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|NDT.net Issue - 2019-04 - NEWS ||NDT.net Issue: 2019-04|
Publication: e-Journal of Nondestructive Testing (NDT) ISSN 1435-4934 (NDT.net Journal)
Advanced Ultrasonic Couplant for Long Term Probe PlacementInnovation Polymers6, Kitchener, Ontario, Canada
Applications exist where ultrasonic probes are required to be in place for long periods of time, sometimes in relatively extreme conditions. Typically, ultrasonic corrosion monitoring and ultrasonic flow metering place probes on a surface and take readings on a continuous or periodic basis. Water soluble gels eventually dry and the coupling effect is reduced and then lost.
Innovation Polymers has developed a new ultrasonic couplant that permits long term probe placement without significant coupling losses. The material is a high viscosity liquid polymer with virtually no evaporation at normal working temperatures. The tacky texture makes it an effective pressure sensitive adhesive i.e. it forms a bond when pressure is applied.
In addition to its long-term coupling capabilities, the new couplant is capable of supporting SH shear waves (i.e. it is a nonnewtonian viscous fluid). Because it is not water-soluble, the couplant was selected for application in the North Sea at 300m below the surface. The North Sea application included successful performance demonstration at temperatures from 5°C to 50°C.
To demonstrate the long-term stability of the couplant a test was configured that coupled a 5MHz compression mode probe and a 5MHz SH shear wave probe to a 9mm thick plate of aluminium.
For the compression mode probe the A-scan was gated to display two thickness multiples, whereas for the SH shear wave probe only a single backwall was gated. Over a four-week period, the only significant shift was seen to occur after Day 1 where the thickness of the couplant had gradually reduced to a steady state. Subsequent measurements indicated less than 1dB variation from the average peak value for both compression and shear modes.
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