Your search keyword '"triga"' showing total 1,178 results

1. A half-century of nuclear research, education and training: Story of the JSI TRIGA reactor

Author

Snoj, Luka, Ambrožič, Klemen, Barbot, Loïc, Benedik, Ljudmila, Bratkič, Arne, Capan, Ivana, Reynard-Carette, Christelle, Cindro, Vladimir, Čalič, Dušan, Destouches, Christophe, Geslot, Benoit, Haghighat, Alireza, Henry, Romain, Horvat, Milena, Huseynov, Elchin M., de Izarra, Grégoire, Jaćimović, Radojko, Jazbec, Anže, Jenčič, Igor, Jeraj, Robert, Joyce, Malcom, Kotnik, Domen, Kramberger, Gregor, Lengar, Igor, Malec, Jan, Mandić, Igor, Mascolino, Valerio, Merljak, Vid, Mikuž, Marko, Noguère, Gilles, Peric, Julijan, Pungerčič, Anže, Radulović, Vladimir, Rupnik, Sebastjan, Smodiš, Borut, Šlejkovec, Zdenka, Štrok, Marko, Štancar, Žiga, Švajger, Ingrid, Thiollay, Nicolas, Tiselj, Iztok, Trkov, Andrej, Žefran, Bojan, Žerovnik, Gašper, Žiber, Ylenia Kogovšek, and Goričanec, Tanja

Published

2025

2. Analysis of the triga mark-II benchmark ieu-comp-therm-003 with monte carlo code openmc.

Author

Islam, Saad and Motalab, Mohammad Abdul

Subjects

*CRITICALITY (Nuclear engineering), *NUCLEAR reactor cores, *COMPUTER programming, *PROJECT evaluation, *LIBRARIES

Abstract

Ensuring the reliable use of particle transport computer codes necessitates verification against benchmark experiments. This study aims to verify the Monte Carlo code OpenMC using the criticality benchmark model IEUCOMP-THERM-003 from the International Criticality Safety Benchmark Evaluation Project (ICSBEP) Handbook. The analysis focuses on the TRIGA Mark II reactor cores 132 and 133, employing nuclear cross-section libraries ENDF/B-VIII.0, ENDF/B-VII.1, ENDF/B-VII.0, and ENDF/BVI. 2. Results show that OpenMC provides KEFF values in close agreement with benchmark values, demonstrating its robustness in neutronic simulations. Comparison with MVP code results obtained previously, particularly with JENDL-3.3, shows similar accuracy. [ABSTRACT FROM AUTHOR]

Published

2024

3. Computational Optimization of 133<italic>m</italic>Xe Production in the Washington State University TRIGA Reactor.

Author

Kimball, Taylor S., Sjoden, Glenn E., Wang, Meng-Jen (Vince), and Watrous, Matthew G.

Abstract

AbstractHere we present a new method of irradiating 132Xe capsules with neutrons to produce 133mXe gas standards that are used for radiation detector calibration at radioxenon measurement laboratories in support of the Comprehensive Test Ban Treaty (CTBT). This method is designed to maximize the production of 133mXe compared to 133Xe, both of which are competing products from the 132Xe(n, g) reaction. The 133mXe is produced at a much higher fraction for high-energy neutron absorptions in 132Xe (~50% for fast neutrons versus ~11% for thermal neutrons).We performed “spectral tuning” of the Washington State University (WSU) TRIGA reactor neutron spectrum inside the 132Xe ampules to maximize the number of fast neutrons and minimize the number of thermal neutrons available for 132Xe absorption. Spectral tuning analysis, done with Monte Carlo simulations, provided valuable insights into a future final design for a 132Xe irradiation capsule. With no spectral tuning, the fractional yield of 133mXe in the WSU reactor was ~11.7%. By surrounding the 132Xe capsule with a 0.5-cm-thick layer of tungsten and a 2.83-cm layer of europium (III) oxide and placing it in the reactor’s cadmium rotator tube next to the fuel elements, the fractional yield of 133mXe can be increased to 24.6%, a 111% increase in yield. Thus, by improving the fractional yield of 133mXe through spectral tuning, the CTBT will have better quality gas standards to use for radioxenon detector calibration to assist in the CTBT’s mission. [ABSTRACT FROM AUTHOR]

Published

2024

4. Past, Present and Future of Research Reactor(s) in Slovenia

Author

Tiselj, Iztok, Cizelj, Leon, Malec, Jan, Snoj, Luka, Chaari, Fakher, Series Editor, Gherardini, Francesco, Series Editor, Ivanov, Vitalii, Series Editor, Haddar, Mohamed, Series Editor, Cavas-Martínez, Francisco, Editorial Board Member, di Mare, Francesca, Editorial Board Member, Kwon, Young W., Editorial Board Member, Tolio, Tullio A. M., Editorial Board Member, Trojanowska, Justyna, Editorial Board Member, Schmitt, Robert, Editorial Board Member, Xu, Jinyang, Editorial Board Member, Shams, Afaque, editor, Al-Athel, Khaled, editor, Tiselj, Iztok, editor, Pautz, Andreas, editor, and Kwiatkowski, Tomasz, editor

Published

2024

5. Advancing Nuclear Research and Education in Slovenia and EU: From Operating the TRIGA Reactor to Building a New Generation Facility

Author

Malec, Jan, Tiselj, Iztok, Cizelj, Leon, Pungerčič, Anže, Goričanec, Tanja, and Snoj, Luka

Published

2024

6. Numerical Dose Assessment and Short-term Radioactivity Impact on Foodstuff for Continuous Release from of TRIGA Mark II Research Reactor

Author

Ahmed Dahia, Amel Dadda, Amina Lyria Cheridi Deghal, and Abdellah Bouam

Subjects

CROM, Radioactivity, TRIGA, Research reactor, Dose, Environmental sciences, GE1-350, Environmental technology. Sanitary engineering, TD1-1066

Abstract

This work is a contribution to the assessment of the radiological consequences of radioactivity and radiation dose for TRIGA Mark II research reactor during continuous operation. The potential release to the atmosphere of 131I, 137Cs, and 90Sr are computed in the South direction is calculated using CROM software. We have attempted to evaluate the daily concentration of radioactivity and its impact on foodstuff. The annual average dose received from internal and external irradiation by age group through the different pathways were also considered. The simulation results showed that the highest air concentration was found at 225 m distance from the source and the calculated doses were found to be significantly very low. The contribution of Iodine 131I is significantly higher in fruit vegetables, while the 137Cs and 90Sr are dominant in animal products. Furthermore, inhalation and ingestion of contaminated food were found to be the most likely routes of entry into the human body.

Published

2024

7. Assessment of the gamma and neutron dose field around the closed-water activation loop at the JSI TRIGA reactor.

Author

Kotnik, Domen, Snoj, Luka, and Lengar, Igor

Subjects

*GAMMA rays, *NEUTRONS, *GRAPHITE, *GRAPHENE

Abstract

A closed-water activation loop is being built at the Jožef Stefan Institute TRIGA reactor in Slovenia to serve as a well-defined and stable source of high-energy gamma rays and neutrons. The radial piercing port, which penetrates the graphite reflector and touching the reactor core was chosen for the installation of the closed-water loop due to the high neutron flux and favourable shielding conditions of the surrounding concrete bioshield. The main objective of this work is to assess the neutron and gamma dose field outside the port to obtain important details for the final design of the inner part of the irradiation facility and to assess the background noise for the detectors. The main part of the work consists of the design of the shielding plugs and the construction of a detailed MCNP model of the whole irradiation facility. The dose field calculations were performed with a two-step hybrid transport approach using ADVANTG for variance reduction and MCNP for particle transport. Such deep penetration and shielding calculations are challenging and computationally intensive. The results showed that the dose rate using shielding plugs is more than 7 orders of magnitude lower compared to an empty open port. To reduce the computational uncertainty, further optimisation of the ADVANTG input is essential. The final design of the shielding plugs is described. Additional lead shielding blocks will be added outside the port afterwards if needed. [ABSTRACT FROM AUTHOR]

Published

2023

8. Computationally Optimized Irradiation Chamber Design for Production of 135Xe in the Washington State University TRIGA Reactor.

Author

Hall, Tanner W., Wang, Meng-Jen, Sjoden, Glenn E., Watrous, Matthew, and Hines, Corey

Subjects

*NEUTRON flux, *STATE universities & colleges, *IRRADIATION, *NUCLEAR reactor cores, *RESEARCH reactors, *PARTICLE analysis, *NUCLEAR reactors

Abstract

This work summarizes the radiation transport–based design for a new D2O-moderated ex-core irradiation facility in the Washington State University (WSU) TRIGA reactor for optimization of 135Xe sources used for calibration and quality control testing of Xe gas detection equipment in support of the Comprehensive Test Ban Treaty (CTBT). Three-dimensional (3-D) particle transport analysis characterizing the WSU reactor core using MCNP6.2 (3-D Monte Carlo) and PENTRAN (3-D deterministic parallel SN) form the basis for the computational optimization. Excellent agreement between MCNP6.2 and PENTRAN predictions is observed. A fundamental fuel bundle depletion analysis is applied to enable a more accurate prediction of neutron flux and neutron spectrum distribution, which drives production rates of 135Xe and 133Xe. The results of various model simulations were used to inform recommendations for the final irradiation chamber design, which has been optimized for safe placement in the reactor tank prior to startup and will allow for insertion and rotation of xenon "bean" samples using existing WSU irradiation equipment, while remaining within operational parameters. The irradiation chamber is expected to produce samples that will remain viable for use in CTBT standards applications for durations 70% to 80% longer than samples produced using current procedures. Thus, this design is expected to improve CTBT-related calibrations and performance testing and to support the continued stability of the CTBT monitoring network. [ABSTRACT FROM AUTHOR]

Published

2023

9. Reliability assessment methods to address fast transient of reactor core

Author

N.H. Badrun, Nandita Talukder, and Nosrat Sharmin

Subjects

TRIGA, Transient, Reliability, FORM-SORM, Directional simulation, Nuclear engineering. Atomic power, TK9001-9401

Abstract

In order to enhance the safety of new advanced reactors, reliability based approach to the design of thermal hydraulic system becomes necessary. In this work, “load exceeds capacity” based approach of structural reliability analysis is employed and probability of failure of the system was then assessed in terms of a limit state function while probabilistic measure of limit state function violation is performed through different methods of reliability assessment. Here, we have focused on TRIGA core subjected to reactivity initiated fast transient. Initially, response surface design method has been used for approximating true failure surface, and then FORM-SORM analysis has been carried out. But, due to non linearity involved with failure surface, there have been noticed instability in FORM-SORM implementation. Later, directional simulation approach of Monte Carlo variance reduction techniques has been employed to illustrate such fast transient. In the investigation, there have been several aspects considered and in each case directional simulation method has shown its ability to give valid results. Hence, the method could be recommended as a viable and efficient scheme to solve even fast transient problem in design and analysis of any reactor.

Published

2022

10. Evaluation of a uranium zirconium hydride fuel rod option for conversion of the MIT research reactor (MITR) from highly-enriched uranium to low-enriched uranium

Author

Hu, L. [MIT Nuclear Reactor Lab., Cambridge, MA (United States)]

Published

2017

11. Reactor dynamics analysis using Model Order Reduction: The TRIGA Mark II reactor case study.

Author

Introini, Carolina, Lorenzi, Stefano, Giacobbo, Francesca, Salvini, Andrea, Wang, Xiang, and Cammi, Antonio

Subjects

*PROPER orthogonal decomposition, *RESEARCH reactors, *NUCLEAR reactors, *COMPUTATIONAL fluid dynamics, *HILBERT-Huang transform

Abstract

Compared to conventional engineering systems, nuclear reactors present unique physical and safety features that make their high-fidelity modelling both necessary and complex. Indeed, modelling nuclear reactors is intrinsically a multi-scale and multi-physics task. Up to recent years, the modelling approach for nuclear reactors saw the use of highly performing computer codes and hardware to retrieve a model as close as possible to reality; whereas this remains true, especially from the point of view of regulators and safety assessments, an alternative modelling approach has appeared in the nuclear reactor world. Indeed, whereas high-fidelity models are invaluable for providing in-depth insights into the system, especially when experimental data are not available, their computational cost is such that they are not suited for all applications that involve multiple simulations over a parametric domain (such as in the design and optimisation phase, known as multi-query scenarios). Thus, this novel approach aims at reducing the computational complexity of high-fidelity models whilst preserving high enough accuracy to satisfy the regulatory requirements of the nuclear world, and modelling techniques with this scope fall into the broad category of Model Order Reduction (MOR) techniques. MOR methodologies offer a trade-off between computational cost and solution accuracy; they can also jointly work with Data Assimilation techniques, which deal with the dynamic integration of experimental data and numerical estimates, thus surpassing the logic of using experimental data only as a posteriori validation tool. As the use of MOR and Data Assimilation (DA) for nuclear reactor analysis and for the development of integrated tools and digital twins for the system is still in the first stages, this work overviews some MOR and DA methodologies developed by the authors applied to an existing nuclear system, the TRIGA Mark II research reactor at the University of Pavia, which represents a benchmark test case of a complete nuclear reactor with experimental data available. The choice of using different MOR techniques to tackle various problems follows the logic of developing specific algorithms for specific issues and then merging them into a single MOR and DA-based digital twin, thus reducing the complexity and the cost of the single algorithm modules compared to a single general one: the three MOR techniques considered in this work (Dynamic Mode Decomposition, Proper Orthogonal Decomposition with Kalman Filtering and Generalised Empirical Interpolation Method) follows this logic. Indeed, the results show the potentiality of this approach for complex engineering problems, showing how these techniques can offer significant insights into the system without the computational cost associated with high-fidelity models. • Definition of the MOR and DA frameworks for reactor dynamics analysis. • Three different MOR techniques have been considered: DMD, POD with KF nd GEIM. • Application to the TRIGA Mark II reactor of the University of Pavia as a test case. • Good results in state prediction and model improvement. [ABSTRACT FROM AUTHOR]

Published

2024

12. Estimation of radionuclides in Bandung TRIGA 2000 reactor core components: A focus on aluminum and its implications for decommissioning planning.

Author

Sumarbagiono, Raden, Ayu Artiani, Pungky, Basuki, Prasetyo, Yusuf, Muhammad, Sulistio Wisnubroto, Djarot, Aisyah, Iskandar, Dadong, Nurliati, Gustri, Setiawan, Andry, Bakhri, Syaiful, Seno, Haryo, Nailatussaadah, Ratnaningsih, Nia, and Setyawan, Daddy

Subjects

*NUCLEAR facility decommissioning, *NUCLEAR reactor cores, *RADIOACTIVE decay, *RESEARCH reactors, *NEUTRON flux, *RADIOISOTOPES, *RADIOACTIVE wastes, *NUCLEAR activation analysis

Abstract

[Display omitted] • Estimation of radionuclides formed in core components of TRIGA 2000 Bandung reactor. • This study focuses on the predominant aluminum components in the reactor core. • The numerical calculation uses MCNP 6.1 and ORIGEN 2.1 software. • Aluminum-27 is found to be the most prevalent stable isotope for all components. • Zinc-65 is the most significant radioactivity up to 6 years after decommissioning. This paper presents estimates of the radionuclides formed in the core components of the TRIGA 2000 Bandung reactor. This research is crucial for updating decommissioning programs and predicting the quantity and activity levels of radioactive wastes. This study primarily focused on the predominant aluminum components in the reactor core. MCNP 6.1 was utilized to calculate the neutron flux during the reactor operation, whereas ORIGEN 2.1 determined the radionuclides resulting from neutron activation. The calculations span over six years, with 2021 as the base year. The nine modelled components include the reflector wall, Lazy Susan, thermal column, thermalizing column, core wall and safety plate, shim wall, top grid plate, bottom grid plate, and beam port. The findings indicate that Aluminum-27 (Al-27) is the most prevalent stable isotope across all components, with mass percentages ranging between 97.89% and 97.93%. Aluminum exhibits low activation, and the radionuclides produced primarily stem from other elements present in 6061-type aluminum. Among the radionuclides, Zinc-65 (Zn-65) displayed the most significant radioactivity, with percentages varying from 81.6% to 99.82% in the initial year and diminishing over six years due to radioactive decay. By the sixth year, a notable reduction in the radioactivity was observed. Decommissioning nuclear facilities requires a holistic approach that encompasses cost, risk, potential environmental impacts, human safety, regulatory compliance, and the chosen technical strategy. Such planning is vital for adhering to the safety and security standards of the national regulatory body, BAPETEN. [ABSTRACT FROM AUTHOR]

Published

2024

13. Validation and Optimization of Activity Estimates of the FiR 1 TRIGA Research Reactor Biological Shield Concrete.

Author

Räty, Antti, Tanhua-Tyrkkö, Merja, Kotiluoto, Petri, and Kekki, Tommi

Subjects

*GERMANIUM detectors, *CONCRETE, *RESEARCH reactors

Abstract

FiR 1 is a TRIGA Mark II-type research reactor in Finland. It was in operation between 1962 to 2015 and will be dismantled in 2022 to 2023. Preliminary calculations of the activities in the reactor main structures were performed in an earlier stage of the decommissioning project. Samples of the activated parts of the reactor biological shield concrete were drilled in December 2018 to validate these estimates. This paper describes the calculations and gamma activity measurements performed for the activated concrete samples to determine the boundary between radioactive parts and concrete that can plausibly be free-released from regulatory control. The activities have been estimated with a two-step calculation process using the MCNP and ORIGEN-S calculation codes and measurements using an ISOCS gamma spectrometer with a high-purity germanium detector. [ABSTRACT FROM AUTHOR]

Published

2022

14. CEA-JSI Experimental Benchmark for validation of the modeling of neutron and gamma-ray detection instrumentation used in the JSI TRIGA reactor.

Author

Fausser, Clément, Thiollay, Nicolas, Destouches, Christophe, Barbot, Loïc, Fourmentel, Damien, Geslot, Benoît, De Izarra, Grégoire, Gruel, Adrien, Grégoire, Gilles, Domergue, Christophe, Radulović, Vladimir, Goričanec, Tanja, Ambrožič, Klemen, Žerovnik, Gasper, Lengar, Igor, Trkov, Andrej, Štancar, Žiga, Pungerčič, Anže, and Snoj, Luka

Subjects

*NEUTRONS, *GAMMA rays, *MONTE Carlo method, *FISSION counters, *NUCLEAR reactors

Abstract

Constant improvements of the computational power and methods as well as demands of accurate and reliable measurements for reactor operation and safety require a continuous upgrade of the instrumentation. In particular, nuclear sensors used in nuclear fission reactors (research or power reactors) or in nuclear fusion facilities are operated under intense mixed neutron and gamma-ray fields, and need to be calibrated and modeled to provide selective and accurate neutron and gamma-ray measurements. The French Atomic Energy and Alternative Energies Commission (CEA) and the Jožef Stefan Institute (JSI) have started an experimental program dedicated to a detailed experimental benchmark with analysis using Monte Carlo particle transport calculations and a series of neutron and gamma-ray sensor types used in the JSI TRIGA Mark II reactor. CEA has setup a simplified TRIPOLI-4® modeling scheme of the JSI TRIGA reactor based on the information available in the IRPhEP benchmark in order to facilitate analysis of future neutron and gamma-ray measurements. These allow the CEA to perform a TRIPOLI-4 instrumentation calculation scheme benchmarked with the JSI MCNP model. This paper presents the main results of this CEA calculation scheme application and the analysis of their comparison to the JSI results obtained in 2012 with the MCNP5 & ENDF/B-VII.0 calculation scheme. This paper will conclude with some information about the new experimental program to be carried out in 2022 in the TRIGA reactor core. [ABSTRACT FROM AUTHOR]

Published

2021

15. Preconceptual Feasibility Study to Evaluate Alternative Means to Produce Plutonium-238

Author

Everson, Matthew

Published

2013

16. United States Domestic Research Reactor Infrastrucutre TRIGA Reactor Fuel Support

Author

Morrell, Douglas

Published

2011

17. Strategies for Fast Fission Matrix Estimation with Fuel Temperature and Control Rod Feedback.

Author

Rau, Adam J. and Walters, William J.

Subjects

*MONTE Carlo method, *HYBRID reactors, *TEMPERATURE distribution

Abstract

Monte Carlo methods are useful for simulating new reactor designs, but even with advances in computing, these methods still require a significant amount of time to perform transient or multiphysics calculations coupled with thermal modeling. This work demonstrates a hybrid reactor physics method that uses Monte Carlo to precalculate an initial database of fission matrix parameters, then combines these results for fast calculations on arbitrary system states. This paper extends previous work that demonstrated these methods on the Penn State Breazeale Reactor (PSBR). Approaches for reducing time and memory cost and increasing the accuracy in reproducing Monte Carlo output are considered. For modeling fuel temperature, a representative temperature distribution is used while tallying the initial fission matrix database. Different approaches for modeling the coupling between individual control rod insertions as well as control and fuel temperature effects are presented as well. Individual solutions are completed in less than 1 s on a single core, and error with respect to Monte Carlo is within 35 pcm for multiplication factor, 0.6% root-mean square, and 2.8% maximum for the normalized three-dimensional fission source distribution on critical, steady-state configurations. Further qualification on different reactor types is needed, but the simplicity and flexibility of this method make further development promising. [ABSTRACT FROM AUTHOR]

Published

2021

18. VOID COEFFICIENT SENSITIVITY ANALYSIS FOR THE TRIGA MARK II REACTOR AT L.E.N.A. (UNIPV).

Author

Margulis, M., Blaise, P., Portinari, D., Cammi, A., Lorenzi, S., Aufiero, M., Calzavara, Y., and Bidaud, A.

Subjects

*NUCLEAR reactors, *PERTURBATION theory, *NEUTRON transport theory, *NUCLEAR physics, *NEUTRON diffusion

Abstract

Sensitivity analysis studies the effect of a change in a given parameter to a response function of the system under investigation. In reactor physics, this usually translates into the study of how cross sections and fission spectrum modifications affect the value of the multiplication factor, the delayed neutron fraction or the void coefficient for example. Generalized Perturbation Theory provides a useful tool for the assessment of adjoint weighed functions such as keff and void coefficient sensitivities. In this work, the capability of SERPENT code to perform sensitivity calculation based on GPT is used to study the TRIGA Mark II research reactor installed at L.E.N.A. of University of Pavia. A general sensitivity analysis to the most important reactor's cross sections has been performed in order to highlight the biggest reactivity contributions. Two numerically challenging tasks related to GPT calculation have been performed thanks to the relatively quick Monte Carlo approach allowed by this reactor: investigating the linearity of the reactivity injection caused by the flooding of the central channel, and calculating the fuel void coefficient sensitivity to the coolant density. [ABSTRACT FROM AUTHOR]

Published

2021

19. BURNUP CALCULATIONS OF THE JSI TRIGA REACTOR FUEL AND COMPARISON WITH MEASUREMENTS.

Author

Margulis, M., Blaise, P., Anže, Pungerčič, Dušan, Čalič, and Snoj, Luka

Subjects

*FUEL burnup (Nuclear engineering), *NUCLEAR fuels, *NUCLEAR reactor reactivity, *NEUTRON transport theory, *NUCLEAR reactor cores

Abstract

Fuel burnup of the JSI TRIGA was calculated by simulating complete operational history consisting of 240 different core configurations from 1966 to 2020. At the moment we are unable to perform burnup measurements, e.g. gamma spectroscopy on burned fuel elements, hence we used weekly measured excess reactivity as a reference point of different core configurations to verify the calculated core reactivity. Changes in reactivity due to burnup were assumed to be linear and this assumption was verified for burnup intervals smaller than 3 MWd/kg(HM). The comparison was performed on 46 different core configurations with different type of fuel elements. The Serpent-2 calculations decently predict the rate of reactivity change on different cases, as 52 % of calculations are withing 1σ and 86.9 % within 2σ of the measurements for total number of 46 cases. Additional analysis was performed by comparing unit cell calculations of different fuel types. Four different types of TRIGA fuel were used to analyse burnup changes in LEU and HEU fuel, where positive reactivity feedback on burnup was observed for HEU fuel due to burnable absorbers. Serpent-2 and WIMSD-5B were compared on unit-cell basis where good agreement within 200 pcm of reactivity change for large burnup was observed. In addition neutron spectrum changes due to burnup were investigated using unit-cell calculations where 4 % increase of the thermal peak and 1 % decrease of fast peak of the spectrum was observed for typical fuel burnups of 20 MWd/kg(HM), which approximately represents JSI TRIGA burnup at this moment. [ABSTRACT FROM AUTHOR]

Published

2021

20. Documented Safety Analysis Addendum for the Neutron Radiography Reactor Facility Core Conversion

Author

Christensen, Boyd

Published

2009

21. Evaluation of Neutron Radiography Reactor LEU-Core Start-Up Measurements

Author

Marshall, Margaret [Idaho National Lab. (INL), Idaho Falls, ID (United States)]

Published

2014

22. High Temperature Fuel Cladding Chemical Interactions Between TRIGA Fuels and 304 Stainless Steel

Author

Woolstenhulme, Eric [Idaho National Lab. (INL), Idaho Falls, ID (United States)]

Published

2016

23. K-J polar angular quadrature set for a method of characteristics based on neutrons cattering cross-sections

Author

Kim Donghoon, Albright Lucas I., Saenz Brittney L., and Jevremovic Tatjana

Subjects

AGENT code, method of characteristics, neutron anisotropic scattering, polar angular quadrature set, C5G7 benchmark, TRIGA, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

A novel polar angular quadrature set called the Kim-Jevremovic polar angular quadrature set is derived for the method of characteristics. It is based on neutron anisotropic scattering cross-sections in the Evaluated Nuclear Data File. This new set is implemented within the state-of-the-art neutron transport code AGENT and tested in comparison to MCNP6 as well as to other known quadrature sets for the UO2 unit cells, the well-known C5G7 benchmark, unreflected cylinders of uranyl-fluoride solutions in heavy water, and the University of Utah 100 kWth TRIGA MARK-I reactor core. These comparisons show that the newly proposed polar angular quadrature set provides better agreements than other quadrature sets for the lower order of anisotropic scattering expansions. This paper presents a complete derivation of the Kim-Jevremovic polar angular quadrature set and the analysis for the mentioned bench-mark examples.

Published

2019

24. Recent modifications of a TRIGA reactor for NAA and other applications.

Author

Rupnik, Sebastjan, Smodiš, Borut, and Jazbec, Anže

Subjects

*NEUTRON irradiation, *PNEUMATICS, *NEUTRON flux, *RESEARCH reactors, *NUCLEAR activation analysis, *FAST reactors

Abstract

TRIGA type research reactors, even relatively new ones, are originally equipped with rather obsolete irradiation pneumatic transfer systems. Therefore, the irradiation system of Slovenian TRIGA Mark II system was renewed in 2015 to improve the overall quality of irradiations. This year, the system was upgraded to allow for automated short irradiations under more thermalized neutron flux. The modernization includes also a so-called "triangular" channel, allowing for in-core irradiation of samples up to 5 cm in diameter and a horizontal channel allowing for irradiations of objects under homogeneous neutron flux in the length of over 60 cm. [ABSTRACT FROM AUTHOR]

Published

2020

25. Gamma-Heating and Gamma Flux Measurements in the JSI TRIGA Reactor: Results and Prospects.

Author

Gruel, A., Ambrozic, K., Destouches, C., Radulovic, V., Sardet, A., and Snoj, L.

Subjects

*IONIZATION chambers, *CONTROL elements (Nuclear reactors), *NUCLEAR reactor cores, *FISSION counters, *MATERIALS testing, *NEUTRON irradiation, *RADIATION dosimetry

Abstract

The neutron field of various irradiation positions of the TRIGA Mark II reactor of the Jožef Stefan Institute (JSI) has been thoroughly characterized by neutron activation dosimetry and miniature fission chambers techniques. In order to have a fully validated calculation scheme to analyze and plan experiments, the gamma field also has to be experimentally validated. The 10-year long collaboration between CEA and JSI is a perfect framework to carry out such a study, and measurements of the gamma field started in late 2016. Several measurement techniques were investigated in in-core and ex-core positions. Online measurements were carried out using miniature ionization chambers (ICs) manufactured by the CEA and PTW Farmer. Positional dependence was studied, showing a decrease in the delayed gamma contribution to the total gamma flux with increasing distance from the reactor core center. To characterize the gamma dose in the core, as well as in the periphery, thermoluminescent and optically stimulated luminescent detectors (TLDs and OSLDs, respectively) were tested. These detectors are commonly used at CEA to measure the gamma dose in a given material, in order to study the nuclear heating in various core elements (control rod, baffle, structural material). Different filters were used in order to assess an integrated dose ranging from a few Gy up to several kGy. The comparisons of experimental results against calculations performed with the JSIR2S code package show a very good agreement. The feasibility of such measurements demonstrates the complementarity between measurements with dosimetry and ICs from low to very high gamma-dose environment, such as in material testing reactors. [ABSTRACT FROM AUTHOR]

Published

2020

26. Conceptual Design of Irradiation Facility with 6 MeV and 7 MeV Gamma Rays at the JSI TRIGA Mark II Research Reactor.

Author

Lyoussi, A., Giot, M., Carette, M., Jenčič, I., Reynard-Carette, C., Vermeeren, L., Snoj, L., Le Dû, P., Žohar, Andrej, Pungerčič, Anže, Ambrožič, Klemen, Radulović, Vladimir, Jazbec, Anže, Rupnik, Sebastjan, Lengar, Igor, and Snoj, Luka

Subjects

*GAMMA rays, *RESEARCH reactors, *SUPERCONDUCTING coils, *COOLING systems, *MONTE Carlo method

Abstract

Activated cooling water in nuclear facilities can present a significant radiation source around primary cooling system causing radiation damage to electrical components, increasing doses to personnel and in the case of fusion facilities additional heating to superconducting coils. As there are only few sources of gamma rays with energies in the range of 6 MeV and 7 MeV an irradiation system using activated cooling water as the source of energetic gamma rays is proposed at the Jožef Stefan Institute (JSI) TRIGA Mark II research reactor. Two different conceptual designs, one utilizing central irradiation channel and one utilizing radial piercing port for water activation, are presented and analysed in the paper. Despite an order of magnitude higher water activation in central channel compared to radial piercing port the 16N decay rate in the irradiation facility is comparable between both design (order of 108 decays per second) due to longer transient time from central channel to irradiation facility. In the irradiation facility the expected biological dose rates due to the 16N decay rate are in order of several mSv/h. From the results he conceptual design utilizing the radial piercing port currently presents the best option for the irradiation facility due to the simpler design of the irradiation loop, already present shielding of the loop and comparable number of 16N decay rates to central channel. [ABSTRACT FROM AUTHOR]

Published

2020

27. Fresh-Core Reload of the Neutron Radiography (NRAD) Reactor with Uranium(20)-Erbium-Zirconium-Hydride Fuel

Author

Lell, Richard [Argonne National Lab. (ANL), Argonne, IL (United States)]

Published

2014

28. Fresh-Core Reload of the Neutron Radiography (NRAD) Reactor with Uranium(20)-Erbium-Zirconium-Hydride Fuel

Author

Montierth, Leland

Published

2013

29. RIA Analysis of Unprotected TRIGA Reactor

Author

M.H. Altaf, S.M. Tazul Islam, and N.H. Badrun

Subjects

Unprotected RIA, TRIGA, Doppler feedback, Cladding temperature, Nuclear engineering. Atomic power, TK9001-9401

Abstract

An RIA (reactivity initiated accident) analysis has been carried out for the TRIGA Mark II research reactor considering both step and ramp reactivity ranges within 0.5 % dk/k (< $1) to 2.0 % dk/k (>$2). The insertion time was set at 10 s. Based on the fact that a reactor becomes unprotected if scram does not work at the event of danger, to define unprotected conditions, the time to actuate scram (trip) was taken as close to total simulation time. In this long duration of scram inactivity, it is obtained from the present analysis that the reactor remained safe to up to 1.8 % dk/k ($2.57) for step reactivity and 1.99 % dk/k ($2.84) for ramp reactivity. In addition to negative temperature coefficient of reativity, probably the longer time of reactivity insertion keeps TRIGA safe even at larger magnitudes of reactivity during unprotected reactor transients. Coupled point kinetics, neutronics, and thermal hydraulics code EUREKA-2/R has been utilized for this work. It appears that EUREKA-2/RR predicts the sequence of unprotected transient scenario of TRIGA core with good approximation and the results will definitely be helpful for the reactor operators.

Published

2017

30. TRIGA-2000 Research Reactor Thermal-hydraulic Analysis using RELAP/SCDAPSIM/MOD3.4

Author

Anhar Riza Antariksawan, Efrizon Umar, Surip Widodo, Mulya Juarsa, and Mukhsinun Hadi Kusuma

Subjects

Loss of coolant, Loss of flow, RELAP5, Research reactor, TRIGA, Technology, Technology (General), T1-995

Abstract

Any events presumed to risk the safety of a nuclear reactor should be analyzed. In a research reactor, the applicability of best estimate thermal-hydraulic codes has been assessed for safety analysis purposes. In this paper, the applicability of the RELAP/SCDAPSIM/MOD3.4 thermal-hydraulic code to one Indonesian research reactor, which is named TRIGA-2000, is performed. The aim is to validate the model and use the model to analyze the thermal-hydraulic characteristics of TRIGA-2000 for main transient events considered in the Safety Analysis Report. The validation was done by comparing the calculation results with experimental data mainly in steady state conditions. The comparison of calculation results with the measurement data showed good agreement with little discrepancies. Based on these results, simulations for thermal-hydraulic analyses were performed for loss of coolant transients. The calculation results also properly depicted the physic of the thermal-hydraulic phenomena following the loss of coolant transients. These results showed the adequacy of the model. It could be shown that the engineered safety features of TRIGA-2000 play an important role in keeping the reactor safe from the risk of postulated loss of a coolant accident.

Published

2017

31. Fresh-Core Reload of the Neutron Radiography (NRAD) Reactor with Uranium(20)-Erbium-Zirconium-Hydride Fuel

Author

Montierth, Leland

Published

2011

32. K-J POLAR ANGULAR QUADRATURE SET FOR A METHOD OF CHARACTERISTICS BASED ON NEUTRON SCATTERING CROSS-SECTIONS.

Author

Donghoon KIM, ALBRIGHT, Lucas I., SAENZ, Brittney L., and JEVREMOVIC, Tatjana

Subjects

NEUTRON scattering, NEUTRON transport theory, DEUTERIUM oxide, NUCLEAR reactor cores, UNIT cell, URANINITE

Abstract

A novel polar angular quadrature set called the Kim-Jevremovic polar angular quadrature set is derived for the method of characteristics. It is based on neutron anisotropic scattering cross-sections in the Evaluated Nuclear Data File. This new set is implemented within the state-of-the-art neutron transport code AGENT and tested in comparison to MCNP6 as well as to other known quadrature sets for the UO2 unit cells, the well-known C5G7 benchmark, unreflected cylinders of uranyl-fluoride solutions in heavy water, and the University of Utah 100 kWth TRIGA MARK-I reactor core. These comparisons show that the newly proposed polar angular quadrature set provides better agreements than other quadrature sets for the lower order of anisotropic scattering expansions. This paper presents a complete derivation of the Kim-Jevremovic polar angular quadrature set and the analysis for the mentioned bench-mark examples. [ABSTRACT FROM AUTHOR]

Published

2019

33. Design Verification Report Neutron Radiography Facility (NRF) TRIGA Fuel Storage Systems

Author

CARRELL, R

Published

2002

34. Selenium Adsorption on Activated Carbon by Using Radiotracer Technique

Author

Tugrul, A. Beril, Haciyakupoglu, Sevilay, Erenturk, Sema Akyıl, Karatepe, Nilgun, Baytas, A. Filiz, Altinsoy, Nesrin, Baydogan, Nilgun, Buyuk, Bulent, Demir, Ertugrul, Dincer, Ibrahim, editor, Colpan, Can Ozgur, editor, and Kadioglu, Fethi, editor

Published

2013

35. Sensitivity and uncertainty quantification of neutronic integral data in the TRIGA Mark II research reactor

Author

M. Kaddour, T. El Bardouni, M. Lahdour, A. Arectout, Abdulaziz Ahmed, El Mahjoub Chakir, M. Makhloul, H. El Yaakoubi, and Hamid Boukhal

Subjects

Physics, Covariance, Fission, Nuclear engineering, Monte Carlo method, TK9001-9401, keff, Uncertainty, Nuclear data, MCNP6.1, TRIGA, Sensitivity, Nuclear Energy and Engineering, Nuclear engineering. Atomic power, Research reactor, Neutron, NJOY, Uncertainty quantification

Abstract

In order to study the sensitivity and the uncertainty of the Moroccan research reactor TRIGA Mark II, a model of this reactor has been developed in our ERSN laboratory for use with the N-Particle MCNP Monte Carlo transport codes (version 6). In this article, the sensitivities of the effective multiplication factor of this reactor are evaluated using the ENDF/B-VII.0, ENDF/B-VII.1 and JENDL-4.0 libraries and in 44 energy groups, for the cross sections of the fuel (U-235 and U-238) and the moderator (H-1 and O-16). However, the quantification of the uncertainty of the nuclear data is performed using the nuclear code NJOY99 for the generation and processing of covariance matrices. On the one hand, the highest uncertainty deviations, calculated using the ENDFB-VII.1 and JENDL4.0 evaluations, are 2275, 386 and 330 pcm respectively for the reactions U235(n, f), U235(n ν ¯ ) and H1(n, γ). On the other hand, these differences are very small for the neutron reactions of O-16 and U-238. Regarding the neutron spectra, in CT-mid plane, they are very close for the three evaluations (ENDF/B-VII.0, ENDF/B-VII.1 and JENDL-4.0). These spectra present two peaks (thermal and fission) around the energies 0.05 eV and 1 MeV.

Published

2022

36. Power peaking factor prediction using ANFIS method

Author

Mohamad Sabri Minhat, Hairie Rabir, Nur Syazwani Mohd Ali, Khaidzir Hamzah, Nor Afifah Basri, Muhammad Arif Sazali, Faridah Mohamad Idris, Jasman Zainal, and Muhammad Syahir Sarkawi

Subjects

Adaptive neuro fuzzy inference system, Adaptive neuro-fuzzy inference system, Artificial neural network, Mean squared error, Control rod, TK9001-9401, TRIGA research Reactors, Power (physics), TRIGA, Power peaking factor, Nuclear Energy and Engineering, Control theory, Neutron flux, Range (statistics), Nuclear engineering. Atomic power, Mathematics

Abstract

Power peaking factors (PPF) is an important parameter for safe and efficient reactor operation. There are several methods to calculate the PPF at TRIGA research reactors such as MCNP and TRIGLAV codes. However, these methods are time-consuming and required high specifications of a computer system. To overcome these limitations, artificial intelligence was introduced for parameter prediction. Previous studies applied the neural network method to predict the PPF, but the publications using the ANFIS method are not well developed yet. In this paper, the prediction of PPF using the ANFIS was conducted. Two input variables, control rod position, and neutron flux were collected while the PPF was calculated using TRIGLAV code as the data output. These input-output datasets were used for ANFIS model generation, training, and testing. In this study, four ANFIS model with two types of input space partitioning methods shows good predictive performances with R2 values in the range of 96%–97%, reveals the strong relationship between the predicted and actual PPF values. The RMSE calculated also near zero. From this statistical analysis, it is proven that the ANFIS could predict the PPF accurately and can be used as an alternative method to develop a real-time monitoring system at TRIGA research reactors.

Published

2022

37. Characterization of control rod worths and fuel rod power peaking factors in the university of Utah TRIGA Mark I reactor

Author

Alroumi Fawaz, Kim Donghoon, Schow Ryan, and Jevremovic Tatjana

Subjects

AGENT, TRIGA, MCNP6, control rod worth, reactivity, criticality, power peaking factor, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

Control rod reactivity (worths) for the three control rods and fuel rod power peaking factors in the University of Utah research reactor (100 kW TRIGA Mark I) are characterized using the AGENT code system and the results described in this paper. These values are compared to the MCNP6 and existing experimental measurements. In addition, the eigenvalue, neutron spatial flux distributions and reaction rates are analyzed and discussed. The AGENT code system is widely benchmarked for various reactor types and complexities in their geometric arrangements of the assemblies and reactor core material distributions. Thus, it is used as a base methodology to evaluate neutronics variables of the research reactor at the University of Utah. With its much shorter computation time than MCNP6, AGENT provides agreement with the MCNP6 within a 0.5 % difference for the eigenvalue and a maximum difference of 10% in the power peaking factor values. Differential and integral control rod worths obtained by AGENT show well agreement with MCNP6 and the theoretical model. However, regulating the control rod worth is somewhat overestimated by both MCNP6 and AGENT models when compared to the experimental/theoretical values. In comparison to MCNP6, the total control rod worths and shutdown margin obtained with AGENT show better agreement to the experimental values.

Published

2016

38. Fabrication and Testing of a Modular Micro-Pocket Fission Detector Instrumentation System for Test Nuclear Reactors.

Author

Reichenberger, Michael A., Nichols, Daniel M., Stevenson, Sarah R., Swope, Tanner M., Hilger, Caden W., Roberts, Jeremy A., Unruh, Troy C., and Mcgregor, Douglas S.

Subjects

*NUCLEAR reactors, *NEUTRON flux, *NEON, *NUCLEAR fuels

Abstract

Advancements in nuclear reactor core modeling and computational capability have encouraged further development of in-core neutron sensors. Measurement of the neutron-flux distribution within the reactor core provides a more complete understanding of the operating conditions in the reactor than typical ex-core sensors. Micro-Pocket Fission Detectors have been developed and tested previously but have been limited to singlenode operation and have utilized highly specialized designs. The development of a widely deployable, multi-node Micro-Pocket Fission Detector assembly will enhance nuclear research capabilities. A modular, four-node Micro-Pocket Fission Detector array was designed, fabricated, and tested at Kansas State University. The array was constructed from materials that do not significantly perturb the neutron flux in the reactor core. All four sensor nodes were equally spaced axially in the array to span the fuel-region of the reactor core. The array was filled with neon gas, serving as an ionization medium in the small cavities of the Micro-Pocket Fission Detectors. The modular design of the instrument facilitates the testing and deployment of numerous sensor arrays. The unified design drastically improved device ruggedness and simplified construction from previous designs. Five 8-mm penetrations in the upper grid plate of the Kansas State University TRIGA Mk. II research nuclear reactor were utilized to deploy the array between fuel elements in the core. The Micro-Pocket Fission Detector array was coupled to an electronic support system which has been specially developed to support pulse-mode operation. The Micro-Pocket Fission Detector array composed of four sensors was used to monitor local neutron flux at a constant reactor power of 100 kWth at different axial locations simultaneously. The array was positioned at five different radial locations within the core to emulate the deployment of multiple arrays and develop a 2-dimensional measurement of neutron flux in the reactor core. [ABSTRACT FROM AUTHOR]

Published

2018

39. University Reactor Instrumentation Grant

Author

Bajorek, S

Published

2000

40. Delayed gamma determination at the JSI TRIGA reactor by synchronous measurements with fission and ionization chambers.

Author

Ambrožič, K., Gruel, A., Radulović, V., Le Guillou, M., Blaise, P., Destouches, C., and Snoj, L.

Subjects

*GAMMA rays, *IONIZATION chambers, *FISSION counters, *SYNCHRONOUS counters, *NEUTRON capture

Abstract

Abstract Well characterized neutron and gamma fields inside a nuclear reactor are of key importance for its safe operation and for successful utilization of various research reactor irradiation facilities. In case of high-flux research reactors such as BR2 in Belgium, Maria in Poland and the future Jules Horowitz Reactor in France, the gamma energy deposition rate in reactor structural components and irradiated samples reaches values well over 10 W/g. To assure safe reactor operation, the gamma field and associated heating must therefore be thoroughly characterized in order to provide adequate component and sample cooling. The gamma field can be divided into two contributions: prompt gamma rays are emitted almost instantly after neutron interaction with nuclei, while the delayed gamma rays are emitted from nuclei, which become radioactive by neutron absorption, generated from fission and other processes. Most modern Monte-Carlo particle transport codes enable the transport of prompt gamma rays; a few support delayed gamma ray generation and transport as well. The latter have mostly been applied to fusion devices, where detailed shutdown dose-rate measurements have been performed. Although the delayed gamma field can also be simulated in fission devices, significant inaccuracy in the result is to be expected due to the computational complexity arising from the large number of radioactive fission products and incompleteness of nuclear data. Furthermore, the unavailability of experimental delayed gamma measurements in fission systems presents an important challenge for the validation of the experimental results. Previous measurements in several research reactors show that the delayed gamma flux amounts to around 30 % of the total gamma flux. However, these evaluations were performed with measurement data obtained during rapid reactor shutdowns (SCRAMs), using a single measurement point per SCRAM. In this paper we propose a new technique to accurately determine the magnitude of the delayed gamma component and its time evolution, based on synchronous acquisition of fission and ionization chamber signals. The measurements were performed at the JSI TRIGA reactor, using fission and ionization chambers placed in several in-core measurement positions. Their signal was acquired synchronously and at the highest possible acquisition rate in order to distinguish between measurement noise and reactor transients. Using the novel delayed gamma extraction technique we were able to estimate the magnitude of the delayed gamma contribution to be: 18.9 % ± 2.0 % at the reactor core periphery, linearly increasing towards the reactor core center to 31.4 % ± 2.8 % of the total measured gamma flux signal after 10 min of reactor operation. [ABSTRACT FROM AUTHOR]

Published

2018

41. The application of nodal method for dynamic analysis of TRIGA Mark II.

Author

Jamalipour, M., Cammi, A., and Ricotti, M.E.

Subjects

*NUCLEAR reactors, *NODAL analysis, *THERMAL hydraulics, *COMPUTER simulation, *KINETIC energy

Abstract

In this paper, Nodal dynamic method is introduced to model the TRIGA Mark II reactor of the University of Pavia as a dynamic system for the total operative power range (i.e. 0–250 kW) using a zero dimensional thermal hydraulic method. Neutronic and thermal hydraulic models are coupled in order to demonstrate reactor dynamic behavior. The reactor is divided into bi-dimensional zones and simulated in Serpent 2 to obtain two group cross sections for each specified zone as well as kinetic parameters. And they are applied in nodal method for the analysis of reactor dynamic behavior. Point kinetic and nodal dynamic methods are utilized for the second core configuration as the neutronic model. Different reactivities (i.e. 190, 104, 78, 40 pcm) are inserted by control rods in different power levels (i.e. 1, 50, 100, 150 kW) for the reactor dynamic analysis. A program is written in MATLAB to couple neutronic and thermal hydraulic models. A system of ordinary differential equations are produced and solved in space state model. The calculated and experimental power excursion results are in good agreement with less than 1% difference. The results between nodal method and point kinetic method are very consistent with less than 0.05% of difference. [ABSTRACT FROM AUTHOR]

Published

2018

42. Coupled unstructured fine-mesh neutronics and thermal-hydraulics methodology using open software: A proof-of-concept.

Author

Vasconcelos, Vitor, Santos, André, Campolina, Daniel, Theler, Germán, and Pereira, Claubia

Subjects

*COMPUTATIONAL fluid dynamics, *COMPUTATIONAL physics, *POWER density, *NUCLEAR engineering, *NUCLEAR physics

Abstract

The development of a fine mesh coupled neutronics/thermal-hydraulics framework mainly using free open source software is presented. The proposed contributions go in two different directions: one, is the focus on the open software approach development, a concept widely spread in many fields of knowledge but rarely explored in the nuclear engineering field; the second, is the use operating system shared memory as a fast and reliable storage area to couple the computational fluid dynamics (CFD) software OpenFOAM to the free and flexible reactor core analysis code milonga . This concept was applied to model the behavior of a TRIGA-IPR-R1 reactor fuel pin in steady-state mode. The macroscopic cross-sections for the model, a set of two-group cross-sections data, were generated using the Serpent code. The results show that this coupled system gives consistent results, encouraging system further development and its use for complex geometries simulations. [ABSTRACT FROM AUTHOR]

Published

2018

43. Transient CFD/Monte-Carlo Neutron Transport Coupling Scheme for simulation of a control rod extraction in TRIGA reactor.

Author

Henry, R., Tiselj, I., and Snoj, L.

Subjects

*NUCLEAR reactors, *NUCLEAR energy, *BOLTZMANN'S equation, *ENERGY conversion, *THERMAL hydraulics, *NEUTRON flux

Abstract

The computational model of the JSI TRIGA Mark II, coupling Monte-Carlo neutron transport code TRIPOLI and computational fluid dynamics code CFX was used to reproduce the behaviour of the reactor after extraction of a control rod. To tackle the time dependent Boltzmann equation, a quasistatic approach has been used and compared with point kinetic. Qualitative assessment of the model was performed by comparison with measured fuel temperature and power. Time evolutions of power and fuel temperature were reproduced. The quasistatic approximation was justified by updating the shape function at different time intervals. The quasistatic approach successfully reproduces the experimental results obtained with the TRIGA reactor. It was shown that most of the local effects (temperature, power density) were due to the control rod and that local effects of coupling were small. [ABSTRACT FROM AUTHOR]

Published

2018

44. Qualification of heavy water based irradiation device in the JSI TRIGA reactor for irradiations of FT-TIMS samples for nuclear safeguards.

Author

Radulović, Vladimir, Kolšek, Aljaž, Fauré, Anne-Laure, Pottin, Anne-Claire, Pointurier, Fabien, and Snoj, Luka

Subjects

*IRRADIATION, *NUCLEAR reactors, *MASS spectrometry, *URANIUM, *MONTE Carlo method, *EQUIPMENT & supplies

Abstract

The Fission Track Thermal Ionization Mass Spectrometry (FT-TIMS) method is considered as the reference method for particle analysis in the field of nuclear Safeguards for measurements of isotopic compositions (fissile material enrichment levels) in micrometer-sized uranium particles collected in nuclear facilities. An integral phase in the method is the irradiation of samples in a very well thermalized neutron spectrum. A bilateral collaboration project was carried out between the Jožef Stefan Institute (JSI, Slovenia) and the Commissariat à l’Énergie Atomique et aux Énergies Alternatives (CEA, France) to determine whether the JSI TRIGA reactor could be used for irradiations of samples for the FT-TIMS method. This paper describes Monte Carlo simulations, experimental activation measurements and test irradiations performed in the JSI TRIGA reactor, firstly to determine the feasibility, and secondly to design and qualify a purpose-built heavy water based irradiation device for FT-TIMS samples. The final device design has been shown experimentally to meet all the required performance specifications. [ABSTRACT FROM AUTHOR]

Published

2018

45. Comparison of relative INAA and k0-INAA using proficiency test materials at ITU TRIGA Mark II research reactor.

Author

Esen, Ayse Nur, Haciyakupoglu, Sevilay, and Erenturk, Sema

Subjects

*NUCLEAR activation analysis, *RADIOACTIVE substances, *RESEARCH reactors, *PLANT-soil relationships, *NUCLEAR energy

Abstract

Proficiency testing is an important way of evaluating the analytical method used in the laboratory. In recent years, neutron activation analysis studies performed in ITU TRIGA Mark II reactor comprised five proficiency tests organized by Wageningen evaluating programs for analytical laboratories. In this study, the results obtained by relative INAA and k0-INAA method for 16 elements in soil and plant samples are presented. Since both methods have some advantages compared to each other, the possible approach for the laboratory should be to combine relative INAA and k0-INAA results. [ABSTRACT FROM AUTHOR]

Published

2018

46. Leveraging Neutronics to Monitor Mass Transfer Corrosion in Lead and Lead-Bismuth Cooled Reactors

Author

Khaled Talaat and Osman Anderoglu

Subjects

inorganic chemicals, Cladding (metalworking), Liquid metal, Materials science, Nuclear engineering, technology, industry, and agriculture, General Engineering, chemistry.chemical_element, equipment and supplies, complex mixtures, Corrosion, TRIGA, Coolant, Nickel, chemistry, Mass transfer, otorhinolaryngologic diseases, General Materials Science, Dissolution

Abstract

Corrosion phenomena in heavy liquid metal cooled reactors primarily result from dissolution and mass transfer of alloying elements such as nickel from the structural materials to the coolant. We propose and preliminarily demonstrate an approach to passively monitor nickel dissolution in lead and lead-bismuth cooled reactors based on the effect of mass transfer on the neutronics. We support this suggestion with parametric simulations that demonstrate the effect of nickel transfer on reactivity in a modified TRIGA Mark-III reactor with steel cladding and lead coolant. Simulations of a uranium sphere show that nickel contributes a negative effect on the reactivity in the fast spectrum through parasitic absorption which is stronger than its effect on moderation. Transfer of nickel from the cladding to lead in the modified TRIGA reactor model results in removal of some of the nickel from the active core and significantly increases the total reactivity.

Published

2021

47. MAP OF RADIOISOTOPE PRODUCTION AND BATAN RESEARCH REACTOR UTILIZATION

Author

Endiah Puji Hastuti, TS Tukiran Surbakti, Geni Rina Sunaryo, Sudarmono Sudarmono, Suwoto Suwoto, Prasetyo Basuki, Syarip Syarip, and Iman Kuntoro

Subjects

Criticality, Nuclear engineering, TK9001-9401, Production (economics), Environmental science, Nuclear engineering. Atomic power, Ocean Engineering, Research reactor, TRIGA

Abstract

Currently, Indonesia through BATAN is operating three research reactors, namely the RSG-GAS reactor with the power of 30 MWt at Puspiptek south Tangerang (the first criticality in 1987), the TRIGA 2000 reactor with the power of 2 MW in Bandung which the first criticality in 1965 with the power of 250 kW, was increased to 1 MW in 1971, and further upgraded to 2 MW in 2000. Beside that, there is Kartini reactor with a power of 100 kW located in Yogyakarta (first criticality in 1979). These reactors are quite old, and in accordance with Bapeten regulations, have carried out the first periodic safety review, to obtain a reactor license for the next 10 years of operation. In line with this, one of BATAN's current national research programs is to increase the production of radioisotopes and radiopharmaceuticals, where reactors play a very important role in the production of certain isotopes. In tracing the data obtained from operational reports related to irradiation requests from reactor users, namely PTRR, PSTNT, and PT INUKI for radioisotope production, which has been carried out in the last 5 years, May 2015 until 25 August 2020, show that the irradiation request at RSG-GAS is still not optimal. In term of the utilization of RSG-GAS, it can still be optimized, which in this case needs to be balanced with post-irradiation processing capabilities. Meanwhile, from the results of tracing and data collection, it can be shown that at this time the reactors are still operating. The utilization activities of the reactors complement each other according to their age and facilities.

Published

2021

48. Thermal hydraulic design of irradiation facility based on O-16 (n,p) N-16 activation in TRIGA reactor

Author

Amano, Bernadeth Luzares and Končar, Boštjan

Subjects

obsevalna zanka, irradiation facility, TRIGA, water activation, CFD analysis, aktivacija vode, RDT analiza

Abstract

Water, typically used as the primary coolant in facilities such as fusion and fission reactors, could be exposed to a large amount of neutrons causing water activation. This phenomenon could cause radiation damage to electrical components and increase the dose to personnel. As there are only few sources of gamma rays with energies in the range of 6 MeV and 7 MeV, an irradiation system using activated cooling water as a source of energetic gamma rays is proposed at the Jozef Stefan Institute (JSI) TRIGA Mark II research reactor. A water activation irradiation loop design is proposed, inserted into a radial piercing port of a research reactor. In this thesis, a numerical model of the irradiation loop was developed and a CFD analysis was performed using ANSYS CFX. Pressure and velocity profiles were established and will serve as design limits and criteria reference for assembling the actual facility. Moreover, the N-16 concentration inside the loop was studied. Its formation and decay inside the loop were predicted. This shall serve as reference for future experimental designs and further studies to be conducted using the proposed facility. Voda s katero običajno hladimo fuzijske in fisijske reaktorje je lahko izpostavljena večji količini nevtronov in se pri tem aktivira. Sevanje zaradi aktivacije vode lahko povzroči poškodbe električnih komponent in poveča prejeto dozo za osebje. Ker obstaja le malo virov gama žarkov z energijami v območju med 6 MeV in 7 MeV, za preučevanje pojava na raziskovalnem reaktorju TRIGA Mark II na Institutu »Jožef Stefan« predlagajo obsevalni sistem z uporabo aktivirane vode kot vira gama žarkov. Predlagana je zasnova obsevalne zanke, ki je vstavljena v radialno odprtino raziskovalnega reaktorja. V tem magistrskem delu smo razvili numerični model obsevalne zanke in izvedli analizo s pomočjo programa za računalniško dinamiko tekočin (RDT) ANSYS CFX. Izračunali smo porazdelitve tlaka in hitrosti, ki bodo služile kot projektna osnova za dejansko izdelavo obsevalne zanke. Poleg tega smo proučevali obnašanje koncentracije izotopa dušika 16N v zanki. Pri tem smo upoštevali njegov nastanek in razpad znotraj zanke. Izračunane koncentracije dušika 16N bodo služile kot referenca za prihodnje zasnove eksperimentov in nadaljnje študije v predlagani obsevalni napravi.

Published

2022

49. Gamma-heating and gamma flux measurements in the JSI TRIGA reactor, results and prospects

Author

Gruel A., Ambrožič K., Destouches C., Radulović V., Sardet A., and Snoj L.

Subjects

caf2, gamma flux, ionization chamber, lif, triga, tld, Physics, QC1-999

Abstract

The neutron field of various irradiation positions of the TRIGA Mark II reactor of the Jožef Stefan Institute has been thoroughly characterized by neutron activation dosimetry and miniature fission chambers techniques. In order to have a fully validated calculation scheme to analyze and plan experiments, the gamma field also has to be experimentally validated. The 10-year long collaboration between CEA and JSI is a perfect framework to carry out such a study, and measurements of the gamma field started in late 2016. Several measurement techniques were investigated in in-core and ex-core positions. On-line measurements were carried out using miniature ionization chambers manufactured by the CEA and PTW Farmer ionization chambers. Positional dependence was studied, showing a decrease in the delayed gamma contribution to the total gamma flux with increasing distance from the reactor core center. To characterize the gamma dose in the core, as well as in the periphery, thermo- and optically stimulated luminescent detectors were tested. These detectors are commonly used at CEA to measure the gamma dose in a given material in order to study the nuclear heating in various core elements (control rod, baffle, structural material). Different filters were used in order to assess an integrated dose ranging from a few Gy up to several kGy. The feasibility of such measurements demonstrates the complementarity between measurements with dosimetry and ionization chambers from low to very high gamma-dose environment, such as in material testing reactors.

Published

2020

50. Radiation hardness studies and detector characterisation at the JSI TRIGA reactor

Author

Snoj L., Ambrožič K., Čufar A., Goričanec T., Jazbec A., Lengar I., Pungerčič A., Radulović V., Rupnik S., Štancar Ž., Žerovnik G., Žohar A., Cindro V., Kramberger G., Mandić I., Mikuž M., Barbot L., Carcreff H., Destouches C., Fourmentel D., Gruel A., and Villard J.F.

Subjects

triga, radiation hardness, detectors, testing, nuclear measurements, neutron radiation effects, gamma-ray effects, reactor instrumentation, Physics, QC1-999

Abstract

The JSI TRIGA reactor features several in-core and ex-core irradiation facilities, each having different properties, such as neutron/gamma flux intensity, spectra and irradiation volume. A series of experiments and calculations was performed in order to characterise radiation fields in irradiation channel thus allowing users to perform irradiations in a well characterised environment. Since 2001 the reactor has been heavily used for radiation hardness studies for components used at accelerators such as the Large Hadron Collider (LHC) at CERN. Since 2010 it has been extensively used for testing of new detectors and innovative data acquisition systems and methods developed and used by the CEA. Recently, several campaigns were initiated to characterise the gamma field in the reactor and use the experimental data for improvement of the treatment of delayed gammas in Monte Carlo particle transport codes. In the future it is planned to extend the testing options by employing pulse mode operation, installation of a high energy gamma ray irradiation facility and allow irradiation of larger samples at elevated temperature.

Published

2020