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The U.S. Advanced Ultra-Supercritical (A-USC) Consortium was formed in 2001 as a government/industry program, sponsored by the U.S. Department of Energy (DOE) and the Ohio Coal Development Office (OCDO) and cost shared by industrial and not-for-profit partners. The purpose of the consortium was to advance the state of the art for power generation by evaluating and developing materials that allow the use of advanced steam cycles in coal-based power plants. These advanced cycles, with steam temperatures up to 1400�F (760�C), can increase the efficiency of coal-fired boilers from an average of 35% (current U.S. fleet) to more than 45% higher heating value (HHV) (>
49% lower heating value [LHV]). The increase in a plant?s efficiency is limited unless new materials able to withstand these higher operating temperatures and pressures are identified and approved for use.<
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The A-USC Consortium identified these needed materials during earlier phases of the program. It developed the welding and joining techniques along with manufacturing processes for casting and wrought products made from these new high-nickel alloys. It subjected these materials to extensive laboratory and steam loop testing. It then obtained ASME code approval for their use in U.S. boiler systems. The program?s successes leave this last remaining activity (ComTest Phase 2) that the U.S. utility industry has recommended to be accomplished prior to commercialization. The focus of the activity is the evaluation and demonstration of commercial readiness for ?full scale? components to be made from these nickel-based alloy materials and provided by a U.S. domestic supply chain that is new to working with these alloys.<
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According to studies completed by the Electric Power Research Institute (EPRI), the cost of an A-USC plant is approximately 20% higher than a non-A-USC plant because of its use of nickel-based alloys needed for the high temperature operating conditions. However, CO<
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reductions of approximately 30% from the current fleet average provide a strong incentive for its consideration. The actual costs and perceived value for CO<
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abatement will determine whether new or retrofitted plants are undertaken, although decisions to build A-USC plants in India would indicate its economic feasibility while also being part of a global carbon emissions strategy.<
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The work by the A-USC Consortium, prior to the start of the ComTest project, has included lab scale and pilot scale materials testing, both in air and oxy-combustion. This testing has included air-cooled and steam-cooled ?loops? that were installed into existing operating utility boilers to gain exposure of these materials to realistic conditions of high temperature and corrosion caused by the constituents in the coal ash. The A-USC Consortium also gained ASME Code approval of the Inconel 740 material, has cast and extruded the largest high nickel precipitation hardened alloys, and developed unique welding techniques to avoid problems identified by the competing European program. However, as valuable as these material test loops and accomplishments have been for obtaining information, their scale is below that required to minimize the risk associated for a U.S. utility to build a multibillion-dollar A-USC power plant.<
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To reduce the final identified risk barrier to full-scale commercialization of these advanced materials and systems, the A-USC Consortium (guided by a utility industry advisory committee) has identified the key areas of the technology they desire to see as being capable of full-scale manufacturing and/or fabrication from an identified, capable U.S. domestic supplier base.<
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A significant amount of work was accomplished during Phase 1 to identity the components, as well as the component size, that would be manufactured from advanced alloys such as Inconel 740H or Haynes 282 alloys. Pathways to supply these components for ComTest have been identified, as well as any further development that would be required. The Phase 2 effort used Phase 1 findings for designing these key full-scale components for A-USC boilers and turbines to include large castings
extrusions, forgings, fabrication of water walls and steam loops with headers from advanced materials, raw material (such as pipe extrusion billets) are at the commercial readiness level to permit advancement to a demonstration project. The Phase 2 work scope was addressed by a diverse team, including government, industry, and not-for-profit partners.<
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The work scope under Phase 2 addressed fabrication of components identified as being outside of the proven capabilities of the existing supply chain, including the following: <
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Steam turbine rotor forging and Haynes 282 nozzle carrier casting <
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Superheater and reheater header and tube assemblies <
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Large-diameter pipe extrusions and forgings <
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Test valve articles to support ASME Code approval<
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In addition, key fabrication steps were completed, including boiler weld overlays and simulated field repairs. Throughout, extensive inspection and quality assurance testing of the components were performed. The team worked to advance ASME Code approval for key components and processes.<
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Although much of the focus of ComTest Phase 2 was the high-temperature nickel-based alloy materials, a broader range of materials were incorporated, which would be representative of the materials used in full-scale A-USC power plant applications and have cross-cutting applicability on other high-temperature power generation options, such as advanced nuclear, supercritical CO<
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cycles, and central solar receivers. This report that has been submitted is organized in the following manner:<
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Section 1 contains an Executive Summary. <
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Section 2 discusses the ComTest project background and organization. <
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Section 3 discusses project management and reporting. <
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Section 4 discusses the procurement of nickel-based alloy and other A-USC materials and components. <
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Section 5 discusses the fabrication of procurement of nickel-based alloy and other A-USC materials and components. <
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Section 6 discusses the fabrication of cast nickel-based A-USC steam turbine components. <
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Section 7 discusses the fabrication of forged nickel-based A-USC steam turbine piping and steam pipe components. <
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Section 8 discusses the qualification of pressure relieve valves (PRVs) for A-USC power plants. <
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Section 9 discusses proposed plans for future evaluation of A-USC components. <
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Section 10 contains the summary and conclusion.<
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