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http://dx.doi.org/10.5516/NET.2011.43.3.243

ANALOG COMPUTING FOR A NEW NUCLEAR REACTOR DYNAMIC MODEL BASED ON A TIME-DEPENDENT SECOND ORDER FORM OF THE NEUTRON TRANSPORT EQUATION  

Pirouzmand, Ahmad (Department of Nuclear Engineering, Shiraz University)
Hadad, Kamal (Department of Nuclear Engineering, Shiraz University)
Suh, Kune Y. (Department of Energy Systems Engineering, Seoul National University)
Publication Information
Nuclear Engineering and Technology / v.43, no.3, 2011 , pp. 243-256 More about this Journal
Abstract
This paper considers the concept of analog computing based on a cellular neural network (CNN) paradigm to simulate nuclear reactor dynamics using a time-dependent second order form of the neutron transport equation. Instead of solving nuclear reactor dynamic equations numerically, which is time-consuming and suffers from such weaknesses as vulnerability to transient phenomena, accumulation of round-off errors and floating-point overflows, use is made of a new method based on a cellular neural network. The state-of-the-art shows the CNN as being an alternative solution to the conventional numerical computation method. Indeed CNN is an analog computing paradigm that performs ultra-fast calculations and provides accurate results. In this study use is made of the CNN model to simulate the space-time response of scalar flux distribution in steady state and transient conditions. The CNN model also is used to simulate step perturbation in the core. The accuracy and capability of the CNN model are examined in 2D Cartesian geometry for two fixed source problems, a mini-BWR assembly, and a TWIGL Seed/Blanket problem. We also use the CNN model concurrently for a typical small PWR assembly to simulate the effect of temperature feedback, poisons, and control rods on the scalar flux distribution.
Keywords
Time-dependent Second Order form of Neutron Transport Equation; Cellular Neural Network; Nuclear Reactor Dynamics; Analog Computing;
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