ULTRA SUPERCRITICAL Pulverized Coal-Fired Steam Generators

Transcription

1 ULTRA SUPERCRITICAL Pulverized Coal-Fired Steam Generators

2 Introduction Q: What is Ultra Supercritical (USC)? A: Not universally defined, but generally can be considered to be >3800 psig and >1100 F final steam conditions Q: Why Consider Ultra Supercritical? A: Dramatic Improvement in Plant Efficiency Economic Pressures Fuel Prices Environmental Pressures Clean Air Act Clear Skies Local BACT Future CO 2 Social/Political Pressures Quest for Permit 2

3 Introduction CYCLE HEAT RATE IMPROVEMENT 3

4 Operating Results Supercritical: Evolution Early Supercritical Units had problems Lengthy start-ups Poor load following flexibility Poor availability Slagging/fouling/corrosion Some of those problems not related to supercritical but other boiler evolution issues Most early design issues have been effectively addressed and availability has improved, though maintenance costs are relatively high Current supercritical designs in Europe and Japan have availability and maintenance commensurate with subcritical units 4

5 Equivalent Forced Outage Factor (EFOF),% Operating Results Availability of Subcritical versus Supercritical Units N. America (Data from NERC ) Plant - Supercr. Plant - Subcr. SG - Supercr. SG - Subcr Years 5

6 Equivalent Forced Outage Factor (EFOF), % Operating Results Availability Data for Supercritical verses Subcritical Units (Europe) VGB Statistics, Subcritical Supercritical 6

7 Design Criteria Size Current commercial range from MW Steam Conditions Fuel Trade off efficiency gains (fuel savings) vs. capital cost Example: Change from 1000/1000 to 1100/1100 results in 3-5% overall increase in plant cost More difficult fuels (often less expensive) require designs higher in capital costs Feedwater Temperature Affected by cycle design Operating Requirements Base load, load following, cycling, on-off peaking Emissions Limits Current and future, including CO 2 7

8 Advanced Designs and Materials Recent Activities Assessing Ultra Supercritical Designs and Materials DOE/NETL - Cost and Performance Baseline for Fossil Energy Plants 2007 EPRI CoalFleet Guideline for Advanced Pulverized Coal Power Plants 2008 EPRI - Engineering and Economic Assessment of Ultra-Supercritical Pulverized Coal Power Plants for Near Term Development Ongoing Thermie (Europe) Japanese Program U.S. - DOE and State of Ohio Shandong Technical Exchange Henan Design Institute Henan Province, PRC 8

9 Advanced Designs and Materials Ultra Supercritical: Current State-of-the-Art Latest Units in Europe 4000 psig, 1105/1110 F China moving up to 3800 psig, 1120/1135 F Most aggressive unit in Japan 3950 psig, 1121/1153 F U.S. Market generally around 3700 psig, 1080/1080 F Most advanced U.S. plant in Engineering Phase at 3800 psig, 1112/1135 F With advanced materials and careful design, Ultra Supercritical units have maintenance and availability similar to more recent standard supercritical units. 9

10 Advanced Designs and Materials 10

11 Advanced Design and Materials Significant Issues with Ultra Supercritical Project Implementation Long term validation of materials ASME/ASTM Re-rating of materials: Grade 91, 92, 122, 23, etc. Creep-Rupture, exfoliation, corrosion resistance Fabrication Welding procedures, heat treatment, bending, etc. Construction Qualified crafts, qualification of procedures, tight Q/A Compatibility of valves, fittings and appurtenances Many shapes, valves, etc. not available in advanced materials Above issues present risks to project costs, schedule, and performance which are significant in comparison to standard subcritical or supercritical cycles. 11

12 Future Generation USC Increase steam conditions to further improve efficiency: For typical US facility, efficiencies up to 48% (HHV) achievable Benefits include: Reduced emissions (including CO 2 ) Lower CO 2 capture costs per MWh Materials for advanced boilers: Current 1150 F (630 C) Ferritic Steels AD700 Program UltraGen II 1295 F (700 C) Austenetic alloys and nickel based superalloys UltraGen III 1400 F (760 C) Nickel based super alloys 12

13 Future Generation USC 100,000 Creep-Rupture Stress for USC Boiler Materials P.J. Maiasz, I.G. Wright, J.P Shingeldecker, T.B. Gibbons, and R.R. Romanosky, Defining the Materials Issues and Research for Ultra-Supercritical Steam Turbines, Proceedings to the Fourth International Conference on Advances in Materials Technology for Fossil Power Plants (Hilton Head, SC, Oct , 2004). ASM-International, Materials Park, OH,

14 Future Generation USC Beyond Advanced Steam Conditions Double Reheat Reduction of Boiler Exit Gas Temperature Low Level Exit Gas Heat Recovery Coal Drying Combustion Air Preheating Feedwater Heater External Desuperheater Multi-Pressure Condenser Maximizing Cooling Tower Performance Optimized Turbine Cycle for Ambient Conditions Variable Speed Drives 14