Magnetic Flux Leakage (MFL) is currently the standard method of gas pipeline inspection in spite of the fact that the accuracy of MFL is only about 10%. Ultrasonic inspection has much better accuracy and is not sensitive to permeability changes but normally requires a liquid couplant to get sufficient energy into the pipe wall. Reported here are the laboratory results of Gas Technology Institute’s (GTI) effort to investigate newly developed transducers that use gas as the coupling media. The combination of transducers specifically designed for this application and high gain amplifiers produced signals strong enough to measure wall thickness in steel at pressures from 200 to 1000 PSIG. Investigations showed that both the sensitivity of the transducers and the gas-metal coupling are functions of pressure and, therefore, limit the useful pressure range. Tests were run in pulse-echo mode and pitch-catch mode to determine the advantages and limitations of each. The average ultrasonic wall thickness will be used to calibrate the MFL improving the accuracy of its measurements.

Issue Section:
Research Papers
Keywords:
pipelines, ultrasonic materials testing, ultrasonic transducers, thickness measurement, steel, inspection
Topics:
Echoes, Inspection, Pipelines, Pressure, Reflection, Signals, Steel, Transducers, Wall thickness, Pipes, Ultrasonic measurement, Metals
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Copyright © 2005
 by American Society of Mechanical Engineers
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