Robust feedback-linearization control for axial power distribution in pressurized water reactors during load-following operation

• Published in: Nuclear engineering and technology Vol. 50; no. 1; pp. 97 - 106
• Main Authors: Zaidabadi nejad, M., Ansarifar, G.R.
• Format: Journal Article
• Language: English
• Published: Elsevier 01.02.2018; 한국원자력학회
• Subjects: Axial Offset; Dynamic Sliding Mode Control; Feedback-Linearization; Validated Four Nodes Kinetics Reactor Model; 원자력공학
• ISSN: 1738-5733; 2234-358X
• DOI: 10.1016/j.net.2017.10.013

Improved load-following capability is one of the most important technical tasks of a pressurized water reactor. Controlling the nuclear reactor core during load-following operation leads to some difficulties. These difficulties mainly arise from nuclear reactor core limitations in local power peaking: the core is subjected to sharp and large variation of local power density during transients. Axial offset (AO) is the parameter usually used to represent the core power peaking. One of the important local power peaking components in nuclear reactors is axial power peaking, which continuously changes. The main challenge of nuclear reactor control during load-following operation is to maintain the AO within acceptable limits, at a certain reference target value. This article proposes a new robust approach to AO control of pressurized water reactors during load-following operation. This method uses robust feedback-linearization control based on the multipoint kinetics reactor model (neutronic and thermal-hydraulic). In this model, the reactor core is divided into four nodes along the reactor axis. Simulation results show that this method improves the reactor load-following capability in the presence of parameter uncertainty and disturbances and can use optimum control rod groups to maneuver with variable overlapping.