Your search keyword '"Bragagni A."' showing total 7 results

1. Series Faults in Electrical Cords and Extension Cords

Author

Luigi Parise, Elisabetta Bragagni Capaccini, Giuseppe Parise, Erling Hesla, and Claudio S. Mardegan

Subjects

arcing and burning, Computer science, 0211 other engineering and technologies, Hardware_PERFORMANCEANDRELIABILITY, 02 engineering and technology, Fault (power engineering), Electric arc, Electric power system, fire ignition hazard, 021105 building & construction, 0502 economics and business, medicine, circuit protection, Electrical conductor, Overheating (electricity), Electronic circuit, arcing fault, 050210 logistics & transportation, business.industry, Ground, Electric shock, 05 social sciences, Structural engineering, medicine.disease, anomalous overheating, business

Abstract

In electrical power systems, the cords and extension cords are exposed to mechanical damage and other insulation stresses. Mechanical damage to the stranded conductors can reduce locally their cross section or break them and cause anomalous local conditions of overheating or arcing. The ordinary protective devices cannot detect the series faults that persist; so the fault point remains energized and subject to electric shock and fire hazards. Effective protection can be accomplished by implementing active and passive measures: installing Arc-fault Circuit Interrupters (AFCI) or Detection Devices (AFDD), able to detect arcing faults; or wiring the circuits with a grounding protection conductor to involve the ground in every fault. In this way, residual current protective devices (RCDs or GFPDs) protect quickly the series faults with arc, but also without arc. The Ground-Fault-Forced Cables (GFFCs) facilitate the conversion of any kind of fault to a ground fault in all the applications and are particularly recommended for cords and extension cords, internal circuits to grounded equipment, UPS continuity circuits, aircraft circuits, road tunnels, data centers, residential houses and hospitals.

Published

2019

2. Design and Characterization of the Interlayer Joint Between Low-Field Nb3Sn Conductors of a Layer Wound DEMO TF Coil.

Author

Muzzi, Luigi, Affinito, Luigi, Chiarelli, Sandro, Corato, Valentina, della Corte, Antonio, De Marzi, Gianluca, Di Zenobio, Aldo, Zignani, Chiarasole Fiamozzi, Freda, Rosa, Turtu, Simonetta, Anemona, Alessandro, Formichetti, Andrea, Righetti, Riccardo, Arabi, Mohammed, Bragagni, Albano, Seri, Massimo, Roveta, Guido, Roveta, Marco, Galignano, Stefano, and Merli, Lucio

Subjects

SUPERCONDUCTING wire, COPPER wire, SUPERCONDUCTING cables, CONCEPTUAL design, SUPERCONDUCTING magnets

Abstract

In the frame of the conceptual design studies for the Toroidal Field (TF) coils of DEMO, a solution based on a layer-wound magnet, rectangular-shaped Cable-in-Conduit conductors and W&R manufacturing approach, is being developed. The feasibility and performance of a large-size Nb3Sn conductor operating at about 82 kA in a 13 T field has been proven in the past. Another key technology to be demonstrated for a layer-wound TF coil, is that of a joint between two different conductor grades, to be possibly manufactured in-line during winding. The proposed joint solution would provide the minimum room occupancy, with the joint embedded within the winding pack volume. A joint between two low-field conductor grades, i.e., constituted of a small number of superconducting strands and a high number of stabilization copper wires, has been designed and manufactured. The two conductor lengths are characterized by a different number of superconducting wires and different outer dimensions. A joint sample has been assembled and instrumented, in the configuration allowing testing at the SULTAN facility of the Swiss Plasma Center. Both DC and AC performance of the joint has been characterized at the DEMO TF operating conditions. The present paper reports the main manufacturing steps for the joint and its main test results. The implications on the performance and design approach of the TF coil are also discussed, based on the outcome of such tests. [ABSTRACT FROM AUTHOR]

Published

2021

3. Series Faults in Electrical Cords and Extension Cords

Author

Parise, Giuseppe, primary, Hesla, Erling, additional, Mardegan, Claudio S., additional, Parise, Luigi, additional, and Capaccini, Elisabetta Bragagni, additional

Published

2019

4. Measures to Minimize Series Faults in Electrical Cords and Extension Cords.

Author

Parise, Giuseppe, Hesla, Erling, Mardegan, Claudio S., Parise, Luigi, and Capaccini, Elisabetta Bragagni

Subjects

UNINTERRUPTIBLE power supply, TUNNELS, ELECTRIC shock, SERVER farms (Computer network management), WENCHUAN Earthquake, China, 2008, AUTOMATIC dependent surveillance-broadcast

Abstract

In electrical power systems, cords and extension cords are exposed to mechanical damage and other insulation stresses. Mechanical damage to stranded conductors can reduce locally their cross section or break them and cause anomalous local conditions of overheating or arcing. The ordinary protective devices cannot detect the series faults that persist, so the fault point remains energized and is subject to electric shock and fire hazards. Effective protection can be accomplished by implementing active and passive measures: installing arc-fault circuit interrupters or arc-fault detection devices, able to detect arcing faults, or wiring the circuits with a grounding protection conductor to involve the ground in every fault. In this way, residual current protective devices (residual current devices or ground fault protective devices) quickly protect the series faults not only with arc, but also without it. Ground-fault-forced cables facilitate by design the conversion of any kind of cable fault to a ground fault. They are particularly recommended for cords and extension cords, internal circuits to grounded equipment, uninterruptible power system continuity circuits, aircraft circuits, road tunnels, data centers, refrigerated containers parks, residences, and hospitals. [ABSTRACT FROM AUTHOR]

Published

2019

5. Design of an Industrially Feasible Twisted-Stack HTS Cable-in-Conduit Conductor for Fusion Application.

Author

Celentano, G., De Marzi, G., Fabbri, F., Muzzi, L., Tomassetti, G., Anemona, A., Chiarelli, S., Seri, M., Bragagni, A., and della Corte, A.

Subjects

SUPERCONDUCTING magnets, ELECTRICAL conductors, HIGH temperature superconductors, SUPERCONDUCTING wire, MAGNETISM

Abstract

Taking advantage of the large experience of the ENEA Superconducting Laboratory in the manufacture and characterization of large scale superconducting systems, a project was launched, aimed at using High Temperature Superconductor (HTS) 2G wires for the manufacture of a cable-in-conduit conductor (CICC). In particular, the main aim was the definition of a conductor design fully compatible with existing cabling technologies, to be promptly transferred to an industrial scale production. The considered layout is based on 150 HTS tapes, arranged as five layered structures of twisted tapes wound on a helically slotted core with external round jacket. All manufacturing steps (slotted core production, tape stacking and insertion into the ducts, external wrapping and jacketing) are fulfilled by using equipments and technologies available at TRATOS Cavi S.p.A. These CICCs are intended for operation using forced flow of Helium. A 2D local thermal model has been developed for the optimization of the cooling configuration. This conductor is designed to target 20 kA at 4.2 K and 15 T (or, alternatively, higher temperature, in self-field and LN2 cooling) corresponding to a Je of about 55 \A/mm^2. The production of a short dummy sample revealed that the exploited industrial production process is very promising for the development of HTS CICC. [ABSTRACT FROM PUBLISHER]

Published

2014

6. A New European Production Line for CIC Conductors.

Author

della Corte, Antonio, Affinito, L., Besi Vetrella, U., Chiarelli, S., Di Zenobio, A., Morici, L., Muzzi, L., Polli, G. M., Reccia, L., Turtu, S., Bragagni, A., Scoccini, G., Seri, M., Valori, D., Quagliata, F., Roveta, G., and Roveta, M.

Subjects

SUPERCONDUCTING magnets, SUPERCONDUCTIVITY, SUSTAINABLE development, TOKAMAKS

Abstract

The on-going construction of the ITER and JT-60SA tokamak reactors requires the production of a large quantity of Cable-In-Conduit Conductors (CICCs) to be employed in the superconducting magnets for plasma confinement and control. A new company, named ICAS (Italian Consortium for Applied Superconductivity), was established thanks to the large expertise in this field that has been present in Italy for nearly three decades. ICAS is a consortium among ENEA (Italian National Agency for New Technologies, Energy and Sustainable Economic Development) and two Italian private companies: CRIOTEC Impianti, which owns an 850m long jacketing line for CICCs, and TRATOS Cavi, which has a large experience in cable manufacturing for various applications. ICAS' current activities are aimed at supplying to Fusion for Energy the European quote of ITER TF and PF conductors and the whole JT-60SA TF conductor quantity, as well as at supplying to the Korean Domestic Agency about 19 km of ITER TF conductor. This paper offers an overview of ICAS' technical capabilities and facilities, and outlines the first outcomes from the first productions. [ABSTRACT FROM PUBLISHER]

Published

2012

7. Conductor Manufacturing of the ITER TF Full-Size Performance Samples.

Author

Di Zenobio, A., della Corte, A., Muzzi, L., Turtù, S., Bragagni, A., Tanguenza, A., Valori, D., Baldini, A., Bessette, D., Devred, A., and Vostner, A.

Subjects

TOROIDAL magnetic circuits, MAGNETIC circuits, ELECTRIC conduits, SUPERCONDUCTORS

Abstract

In the framework of the final design activities related to the ITER Toroidal Field (TF) coils, following the very good results obtained during the TF Prototype Conductors measurement campaign, Fusion For Energy, the European Domestic Agency for ITER, has launched the conductor performance qualification phase in order to confirm the final ITER TF conductor design. Six conductor lengths have been cabled by different Nb3Sn strand types coming from different producers: LUVATA Pori, Oxford Instruments Superconducting Technology (OST), ALSTOM (for two different strand layouts) and European Advanced Superconductors (EAS) (for two different strand layouts). ENEA has been in charge of performing QA and monitoring activity during the conductor production at LUVATA Fornaci di Barga and TRATOS Cavi, and to make visual/destructive tests over some spare lengths of the samples in order to have a detailed characterization of the produced conductors. The conductor unit lengths have been successfully manufactured and all the different work phases are here described, along with a discussion of the encountered problems and the adopted solutions. Five samples have been successfully tested in the SULTAN facility during 2009. [ABSTRACT FROM AUTHOR]

Published

2010