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2. CORTEX experiments – Part I: Modulation campaigns in AKR-2 & CROCUS for the validation of neutron noise codes

Author

Lamirand, Vincent, Knospe, Alexander, Ambrožič, Klemen, Hübner, Sebastian, Lange, Carsten, Pakari, Oskari, Vitullo, Fanny, Rais, Adolfo, Pohlus, Joachim, Paquee, Uwe, Pohl, Christoph, Weiss, Nicolas, Frajtag, Pavel, Godat, Daniel, Mylonakis, Antonios, Laureau, Axel, Ligonnet, Thomas, Hursin, Mathieu, Perret, Grégory, and Pautz, Andreas

Published
2025
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6. Revision of PSI calculation capabilities and validation experience on the BEPU-type reactor dosimetry applications.

Author

Vasiliev, Alexander, Ferroukhi, Hakim, Pecchia, Marko, Rochman, Dimitri, Laureau, Axel, Lamirand, Vincent, and Pautz, Andreas

Subjects
NUCLEAR reactors, THERMAL hydraulics, RADIATION dosimetry, NUCLEAR energy, NUCLEAR reactor cores
Abstract

The present paper summarizes the experience accumulated at the Laboratory for Reactor Physics and Thermal-Hydraulics (LRT) of the Paul Scherrer Institute in the field of reactor dosimetry, as well as outlines the recent progress achieved in relation to the associated nuclear data uncertainty propagation methodologies. For dosimetry simulations, the CASMO/SIMULATE/MCNP/FISPACT-II system of codes is in operation at LRT/Nuclear Energy and Safety (NES) Research Division, which is based on the use of validated CASMO/SIMULATE cycle-specific core-follow models of Swiss LWRs. Coupling with FISPACT-II provides the capability for detailed isotopic inventory tracking under irradiation, assessment of materials activation and dpa values, etc. The use of the seamless calculation scheme with translation of the core-follow simulation results into the detailed neutron source specifications for consequent Monte Carlo simulations, accomplished with nuclear data uncertainty propagation capabilities and integrated with appropriate dosimetry validation database, makes the PSI methodology well aligned with the generic best estimate plus uncertainty (BEPU) approach principles. For specific illustrations, this paper presents some results on evaluation of: 1) a few well-known OECD/NEA reactor shielding experimental benchmarks (SINBAD benchmarks H.B. Robinson-2, ASPIS-PCA REPLICA), 2) some dosimetry data obtained from a Swiss PWR and 3) simulation of the dosimetry measurements for the 'PETALE' experimental program at the EPFL research reactor 'CROCUS', as they were foreseen at the time of the experimental planning. Finally, ways to further enhance the simulation methodology and models are discussed. [ABSTRACT FROM AUTHOR]

Published
2024
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7. Fast simulation of neutron noise using the Transient Fission Matrix approach and validation on the CROCUS reactor

Author

Laureau Axel, Begue Max, Lamirand Vincent, Merle Elsa, and Pakari Oskari

Subjects
Physics, QC1-999
Abstract

This article presents the development of a neutron noise calculation technique with a reduced calculation time based on the TFM (Transient Fission Matrix) approach. The latter contains different information such as the system transfer function (fission and absorption probability density functions and corresponding neutron multiplicity) of prompt and delayed neutrons, and the corresponding propagation time. This information is used to reconstruct neutron showers based on precursor decays up to the shower disappearance by absorption, leakage or delayed neutron precursor creation. Then pseudo-detectors such as fission chamber count rate histograms are reconstructed from these neutron showers and the αprompt is calculated from the cross-correlation function. A very good agreement has been obtained on the uranium-fueled light water reactor CROCUS between the model developed and the reference value.

Published
2024
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8. Towards a highly efficient and unbiased population-control algorithm for kinetic Monte Carlo simulations

Author

Montecchio Cecilia, Lamirand Vincent, Mancusi Davide, Monange Wilfried, and Zoia Andrea

Subjects
Physics, QC1-999
Abstract

Population-control methods are key to non-stationary Monte Carlo simulations of multiplying systems: they prevent either the unbounded growth or the disappearance of neutrons, occurring respectively in supercritical and subcritical conditions; furthermore, they contribute to an efficient allocation of computational resources by addressing the unbalance between the neutron and the precursor populations. In this paper, we present two alternative populationcontrol algorithms: the legacy implementation in TRIPOLI-4®, the Monte Carlo code developed at CEA, and an improved version that is currently under investigation, based on the use of a simplified point-kinetics solver. We assess the performance of these methods through the simulation of a $2.2 step reactivity insertion in a fast system (Flattop-Pu), leading to an increase of the neutron population by a factor 200, which is benchmarked against point kinetics. We show that the new implementation not only suppresses the slight bias that was present in the legacy method due to a stochastic normalization factor, but also outperforms the previous algorithm in terms of variance reduction and improvement of the figure of merit.

Published
2024
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13. Ten springs of experiments in CROCUS

Author

Lamirand Vincent

Subjects
reactor experiments, nuclear data, neutron detector, crocus, colibri, cortex, petale, harvest-x, bloom, nectar, mimi detector, saffron, Physics, QC1-999
Abstract

Around a decade ago, a new team rebuilt experimental research at EPFL’s nuclear facilities, and in particular in the CROCUS nuclear reactor. After a broad investigation and open discussions with colleagues from the nuclear community, a number of experiments and research directions were selected. They range from reactor physics to nuclear data, with a focus on instrumentation. We present here the variety of experiments carried out and how instrumentation has been instrumental in these perspectives. Developments on branching or intrinsic reactor noise were made possible thanks to extensive theoretical investigation coupled with the developments of pulse and current modes neutron detection systems, as well as the LEAF gamma detection array. With regard to modulation or perturbation reactor noise, a study of fuel rods vibration was carried out thanks to the unique COLIBRI in-core fuel rods oscillation device; in the VOID experiments, a method was tested to measure the void coefficient with neutron modulation; in the APRHODITE project, the PISTIL rotating absorber, or absorber of variable strength, was used to determine the zero power reactor transfer function, in order to obtain feedback on kinetics nuclear data, particularly delayed neutrons. On the topic of nuclear data, the PETALE programme consisted on criticality and transmission experiments for the study of stainless steel, using instrumented metal reflectors. New dosimetry methodologies were developed for consistent and complete propagation of uncertainties, which also enabled experiments to be optimized. It will be continued in the HARVEST-X project, and its pile-oscillation program, BLOOM. Last but not least, developments in dosimetry as well as for a novel miniature neutron scintillation technology (MiMi detectors) allowed for interand intrapin (NECTAR) neutron measurements. 160 MiMi detectors have recently been distributed throughout the CROCUS core in a unique 3D detector array called SAFFRON, paving the way for novel high-resolution neutronics.

Published
2023
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14. POLLEN: A Pile-Oscillator for the BLOOM Experimental Program

Author

Ligonnet Thomas, Weiss Nicolas, Lamirand Vincent, Laureau Axel, and Pautz Andreas

Subjects
pile-oscillation, pollen, bloom, harvestx, crocus, nuclear data, stainless-steel, Physics, QC1-999
Abstract

In the scope of its project on the assimilation and reproduction of experiments for the evaluation of stainless-steel nuclear data HARVEST-X, the LRS launches a pile-oscillation experimental program in the CROCUS reactor: BLOOM. For this program, an oscillator called POLLEN originally developed to be used as a vibrating absorber to compensate the fuel rods oscillator COLIBRI was reworked as a standalone pile-oscillator called. The oscillator operates with an arbitrary periodical shape, an amplitude of 1 m and a frequency ranging from the mHz to the Hz. An emphasis was put in the development of an interface for pseudo-square oscillations for BLOOM. This interface also allows independent adjustment of the ramping time and dwell time of the pseudo-square. The qualification of POLLEN was performed by video analysis of sinusoidal oscillations, using a 4K 30fps camera. With the current system, a precision of 0.2 mm was achieved during slow sinusoidal oscillation and a precision of 0.17 mm was obtained for pseudo square oscillations with a 500 g load. Whereas the results are satisfactory with respect to the current system and fulfill the requirement of the BLOOM program, it is planned to upgrade the system with the addition of a mechanical reference in the system. It is also in consideration to upgrade the acquisition card and controller to 16 bits systems to allow the use of POLLEN in setups where larger displacements are needed. The first in-core oscillation experiments are planned for early 2024.

Published
2023
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15. Design of an Instrumented Fuel Rod for Intra-pin Neutron Flux Measurements in the CROCUS Experimental Reactor

Author

Mager Tom, Valentin Jean-Baptiste, Lamirand Vincent, Ligonnet Thomas, Shin Won Dong, Fürbringer Jean-Marie, Hursin Mathieu, and Pautz Andreas

Subjects
instrumented fuel rod, intra-pin measurements, high-fidelity, crocus, Physics, QC1-999
Abstract

In response to the need for validating high-fidelity deterministic neutronics solvers capable of pin-resolved neutron flux distributions, an instrumented fuel rod was designed for the experimental reactor CROCUS, operated by EPFL’s Laboratory for Reactor Physics and Systems Behaviour. This rod aims at obtaining intra-pin data using activation dosimetry techniques. Placed in the outer region of the reactor core, the rod utilizes spaces between four metal uranium cigars (25 cm each) to house various disk dosimeters, targeting different neutron energy ranges and allowing retrieval of radial and azimuthal intra-pin neutron reaction rates. A design of experiment (DOE) study, aided by Serpent2 Monte Carlo calculations, facilitated the selection of dosimeter material and rod design, ensuring detection of within-pin neutron flux v ariations w hile adhering to mechanical and regulatory constraints. Azimuthal divisions of activation dosimeters were irradiated at the core center and subsequently subjected to activity determination using an HPGe gamma spectrometer. The objectives were met, detecting expected azimuthal variations within dosimeters and confirming uncertainties on reconstructed activity to be smaller than the amplitude of the observed variations. A permit from the Swiss nuclear regulatory authority ENSI-IFSN was obtained, allowing installation and usage of the instrumented fuel rod in CROCUS, known as the NECTAR experiments.

Published
2023
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16. Reactivity modulation experiments for nuclear data in CROCUS within a CEA-EPFL collaboration

Author

Geslot Benoit, Lamirand Vincent, Jiang Yifeng, Leconte Pierre, Pakari Oskari, Godat Daniel, Braun Laurent, Frajtag Pavel, Pantera Laurent, and Pautz Andreas

Subjects
reactor physics, reactor transfer function, crocus, delayed neutron groups, Physics, QC1-999
Abstract

In nuclear research reactors, integral experiments are powerful tools to measure integral core parameters, such as the delayed neutron fraction. Within the scope of the point kinetic approximation, reactivity modulation experiments can be used for probing the reactor transfer function and then infer integral parameters of the core. In this context, Commissariat à l’Energie Atomique et aux Energies Alternatives (CEA) and Ecole Polytechnique Fédérale de Lausanne (EPFL) have been collaborating for developing a probe device (PISTIL) and measurement setup adapted to the CROCUS zero power research reactor operated by EPFL (Lausanne, Switzerland). Despite some mechanical limitations of PISTIL, its maximum reactivity worth was measured with a good precision and repeatability using different methods (8.82 ±0.07 pcm), and its value is found rather close to the simulated one using TRIPOLI-4 (9.4 ± 0.4 pcm with JEFF-3.3). Above 1 Hz, the shape of the used modulation is pseudo-sinusoidal, with only a few well defined harmonics of excitation. The strongest harmonic only was analyzed using standard signal processing algorithms such as the Fourier transform and the Bartlett estimator. Twelve data points were produced in the range 0.5 Hz to 200 Hz, with uncertainty ranging from 1 % to 15 %. The prompt decay constant was measured at 150 ± 3 rad/s. Below 1 Hz, stepwise modulations were used with pseudo-random time sequences, which allowed exciting at once a large number of frequencies. Around 150 data points were produced in this particularly interesting frequency domain, between 1.6 mHz and 0.75 Hz, thanks to the use of three distinctive sequences with different base frequencies and overlapping ranges. The amplitude and phase of the RTF were measured satisfactorily, with uncertainties below 1 % for the strongest harmonics. The shape of the RTF was found consistent with the predictions of both JEFF-3.3 and ENDF/B-VII.1 libraries.

Published
2023
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17. Simultaneous inter-calibration of 160 MiMi neutron detectors

Author

Vitullo Fanny, Lamirand Vincent, Godat Daniel, and Pautz Andreas

Subjects
neutron detector, mimi detector, inter-calibration, pu-be neutron source, carrousel, relative sensitivity, source factor, crocus, Physics, QC1-999
Abstract

The 160 MiMi neutron detectors of SAFFRON, a 3D full-core mapping system developed at EPFL for the CROCUS zero-power reactor, have been simultaneously inter-calibrated in preparation for their in-core installation. An experimental setup was built to distribute up to 180 MiMi detectors radially at 15 cm around the Pu-Be neutron source of the CARROUSEL facility. An efficient inter-calibration methodology is presented: first, the azimuthal shape of the relative source strength is characterized by rotating 18 MiMi detectors distributed every 20º around the PuBe, followed by the simultaneous determination of the relative sensitivity of 160 MiMi detectors, distributed all around the Pu-Be source.

Published
2023
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18. Analysis of the preliminary campaign for the PETALE program

Author

Laureau Axel, Gruel Adrien, Lamirand Vincent, Ligonnet Thomas, Sardet Alix, and Pautz Andreas

Subjects
Nuclear engineering. Atomic power, TK9001-9401
Abstract

The PETALE program aims to provide new experimental data to constrain the stainless steel nuclear data. In this frame, a preliminary measurement campaign has been performed to characterize the neutron flux in key positions of the CROCUS reactor and to develop analysis tools. During this preliminary campaign detailed in the present paper, an efficiency ratio technique has been developed and tested to speed up HPGe measurements by a factor of 30. A second objective of the campaign concerns the propagation of nuclear data uncertainty from the core neutron cross-sections to the reaction rates in the dosimeters. Uncertainties in the core cross sections, such as the uranium cross section, are nuisance parameters that add uncertainty to the dosimeter reaction rate calculation. This component must be fully characterized with covariances to constrain the metal reflector component for Bayesian assimilation. The experimental results are compared to the calculations with different nuclear databases for the nuclear data uncertainty propagation. A good agreement is obtained with the ENDF/B-VII.1 database and a systematic underestimation of around 5–10% in the fast range is observed with the ENDF/B-VIII.0 and JEFF-3.3 databases.

Published
2023
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19. HIGHLY LOCALIZED AZIMUTHAL MEASUREMENTS IN THE CROCUS REACTOR TOWARDS THE VALIDATION OF HIGH-FIDELITY NEUTRONICS CODES

Author

Vitullo Fanny, Lamirand Vincent, Frajtag Pavel, Perret Gregory, and Pautz Andreas

Subjects
azimuthal flux measurements, crocus zero-power research reactor, micro-reactor physics, miniature neutron detector, Physics, QC1-999
Abstract

Highly localized in-core measurements are necessary for the validation of neutron transport calculations with high spatial resolution. In the present work, a miniature neutron detector developed at EPFL in collaboration with PSI was used to carry out a set of thermal neutrons counting measurements in the zero-power CROCUS reactor core within a spatial range in order of mm. The miniature detector, positioned close to the core reflector, shows a gradient of +(4.29 ± 0.10)% in the count rate profile in the radial direction within 1.3 cm, with higher values pointing towards the core reflector because of the higher share of neutrons in the thermal range. On the contrary, in a control rod guide tube the count rate gradient is -(4.37 ± 0.10)% and it is directed towards the core center. The measured values are compared with the azimuthal trend of the normalized 6Li reaction rate calculated with an iterative three-steps method performed with the Monte Carlo code Serpent 2. These measurements proved the feasibility of resolving spatial effects in the mm-range and they represent a basis for further investigating highly spatially-resolved phenomena in the CROCUS core.

Published
2021
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20. VALIDATION OF AXIAL VOID PROFILE MEASURED BY NEUTRON NOISE TECHNIQUES IN CROCUS

Author

Hursin Mathieu, Pakari Oskari, Perret Gregory, Frajtag Pavel, Lamirand Vincent, Pázsit Imre, Dykin Victor, Por Gabor, Nylén Henrik, and Pautz Andreas

Subjects
attenuation measurements, two-phase flow, void measurements, Physics, QC1-999
Abstract

Recently a joint project has been carried out between the Paul Scherrer Institut, the Ecole Polytechnique Federale de Lausanne and swissnuclear, an industrial partner, in order to determine the axial void distribution in a channel installed in the reflector of the zero power research reactor CROCUS, using neutron noise techniques. The main objective of the present paper is to report on the validation of the results against an alternative measurement technique using gamma-ray attenuation and simulations with the TRACE code. For the gamma-ray attenuation experiments, the channel used in CROCUS is installed out of the core in a Plexiglass water tank. The source and detector are fixed and the channel is moved axially to keep the geometry of the source/detector arrangement untouched. This is key to measure the void effect by gamma attenuation due to the low contrast of this technique. The paper compares the experimental results obtained with both techniques, with the outcomes of simulations carried out with the TRACE code. Even though the quantitative void fraction estimations are not consistent, the trends obtained with the simulation and experimental techniques are the same. The discrepancies between the various experimental techniques and the simulation outcomes are related to the heterogeneous distribution of the water-air mixture in the radial sections of the channel.

Published
2021
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21. TOWARDS THE VALIDATION OF NOISE EXPERIMENTS IN THE CROCUS REACTOR USING THE TRIPOLI-4 MONTE CARLO CODE IN ANALOG MODE

Author

Pakari Oskari, Mancusi Davide, Petit Odile, Zoia Andrea, Lamirand Vincent, and Pautz Andreas

Subjects
neutron noise, monte carlo, validation, crocus, tripoli-4, Physics, QC1-999
Abstract

Intrinsic neutron noise experiments offer a non-invasive manner to measure the prompt decay constant or reactivity of fissile systems. Using the fluctuations in the density of fission chains, one can infer the kinetics parameters via correlation analysis such as the Rossi-alpha method. The models allowing for the interpretation of these measurements typically rely on the assumption of the system behaving according to point kinetics. When dealing with systems where point kinetics fail to predict the true time correlation – such as heterogeneous or large cores – the direct simulation of fission chains using Monte Carlo methods appears as the only reliable candidate to provide reference predictions for the correlation functions. Monte Carlo methods using explicit fission model libraries are thus being examined as tools for prediction in noise analysis. In this work we illustrate the developments and simulation results of the analog transport capabilities of the TRIPOLI-4 Monte Carlo code coupled with the LLNL fission library FREYA, as applied to a set of neutron noise experiments carried out in the CROCUS zero-power reactor with emphasis on the identification of spatial effects. To validate the general capability of the code to predict noise correlations, we examine time distributions of the whole core fission and explicit detection reactions. We present the methodology to achieve a good agreement between experiments and simulations. We reproduced experimental results for relative α, within typical biases, and conclude on the general feasibility of the analog method. We further explore a decoupled core model and analyze it using the noise method. The results indicate an effective method to treat decoupled systems.

Published
2021
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22. Delayed gamma fraction determination in the zero power reactor CROCUS

Author

Pakari Oskari, Mager Tom, Lamirand Vincent, Frajtag Pavel, and Pautz Andreas

Subjects
Nuclear engineering. Atomic power, TK9001-9401
Abstract

Gamma rays are an inextricable part of a nuclear reactor’s radiation field, and as such require characterization for dose rate estimations required for the radiation protection of personnel, material choices, and the design of nuclear facilities. Most commonplace radiation transport codes used for shielding calculations only included the prompt neutron induced component of the emitted gamma rays. The relative amount of gamma rays that are emitted from delayed processes – the delayed gamma fraction – amount to a significant contribution, e.g. in a typical zero power reactor at steady state is estimated to be roughly a third. Accurate predictions of gamma fields thus require an estimation of the delayed content in order to meaningfully contribute. As a consequence, recent code developments also include delayed gamma sources and require validation data. The CROCUS zero power research reactor at EPFL is part of the NEA IRPhE and has therefore been characterized for benchmark quality experiments. In order to provide the means for delayed gamma validation, a dedicated experimental campaign was conducted in the CROCUS reactor using its newly developed gamma detection capabilities based on scintillators. In this paper we present the experimental determination of the delayed gamma fraction in CROCUS using in-core neutron and gamma detectors in a benchmark reactor configuration. A consistent and flexibly applicable methodology on how to estimate the delayed gamma fraction in zero power reactors has hitherto not existed – we herein present a general experimental setup and analysis technique that can be applied to other facilities. We found that the build-up time of relevant short lived delayed gamma emitters is likely attributed to the activation of the aluminium cladding of the fuel. Using a CeBr3 scintillator in the control rod position of the CROCUS core, we determined a delayed gamma fraction of (30.6±0.6)%.

Published
2021
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23. PISTIL, a reactivity modulation device to probe the transfer function of the nuclear reactor CROCUS

Author

Jiang Yifeng, Geslot Benoit, Lamirand Vincent, Leconte Pierre, Godat Daniel, Braun Laurent, Frajtag Pavel, Coquelet-Pascal Christine, and Pautz Andreas

Subjects
in-core integral experiment, reactivity modulation, zero-power reactor transfer function, reactor kinetics, Physics, QC1-999
Abstract

The present article summarizes the development and testing of a reactivity modulation device developed by the French Atomic and Alternative Energies Commission (CEA). It was installed in the CROCUS reactor of the Swiss Federal Institute of Technology in Lausanne (EPFL). Experimental tests were performed in the framework of a collaboration between CEA and EPFL. The so-called PISTIL device aims at measuring the nuclear reactor transfer function in the frequency range of interest between 1 mHz and 200 Hz, in order to probe the in-core kinetic behavior of prompt and delayed neutrons. The reactivity modulation is obtained from the rotation of cadmium foils. The design of the system was driven with the objective of installing PISTIL at the center of the CROCUS reactor. Neutronic simulations with TRIPOLI-4 Monte Carlo code were performed to select the suitable design parameters and meet the safety requirements of the reactor operation. The total reactivity worth of the device, as estimated by TRIPOLI-4 Monte Carlo calculation, was approximately 0.16 $ and the maximum amplitude of the reactivity modulation was about 0.013 $. In-core reactivity calibration was then performed and were consistent as compared to TRIPOLI-4 estimations.

Published
2021
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24. High resolution measurements with miniature neutron scintillators in the SUR-100 zero power reactor

Author

Brunetto Edoardo L., Vitullo Fanny, Lamirand Vincent, Ambrožič Klemen, Godat Daniel, Buck Michael, Pohlner Georg, Starflinger Jörg, and Pautz Andreas

Subjects
scintillation detectors, monte carlo simulations, reaction rate profiles, Physics, QC1-999
Abstract

Three 1-mm3 miniature fiber-coupled scintillators have been used to perform cm-wise resolution measurements of the thermal neutron flux within experimental channels of the SUR-100 facility, a zero power thermal reactor operated by the Institute of Nuclear Technology and Energy Systems at the University of Stuttgart. The detection system is developed at the École Polytechnique Fédérale de Lausanne in collaboration with the Paul Scherrer Institut. Thermal neutrons count rates were measured along the experimental channels I and II, which cross the reactor at the center and tangentially to the core, respectively. The reactor was modelled with the Monte Carlo neutron transport code Serpent-2.1.31. The comparison of experimental and computed reaction rate distributions showed a good agreement within the core region, with discrepancies within 2σ. An unexpected discrepancy, probably caused by a geometric inconsistency in the computational model of the reactor, was observed in the reflector region of the experimental channel I, where a 20% difference (i.e. 8σ) was found between experimental and simulated results. Significant discrepancies, respectively worth 10σ and 15σ, were noticed at distance, in the lead shielding region, for both experimental channels I and II. In addition, reaction rate gradients across the 2.6 cm and 5.4 cm diameters of both channels were measured. A horizontal reaction rate gradient of (9.09 ± 0.20) % was measured within 2.4 cm across the diameter of the experimental channel II, with a difference from computed results of 2%. The absence of a vertical reaction rate gradient inside the experimental channel I was confirmed by measurements.

Published
2021
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25. Local and high distance neutron and gamma measurements of fuel rods oscillation experiments

Author

Lamirand Vincent, Pakari Oskari, Vitullo Fanny, Ambrožič Klemen, Godat Daniel, Frajtag Pavel, and Pautz Andreas

Subjects
reactor instrumentation, miniature neutron detector, neutron scintillator, gamma scintillator, reactor noise, noise analysis, zero power transfer function, Physics, QC1-999
Abstract

We report in the present article on the successful observation using noise analysis of the lateral oscillation of one fuel rod by ±2.5 mm around nominal at 0.1 Hz frequency, using an mm3 miniature neutron scintillator at the rod level, and a BGO gamma detector seven meters away from the reactor core center. The experiment was conducted as part of the COLIBRI program in the CROCUS reactor, which is dedicated to the investigation of reactor noise induced by fuel vibrations. It consists in experiments on rod lateral displacement (static) and oscillation (dynamic) with different rods’ numbers at various relevant amplitudes and frequencies. Its main motivation is the increased amplitudes in the neutron noise distributions recorded in ex- and in-core detectors that have been observed in recent years in Siemens pre-Konvoi type of PWR reactors. The obtained experimental data are used for the purpose of code validation, especially within the framework of the European project CORTEX on reactor noise applications. During the first phase of COLIBRI, the observation of a spatial dependence of the perturbation noise, also called neutron modulation, was demonstrated. In the second phase of COLIBRI starting 2021, it is planned to use a core mapping array of neutron detectors to record its propagation. It consists in about 150 miniature scintillators coupled to optical fibers and SiPM readouts, to be distributed in the reactor core. As a feasibility test, experiments were performed using a miniature scintillator prototype placed on a fuel rod, and oscillating the instrumented rod or the one directly adjacent to the detector. In addition, it is theoretically possible to measure branching or perturbation reactor noise using gamma radiation. Following recent developments on gamma measurements in CROCUS, the fuel oscillation was simultaneously recorded with a gamma detection array, LEAF. Its large BGO detectors were used by placing them at the maximum distance to the core, i.e. seven meters away with a clear line of sight using an experimental channel through the shielding of the reactor cavity.

Published
2021
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26. Design of a 150-miniature detectors 3D core-mapping system for the CROCUS reactor

Author

Vitullo Fanny, Lamirand Vincent, Ambrožič Klemen, Braun Laurent, Godat Daniel, Frajtag Pavel, and Pautz Andreas

Subjects
reactor instrumentation, 3d core-mapping, miniature neutron detector, in-core neutron detection, crocus, Physics, QC1-999
Abstract

The present article provides an overview of the design of a three-dimensional (3D) full-core mapping system for the CROCUS reactor, operated at the École polytechnique fédérale de Lausanne (EPFL), Switzerland. The system is composed of 149 miniature neutron detectors distributed within the core double lattice at three main axial levels. The miniature detector technology is based on the optimization of the well-proven coupling of a miniature ZnS:6LiF(Ag) scintillator to a state-of-the-art silicon photomultiplier (SiPM) via jacketed optical fibers. The challenges in the mechanical design, the detector optimization, the core criticality, and the development of the acquisition electronics are strongly interconnected and their combination is addressed in this article. The 3D full-core mapping system is foreseen to be installed in CROCUS in autumn 2021 and it will pave the way for the investigation of 3D dynamic phenomena in nuclear reactor cores.

Published
2021
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27. First in-core gamma spectroscopy experiments in a zero power reactor

Author

Pakari Oskari, Lamirand Vincent, Mager Tom, Laureau Axel, Frajtag Pavel, and Pautz Andreas

Subjects
gamma spectroscopy, zero power research reactor, Physics, QC1-999
Abstract

Gamma rays in nuclear reactors, arising either from nuclear reactions or decay processes, significantly contribute to the heating and dose of the reactor components. Zero power research reactors offer the possibility to measure gamma rays in a purely neutronic environment, allowing for validation experiments of dose estimates, computed spectra, and prompt to delayed gamma ratios. The resulting data can contribute to models, code validation and photo atomic/nuclear data evaluation. To date, most experiments have relied on flux measurements using TLDs, ionization chambers, or spectrometers set in low flux areas. The CROCUS reactor allows for flexible detector placement in and around the core, and has recently been outfitted with gamma detection capabilities to fulfill the need for in-core gamma spectroscopy, as opposed to flux. In this paper we report on the experiments and accompanying simulations of gamma spectrum measurements inside a zero power reactor core, CROCUS. It is a two-zone, uranium-fueled light water moderated facility operated by the Laboratory for Reactor Physics and Systems Behaviour (LRS) at the Swiss Federal Institute of Technology Lausanne (EPFL). Herein we also introduce, in detail, the new LEAF system: A Large Energy-resolving detection Array for Fission gammas. It consists of an array of four detectors – two large ø 127 254 mm Bismuth Germanate (BGO) and two smaller ø 12 50 mm Cerium Bromide (CeBr3) scintillators. We describe the calibration and characterization of LEAF followed by first in-core measurements of gamma ray spectra in a zero power reactor at different sub-critical and critical states, and different locations. The spectra are then compared to code results, namely MCNP6.2 pulse height tallies. We were able to distinguish prompt processes and delayed peaks from decay databases. We present thus experimental data from hitherto inaccessible core regions. We provide the data as validation means for codes that attempt to model these processes for energies up to 10 MeV. We finally draw conclusions and discuss the future uses of LEAF. The results indicate the possibility of isotope tracking and burn-up validation.

Published
2021
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28. Intra-Pin Reaction Rate Measurements in the CROCUS Experimental Reactor

Author

Mager, Tom, Pakari, Oskari, Hursin, Mathieu, Ligonnet, Thomas, Pautz, Andreas, and Lamirand, Vincent

Abstract

In response to the need for validating high-fidelity deterministic neutronics solvers capable of providing pin-resolved neutron flux distributions, intra-pin reaction rates measurements were performed in the CROCUS experimental reactor. A specially designed instrumented fuel rod was used to gather intra-pin data, thanks to activation dosimetry techniques. Positioned in the outer region of the reactor core, the rod takes advantage of spaces between the fuel elements to house pre-cut gold disk dosimeters for in-core irradiation. Subsequently, radial and azimuthal sections of the irradiated dosimeters are subjected to activity determination using an HPGe gamma spectrometer to retrieve the 197Au(n, $\gamma $ )198Au reaction rate distribution within the dosimeter. This article comprehensively describes the setup of the instrumented fuel rod as well as the experimental protocol and planning needed for such measurements. First, the measured radial and azimuthal intra-pin reaction rate distributions are presented and compared with predictions from the GeN-Foam high-fidelity model of the CROCUS reactor. In addition, the repeatability of the measurements has been demonstrated, with particular emphasis on the identification of the experimental sources of variability in the measured reaction rates.

Published
2024
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29. Neutron-Gamma Noise Measurements in a Zero-Power Reactor Using Organic Scintillators

Author

Darby, Flynn B., Pakari, Oskari V., Hua, Michael Y., Lamirand, Vincent, Clarke, Shaun D., Pautz, Andreas, and Pozzi, Sara A.

Abstract

Noise measurements in light water reactor systems aid in generating validation data for integral point kinetic parameter predictions and generating monitoring parameters for reactor safety and safeguards. The CROCUS zero-power reactor has been used to support both efforts via measurements with thermal neutron detectors to observe neutron noise and inorganic scintillators to observe gamma noise. The cross-correlation of gamma and neutron noise has been investigated at CROCUS with separate gamma-only and neutron-only detectors. Organic scintillators, sensitive to both neutrons and gamma rays, can be used to cross-correlate gamma-ray and neutron noise with a single detector type. Herein, we present noise measurements using organic scintillators in a light-water, zero-power research reactor for the first time. We discuss data obtained with two 5.08-cm-length by 5.08-cm-diameter cylindrical trans-stilbene detectors and two 6-mm cubic scintillators—one trans-stilbene and one organic glass (OGS)—set in the water reflector of CROCUS and outside the reactor vessel. The prompt neutron decay constant was estimated to be $\alpha _{\text {CPSD}}=(154 \pm 1) \hspace {2pt} \text {s}^{-1}$ at 3 mW critical from the ( $\gamma $ , $\gamma $ ) signal, which agrees within one standard deviation overlap with previous measurements with CeBr3 and simulation in Serpent 2. The ( $n,n$ ) estimate of $\alpha _{\text {CPSD}}=(145 \pm 23) \hspace {2pt} \text {s}^{-1}$ at 3 mW critical lacked precision but agreed within one standard deviation overlap with previous 235U fission chamber estimates and simulation in Serpent 2. The 6-mm cubic scintillators were too inefficient to estimate $\alpha $ , but informed possible small-cell, high-volume detection systems to improve the ( $n,n$ ) estimate capabilities. Based on the high-precision estimate of $\alpha $ from the ( $\gamma $ , $\gamma $ ) cross power spectral density (CPSD) signal, we suggest further development of theory to calculate $\beta _{\text {eff}}$ and $\Lambda $ from gamma-ray noise measurements and recommend gamma noise measurements for future simulation validation and as a method of reactor monitoring.

Published
2024
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32. Uncertainty propagation based on correlated sampling technique for nuclear data applications

Author

Laureau Axel, Lamirand Vincent, Rochman Dimitri, and Pautz Andreas

Subjects
Nuclear engineering. Atomic power, TK9001-9401
Abstract

A correlated sampling technique has been implemented to estimate the impact of cross section modifications on the neutron transport and in Monte Carlo simulations in one single calculation. This implementation has been coupled to a Total Monte Carlo approach which consists in propagating nuclear data uncertainties with random cross section files. The TMC-CS (Total Monte Carlo with Correlated Sampling) approach offers an interesting speed-up of the associated computation time. This methodology is detailed in this paper, together with two application cases to validate and illustrate the gain provided by this technique: the highly enriched uranium/iron metal core reflected by a stainless-steel reflector HMI-001 benchmark, and the PETALE experimental programme in the CROCUS zero-power light water reactor.

Published
2020
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33. Review of kinetic modulation experiments in low power nuclear reactors

Author

Jiang Yifeng, Geslot Benoit, Lamirand Vincent, and Leconte Pierre

Subjects
Nuclear engineering. Atomic power, TK9001-9401
Abstract

The safety improvement of nuclear reactors requires continuous efforts in understanding the fundamental physical quantities related to the fission process. In neutronic models, the reactor dynamics is covered by the kinetic parameters to characterize the temporal behavior of the neutron population subject to perturbations. The reactor transfer function is a frequency domain analogy of this temporal description. It can be measured experimentally through transfer function analysis via noise analysis or kinetic modulation, for the study of reactor stability and kinetic parameters. This paper summarizes the experimental measurements of reactor transfer function through kinetic modulation. Extensive work have been conducted experimentally, starting from the beginning of reactor physics research. An overview is given regarding various experimental designs and conducted analyses. The concepts of the modulation system are also discussed. The current work is limited to online contents and internal archives of CEA Cadarache due to difficulties in accessing references traced back to 1950s.

Published
2020
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34. Uncertainty propagation for the design study of the PETALE experimental programme in the CROCUS reactor

Author

Laureau Axel, Lamirand Vincent, Rochman Dimitri, and Pautz Andreas

Subjects
Nuclear engineering. Atomic power, TK9001-9401
Abstract

The PETALE experimental programme in the CROCUS reactor intends to provide integral measurements to constrain stainless steel nuclear data. This article presents the tools and the methodology developed to design and optimize the experiments, and its operating principle. Two acceleration techniques have been implemented in the Serpent2 code to perform a Total Monte Carlo uncertainty propagation using variance reduction and correlated sampling technique. Their application to the estimation of the expected reaction rates in dosimeters is also discussed, together with the estimation of the impact of the nuisance parameters of aluminium used in the experiment structures.

Published
2020
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35. Neutron noise experiments in the AKR-2 and CROCUS reactors for the European project CORTEX

Author

Lamirand Vincent, Rais Adolfo, Hübner Sebastian, Lange Carsten, Pohlus Joachim, Paquee Uwe, Pohl Christoph, Pakari Oskari, Frajtag Pavel, Godat Daniel, Hursin Mathieu, Laureau Axel, Perret Grégory, Fiorina Carlo, and Pautz Andreas

Subjects
core monitoring and diagnostics, noise analysis, research reactor experiment, zero-power reactor, Physics, QC1-999
Abstract

The present article gives an overview of the first experimental campaigns carried out in the AKR-2 and CROCUS reactors within the framework of the Horizon 2020 European project CORTEX. CORTEX aims at developing innovative core monitoring techniques that allow detecting anomalies in nuclear reactors, e.g. excessive vibrations of core internals. The technique will be mainly based on using the fluctuations in neutron flux, i.e. noise analysis. The project will result in a deepened understanding of the physical processes involved. This will allow utilities to detect operational problems at a very early stage, and to take proper actions before such problems have any adverse effect on plant safety and reliability. The purpose of the experimental campaigns in the AKR-2 and CROCUS reactors is to produce noise-specific experimental data for the validation of the neutron noise computational models developed within this framework. The first campaigns at both facilities consisted in measurements at reference static states, and with the addition of mechanical perturbations. In the AKR-2 reactor, perturbations were induced by two devices: a rotating absorber and a vibrating absorber, both sets in experimental channels close to the core. In CROCUS, the project benefited from the COLIBRI experimental program: 18 periphery fuel rods were oscillated at a maximum of ±2 mm around their central position in the Hz range. The present article documents the experimental setups and measurements for each facility and perturbation type.

Published
2020
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36. The COLIBRI experimental program in the CROCUS reactor: characterization of the fuel rods oscillator

Author

Lamirand Vincent, Frajtag Pavel, Godat Daniel, Pakari Oskari, Laureau Axel, Rais Adolfo, Hursin Mathieu, Hursin Grégory, Fiorina Carlo, and Pautz Andreas

Subjects
core monitoring and diagnostics, fuel vibration, noise analysis, research reactor experiment, zero-power reactor, Physics, QC1-999
Abstract

The present article presents the mechanical characterization of the fuel rods oscillator developed for the purposes of the COLIBRI experimental program in CROCUS. COLIBRI aims at investigating the radiation noise related to fuel vibrations. The main motivation is the increased amplitudes in the neutron noise distributions recorded in ex- and in-core detectors that have been observed in recent years in Siemens pre-Konvoi type of pressurized water reactors. Several potential explanations have been put forward, but no definitive conclusions could yet be drawn. Among others, changes in fuel assembly or pin vibration patterns, due to recent modifications of assembly structural designs, were pointed out as a possible cause. Computational dynamic tools are currently developed within the Horizon 2020 European project CORTEX, to help with understanding the additional noise amplitude. The COLIBRI program is used for their validation. An in-core device was designed, tested, and licensed between 2015 and 2019 for fuel rods oscillation in CROCUS, in successive steps from out-of-pile tests with dummy fuel rods to critical in-core tests. The characterization of its mechanical behavior is presented, in air and in water, and as a function of the load, for safety and experimental purposes. The device allows simultaneously oscillating up to 18 fuel rods. The maximum oscillation amplitude is 5 mm, while the maximum allowed frequency is 2 Hz, i.e. in the frequency range in which the induced neutron flux fluctuations are most pronounced in nuclear power plants.

Published
2020
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37. Power calibration methodology at the CROCUS reactor

Author

Lamirand Vincent, Laureau Axel, Pakari Oskari, Frajtag Pravel, and Pautz Andreas

Subjects
neutron dosimetry, neutron activation analysis, in-core dosimetry, integral experiment, zero-power reactor, Physics, QC1-999
Abstract

In the present article, we detail the method used to experimentally determine the power of the CROCUS zero-power reactor, and to subsequently calibrate its ex-core monitor fission chambers. Knowledge of the reactor power is a mandatory quantity for a safe operation. Furthermore, most experimental research programs rely on absolute fission rates in design and interpretation – for instance, tally normalization of reaction rate studies in dosimetry, or normalization of power spectral density in neutron noise measurements. The minimization of associated uncertainties is only achieved by an accurate power determination method. The main experiment consists in the irradiation, and therefore, the activation of several axially distributed Au-197 foils in the central axis of the core, which activities are measured with a High-Purity Germanium (HPGe) gamma spectrometer. The effective cross sections are determined by MCNP and Serpent Monte Carlo simulations. We quantify the reaction rate of each gold foil, and derive the corresponding fission rate in the reactor. The variance weighted average over the distributed foils then provides a calibration factor for the count rates measured in the fission chambers during the irradiation. We detail the calibration process with minimization of respective uncertainties arising from each sub-step, from power control after reactivity insertion, to the calibration of the HPGe gamma spectrometer. Biases arising from different nuclear data choices are also discussed.

Published
2020
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38. Developing and testing a miniature fiber-coupled scintillator for in-core neutron counting in CROCUS

Author

Vitullo Fanny, Lamirand Vincent, Mosset Jean-Baptiste, Frajtag Pavel, Pakari Oskari, Gregory Perret, and Pautz Andreas

Subjects
scintillators, scintillation detectors, pulse shape discrimination, figure of merit, Physics, QC1-999
Abstract

An advanced neutron detection system for highly localized measurements in nuclear reactor cores was developed and tested in the Laboratory for Reactor Physics and System Behaviour (LRS) at the École polytechnique fédérale de Lausanne (EPFL), Switzerland, in close collaboration with the Detector group of the Laboratory for Particle Physics (LTP) at the Paul Scherrer Institute (PSI), Switzerland. The miniature-size detector is based on the coupling of a ZnS:6LiF scintillator/converter screen of 1 mm2 and 0.2 mm thickness with a 10-m optical fiber, the latter being connected to a silicon photomultiplier (SiPM). In this development version, the output signal is processed via analog read-out electronics. The present work documents the characterization of a detection system prototype in the mixedradiation fields o f t he C ARROUSEL f acility a nd i ts t esting in the CROCUS zero-power reactor operated at LRS. The fibercoupled scintillator shows a linear response with the reactor power increase up to 6.5 W (i.e. around 108 cm-2s-1 total neutron flux), with a s ubsequent l oss o f l inearity d ue t o e lectronic dead time of the analog system. Nevertheless, the detector shows excellent neutron counting capabilities whether compared to other localized detection systems available at LRS, e.g. miniature fission chambers and an sCVD diamond detector.

Published
2020
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39. Bayesian Monte Carlo assimilation for the PETALE experimental programme using inter-dosimeter correlation

Author

Laureau Axel, Lamirand Vincent, Rochman Dimitri, and Pautz Andreas

Subjects
Physics, QC1-999
Abstract

This article presents the methodology developed to generate and use dosimeter covariances and to estimate nuisance parameters for the PETALE experimental programme. In anticipation of the final experimental results, this work investigates the consideration of these experimental correlations in the Bayesian assimilation process on nuclear data. Results show that the assimilation of a given set of dosimeters provides a strong constraint on some of the posterior reaction rate predictions of the other dosimeters. It confirms that, regarding the assimilation process, the different sets of dosimeters are correlated.

Published
2020
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40. Assessment of representativity of the PETALE experiments for validation of Swiss LWRs ex-core dosimetry calculations

Author

Vasiliev Alexander, Pecchia Marco, Rochman Dimitri, Perret Gregory, Ferroukhi Hakim, Laureau Axel, Lamirand Vincent, and Pautz Andreas

Subjects
Physics, QC1-999
Abstract

The international experimental program PETALE will be carried out at the CROCUS research reactor of EPFL. The program aims at measuring neutron penetration in slabs made of materials composing typical LWR reactor pressure vessel. The measurements will be used for code and nuclear data validation and for the evaluation of the reflecting properties of these materials. In this paper the representativity of the PETALE experiments is assessed with respect to operational LWR reactors dosimetry and activation evaluations using the Paul Scherrer Institute (PSI) in-house tool NUSS. The NUSS tool allows the stochastic sampling of nuclear data using covariance matrices available in modern nuclear data libraries and the subsequent running of a Monte Carlo code with the modified data files. The representativity can then be assessed based on the Pearson correlation coefficients. The ultimate goal of the work is first of all to assess if the planned PETALE measurements could be applicable beyond their primary purpose and serve for extending the PSI validation database for LWR reactor dosimetry evaluations. Secondly, provided that the PETALE measurements are found useful for the task above, the information on the correlations between the PETALE neutron detectors’ responses and the reactor dosimetry quantities of interest, shall be presented and discussed.

Published
2020
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41. An Experimental Programme optimized with Uncertainty Propagation: PETALE in the CROCUS Reactor

Author

Lamirand Vincent, Laureau Axel, Rochman Dimitri, Perret Gregory, Gruel Adrien, Leconte Pierre, Blaise Patrick, and Pautz Andreas

Subjects
Physics, QC1-999
Abstract

The PETALE experimental programme in the CROCUS reactor at EPFL intends to contribute to the validation and improvement of neutron nuclear data in the MeV energy range for stainless steel, particularly in the prospect of heavy reflector elements of pressurized water reactors. It mainly consists of several transmission experiments: first, through metallic sheets of nuclear-grade stainless steel interleaved with dosimeter foils, and, successively, through its elemental components of interest – iron, nickel, and chromium. The present article describes the study for optimizing the response of the dosimetry experiments to the nuclear data of interest.

Published
2019
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42. Total Monte Carlo acceleration for the PETALE experimental programme in the CROCUS reactor

Author

Laureau Axel, Lamirand Vincent, Rochman Dimitri, and Pautz Andreas

Subjects
Physics, QC1-999
Abstract

The Bayesian Monte Carlo technics requires individual evaluations of random cross section files based on a Total Monte Carlo propagation. This article discusses the use of a Correlated Sampling acceleration applied to TMC calculations for experiments where a brute force technics is too expensive. An e_cient estimation of the reaction rate uncertainties in small dosimeters is obtained, together with the inter-dosimeter correlation associated to the cross section uncertainties.

Published
2019
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45. FLUOLE-2: An Experiment for PWR Pressure Vessel Surveillance

Author

Thiollay Nicolas, Salvo Jacques Di, Sandrin Charlotte, Soldevila Michel, Bourganel Stéphane, Fausser Clément, Destouches Christophe, Blaise Patrick, Domergue Christophe, Philibert Hervé, Bonora Jonathan, Gruel Adrien, Geslot Benoit, Lamirand Vincent, Pepino Alexandra, Roche Alain, Méplan Olivier, and Ramdhane Mourad

Subjects
Physics, QC1-999
Abstract

FLUOLE-2 is a benchmark-type experiment dedicated to 900 and 1450 MWe PWR vessels surveillance dosimetry. This two-year program started in 2014 and will end in 2015. It will provide precise experimental data for the validation of the neutron spectrum propagation calculation from core to vessel. It is composed of a square core surrounded by a stainless steel baffe and internals: PWR barrel is simulated by steel structures leading to different steel-water slides; two steel components stand for a surveillance capsule holder and for a part of the pressure vessel. Measurement locations are available on the whole experimental structure. The experimental knowledge of core sources will be obtained by integral gamma scanning measurements directly on fuel pins. Reaction rates measured by calibrated fission chambers and a large set of dosimeters will give information on the neutron energy and spatial distributions. Due to the low level neutron flux of EOLE ZPR a special, high efficiency, calibrated gamma spectrometry device will be used for some dosimeters, allowing to measure an activity as low as 7. 10−2 Bq per sample. 103mRh activities will be measured on an absolute calibrated X spectrometry device. FLUOLE-2 experiment goal is to usefully complete the current experimental benchmarks database used for the validation of neutron calculation codes. This two-year program completes the initial FLUOLE program held in 2006–2007 in a geometry representative of 1300 MWe PWR.

Published
2016
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46. Noise Analysis Techniques Of In-core Modulation Experiments For The European Project CORTEX

Author

Ambrozic, Klemen, Lamirand, Vincent, Hübner, Sebastian, Hursin, Mathieu, Rais, Adolfo, Pakari, Oskari, Frajtag, Pavel, Fiorina, Carlo, and Pautz, Andreas

Abstract

This paper deals with the analysis of reactor modulation experiments for code validation in the framework of the Horizon 2020 European project CORTEX. The analysis is based on a statistical based approach on spectral powers and their phase shift angles calculations. The treatment of individual oscillations as independent aids in elimination of possible biases and correlations of consecutive oscillations. Results from one of the experimental campaign performed at the AKR-2 and CROCUS reactors are also presented.

Published
2020
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47. Review of kinetic modulation experiments in low power nuclear reactors

Author

Jiang, Yifeng, Geslot, Benoit, Lamirand, Vincent, Leconte, Pierre, Jiang, Yifeng, Geslot, Benoit, Lamirand, Vincent, and Leconte, Pierre

Abstract

The safety improvement of nuclear reactors requires continuous efforts in understanding the fundamental physical quantities related to the fission process. In neutronic models, the reactor dynamics is covered by the kinetic parameters to characterize the temporal behavior of the neutron population subject to perturbations. The reactor transfer function is a frequency domain analogy of this temporal description. It can be measured experimentally through transfer function analysis via noise analysis or kinetic modulation, for the study of reactor stability and kinetic parameters. This paper summarizes the experimental measurements of reactor transfer function through kinetic modulation. Extensive work have been conducted experimentally, starting from the beginning of reactor physics research. An overview is given regarding various experimental designs and conducted analyses. The concepts of the modulation system are also discussed. The current work is limited to online contents and internal archives of CEA Cadarache due to difficulties in accessing references traced back to 1950s.

Published
2020
Full Text
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