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Designing an Internal Corrosion Program

Designing an Internal Corrosion Program. NACE Eastern Area Conference Roy D. Fultineer Jr. Introduction. Plans and Procedures Training Know the system When do we get involved Understand Corrosion Mechanisms Identify the right monitoring locations Monitor and Trend data

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Designing an Internal Corrosion Program

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  1. Designing an Internal Corrosion Program NACE Eastern Area Conference Roy D. Fultineer Jr.

  2. Introduction • Plans and Procedures • Training • Know the system • When do we get involved • Understand Corrosion Mechanisms • Identify the right monitoring locations • Monitor and Trend data • Possible Mitigation • Follow-up

  3. Plans and Procedures • Internal Corrosion Plans • Generic • Potential Treats – Acid Gases, Bacteria, Erosion, etc. • Types of monitoring • Gas samples • Liquid samples • Coupons • Requirements for internal corrosion monitoring • Parameters to monitor and trend

  4. Plans and Procedures • Internal Corrosion Plans • Generic • Basic Decision Criteria • If indications are found, what is the next step.

  5. Plans and Procedures • Internal Corrosion Plans • Specific • Location of facility • Specific location of monitoring locations • Specific timing of monitoring • Specific water control methods • Pigging • Drips • Dehydration • Schedule of these control methods • What action has been taken?

  6. Plans and Procedures • Internal Corrosion Plans • Specific • What action is planned? • How will action be evaluated?

  7. Plans and Procedures • Procedures • Procedures go into specific action of how to conduct sampling and monitoring • Important aspect of internal corrosion plan • Procedures go hand-in–hand with training

  8. Training • Properly trained personnel is critical to the success of any internal corrosion program • In house training • On the job training • NACE and other professional organizations • Collecting accurate data is critical • The better the data, the better the decisions

  9. When do we get involved • Internal corrosion should be considered in the initial design phase of any project • Things to consider: • Water content and water removal • Elevation profile • Inlets and outlets to the system • Gas Quality • Flow regimes

  10. Know your system • Operation Factors • Direction of flow • Flow rates • Flow regime • Pressures • Product • Upsets • Elevation Profile

  11. Elevation Profile

  12. Understand Corrosion Mechanisms • Causes • Water • CO2 Influenced • H2S Influenced • MIC • O2 • Velocity/Flow Related

  13. Understand Corrosion Mechanisms • Water • Necessary for internal corrosion • Temperature • Reaction rates double for every 10 degree Celsius rise • pH • Less then 5 can result in increased corrosion • Carbonates • Acts as a acid buffer

  14. Understand Corrosion Mechanisms • CO2 Corrosion • Carbon Dioxide + water = Carbonic Acid • Carbonic Acid + iron = iron carbonate + hydrogen • Carbon dioxide is in the gas • Carbonic acid creates corrosion • Generally mild corrosion except when with other corrodents

  15. Understand Corrosion Mechanisms • H2S Corrosion • Hydrogen Sulfide + iron + water = • Iron Sulfide + water + hydrogen • From sour gas operations or from SRB’s (MIC) • Corrosion pitting occurs where FeS forms on the metal surface and creates a local corrosion cell

  16. Understand Corrosion Mechanisms • MIC • Acid Producers - APB’s • Sulfate Reducing Bacteria - SRB’s • Controlled with a clean system and bacteriacides/biocides

  17. Understand Corrosion Mechanisms • Oxygen • Oxygen + iron + water = Iron oxide + water • Oxygen creates an oxidizing effect and with other corrodents = accelerated corrosion • Oxygen concentration cells create corrosion due to oxygen depletion areas

  18. Understand Corrosion Mechanisms • Velocity/Flow related attacks • High surface fluid or particle velocities • Erosion • High Energy with or without particles • Removes metal • Leaves smooth surface • Erosion Corrosion • Erosion removes protective film or scale • Exposes metal surface to environment

  19. Pick the right monitoring locations • Representative of system • Right location • Know what your looking for and put monitoring devices in right location. • Top of the line versus bottom of line corrosion • Right device • Pick the monitoring device that is designed for the application

  20. Monitor and trend data • Collect the data you need and compare it to all other data • Be careful not to add to much weight to any one data set • Determine if action is required

  21. Possible Mitigation Methods • Do nothing • Sometimes the best answer is to continue to monitor and study • More information will lead to better decisions • More technical or sophisticated analysis may be appropriate • Chemicals can actually make the situation worse

  22. Possible Mitigation Methods • Liquid removal • Drip Blowing • Drip should be monitored and blown on frequencies that ensure no free liquids • Used to monitor for corrosion parameters • Pigging • Ran on frequencies that ensure no free liquids • Thought should be given to the type of pigs used • Speed of pigging can influence

  23. Possible Mitigation Methods • Dehydration • Removal of water through dehydration can greatly reduces possibility of internal corrosion • High initial cost and added O&M cost • Does not necessarily remove the need for chemical

  24. Possible Mitigation Methods • Control Inlet Product Quality • Monitor product quality entering system • Have control to shut in suppliers

  25. Possible Mitigation Methods • Chemical Treating • Batch • Slug • Continuous • Squeeze

  26. Possible Mitigation Methods • Design • One of the most effective means of control • Use of proper materials • Size pipeline properly (oversized = liquid hold-up) • Modeling and/or flow regime will dictate location and/or need for drips, pigging, etc. • Material selection can be key • Steel is not always the best solution • Example: Fiberglass piping in acid gas environment

  27. Follow-up (Did it Work?) • Coupons • Liquid Sampling • Residuals Monitoring • In Line Inspection (ILI) • Gas Monitoring

  28. Coupons • Weight Loss • Compare previous rates to new rates • Compare pretreated versus post-treatment • CID – Copper Ion Displacement – monitoring chemical distribution

  29. Liquid Sampling • Monitor effects on water chemistry • pH (increasing or decreasing) • Increase – Scaling • Decrease – Corrosion • Metals (increasing decreasing) • Mn/Fe ratio • Trending • Bacteria levels

  30. Residual Monitoring • Are chemicals getting where you need them • Are the residuals adequate • If not, • Adjust existing facilities • Add new injection points • Change application (continuous to pigging)

  31. ILI Inspection • Need base line • Follow-ups • Monitor corrosion growth • Monitor for new corrosion.

  32. Gas Monitoring • Monitor Quality • CO2 • H2S • Water • O2 • Monitor for changes

  33. Questions?

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