Fire-Side Corrosion Rates of Heat Transfer Surface Materials for Air- and Oxy-coal Combustion

Size: px

Start display at page:

Download "Fire-Side Corrosion Rates of Heat Transfer Surface Materials for Air- and Oxy-coal Combustion"

Easter Whitehead
5 years ago
Views:

1 Fire-Side Corrosion Rates of Heat Transfer Surface Materials for Air- and Oxy-coal Combustion Andrew Fry, Bradley Adams, Kevin Davis, Dave Swensen, Shawn Munson Reaction Engineering International William Cox Corrosion Management Ltd. U.S. Department of Energy, Agreement # DE-NT IEAGHG SO2/SO3/Hg Workshop

2 Presentation Roadmap Program Overview (Pilot-Scale Testing of Oxy-Coal Combustion) Fire-Side Corrosion Corrosion Probe Configuration Summary of Corrosion Rates Air vs. Oxy Temperature Effects Effects of Stoichiometric Ratio Summary and Conclusions Acknowledgements Questions

Program Overview Objective: Characterize performance

coal-fired boilers Utilize multi-scale testing and

data that describe flame characteristics, waterwall

oxy-firing Validated mechanisms that describe impacts

oxy-burner design, flue-gas recycle) Incorporate

3 Program Overview Objective: Characterize performance and impacts of oxycombustion retrofit on existing coal-fired boilers Utilize multi-scale testing and theoretical investigations to develop: Fundamental data that describe flame characteristics, waterwall corrosion, and ash properties (slagging, fouling) in oxy-firing Validated mechanisms that describe impacts of oxy-combustion Firing system principles (effects of oxy-burner design, flue-gas recycle) Incorporate validated mechanisms into CFD models and evaluate full-scale oxy-retrofit designs

4 1.5 MWPilot-Scale Furnace Experiments Experiments Burner Parametrics Fuel, Oxygen and Fuel/Oxygen/FGR FGR Mixing in Burner Mixing in Burner Corrosion, Fire-Side Corrosion Radiation (Radiation, and Soot Particle Formation and Particle Deposition Deposition) Measurements Flame Stabilization Location Flue Gas Composition and Concentrations Unburned Carbon in Ash Temperature Profile Real-Time Corrosion Rate Electrochemical Noise (ECN) Technology Soot Volume Fraction Two-Color Heat Pyrometry Flux Heat Flux/Radiation Deposition Rate Intensity Deposition Sampling

Conditions - Realistic Time Temperature History Radiative Section

5 1.5 MW Pilot-Scale Furnace (L1500) Unique L1500 Capabilities: - Realistic Burner Turbulent Mixing Scale - Realistic Radiative Conditions - Realistic Time Temperature History Radiative Section Air/FGR/O 2 Control Convective Section Baghouse Burner Sample Ports FD and Recycle Fan

6 Coal Analysis Skyline PRB Illinois Skyline PRB Illinois Coal Analyses Mineral Matter Analyses C Al H Ca N Fe S Mg O Mn Ash P Moisture K Volatile Matter Si Fixed Carbon Na HHV, Btu/lb 12,606 9,078 11,598 S * all values in mass % unless otherwise specified Ti Skyline is a western bituminous coal and was used for all burner parametric testing - All three coals were used for corrosion testing

7 Corrosion Testing (Feb April 2010) Electrochemical Noise (EN) Real Time Measurements EN sensing is performed by monitoring the spontaneous fluctuations in the electrical potential and current signals as generated during electrochemical corrosion activity Corrosion materials were chosen that are typical in existing US Utility Boilers OFA Super Heat Probes 1255 K Gas Temperature Corrosion element 761 K Corrosion Element Probe Face Water Wall Probe One Probe, One Material SA-210 Water Wall Probe 1533 K Gas Temperature Corrosion element 655 K Corrosion Element Super Heat Probe Three Probes, Three Materials T22, T91 and 347h

8 Corrosion Element Material Analysis Material SA 210 T22 P91 347H HT Surface Waterwall Superheat Superheat Superheat C Si Mn Ni Cr Mo S P Cu Al Nb/Cb V N Ta * All values in mass %

9 Corrosion Probes Superheat Probes Water Wall Probe P91 347h T22

Normal Operating Conditions Superheat corrosion probe (347h) Probe Element Temperatures SA210 (655 728 K) T22 (761 839 K) P91 (761-866 K) 347h (761 978 K) Gas Temperatures Water wall probe ~ 1533 K

10 Normal Operating Conditions Superheat corrosion probe (347h) Probe Element Temperatures SA210 ( K) T22 ( K) P91 ( K) 347h ( K) Gas Temperatures Water wall probe ~ 1533 K Superheat probes ~ 1255 K SO2 Concentrations Utah, Air ~ 500 ppmv Utah, Oxy ~ 1,800 ppmv PRB, Air ~ 100 ppmv PRB, Oxy ~ 300 ppmv Illinois, Air ~ 3,000 ppmv Illinois, Oxy ~ 18,000 ppmv Oxidizing / Reducing Conditions Water wall probe Mostly reducing conditions (BSR = 0.9) Superheat probes Oxidizing conditions

11 Results

12 Corrosion Rate (mm/yr) Average Corrosion Rates Baseline sensor element temperatures, probe locations and staging conditions Skyline Air Skyline Oxy PRB Air PRB Oxy Illinois Air Illinois Oxy Corrosion Rate (mm/yr) Skyline Air Skyline Oxy PRB Air PRB Oxy Illinois Air Illinois Oxy 0 SA210 T22 P91 347h Material 0 SA210 T22 P91 347h Material High corrosion rates for high SO 2 conditions (3,000 18,000 ppmv) High corrosion rates for low- alloy T22 and Utah, Skyline coal All other corrosion rates very low

13 Increase in Corrosion Rate Air Oxy Baseline sensor element temperatures, probe locations and staging conditions 6000% 700% Corrosion Rate Increase, Air Oxy 5000% 4000% 3000% 2000% 1000% 0% -1000% Skyline PRB Illinois SA210 T22 P91 347h Corrosion Rate Increase, Air Oxy 600% 500% 400% 300% 200% 100% 0% -100% Skyline PRB Illinois SA210 T22 P91 347h Wow, Why? Waterwall Probe Corrosion Air Oxy Combustion Superheat Probes Generally Corrosion Air Oxy Combustion

14 Corrosion Signal Response to Air- and Oxy-Combustion P91 Superheater Probe Corrosion Rate (mm/yr) Natural Gas Firing Inserted Probe Started Coal (Air-Firing) Corrosion Signal Smoothed Corrosion Signal Corrosion Rate (mm/yr) Coal Air-Firing Inserted Probe Started Oxy- Firing Corrosion Signal Smoothed Corrosion Signal 0 8:00 9:00 10:00 11:00 12:00 13:00 14:00 15:00 16:00 0 8:00 9:00 10:00 11:00 12:00 13:00 14:00 15:00 16:00 Similar Air Response Across Multiple Days Increased Corrosion Rate for Oxy-Combustion

15 Temperature Effects on Corrosion Temperature ( K) Corrosion Rate (mm/yr) 0 8:00:00 9:12:00 10:24:00 11:36:00 12:48:00 14:00:00 15:12:00 T22 Temp P91 Temp 347H Temp T22 Corrosion P91 Corrosion 347H Corrosion Operation of 347H at subcritical temperatures in the presence of high SO 2 concentrations will produce extremely high corrosion rates. 0.0 Decomposition and volatilization of the trisulphate species (Viswanathan and Bakker, 2000)

16 Temperature Effects on Corrosion Illinois/Air T P Illinois/Oxy T P h Illinois/Oxy T P h Illinois/Oxy T P h Illinois/Oxy T P h Temperature (K) Started Oxy-Firing Corrosion Rate (mm/yr) 0 8:00:00 9:12:00 10:24:00 11:36:00 12:48:00 14:00:00 15:12:00 T22 Temp P91 Temp 347H Temp T22 Corrosion P91 Corrosion 347H Corrosion 0 Temperature dependence of corrosion with reproducibility

17 Effect of Stoichiometric Ratio on Corrosion Variable oxidizing and reducing conditions Always oxidizing conditions OFA Super Heat Probes ~ 1394 K Gas Temperature Corrosion element 761 K

18 Effect of Stoichiometric Ratio on Corrosion Burner Outer Secondary Air (kg/s) BSR = 1.16 BSR = 1.16 BSR = 0.9 Started Oxy-Firing BSR = 1.09 BSR = 0.9 BSR = Corrosion Rate (mm/yr) :36 10:36 11:36 12:36 13:36 14:36 15:36 16:36 0 Secondary Air T22 Corrosion P91 Corrosion 347H Corrosion (AIR) T22 corrosion rate spikes when going from reducing to oxidizing T22 corrosion rate spikes when going from oxidizing to reducing (Oxy)

19 Summary and Conclusions Fire-Side Corrosion Waterwall (SA210) corrosion rates decreased when converting from air to oxy-firing for all coals Superheater (T22, P91 and 347H) corrosion rates generally increased when converting from air- to oxy-firing Corrosion rates for the lower alloyed materials (SA210 and T22) were shown to increase drastically during transients between reducing and oxidizing conditions likely to contribute greatly to practical in-plant corrosion rates in the nearburner and near-ofa port regions These effects cannot be resolved using coupon tests The presence of trisulphates strongly increases the corrosion rate of the 347H material under high sulfur and low temperature conditions The dependence of corrosion rate on material temperatures was demonstrated along with the repeatable nature of the results

20 Acknowledgements Thanks to Ryan Okerlund at the University of Utah for preparing and operating the pilotscale furnace Thanks to Danny Oryshchyn, Steve Gerdemann and Casey Carney from NETL ORD for the radiation intensity measurements Thanks to Tim Fout, our DOE program manager for his patients This material is based upon work supported by the Department of Energy under Award Number DE-NT This report was prepared as an account of work sponsored by an agency of the United States Government. Neither the United States Government nor any agency thereof, nor any of their employees, makes any warranty, express or implied, or assumes any legal liability or responsibility for the accuracy, completeness, or usefulness of any information, apparatus, product, or process disclosed, or represents that its use would not infringe privately owned rights. Reference herein to any specific commercial product, process, or service by trade name, trademark, manufacturer, or otherwise does not necessarily constitute or imply its endorsement, recommendation, or favoring by the United States Government or any agency thereof. The views and opinions of authors expressed herein do not necessarily state or reflect those of the United States Government or any agency thereof.

21 Questions? 21