The multi-modes and disperse characteristics of torsional modes in pipes are investigated theoretically and experimentally. At all frequencies, both phase velocity and group velocity of the lowest torsional mode T(0,...The multi-modes and disperse characteristics of torsional modes in pipes are investigated theoretically and experimentally. At all frequencies, both phase velocity and group velocity of the lowest torsional mode T(0,1) are constant and equal to shear wave velocity. T(0,1) mode at all frequencies is the fastest torsional mode. In the experiments, T(0,1) mode is excited and received in pipes using 9 thickness shear vibration mode piezoelectric ceramic elements. Furthermore, an artificial longitudinal defect of a 4 m long pipe is detected using T(0,1) mode at 50 kHz. Experimental results show that it is feasible for longitudinal defect detection in pipes using T(0,1) mode of ultrasonic guided waves.展开更多
基金This project is supported by National Natural Science Foundation of China(No. 10272007, No.60404017, No.10372009)Municipal Natural Science Foundation of Beijing, Clina(No.4052008).
文摘The multi-modes and disperse characteristics of torsional modes in pipes are investigated theoretically and experimentally. At all frequencies, both phase velocity and group velocity of the lowest torsional mode T(0,1) are constant and equal to shear wave velocity. T(0,1) mode at all frequencies is the fastest torsional mode. In the experiments, T(0,1) mode is excited and received in pipes using 9 thickness shear vibration mode piezoelectric ceramic elements. Furthermore, an artificial longitudinal defect of a 4 m long pipe is detected using T(0,1) mode at 50 kHz. Experimental results show that it is feasible for longitudinal defect detection in pipes using T(0,1) mode of ultrasonic guided waves.
