Your search keyword '"G. Pedroche"' showing total 4 results

1. 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

2. Nuclear analysis of the ITER torus cryopumps

Author

A.J. Lopez-Revelles, R. Pearce, Javier Sanz, G. Pedroche, G. Bansal, A. Kolsek, Rafael Juarez, and M. Dremel

Subjects

Nuclear and High Energy Physics, Materials science, Phosphoric Acid Esters, Nuclear engineering, Iter tokamak, Torus, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Radiation flux, Neutron flux, 0103 physical sciences, 010306 general physics, Dose rate

Published

2019

3. Nuclear analysis of the ITER torus cryopumps.

Author

G. Pedroche, A.J. Lopez-Revelles, A. Kolsek, M. Dremel, G. Bansal, R. Pearce, J. Sanz, and R. Juarez

Subjects

TORUS, NEUTRON flux, RADIATION sources, TCP/IP, NEUTRON irradiation, MAINTENANCE

Abstract

The ITER Tokamak will feature six torus cryopumps (TCP) to maintain the vacuum requirements inside the vacuum vessel for plasma operation. They will be connected to the ITER vacuum vessel through the lower ducts, which have limited shielding to ensure an efficient pumping. Therefore, these ducts will represent a relevant path for radiation to travel from the plasma and affect diverse aspects of the ITER facility, such as the electronics allocation or the maintenance operations during the machine shutdown. Previous analyses have addressed these important aspects. Nonetheless, limitations in those studies and design evolution have justified a new analysis, specifically dedicated to the TCP final design review. The results of the nuclear analysis are presented here focusing on the B1 level port cell #4. The TCP design and the associated and neighboring equipment have evolved and updated models have been considered. The TCP modelling has required an explicit heterogeneous treatment of the internal parts. The radiation source from the divertor cooling water pipes running along the port cell ceiling has been considered with the latest available source definition. In terms of methodology, one major improvement has been the modelling of the radiation transmission from C-model to the Tokamak Complex model. Another important improvement has been the consideration of D1SUNED for the determination of shutdown dose rates, covering a broader fraction of the radioactive inventory than in previous studies. The following quantities have been determined: neutron flux, absorbed dose to silicon, 1 MeV equivalent neutron fluence and shutdown dose rates (SDDR) after 106 s of cooling time. Finally, a set of proposals have been made to considerably mitigate the SDDR after 106 s of cooling. This work represents a realistic and matured source of information of the radiation environment in the ITER TCP port cells as presented in the final design review. [ABSTRACT FROM AUTHOR]

Published

2019

4. The use of the long modular diagnostics shield module to mitigate shutdown dose rates in the ITER diagnostics equatorial ports.

Author

R. Juárez, J. Guirao, A. Kolsek, A. Lopez, G. Pedroche, L. Bertalot, V.s. Udintsev, M.j. Walsh, P. Sauvan, and J. Sanz

Subjects

PLASMA diagnostics, VACUUM, NUCLEAR fusion, NEUTRONS, NEUTRON flux

Abstract

The ITER equatorial port plugs are submitted to a drained weight limit of 45 T. This limitation can conflict with their radiation shielding demands, although some weight margin is being discussed. The port interspaces are subject to a shutdown dose rate limit of 100 µSv h−1 after 106 s of cooling time. To meet it, the port plugs must show a neutron flux attenuation comparable to their neighborhood, despite considering penetrations to host systems. Most of this task relies on the drawer shield module (DSM). In this work, two DSM concepts are analyzed with this perspective: the box-based DSM and the modular DSM. Regardless the penetrations, the box-based DSM leads to unsatisfactory port plugs to meet both weight and SDDR requirements. On the contrary, the modular DSM shows a performance which allows for the adoption of such DSM concept, or equivalent, a port may comply with both requirements at the same time, provided the penetrations are well designed. [ABSTRACT FROM AUTHOR]

Published

2018