Safety in Tritium Handling Technology [electronic resource] /

Safety in Tritium Handling Technology [electronic resource] /

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The use of tritium as a basic fuel material in a thermonuclear fusion reactor raises particular safety issues due to the combined effects of its physico­ chemical properties and radioactive nature. Furthermore the possibility of attaining further significant progresses in developing and demonstrating the feasibility of tritium burning devices relies on the handling of tritium macroquantities, say ten grammes, in a safe and reliable manner. It is also undoubted that, apart from technological constraints, any validation and exploitation of thermonuclear fusion as a source of energy will be strongly conditioned by the application of stringent operational and environmental safety criteria as it derives from norms of the modern legislation and public acceptance considerations. Even if the safe handling of tritium has already been demonstrated to be feasible on a full fuel cycle scale, it is unanimously recognized that further efforts are still to be concentrated on the improvement of current concepts and development of advanced technologies. Some of the areas requiring substantial additional efforts are plasma exhaust fuel c1ean-up, tritium pellet injection, processing of inert carrier gas, development of large free-oil pumps,tritlUm process analytics, development of large detritiation systems, beryllium-tritium interaction studies, tritium hold-up studies in getter beds, adsorbers and structural materials, tritium recovery from first wall, structural and breeder materials for minimizing tritiated waste arising,tritium storage technology, tritiated waste disposal technolo~y, methodology for routine tritium accountancy,etc . . Most of them are intrinsically related to the safety requirement of tritium technology.

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Bibliographic Details
Main Authors: Mannone, F. editor., SpringerLink (Online service)
Format: Texto biblioteca
Language:eng
Published: Dordrecht : Springer Netherlands : Imprint: Springer, 1993
Subjects:Engineering., Quality control., Reliability., Industrial safety., Nuclear engineering., Environment., Environmental management., Nuclear Engineering., Environment, general., Environmental Management., Quality Control, Reliability, Safety and Risk.,
Online Access:http://dx.doi.org/10.1007/978-94-011-1910-8
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id KOHA-OAI-TEST:204051
record_format koha
institution COLPOS
collection Koha
country México
countrycode MX
component Bibliográfico
access En linea
En linea
databasecode cat-colpos
tag biblioteca
region America del Norte
libraryname Departamento de documentación y biblioteca de COLPOS
language eng
topic Engineering.
Quality control.
Reliability.
Industrial safety.
Nuclear engineering.
Environment.
Environmental management.
Engineering.
Nuclear Engineering.
Environment, general.
Environmental Management.
Quality Control, Reliability, Safety and Risk.
Engineering.
Quality control.
Reliability.
Industrial safety.
Nuclear engineering.
Environment.
Environmental management.
Engineering.
Nuclear Engineering.
Environment, general.
Environmental Management.
Quality Control, Reliability, Safety and Risk.
spellingShingle Engineering.
Quality control.
Reliability.
Industrial safety.
Nuclear engineering.
Environment.
Environmental management.
Engineering.
Nuclear Engineering.
Environment, general.
Environmental Management.
Quality Control, Reliability, Safety and Risk.
Engineering.
Quality control.
Reliability.
Industrial safety.
Nuclear engineering.
Environment.
Environmental management.
Engineering.
Nuclear Engineering.
Environment, general.
Environmental Management.
Quality Control, Reliability, Safety and Risk.
Mannone, F. editor.
SpringerLink (Online service)
Safety in Tritium Handling Technology [electronic resource] /
description The use of tritium as a basic fuel material in a thermonuclear fusion reactor raises particular safety issues due to the combined effects of its physico­ chemical properties and radioactive nature. Furthermore the possibility of attaining further significant progresses in developing and demonstrating the feasibility of tritium burning devices relies on the handling of tritium macroquantities, say ten grammes, in a safe and reliable manner. It is also undoubted that, apart from technological constraints, any validation and exploitation of thermonuclear fusion as a source of energy will be strongly conditioned by the application of stringent operational and environmental safety criteria as it derives from norms of the modern legislation and public acceptance considerations. Even if the safe handling of tritium has already been demonstrated to be feasible on a full fuel cycle scale, it is unanimously recognized that further efforts are still to be concentrated on the improvement of current concepts and development of advanced technologies. Some of the areas requiring substantial additional efforts are plasma exhaust fuel c1ean-up, tritium pellet injection, processing of inert carrier gas, development of large free-oil pumps,tritlUm process analytics, development of large detritiation systems, beryllium-tritium interaction studies, tritium hold-up studies in getter beds, adsorbers and structural materials, tritium recovery from first wall, structural and breeder materials for minimizing tritiated waste arising,tritium storage technology, tritiated waste disposal technolo~y, methodology for routine tritium accountancy,etc . . Most of them are intrinsically related to the safety requirement of tritium technology.
format Texto
topic_facet Engineering.
Quality control.
Reliability.
Industrial safety.
Nuclear engineering.
Environment.
Environmental management.
Engineering.
Nuclear Engineering.
Environment, general.
Environmental Management.
Quality Control, Reliability, Safety and Risk.
author Mannone, F. editor.
SpringerLink (Online service)
author_facet Mannone, F. editor.
SpringerLink (Online service)
author_sort Mannone, F. editor.
title Safety in Tritium Handling Technology [electronic resource] /
title_short Safety in Tritium Handling Technology [electronic resource] /
title_full Safety in Tritium Handling Technology [electronic resource] /
title_fullStr Safety in Tritium Handling Technology [electronic resource] /
title_full_unstemmed Safety in Tritium Handling Technology [electronic resource] /
title_sort safety in tritium handling technology [electronic resource] /
publisher Dordrecht : Springer Netherlands : Imprint: Springer,
publishDate 1993
url http://dx.doi.org/10.1007/978-94-011-1910-8
work_keys_str_mv AT mannonefeditor safetyintritiumhandlingtechnologyelectronicresource
AT springerlinkonlineservice safetyintritiumhandlingtechnologyelectronicresource
_version_ 1756267921817993216
spelling KOHA-OAI-TEST:2040512018-07-30T23:32:43ZSafety in Tritium Handling Technology [electronic resource] / Mannone, F. editor. SpringerLink (Online service) textDordrecht : Springer Netherlands : Imprint: Springer,1993.engThe use of tritium as a basic fuel material in a thermonuclear fusion reactor raises particular safety issues due to the combined effects of its physico­ chemical properties and radioactive nature. Furthermore the possibility of attaining further significant progresses in developing and demonstrating the feasibility of tritium burning devices relies on the handling of tritium macroquantities, say ten grammes, in a safe and reliable manner. It is also undoubted that, apart from technological constraints, any validation and exploitation of thermonuclear fusion as a source of energy will be strongly conditioned by the application of stringent operational and environmental safety criteria as it derives from norms of the modern legislation and public acceptance considerations. Even if the safe handling of tritium has already been demonstrated to be feasible on a full fuel cycle scale, it is unanimously recognized that further efforts are still to be concentrated on the improvement of current concepts and development of advanced technologies. Some of the areas requiring substantial additional efforts are plasma exhaust fuel c1ean-up, tritium pellet injection, processing of inert carrier gas, development of large free-oil pumps,tritlUm process analytics, development of large detritiation systems, beryllium-tritium interaction studies, tritium hold-up studies in getter beds, adsorbers and structural materials, tritium recovery from first wall, structural and breeder materials for minimizing tritiated waste arising,tritium storage technology, tritiated waste disposal technolo~y, methodology for routine tritium accountancy,etc . . Most of them are intrinsically related to the safety requirement of tritium technology.1. Fundamentals on Tritium -- 2. Tritium Processing Using Scavenger Beds Theory and Operation -- 3. Tritium Handling Options: From NET to Power Reactor -- 4. Tritium Materials Interactions -- 5. Tritium Storage -- 6. Tritium Containment -- 7. Radiation Protection -Tritium Instrumentation and Monitoring Methods -- 8. Tritium Biological Hazard and Dosimetry -- 9. Radiological Protection and Environmental Safety -- 10. Dismantling of Tritiated Facilities Management of Tritiated Wastes -- 11. JET Tritium Experience.The use of tritium as a basic fuel material in a thermonuclear fusion reactor raises particular safety issues due to the combined effects of its physico­ chemical properties and radioactive nature. Furthermore the possibility of attaining further significant progresses in developing and demonstrating the feasibility of tritium burning devices relies on the handling of tritium macroquantities, say ten grammes, in a safe and reliable manner. It is also undoubted that, apart from technological constraints, any validation and exploitation of thermonuclear fusion as a source of energy will be strongly conditioned by the application of stringent operational and environmental safety criteria as it derives from norms of the modern legislation and public acceptance considerations. Even if the safe handling of tritium has already been demonstrated to be feasible on a full fuel cycle scale, it is unanimously recognized that further efforts are still to be concentrated on the improvement of current concepts and development of advanced technologies. Some of the areas requiring substantial additional efforts are plasma exhaust fuel c1ean-up, tritium pellet injection, processing of inert carrier gas, development of large free-oil pumps,tritlUm process analytics, development of large detritiation systems, beryllium-tritium interaction studies, tritium hold-up studies in getter beds, adsorbers and structural materials, tritium recovery from first wall, structural and breeder materials for minimizing tritiated waste arising,tritium storage technology, tritiated waste disposal technolo~y, methodology for routine tritium accountancy,etc . . Most of them are intrinsically related to the safety requirement of tritium technology.Engineering.Quality control.Reliability.Industrial safety.Nuclear engineering.Environment.Environmental management.Engineering.Nuclear Engineering.Environment, general.Environmental Management.Quality Control, Reliability, Safety and Risk.Springer eBookshttp://dx.doi.org/10.1007/978-94-011-1910-8URN:ISBN:9789401119108

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