Automatic determination of pressurized water reactor core loading patterns that maximize beginning-of-cycle reactivity within power-peaking and burnup constraints
Journal Article
·
· Nucl. Technol.; (United States)
OSTI ID:5043850
Computational capability has been developed to automatically determine a good estimate of the core loading pattern, which minimizes fuel cycle costs for a pressurized water reactor (PWR). Equating fuel cycle cost minimization with core reactivity maximization, the objective is to determine the loading pattern that maximizes core reactivity while satisfying power peaking, discharge burnup, and other constraints. The method utilizes a two-dimensional, coarse-mesh, finite difference scheme to evaluate core reactivity and fluxes for an initial reference loading pattern. First-order perturbation theory is applied to determine the effects of assembly shuffling on reactivity, power distribution, end-of-cycle burnup. Monte Carlo integer programming is then used to determine a near-optimal loading pattern within a range of loading patterns near the reference pattern. The process then repeats with the new loading pattern as the reference loading pattern and terminates when no better loading pattern can be determined. The process was applied with both reactivity maximization and radial power-peaking minimization as objectives. Results on a typical large PWR indicate that the cost of obtaining an 8% improvement in radial power-peaking margin is approx. =2% in fuel cycle costs, for the reload core loaded without burnable poisons that was studied.
- Research Organization:
- North Carolina State Univ., Dept. of Nuclear Engineering, P.O. Box 7909, Raleigh, NC 27695-7909
- OSTI ID:
- 5043850
- Journal Information:
- Nucl. Technol.; (United States), Journal Name: Nucl. Technol.; (United States) Vol. 74:1; ISSN NUTYB
- Country of Publication:
- United States
- Language:
- English
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Related Subjects
21 SPECIFIC NUCLEAR REACTORS AND ASSOCIATED PLANTS
210200* -- Power Reactors
Nonbreeding
Light-Water Moderated
Nonboiling Water Cooled
BURNUP
COMPUTER CALCULATIONS
COST
FINITE DIFFERENCE METHOD
FUEL CYCLE
ITERATIVE METHODS
MONTE CARLO METHOD
NUMERICAL SOLUTION
PEAK LOAD
PERTURBATION THEORY
POWER DISTRIBUTION
PWR TYPE REACTORS
REACTIVITY
REACTOR COMPONENTS
REACTOR CORES
REACTOR FUELING
REACTORS
TWO-DIMENSIONAL CALCULATIONS
WATER COOLED REACTORS
WATER MODERATED REACTORS
210200* -- Power Reactors
Nonbreeding
Light-Water Moderated
Nonboiling Water Cooled
BURNUP
COMPUTER CALCULATIONS
COST
FINITE DIFFERENCE METHOD
FUEL CYCLE
ITERATIVE METHODS
MONTE CARLO METHOD
NUMERICAL SOLUTION
PEAK LOAD
PERTURBATION THEORY
POWER DISTRIBUTION
PWR TYPE REACTORS
REACTIVITY
REACTOR COMPONENTS
REACTOR CORES
REACTOR FUELING
REACTORS
TWO-DIMENSIONAL CALCULATIONS
WATER COOLED REACTORS
WATER MODERATED REACTORS