Your search keyword '"Eboli, M"' showing total 11 results

1. Advancements in DEMO WCLL breeding blanket design and integration

Author

Martelli, E., Del Nevo, Arena, P., Bongiovì, G., Caruso, G., Di Maio, P. A. ., Eboli, M., Mariano, G., Marinari, R., Moro, F., MOZZILLO, ROCCO, Giannetti, F., DI GIRONIMO, GIUSEPPE, TARALLO, ANDREA, Tassone, A., Villari, S., Martelli, E., Del, Nevo, Arena, P., Bongiovì, G., Caruso, G., Di Maio, P. A. ., Eboli, M., Mariano, G., Marinari, R., Moro, F., Mozzillo, Rocco, Giannetti, F., DI GIRONIMO, Giuseppe, Tarallo, Andrea, Tassone, A., and Villari, S.

Subjects

breeding blanket, DEMO, WCLL

Abstract

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 2015specifications and represents the follow-up of the design developed in 2015. The single-module-segment approach isemployed. This is constituted by a basic geometry repeated along the poloidal direction. The power is removed by meansof radial–toroidal (i.e., horizontal) water cooling tubes in the breeding zone. The lithium–lead flows in a radial–poloidaldirection. On the back of the segment, a 100-mm-thick plate is in charge of withstanding the loads due to normal operationand selected postulated initiating events. Water and lithium–lead manifolds are designed and integrated with a consistentprimary heat transport system, based on a reliable pressurized water reactor operating experience, and the lithium–leadsystem. Rationale and features of the single-module-segment water-cooled lithium–lead breeding blanket design arediscussed and supported by thermo-mechanic, thermo-hydraulic, and neutronic analyses. Preliminary integration withthe primary heat transfer system, the energy storage system, and the balance of plant is briefly discussed. Open issues, areasof research, and development needs are finally pointed out.

Published

2018

2. Advancements in DEMO WCLL breeding blanket design and integration

Author

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

Subjects

breeding blanket, breeding blanket, DEMO, WCLL, DEMO, WCLL, Settore ING-IND/19 - Impianti Nucleari

Abstract

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

Published

2018

3. Thermal-hydraulic assessment of the Steam Generator mock-up for the EU DEMO WCLL using CFD co-simulation.

Author

Caterino, D., Del Nevo, A., Eboli, M., Froio, A., Marinari, R., Vannoni, A., and Zappatore, A.

Subjects

*STEAM generators, *COMPUTATIONAL fluid dynamics, *HEATING, *HEAT transfer

Abstract

The Primary Heat Transfer System (PHTS) of the EU DEMO Water-Cooled Lithium-Lead (WCLL) Breeding Blanket might rely on Once-Through Steam Generators (OTSGs) technology, widely used in fission industry. ENEA is currently developing the STEAM facility, in order to characterize the behaviour of the EU DEMO OTSG. To this aim, a dedicated OTSG mock-up is being designed. The present work describes the Computational Fluid Dynamics (CFD) approach used to investigate the flow field within the inlet and outlet regions of the OTSG mock-up in steady-state conditions. One of the key objectives of the analysis is to assess the mass flow distribution within the OTSG primary bundle, as uniform distribution is crucial for achieving the desired performance. To this aim, the computational approach employs reliable models such as RANS k − ϵ as well as a fluid–fluid co-simulation routine. The aim is to reach a satisfactory self-consistency of the flow distribution within the OTSG primary bundle without the discretization of the full geometry. The CFD analysis predicts a maximum absolute deviation from the average mass flow rate value lower than 2%. This predicted behaviour is compared against a benchmark simulation that discretizes the whole primary bundle. The comparison displays an acceptable compatibility and a significant reduction in the required computational resources thanks to the implementation of a co-simulation routine. [ABSTRACT FROM AUTHOR]

Published

2024

4. 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

5. Status of Pb-16Li technologies for European DEMO fusion reactor.

Author

Utili, M., Bassini, S., Boccaccini, L., Bühler, L., Cismondi, F., Del Nevo, A., Eboli, M., DiFonzo, F., Hernandez, T., Wulf, S., Kordač, M., Martelli, D., De les Valls, E. Mas, Melichar, T., Mistrangelo, C., Tarantino, M., Tincani, A., and Vála, L.

Subjects

*FUSION reactor blankets, *FUSION reactors, *HEAT transfer, *TRITIUM, *TECHNOLOGY

Abstract

• The preliminary Pb15.7Li Loop layout was shown in the paper. • The Magneto Hydro Dynamic effect induced in the flowing Pb-16Li inside BB and the pressure drops generated were analysed. • The developed anti-permeation and corrosion barriers inside the BB where shown. • The code developed to analyse the In-box Loca inside WCLL BB was introduced. • Preliminary integration of Pb-16Li loops inside the tokamak building was shown. Three of the four breeder blanket concepts currently under investigation for the European DEMO Reactor use the eutectic Pb-16Li as breeder material. Those are the Helium Cooled Lithium Lead (HCLL), Water Cooled Lithium Lead (WCLL) and Dual Coolant Lithium Lead (DCLL) blankets. Moreover, the WCLL is one of the blanket concepts that will be qualified in the ITER reactor, therefore the development and design of lead lithium loops and auxiliary systems is essential. The main functional requirements that Pb-16Li systems have to fulfill are: • to circulate the liquid Pb-16Li through the blanket and ancillaries; • to extract the tritium produced inside the breeder modules from Pb-16Li; • to control Pb-16Li chemistry and to remove accumulated impurities; The present work aims to describe the activities performed in order to achieve the following objectives: i) design and integration of the Pb-16Li loops inside the tokamak building, ii) development and characterization of antipermeation and anticorrosion coatings on structures in contact with Pb-16Li, iii) development and design of an activation products removal system, iv) design of a chemistry control system for Pb-16Li loops, v) performing magnetohydrodynamic analyses taking into account the impact on heat transfer and tritium transport in breeding blankets and performing safety analyses of water/Pb-16Li interaction due to LOCA inside the WCLL blanket. [ABSTRACT FROM AUTHOR]

Published

2019

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

Author

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., and Tassone, A.

Subjects

*FUSION reactor blankets, *CONCEPTUAL design, *FUSION reactors, *PRESSURIZED water reactors

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. [ABSTRACT FROM AUTHOR]

Published

2019

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

Author

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., and Utili, M.

Subjects

*FUSION reactor blankets, *FUSION reactors, *WATER cooled reactors, *THERMAL hydraulics, *INTEGRATION (Theory of knowledge)

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. [ABSTRACT FROM AUTHOR]

Published

2017

8. 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

9. Status of Pb-16Li technologies for European DEMO fusion reactor

Author

Daniele Martelli, Lorenzo Virgilio Boccaccini, Serena Bassini, Tomáš Melichar, A. Del Nevo, Ladislav Vála, Chiara Mistrangelo, T. Hernández, Michal Kordač, Fabio Cismondi, Marica Eboli, E. Mas de les Valls, A. Tincani, Marco Utili, F. DiFonzo, Sven-Erik Wulf, Mariano Tarantino, Leo Bühler, Utili, M., Bassini, S., Boccaccini, L., Buhler, L., Cismondi, F., Del Nevo, A., Eboli, M., Difonzo, F., Hernandez, T., Wulf, S., Kordac, M., Martelli, D., De les Valls, E. M., Melichar, T., Mistrangelo, C., Tarantino, M., Tincani, A., and Vala, L.

Subjects

Tokamak, Nuclear engineering, chemistry.chemical_element, Blanket, BB, 7. Clean energy, 01 natural sciences, 010305 fluids & plasmas, law.invention, Breeder (animal), law, 0103 physical sciences, General Materials Science, 010306 general physics, Civil and Structural Engineering, Pb-16Li, Mechanical Engineering, Water cooled, Fusion power, Coolant, WCLL, DCLL, HCLL, Loop, Nuclear Energy and Engineering, chemistry, Lithium

Abstract

Three of the four breeder blanket concepts currently under investigation for the European DEMO Reactor use the eutectic Pb-16Li as breeder material. Those are the Helium Cooled Lithium Lead (HCLL), Water Cooled Lithium Lead (WCLL) and Dual Coolant Lithium Lead (DCLL) blankets. Moreover, the WCLL is one of the blanket concepts that will be qualified in the ITER reactor, therefore the development and design of lead lithium loops and auxiliary systems is essential. The main functional requirements that Pb-16Li systems have to fulfill are: • to circulate the liquid Pb-16Li through the blanket and ancillaries; • to extract the tritium produced inside the breeder modules from Pb-16Li; • to control Pb-16Li chemistry and to remove accumulated impurities; The present work aims to describe the activities performed in order to achieve the following objectives: i) design and integration of the Pb-16Li loops inside the tokamak building, ii) development and characterization of antipermeation and anticorrosion coatings on structures in contact with Pb-16Li, iii) development and design of an activation products removal system, iv) design of a chemistry control system for Pb-16Li loops, v) performing magnetohydrodynamic analyses taking into account the impact on heat transfer and tritium transport in breeding blankets and performing safety analyses of water/Pb-16Li interaction due to LOCA inside the WCLL blanket.

Published

2019

10. Development of a SIMMER\RELAP5 coupling tool

Author

G. Barone, Marica Eboli, Bruno Gonfiotti, Samad Khani Moghanaki, Daniele Martelli, Alessandro Del Nevo, Gonfiotti, B., Moghanaki, S. K., Eboli, M., Barone, G., Del Nevo, A., and Martelli, D.

Subjects

Computer science, Nuclear engineering, Chemical interaction, Blanket, 7. Clean energy, 01 natural sciences, 010305 fluids & plasmas, PbLi, Development (topology), 0103 physical sciences, General Materials Science, 010306 general physics, Civil and Structural Engineering, Coupling, RELAP5 code, Mechanical Engineering, Frame (networking), Fusion power, Coolant, WCLL, Test case, Coupling codes, Nuclear Energy and Engineering, Coupling code, SIMMER-III code

Abstract

The In-Box Loss Of Coolant (LOCA) postulated accident is considered a major concern for the safety connected with the development of EU-DEMO fusion reactor. Relating to the renewed interest in the Water-Cooled Lithium Led blanket concept, an innovative experimental campaign is under development at ENEA Brasimone laboratories aiming at investigating the consequences related to the In-Box LOCA applied to the WCLL breeding blanket. In this frame, a new coupling tool between the SIMMER-III (modified version to implement the PbLi/water chemical interaction) and the RELAP5/Mod3.3 codes (modified version to implement PbLi thermo-physical properties) has been developed together with its preliminary application to simple test cases with water as working fluid. The coupling procedure can be defined as a “two-way”, “non-overlapping”, “online” technique aiming at investigating multi-physics and multi-scales phenomena in support of the development of fusion reactor technologies.

Published

2019

11. RELAP5/SIMMER-III code coupling development for PbLi-water interaction

Author

Nicola Forgione, Samad Khani Moghanaki, Rosa Lo Frano, Alessandro Del Nevo, F. Galleni, M. Eboli, Riccardo Ciolini, Sandro Paci, Galleni, F., Moghanaki, S., Eboli, M., Del Nevo, A., Paci, S., Ciolini, R., Lo Frano, R., and Forgione, N.

Subjects

Exothermic reaction, Materials science, Hydrogen, Nuclear engineering, chemistry.chemical_element, Blanket, 7. Clean energy, 01 natural sciences, Chemical reaction, PbLi, 010305 fluids & plasmas, 0103 physical sciences, General Materials Science, Neutron, 010306 general physics, Civil and Structural Engineering, RELAP5 code, Mechanical Engineering, Fusion power, Code coupling, WCLL, Coolant, Coupling codes, Nuclear Energy and Engineering, chemistry, Coupling code, SIMMER-III code

Abstract

A major safety issue in the Water-Cooled Lead-Lithium Breeding Blanket (WCLL-BB) system foreseen for fusion reactor is the interaction concerning the primary coolant (water) and the neutron multiplier (PbLi), due to a hypothetical tube rupture in the coolant circuit. This scenario involves an exothermic chemical reaction between PbLi and water with the production of hydrogen, in addition to critical interactions in a complex multiphase system in non-thermal equilibrium. In recent years the PbLi/water reaction was successfully implemented in the SIMMER-III code and validated against data from the LIFUS5/Mod3 experimental campaign. However, due to limitations of SIMMER-III, this work was restricted to the prediction of the phenomena inside the vessel, neglecting the simulation of the injection line. Nevertheless, since the injection line may actually have an important effect on the development of the transient, the simulation of the whole facility would be highly desirable. Indeed, the University of Pisa recently developed a coupling methodology between the SIMMER-III and RELAP5/Mod3.3 codes and applied it to simple single-phase cases. In this paper the complete simulation of the LIFUS5/Mod3 facility is presented, with the injection line modelled through RELAP5. Furthermore, all the complex aspects of the phenomena inside the reaction tank were included: the multiphase system and the interaction between water and PbLi with the chemical reaction and the production of hydrogen were modelled by SIMMER. Preliminary results are presented, showing that the coupling methodology can be effectively employed for the prediction of the chemical and thermal-hydraulic behaviour of complex loop experimental facilities.

Published

2020