Gains in operational flexibility, safety margins, and cost efficiencies via integrated Plant Reload Optimization platform

Kim, Junyung; Lawrence, Svetlana; M Mostafa Abdo, Mohammad Gamal; Luque-Gutierrez, Juan C.; Rollins, Nicholas; Hou, Jason; Ivanov, Boyan; Donell, Adam; Spooner, Seth

Gains in operational flexibility, safety margins, and cost efficiencies via integrated Plant Reload Optimization platform

Conference · Tue May 07 00:00:00 EDT 2024

OSTI ID:2352474

^[1]; Lawrence, Svetlana ^[1]; ^[1]; Luque-Gutierrez, Juan C. ^[2]; Rollins, Nicholas ^[2]; Hou, Jason ^[2]; Ivanov, Boyan ^[3]; Donell, Adam ^[3]; Spooner, Seth ^[3]

Idaho National Laboratory
North Carolina State University
Constellation

The U.S. Department of Energy Light Water Reactor Sustainability Program Risk-Informed Systems Analysis Pathway Plant Reload Optimization Project aims to develop an integrated, comprehensive framework offering an all-in-one solution for reload evaluations with a special focus on optimizing core design. Optimizing the fuel loading pattern is one of the most important considerations in reducing the amount of new fuel used in the core. Due to thousands of possible core configuration options, finding optimal solutions is an unachievable task for a human. The Plant ReLoad Optimization platform, which supports artificial-intelligence-based reactor core designing, is now fully capable of handling realistic problems. The Plant ReLoad Optimization platform development project aims to build a reactor core design tool that includes reactor safety and fuel performance analyses and uses artificial intelligence to support the optimization of core design solutions. The NSGA-II (Non-dominated Sorting Genetic Algorithm II) optimizer was developed and tested within RAVEN (Risk Analysis and Virtual ENvironment) to handle many constraints by using an augmented objectives methodology. The demonstration was performed with constrained multiobjective optimization of a 17 × 17 pressurized-water reactor core loading patterns to minimize fuel cost and maximize fuel cycle length.

Research Organization:: Idaho National Laboratory (INL), Idaho Falls, ID (United States)

Sponsoring Organization:: 62

DOE Contract Number:: AC07-05ID14517

OSTI ID:: 2352474

Report Number(s):: INL/MIS-24-77706-Rev000

Country of Publication:: United States

Language:: English

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11 NUCLEAR FUEL CYCLE AND FUEL MATERIALS
22 GENERAL STUDIES OF NUCLEAR REACTORS
NSGA-II
fuel cost
genetic algorithm
plant reload optimization

Gains in operational flexibility, safety margins, and cost efficiencies via integrated Plant Reload Optimization platform

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