Computational Analysis of Neutron Moderation in Graphite Reflectors for Advanced Small Modular Reactors (High Temperature)

Authors

  • Rabeeah Mohammed Abdullah University of Benghazi
  • Asmaa Rajab Salim University of Benghazi

DOI:

https://doi.org/10.37376/ajhas.vi3.7260

Keywords:

nuclear reactors, high temperature reactors, small modular reactors, reactor design, reactor control, compact reactors

Abstract

Abstract:
With growing interest in compact modular reactor concepts, new design challenges have emerged for the nuclear industry. A key economic issue is the ability of small reactors to compete with large-scale plants. This study explores a novel approach to reduce dependence on fixed burnable poisons during high-reactivity periods in a high-temperature graphite-moderated design. The proposed method involves modifying the core’s neutron energy spectrum over the fuel cycle to utilize bred plutonium. Removing part of the central reflector hardens the spectrum, increasing plutonium breeding. Later reinserting the reflector softens the spectrum to fission more plutonium. This provides a neutronic storage effect in 238U while breeding plutonium. The small annular core depends heavily on the central reflector for thermal neutrons. Removing it reduces thermal neutron fluence near the center, shifting fission outwards. Reinserting it then shifts fission back to the center to utilize bred plutonium and 235U there. Simulations show removing the reflector provides a 320 pcm reactivity drop over the cycle. The plutonium buildup offers additional fissile material until reflector reinsertion. This twofold benefit increased full-power days by ~31 days from extra fissility and reduced peak pin power by 30% during reflector removal.

Downloads

Download data is not yet available.

Author Biographies

Rabeeah Mohammed Abdullah, University of Benghazi

Physics Department, Faculty of Arts Science, Benghazi University, EL-Marj, Libya

Asmaa Rajab Salim, University of Benghazi

Physics Department, Faculty of Arts Science, Benghazi University, EL-Marj, Libya

References

Atkinson. S, Abram. T.J, & Litskevich. D.B.M, “A Comparison between Beryllium Oxide and Nuclear Graphite in a Small Scale High Temperature Reactor,” unpublished. 2018, V(7), p1897.

Bess. J.D, & Dolphin. B.H, “Evaluation of the Start-Up Core Physics Tests at Japan’s High Temperature Engineering Test Reactor,” 2018.

Burnup Equations,” Nucl. Sci. Eng., vol. 182, pp. 297–318, 2016.

Department for Business, Energy & Industrial Strategy, “Advanced Nuclear Technologies,” 2018.

DECC, “UK Renewable Energy Roadmap,” Carbon N. Y., vol. 5, pp. 293–298, 2011.

Elder, R. and Allen, R. Nuclear Heat for Hydrogen Production Coupling a Very High/High Temperature Reactor to a Hydrogen Production Plant. 2009, 51,PP, 500-525.

Heijna. M.C.R, Groot. S. de, & J.A. Vreeling, “Comparison of Irradiation Behavior of HTR Graphite Grades,” J. Nucl. Mater., vol. 492, pp. 148–156, 2017.

IAEA, “Pathways to 2050—Key Results,” 2018.

IAEA, “High Temperature Gas Cooled Reactor Fuels and Materials,” 2018.

IAEA, “Boiling Water Reactor Simulator with Passive Safety Systems User Manual,” 2018.

IAEA, “Design of the Reactor Core for Nuclear Power Plants—Safety G,” 2018.

IAEA-TECDOC”STATUS OF FAST REACTOR RESEARCH AND TECHNOLOGY DEVELOPMENT”,1691.

Grimston. M, Nuttall.W.J, & Vaughan. G, “The Siting of UK Nuclear Reactors,” J. Radiol. Prot., vol. 34, pp. R1–R24, 2014.

Leppänen. J.et al., “The Serpent Monte Carlo Code: Status, Development and Applications in 2013,” Ann. Nucl. Energy, vol. 82, pp. 142–150, 2015.

Lohnert. G.H, & Reutler. H, “The Modular HTR—A New Design of High-Temperature Pebble-Bed Reactor,” Nucl. Energy, vol. 22, pp. 197–200, 1983.

Maria. P, “Higher-Order Chebyshev Rational Approximation Method and Application to Burnup Equations,” Nucl. Sci. Eng., vol. 182, pp. 297–318, 2016.

Science Alert, “China Says It’ll Have a Meltdown-Proof Nuclear Reactor Ready by Next Year,” 2018.

Snead. L.L, Contescu. C.I, Byun. T.S, & W. Porter, “Thermo physical Property and Pore Structure Evolution in Stressed and Non-Stressed Neutron Irradiated IG-110 Nuclear Graphite,” J. Nucl. Mater., vol. 476, pp. 102–109, 2016.

UK GOV BAIS, “UK Ratifies the Paris Agreement,” , N. Y., 5,PP 293–298,2018.

Zhang. Z, et al., “The Shandong Shidao Bay 200 MWe High-Temperature Gas-Cooled Reactor Pebble-Bed Module (HTR-PM) Demonstration Power Plant: An Engineering and Technological Innovation,” Engineering, vol. 2, pp. 112–118, 2016.

Downloads

Published

2025-03-17

How to Cite

Mohammed Abdullah, R. ., & Rajab Salim, A. . . (2025). Computational Analysis of Neutron Moderation in Graphite Reflectors for Advanced Small Modular Reactors (High Temperature). Afaq Journal for Human and Applied Studies, (3), 328–337. https://doi.org/10.37376/ajhas.vi3.7260

Issue

No. 3 (2025)

Section

المقالات

License

Copyright (c) 2025 Afaq Journal for Human and Applied Studies

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.