DESAIN KONSEPTUAL TERAS REAKTOR RISET INOVATIF BERBAHAN BAKAR URANIUM-MOLIBDENUM DARI ASPEK NEUTRONIK

Authors

  • Tukiran Surbakti Pusat Teknologi dan Keselamatan Reaktor Nuklir, BATAN
  • Surian Pinem Pusat Teknologi dan Keselamatan Reaktor Nuklir, BATAN
  • Tagor Malem Sembiring Pusat Teknologi dan Keselamatan Reaktor Nuklir, BATAN
  • Lily Suparlina Pusat Teknologi dan Keselamatan Reaktor Nuklir, BATAN
  • Jati Susilo Pusat Teknologi dan Keselamatan Reaktor Nuklir, BATAN

Keywords:

conceptual design, uarium-molibdenum-uarium feul, berilium, D2O, WIMS, BATAN-FUEL

Abstract

The multipurpose of research reactor utilization make many countries build the new research reactor. Trend of this reactor for this moment is multipurpose reactor type with a compact core to get high neutron flux at the low or medium level of power. The research newest reactor in Indonesia right now is already 25 year old. Therefore, it is needed to design a new research reactor, called innovative research reactor (IRR) and then as an alternative to replace the old research reactor. The aim of this research is to get the optimal configuration of equilibrium core with the acceptance criteria are minimum thermal neutron flux is 2.5E14 n/cm2 s at the power level of 20 MW (minimum), length of cycle of more than 40 days, and the most efficient of using fuel in the core. Neutronics design has been performed for new fuel of U-9Mo-Al with various fuel density and reflector. Design calculation has been performed using WIMSD-5B and BATAN-FUEL computer codes. The calculation result of the conceptual design shows four core configurations namely 5x5, 5x7, 6x5 and 6x6. The optimalization result for equilibrium core of innovative research reactor is the 5x5 configuration with 450 gU fuel loading, berilium reflector, maximum thermal neutron flux at reflector is 3.33E14 n/cm2 s and lenght of cycle is 57 days is the most optimal of IRR.

 

 

References

V.K., Raina, K. Sasidharan, Samiran Sengupta, Tej Singh. Multi Purpose Reactor. Nucl. Eng. April 2006 ; 7-8: 770-783

https://doi.org/10.1016/j.nucengdes.2005.09.022

Teruel, F.E, Rizwan-uddin. An innovative research reactor design. Nucl. Eng. Des. 2009; 239: 395-407

https://doi.org/10.1016/j.nucengdes.2008.10.025

IAEA, 2010. Tersedia di web pada http://www.iaea.org/worldatom/rrdb/.

Hastuti, E.P., Setiyanto. Perencanaan Reaktor Riset Inovatif Sebagai Solusi Pengganti Reaktor Penelitian dan Produksi Isotop di Indonesia. Prosiding Seminar Nasional Energi Nuklir; PPEN-BATAN 2010

Liem, P.H., Batan-FUEL: A General In-Core Fuel Management Code. Atom Indonesia 1996, 22, No.2.

WIMS-D5. OECD/NEA Data Bank Documentation, Package ID No. 1507/02; 1998

IAEA. WIMS-D Library Update. IAEA, Vienna, 2007.

BATAN. Laporan Analisis Keselamatan Rev. 10. BATAN, 2010.

Liem, P.H., Sembiring, T.M. Design of transition cores of RSG GAS (MPR-30) with higher loading silicide fuel. Nucl. Eng. Des. 2010; 240: 1433-1442

https://doi.org/10.1016/j.nucengdes.2010.01.028

Raina, V.K., Sasidharan, K., Sengupta, S., Singh, T. Multi purpose research reactor. Nucl. Eng. Des. 2006; 236: 770-783

https://doi.org/10.1016/j.nucengdes.2005.09.022

IAEA. Characterization and testing of materials for nuclear reactors. IAEA-TECDOC-1545, Vienna:IAEA;2007;p.65.

Downloads

Published

2015-03-29

How to Cite

Surbakti, T., Pinem, S., Sembiring, T. M., Suparlina, L., & Susilo, J. (2015). DESAIN KONSEPTUAL TERAS REAKTOR RISET INOVATIF BERBAHAN BAKAR URANIUM-MOLIBDENUM DARI ASPEK NEUTRONIK. Jurnal Teknologi Reaktor Nuklir Tri Dasa Mega, 14(3), 178–191. Retrieved from https://ejournal.brin.go.id/tridam/article/view/2431

Issue

Vol. 14 No. 3 (2012): Oktober 2012; Jurnal Teknologi Reaktor Nuklir Tri Dasa Mega

Section

Articles