科技报告详细信息
Optimized Gen-II FeCrAl cladding production in large quantity for campaign testing
Yamamoto, Yukinori1  Sun, Zhiqian1  Pint, Bruce A.1  Terrani, Kurt A.1 
[1] Oak Ridge National Lab. (ORNL), Oak Ridge, TN (United States)
关键词: IRON BASE ALLOYS;    CHROMIUM ALLOYS;    ALUMINIUM ALLOYS;    MOLYBDENUM ALLOYS;    NIOBIUM ADDITIONS;    ACCIDENT-TOLERANT NUCLEAR FUELS;    DRAWING;    DUCTILITY;    TUBES;    ANNEALING;    FUEL CANS;    ROLLING;    MICROSTRUCTURE;    MANUFACTURERS;    STRAIN HARDENING;    CO;   
DOI  :  10.2172/1257911
RP-ID  :  ORNL/TM--2016/227
PID  :  OSTI ID: 1257911
Others  :  Other: AF5810000
Others  :  NEAF278
Others  :  TRN: US1601501
学科分类:材料科学(综合)
美国|英语
来源: SciTech Connect
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【 摘 要 】

There are two major objectives in this report; (1) to optimize microstructure control of ATF FeCrAl alloys during tube drawing processes, and (2) to provide an update on the progress of ATF FeCrAl tube production via commercial manufacturers. Experimental efforts have been made to optimize the process parameters balancing the tube fabricability, especially for tube drawing processes, and microstructure control of the final tube products. Lab-scale sheet materials of Gen II FeCrAl alloys (Mo-containing and Nb-containing FeCrAl alloys) were used in the study, combined with a stepwise warm-rolling process and intermediate annealing, aiming to simulate the tube drawing process in a commercial tube manufacturer. The intermediate annealing at 650??C for 1h was suggested for the tube-drawing process of Mo-containing FeCrAl alloys because it successfully softened the material by recovering the work hardening introduced through the rolling step, without inducing grain coarsening due to recrystallization. The final tube product is expected to have stabilized deformed microstructure providing the improved tensile properties with sufficient ductility. Optimization efforts on Nb-containing FeCrAl alloys focused on the effect of alloying additions and annealing conditions on the stability of deformed microstructure. Relationships between the second-phase precipitates (Fe2Nb-Laves phase) and microstructure stability are discussed. FeCrAl tube production through commercial tube manufacturers is currently in progress. Three different manufacturers, Century Tubes, Inc. (CTI), Rhenium Alloys, Inc. (RAI), and Superior Tube Company, Inc. (STC), are providing capabilities for cold-drawing, warm-drawing, and HPTR cold-pilgering, respectively. The first two companies are currently working on large quantity tube production (expected 250 ft length) of Gen I model FeCrAl alloy (B136Y3, at CTI) and Gen II (C35M4, at RAI), with the process parameters obtained from the experimental efforts. The expected delivery dates are at the end of July, 2016, and the middle of June, 2016, respectively. Tube production at STC would be the first attempt to apply cold-pilgering to the FeCrAl alloys. Communication has been initiated, and the materials have been machined for the cold-pilgering process.

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