Cloud native EDA tools & pre-optimized hardware platforms
Posted on 4 October 2022 by David Harman
Jet engine turbine blades are required to operate in some of the most extreme conditions, where operating temperatures may exceed the melting point of the alloys used. As a result, complex cooling geometries, coatings, and other properties are used to keep blades within operational temperature, with failure not being an option. However, manufactured parts may contain small embedded and hidden defects, creating a need to use a methodology such as CT inspection to inspect the inside of these parts.
CT inspection is a nondestructive industrial x-ray process, where a part is rotated 360 degrees while hundreds or thousands of individual 2D radiographs are captured at specific degree intervals. This collection of 2D radiographs are then reconstructed into a 3D CT volume which can be digitally sliced through at any angle, allowing users to inspect both the external and internal features of the product without needing to physically cut or open their product.
However, one challenge with this workflow is that the ability to resolve defects and dimensions within the part is dictated by overall image quality and image quality can be directly correlated with inspection cycle time. High density and complex parts, like turbine blades, typically require a significant amount of scan and technician interpretation time. This can create a potential bottleneck for high-throughput applications.
Synopsys Simpleware Custom Modeler offers a solution to the challenge of bottlenecks in manual image review through case-specific analysis with AI-enabled Machine Learning methods. With this approach, time-consuming manual segmentation time is eliminated from the work, and inspection time is reduced by the pre-determination of defect locations. Further scaling up of inspection is therefore only dependent on the power of the hardware being used for the inspection. In collaboration with , a project was developed to detect low-frequency critical defects in high-pressure turbine blades, with the goal of creating a fully automated inspection assistant to highlight possible defect regions, and to speed up critical inspection workflows.
Automated critical defect inspection tool in Simpleware software
X-ray CT technology has seen a lot of great innovation in recent years. Expanded capabilities through scanning methods like Pixel Push, Helical CT, Offset CT, and even hardware improvements including Heat Dissipating Rotating Targets and 450kV Microfocus tubes have been instrumental in the growth of CT scanning across many industries. Oftentimes, CT can provide a view that users cannot obtain any other way.
Deciding which CT method and technique is best is largely dependent on the specific needs of each company and the goals of their project. CT technicians need to consider a product¡¯s material, density, size, shape, features, as well as defect size requirements, scan time goals, and even the desired output format, as all these details can have an impact on the optimum CT scanning technique.
Illustration of X-ray process: high-resolution LDA scan (a) and a slice from a high-speed DDA scan (b)
Once goals and product details are understood, a scan technique can be developed. The most common hardware parameters used with industrial CT are, x-ray energy (225kV or 450kV), focal spot size (mini-focus or micro-focus) and detector type (LDA or DDA). From there, part fixturing, geometric magnification and manipulator positioning (source to part, source to detector, etc.) are set. Finally, acquisition methods, number of projections and other fine-tuning adjustments are made before running the CT scan.
As for this project, due to the high density of turbine blades, 450kV micro-focus tube was selected and both an LDA and DDA detector was tested. To develop an ideal reference scan, Avonix Imaging performed a number of high-quality LDA scans as well as a sample of high-speed scans using a DDA detector on the same set of turbine blade samples. Scan times during these sample runs ranged from a few minutes to many hours, therefore illustrating the importance of understanding project goals and finding a technique that meets those goals as efficiently as possible.
Once the CT scanning process is optimized for efficiency, the next step is to develop an automated inspection workflow.
Automated inspection workflow using Simpleware Custom Modeler
In practice, the automated workflow involves:
This customized automated workflow is designed to allow rapid defect defection for high-volume manufacturing, reducing the need for time-intensive manual segmentation.
The automated workflow developed with data from Avonix Imaging demonstrates the potential to solve bottlenecks associated with inspection for high-value parts such as jet engine blades. In addition, the methods used in Simpleware Custom Modeler can be easily extended through 'bolt-on' additional measurement strategies for further analyses. Example measurements include GD&T-style measurements, wall thickness, and centerline cross-section analysis. This method aims to aid inspectors by providing augmented data including preliminary locations of interest to evaluate, which can ease the inspection process and reduce overall inspection time, creating more efficient production lines for manufacturers.
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If you would like to know more about Simpleware Custom Modeler, please contact us. Our technical specialists will be happy to show you the capabilities of Simpleware software.