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Inspection of carbon and glass fiber-reinforced polymer composites

By Daniel Richard, Zetec UT Technology Manager

There is a multitude of nondestructive testing methods for conductive materials like aluminum and steel but far fewer options for carbon and glass fiber-reinforced polymer (CFRP and GFRP) composites.

Given the multi-layered, anisotropic nature of these materials, flaws like cracks, porosities and foreign bodies can occur on the surface or within a particular layer of fiber or resin with no predictable orientation. Delamination defects can propagate quickly, especially in components where a laminate is loaded through the thickness. There may be little or no warning between the points of fatigue and catastrophic failure, which is of critical importance in aerospace, automotive and other industries that value the strength-to-weight ratio of composites.

As NDT technology evolves, ultrasound has proven to be an effective way to determine the depth and size of flaws in composite materials.

Ultrasonic testing uses pulses of high-frequency sound energy emitted into the material by a transducer or probe. The probe transmits ultrasonic waves at precise intervals and a set angle, and when a wave encounters a defect, some of that energy is reflected back like an echo. The time it takes for that energy to reach the probe is calculated, analyzed and presented as an image on a screen for the technician to review.

Conventional ultrasound, using single-element transducers, is limited by high attenuation and low signal-to-noise ratio (SNR). Phased array UT uses multiple independent elements (typically from 16 to 64) in a single probe to generate high-quality guided signals that can travel longer distances and cover cover more area, making faster and more thorough inspections possible.

Instrumentation

Phased array ultrasonic testing encompasses a system of hardware and software that works together to acquire and process inspection data into meaningful results.

At the center of this system is a powerful, compact, portable phased array UT instrument that can perform sophisticated testing in the field or at the factory.

These instruments have features like 64-channel code-compliant PAUT and the ability to capture and store all time-domain signals (A-scans) from every transmitter-receiver pair of elements in the array, a technique called Full Matrix Capture or FMC. FMC allows this “full matrix” of raw A-scan signals to be processed in real time, or saved for offline processing using different sets of reconstruction parameters for any given focal law or beam (aperture, angle, or focus depth).

Having access to the raw signal information opens the door to advanced algorithms like the Total Focusing Method (TFM), which uses FMC data to produce high-resolution two and three-dimensional images for defect characterization and sizing; Time of Flight Diffraction (TOFD) capabilities; and plane wave imaging (PWI) data acquisition.

Software

As computing power evolves, so does inspection software. Software can manage the entire inspection process including probe design (acoustic beam simulation), inspection technique development and validation, high-speed data acquisition, advanced data analysis and comprehensive reporting.

Software can also provide more flexibility in the inspection process. For instance, on a component with curves or variable thicknesses, maintaining the proper probe orientation typically involves sophisticated and therefore expensive mechanical systems and an exact knowledge of the specimen geometry. Software can enable adaptive UT inspection techniques like Time Reversal, which can compensate for the effects of misalignment between the probe and the specimen in real-time.

Software development kits (SDK) allow users to integrate their own development to create custom solutions such as specific UI, processing and analysis tools, custom processed data, remote interaction with an inspection management system and real-time streaming of data to another software platform.

Composites are a challenging application for NDT. As their use expands, the demand for more capable inspection systems continues to build. For NDT service providers faced with complicated tasks like testing composite materials, that means using instruments and software that excel as a combination in terms of performance, speed and cost-effectiveness.

Zetec is a global leader in nondestructive testing (NDT) solutions for the critical inspection needs of industries the world counts on every day. To learn more, contact Zetec today!