Search

Your search keyword '"Pungerčič, A."' showing total 38 results
Start Over Author "Pungerčič, A."
38 results on '"Pungerčič, A."'

3. JSI TRIGA fuel rod reactivity worth experiments for validation of Serpent-2 and RAPID fuel burnup calculations

Author

Anže Pungerčič, Alireza Haghighat, and Luka Snoj

Subjects
Burnup calculation, Experimental validation, TRIGA reactor, Reactivity measurements, Fission matrix, Nuclear engineering. Atomic power, TK9001-9401
Abstract

Reactivity worth of fuel rods at the JSI TRIGA research reactor was measured. Differently burned fuel rods were chosen to validate fuel burnup calculations. Two methods of measuring reactivity worth of fuel rods are used, traditional method is compared to newly introduced method using fuel rods swapping. Connection between both methods is described theoretically and the theory is validated experimentally. Fuel rod worth calculated using the newly introduced fuel rod swap method was within 1σ of worth measured using the traditional method. In addition to the recently performed experiments, weekly measurements of reactor core reactivity throughout the operational history are used for validation. The measured data were used to validate the fuel burnup and core criticality calculations. Fuel burnup calculations are performed using three different computer codes: the deterministic TRIGLAV, the Monte Carlo Serpent-2, and the hybrid RAPID. Great agreement was observed for Serpent-2 and RAPID by simulating fuel rod worth and its burnup, indicating that the fuel burnup and criticality calculations are accurate and that reactivity changes due to small burnup differences on the order of 10 pcm can be accurately simulated. In addition it was shown using ex-core detectors and large fission chamber that detector response changes due to fuel swapping are evident for fuel rod burnup differences of 20 MWd/kg. Fuel burnup calculations were further validated on excess reactivity measurements for three mixed TRIGA cores. The calculated burnup reactivity coefficient ΔρBU using Serpent-2 and RAPID was within 1σ of the measurements, showing both codes are capable of calculating burnup for different TRIGA fuel types.

Published
2024
Full Text
View/download PDF

6. Evaluation of reactor pulse experiments

Author

I. Švajger, D. Čalič, A. Pungerčič, A. Trkov, and L. Snoj

Subjects
TRIGA Mark II research reactor, pulse experiments, Fuchs-Hansen and Nordheim-Fuchs models, Improved Pulse Model, uncertainties of physical parameters of reactor pulse, Doppler broadening of resonances and neutron spectrum shift, Nuclear engineering. Atomic power, TK9001-9401
Abstract

In the paper we validate theoretical models of the pulse against experimental data from the Jozef Stefan Institute TRIGA Mark II research reactor. Data from all pulse experiments since 1991 have been collected, analysed and are publicly available. This paper summarizes the validation study, which is focused on the comparison between experimental values, theoretical predictions (Fuchs-Hansen and Nordheim-Fuchs models) and calculation using computational program Improved Pulse Model. The results show that the theoretical models predicts higher maximum power but lower total released energy, full width at half maximum and the time when the maximum power is reached is shorter, compared to Improved Pulse Model.We evaluate the uncertainties in pulse physical parameters (maximum power, total released energy and full width at half maximum) due to uncertainties in reactor physical parameters (inserted reactivity, delayed neutron fraction, prompt neutron lifetime and effective temperature reactivity coefficient of fuel). It is found that taking into account overestimated correlation of reactor physical parameters does not significantly affect the estimated uncertainties of pulse physical parameters. The relative uncertainties of pulse physical parameters decrease with increasing inserted reactivity. If all reactor physical parameters feature an uncorrelated uncertainty of 10 % the estimated total uncertainty in peak pulse power at 3 $ inserted reactivity is 59 %, where significant contributions come from uncertainties in prompt neutron lifetime and effective temperature reactivity coefficient of fuel. In addition we analyse contribution of two physical mechanisms (Doppler broadening of resonances and neutron spectrum shift) that contribute to the temperature reactivity coefficient of fuel. The Doppler effect contributes around 30 %–15 % while the rest is due to the thermal spectrum hardening for a temperature range between 300 K and 800 K.

Published
2024
Full Text
View/download PDF

7. 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
Full Text
View/download PDF

14. Identified Opportunities in Utilization of the European Research Reactor Fleet as a Part of the TOURR Project

Author

Pungerčič Anže, Cirillo Roberta, Walkiewicz Joanna, Novák Evžen, Gajewski Jacek, Szentmiklósi Laszlo, Van Puyvelde Lisanne, Starflinger Jörg, Cano Daniel, Pohlner Georg, Mikolajczak Renata, Pavel Gabriel, and Snoj Luka

Subjects
research reactor, tourr, european reactors, utilization, research reactor applications, Physics, QC1-999
Abstract

This paper discusses the current status of the European research reactor (RR) fleet and identified opportunities for its utilization. The data for this analysis was collected through a specific questionnaire from which a database of the European RR fleet was created. The questionnaire was designed to assess the degree of exploitation of different RR applications and to identify gaps and opportunities for future utilization. The results indicate that the European RR fleet is older compared to the world average, with no new research reactors built in Europe since 1992. The majority of RRs reported low levels of exploitation across all applications, and a desire to expand utilization was expressed by 78% of respondents. Lack of manpower, finance, and customers were identified as the main obstacles preventing expansion, while the need for more nuclear engineers was identified as a clear opportunity to attract people to the field. The findings of this study emphasize the need for actions to be taken to combat future needs and to improve the utilization of the European RR fleet. Overall, this study provides valuable insights for policymakers, industry professionals, and researchers working in the field of nuclear energy.

Published
2023
Full Text
View/download PDF

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

Author

Anže Pungerčič, Dušan Čalič, and Snoj Luka

Subjects
burnup, triga, reactivity, serpent-2, validation, triglav, Physics, QC1-999
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.

Published
2021
Full Text
View/download PDF

16. 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
monte carlo, triga, tripoli-4, mcnp, jeff, irdf, benchmark, fission chamber, fission rate, Physics, QC1-999
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.

Published
2021
Full Text
View/download PDF

17. 3-D thermal and radiation-matter interaction simulations of a SiC solid-state detector for neutron flux measurements in JSI TRIGA Mark II research reactor

Author

Valero V., Ottaviani L., Lyoussi A., Ghninou H., Radulović V., Snoj L., Pungerčič A., Volte A., Carette M., and Reynard-Carette C.

Subjects
neutron detection, silicon carbide, irradiation campaign, thermal, radiation-matter interaction, 3-d simulations, Physics, QC1-999
Abstract

Neutron detection is a relevant topic in the field of nuclear instrumentation. It is at the heart of the concerns for fusion applications (neutron diagnostics, measurements inside the Test Blanket Modules TBM) as well as for fission applications (in-core and ex-core monitoring, neutron mapping or safety applications in research reactors). Moreover, due to the even more harsh conditions of the future experimental reactors such as the Jules Horowitz Reactor (JHR) or International Thermonuclear Experimental Reactor (ITER), neutron detectors need to be adapted to high neutron and γ fluxes, high nuclear heating rates and high temperatures. Consequently, radiation and temperature hardened sensors with fast response, high energy resolution and stability in a mixed neutron and γ environment are required. All these requirements make wide-bandgap semiconductors and, more precisely, Silicon Carbide (SiC) serious candidates due to their intrinsic characteristics in such extreme environments. Thus, since the last decades, SiC-based detectors are developed and studied for neutron detection in various nuclear facilities. In this paper, a SiC-based neutron detector is 3-D designed and studied through thermal and radiation-matter interaction numerical simulations for a future irradiation campaign at the Jožef Stefan Institute TRIGA Mark II research reactor in Slovenia. Firstly, this paper presents the scientific background and issues of our SiC-based detectors. In a second part the 3-D geometry is shown. Thereafter, the 3-D numerical thermal simulation results are reported. Finally, the 3-D numerical radiation/matter interaction simulations results are presented.

Published
2021
Full Text
View/download PDF

18. Utilisation of JSI TRIGA Pulse Experiments for Testing of Nuclear Instrumentation and Validation of Transient Models

Author

Vavtar Ingrid, Pungerčič Anže, and Snoj Luka

Subjects
pulse experiments, fuchs-hansen model, nordheim-fuchs model, maximum power, total energy released, full width at half maximum, Physics, QC1-999
Abstract

A pulse experiment model was validated in order to support future pulse experimental campaigns. All pulse experiments data was collected and are publicly available at http://trigapulse.ijs.si/. A comparison of the measured pulse physical parameters (maximal power, total released energy and full width at half maximum) and theoretical predictions (Fuchs-Hansen and the Nordheim-Fuchs models) was made.

Published
2020
Full Text
View/download PDF

19. 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
Full Text
View/download PDF

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

Author

Žohar Andrej, Pungerčič Anže, Ambrožič Klemen, Radulović Vladimir, Jazbec Anže, Rupnik Sebastjan, Lengar Igor, and Snoj Luka

Subjects
activated cooling water, monte carlo, triga, irradiation facility, Physics, QC1-999
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.

Published
2020
Full Text
View/download PDF

21. 3-D thermal and radiation-matter interaction simulations of a SiC solid-state detector for neutron flux measurements in JSI TRIGA Mark II research reactor

Author

Abdallah Lyoussi, Laurent Ottaviani, V. Valero, M. Carette, A. Volte, Luka Snoj, C. Reynard-Carette, H. Ghninou, Anže Pungerčič, and Vladimir Radulović

Subjects
Materials science, Thermonuclear fusion, 3-d simulations, Nuclear engineering, Physics, QC1-999, radiation-matter interaction, Radiation, neutron detection, TRIGA, thermal, chemistry.chemical_compound, chemistry, Neutron flux, silicon carbide, Silicon carbide, Neutron detection, Research reactor, Neutron, irradiation campaign
Abstract

Neutron detection is a relevant topic in the field of nuclear instrumentation. It is at the heart of the concerns for fusion applications (neutron diagnostics, measurements inside the Test Blanket Modules TBM) as well as for fission applications (in-core and ex-core monitoring, neutron mapping or safety applications in research reactors). Moreover, due to the even more harsh conditions of the future experimental reactors such as the Jules Horowitz Reactor (JHR) or International Thermonuclear Experimental Reactor (ITER), neutron detectors need to be adapted to high neutron and γ fluxes, high nuclear heating rates and high temperatures. Consequently, radiation and temperature hardened sensors with fast response, high energy resolution and stability in a mixed neutron and γ environment are required. All these requirements make wide-bandgap semiconductors and, more precisely, Silicon Carbide (SiC) serious candidates due to their intrinsic characteristics in such extreme environments. Thus, since the last decades, SiC-based detectors are developed and studied for neutron detection in various nuclear facilities. In this paper, a SiC-based neutron detector is 3-D designed and studied through thermal and radiation-matter interaction numerical simulations for a future irradiation campaign at the Jožef Stefan Institute TRIGA Mark II research reactor in Slovenia. Firstly, this paper presents the scientific background and issues of our SiC-based detectors. In a second part the 3-D geometry is shown. Thereafter, the 3-D numerical thermal simulation results are reported. Finally, the 3-D numerical radiation/matter interaction simulations results are presented.

Published
2021

22. Molecular genetics of suicide

Author

Alja Videtič and Galina Pungerčič

Subjects
suicide, serotonin, dopamine, polymorphism, genetics, Medicine
Abstract

Background: Suicide is a complex phenomenon that is triggered by environmental factors, and probably partially also by genetic code. Genetic studies performed on suicide brain contributed interesting findings on serotonergic, dopaminergic and noradrenergic neurotransmitter systems and on cholesterol system as well as on cell morphology of the brain.Conclusions: Despite numerous results from studies on particular subpopulations (particular psychiatric diseases, gender, etc.) supporting or rejecting association of polymorphisms and suicide, the complexity of suicidal genetics, as in most of the behavioral traits, seems to result as a consequence of more complicated undisclosed mechanisms of interactions of a larger number of genes.

Published
2006

24. The Marfan syndrome genetics

Author

Galina Pungerčič

Subjects
Marfan syndrome, fibrillin-1, connective tissue, mutations, heritable disorder, Medicine
Abstract

Background: The Marfan syndrome is an autosomal dominant heritable disorder of connective tissue. It is caused by mutations in the fibrillin-1 gene encoding glycoprotein fibrillin-1, a component of microfibrils of extracellular matrix. Patients with Marfan syndrome show wide spectra of clinical signs, primarily on skeletal, cardiovascular and ocular organ systems. Cardiovascular complications (especially aortic aneurysm and aortic dissection) are the most common cause of mortality of Marfan syndrome patients. Discovering genotype-phenotype correlations is complicated because of the large number of mutations reported as well as clinical heterogeneity among individuals with the same mutation. Despite the progress in the knowledge of the molecular nature of Marfan syndrome the diagnosis is still based mainly on the clinical features in the different body systems.Conclusions: Early identification of patient with Marfan syndrome is of considerable importance because of appropriate treatment that can greatly improve life expectancy. Unfortunately, despite the improvement of diagnostic methods, medical and surgical therapy, the mortality due to undiagnosed Marfan syndrome is still high. The present article reviews the molecular genetic studies of Marfan syndrome since the discovery of the mutations in the fibrillin-1 gene.

Published
2005

25. Utilisation of JSI TRIGA Pulse Experiments for Testing of Nuclear Instrumentation and Validation of Transient Models

Author

I. Vavtar, Anže Pungerčič, and Luka Snoj

Subjects
fuchs-hansen model, Maximum power principle, 010308 nuclear & particles physics, maximum power, 020209 energy, Instrumentation, Nuclear engineering, Physics, QC1-999, total energy released, 02 engineering and technology, 01 natural sciences, full width at half maximum, TRIGA, Power (physics), Pulse (physics), Full width at half maximum, pulse experiments, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Transient (oscillation), nordheim-fuchs model, Energy (signal processing)
Abstract

A pulse experiment model was validated in order to support future pulse experimental campaigns. All pulse experiments data was collected and are publicly available at http://trigapulse.ijs.si/. A comparison of the measured pulse physical parameters (maximal power, total released energy and full width at half maximum) and theoretical predictions (Fuchs-Hansen and the Nordheim-Fuchs models) was made.

Published
2020

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

Author

Hubert Carcreff, Luka Snoj, Vladimir Cindro, Marko Mikuž, Anže Pungerčič, Igor Lengar, Aljaž Čufar, Loïc Barbot, J. F. Villard, Gregor Kramberger, Damien Fourmentel, Tanja Goričanec, A. Gruel, Anže Jazbec, Žiga Štancar, Christophe Destouches, Vladimir Radulović, Klemen Ambrožič, Sebastjan Rupnik, Igor Mandić, Gašper Žerovnik, and Andrej Žohar

Subjects
Materials science, Large Hadron Collider, Physics::Instrumentation and Detectors, Nuclear engineering, Physics, QC1-999, Monte Carlo method, Detector, Radiation, neutron radiation effects, radiation hardness, testing, TRIGA, nuclear measurements, reactor instrumentation, Neutron, Irradiation, triga, gamma-ray effects, Radiation hardening, detectors
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

27. 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
Full Text
View/download PDF

28. Analiza zgorelosti gorivnih elementov reaktorja TRIGA

Author

Pungerčič, Anže and Snoj, Luka

Subjects
core configuration, Monte Carlo metoda, raziskovalni reaktor TRIGA, polnitvena shema, fuel burnup, excess reactivity, fission reactor, fisijski reaktor, razcepni produkti, reactor operation, Monte Carlo method, TRIGA Mark II, research reactor, nuclear fuel isotopic composition, zgorevanje goriva, fission products, presežna reaktivnost, deterministična metoda, deterministic method, obratovanje reaktorja, porazdelitev izotopov, izotopska sestava goriva, isotope distribution
Abstract

V magistrskem delu je predstavljena analiza zgorevanja jedrskega goriva v raziskovalnem reaktorju TRIGA Mark II, ki pod okriljem Instituta Jožef Stefan obratuje že od leta 1966 in igra pomembno vlogo pri razvoju jedrske tehnologije v Sloveniji. V tem času je bilo uporabljenih 300 različnih gorivnih elementov, razvrščenih v 220 polnitvenih shem reaktorske sredice. Z zgorevanjem goriva se zaradi jedrskih reakcij spreminja izotopska sestava goriva. V kolikor želimo določiti končno izotopsko sestavo goriva, moramo natančno poznati obratovalno zgodovino reaktorja. V ta namen smo skonstruirali model obratovalne zgodovine, ki vsebuje spremembe moči reaktorja, polnitvene sheme in meritve presežne reaktivnosti. Razvili smo metodologijo, ki avtomatizirano upošteva celotno zgodovino reaktorja TRIGA in omogoča izračune zgorelosti posameznih gorivnih elementov. Celotno obratovalno zgodovino smo izračunali z deterministično in stohastično metodo. Prva rešuje transportno enačbo nevtronov, medtem ko pri drugi simuliramo vsak nevtron posebej in z vzorčenjem velikega števila simulacij pridobimo informacije o populaciji nevtronov. Med seboj smo primerjali končne zgorelosti posameznih gorivnih elementov, izračunane z obema programoma in pri večini opazili dobro ujemanje. Pri nekaterih smo pa opazili razlike višje od 20 %. Ugotovili smo, da so bili to tisti elementi, ki so bili po rekonstrukciji reaktorja leta 1991 vstavljeni skupaj z že zgorelimi gorivnimi elementi. V ta namen smo naredili občutljivostno analizo vpliva starih gorivnih elementov in ugotovili, da je maksimalni vpliv na zgorelost sedanjih gorivnih elementov 5 %. Ostalo odstopanje pa je posledica pomanjkljivosti difuzijske aproksimacije. Izračunane spremembe reaktivnosti sredice zaradi zgorevanja goriva, smo primerjali z meritvami presežne reaktivnosti za celotno zgodovino, kjer se je končna napoved reaktivnosti razlikovala od meritev le za 200 pcm, kar je manj kot 10 %. Zanimalo nas je kateri izotopi vplivajo na spremembo reaktivnosti. V ta namen smo z Monte Carlo metodo naredili občutljivostno analizo vpliva posameznih izotopov, kjer smo ugotovili, da ima največji negativni vpliv Xe-135 in velik pozitivni vpliv Pu-239. Vrednosti 20 pomembnih izotopov smo primerjali z rezultati, pridobljenimi z determinističnimi izračuni v preteklosti, in opazili dobro ujemanje obeh metod. Za konec smo z Monte Carlo metodo določili še prostorsko porazdelitev izotopov znotraj gorivnega elementa in spremembo nevtronskega spektra zaradi zgorevanja goriva, kjer smo ugotovili znižanje fluksa termičnih nevtronov za 10 % pri zgorelem gorivu. This master thesis focuses on the determination of nuclear fuel burnup for the TRIGA Mark II research reactor at the Jožef Stefan Institute. The reactor has been operating since 1966 and has been playing an important role in developing nuclear technology and safety culture in Slovenia. During this period 300 different fuel elements were used, arranged in 220 core configurations. In order to determine the current isotopic composition of each fuel element we initiated activities to thoroughly document and analyse complete operation history. From the data regarding changes in reactor power, core configurations and measuremets of excess reactivity, we constructed a complete operational model, which could be used as an experimental benchmark for testing and validation of neutron transport and burnup codes. Complete operational history of the reactor was simulated with the deterministic method, which solves diffusion approximation of the neutron transport equation. Operational history after the reconstruction in 1991 was calculated with stochastic Monte Carlo, which simulates high number of individual neutrons and by sampling calculates the needed information about our system. Clear correspondence is observed from the comparison of final fuel element burnup, calculated with both codes. The discrepancies were 5 %, except for around 20 fuel elements where the discrepancies were above 20 %. The reason for this is that the mentioned fuel elements were mixed together with the old already burned ones after the reconstruction of the reactor in 1991. For the further analysis of the discrepancies we performed a sensibility study of the effects of old fuel elements, and found that they contribute up to 5 %. The rest is because of the diffusion approximation in deterministic calculations. The calculated changes in core reactivity due to burnup, clearly matches the ones measured during reactor operation and the discrepancy between measured and calculated core reactivity for final core configuration in 2017 is only 200 pcm or below 10 %. Furthermore the effect of individual isotopes on core reactivity was studied with the Monte Carlo method, where the largest negative contribution is due to Xe-135 build-up and the only visible positive contribution due to Pu-239. The results for 20 important isotopes were compared with deterministic calculations performed in the past, where clear correspondence between both methods is observed. In the end Monte Carlo method was used to determined isotope distribution inside each type of fuel element, together with changes in neutron spectrum due to burnup, where the thermal peak of burned fuel is lower for around 10 %.

Published
2018

30. Utilisation of JSI TRIGA Pulse Experiments for Testing of Nuclear Instrumentation and Validation of Transient Models.

Author

Lyoussi, A., Giot, M., Carette, M., Jenčič, I., Reynard-Carette, C., Vermeeren, L., Snoj, L., Le Dû, P., Vavtar, Ingrid, Pungerčič, Anže, and Snoj, Luka

Subjects
URANIUM, RADIATION dosimetry, NEUTRON sources, NEUTRON flux, ACQUISITION of data
Abstract

A pulse experiment model was validated in order to support future pulse experimental campaigns. All pulse experiments data was collected and are publicly available at http://trigapulse.ijs.si/. A comparison of the measured pulse physical parameters (maximal power, total released energy and full width at half maximum) and theoretical predictions (Fuchs-Hansen and the Nordheim-Fuchs models) was made. [ABSTRACT FROM AUTHOR]

Published
2020
Full Text
View/download PDF

31. 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
Full Text
View/download PDF

33. Nepotizem

Author

Pungerčič, Barbara and Mesner-Andolšek, Dana

Subjects
udc:331.1(043), nepotizem, nepotism
Published
2014

34. JSI TRIGA fuel rod reactivity worth experiments for validation of Serpent-2 and RAPID fuel burnup calculations

Author

Pungerčič, Anže, Haghighat, Alireza, and Snoj, Luka

Abstract

Reactivity worth of fuel rods at the JSI TRIGA research reactor was measured. Differently burned fuel rods were chosen to validate fuel burnup calculations. Two methods of measuring reactivity worth of fuel rods are used, traditional method is compared to newly introduced method using fuel rods swapping. Connection between both methods is described theoretically and the theory is validated experimentally. Fuel rod worth calculated using the newly introduced fuel rod swap method was within 1σof worth measured using the traditional method. In addition to the recently performed experiments, weekly measurements of reactor core reactivity throughout the operational history are used for validation. The measured data were used to validate the fuel burnup and core criticality calculations. Fuel burnup calculations are performed using three different computer codes: the deterministic TRIGLAV, the Monte Carlo Serpent-2, and the hybrid RAPID. Great agreement was observed for Serpent-2 and RAPID by simulating fuel rod worth and its burnup, indicating that the fuel burnup and criticality calculations are accurate and that reactivity changes due to small burnup differences on the order of 10 pcm can be accurately simulated. In addition it was shown using ex-core detectors and large fission chamber that detector response changes due to fuel swapping are evident for fuel rod burnup differences of 20 MWd/kg. Fuel burnup calculations were further validated on excess reactivity measurements for three mixed TRIGA cores. The calculated burnup reactivity coefficient ΔρBUusing Serpent-2 and RAPID was within 1σof the measurements, showing both codes are capable of calculating burnup for different TRIGA fuel types.

Published
2024
Full Text
View/download PDF

36. Genetika Marfanovega sindroma: The Marfan syndrome genetics

Author

Pungerčič, Galina

Abstract

Background. The Marfan syndrome is an autosomal dominant heritable disorder ofconnective tissue. It is caused by mutations in the fibrillin-1 gene encoding glycoprotein fibrillin-1, a component of microfibrils of extracellular matrix. Patients with Marfan syndrome show wide spectra of clinical signs, primarily on skeletal, cardiovascular and ocular organ systems. Cardiovascular complications (especially aortic aneurysm and aortic dissection) are the most common cause of mortality of Marfan syndrome patients. Discovering genotype-phenotype correlations is complicated because of the large number of mutations reported as well as clinical heterogeneity among individuals with the same mutation. Despite the progress in the knowledge of the molecular nature of Marfan syndrome the diagnosis is still based mainly on the clinical features in the different body systems. Conclusions. Early identification of patient with Marfan syndrome is of considerable importance because of appropriate treatment that can greatly improve life expectancy. Unfortunately, despite the improvement of diagnostic methods, medical and surgical therapy, the mortality due to undiagnosed Marfansyndrome is still high. The present article reviews the molecular genetic studies of Marfan syndrome since the discovery of the mutations in thefibrillin-1 gene. Izhodišča. Marfanov sindrom (MFS) je dedna bolezen vezivnega tkiva, ki se deduje avtosomno dominantno. Povzročajo ga mutacije v genu za glikoprotein fibrilin-1, ki je sestavni del mikrofibrilov zunajceličnega matriksa. Bolniki z Marfanovim sindromom kažejo širok spekter kliničnih znakov. Najpogostejše sospremembe na skeletu, srčno-žilnem sisstemu in očeh. Srčno-žilne težave (predvsem anevrizma in disekcija aorte) so najpogostejši vzroki za zgodnjo smrtnost teh bolnikov. Odkrivanje povezanosti genotipa s fenotipom je zapleteno zaradi velikega števila mutacij in tudi zaradi heterogene klinične slike bolnikov z enako mutacijo. Zato je diagnosticiranje MFS kljub napredku vznanju o molekularni naravi Marfanovega sindroma še vedno skoraj izključno napodlagi kliničnih znakov v različnih delih telesa. Zaključki. Zgodnje odkrivanje bolnikov z MFS je pomembno zaradi pravočasnega zdravljenja, ki lahko znatno izboljša pričakovano trajanje življenja. Žal pa je kljub napredkuv diagnostičnih metodah, medikamentnem in operativnem zdravljenju MFS smrtnost zaradi nepravočasno diagnosticirane bolezni še vedno visoka. Prispevek prikazuje pregled molekularnogenetskih študij MFS od odkritja sprememb v genu za fibrilin-1 do danes.

Published
2005

Catalog

Books, media, physical & digital resources
See catalog results