Craig Woolhouse - The Use of Pulsed DC Holiday Detectors for Field Testing Pipeline Coatings
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Craig Woolhouse - The Use of Pulsed DC Holiday Detectors for Field Testing Pipeline Coatings
- 1. inspection equipment THE USE OF PULSED DC HOLIDAY DETECTORS FOR FIELD TESTING PIPELINE COATINGS Author: John Fletcher FICORR Technical Support Manager Elcometer Limited © Elcometer Limited 2011 60 years of excellence www.elcometer.com
- 2. inspection equipment THE USE OF PULSED DC HOLIDAY DETECTORS FOR FIELD TESTING PIPELINE COATINGS Presented by Craig Woolhouse Regional Sales Manager Elcometer Limited © Elcometer Limited 2011 60 years of excellence www.elcometer.com
- 3. Content Introduction The Problem - Flaws & Defects Standards for Porosity Detection Continuous DC High Voltage Testing Pulsed DC High Voltage Testing Conclusions
- 4. Introduction High Voltage Holiday Detection is used on cured coatings to ensure there are no flaws Two main high voltage equipment types Continuous DC Pulsed DC
- 5. Introduction Continuous AC High Voltage Testers are also available but these are often mains operated, which is inconvenient for site work Surface contamination & moisture cause AC sparks High AC voltage is more hazardous than DC
- 6. The Problem Flaws in cured coatings reduce service life: Pipeline – internal and external coatings Tank linings Immersion Service
- 7. The Problem Some Examples of Coating Flaws Runs & Sags Pinholes Cratering Cissing Incorrect Coating Thickness
- 8. The Problem Runs & Sags Caused by excessive local thickness prior to cure
- 9. The Problem Pinholes Caused by air or blast media inclusion in the coating
- 10. The Problem Cratering Caused by air release from the partially cured coating
- 11. The Problem Cissing Caused by contamination of substrate by oil or grease (also known as crawling or fisheyes)
- 12. The Problem Incorrect Coating Thickness Profile peaks through thin coatings Cracking due to excess coating thickness
- 13. Test Standards NACE SP0188:2006 “Discontinuity (Holiday) Testing of New Protective Coatings on Conductive Substrates” Test Voltage Table
- 14. Test Standards NACE RP0274:2004 V 7,900 T Where: V = test voltage “High Voltage Electrical and T is the thickness in Inspection of Pipeline mm Coatings” Voltage Formula or Table V 1,250 T Where: V = test voltage and T is the thickness in mil
- 15. Test Standards NACE SP0490:2007 V 104 T “Holiday Detection of Fusion- Where: V = test voltage and T is the thickness in Bonded Epoxy External µm Coatings of 250 to 760 µm (10 to 30 mil) ” V 525 T Voltage Formula or Table Where: V = test voltage and T is the thickness in mil
- 16. Test Standards ASTM D5162:2008 V M Tc “Practice for Discontinuity Where: V = test voltage, Tc is the thickness in (Holiday) Testing of mm or mil and M is a Nonconductive Protective constant dependant on the range of the Coating on Metallic thickness Substrates ” Voltage Formula or Table
- 17. Test Standards ASTM D4787:2008 V M Tc “Continuity verification for Where: V = test voltage, Tc is the thickness in liquid or sheet linings applied mm or mil and M is a to concrete substrates ” constant dependant on the range of the thickness Voltage Formula or Table
- 18. Test Standards ISO BS EN ISO29601:2011 “Paints and varnishes – Corrosion protection by protective paint systems – Assessment of porosity in a dry film” Test Voltage Table
- 19. Test Standards Test Voltage Comparisons Standard Test Voltage for 500 µm (20 mil) Coating NACE SP0188 2.5 kV NACE RP0274 6.0 kV NACE SP0490 2.3 kV ASTM D4787 (Formula) 2.3 kV ASTM D4787 (Table) 2.7 kV BS EN ISO 29601 2.9 kV
- 20. Continuous DC Testing Test Set-up Signal return connected to substrate DC Voltage from 0.5 to 30 kV Conductive Electrodes
- 21. Continuous DC Testing Test Electrodes Insulated Handle Rolling Spring Internal Pipe Brush Metal or Conductive Rubber Brush Electrodes Extension rods
- 22. Pulsed DC Testing Test Set-up Capacitive Signal Return Cable
- 23. Pulsed DC Testing Test Set-up 35 kV Test Voltage Range Menu operated standards Voltage calculator
- 24. Pulsed DC Testing Full Set of Electrodes Band brushes Wire brushes up to 1 m wide Internal pipe brushes Conductive Rubber Strip Electrode adaptors Steel rolling springs Phosphor-Bronze Rolling Springs
- 25. Pulsed DC Testing Signal Return Conductive Mat
- 26. THE USE OF PULSED DC HOLIDAY DETECTORS FOR FIELD TESTING PIPELINE COATINGS CONCLUSIONS .
- 27. Conclusions The key to successful high voltage holiday detection is the selection of the correct test voltage: Too low a voltage and flaws will be missed Too high a voltage and the coating will be burnt .
- 28. Conclusions Care must be taken with low dielectric strength coating: Thin sections may not resist the high voltage if the dielectric strength is low Breakdown voltage of air is: 4 kV/mm Some coatings have a dielectric strength of 6 kV/mm .
- 29. Conclusions Continuous DC vs. Pulsed DC Testing Determined by practical issues Pulsed DC when direct connection to substrate is not possible Pulsed DC when coating is damp or dirty .
- 30. Conclusions Continuous DC vs. Pulsed DC Testing Continuous DC recommended when accurate voltage setting required – low dielectric strength coatings .
- 31. Conclusions Care when referencing a standard The different standards produce different test voltages for the same thickness .
- 32. THE USE OF PULSED DC HOLIDAY DETECTORS FOR FIELD TESTING PIPELINE COATINGS THANK YOU FOR YOUR ATTENTION Any Questions? .