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31	Análises neutrônica e termo-hidráulica de um dispositivo para irradiação de alvos tipo LEU de UAlsub(x-)Al para produção de sup(99)Mo no reator IEA-R1 / Neutronic and thermal-hydraulic analysis of a device for irradiation of LEU UAlsub(x-)Al targets for de sup(99)Mo production in the IEA-R1 reactor NISHIYAMA, PEDRO J.B. de O. 09 October 2014 (has links) Made available in DSpace on 2014-10-09T12:35:26Z (GMT). No. of bitstreams: 0 / Made available in DSpace on 2014-10-09T14:05:40Z (GMT). No. of bitstreams: 0 / Dissertação (Mestrado) / IPEN/D / Instituto de Pesquisas Energeticas e Nucleares - IPEN-CNEN/SP IEAR-1 REACTOR SLIGHTLY ENRICHED URANIUM ISOTOPE PRODUCTION MOLIBDENUM 99 NEUTRONS THERMAL HYDRAULICS THERMAL ANALYSIS S CODES
32	Impacto da redução na concentração de Urânio nas placas laterais dos elementos combustíveis do reator IEA-R1 nas análises neutrônica e termo-hidráulica / Uranium density reduction on fuel element side plates assessment RIOS, ILKA A. 09 October 2014 (has links) Made available in DSpace on 2014-10-09T12:33:05Z (GMT). No. of bitstreams: 0 / Made available in DSpace on 2014-10-09T14:06:06Z (GMT). No. of bitstreams: 0 / Dissertação (Mestrado) / IPEN/D / Instituto de Pesquisas Energeticas e Nucleares - IPEN-CNEN/SP IEAR-1 REACTOR FUEL ELEMENTS URANIUM FUEL PLATES REDUCTION NEUTRONS THERMAL HYDRAULICS THERMAL ANALYSIS H CODES C CODES
33	Análises neutrônica e termo-hidráulica de um dispositivo para irradiação de alvos tipo LEU de UAlsub(x-)Al para produção de sup(99)Mo no reator IEA-R1 / Neutronic and thermal-hydraulic analysis of a device for irradiation of LEU UAlsub(x-)Al targets for de sup(99)Mo production in the IEA-R1 reactor NISHIYAMA, PEDRO J.B. de O. 09 October 2014 (has links) Made available in DSpace on 2014-10-09T12:35:26Z (GMT). No. of bitstreams: 0 / Made available in DSpace on 2014-10-09T14:05:40Z (GMT). No. of bitstreams: 0 / Tecnécio-99m (99mTc), o produto de decaimento do molibdênio-99 (99Mo), é um dos radioisótopos mais utilizados na medicina nuclear, abrangendo cerca de 80% de todos os procedimentos de radiodiagnóstico médico pelo mundo. Atualmente o Brasil necessita de uma quantidade de aproximadamente 450 Ci de 99Mo por semana. Devido à crise e à escassez em seu fornecimento que vem sendo observada no cenário mundial desde 2008, o IPEN decidiu desenvolver um projeto próprio para produção de 99Mo através da fissão do urânio-235. O objetivo deste trabalho de dissertação foi desenvolver cálculos neutrônicos e temo-hidráulicos para avaliar a segurança operacional de um dispositivo para produção de 99Mo a ser irradiado no núcleo do reator IEA-R1. Neste dispositivo serão alojados dez alvos do tipo dispersão de UAlx-Al com baixo enriquecimento de urânio (LEU) e densidade de 2,889 gU/cm³. Para o cálculo neutrônico foram utilizados os programas computacionais HAMMER-TECHNION e CITATION e as temperaturas máximas atingidas nos alvos foram calculadas com o código MTRCR-IEAR1. Os cálculos demonstram que a irradiação do dispositivo deverá ocorrer sem consequências adversas à operação do reator. A quantidade total de 99Mo foi calculada com o programa SCALE e considerando que o tempo necessário para o processamento químico e recuperação do 99Mo será de cinco dias após a irradiação, teremos disponível para distribuição uma atividade de 99Mo de 176 Ci para 3 dias de irradiação, 236 Ci para 5 dias de irradiação e 272 Ci para 7 dias de irradiação dos alvos. / Dissertação (Mestrado) / IPEN/D / Instituto de Pesquisas Energeticas e Nucleares - IPEN-CNEN/SP iear-1 reactor slightly enriched uranium isotope production molybdenum 99 neutrons thermal hydraulics thermal analysis s codes
34	Impacto da redução na concentração de Urânio nas placas laterais dos elementos combustíveis do reator IEA-R1 nas análises neutrônica e termo-hidráulica / Uranium density reduction on fuel element side plates assessment RIOS, ILKA A. 09 October 2014 (has links) Made available in DSpace on 2014-10-09T12:33:05Z (GMT). No. of bitstreams: 0 / Made available in DSpace on 2014-10-09T14:06:06Z (GMT). No. of bitstreams: 0 / Neste trabalho, propõe-se um estudo para verificação do impacto da redução na concentração de urânio nas placas laterais dos elementos combustíveis do reator IEA-R1, nas análises neutrônica e termo-hidráulica. Ao se desenvolver o referido trabalho, reproduziu-se estudo conduzido anteriormente pelo IPEN-CNEN/SP, simulando a queima de elementos combustíveis, cujas placas laterais apresentam densidade de urânio reduzida para 50, 60 e 70% em relação às demais placas do elemento combustível. Tal estudo inicia-se com a análise neutrônica, cujo primeiro passo é o cálculo das seções de choque dos materiais presentes no núcleo a partir de suas concentrações iniciais, com a utilização do código computacional HAMMER; o segundo passo é o cálculo dos fluxos de nêutrons dos grupos rápido e térmico e das densidades de potência nos elementos combustíveis estudados em modelagem do núcleo feita no código computacional CITATION, que utiliza os dados gerados pelo HAMMER. Terminada a análise neutrônica e definidos os elementos combustíveis mais críticos com maior densidade de potência, executa-se a análise termo-hidráulica, que utiliza o modelo termo-hidráulico MCTR-IEA-R1, o qual é baseado no pacote comercial EES. A densidade de potência gerada pelo CITATION é utilizada como dado de entrada da análise termo-hidráulica nas equações de balanço de energia do modelo para o cálculo das temperaturas nos pontos de interesse. Neste trabalho, é feita a comparação da operação do reator com três diferentes densidades de urânio nas placas laterais. Concluiu-se que a redução da densidade de urânio contribui para que a temperatura da superfície do revestimento não ultrapasse o limite estabelecido como condição de operação do reator; não há impacto significativo na queima final dos elementos combustíveis, nem na reatividade do reator IEA-R1. A redução de urânio nas placas laterais dos elementos combustíveis do reator IEA-R1 mostrou ser uma opção viável para evitar problemas de corrosão devido a altas temperaturas. / Dissertação (Mestrado) / IPEN/D / Instituto de Pesquisas Energeticas e Nucleares - IPEN-CNEN/SP iear-1 reactor fuel elements uranium fuel plates reduction neutrons thermal hydraulics thermal analysis h codes c codes
35	An Experimental Facility for Studying Heat Transfer in Supercritical Fluids Jiang, Kai January 2015 (has links) A state-of-art research facility has been built at the University of Ottawa, which is suitable for thermalhydraulic experiments in support of the development of the Canadian Supercritical-Water-Cooled Reactor (SCWR). The facility is a recirculating flow loop, using carbon dioxide as a medium and having three different test sections, two tubes with inner diameters of 8 and 22 mm, respectively, and a three-rod bundle. The loop can operate within ranges of pressure, temperature, heat flux and mass flux, which are of interest to the current SCWR design. The present thesis includes a comprehensive description of the facility. It also documents the procedure and results of its commissioning, as well as some preliminary measurements that have been collected so far. It is intended to provide an insight to the design of the facility and its functionality and to serve as a reference for future research activities. A number of tests performed by previous researchers in other facilities were replicated and nearly identical results were obtained. It was demonstrated that the design of the facility is sound and its performance is adequate within the intended ranges of operation conditions. It is expected that the results obtained in this facility will make a significant contribution to the understanding of supercritical heat transfer and pressure losses in the SCWR context. Nuclear Power Heat Transfer Supercritical Fluids Fluid Dynamics Experimentation Reactor Cooling Thermal Hydraulics Research Facility Nuclear Energy
36	Validierung des gekoppelten neutronenkinetischen-thermohydraulischen Codes ATHLET/DYN3D mit Hilfe von Messdaten des OECD Turbine Trip Benchmarks Kliem, Sören, Grundmann, Ulrich January 2003 (has links) Das Vorhaben bestand in der Validierung des gekoppelten neutronenkinetisch-thermohydraulischen Programmkomplexes ATHLET/DYN3D für Siedewasserreaktoren durch Teilnahme an dem OECD/NRC Benchmark zum Turbinenschnellschluss. Das von der OECD und der amerikanischen NRC definierte Benchmark basiert auf einem Experiment mit Schließens des Turbinenschnellschlussventils, das 1977 im Rahmen einer Serie von 3 Experimenten im Kernkraftwerk Peach Bottom 2 durchgeführt wurde. Im Experiment erzeugte das Schließen des Ventils eine Druckwelle, die sich unter Abschwächung bis in den Reaktorkern ausbreitete. Die durch den Druckanstieg bewirkte Kondensation von Dampf im Reaktorkern führte zu einem positiven Reaktivitätseintrag. Der folgende Anstieg der Reaktorleistung wurde durch die Rückkopplung und das Einfahren der Regelstäbe begrenzt. Im Rahmen des Benchmarks konnten die Rechenprogramme durch Vergleiche mit den Messergebnissen und den Ergebnissen der anderen Teilnehmer an dem Benchmark validiert werden. Das Benchmark wurde in 3 Phasen oder Exercises eingeteilt. Die Phase I diente der Überprüfung des thermohydraulischen Modells für das System bei vorgegebener Leistungsfreisetzung im Kern. In der Phase II wurden 3-dimensionale Berechnungen des Reaktorkerns für vorgegebene thermohydraulische Randbedingungen durchgeführt. Die gekoppelten Rechnungen für das ausgewählte Experiment und für 4 extreme Szenarien erfolgten in der Phase III. Im Rahmen des Projekts nahm FZR an Phase II und Phase III des Benchmarks teil. Die Rechnungen für Phase II erfolgten mit dem Kernmodell DYN3D unter Berücksichtigung der Heterogenitätsfaktoren und mit 764 thermohydraulischen Kanälen (1 Kanal/Brennelement). Der ATHLET-Eingabedatensatz für die Reaktoranlage wurde von der Gesellschaft für Anlagen- und Reaktorsicherheit (GRS) übernommen und für die Rechnungen zu Phase III, die mit der parallelen Kopplung von ATHLET mit DYN3D erfolgten, geringfügig modifiziert. Für räumlich gemittelte Parameter wurde eine gute Übereinstimmung mit den Messergebnissen und den Resultaten anderer Codes erzielt. Der Einfluss der Modellunterschiede wurde mit Hilfe von Variantenrechnungen zu Phase II untersucht. So können Unterschiede in der Leistungs- und Voidverteilung in einzelnen Brennelementen auf die unterschiedliche neutronenkinetische und thermohydraulische Modellierung des Reaktorkerns zurückgeführt werden. Vergleiche zwischen ATHLET/DYN3D (parallele Kopplung) und ATHLET/QUABOX-CUBBOX (interne Kopplung) zeigen für räumlich gemittelte Parameter nur geringe Unterschiede. Abweichungen in den lokalen Parametern können im wesentlichen mit der unterschiedlichen Modellierung des Reaktorkerns erklärt werden (geringere Anzahl von modellierten Kühlkanälen, keine Berücksichtigung der Heterogenitätsfaktoren und ein anderes Siedemodell in der Rechnung mit ATHLET/QUABOX-CUBBOX). Die Rechnungen für die extremen Szenarien von Phase III zeigen die Anwendbarkeit des gekoppelten Programms ATHLET/DYN3D für die Bedingungen bei Störfällen, die weit über das Experiment hinausgehen.
37	Qualifizierung des Kernmodells DYN3D im Komplex mit dem Störfallcode ATHLET als fortgeschrittenes Werkzeug für die Störfallanalyse von WWER-Reaktoren - Teil 2 Kliem, S., Grundmann, U., Rohde, U. January 2002 (has links) Benchmark calculations for the validation of the coupled neutron kinetics/thermohydraulic code complex DYN3D-ATHLET are described. Two benchmark problems concerning hypothetical accident scenarios with leaks in the steam system for a VVER-440 type reactor and the TMI-1 PWR have been solved. The first benchmark task has been defined by FZR in the frame of the international association "Atomic Energy Research" (AER), the second exercise has been organised under the auspices of the OECD. While in the first benchmark the break of the main steam collector in the sub-critical hot zero power state of the reactor was considered, the break of one of the two main steam lines at full reactor power was assumed in the OECD benchmark. Therefore, in this exercise the mixing of the coolant from the intact and the defect loops had to be considered, while in the AER benchmark the steam collector break causes a homogeneous overcooling of the primary circuit. In the AER benchmark, each participant had to use its own macroscopic cross section libraries. In the OECD benchmark, the cross sections were given in the benchmark definition. The main task of both benchmark problems was to analyse the re-criticality of the scrammed reactor due to the overcooling. For both benchmark problems, a good agreement of the DYN3D-ATHLET solution with the results of other codes was achieved. Differences in the time of re-criticality and the height of the power peak between various solutions of the AER benchmark can be explained by the use of different cross section data. Significant differences in the thermohydraulic parameters (coolant temperature, pressure) occurred only at the late stage of the transient during the emergency injection of highly borated water. In the OECD benchmark, a broader scattering of the thermohydraulic results can be observed, while a good agreement between the various 3D reactor core calculations with given thermohydraulic boundary conditions was achieved. Reasons for the differences in the thermohydraulics were assumed in the difficult modelling of the vertical once-through steam generator with steam superheating. Sensitivity analyses which considered the influence of the nodalisation and the impact of the coolant mixing model were performed for the DYN3D-ATHLET solution of the OECD benchmark. The solution of the benchmarks essentially contributed to the qualification of the code complex DYN3D-ATHLET as an advanced tool for the accident analysis for both VVER type reactors and Western PWRs.
38	Coupling between Monte Carlo neutron transport and thermal-hydraulics for the simulation of transients due to reactivity insertions / Couplage entre la simulation neutronique Monte-Carlo et la thermo-hydraulique pour les transitoires liés à des insertions de réactivité Faucher, Margaux 18 October 2019 (has links) Dans le contexte de la physique des réacteurs, l’analyse du comportement non stationnaire de la population neutronique avec contre-réactions dans le combustible et dans le modérateur se rend indispensable afin de caractériser les transitoires opérationnels et accidentels dans les systèmes nucléaires et d’en améliorer par conséquent la sûreté. Pour ces configurations non stationnaires, le développement de méthodes Monte-Carlo qui prennent en compte la dépendance en temps du système neutronique, mais aussi le couplage avec les autres physiques, comme la thermohydraulique et la thermomécanique, a pour but de servir de référence aux calculs déterministes.Ce travail de thèse a consisté à mettre en place une chaîne de calcul pour la simulation couplée neutronique Monte-Carlo, avec le code TRIPOLI-4, en conditions non stationnaires et avec prise en compte des contre-réactions thermohydrauliques.Nous avons d'abord considéré les méthodes cinétiques dans TRIPOLI-4, c'est-à-dire avec prise en compte du temps mais sans prise en compte des contre-réactions, en incluant une évaluation des méthodes existantes ainsi que le développement de nouvelles méthodes. Ensuite, nous avons développé un schéma de couplage entre TRIPOLI-4 et le code de thermohydraulique sous-canal SUBCHANFLOW. Enfin, nous avons réalisé une analyse préliminaire de la propagation des incertitudes au sein du calcul couplé sur un modèle simplifié. En effet, les fluctuations statistiques sont inhérentes à notre schéma de par la nature stochastique de TRIPOLI-4. De plus, les équations de la thermohydraulique étant non-linéaires, la propagation des incertitudes au long du calcul doit être étudiée afin de caractériser la convergence du résultat. / One of the main issues for the study of a reactor behaviour is to model the propagation of the neutrons, described by the Boltzmann transport equation, in the presence of multi-physics phenomena, such as the coupling between neutron transport, thermal-hydraulics and thermomecanics. Thanks to the growing computer power, it is now feasible to apply Monte Carlo methods to the solution of non-stationary transport problems in reactor physics, which play an instrumental role in producing reference numerical solutions for the analysis of transients occurring during normal and accidental behaviour.The goal of this Ph. D. thesis is to develop, verify and test a coupling scheme between the Monte Carlo code TRIPOLI-4 and thermal-hydraulics, so as to provide a reference tool for the simulation of reactivity-induced transients in PWRs.We have first tested the kinetic capabilities of TRIPOLI-4 (i.e., time dependent without thermal-hydraulics feedback), evaluating the different existing methods and implementing new techniques. Then, we have developed a multi-physics interface for TRIPOLI-4, and more specifically a coupling scheme between TRIPOLI-4 and the thermal-hydraulics sub-channel code SUBCHANFLOW. Finally, we have performed a preliminary analysis of the stability of the coupling scheme. Indeed, due to the stochastic nature of the outputs produced by TRIPOLI-4, uncertainties are inherent to our coupling scheme and propagate along the coupling iterations. Moreover, thermal-hydraulics equations are non linear, so the prediction of the propagation of the uncertainties is not straightforward. Thermohydraulique Dynamique Simulation Monte-Carlo Multiphysique Transitoires Neutronique Thermal-Hydraulics Dynamic Monte Carlo simulation Multi-Physics Transients Neutron transport
39	Simulation of IB-LOCA in TRACE : A semi-blind study of numerical simulations compared to the PKL test facility Tiberg, Matilda January 2022 (has links) This thesis studied the performance of the thermal hydraulic software TRACE applied on an intermediate sized break (IB) happening on the cold leg in a pressurized water reactor (PWR), causing a loss-of-coolant accident (LOCA). The same accident has previously been simulated in the PKL Test Facility, which is a scaled version of a PWR and is used to simulate transients stemming from different accidents. The thesis was performed as a semi-blind study: firstly, the accident was simulated without any knowledge of the PKL results. When a final blind model was chosen, the PKL results were revealed, and the TRACE model was improved. Before the simulations of the IB-LOCA took place, the new internal parts in the upper parts of the reactor pressure vessel in PKL had to be modelled, and the steady state had to be tuned to attain the correct initial conditions. The simulations were performed by using the software SNAP together with TRACE, providing a graphical interface. TRACE achieved steady state with satisfying results regarding water levels, pressure losses and mass flows. The temperatures in TRACE deviated from the PKL temperatures but an explanation is uncertainties in PKL. To verify TRACE’s core output power, the calculation of the power was done by using mass flow rate and specific entropy and comparing to the heaters’ specified power. This resulted in lower output power meaning that the coolant was not heated enough. This indicated non-physical energy losses in the TRACE model and should be further investigated.The blind transient simulation, modelled with default choked flow and no offtake model, resulted in TRACE overestimating the break mass flow and the peak cladding temperatures, compared to the PKL reference solution. This resulted in the pressure decreasing too quickly and too early activation of the safety system. The modified simulations showed that it is important that the offtake model, which accounts for different flow regimes, is activated. Default choked flow multipliers were the multipliers that performed the best. However, none of the transient simulations could be completed due to fatal errors and memory problems, but some conclusions could be drawn from the observed trends. This concluded in the offtake model being most important due to stratified flow occurring. Pressurized Water Reactor Safetey analysis LOCA Intermediate Break PKL TRACE transient thermal hydraulics Engineering and Technology Teknik och teknologier
40	Computational Study of Critical Flow Discharge in Supercritical Water Cooled Reactors Chatharaju, Madhuri 10 1900 (has links) <p>Supercritical Water-cooled Reactor (SCWR) is a Generation-IV nuclear reactor design that operates on a direct energy conversion cycle above the thermodynamic critical point of water (374<sup>0</sup>C and 22.1 MPa), and offers higher thermal efficiency and considerable design simplification. As an essential step in the design of SCWR safety systems, the accident behaviour of the reactor is evaluated to ensure that the safety systems can achieve safe shutdown for all the design basis accidents. Unfortunately, the computational tools and computer codes that are currently employed for safety analysis have little application in the supercritical region, and faces significant challenges in simulating the transitions from subcritical to supercritical conditions.</p> <p>This thesis examines the predictive capabilities of Computational Fluid Dynamics (CFD) code STAR-CCM+ by evaluating critical flow (or choked flow) due to accidental release of coolant from supercritical fluid systems. The biggest challenge of this research is that the current version of STAR-CCM+ does not support supercritical simulations because the steam tables included in the package are only limited to the subcritical subset of the thermodynamic fluid properties.</p> <p>The research was carried out in two stages. In the first stage, the CFD code STAR-CCM+ was customized to simulate supercritical conditions by, (i) Generating updated steam tables to include subcritical and supercritical fluid properties and using more pressure and temperature points in the pseudo critical region (22 – 25 MPa, 645 -660 K) to handle the rapid changes in the fluid properties, and (ii) Implementing a multi-dimensional steam table interpolation scheme to access the fluid property data at any thermodynamic state during the simulation. In the second stage, the customized CFD code was extensively evaluated by simulating several accidental release scenarios from supercritical conditions using rounded-edge and sharp-edge nozzles and the model results were validated with experimental data. To overcome the solution stability (or convergence) issues encountered during the supercritical simulations, a fine tuning procedure was proposed that guaranteed convergence for all the case studies considered in this thesis.</p> <p>The simulation results revealed that the CFD model produced results that were in good agreement with experimental data and only about 10% prediction error was noticed for most cases considered in the thesis. Considering the sensitivity of the CFD model for upstream temperatures and pressures, these results appear to be quite reasonable. From the computational experience gained in this research , we believe that the CFD code STAR-CCM+ is a very useful tool to perform thermal hydraulic simulations for supercritical systems. However, an appropriate customization and extensive validation of the code is required before it can be exclusively used for safety analysis.</p> / Master of Applied Science (MASc) Supercritical water cooled reactors LOCA Critical flow Thermal hydraulics Safety Analysis CFD STAR-CCM+ Nuclear Engineering Nuclear Engineering

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