Your search keyword '"G. Pedroche"' showing total 6 results

1. Integral modelling of the ITER cooling water systems radiation source for applications outside of the Bio-shield

Author

Rafael Juarez, A. Kolsek, Y. Le Tonqueze, E. Polunovskiy, N. Ghirelli, G. Pedroche, M. De Pietri, Michael Loughlin, J. Alguacil, and Javier Sanz

Subjects

Work (thermodynamics), Neutron transport, Tokamak, Mechanical Engineering, Nuclear engineering, Radiation, 01 natural sciences, 010305 fluids & plasmas, Coolant, law.invention, Nuclear Energy and Engineering, law, Shield, 0103 physical sciences, Water cooling, Environmental science, General Materials Science, 010306 general physics, Civil and Structural Engineering, Electronic circuit

Abstract

During the plasma pulses, the neutron-induced activation of the cooling water will produce an important contribution to the radiation levels in the ITER Tokamak Complex. The resulting radiation field has a complex spatial distribution due to the combination of decay and production of radioisotopes in the intricate cooling lines that feed the numerous systems inside and outside the bio-shield. An accurate estimation of the cooling water radiation field is necessary to ensure that the radiological zoning is respected. As of today, this issue has been studied using simple, manually defined geometries with limited representation of the tens of thousands of components that constitutes the cooling circuits. This work describes the first production of a realistic and up-to-date integral neutronics modelling of all the cooling systems containing activated water beyond the bio-shield. The work was enabled by the development of computerized geometry modelling techniques to automatically simplify and dimension the system components. An independent review of the method ensured the validity of the simplified model. Moreover, automated scripts produced the activated water radiation source associated with the geometry model. The latter was obtained by linking thousands of cylinders, representing the coolant volumes, in chains of MCNP cells that reproduced the paths of the water lines inside the Tokamak Complex and, eventually, by calculating the radioisotopes activity in each cell. This methodology greatly speeds up the modelling time, reduces the risk of human error and enables the representation of the Tokamak Cooling Water System radiation source with an unprecedented degree of realism.

Published

2021

2. Shielding conceptual designs of ITER TCP ports to protect electronics

Author

P. Martínez-Albertos, G. Pedroche, M. Dremel, R. Pearce, M. Loughlin, Y. Le Tonqueze, J. Sanz, and R. Juárez

Subjects

Nuclear Energy and Engineering, Mechanical Engineering, General Materials Science, Civil and Structural Engineering

Published

2022

3. Shutdown dose rate mitigation in the ITER upper ports

Author

Antonio José Cano López, Rafael Juarez, Arkady Serikov, G. Pedroche, J. Guirao, Victor Udintsev, Javier Sanz, Luciano Bertalot, A. Kolsek, and Raul Pampin

Subjects

Materials science, Mechanical Engineering, Nuclear engineering, Shields, Plasma, 01 natural sciences, 010305 fluids & plasmas, Nuclear Energy and Engineering, Prompt neutron, 0103 physical sciences, Electromagnetic shielding, Water cooling, Neutron source, General Materials Science, Neutron, Duct (flow), 010306 general physics, Civil and Structural Engineering

Abstract

In this work, the D1SUNED code has been used to characterize the shutdown dose rate (SDDR) in the ITER Upper Port (UP) interspace due to activation induced by two neutron sources: plasma prompt neutrons and 17N decay neutrons emitted from the activated cooling water conducted through the UP. Furthermore, shielding measures have been proposed to mitigate the SDDR in the UP interspace; a set of conceptual shields has been designed and inserted into the MCNP computational model C-lite v2 covering the Vacuum Vessel UP Stub Extension and the UP Connecting Duct. The results have shown that the integration of proposed shields has significantly decreased the SDDR due to the activation induced by plasma prompt neutrons, while the activation induced by 17N decay neutron has a negligible contribution to the total SDDR in the ITER UP interspace.

Published

2018

4. Update in the nuclear responses of the European TBMs for ITER during operation and shutdown

Author

Aljaz Kolsek, Javier Sanz, Daniele Ugolini, Antonio José Cano López, J. Alguacil, Rafael Juarez, Italo Ricapito, Francisco Jose Calvo, G. Pedroche, Yves Poitevin, Patrick Sauvan, and Joelle Vallory

Subjects

Mechanical Engineering, Nuclear engineering, Shutdown, Blanket, 01 natural sciences, 7. Clean energy, 010305 fluids & plasmas, Nuclear Energy and Engineering, 0103 physical sciences, Environmental science, General Materials Science, 010306 general physics, Dose rate, Civil and Structural Engineering

Abstract

The depiction of the nuclear responses of the ITER European Test Blanket Modules (TBMs), Helium Cooled Lithium Lead (HCLL) and Helium Cooled Pebbles Bed (HCPB) is presented in this work. Following important components update, and important methodological advances, the nuclear heat and the tritium production have been revisited, giving new estimations 10% higher than the previous evaluation for nuclear heat in both TBMs and to 15% higher for HCPB T production. This has an impact on the thermo-mechanical design of the TBM and the tritium handling. In addition, the Shutdown Dose Rates in the respective port interspace have been characterized in local approach. It shows a performance that could imply compatibility with planned in-situ maintenance activities when analysed in global approach, an improvement with respect to previous evaluations.

Published

2018

5. Nuclear data for D1SUNED for the study of ITER planned in-situ maintenance dose scenarios

Author

Patrick Sauvan, G. Pedroche, J. Alguacil, Javier Sanz, and Rafael Juarez

Subjects

Tokamak, Mechanical Engineering, Shutdown, Nuclear engineering, Nuclear data, law.invention, Radiation exposure, Nuclear Energy and Engineering, law, Environmental science, General Materials Science, Neutron, Dose rate, Civil and Structural Engineering

Abstract

ITER will be the largest Tokamak in the world, and it is expected to produce a total of up to 2.8•1027 neutrons during its operation. The Tokamak infrastructure will become radioactive as the machine operates, which is an aspect that needs to be considered in the design of the planed in-situ maintenance activities. The occupational radiation exposure (ORE) must be accounted for, and an ALARA program must be implemented to minimize it. It requires the determination and analysis of shutdown dose rates fields, the purpose of D1SUNED tool. Common to all Direct one-step-based approaches, this tool needs to be fed with a nuclear data set tailored for each problem and produced ex professo. In this paper, we characterize the radioactive inventory relevant for the ORE of ITER maintenance activities using ACAB activation code. The ITER reference irradiation scenario SA-2 and the cooling times of interest 105 s and 106 s are considered. A comprehensive list of typical materials has been studied with detailed impurities content. The nuclear data set covers 99% of the radioactive inventory of concern, and all the pathways responsible for 99% of its production. It has been prepared following the ITER recommendations of cross-sections libraries and it has been verified against Rigorous-two steps calculations. This batch of nuclear data complements D1SUNED for shutdown dose rate exhaustive analysis for ITER with the perspective of maintenance according to the latest ITER nuclear data standards.

Published

2021

6. D1SUNED system for the determination of decay photon related quantities

Author

J. Alguacil, Rafael Juarez, Francisco Ogando, J.P. Catalan, G. Pedroche, Patrick Sauvan, and Javier Sanz

Subjects

Physics, Photon, Boosting (machine learning), Mechanical Engineering, 7. Clean energy, 01 natural sciences, 010305 fluids & plasmas, Computational physics, Acceleration, Nuclear Energy and Engineering, Neutron flux, 0103 physical sciences, Code (cryptography), Benchmark (computing), Nuclear fusion, General Materials Science, Neutron, 010306 general physics, Civil and Structural Engineering

Abstract

The neutron fields alter the radioactive inventory of the irradiated materials leading to subsequent decay photon fields. In some cases, these fields are of relevance either intended or undesired, normally involving safety and economics aspects. The determination of these fields can be of paramount complexity if high spatial resolution is required. The determination of these fields requires both radiation transport and activation calculations. The Direct-one-Step methodology, under the assumption that the radioactive inventory activity is lineal with the neutron flux, can address the problem with only one coupled neutron-photon transport calculation. In this paper the D1SUNED code for the calculation of decay photon field and related quantities using D1S methodology is presented. Calculation capabilities including the determination of 3D decay photon sources, filtering options, and other relevant features are presented. In terms of computational load, D1SUNED, which is based on MCNP5 code, presents improvements with respect to MCNP. It can save a 79% of the RAM memory used to store the geometry, a 98% of the loading time, and an acceleration of a factor two by controlling the decay photon emission, boosting the simulations for ITER-like problems. D1SUNED has been validated with the FNG benchmark experiment considering the null hypothesis rejection test and the C/E ratio with very positive results. As a consequence, D1SUNED has become a reference tool for the design of ITER, and other relevant nuclear fusion facilities.

Published

2020