Single-Transducer, Ultrasonic Imaging Method for High-Temperature Structural Materials Eliminates the Effect of Thickness Variation in the Image

NASA Lewis Research Center's Life Prediction Branch, in partnership with Sonix, Inc., and Cleveland State University, recently advanced the development of, refined, and commercialized an advanced nondestructive evaluation (NDE) inspection method entitled the Single Transducer Thickness-Independent Ultrasonic Imaging Method (refs. 1 to 4). Selected by R&D Magazine as one of the 100 most technologically significant new products of 1996, the method uses a single transducer to eliminate the superimposing effects of thickness variation in the ultrasonic images of materials. As a result, any variation seen in the image is due solely to microstructural variation. This nondestructive method precisely and accurately characterizes material gradients (pore fraction, density, or chemical) that affect the uniformity of a material's physical performance (mechanical, thermal, or electrical). Advantages of the method over conventional ultrasonic imaging include (1) elimination of machining costs (for precision thickness control) during the quality control stages of material processing and development and (2) elimination of labor costs and subjectivity involved in further image processing and image interpretation.

At NASA Lewis, the method has been used primarily for accurate inspections of high-temperature structural materials including monolithic ceramics, metal matrix composites, and polymer matrix composites. Data were published this year for platelike samples, and current research is focusing on applying the method to tubular components.

The initial publicity regarding the development of the method generated 150 requests for further information from a wide variety of institutions and individuals including the Federal Bureau of Investigation (FBI), Lockheed Martin Corporation, Rockwell International, Hewlett Packard Company, and Procter & Gamble Company. In addition, NASA has been solicited by the 3M Company and Allison Abrasives to use this method to inspect composite materials that are manufactured by these companies.

References

1. Roth, D.J.: Single Transducer Ultrasonic Imaging Method That Eliminates the Effect of Plate Thickness Variation in the Image. NASA TM-107184, 1996.

2. Roth, D. J., et al.: Commercial Implementation of Ultrasonic Velocity Imaging Methods via Cooperative Agreement Between NASA Lewis Research Center and Sonix, Inc. NASA TM-107138, 1996.

3. Roth, D.J., et al.: Commercial Implementation of NASA-Developed Ultrasonic Imaging Methods via Technology Transfer. Mater. Eval., vol. 54, no. 11, 1996, pp. 1305-1309.

4. Roth, D.J.: Using a Single Transducer Ultrasonic Imaging Method to Eliminate the Effect of Thickness Variation in the Images of Ceramic and Composite Plates. J. Nondestr. Eval., vol. 16, no. 2, June 1997.

Lewis contact: Dr. Don J. Roth, (216) 433-6017, Don.J.Roth@grc.nasa.gov
Author: Dr. Don J. Roth
Headquarters program office: OASTT
Programs/Projects: HITEMP, Propulsion Systems R&T, P&PM,

Special recognition: 1996 R&D 100 Award

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