Thermal Conductivity Change in High Burnup MOX Fuel Pellet
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概要
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High burnup MOX and UO2 test rods were prepared from the fuel rods irradiated in commercial BWRs. Each test rod was equipped with a fuel center thermocouple and reirradiated in the Halden boiling water reactor (HBWR) in Norway. The burnups of MOX and UO2 test rods reached about 84 GWd/tHM and 72 GWd/t, respectively. Fuel temperature was measured continuously during the re-irradiation tests. Thermal conductivity change in high burnup fuel was evaluated from the results of comparison between the measured fuel temperature and the data calculated by using the fuel analysis code FEMAXI-6. The comparison results suggested that the thermal conductivity of MOX fuel pellets is comparable to that of UO2 fuel pellets in the high burnup region around 80 GWd/t. It is probable that the impurity effect of Pu atoms gradually diminishes with increasing burnup because other factors that affect pellet thermal conductivity, such as the accumulation effect of soluble fission products and irradiation-induced defects in crystal lattice, become dominant in a high burnup region.
- 2009-09-01
著者
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NAKAMURA Jinichi
Fuel Safety Research Group, Nuclear Safety Research Center, Japan Atomic Energy Agency
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AMAYA Masaki
Fuel Safety Research Group, Nuclear Safety Research Center, Japan Atomic Energy Agency
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NAGASE Fumihisa
Fuel Safety Research Group, Nuclear Safety Research Center, Japan Atomic Energy Agency
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FUKETA Toyoshi
Fuel Safety Research Group, Nuclear Safety Research Center, Japan Atomic Energy Agency
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Nakamura Jinichi
Fuel Safety Research Group Nuclear Safety Research Center Japan Atomic Energy Agency
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Amaya M
Fuel Safety Research Group Nuclear Safety Research Center Japan Atomic Energy Agency
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Amaya Masaki
Fuel Safety Research Group Nuclear Safety Research Center Japan Atomic Energy Agency
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Fuketa T
Japan Atomic Energy Agency
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NAGASE Fumihisa
Nuclear Safety Research Center, Japan Atomic Energy Agency
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Nagase Fumihisa
Nuclear Safety Research Center Japan Atomic Energy Agency
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