Abstract
Quantification of damage sizes in cylindrical structures such as pipes and rods is of paramount importance in various industries. This work proposes an efficient damage quantification method by using a dry-point-contact (DPC) transducer based on the non-dispersive torsional waves in the low-frequency range. Theoretical analyses are first carried out to investigate the torsional wave interaction with different sizes of defects in cylindrical structures. A damage quantification algorithm is designed based on the wave reflections from the defect and end. Capitalizing on multiple excitations at different frequencies, the proposed algorithm constructs a damage image that identifies the geometric parameters of the defects. Numerical simulations are conducted to validate the characteristics of the theoretically-predicted wave-damage interaction analyses as well as the feasibility of the designed damage quantification method. Using the DPC transducer, experiments are efficiently carried out with a simple physical system. The captured responses are first assessed to confirm the capability of the DPC transducer for generating and sensing torsional waves. The sizes of the defects in two representative steel rods are then quantified with the proposed method. Both numerical and experimental results demonstrate the efficacy of the proposed damage quantification method. The understandings of the wave-damage interaction and the concept of the damage quantification algorithm lay out the foundation for engineering applications.
Highlights
IntroductionCylindrical structures are widely used in various industries such as pipes in the petrochemical industry and solid rods in the electrical grounding system
We propose a damage quantification method using a non-dispersive torsional wave in the low-frequency range for cylindrical structures under the roof of the pulse-echo scheme
Work, damage method for cylindrical cylindrical structures such as rods rods and pipes proposed based quantification on the theoretical prediction of the torsional wave interaction and pipes is proposed based on the theoretical prediction of the torsional wave interaction and pipes is proposed based on the theoretical prediction of the torsional wave interaction with defects
Summary
Cylindrical structures are widely used in various industries such as pipes in the petrochemical industry and solid rods in the electrical grounding system. Regular inspection of these structures is necessary to mitigate the risk of structural failure or even catastrophic consequences [1,2,3]. Among various non-destructive testing approaches, the one based on ultrasonic guided waves has the capability for fast screening the structures and exhibits high sensitivity to small defects, showing great promise for engineering applications [4,5,6,7,8,9]
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