A Signal-Based Data Fusion Approach in Non-DestructiveTesting of Composite Materials in the Aerospace Industry
Non-Destructive Testing (NDT) plays a crucial role in the aerospace industry by ensuring aircraft structural integrity and safety, while also supporting operational efficiency. Aircraft components are subject to extreme conditions and stresses, making routine inspections vital to prevent failu...
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| Main Authors: | , |
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| Format: | Article |
| Language: | deu |
| Published: |
NDT.net
2025-03-01
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| Series: | e-Journal of Nondestructive Testing |
| Online Access: | https://www.ndt.net/search/docs.php3?id=30850 |
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| Summary: | Non-Destructive Testing (NDT) plays a crucial role in
the aerospace industry by ensuring aircraft structural
integrity and safety, while also supporting operational
efficiency. Aircraft components are subject to extreme
conditions and stresses, making routine inspections vital
to prevent failures. Traditional NDT techniques—such as
ultrasonic testing, radiography, and eddy current
testing—have long been relied upon in aerospace
maintenance, providing valuable insights into material
integrity. However, these methods have limitations.
Ultrasonic testing effectively detects internal flaws but
depends on material acoustic properties and requires
coupling media, limiting its applications. Radiography
offers high-resolution imaging yet involves ionizing
radiation and is constrained by material thickness. Eddy
current testing is efficient for surface flaws but is
limited by the material's conductivity and permeability.
Recent advancements in NDT, including thermography
and shearography, have introduced enhanced capabilities.
Thermography leverages infrared imaging to identify surface
temperature variations indicative of subsurface defects
like delamination and corrosion, allowing for rapid,
non-contact inspection of large areas in real-time.
However, it is sensitive to environmental conditions and
material emissivity. Shearography, an optical technique
that assesses surface deformation under stress, reveals
defects by analyzing interference patterns from laser
light, particularly useful for detecting cracks and voids.
Despite its sensitivity to stress-induced anomalies in
composites, it requires a stable environment due to
susceptibility to vibrations.
This study explores signal-based data fusion,
integrating traditional and advanced NDT techniques to
enhance defect detection and characterization in aerospace
materials. By combining multiple signals, data fusion and
deep learning improve NDT reliability, offering a
comprehensive understanding of material integrity. This
approach enables detection of various defect types, assists
inspectors by reducing noise and false detections, and
enhances precision through combined signals. Our findings
highlight that data fusion markedly improves NDT
effectiveness in complex, multi-layered composite aerospace
materials, raising industry standards in both efficiency
and accuracy.
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| ISSN: | 1435-4934 |