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|NDT.net Issue - 2019-02 - NEWS ||NDT.net Issue: 2019-02|
Publication: e-Journal of Nondestructive Testing (NDT) ISSN 1435-4934 (NDT.net Journal)
Patent granted for STARS tank bottom mapping capabilitySilverwing UK Ltd11, Swansea, United Kingdom
NDT Equipment manufacturer Eddyfi Technologies have recently been granted a patent (number EP2506003A1) for their proprietary technology to map near surface discontinuities on ferrous materials through thick coatings in excess of 10 mm. Because magnetic flux leakage (MFL) signals alone are unable to reliably discriminate between near-side and far-side material loss, the complementary surface topology air-gap reluctance sensor (STARS) approach was designed to perform discrimination automatically.
STARS technology is included in their flagship MFL tank floor scanner, the Floormap3Di-R, which uses an array of sensors to give a clear presentation of product side features with a near photographic quality image of the plate surface. With STARS, the Floormap3Di-R can automatically make product-side or soil-side calls on MFL data and display these calls as separate side as near-side and far-side maps.
STARS works on the principle of air-gap reluctance located under the magnetic poles of the tank floor scanner. Any deviation in the air-gap, by a near-side defect for example, causes a change in the reluctance of the magnetic path and thus a change in flux density amplitude. The shape of the defect can also influence the direction of the magnetic field to give phase information. In the region of a defect, the magnetic field will take the path of least reluctance. Then, during a scan, as a defect passes under the pole, the field lines will direct towards the sides of the defect profile. So the flux density not only changes in strength, but also in direction. The field direction is a key component to the high-resolution images that can be created with the STARS approach because it creates a bipolar signal which identifies the rising or falling edge of a defects profile. As shown in Figure 1, a near-surface map of the plate is obtained with a detailed representation of corrosion features that can help inspectors identify the shape of corrosion and their distribution across large areas.
Figure 1: Product-side material loss indications from STARS
STARS not only responds to loss of ferrous material, but also responds to additional ferrous material such as remnant welds. The ‘Horses’ image in Figure 2 is an interesting example to help illustrate all of the above. Most tanks bottoms don’t have lettering welded onto them. However, it is a real-world example of welding being practiced on a tank floor which was then detected by STARS underneath a non-ferrous thick film coating.
Figure 2: Weld lettering presented by STARS through a thick coating
The phase change from additional material applied to the floor of this storage tank is identified as the colour transitions from white to black, whereas the signal phase of material loss tends to be from black to white. Some minor product side pitting can also be seen surrounding the weld demonstrating this discriminatory phase change. This is an excellent classification tool when reviewing MFL data in recognizing MFL ‘false calls’ due to passing the scanner over remnant welds.
Stuart Kenny, General Manager of Eddyfi Technologies based in Swansea says “STARS technology is another great example of how Eddyfi Technologies, through the Silverwing Brand is pushing the boundaries with sensor development and analysis software. Although specifically designed to help MFL operators differentiate between near-side and under-side corrosion, we believe there are vast applications that would benefit from high resolution imaginary through standard coatings and other protective layering.”
Acknowledgments to Matthew Kircough and Ralf Lieb for their contributions.
Visit: Silverwing UK Ltd