The Canadian supercritical water-cooled reactor (SCWR) design is part of Canada's Generation IV reactor development program. The reactor uses batch fueling, light water above the thermodynamic critical point as a coolant and a heavy water moderator. The design has evolved considerably and is currently at the conceptual design level. As a result of batch fueling, a certain amount of excess reactivity is loaded at the beginning of each fueling cycle. This excess reactivity must be controlled using a combination of burnable neutron poisons in the fuel, moderator poisons, and control blades interspersed in the heavy water moderator. Recent studies have shown that the combination of power density, high coolant temperatures, and reactivity management can lead to high maximum cladding surface temperatures (MCST) and maximum fuel centerline temperatures (MFCLT) in this design. This study focuses on improving both the MCST and the MFCLT through modifications of the conceptual design including changes from a 3 to 4 batch fueling cycle, a slightly shortened fuel cycle (although exit burnup remains the same), axial graded fuel enrichment, fuel-integrated burnable neutron absorbers, lower reactivity control blades, and lower reactor thermal powers as compared to the original conceptual design. The optimal blade positions throughout the fuel cycle were determined so as to minimize the MCST and MFCLT using a genetic algorithm and the reactor physics code PARCS. The final design was analyzed using a fully coupled PARCS-RELAP5/SCDAPSIM/MOD4.0 model to accurately predict the MCST as a function of time during a fueling cycle.
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April 2018
Research-Article
Optimization of the Canadian SCWR Core Using Coupled Three-Dimensional Reactor Physics and Thermal-Hydraulics Calculations
F. Salaun,
F. Salaun
Engineering Physics Department,
McMaster University,
1280 Main Street West,
Hamilton, ON L8S 4L8
e-mail: salaunf@mcmaster.ca
McMaster University,
1280 Main Street West,
Hamilton, ON L8S 4L8
e-mail: salaunf@mcmaster.ca
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D. R. Novog
D. R. Novog
Engineering Physics Department,
McMaster University,
1280 Main Street West,
Hamilton, ON L8S 4L8
McMaster University,
1280 Main Street West,
Hamilton, ON L8S 4L8
Search for other works by this author on:
F. Salaun
Engineering Physics Department,
McMaster University,
1280 Main Street West,
Hamilton, ON L8S 4L8
e-mail: salaunf@mcmaster.ca
McMaster University,
1280 Main Street West,
Hamilton, ON L8S 4L8
e-mail: salaunf@mcmaster.ca
D. R. Novog
Engineering Physics Department,
McMaster University,
1280 Main Street West,
Hamilton, ON L8S 4L8
McMaster University,
1280 Main Street West,
Hamilton, ON L8S 4L8
1Corresponding author.
Manuscript received March 8, 2017; final manuscript received October 31, 2017; published online March 5, 2018. Assoc. Editor: Jovica R. Riznic.
ASME J of Nuclear Rad Sci. Apr 2018, 4(2): 021003 (13 pages)
Published Online: March 5, 2018
Article history
Received:
March 8, 2017
Revised:
October 31, 2017
Citation
Salaun, F., and Novog, D. R. (March 5, 2018). "Optimization of the Canadian SCWR Core Using Coupled Three-Dimensional Reactor Physics and Thermal-Hydraulics Calculations." ASME. ASME J of Nuclear Rad Sci. April 2018; 4(2): 021003. https://doi.org/10.1115/1.4038557
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