Your search keyword '"Fabio Moro"' showing total 124 results

1. Design and Integration of the EU-DEMO Water-Cooled Lead Lithium Breeding Blanket

Author

Pietro Arena, Gaetano Bongiovì, Ilenia Catanzaro, Cristiano Ciurluini, Aldo Collaku, Alessandro Del Nevo, Pietro Alessandro Di Maio, Matteo D’Onorio, Fabio Giannetti, Vito Imbriani, Pietro Maccari, Lorenzo Melchiorri, Fabio Moro, Rocco Mozzillo, Simone Noce, Laura Savoldi, Simone Siriano, Alessandro Tassone, and Marco Utili

Subjects

DEMO, WCLL, breeding blanket, integration, Technology

Abstract

The water-cooled lead lithium breeding blanket (WCLL BB) is one of two BB candidate concepts to be chosen as the driver blanket of the EU-DEMO fusion reactor. Research activities carried out in the past decade, under the umbrella of the EUROfusion consortium, have allowed a quite advanced reactor architecture to be achieved. Moreover, significant efforts have been made in order to develop the WCLL BB pre-conceptual design following a holistic approach, identifying interfaces between components and systems while respecting a system engineering approach. This paper reports a description of the current WCLL BB architecture, focusing on the latest modifications in the BB reference layout aimed at evolving the design from its pre-conceptual version into a robust conceptual layout. In particular, the main rationale behind design choices and the BB’s overall performances are highlighted. The present paper also gives an overview of the integration between the BB and the different in-vessel systems interacting with it. In particular, interfaces with the tritium extraction and removal (TER) system and the primary heat transfer system (PHTS) are described. Attention is also paid to auxiliary systems devoted to heat the plasma, such as electron cyclotron heating (ECH). Indeed, the integration of this system in the BB will strongly impact the segment design since it envisages the introduction of significant cut-outs in the BB layout. A preliminary CAD model of the central outboard blanket (COB) segment housing the ECH cut-out has been set up and is reported in this paper. The chosen modeling strategy, adopted loads and boundary conditions, as well as obtained results, are reported in the paper and critically discussed.

Published

2023

2. Neutronics Assessment of the Spatial Distributions of the Nuclear Loads on the DEMO Divertor ITER-like Targets: Comparison between the WCLL and HCPB Blanket

Author

Simone Noce, Davide Flammini, Pasqualino Gaudio, Michela Gelfusa, Giuseppe Mazzone, Fabio Moro, Francesco Romanelli, Rosaria Villari, and Jeong-Ha You

Subjects

PFC, DEMO, neutronics, divertor, MCNP, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

The Plasma Facing Components (PFCs) of the divertor target contribute to the fundamental functions of heat removal and particle exhaust during fusion operation, being subjected to a very hostile and complex loading environment characterized by intense particles bombardment, high heat fluxes (HHF), varying stresses loads and a significant neutron irradiation. The development of a well-designed divertor target, which represents a crucial step in the realization of DEMO, needs the assessment of all these loads as accurately as possible, to provide pivotal data and indications for the design and structural performance prediction of the PFCs. In a particular way, this study is fully devoted to the comprehension of the distributions on the divertor target of the main nuclear loads due to neutron irradiation, performed for the first time using an extremely detailed approach. This work has been carried-out considering the latest configuration of the DEMO reactor, including the updated design of the divertor and ITER-Like PFCs geometry, varying the blanket layout (Water Cooled Lithium Lead—WCLL and Helium Cooled Pebble Bed—HCPB), thus evaluating the impact of the different blanket concept on the above-mentioned distributions. Neutronics analyses have been performed with MCNP5 Monte Carlo code and JEFF3.3 nuclear data libraries. 3D DEMO MCNP models have been created, focusing in particular on a thorough representation of the divertor and PFCs, allowing for the assessment of the distributions of the main nuclear loads: radiation damage (dpa/FPY), He-production rate (appm/FPY) and nuclear heating density (W/cm3) and total nuclear power deposition (MW). These results are presented by means of 2D maps and plots for each PFCs sub-component both for WCLL and HCPB blanket case: W-monoblocks, Cu-interlayers\CuCrZr-pipe and PFC-CB (Cassette Body) supports made of Eurofer steel.

Published

2023

3. Preliminary Assessment of Radiolysis for the Cooling Water System in the Rotating Target of SORGENTINA-RF

Author

Camillo Sartorio, Massimo Angiolini, Davide Flammini, Antonino Pietropaolo, Pietro Agostini, Ciro Alberghi, Luigi Candido, Marco Capogni, Mauro Capone, Sebastiano Cataldo, Gian Marco Contessa, Marco D’Arienzo, Alessio Del Dotto, Dario Diamanti, Danilo Dongiovanni, Mirko Farini, Paolo Ferrari, Angela Fiore, Nicola Fonnesu, Manuela Frisoni, Gianni Gadani, Angelo Gentili, Giacomo Grasso, Manuela Guardati, David Guidoni, Marco Lamberti, Luigi Lepore, Andrea Mancini, Andrea Mariani, Ranieri Marinari, Giuseppe A. Marzo, Bruno Mastroianni, Fabio Moro, Agostina Orefice, Valerio Orsetti, Tonio Pinna, Antonietta Rizzo, Alexander Rydzy, Stefano Salvi, Demis Santoli, Alessia Santucci, Luca Saraceno, Salvatore Scaglione, Valerio Sermenghi, Emanuele Serra, Andrea Simonetti, Ivan Panov Spassovsky, Nicholas Terranova, Silvano Tosti, Alberto Ubaldini, Marco Utili, Pietro Zito, Danilo Zola, Konstantina Voukelatou, and Giuseppe Zummo

Subjects

radiolysis, cooling water, neutron source, fusion, Environmental technology. Sanitary engineering, TD1-1066

Abstract

The SORGENTINA-RF project aims at developing a 14 MeV fusion neutron source featuring an emission rate in the order of 5–7 × 1013 s−1. The plant relies on a metallic water-cooled rotating target and a deuterium (50%) and tritium (50%) ion beam. Beyond the main focus of medical radioisotope production, the source may represent a multi-purpose neutron facility by implementing a series of neutron-based techniques. Among the different engineering and technological issues to be addressed, the production of incondensable gases and corrosion product into the rotating target deserves a dedicated investigation. In this study, a preliminary analysis is carried out, considering the general layout of the target and the present choice of the target material.

Published

2022

4. Risk Management of a Fusion Facility: Radiation Protection and Safety Integrated Approach for the Sorgentina-RF Project

Author

Gian Marco Contessa, Nicholas Terranova, Tonio Pinna, Danilo Nicola Dongiovanni, Marco D’Arienzo, Fabio Moro, Paolo Ferrari, Antonino Pietropaolo, and The SRF Collaboration

Subjects

fusion accelerators, safety analysis, radiation protection, Environmental technology. Sanitary engineering, TD1-1066

Abstract

The Sorgentina-RF project will use fusion neutrons to produce 99Mo, a precursor of 99mTc, by irradiating natural molybdenum. 99Mo is produced by means of the inelastic reaction 100Mo(n, 2n)99Mo on 100Mo, which is an isotope of natural Mo. From a functional point of view, the project consists of two parts: an irradiation neutron source at 14 MeV and a radiochemistry facility dedicated to the extraction of 99Mo from the solid sample irradiated by the neutron source. Given the degree of complexity of such a facility, the risk management strategy is based on an integrated approach that combines the engineering method of safety with that of radiation protection. Therefore, design issues were studied and systems were planned according to both radiation protection and safety criteria already in the preliminary phase, allowing a general strengthening of the safety of the plant. This work discusses the preventive analysis and the related activities to identify the ways in which potential exposures to radiation may occur. In particular, the preliminary safety analysis is presented for the innovative rotating target, developed for the project, and, accordingly, some specific technical solutions are given to refine the initial design of the facility.

Published

2022

5. The DEMO Water-Cooled Lead–Lithium Breeding Blanket: Design Status at the End of the Pre-Conceptual Design Phase

Author

Pietro Arena, Alessandro Del Nevo, Fabio Moro, Simone Noce, Rocco Mozzillo, Vito Imbriani, Fabio Giannetti, Francesco Edemetti, Antonio Froio, Laura Savoldi, Simone Siriano, Alessandro Tassone, Fernando Roca Urgorri, Pietro Alessandro Di Maio, Ilenia Catanzaro, and Gaetano Bongiovì

Subjects

DEMO, nuclear fusion, breeding blanket, nuclear reactor, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

The Water-Cooled Lead–Lithium Breeding Blanket (WCLL BB) is one of the two blanket concept candidates to become the driver blanket of the EU-DEMO reactor. The design was enacted with a holistic approach. The influence that neutronics, thermal-hydraulics (TH), thermo-mechanics (TM) and magneto-hydro-dynamics (MHD) may have on the design were considered at the same time. This new approach allowed for the design team to create a WCLL BB layout that is able to comply with different foreseen requirements in terms of integration, tritium self-sufficiency, and TH and TM needs. In this paper, the rationale behind the design choices and the main characteristics of the WCLL BB needed for the EU-DEMO are reported and discussed. Finally, the main achievements reached during the pre-conceptual design phase and some remaining open issues to be further investigated in the upcoming conceptual design phase are reported as well.

Published

2021

6. Tritium Transport in WCLL Outboard Breeding Blanket of EU-DEMO Reactor Under Pulsed Plasma Operation

Author

Ciro Alberghi, Marco Utili, Simone Noce, Luigi Candido, Massimo Zucchetti, Fabio Moro, and Pietro Arena

Subjects

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

Published

2023

7. Nuclear Analyses of ITER Diagnostics Lower Ports

Author

Rosaria Villari, Daniel NAgy, Luciano Bertalot, Andrea Colangeli, Davide Flammini, Nicola Fonnesu, Giovanni Mariano, Fabio Moro, and Eduard Polunovskiy

Subjects

Nuclear and High Energy Physics, Condensed Matter Physics

Published

2022

8. Nuclear Analysis for the Upper Ports in the NB Cell in ITER

Author

Davide Flammini, Sunil Pak, Andrea Colangeli, Nicola Fonnesu, Frederik Sorel Mballa Mballa, Giovanni Mariano, Fabio Moro, Eduard Polunovskiy, and Rosaria Villari

Subjects

Nuclear and High Energy Physics, Condensed Matter Physics

Published

2022

9. Biotécnicas da reprodução em bovinos aplicações práticas

Author

Marcelo Marcondes Seneda, Deborah Nakayama Yokomizo, Fernanda Amarante Mendes de Oliveira, Mariana Moreira dos Anjos, and Fabio Moro

Published

2022

10. Design and FEM modeling of a fire resistant cabinet for fusion environment

Author

Rafal Ortwein, Basilio Esposito, Daniele Marocco, Jerzy Kotula, Danilo Dongiovanni, Waldemar Maciocha, Dariusz Bocian, and Fabio Moro

Subjects

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

Published

2023

11. Nuclear Analyses for the Assessment of the Loads on the ITER Radial Neutron Camera In-Port System and Evaluation of Its Measurement Performances

Author

Fabio Moro, Daniele Marocco, Francesco Belli, Giorgio Brolatti, Andrea Colangeli, Fabio Crescenzi, Davide Flammini, Nicola Fonnesu, Giada Gandolfo, Ryszard Kantor, Giovanni Mariano, Domenico Marzullo, Salvatore Podda, Dustin Sancristobal, Rosaria Villari, Basilio Esposito, Moro, F, Marocco, D, Belli, F, Brolatti, G, Colangeli, A, Crescenzi, F, Flammini, D, Fonnesu, N, Gandolfo, G, Kantor, R, Mariano, G, Marzullo, D, Podda, S, Sancristobal, D, Villari, R, and Esposito, B

Subjects

neutron diagnostics, radial neutron camera (RNC), Nuclear and High Energy Physics, Collimators, Neutron, Plug, Plasma, Plugs, Collimator, ITER, MCNP, neutron measurement, Heating system, Neutrons, Detector, Monte Carlo methods, Detectors, Heating systems, Condensed Matter Physics, Plasmas, Solid modeling, neutron measurements, radiation transport, Monte Carlo method, neutron diagnostic

Abstract

The radial neutron camera (RNC) is a key ITER diagnostic system designed to measure the uncollided 14- and 2.5-MeV neutrons from deuterium-tritium (DT) and deuterium-deuterium (DD) fusion reactions, through an array of detectors covering a full poloidal plasma section along collimated lines of sight (LoS). Its main objective is the assessment of the neutron emissivity/alpha source profile and the total neutron source strength, providing spatially resolved measurements of several parameters needed for fusion power estimation, plasma control, and plasma physics studies. The present RNC layout is composed of two fan-shaped collimating structures viewing the plasma radially through vertical slots in the diagnostic shielding module (DSM) of ITER Equatorial Port 1 (EP01): the ex-port subsystem and the in-port one. The ex-port subsystem, devoted to the plasma core coverage, extends from the Port Interspace to the Bioshield Plug: it consists of a massive shielding unit hosting two sets of collimators lying on different toroidal planes, leading to a total of 16 interleaved LoS. The in-port system consists of a cassette, integrated inside the port plug DSM, containing two detectors per each of the six LoS looking at the plasma edges. The in-port system must guarantee the required measurement performances in critical operating conditions in terms of high radiation levels, given its proximity to the plasma neutron source. This article presents an updated neutronic analysis based on the latest design of the in-port system and port plug. It has been performed by means of the Monte Carlo MCNP code and provides nuclear loads on the in-port RNC during normal operating conditions (NOC) and inputs for the measurement performance analysis.

Published

2022

12. Strategy and guidelines for the calibration of the ITER Radial Neutron Camera

Author

Salvatore Podda, Fabio Moro, Ryszard Miklaszewski, Barbara Bienkowska, Adam Szydlowski, B. Esposito, Daniele Marocco, Sean Conroy, Marco Cecconello, Cecconello, M., Miklaszewski, R., Marocco, D., Conroy, S., Moro, F., Esposito, B., Podda, S., Bienkowska, B., and Szydlowski, A.

Subjects

Accuracy and precision, Physics - Instrumentation and Detectors, Nuclear engineering, Monte Carlo method, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Measure (physics), FOS: Physical sciences, 01 natural sciences, Radial Neutron Camera, 010305 fluids & plasmas, ComputerApplications_MISCELLANEOUS, ITER, 0103 physical sciences, Calibration, Emissivity, General Materials Science, Neutron, 010306 general physics, Image resolution, Civil and Structural Engineering, Physics, Mechanical Engineering, Astrophysics::Instrumentation and Methods for Astrophysics, Instrumentation and Detectors (physics.ins-det), Fusion power, Nuclear Energy and Engineering

Abstract

A calibration procedure is proposed for ITER Radial Neutron Camera that relies on embedded sources, reference ITER pulses and cross-calibration with ITER fission chambers and activation system coupled to Monte Carlo simulations of radiation transport. The proposed procedure would allow to measure the neutron emissivity profile and of the fusion power with 10 % accuracy and precision, a time resolution of 10 ms and a spatial resolution of a/10 for ITER entire life-time.

Published

2019

13. The ITER radial neutron camera in-port system: Nuclear analyses in support of its design development

Author

Salvatore Podda, Davide Flammini, Daniele Marocco, Ryszard Kantor, A. Colangeli, Fabio Moro, F. Pompili, Marco Riva, and B. Esposito

Subjects

Physics, Toroid, Mechanical Engineering, Nuclear engineering, Detector, Port (circuit theory), 01 natural sciences, 010305 fluids & plasmas, Signal-to-noise ratio, Nuclear Energy and Engineering, Neutron flux, 0103 physical sciences, Electromagnetic shielding, Emissivity, General Materials Science, Neutron, 010306 general physics, Civil and Structural Engineering

Abstract

The ITER Radial Neutron Camera (RNC) is a multichannel detection system hosted in the Equatorial Port Plug 1 (EPP 1). It is designed to measure the uncollided neutron flux from the plasma, providing information on the neutron emissivity profile and total strength. The RNC structure consists of two sub-systems based on fan-shaped arrays of cylindrical collimators: the ex-port system, covering the plasma core with 2 sets of lines of sight lying on different toroidal planes, and the in-port system, enclosed in a dedicated cassette within the EPP1 diagnostic shielding module, for the measurement of neutrons generated in the plasma edge. Due to the harsh environment in which it has to operate, the design of the in-port RNC system is particularly critical both from the measurements point of view (low signal to noise ratio induced by the high level of scattered neutrons at the detector positions) and from the structural point of view. The paper presents the results of the neutronic analyses performed with the MCNP Monte Carlo code with the aim of optimizing the in-port RNC design in order to enhance the diagnostic measurement performance and evaluating the nuclear loads that have to be withstand by its structural elements, detectors and associated components.

Published

2019

14. Addressing the feasibility of inboard direct-line injection of high-speed pellets, for core fueling of DEMO

Author

Chr. Day, B. Pégourié, Fabio Moro, Bernhard Ploeckl, A. Colangeli, Rocco Mozzillo, T. E. Gebhart, Larry R. Baylor, F. Bombarda, Antonio Frattolillo, Fabio Cismondi, Silvio Migliori, F. Iannone, Peter Lang, G. D’Elia, S.K. Combs, F. Poggi, Salvatore Podda, Steven J. Meitner, Frattolillo, A., Baylor, L. R., Bombarda, Andrea, Cismondi, F., Colangeli, Raimondo, Combs, S. K., Day, C., D'Elia, G., Gebhart, T. E., Iannone, F., Lang, P. T., Meitner, S. J., Migliori, S., Moro, F., Mozzillo, R., Pegourie, B., Ploeckl, B., Podda, S., Poggi, F., Bombarda, F., and Colangeli, A.

Subjects

EU-DEMO tokamak, 010302 applied physics, Materials science, Tokamak, Line-of-sight, Straight guide tubes, Mechanical Engineering, Pellets, Conical surface, Mechanics, Curvature, 7. Clean energy, 01 natural sciences, High Field Side high-speed pellet injection, 010305 fluids & plasmas, law.invention, Nuclear Energy and Engineering, Neutron flux, law, 0103 physical sciences, Electromagnetic shielding, General Materials Science, Neutron, Civil and Structural Engineering

Abstract

Pellet injection represents, to date, the most promising option for core fuelling of the EU-DEMO tokamak. Simulations with the HPI2 pellet ablation/deposition code indicate, however, that sufficiently deep fuel deposition requires injection from the High Field Side (HFS) at velocities ≳1 km/s. Two complementary inboard injection schemes are being explored: one makes use of guide tubes with curvature radii ≥6 m in the attempt of preserving pellet integrity at speeds of ˜1 km/s, the other is investigating the feasibility of injecting high-speed (˜3 km/s) pellets along “direct line of sight” (DLS) trajectories, from either the HFS or a vertical port. Options using quasi-vertical DLS paths routed across the upper vertical port have been explored first, as they can be more easily integrated, Unfortunately, the radial position of the available vertical access (≳9 m from the machine axis) turns out to be unfavorable; further simulations with the HPI2 code predict indeed that vertical injection may be effective only if pellets trajectories are well inboard the magnetic axis. High-speed injection through oblique inboard “DLS” paths, not interfering with the Central Solenoid (CS), are instead predicted to yield good performance, provided that the injection location is ≲2.5 m from the equatorial mid-plane. The angular spread of high-speed free-flight pellets, recently measured using an existing facility, turns out to be enclosed within ˜ 0.7°. This scatter cone may require significant cut off volume of the Breeding Blanket (BB). Moreover, DLS in-vessel conical penetrations may increase the neutron flux outside of the bio-shield, and also result in a significant heat load in the cryogenic pellet source. These issues are being investigated, to identify suitable shielding strategies; preliminary results are reported. The suitability of straight guide tubes to reduce the scatter cone, and hence the corresponding open cross section on BB penetration and the neutron streaming, will be explored as a further step. © 2019 Elsevier B.V.

Published

2019

15. Contribution of random noise in the ITER RNC diamond neutron detectors pulses to the counting rate uncertainty

Author

Salvatore Podda, F. Pompili, Daniele Marocco, Marco Riva, Fabio Moro, Fabio Pollastrone, B. Esposito, Riva, M., Esposito, B., Marocco, D., Moro, F., Podda, S., Pompili, F., and Pollastrone, F.

Subjects

Physics::Instrumentation and Detectors, Neutron emission, engineering.material, Collimated light, Optics, Random noise, ITER, Emissivity, Nuclear fusion, Neutron detection, General Materials Science, Neutron, Nuclear Experiment, Civil and Structural Engineering, Physics, Radial neutron camera, business.industry, Mechanical Engineering, Detector, Diamond, Diamond detector emulator, Nuclear Energy and Engineering, engineering, business

Abstract

The main goal of the ITER Radial Neutron Camera (RNC) is to provide the plasma neutron emission profile (neutron emissivity) through measurement of the uncollided 14 MeV and 2.5 MeV neutrons from deuterium-tritium (DT) and deuterium-deuterium (DD) fusion reactions. The system is based on an array of detectors (diamonds are among the candidate detectors) located in collimated lines of sight (LOS) viewing the plasma through the ITER Equatorial Port Plug #1. Tomographic reconstruction techniques are used to calculate the neutron emissivity. The contribution of random noise on diamond detector pulses to the count rate uncertainty is investigated in this paper. The energy spectrum of the neutrons impinging on the detector has been calculated by means of MCNP calculations for one line of sight of the RNC In-Port system. The spectrum has been convoluted with the diamond detector response functions and the Pulse Height Spectrum (PHS) has been obtained. Experiments have been carried out with the CAEN™ 5810D detector emulator, that is able to produce arbitrary pulse height distributions as those expected in the ITER RNC. Random noise has been added on each detector pulse of the distribution using the detector emulator. The resulting uncertainty produced on the count rate has been evaluated as a function of the random noise level.

Published

2019

16. Integral Benchmark Experiments on a Large Copper Block Using the GELINA Accelerator to Validate natCu Neutron Cross Sections From Different Neutron Cross-Sectional Databases

Author

Dong Hwan Dani Kim, Markus Nyman, Mario Pillon, Maurizio Angelone, Arjan Plompen, Fabio Moro, Pillon, M., Angelone, M., Moro, F., Kim, D. H. D., Nyman, M., and Plompen, A. J. M.

Subjects

Nuclear and High Energy Physics, Neutron transport, Nuclear Theory, computer.software_genre, 01 natural sciences, 010305 fluids & plasmas, Cross section (physics), neutron, radiation detectors, Neutron flux, 0103 physical sciences, Neutron, Nuclear Experiment, Physics, Database, neutrons, Nuclear data, Monte Carlo methods, Condensed Matter Physics, Neutron temperature, Monte Carlo method, neutron source, neutron shielding, neutron sources, Cathode ray, computer, Intensity (heat transfer)

Abstract

A neutronics integral benchmark experiment on a pure copper block, aimed at testing and validating recent copper nuclear data libraries, has been performed at Geel Electron LINear Accelerator Facility (GELINA). GELINA is a powerful photoneutron source using a 75- $\mu \text{A}$ , 110-MeV electron beam impinging on a depleted U rotating target, producing a white neutron spectrum ranging from the epithermal region up to about 20 MeV with a mean energy of about 1.4 MeV and intensity up to $3.2 \times 10^{13}$ n/s. A large natCu block (dimensions $60 \times 60 \times 60$ cm3) has been positioned at 100 cm from the target. Thin activation foils were used as neutron flux probes and located inside the block in six positions at different depths with respect to the main neutron propagation direction. Materials whose activation cross section are sensitive to different neutron energy ranges were used, and the measured fluxes were compared with calculations performed using the MCNP6 neutron transport code coupled to different neutron cross-sectional databases (FENDL3.1, JEFF33_T2, and ENDF 7.1). The MCNP6 calculation also used the neutron spectrum produced by the GELINA accelerator. This is the first time that a neutronics integral experiment on copper is performed using such a white neutron spectrum and the results of our comparison could be used to validate the neutron copper cross sections in the neutron energy range covered by GELINA. The C/E results, taking into account the sources of uncertainties, are satisfactory: no large differences are observed among the result obtained using the three cross-sectional databases; however, the JEFF-3.3 seems, slightly, better predict the results.

Published

2019

17. Preliminary evaluations of the environmental impact for the production of 99Mo by fusion neutrons

Author

Fabio Moro, Marco D’Arienzo, Gian Marco Contessa, Antonino Pietropaolo, M. Frisoni, P. Ferrari, R. Panichi, Contessa, G. M., D'Arienzo, M., Frisoni, M., Ferrari, P., Panichi, R., Moro, F., and Pietropaolo, A.

Subjects

education.field_of_study, Waste management, 010308 nuclear & particles physics, Population, General Physics and Astronomy, Radioactive waste, 02 engineering and technology, Raw material, 021001 nanoscience & nanotechnology, 01 natural sciences, 0103 physical sciences, Neutron source, Production (economics), Environmental science, Neutron, Environmental impact assessment, 0210 nano-technology, education, Neutron irradiation

Abstract

ENEA is developing an accelerator-driven 14 MeV neutron source exploiting the deuterium–tritium fusion reaction to produce 99Mo medical radioisotope as an alternative production route not based on fission reactors. It is expected that, during normal operation, a number of radionuclides, generated by means of neutron irradiation on the raw material (natural Molybdenum), will be produced and managed. The present manuscript, as foreseen by national law, discusses a hypothetical scenario to test the environmental screening models, in turn evaluating the mechanisms and parameters which affect and control the path of liquid effluents potentially released during normal operation of the facility. The aim is to estimate the amount of radioactivity to be operated and the fraction potentially discharged in this hypothetical scenario, so as to ensure that the radioactive material can be managed without any risk for the population and the environment, according to national regulations and thoroughly fulfilling the international guidelines.

Published

2021

18. Neutron streaming analyses and shielding optimization through ECRH openings in DTT Tokamak building

Author

R. Luis, A. Romano, Davide Flammini, R. Remetti, Rosaria Villari, N. Fonnesu, Gustavo Granucci, A. Colangeli, Fabio Moro, Saul Garavaglia, G. Mariano, Colangeli, A., Flammini, D., Fonnesu, N., Garavaglia, S., Granucci, G., Luis, R., Mariano, G., Moro, F., Romano, A., Remetti, R., and Villari, R.

Subjects

Neutron transport, Tokamak, Nuclear engineering, Population, 01 natural sciences, 010305 fluids & plasmas, law.invention, Radiation shielding, law, 0103 physical sciences, MCNP, Neutronics, General Materials Science, Neutron, ECRH, Fusion devices, 010306 general physics, education, Civil and Structural Engineering, Physics, education.field_of_study, Mechanical Engineering, Divertor, Neutral beam injection, Electric power transmission, Nuclear Energy and Engineering, Electromagnetic shielding

Abstract

The Divertor Tokamak Test facility (DTT) will be a superconductive machine that aims at studying the power exhaust issue in a DEMO relevant environment. A significant power across the separatrix (compared to the radius of the machine), PSep/R ≅15 MW/m is of primary importance to fulfill this requirement and it can be obtained by injecting to the plasma up to 45 MW of additional power. This amount of power will be reached with a mix of Heating and Current Drive (HCD) systems: Electron Cyclotron Resonance Heating (ECRH), Ion Cyclotron Resonance Heating (ICRH) and Negative Neutral Beam Injection (NNBI). Power supply and wave generators of HCD will be hosted in remote-control buildings around the DTT Tokamak hall, and thus several ducts have been designed to connect the systems to the machine. The evacuated transmission lines will pass through dedicated holes in the main building making almost empty and big penetrations which cause a large neutron streaming through the walls. This work is devoted to a three-dimensional neutronics study, in support of the DTT licensing procedure, addressing the neutron and gamma streaming through the ECRH penetrations in order to optimize and determine the effectiveness of several proposed shielding options required to protect workers, population and auxiliary systems. Neutron and gamma transport simulations were carried out with the MCNP5 Monte Carlo code. Surface sources of neutrons and gammas have been used to propagate the radiation outside the penetrations. The ADVANTG hybrid transport code has been also used for variance reduction techniques in order to obtain statistically significant results in regions located several meters away from the plasma source. The results of the calculations are presented and discussed as well as the effectiveness of the proposed options to mitigate the radiation streaming and to reduce the doses outside the tokamak hall.

Published

2021

19. Cambodian Performing Arts in the Era of UNESCO’s Intangible Cultural Heritage

Author

Fabio Morotti

Subjects

Anthropology, GN1-890, Dramatic representation. The theater, PN2000-3307

Abstract

UNESCO’s protection of Intangible Cultural Heritage (ICH) has been a topic of ongoing debate inthe field of Cambodian performing arts. UNESCO’s recognition as ICH means that international attention and renewed economic opportunities arise for the selected performing arts and thus can help to preserve cultural practices that are at risk of being lost. In Cambodia, only a handful of teachers and performers survived the brutalities of Pol Pot’s regime (1975-79), and the incorporation of the artistic traditions into a global scenario, also thanks to the UNESCO cultural strategy, has led to the possibility of revitalizing and rebuilding both old and new repertoires. This is certainly the case regarding the musical tradition of Chapei Dang Veng and the dance-drama Lkhon Khol Wat Svay Andet, registered in the “List of the Intangible Cultural Heritage in Need of Urgent Safeguarding” in 2016 and 2018 respectively. However, considering the “branding” effect of listing and heritage-making, ICH seems to open the doors to mass tourism and in general favors over-commercialization and folklorization of cultural practices, leading to the erosion of their religious significance.

Published

2023

20. On the slowing down of 14 MeV neutrons

Author

Roberto Bedogni, Fabio Moro, Davide Flammini, Antonino Pietropaolo, Herwig, Kenneth W., Flammini, D., Bedogni, R., Moro, F., and Pietropaolo, A.

Subjects

Physics, Nuclear and High Energy Physics, Nuclear Theory, Monte Carlo method, neutron moderators, Fusion neutrons, 01 natural sciences, 010305 fluids & plasmas, Monte Carlo simulations, Nuclear physics, Nuclear Energy and Engineering, 0103 physical sciences, Physics::Accelerator Physics, Neutron source, neutron sources, Neutron, Nuclear Experiment, 010306 general physics

Abstract

An experimental procedure is assessed to obtain moderated neutron fields starting from almost monochromatic 14 MeV neutrons generated by means of an accelerator-driven D-T source. The use of a metallic pre-moderator and a standard hydrogen-containing moderator is effective in producing neutron spectra featuring a thermal peak and an epithermal slowing down tail extending up to 14 MeV. The performance of proposed moderation system was investigated by means of MCNP Monte Carlo calculations, benchmarked against experimental measurements using an explorative set up, assembled at the Frascati Neutron Generator. The benchmarked calculations allow at making predictions about the brilliance of a 14 MeV neutron moderator in view of possible applications in neutron science.

Published

2020

21. Comparison between measurement and calculations for a 14 MeV neutron water activation experiment

Author

Massimo Angelone, G. Mariano, Davide Flammini, G. Pagano, F. Andreoli, Antonino Pietropaolo, U. Besi Vetrella, C.R. Nobs, Rosaria Villari, J. Naish, L.W. Packer, Fabio Moro, Stefano Loreti, S. Fiore, Mario Pillon, A. Colangeli, Nicholas Terranova, G. Mazzitelli, and P. Del Prete

Subjects

Materials science, 010308 nuclear & particles physics, Water flow, Physics, QC1-999, Gamma ray, Nuclear data, Scintillator, 01 natural sciences, Nuclear physics, Neutron generator, 0103 physical sciences, Water cooling, Neutron, 010306 general physics, Delayed neutron

Abstract

The nuclear heat loads due to gamma rays emitted from the decay of 16N and delayed neutrons from17N, generated by the activation of water in cooling circuits, are critical for ITER design. The assessment of nuclear heating from activated water is complex; it requires temporal and spatial dependent transport and activation calculations taking into account variation of irradiation, water flow conditions and cooling circuits’ parameters. A water activation experiment has been recently conducted at the14 MeV Frascati Neutron Generator (FNG) in order to validate the methodology for water activation assessment used for ITER and to reduce the safety factors applied to the calculation results, which have a large impact on the schedule, commissioning and licensing. Water circulating inside an ITER First Wall (FW) mock-up was irradiated with 14 MeV neutrons and then measured using a large CsI scintillator detector. The system consists of a closed water loop where the cooling water, transiting through an ITER FW mock-up, is irradiated by FNG. The induced 16N activity via 14 MeV neutrons interactions with 16O via the 16O(n,p)16N reaction is measured in a dedicated counting station via an expansion volume. The water then passes to a much larger holding delay tank, and after several 16N half-lives decay time, it is then recirculated and exposed again to neutrons in the ITER First Wall (FW) mock-up. The measured 16N activity is obtained measuring the emitted characteristic 6.13 and 7.12 MeV gamma-rays. Calculations were performed in an accurate model of the FW mock-up using the MCNP Monte Carlo code and FENDL-3.1 nuclear data library to obtain the predicted flux impinging on the water. The EASY-2007 inventory code was used to predict the 16N activity. In this work, a comparison between measurements and calculations is reported together with associated uncertainty analysis.

Published

2020

22. Pre-analysis of the WCLL breeding blanket mock-up neutronics experiment at the frascati neutron generator

Author

Davide Flammini, Fabio Moro, G. Mariano, Rosaria Villari, Barbara Caiffi, N. Fonnesu, Massimo Angelone, A. Colangeli, Flammini, D., Angelone, M., Caiffi, B., Colangeli, A., Fonnesu, N., Mariano, G., Moro, F., and Villari, R.

Subjects

Neutron transport, Nuclear engineering, Neutronic, Benchmark, Breeding blanket, DEMO, MCNP, Neutronics, TPR, WCLL, Blanket, 01 natural sciences, 7. Clean energy, 010305 fluids & plasmas, Tritium breeding ratio, Neutron generator, 0103 physical sciences, General Materials Science, Neutron, 010306 general physics, Civil and Structural Engineering, Mechanical Engineering, Fusion power, Nuclear Energy and Engineering, Mockup, Electromagnetic shielding, Environmental science

Abstract

The Water Cooled Lithium Lead (WCLL) is one of the breeding blanket (BB) concept candidate for the future European Demonstration Fusion Power Reactor (DEMO). In the frame of the EUROfusion Consortium, a WCLL BB mock-up neutronics experiment will be performed at the 14 MeV Frascati Neutron Generator (FNG) irradiation facility, devoted to the validation of the Tritium Breeding Ratio (TBR) and the shielding capability predicted by neutronics design calculations. It will include the assessment of the uncertainties on the calculated Tritium Production Rate (TPR) and the neutron/gamma attenuation which will be useful to evaluate design margins required to guarantee tritium self-sufficiency. In preparation of the future experiment, a detailed pre-analysis has been performed with the MCNP Monte Carlo code for the definition of the mock-up assembly and for the optimisation of the experimental setup. The WCLL mock-up has been designed in such a way that the essential nuclear features of the WCLL BB in DEMO can be represented in the experiment and the relevant nuclear quantities can be measurable with sufficient accuracy under FNG irradiation conditions, with several experimental techniques. This study reports the results of the pre-analysis: the optimised experimental layout and its representativeness of WCLL DEMO blanket.

Published

2020

23. Thermo-hydraulic modeling of the ITER radial neutron camera

Author

Dariusz Bocian, Danilo Nicola Dongiovanni, G. Brolatti, Cristina Centioli, Basilio Esposito, D. Marzullo, Daniele Marocco, Przemysław Młynarczyk, F. Crescenzi, Ryszard Kantor, Fabio Moro, Giuseppe Mazzone, J. Kotula, Kantor, R., Mlynarczyk, P., Kotula, J., Bocian, D., Crescenzi, F., Esposito, B., Marocco, D., Mazzone, G., Brolatti, G., Moro, F., Centioli, C., Dongiovanni, D., Marzullo, D., and AIP

Subjects

Tokamak, Computer science, business.industry, Nuclear engineering, Detector, Process (computing), law.invention, Radial Neutron Camera, Software, law, Neutron flux, ITER, Thermo-Hydraulic Modeling, Emissivity, Water cooling, Neutron, business

Abstract

The ITER Radial Neutron Camera (RNC) is a diagnostic system designed as a multichannel detection system to measure the uncollided neutron flux from the plasma, generated in the tokamak vacuum vessel, providing information on neutron emissivity profile. The RNC consists of array of cylindrical collimators located in two diagnostic structures: the ex-port system and the in-port system. The in-port system, contains the diamond detectors which need a temperature protection. Feasibility study of the efficiency of the cooling system for the In-port Detector Modules of the RNC during baking process was the main goal of thermo-hydraulic numerical modeling. The paper presents the concept of the cooling system layout and the original way of integration of numerical thermo-hydraulic analyses of the in-port detector cassette. Due to the large extent of the detector cassette it is impossible to include all relevant thermal and hydraulic effects in one global model with sufficient level of details. Thus the modelling strategy is based on the concept of three stage modelling from details to global model. The presented paper includes results of numerical calculations made with ANSYS Fluent software in order to provide the final answer, including calculation of heat loads in the detector cassette from adjacent walls during baking and normal operation conditions.

Published

2020

24. Nuclear design of Divertor Tokamak Test (DTT) facility

Author

Daniele Marocco, G. Mariano, F. Crisanti, N. Fonnesu, Sandro Sandri, Barbara Caiffi, R. Luis, Davide Flammini, A. Colangeli, Maurizio Angelone, Fabio Moro, Rosaria Villari, Gian Mario Polli, Villari, R., Angelone, M., Caiffi, B., Colangeli, A., Crisanti, F., Flammini, D., Fonnesu, N., Luis, R., Mariano, G., Marocco, D., Moro, F., Polli, G. M., and Sandri, S.

Subjects

Neutron transport, Tokamak, Computer science, Nuclear engineering, Shutdown, 01 natural sciences, 010305 fluids & plasmas, law.invention, activation, Divertor Tokamak Test facility, MCNP, neutronics, shielding, law, 0103 physical sciences, General Materials Science, 010306 general physics, Civil and Structural Engineering, Test facility, Mechanical Engineering, Divertor, Maintenance strategy, Nuclear Energy and Engineering, Electromagnetic shielding, Dose rate

Abstract

Three-dimensional neutronics, activation and shutdown dose rate analyses were performed with MCNP5 Monte Carlo code, FISPACT-II inventory code and Advanced D1S dynamic tool for the design and licensing of Divertor Tokamak Test facility (DTT). Advanced shielding concepts and mitigation strategies have been studied to guarantee sufficient protection of the superconducting coils and to reduce the streaming and the neutron-induced radioactivity. The present nuclear design study provides main outcomes for the loads assessment, shielding and materials requirements and on maintenance strategy and storage of activated components.

Published

2020

25. Nuclear analysis of the Water cooled lithium lead DEMO reactor

Author

Rosaria Villari, Davide Flammini, G. Mariano, Fabio Moro, Rocco Mozzillo, Emanuela Martelli, Simone Noce, A. Colangeli, A. Del Nevo, Moro, F., Colangeli, A., Del Nevo, A., Flammini, D., Mariano, G., Martelli, E., Mozzillo, R., Noce, S., and Villari, R.

Subjects

Neutron transport, Mechanical Engineering, Nuclear engineering, Nuclear data, Fusion power, Blanket, 01 natural sciences, 7. Clean energy, 010305 fluids & plasmas, Coolant, WCLL, Nuclear Energy and Engineering, Conceptual design, Nuclear analysis, 0103 physical sciences, Electromagnetic shielding, MCNP, Neutronics, Environmental science, General Materials Science, Neutron, Breeding blanket, 010306 general physics, DEMO, Civil and Structural Engineering

Abstract

In the frame of the EUROfusion roadmap, the development of a conceptual design for the Demonstration Fusion Power Reactor (DEMO), beyond ITER, is a key issue. The DEMO reactor shall guarantee the tritium self-sufficiency, generate electricity and operate as a test facility for the fusion power plant relevant technologies, such as the breeding blanket (BB). The Water Cooled Lithium Lead (WCLL) concept has been chosen as a candidate for the DEMO BB: it relies on liquid Lithium Lead as breeder and neutron multiplier, Eurofer as structural material and pressurized water as coolant. A detailed MCNP model of the latest WCLL BB layout has been generated and integrated in the DEMO MCNP generic model suitably designed for neutronic analyses. Three-dimensional neutron and gamma transport simulations have been carried out by means the MCNP Monte Carlo code and JEFF nuclear data libraries in order to assess the WCLL-DEMO performances in terms of tritium self-sufficiency and shielding effectiveness to protect the vacuum vessel and the toroidal field coils. Moreover, the impact on the Tritium production of the water content in the first wall (FW) and the effect of its pressure/temperature has been addressed. The outcomes of the present study provide guidelines for the optimization of the WCLL DEMO reactor nuclear performances through the assessment of the loads on sensitive components and the estimation of its potential tritium generation capabilities.

Published

2020

26. Neutronic analyses in support of the WCLL DEMO design development

Author

Rosaria Villari, Simone Noce, Davide Flammini, Fabio Moro, Alessandro Del Nevo, Emanuela Martelli, Rocco Mozzillo, Moro, F., Del Nevo, A., Flammini, D., Martelli, E., Mozzillo, R., Noce, S., and Villari, R.

Subjects

Neutron transport, Neutronic, Nuclear engineering, Blanket, 7. Clean energy, 01 natural sciences, 010305 fluids & plasmas, Conceptual design, Neutron flux, Shielding, 0103 physical sciences, MCNP, Nuclear, General Materials Science, Neutron, 010306 general physics, DEMO, TBR, Civil and Structural Engineering, Mechanical Engineering, Nuclear data, Fusion power, WCLL, Nuclear Energy and Engineering, Electromagnetic shielding, Environmental science

Abstract

In the frame of the EUROfusion Consortium programme, the Water Cooled Lithium Lead (WCLL) option has been chosen as a candidate for the breeding blanket (BB) of the European fusion power demonstration plant (DEMO) conceptual design. Neutronic analyses play a fundamental role in the development of the WCLL blanket, providing guidelines for its design based on the evaluation of the nuclear performances. A detailed three-dimensional MCNP model of the latest WCLL layout has been generated and integrated in a DEMO MCNP generic model suitably designed for neutronic analyses. Three-dimensional neutron and gamma transport simulations have been performed using the MCNP5v1.6 Monte Carlo code and JEFF 3.2 nuclear data libraries, in order to assess the WCLL-DEMO tritium self-sufficiency and the shielding capabilities of the breeding blanket/manifold system to protect the vacuum vessel and toroidal field coils. Furthermore, radial profiles of the neutron flux, nuclear heating, neutron damage and he-production have been assessed in the inboard and outboard equatorial planes. The outcome of the present study highlights the potential and suitability of the WCLL breeding blanket for the application to DEMO, both in terms of tritium production and shielding performances.

Published

2018

27. Shutdown dose rate calculation along the ITER IVVS port

Author

Raul Pampin, Davide Flammini, Yuefeng Qiu, Rosaria Villari, Anton Travleev, Ulrich Fischer, Adrian Puiu, Roger Reichle, and Fabio Moro

Subjects

Physics, Neutron transport, Tokamak, Mechanical Engineering, Shutdown, Radiation field, Nuclear engineering, Combined use, 01 natural sciences, Port (computer networking), 010305 fluids & plasmas, law.invention, Nuclear Energy and Engineering, law, 0103 physical sciences, General Materials Science, Neutron, 010306 general physics, Dose rate, Civil and Structural Engineering

Abstract

The ITER In-Vessel Viewing System (IVVS) consists of six identical units located at the B1 level of the Tokamak complex, at lower ports 3, 5, 9, 11, 15 and 17. It can be used for visual inspection of the plasma chamber in between plasma pulses. This work is devoted to the nuclear analyses performed for the latest design of the IVVS, to assess the shutdown dose rate (SDDR) in the port cell (PC) and the gallery at 1 day after shutdown in order to verify the design limit in the maintenance area. This analysis was performed through a combined use of the R2S method, for the activation of components from the vacuum vessel VV up to the bioshield, and Advanced D1S method for activation of components from the bioshield up to the gallery. Several MCNP calculations have been performed to transport neutrons and decay gammas up to the bioshield, then, by means of secondary sources, the radiation field has been extended in the PC up to the gallery. This strategy allowed to provide high resolution (voxel size 10 × 10 × 10 cm3) maps of shutdown dose rate in the PC with a statistical uncertainty within ±1% and in the gallery with a statistical uncertainty within ±20%. The consistency of the SDDR results obtained by the two codes at the interface highlighted the reliability of the coupled techniques used in the present analyses. Moreover it is assessed that the design target of 10 μSv/h in the PC is satisfied for the IVVS port.

Published

2018

28. High-Priority Prototype Testing in Support of System-Level Design Development of the ITER Radial Neutron Camera

Author

Andreas Zimbal, Nuno Cruz, M. Curylo, J. Kotula, Ana C. Fernandes, F. Pompili, L. Di Pace, Salvatore Podda, T. Cieslik, Anders Hjalmarsson, Marco Riva, F. Belli, Giuseppe Mazzone, Alessandro Lampasi, R. C. Pereira, Daniele Marocco, Marco Cecconello, B. Esposito, B. Brichard, Cristina Centioli, Dariusz Bocian, Bruno Santos, Paulo Carvalho, Ryszard Kantor, Sean Conroy, Fabio Moro, Fabio Pollastrone, Pollastrone, F., Podda, S., Pompili, F., Mazzone, G., Lampasi, A., Di Pace, L., Centioli, C., Belli, F., Moro, F., Marocco, D., Esposito, B., and Riva, M.

Subjects

Nuclear and High Energy Physics, Field-programmable gate array (FPGA), Detectors, Real time, Neutronics, ITER, Computer science, Neutronic, Astrophysics::High Energy Astrophysical Phenomena, Nuclear engineering, Scintillator, 01 natural sciences, Collimated light, 010305 fluids & plasmas, 0103 physical sciences, Emissivity, Nuclear fusion, Neutron, Nuclear Experiment, Electronic system-level design and verification, Spectrometer, 010308 nuclear & particles physics, Detector, Condensed Matter Physics

Abstract

This paper describes the high-priority testing activities supporting the ITER radial neutron camera (RNC) design, performed by a consortium of European institutes within a framework contract placed by fusion for energy, the ITER European Domestic Agency. The main role of the RNC is to measure the uncollided 14- and 2.5-MeV neutrons from deuterium-tritium and deuterium-deuterium fusion reactions through an array of flux monitors/spectrometers located in collimated lines of sight viewing the plasma through the ITER equatorial port plug #1. The line-integrated neutron fluxes will be used to evaluate, through reconstruction techniques, the radial profile of the neutrons emitted per unit time and volume (neutron emissivity) and, therefore, the neutron yield and the alpha particles' birth profile. The activity of high-priority testing is dedicated to the preparation and the design of experimental test environment, the conduction of appropriate tests and reporting of test results for the high-priority prototypes, clarifying or verifying the expected key function and system behavior, and enhancing learning on specific issues (potential showstoppers). © 1973-2012 IEEE.

Published

2018

29. Neutronics analysis and activation calculation for tungsten used in the DEMO divertor targets: A comparative study between the effects of WCLL and HCPB blanket, different W compositions and chromium

Author

G. Mariano, Jeong-Ha You, Rosaria Villari, Davide Flammini, Giuseppe Mazzone, Francesco Romanelli, Fabio Moro, and Simone Noce

Subjects

Neutron transport, Materials science, Mechanical Engineering, Nuclear engineering, Divertor, Monte Carlo method, chemistry.chemical_element, Nuclear data, Blanket, Tungsten, Fusion power, 7. Clean energy, 01 natural sciences, 010305 fluids & plasmas, Nuclear Energy and Engineering, chemistry, 0103 physical sciences, General Materials Science, Decay heat, 010306 general physics, Civil and Structural Engineering

Abstract

The Divertor Plasma Facing Components (PFCs) of a fusion reactor play a key role in the removal of plasma power exhaust and impurity particles, being exposed to very intense thermal load and high neutron irradiation, which can severely compromise their functioning capability. Therefore, the choice of the plasma facing materials (PFMs) is a fundamental aspect in the design of these components. Tungsten is presently the main candidate being characterised by several advantages from a thermo-physical point of view, but also some drawbacks (e.g. significant activation under neutron irradiation). Neutronics assessment plays a key role in the design of these critical components and in the choice of the most suitable PFMs. Detailed nuclear analyses have been performed by implementing, for the first time, heterogeneous models of the actual ITER-Like PFCs geometry [ 1 , 2 ], aimed to assess the impact of neutronics and activation issues on design, lifetime, operations and safety of the PFCs of DEMO divertor and to provide outcomes useful in the PFCs selection concept, under study within the EUROfusion WPDIV-2 project. In particular way, the effects of two different blankets (WCLL and HCPB) on W activation and the impact of three different W compositions and chromium, have been compared. Three-dimensional neutronic analyses have been performed with the MCNP5 Monte Carlo [ 3 ] using the reference JEFF 3.3 nuclear data libraries [ 4 ] to calculate neutron spectra in PFCs subcomponents. Activation analysis has been performed with FISPACT II inventory codes [ 5 ] to assess the specific activity, decay heat and contact dose at the end of DEMO-1 operations. The calculations have been carried-out on ENEA HPC CRESCO6 cluster (Ponti et al., 2014).

Published

2021

30. Nuclear performances of the water-cooled lithium lead DEMO reactor: Neutronic analysis on a fully heterogeneous model

Author

Rosaria Villari, Davide Flammini, Rocco Mozzillo, V. Imbriani, Ruggero Forte, A. Colangeli, I. Catanzaro, G. Mariano, A. Del Nevo, Simone Noce, N. Fonnesu, P. Arena, Fabio Moro, Moro, F., Arena, P., Catanzaro, I., Colangeli, A., Del Nevo, A., Flammini, D., Fonnesu, N., Forte, R., Imbriani, V., Mariano, G., Mozzillo, R., Noce, S., and Villari, R.

Subjects

Neutron transport, Tokamak, Breeding blanket, Computer science, Nuclear engineering, Blanket, 01 natural sciences, 010305 fluids & plasmas, law.invention, Breeder (animal), Conceptual design, law, 0103 physical sciences, MCNP, Neutronics, General Materials Science, Neutron, 010306 general physics, DEMO, Civil and Structural Engineering, Mechanical Engineering, Fusion power, WCLL, Coolant, Nuclear Energy and Engineering, Nuclear analysis

Abstract

The development of a conceptual design for the Demonstration Fusion Power Reactor (DEMO) is a key issue within the EUROfusion roadmap. The DEMO reactor is designed to produce a fusion power of about 2 GW and generate a substantial amount of electricity, relying on a closed tritium fuel cycle: it implies that the breeding blanket (BB) shall guarantee a suitable tritium production to enable a continuous operation without any external supply. The Water-Cooled Lithium Lead (WCLL) concept is a candidate for the DEMO BB: it uses liquid Lithium Lead as breeder and neutron multiplier and water in PWR condition as coolant. The neutronics analyses carried out in the past have been performed using a semi-heterogeneous representation of the BB, since the complexity of its structure makes the generation of a detailed MCNP model a very demanding and challenging task. Results highlighted good performances for the WCLL BB, both in terms of shielding effectiveness and tritium self-sufficiency. A recently updated assessment of the tritium breeding ratio (TBR) requirement for DEMO, considering margins for calculation uncertainties and incomplete models of the whole machine, led to the definition of a tentative 1.15 value for the TBR. Moreover, the implementation of an accurate BB neutronics model, consistent with the engineering design, is recommended for the evaluation of the tritium self-sufficiency. In order to tackle these issues, an MCNP model of the DEMO tokamak, integrating a fully heterogeneous WCLL BB has been developed for the first time, including an accurate description of the FW water channels, as well as a comprehensive definition of the breeding zone inner structure. A complete assessment of the WCLL BB nuclear performances, through 3D neutron and gamma transport simulations, has been carried out by means the MCNP Monte Carlo code and JEFF nuclear libraries.

Published

2021

31. A novel approach to the study of magnetohydrodynamic effect on tritium transport in WCLL breeding blanket of DEMO

Author

Ciro Alberghi, Massimo Zucchetti, Raffaella Testoni, Marco Utili, Luigi Candido, Fabio Moro, and Simone Noce

Subjects

MHD, Multiphysics, Nuclear engineering, Population, Blanket, 01 natural sciences, 010305 fluids & plasmas, Breeder (animal), 0103 physical sciences, MCNP, Water cooling, General Materials Science, 010306 general physics, education, DEMO, Civil and Structural Engineering, education.field_of_study, WCLL, Tritium transport, Mechanical Engineering, Coolant, Nuclear Energy and Engineering, Heat transfer, Environmental science, Tritium

Abstract

The Water-Cooled Lithium Lead (WCLL) breeding blanket is one of the European blanket designs proposed for DEMO reactor. Tritium can permeate into the different structural materials, arising potential issues concerning the fuel self-sufficiency and can be lost into the environment with consequent radiological hazard for the population. Within this frame, a tritium transport analysis is fundamental to evaluate tritium retention in LiPb (15.7 at. % Li) and in the structures and tritium permeation fluxes into the cooling water. To assess this study, a portion of the breeder unit of the outboard equatorial module of the WCLL was modelled. The buoyancy forces and the magnetohydrodynamic (MHD) effect were also included. The final system of partial differential equations was solved with a novel approach through COMSOL Multiphysics. The coupled MHD and heat transfer system of equations was solved performing a transient simulation, that was stopped when the main average variables, temperature and velocity, reached a stable condition. In this way, it was possible to determine the lithium-lead velocity field and to use it as an input for the transport analysis. Tritium transport was modelled by using the input data of tritium generation rate and volumetric power deposition coming from an ad-hoc Monte Carlo simulation realized with MCNP software. Moreover, the transport analysis included advection-diffusion of tritium into the LiPb, transfer of tritium from the liquid interface towards the steel, diffusion of tritium inside the steel, transfer of tritium from the steel towards the coolant, advection-diffusion of diatomic tritium into the coolant.

Published

2021

32. Nuclear responses in the ITER IVVS port cell

Author

Roger Reichle, Adrian Puiu, Raul Pampin, Ulrich Fischer, Davide Flammini, Anton Travleev, Fabio Moro, Rosaria Villari, and Yuefeng Qiu

Subjects

Physics, Tokamak, Mechanical Engineering, Nuclear engineering, Monte Carlo method, Port (circuit theory), Radiation, 01 natural sciences, 010305 fluids & plasmas, law.invention, Nuclear Energy and Engineering, law, Absorbed dose, 0103 physical sciences, Electromagnetic shielding, General Materials Science, Neutron, 010306 general physics, Dose rate, Civil and Structural Engineering

Abstract

The ITER In-Vessel Viewing System (IVVS) consists of six identical units located at the B1 level of the Tokamak complex. In this work relevant nuclear quantities in the Port Cell (PC) have been calculated by means of the MCNP Monte Carlo code in a full 3-D geometry, including the IVVS and its shielding blocks. A comprehensive MCNP model of the PC has been developed including a detailed description of the Bioshield plug, pipes, penetrations, cask rails and PC door. The neutron and gamma sources needed to perform the nuclear analyses include both contributions from the radiation streaming through the Lower Port and activated water. Monte Carlo calculations have been performed to assess the radiation field inside the PC through maps of neutron and gamma fluxes. Absorbed dose on sensitive components over the ITER lifetime has been calculated in the PC area, in order to estimate the nuclear loads that the installed equipment has to withstand. Moreover, the shutdown dose rate distribution at 1 day after shutdown has been calculated.

Published

2017

33. WCLL breeding blanket design and integration for DEMO 2015: status and perspectives

Author

Andrea Tarallo, Pietro Agostini, A. Del Nevo, Marco Utili, G. Mariano, Emanuela Martelli, Rocco Mozzillo, Rosaria Villari, Fabio Moro, G. Di Gironimo, Fabio Giannetti, Gianfranco Caruso, P. Arena, G. Bongiovì, R. Giammusso, Mariano Tarantino, P.A. Di Maio, Alessandro Tassone, D. Rozzia, Marica Eboli, A. Giovinazzi, Del Nevo, A., Martelli, E., Agostini, P., Arena, P., Bongiovì, G., Caruso, G., Di Gironimo, G., Di Maio, P.A., Eboli, M., Giammusso, R., Giannetti, F., Giovinazzi, A., Mariano, G., Moro, F., Mozzillo, R., Tassone, A., Rozzia, D., Tarallo, A., Tarantino, M., Utili, M., Villari, R., DI GIRONIMO, Giuseppe, Di Maio, P. A., Mozzillo, Rocco, and Tarallo, Andrea

Subjects

Neutron transport, Computer science, Blanket, 7. Clean energy, 01 natural sciences, breeding blanket, CFD, DEMO, WCLL, 010305 fluids & plasmas, law.invention, law, 0103 physical sciences, Design choice, General Materials Science, 010306 general physics, WCLL, Breeding blanket, DEMO, Settore ING-IND/19 - Impianti Nucleari, Civil and Structural Engineering, WCLL Breeding blanket DEMO, business.industry, Mechanical Engineering, Lead system, Pressurized water reactor, Fusion power, Modular design, Nuclear Energy and Engineering, Systems engineering, business, Transport system

Abstract

Water-cooled lithium-lead breeding blanket is considered a candidate option for European DEMO nuclear fusion reactor. ENEA and the linked third parties have proposed and are developing a multi-module blanket segment concept based on DEMO 2015 specifications. The layout of the module is based on horizontal (i.e. radial-toroidal) water-cooling tubes in the breeding zone, and on lithium lead flowing in radial-poloidal direction. This design choice is driven by the rationale to have a modular design, where a basic geometry is repeated along the poloidal direction. The modules are connected with a back supporting structure, designed to withstand thermal and mechanical loads due to normal operation and selected postulated accidents. Water and lithium lead manifolds are designed and integrated with a consistent primary heat transport system, based on a reliable pressurized water reactor operating experience, and the lithium lead system. Rationale and features of current status of water-cooled lithium-lead breeding blanket design are discussed and supported by thermo-mechanics, thermo-hydraulics and neutronics analyses. Open issues and areas of research and development needs are finally pointed out.

Published

2017

34. Neural network implementation for ITER neutron emissivity profile recognition

Author

Fabio Moro, Marco Cecconello, Sean Conroy, B. Esposito, and Daniele Marocco

Subjects

Accuracy and precision, Artificial neural network, Computer science, Astrophysics::High Energy Astrophysical Phenomena, Mechanical Engineering, Fusion power, 01 natural sciences, 010305 fluids & plasmas, Set (abstract data type), Nuclear Energy and Engineering, 0103 physical sciences, Emissivity, General Materials Science, Neutron, 010306 general physics, Algorithm, Selection (genetic algorithm), Civil and Structural Engineering

Abstract

The ITER Radial Neutron Camera (RNC) is a neutron diagnostic intended for the measurement of the neutron emissivity radial profile and the estimate of the total fusion power. This paper presents a proof-of-principle method based on neural networks to estimate the neutron emissivity profile in different ITER scenarios and for different RNC architectures. The design, optimization and training of the implemented neural network is presented together with a decision algorithm to select, among the multiple trained neural networks, which one provides the inverted neutron emissivity profile closest to the input one. Examples are given for a selection of ITER scenarios and RNC architectures. The results from this study indicate that neural networks for the neutron emissivity recognition in ITER can achieve an accuracy and precision within the spatial and temporal requirements set by ITER for such a diagnostic.

Published

2017

35. Nuclear analysis of the ITER radial neutron camera architectural options

Author

Rosaria Villari, Davide Flammini, B. Esposito, Salvatore Podda, Sean Conroy, Daniele Marocco, and Fabio Moro

Subjects

Physics, Neutron transport, Electronic system-level design and verification, Mechanical Engineering, Nuclear engineering, Detector, Port (circuit theory), Radiation, 01 natural sciences, 010305 fluids & plasmas, Nuclear Energy and Engineering, 0103 physical sciences, Emissivity, Neutron source, General Materials Science, Neutron, 010306 general physics, Civil and Structural Engineering

Abstract

The ITER Radial Neutron Camera (RNC) is a multichannel detection system hosted in the Equatorial Port Plug 1 (EPP 1) designed to provide information on the neutron source total strength and emissivity profiles. It consists of two sub-systems: the ex-port line-of-sights (LOSs), covering the plasma core, embedded in a massive shielding block located in the Port Interspace, and the in-port LOSs distributed in two removable cassettes integrated inside the Port Plug. Presently, the RNC layout development process is undergoing a System Level Design phase: several preliminary architectural options based on a System Engineering work have been defined: a detailed nuclear analysis of these options has been performed through radiation transport calculations with the MCNP Monte Carlo code. The radiation environment at the detectors positions has been fully characterized through the evaluation of the expected neutron spectra and the secondary gamma background and the analysis of the 3D radiation maps. Moreover, the impact of a reduced ex-port shielding block on the neutron and gamma spectra has been investigated. The results of the present study provide guidelines for the development of the RNC final design and the necessary data for the measurement performance analysis.

Published

2017

36. Advancements in DEMO WCLL breeding blanket design and integration

Author

A. Del Nevo, G. Bongiovì, Andrea Tarallo, G. Mariano, R. Marinari, Rocco Mozzillo, Rosaria Villari, Fabio Giannetti, G. Di Gironimo, Emanuela Martelli, P.A. Di Maio, Gianfranco Caruso, P. Arena, Fabio Moro, Alessandro Tassone, and Marica Eboli

Subjects

Engineering, Power station, Renewable Energy, Sustainability and the Environment, business.industry, Pressurized water reactor, Energy Engineering and Power Technology, Mechanical engineering, Blanket, Fusion power, 7. Clean energy, 01 natural sciences, Energy storage, 010305 fluids & plasmas, Coolant, law.invention, Fuel Technology, Nuclear Energy and Engineering, law, 0103 physical sciences, Heat transfer, Water cooling, 010306 general physics, business

Abstract

Summary The water-cooled lithium–lead breeding blanket is a candidate option for the European Demonstration Power Plant (DEMO) nuclear fusion reactor. This breeding blanket concept relies on the liquid lithium–lead as breeder–multiplier, pressurized water as coolant, and EUROFER as structural material. The current design is based on DEMO 2015 specifications and represents the follow-up of the design developed in 2015. The single-module-segment approach is employed. This is constituted by a basic geometry repeated along the poloidal direction. The power is removed by means of radial–toroidal (i.e., horizontal) water cooling tubes in the breeding zone. The lithium–lead flows in a radial–poloidal direction. On the back of the segment, a 100-mm-thick plate is in charge of withstanding the loads due to normal operation and selected postulated initiating events. Water and lithium–lead manifolds are designed and integrated with a consistent primary heat transport system, based on a reliable pressurized water reactor operating experience, and the lithium–lead system. Rationale and features of the single-module-segment water-cooled lithium–lead breeding blanket design are discussed and supported by thermo-mechanic, thermo-hydraulic, and neutronic analyses. Preliminary integration with the primary heat transfer system, the energy storage system, and the balance of plant is briefly discussed. Open issues, areas of research, and development needs are finally pointed out. @EUROfusion Consortium*, 2017. *For more details see http://www.euro-fusionscipub.org/disclaimer-copyright

Published

2017

37. An active Bonner sphere spectrometer for intense neutron fields

Author

E. Durisi, Antonino Pietropaolo, Davide Flammini, Mario Pillon, Mário Costa, V. Monti, Fabio Moro, Roberto Bedogni, L. Menzio, O. Sans Planell, J.M. Gómez-Ros, Bedogni, R., Gomez-Ros, J. M., Costa, M., Monti, V., Durisi, E., Sans Planell, O., Menzio, L., Flammini, D., Moro, F., Pillon, M., and Pietropaolo, A.

Subjects

Nuclear and High Energy Physics, Physics::Instrumentation and Detectors, Bonner spheres, FNG, Frascati neutron generator, FRUIT, TNRD, Unfolding, Scintillator, Radiation, 030218 nuclear medicine & medical imaging, law.invention, Nuclear physics, 03 medical and health sciences, 0302 clinical medicine, Neutron generator, law, Neutron, Nuclear Experiment, Instrumentation, Bonner sphere, Physics, Spectrometer, Particle accelerator, Neutron temperature, 030220 oncology & carcinogenesis

Abstract

Neutron producing installations can be characterized by the presence of intense pulsed fields, possibly accompanied by large photon background. This is the case of particle accelerators and, more recently, laser-based radiation sources. Determining neutron spectra in these fields is particularly complex, as active detectors may likely be affected by dead-time and saturation effects, and their parasitic response to photons is generally non zero. Passive Bonner Spheres Spectrometers (BSS) equipped with activation foils have been used in these cases. Owing on a new type of active thermal neutron detector (TNRD, Thermal Neutron Rate Detector), this work presents a BSS able to operate in intense, pulsed fields, with large photon background. The response matrix of this spectrometer was experimentally verified by comparison with a well-established BSS based on a 11 mm (diameter) × 3 mm (thickness) 6 LiI(Eu) scintillator . The comparison was performed in the 14 MeV and 2.9 MeV neutron fields produced at the Frascati Neutron Generator. The proposed spectrometer can constitute a valuable tool for operational neutron dosimetry .

Published

2019

38. Parametric study of the influence of First Wall cooling water on the Water Cooled Lithium Lead Breeding Blanket nuclear response

Author

Pietro Alessandro Di Maio, Rosaria Villari, Pierluigi Chiovaro, Fabio Moro, Alessandro Del Nevo, E. Vallone, Chiovaro, P., Del Nevo, A., Di Maio, P. A., Moro, F., Vallone, E., Villari, R., Chiovaro P., Del Nevo A., Di Maio P.A., Moro F., Vallone E., and Villari R.

Subjects

Work package, Nuclear engineering, Neutronic, chemistry.chemical_element, Context (language use), DEMO reactor, Blanket, 7. Clean energy, 01 natural sciences, 010305 fluids & plasmas, 0103 physical sciences, Water cooling, Neutronics, WCLL blanket, General Materials Science, 010306 general physics, Settore ING-IND/19 - Impianti Nucleari, Civil and Structural Engineering, Parametric statistics, business.industry, Mechanical Engineering, Water cooled, Nuclear power, Nuclear Energy and Engineering, chemistry, Environmental science, Lithium, business

Abstract

In the framework of EUROfusion Work Package International Cooperation R&D activities, a close collaboration has been started among University of Palermo, ENEA Brasimone and ENEA Frascati for the development of the Water Cooled Lithium Lead (WCLL) Breeding Blanket (BB) concept. In this context, a research campaign has been carried out at the University of Palermo in order to investigate the influence of First Wall (FW) cooling water configuration on the nuclear response of the WCLL BB under irradiation in EU-DEMO, in order to gain useful indications for the WCLL BB pre-conceptual designs. To this end, three-dimensional nuclear analyses have been performed by MCNP5 v. 1.6 Monte Carlo code. A semi-heterogeneous MCNP model of the WCLL BB “single module segment” concept has been used and its nuclear response has been assessed for different FW configurations, centring the attention, mainly, on global quantities as nuclear power deposition and tritium breeding ratio. The results obtained provided some information on the nuclear features of the WCLL BB concept, useful for its design optimisation. The outcomes of this parametric study are herein presented and critically discussed.

Published

2019

39. Neutronics study for DTT tokamak building

Author

R. Luis, Davide Flammini, Sandro Sandri, Dtt team, N. Fonnesu, G. Ramogida, G. Mariano, Fabio Moro, Rosaria Villari, F. Lucca, F. Crisanti, G. Mazzitelli, A. Colangeli, Colangeli, A., Villari, R., Luis, R., Moro, F., Sandri, S., Fonnesu, N., Flammini, D., Mariano, G., Crisanti, F., Ramogida, G., Lucca, F., and Mazzitelli, G.

Subjects

Neutron transport, licensing, Tokamak, neutronics, tokamaks, DTT, MCNP, Nuclear engineering, Neutronic, 7. Clean energy, 01 natural sciences, 010305 fluids & plasmas, law.invention, law, 0103 physical sciences, General Materials Science, Neutron, 010306 general physics, Civil and Structural Engineering, Physics, Mechanical Engineering, Divertor, Licensing, Neutronics, Tokamaks, Fusion power, Power (physics), Nuclear Energy and Engineering, Electromagnetic shielding, Wall thickness

Abstract

The Divertor Tokamak Test (DTT) facility is a project proposed by an Italian consortium aimed to test the physics and technology of various alternative divertor concepts in order to design a heat and power exhaust system able to withstand the large loads expected in the divertor of a DEMO fusion power plant. The DTT machine is expected to produce up to 1.0 × 1017 2.5-MeV neutrons per second through deuterium-deuterium (DD) reactions with a significant 14 MeV neutron production (1% of the total yield) due to triton burn-up during the high-performance phase. This work is devoted to a preliminary three-dimensional shielding study to optimize the DTT building for licensing purposes. Neutron and gamma transport simulations were carried-out with MCNP5 Monte Carlo code using weight windows generated with ADVANTG hybrid code. Three-dimensional model of the DTT machine and building has been developed to assess the spatial distributions of the neutron and gamma fluxes, spectra and effective doses inside and outside the tokamak hall. The wall thickness (in the range 150–250 cm) has no impact on satisfying dose limits for the public, but is important when satisfying limits for workers.

Published

2019

40. On the slowing-down of 14 MeV fusion neutrons: A spectrometry benchmark and perspectives on future neutron science facilities

Author

Antonino Pietropaolo, Fabio Moro, Mario Pillon, Davide Flammini, G. Pagano, Roberto Bedogni, Pietropaolo, A., Flammini, D., Moro, F., Pagano, G., Pillon, M., and Bedogni, R.

Subjects

Physics, Bonner sphere, Spectrometer, Neutron emission, Astrophysics::High Energy Astrophysical Phenomena, Nuclear Theory, Monte Carlo method, General Physics and Astronomy, 01 natural sciences, Fluence, 010305 fluids & plasmas, Nuclear physics, Neutron generator, 0103 physical sciences, Neutron source, Neutron, Nuclear Experiment, 010306 general physics

Abstract

The spectral fluence rate of the thermalized neutron field obtained by slowing down the 14MeV fusion neutrons produced at the accelerator-driven Frascati Neutron Generator is measured by means of the Bonner Sphere Spectrometer. Neutron thermalization is achieved by means of a moderator assembly made of a copper pre-moderator and a polyethylene moderator. A Monte Carlo simulation reproducing the experimental set-up is also performed by means of the MCNP code and the results are compared to the experimental data. The benchmarked Monte Carlo is then used to predict the brilliance of a thermal moderator operating at a potential highintensity 14MeV neutron continuous source featuring a neutron emission rate of 1015 s-1. The results obtained show that if a D-T neutron source featuring a continuous neutron emission rate of 1015 s-1 could be made operative, it could be effectively exploited for neutron science.

Published

2019

41. Calibration and test of a 6LiF-diamond detector for the HCPB mock-up experiment at JET

Author

Massimo Angelone, N. Fonnesu, Fabio Moro, Rosaria Villari, A. Colangeli, Mario Pillon, Angelone, M., Fonnesu, N., Colangeli, A., Moro, F., Pillon, M., and Villari, R.

Subjects

Jet (fluid), Neutron transport, Materials science, HCPB mock-up, Physics::Instrumentation and Detectors, MCNP simulation, Mechanical Engineering, Nuclear engineering, Detector, Monte Carlo method, 01 natural sciences, 010305 fluids & plasmas, Diamond detector, Nuclear Energy and Engineering, Neutron generator, Mockup, 0103 physical sciences, Calibration, ITER-TBM, Tritium production rate, General Materials Science, Neutron, 010306 general physics, Civil and Structural Engineering

Abstract

One relevant experiment selected for the DT phase at JET is the irradiation of the HCPB-TBM mock-up of ITER which will be located in front of the horizontal port of Octant-8. The neutronics performances of the HCPB-TBM will be studied through independent measurement techniques and the experimental quantities compared to the results of Monte Carlo simulation. Of paramount importance is the measurement of the tritium production rate (TPR) to be performed by using a single crystal diamond detector covered with a thin layer of 6LiF (LiDia detector). This requires the knowledge of the 6Li mass. In this work the 6Li mass calibration of the selected LiDia detector was first performed in a well characterized thermal neutron flux spectrum. Furthermore, a performance test of the detector was carried out by locating it inside a polyethylene phantom irradiated with 14 MeV neutrons at the Frascati Neutron generator. The experimental set-up was accurately simulated by using the MCNP5 code and the TPR compared to the measured one. The goal was to point out and assess the issues with the measurement method.

Published

2019

42. Nuclear analysis of the Single Module Segment WCLL DEMO

Author

Rosaria Villari, Francesco Romanelli, Simone Noce, Fabio Moro, Noce, S., Moro, F., Romanelli, F., and Villari, R.

Subjects

Materials science, Nuclear engineering, Neutronic, Monte Carlo method, Blanket, DEMO, MCNP, Neutronics, Nuclear, Shielding, TBR, WCLL, 7. Clean energy, 01 natural sciences, 010305 fluids & plasmas, Neutron flux, 0103 physical sciences, Nuclear fusion, General Materials Science, Neutron, 010306 general physics, Civil and Structural Engineering, business.industry, Mechanical Engineering, Nuclear power, Nuclear Energy and Engineering, Electromagnetic shielding, Tritium, business

Abstract

The latest design of the Water Cooled Lithium Lead blanket for the European DEMO reactor is based on a Single Module Segment (SMS) concept for the blanket segments: the removal of the gaps between the modules (present in the former Multi Module structure design), with the consequent reduction of the neutron streaming, improves the tritium production and the shielding capabilities. A nuclear analysis has been carried out with the Monte Carlo N-Particle transport code version 5 (MCNP5) and the Joint Evaluated Fission and Fusion nuclear data libraries version 3.2 (JEFF 3.2). A detailed three-dimensional MCNP DEMO model with the Single Module layout has been generated. Three-dimensional neutron and gamma transport simulations have been carried out in order to assess the tritium production, nuclear power deposition in each subcomponent of the blanket and nuclear heating density, neutron flux, neutron damage (dpa) and Helium production, relevant for the design of the system. The results confirm the fulfilment of tritium self-sufficiency and shielding requirements of DEMO. Furthermore, a parametric analysis has been carried out by varying the thickness of the first wall tungsten layer to evaluate how the blanket performances are influenced by the tungsten layer thickness.

Published

2019

43. Recent progress in developing a feasible and integrated conceptual design of the WCLL BB in EUROfusion project

Author

Laura Savoldi, Mariano Tarantino, Marica Eboli, G. Di Gironimo, Rosaria Villari, Francesco Edemetti, Marco Utili, Fabio Giannetti, Rocco Mozzillo, Shanshan Liu, P. Arena, Andrea Tarallo, Ruggero Forte, Kecheng Jiang, Alessandro Tassone, P.A. Di Maio, Antonio Froio, Emanuela Martelli, Roberto Zanino, Gianfranco Caruso, Nicola Forgione, A. Del Nevo, Pierluigi Chiovaro, Fabio Moro, Del Nevo, A., Arena, P., Caruso, G., Chiovaro, P., Di Maio, P. A., Eboli, M., Edemetti, F., Forgione, N., Forte, R., Froio, A., Giannetti, F., Di Gironimo, G., Jiang, K., Liu, S., Moro, F., Mozzillo, R., Savoldi, L., Tarallo, A., Tarantino, M., Tassone, A., Utili, M., Villari, R., Zanino, R., Martelli, E., Del Nevo, A, Arena, P, Caruso, G, Chiovaro, P, Di Maio, PA, Eboli, M, Edemetti, F, Forgione, N, Forte, R, Froio, A, Giannetti, F, Di Gironimo, G, Jiang, K, Liu, S, Moro, F, Mozzillo, R, Savoldi, L, Tarallo, A, Tarantino, M, Tassone, A, Utili, M, Villari, R, Zanino, R, and Martelli, E

Subjects

Breeding blanket, DEMO, EUROfusion, WCLL, breeding blanket, Computer science, Nuclear engineering, Blanket, 01 natural sciences, 010305 fluids & plasmas, law.invention, Breeder (animal), Conceptual design, law, 0103 physical sciences, General Materials Science, 010306 general physics, Settore ING-IND/19 - Impianti Nucleari, Civil and Structural Engineering, Mechanical Engineering, Pressurized water reactor, Fusion power, Coolant, Design phase, Nuclear Energy and Engineering, Materials Science (all)

Abstract

The water-cooled lithium-lead breeding blanket is in the pre-conceptual design phase. It is a candidate option for European DEMO nuclear fusion reactor. This breeding blanket concept relies on the liquid lithium-lead as breeder-multiplier, pressurized water as coolant and EUROFER as structural material. Current design is based on DEMO 2017 specifications. Two separate water systems are in charge of cooling the first wall and the breeding zone: thermo-dynamic cycle is 295–328 °C at 15.5 MPa. The breeder enters and exits from the breeding zone at 330 °C. Cornerstones of the design are the single module segment approach and the water manifold between the breeding blanket box and the back supporting structure. This plate with a thickness of 100 mm supports the breeding blanket and is attached to the vacuum vessel. It is in charge to withstand the loads due to normal operation and selected postulated initiating events. Rationale and progresses of the design are presented and substantiated by engineering evaluations and analyses. Water and lithium lead manifolds are designed and integrated with the two consistent primary heat transport systems, based on a reliable pressurized water reactor operating experience, and six lithium lead systems. Open issues, areas of research and development needs are finally pointed out. © 2019 Elsevier B.V.

Published

2019

44. Neutronics studies for the novel design of lower port in DEMO

Author

A. Colangeli, C. Gliss, Christian Bachmann, Fabio Moro, Davide Flammini, Rosaria Villari, Flammini, D., Bachmann, C., Colangeli, A., Gliss, C., Moro, F., and Villari, R.

Subjects

Neutron transport, Materials science, Nuclear engineering, Neutronic, 7. Clean energy, 01 natural sciences, Nuclear heating, 010305 fluids & plasmas, Neutron flux, 0103 physical sciences, MCNP, Neutronics, General Materials Science, Duct (flow), 010306 general physics, DEMO, Civil and Structural Engineering, Lower port, Mechanical Engineering, Divertor, Fusion power, Conductor, Nuclear Energy and Engineering, Electromagnetic coil, Electromagnetic shielding

Abstract

The conceptual design activity of the Demonstration Fusion Power Reactor (DEMO) is in progress in the Power Plant Physics and Technology (PPPT) programme, within the EUROfusion Consortium. In this work neutronics studies, fundamental for the nuclear design of DEMO, are presented for a novel design of the lower port (LP). Two possible configurations of the LP have been investigated: the vacuum pumping port, with the pumping unit located inside the port, and an empty port designed for remote handling. For both configurations 3-dimensional Monte Carlo calculations have been performed with MCNP5 to assess the neutron flux inside and around the port and the nuclear heating in sensitive components, such as the toroidal field coil conductor, the vacuum pumps, the shielding elements and the port closure plate. Different shielding configurations have been considered, by adding shielding blocks at the lower port entrance. Single and double wall port walls and closure plates with different thickness have been studied to reduce nuclear loads and neutron flux. Nuclear quantities under analysis were found to be within the limit for all the components, with the exception of the nuclear heating on the toroidal field coils. The absence of any shield of the divertor cassette pumping duct, as in the DEMO 2017 baseline configuration, is responsible for a huge amount of radiation streaming inside the pumping duct that can cause the excess of heating on the coil conductor. The use of a liner, or of an equivalent shielding component, is proposed, but further improvements are needed to keep the nuclear loads on the coil conductor within the limit.

Published

2019

45. Neutronics experiments and analyses in preparation of DT operations at JET

Author

Alexander Lukin, Stefan Matejcik, Lee Packer, Soare Sorin, Francesco Romanelli, Emilio Blanco, Ulrich Fischer, Rosaria Villari, Bohdan Bieg, Vladislav Plyusnin, José Vicente, Alberto Loarte, Patrick Sauvan, Juan Pablo Catalan, Fabio Moro, Rajnikant Makwana, CHIARA MARCHETTO, Marco Wischmeier, Choong-Seock Chang, Aneta Gójska, and Manuel Garcia-munoz

Subjects

Jet (fluid), Neutron transport, Computer science, Mechanical Engineering, Shutdown, Nuclear engineering, Frame (networking), 01 natural sciences, 010305 fluids & plasmas, Nuclear Energy and Engineering, 0103 physical sciences, Benchmark (computing), General Materials Science, 010306 general physics, Dose rate, Civil and Structural Engineering

Abstract

In the frame of the WPJET3-DT Technology project within the EUROfusion Consortium program, neutronics experiments are in preparation for the future deuterium–tritium campaign on JET (DTE2). The experiments will be conducted with the purpose to validate the neutronics codes and tools used in ITER, thus reducing the related uncertainties and the associated risks in the machine operation. This paper summarizes the status of previous shutdown dose rate benchmarks experiments and analyses performed at JET and focuses on the computational and experimental efforts conducted in preparation of the future DTE2 experiments. In particular, preliminary calculations and studies to select detectors and positions aimed to reduce uncertainties in the shutdown dose rate experiment are presented and discussed.

Published

2016

46. Characterization of the radiation field and evaluation of the nuclear responses in the ITER cryopump port cell

Author

B. Levesy, A. Antipenkov, Davide Flammini, Rosaria Villari, Michael Loughlin, M. Dremel, Dan Gabriel Cepraga, Luigino Petrizzi, Fabio Moro, Gilio Cambi, and Salvatore Podda

Subjects

Cryostat, Materials science, Astrophysics::High Energy Astrophysical Phenomena, Mechanical Engineering, Nuclear engineering, Monte Carlo method, technology, industry, and agriculture, Port (circuit theory), Cryopump, Radiation, 01 natural sciences, 010305 fluids & plasmas, Nuclear Energy and Engineering, Absorbed dose, visual_art, 0103 physical sciences, Electronic component, visual_art.visual_art_medium, General Materials Science, Neutron, 010306 general physics, Civil and Structural Engineering

Abstract

The ITER main vacuum system consists of six torus exhaust pumps integrated in the Cryostat through dedicated housings at the building B1 level. The Port Cell area outside the cryopump plug is affected by neutrons streaming through the housing structure and diagnostics penetrations. The aim of the study presented in this paper is to perform a complete assessment of the nuclear responses in the Cryopump Port Cell #12 by means of the MCNP-5 Monte Carlo code in a full 3-D geometry. The results of the neutronic analyses provide guidelines for the design and maintenance of the embedded components, ensuring their structural integrity and proper operation. Radiation transport calculations have been carried out to determine the radiation field inside the Port Cell through 3-D neutrons and gamma maps. Nuclear heating induced by neutrons and photons and the absorbed dose during the ITER lifetime on steel and silicon have been estimated in the Port Cell area, in order to assess the nuclear loads that the diagnostics and related electronic components have to withstand. Furthermore, the impact of the gamma-rays emitted by neutron-activated water circulating in the Primary Heat Transfer System have been evaluated on the Port Cell environment: 3-D maps of the gamma flux, nuclear loads on steel/silicon during plasma operation are provided.

Published

2016

47. Copper benchmark experiment at the Frascati Neutron Generator for nuclear data validation

Author

Massimo Angelone, Davide Flammini, Mario Pillon, Rosaria Villari, Stefano Loreti, and Fabio Moro

Subjects

Physics, Neutron transport, Mechanical Engineering, Nuclear data, chemistry.chemical_element, Germanium, 01 natural sciences, 010305 fluids & plasmas, Semiconductor detector, Nuclear physics, Reaction rate, Nuclear Energy and Engineering, Neutron generator, chemistry, Neutron flux, 0103 physical sciences, General Materials Science, Neutron, 010306 general physics, Civil and Structural Engineering

Abstract

A neutronics benchmark experiment on a pure Copper block (dimensions 60 × 70 × 60 cm3), aimed at testing and validating the recent nuclear data libraries for fusion applications, was performed at the 14-MeV Frascati Neutron Generator (FNG) as part of a F4E specific grant (F4E_FPA-395_01) assigned to the European Consortium on Nuclear Data and Experimental Techniques. The relevant neutronics quantities (e.g., reaction rates, neutron flux spectra, doses, etc.) were measured using different experimental techniques and the results were compared to the calculated quantities using fusion relevant nuclear data libraries. This paper focuses on the analyses carried-out by ENEA through the activation foils techniques. 197Au(n,γ)198Au, 186W(n,γ)187W, 115In(n,n′)115In, 58Ni(n,p)58Co, 27Al(n,α)24Na, 93Nb(n,2n)92Nbm activation reactions were used. The foils were placed at eight different positions along the Cu block and irradiated with 14 MeV neutrons. Activation measurements were performed by means of High Purity Germanium (HPGe) detector. Detailed simulation of the experiment was carried-out using MCNP5 Monte Carlo code and the European JEFF-3.1.1 and 3.2 nuclear cross-sections data files for neutron transport and IRDFF_v1.05 library for the reaction rates in activation foils. The calculated reaction rates (C) were compared to the experimental quantities (E) and the C/E ratio with relative uncertainties was assessed.

Published

2016

48. Study of shielding options for lower ports for mitigation of neutron environment and shutdown dose inside the ITER cryostat

Author

Raul Pampin, Flavien Sabourin, E. Polunovskiy, Rafael Juarez, N. Casal, Fernando Mota, Anne Arnould, Fabio Moro, Alejandro Suarez, and A. Martin

Subjects

Cryostat, Mechanical Engineering, Nuclear engineering, Shutdown, Cryopump, 01 natural sciences, Thermostat, 010305 fluids & plasmas, law.invention, Nuclear Energy and Engineering, Electromagnetic coil, law, 0103 physical sciences, Electromagnetic shielding, Environmental science, General Materials Science, Neutron, 010306 general physics, Civil and Structural Engineering, Leakage (electronics)

Abstract

Mitigation of the neutron environment inside the cryostat, and of the subsequent decay gamma dose field from activated materials, is necessary in order to reduce heating of coils and occupational exposure, thereby facilitating smooth operation and maintenance of ITER. Several lines of action are currently being explored to mitigate crucial contributions, such as the leakage through the lower ports. Results are presented here for the two types of lower ports in ITER: cryopump ports and remote-handling ports. Different shielding configurations and material options are investigated and compared in terms of neutron attenuation, coil heating and shutdown dose rate reduction, whilst also considering other engineering constraints such as weight or pumping power. Results enable informed decision-making of best compromise solutions for subsequent design and integration.

Published

2016

49. Neutronics related integration studies of EU-DEMO pellet injection system

Author

F. Lucca, Rosaria Villari, Antonio Frattolillo, F. Viganò, Fabio Moro, Fabio Cismondi, A. Colangeli, Davide Flammini, A. Marin, Colangeli, A., Villari, R., Moro, F., Flammini, D., Frattolillo, A., Lucca, F., Marin, A., Vigano, F., and Cismondi, F.

Subjects

Neutron transport, thermal analyses, Mechanical Engineering, Nuclear engineering, Pellets, Injector, DEMO, fueling systems, MCNP, neutronics, Blanket, Fueling systems, law.invention, Thermal – analyses, Nuclear Energy and Engineering, law, Electromagnetic shielding, Thermal, Neutronics, Environmental science, General Materials Science, Neutron, Engineering design process, Civil and Structural Engineering

Abstract

In the frame of the EU DEMO development program within the EUROfusion Consortium, the integration of the in-vessel components is crucial even at an early stage of the design process. The auxiliary, heating and fueling systems have to be integrated into the Breeding Blanket and, thus, they will undergo to a harsh nuclear environment during operation, and have a significant impact on the Tritium Breeding capability, loads and shielding performances. This work presents the neutronics and thermal analyses performed to support the integration studies of the pellet injection systems. This study is mainly devoted to optimize the design of a fueling line option consisting in a protrusion of the Vacuum Vessel (VV) in the inboard side supporting a guiding tube to drive the pellets along the ideal trajectory as close as possible to the First Wall. An alternative concept with a free-flight injector through the upper port, has also been studied evaluating the feasibility and the shielding needs. The three-dimensional neutronics simulations were carried-out with the MCNP5 Monte-Carlo code using a DEMO model with the integrated systems to calculate neutron fluxes, damage and nuclear heating distribution. Thermal analyses were carried-out using ABAQUS. Results of neutronics and thermal analyses on the fueling systems are presented and discussed.

Published

2020

50. Progress in development of advanced D1S dynamic code for three-dimensional shutdown dose rate calculations

Author

Davide Flammini, Rosaria Villari, N. Fonnesu, G. Mariano, Fabio Moro, Mariano, G., Flammini, D., Fonnesu, N., Moro, F., and Villari, R.

Subjects

Tokamak, Computer science, Mechanical Engineering, Shutdown, Nuclear engineering, Activation, Python (programming language), Fusion power, law.invention, Nuclear Energy and Engineering, law, Neutronics, Shutdown dose rate, Code development, D1S, General Materials Science, Neutron irradiation, Dose rate, computer, Civil and Structural Engineering, computer.programming_language

Abstract

The Advanced Direct 1-Step (AdD1S) is one of the most validated tools for the evaluation of Shutdown Dose Rate in complex fusion tokamak machines. The present work is built on the experience in analyzing tokamaks using prior versions of the code, where the activation analysis was limited to the first-step reactions. In the light of the neutron irradiation scenarios foreseen for fusion power reactors and the increasing importance of safety requirements, the possibility to treat the multi-step reactions introduced in the present version represents a novel and relevant development in the field. Moreover, a new Python library, PyD1S, has been developed to optimize the MCNP-FISPACT interface and data analysis. In this paper, the recent developments and the first applications are presented.

Published

2020