Abstract
The automatic radioscopic inspection of industrial parts usually uses reference based methods. These methods select, as benchmark for comparison, image data from good parts to detect the anomalies of parts under inspection. However, parts can vary within the specification during the production process, which makes comparison of older reference image sets with current images of parts difficult and increases the probability of false rejections. To counter this variability, the reference image sets have to be updated. This paper proposes an adaptive reference image set selection procedure to be used in the assisted defect recognition (ADR) system in turbine blade inspection. The procedure first selects an initial reference image set using an approach called ADR Model Optimizer and then uses positive rate in a sliding-time window to determine the need to update the reference image set. Whenever there is a need, the ADR Model Optimizer is retrained with new data consisting of the old reference image sets augmented with false rejected images to generate a new reference image set. The experimental result demonstrates that the proposed procedure can adaptively select a reference image set, leading to an inspection process with a high true positive rate and a low false positive rate.
Highlights
The highly competitive manufacturing industry has demanded higher quality and lower manufacturing costs for the past several decades
Use MOA for assisted defect recognition (ADR) to inspect the image data generated after point A, and use the callout rate in a sliding window (CR STW) to measure the variation of the image data
This proposed procedure for reference model image sets selection has been validated by X-ray images from trailing edge view for turbine blades of blade type “A” through extensive experiments
Summary
The highly competitive manufacturing industry has demanded higher quality and lower manufacturing costs for the past several decades. These requirements have led to great technological advances of automation in manufacturing processes [1, 2]. NDE methods include diverse techniques, like radiographic Xray imaging, and penetrate testing and eddy-current testing. Among these techniques, radiographic X-ray imaging is the most commonly used for locating abnormal features that are located inside the manufactured parts, for example, the aluminum wheels, steering gears of cars, and the turbine blades of jet engines [4, 5]
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