structure, based on Raspberry Pi microcomputers, Pi cameras, respectively, Python and OpenCV environments. This paper presents the two main stages of the research, the experimental model, and the prototype. The rapid integration into the production line represented an important goal, meaning the accomplishment of the specific hard acceptance requirements regarding both performance and functionality. The solution was implemented and tested as an experimental model and prototype in a real industrial environment, proving excellent results.
Highlights
With the application and promotion of Industry 4.0 in industrial engineering, each big manufacturing plant received obvious improvements in human cost, quality-enhancing, rapid customization, and manufacturing, and learned that the application of advanced intelligent processing technology to manufacturing is the new development trend
Optical Inspection (AOI) has attracted increasing interest in product quality control in both academic and industrial communities, on mass production processes, because product quality can often be characterized by their corresponding surface visual attributes
Following applications based on convolutional neural networks for fault detection, recognition, and classification, this paper proposes an optimized visual geometry group model that contributed to a high rate of testing accuracy of 99.87%
Summary
With the application and promotion of Industry 4.0 in industrial engineering, each big manufacturing plant received obvious improvements in human cost, quality-enhancing, rapid customization, and manufacturing, and learned that the application of advanced intelligent processing technology to manufacturing is the new development trend. Optical Inspection (AOI) has attracted increasing interest in product quality control in both academic and industrial communities, on mass production processes, because product quality can often be characterized by their corresponding surface visual attributes. Considering that most product qualities can be characterized by corresponding surface visual attributes, the visual appearance, including the attributes of color, size, surface coarseness, and variety of defects of the product surface, is an effective and direct sensory indicator for product quality inspection or production condition monitoring to a certain extent. It is found that the correct diagnosis of some defects based on the image processing depends highly on the resolution and quality of the image acquisition, position of the piece, contrast and brightness of certain elements, lighting mode, etc
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