1. Todd Kedzie�El Paso Corporation �Manager of Laboratory Services Bell Hole Inspection Techniques for Assessing SCC Severity�December 2, 2003
2. Introduction Magnetic Particle Inspection (MPI) Techniques
SCC Depth Measurement by Grinding
SCC Depth Measurement Technology Research
3. Magnetic Particle Inspection (MPI) MPI is an NDE method of inspection that uses fine magnetic particles (iron) that are applied to the part, and are attracted to any magnetic-leakage field created by an imperfection, such as SCC
Magnetic yokes are commonly used for bell hole MPI of pipelines
Each MPI method discussed is capable of detecting SCC, depending on field and pipeline operating conditions
No single MPI method is effective in all situations, therefore several methods must be available to choose from
MPI can be performed at all clock positions
4. Dry MPI Description: Dry MPI uses fine iron particles that are not suspended in a liquid. The iron particles are blown onto the pipe surface using a bulb or powder blower applicator. Iron particles are available in a variety of colors to obtain contrast with the pipe surface
5. Dry MPI Limitations
Dry MPI method is not suitable for use when the pipe surface is wet (sweating, rain, etc.)
Least sensitive method of MPI
6. Wet Fluorescent MPI Description: Wet Fluorescent MPI uses fine iron particles that are suspended in a liquid (water or hydrocarbon). The iron particle suspension liquid is sprayed onto the pipe surface. The iron particles fluoresce in the dark when illuminated with a black light
7. Wet Fluorescent MPI Limitations
Hydrocarbon suspension can result in a cloudy fluorescent background that can reduce the contrast between the indications and the background when inspecting coal tar coated pipelines
Requires dark background often provided by a tarp or tent for black light use
8. Wet Visible MPI Description: Wet visible MPI uses fine iron particles that are suspended in a liquid (water or hydrocarbon). The iron particle suspension liquid is sprayed onto the pipe surface. The iron particles are visible, and do not require black light illumination
Limitations
Limited variety of colors for contrast
9. Black and White Contrast MPI Description: Contrast MPI uses fine iron particles that are suspended in a liquid (hydrocarbon) that is sprayed onto the pipe surface. The surface of the pipe is painted prior to application of MPI in order to provide contrast with the visible iron particles
Limitations
Greater surface cleanliness required for white paint application
Contrast paint may increase the clean up time
10. Grinding Method to Determine�SCC Depth Description: The population of SCC indications are assessed, and grinding is performed on selected indications. MPI is performed, and the depth of the SCC is measured when the indication has been removed
Limitations
Depth is only determined�for those indications chosen�for examination
Grinding on loaded lines must�be performed cautiously�(see PRCI Pipeline Repair�Manual for additional�information)
11. SCC Depth Measurement Research Description: Technologies from 16 companies were evaluated for SCC depth measurement
Technical Challenge: Accurately measuring the deepest crack within a colony using NDE from the same side as the cracking
3 general types of technologies were studied
Ultrasonic based methods
Electromagnetic methods
Electromagnetic acoustic transducer methods
12. SCC Depth Measurement Research Techniques were evaluated with the following criteria:
Accurate depth measurement for near-critical flaws
Accurate depth measurement for sub-critical flaws
Accurate discrimination of inconsequential cracks from cracks that may grow to failure though fatigue mechanism
13. SCC Depth Measurement Research Results of research:
None of the techniques completely met the goal of a simple, low cost, operator independent sizing technique
Ultrasonic techniques were found to have the greatest potential for sizing SCC
Most successful techniques were:
Ultrasonic Time of Flight Diffraction (TOFD)
Ultrasonic Phased Array. Note: This method provided a 3-dimensional examination of the cracks
Electromagnetic methods were found to consistently under estimate the crack depths. Improved technology, calibration methods, and cleaning procedures will be required for this method to become useful
14. Current SCC Depth Measurement Research Research program:
Application of phased array UT characterization in the field
15. Concluding Remarks Current bell hole inspection techniques utilize MPI and grinding to determine SCC depth, length, orientation, and clock position
More advanced inspection methods have been evaluated, but none of these methods have proven to be capable of accurately measuring SCC depth
Most promising technologies (phased array UT characterization) are currently being evaluated
16. Todd Kedzie�El Paso Corporation �Manager of Laboratory Services Bell Hole Inspection Techniques for Assessing SCC Severity�December 2, 2003
