Optimization of Nonlinear Lamb Wave Detection System Parameters in CFRP Laminates

Carbon fiber reinforced polymer (CFRP) laminates, as unique multifunctional materials, are widely applied in various aircraft, such as airliners, fighter planes, and space shuttles. To ensure aircraft safety during the production and application of CFRP laminates, it is necessary to improve the accuracy of nonlinear Lamb wave nondestructive testing to assess the damage in CFRP laminates caused by impact, high temperature, friction, corrosion, etc. In this study, the accuracy of nonlinear ultrasonic nondestructive testing was found to highly depend on the cycle number, output level and gain of the nonlinear ultrasonic detection system. Based on a single-factor experiment that considered the cycle number, output level, and gain of the amplifier as independent variables, a regression analysis was carried out on the fundamental wave amplitude value (A(1)) and second harmonic amplitude value (A(2)). Two response surface surrogate models were established to improve the accuracy of nonlinear Lamb wave nondestructive testing and to optimize the detection system parameters. The response surface models were verified via an analysis of variance (ANOVA), significance tests and an error statistical analysis. The results revealed the significant influence of these three factors on A(1) and A(2). Optimization of the response surface was achieved at eight cycles, an output level of 42 and a gain of 32 dB. Moreover, the nonlinear ultrasonic detection system achieved good operational stability, high accuracy and reliability under the above optimal parameter conditions. This approach provides scientific guidance for the accurate assessment of CFRP laminate damage.

Automated summary

The accuracy of nonlinear ultrasonic nondestructive testing highly depends on the cycle number, output level, and gain of the nonlinear ultrasonic detection system. Response surface surrogate models were established to improve the accuracy of damage assessment in CFRP laminates and optimize detection system parameters. The optimized response surface was achieved at eight cycles, an output level of 42, and a gain of 32 dB, providing operational stability, high accuracy, and reliability for the nonlinear ultrasonic detection system.