Optimization of Core Regions and Fuel Fractions for Better Power Peaking Factor of 150, 450 and 1,000 MWth Molten Salt Reactor

Authors

  • Marisa Variastuti Department of Nuclear Science and Engineering, Faculty of Mathematics and Natural Science, Bandung Institute of Technology, West Java 40132, Indonesia
  • Dwi Irwanto Nuclear Physics and Biophysics Research Group, Department of Physics, Faculty of Mathematics and Natural Sciences, Bandung Institute of Technology, West Java 40132, Indonesia https://orcid.org/0000-0001-6519-190X
  • Mohamad Nurul Subkhi Physics Department, Faculty of Science and Technology, State Islamic University of Sunan Gunung Djati Bandung, West Java 40614, Indonesia
  • Piyatida Trinuruk Department of Mechanical Engineering, Faculty of Engineering, King Mongkut’s University of Technology Thonburi, Bangkok 10140, Thailand

DOI:

https://doi.org/10.48048/tis.2023.6937

Keywords:

Effective multiplication factor, Molten salt reactor, Power distribution, Power peaking factor, Thermal power

Abstract

The power peaking factor (PPF) is an important parameter that needs to be considered to maintain the reactor's stability, safety and efficiency. The present study discusses the power density distribution in the reactor core by calculating the PPF to increase the reactor safety margin and minimize the possibility of a high power density at a certain point causing core failure in the Molten Salt Reactor (MSR), which is one of the Generation-IV reactors with fuel and coolant dissolved in molten salt. Important parameters discussed in the present study are the distribution of the reactor core region and the fuel composition in each region during the reactor operation time of 2,000 days. Analysis was performed for 3 different thermal power: 150, 450 and 1,000 MWth as a representative to determine the behavior of PPF at small to large power by taking the reference design of the FUJI U3 reactor developed by ITMSF (International Thorium Molten-Salt Forum) Japan. FliBe (Lithium and Beryllium Fluoride) is used as the coolant, and the fuel mixture is 233UF4-ThF4. The calculation was conducted using SRAC2006 with PIJ and CITATION modules that solve the neutron diffusion equation providing power distribution values and effective multiplication factors. As a result, the MSR with 4 core regions produces a more balanced power distribution, a better PPF value, and a good effective multiplication factor for 2,000 days of operation time compared to the reference design.

HIGHLIGHTS

  • The research emphasizes the analysis of thermal power levels of 150, 450, and 1000 MWth to understand the Power Peaking Factor (PPF) behavior at different power levels
  • An even power distribution is accomplished by optimizing the number of core regions with different fuel fractions
  • After optimization, the decrease in Power Peaking Factor (PPF) values indicates an improvement in maintaining reactor stability, safety, and efficiency


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Published

2023-09-15

How to Cite

Variastuti, M. ., Irwanto, D. ., Subkhi, M. N. ., & Trinuruk, P. . (2023). Optimization of Core Regions and Fuel Fractions for Better Power Peaking Factor of 150, 450 and 1,000 MWth Molten Salt Reactor. Trends in Sciences, 20(12), 6937. https://doi.org/10.48048/tis.2023.6937

Issue

Vol. 20 No. 12 (2023): Trends in Sciences, Volume 20, Number 12, December 2023

Section

Research Articles

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