Engineering Compendium on Radiation Shielding

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Volume 2: Shielding Materials

ISBN:	3642650031
ISBN 13:	9783642650031
Herausgeber:	R G Jaeger/E P Blizard/A B Chilton et al
Verlag:	Springer Verlag GmbH
Umfang:	xii, 436 S.
Erscheinungsdatum:	21.12.2011
Auflage:	1/1975
Produktform:	Kartoniert
Einband:	Kartoniert

Inhaltsangabe9 Shielding Materials.- 9.1. Materials against gamma rays.- 9.1.1. Lead and lead alloys.- 9.1.1.1. Introduction.- 9.1.1.2. Occurrence and extraction.- 9.1.1.3. Properties.- 9.1.1.4. Fabrication.- 9.1.1.5. Applications and design considerations.- 9.1.2. Steel (iron and iron alloys).- 9.1.2.1. Introduction.- 9.1.2.2. Occurrence and extraction.- 9.1.2.3. Properties.- 9.1.2.4. Fabrication.- 9.1.2.5. Applications and design considerations.- 9.1.3. Uranium.- 9.1.3.1. Introduction.- 9.1.3.2. Occurrence and extraction.- 9.1.3.3. Properties.- 9.1.3.4. Fabrication.- 9.1.3.5. Applications and design considerations.- 9.1.4. Tungsten.- 9.1.4.1. Introduction.- 9.1.4.2. Occurrence and extraction.- 9.1.4.3. Properties.- 9.1.4.4. Fabrication.- 9.1.4.5. Applications and design considerations.- 9.1.5. Bismuth.- 9.1.5.1. Introduction.- 9.1.5.2. Occurrence and extraction.- 9.1.5.3. Properties.- 9.1.5.4. Fabrication.- 9.1.6. Copper.- 9.1.6.1. Introduction.- 9.1.6.2. Occurrence and extraction.- 9.1.6.3. Properties.- 9.1.6.4. Fabrication.- 9.1.7. Aluminum.- 9.1.7.1. Introduction.- 9.1.7.2. Occurrence and extraction.- 9.1.7.3. Properties.- 9.1.7.4. Fabrication.- 9.1.8. Soil.- 9.1.8.1. Introduction.- 9.1.8.2. Method of calculation.- 9.1.9. Ceramics.- 9.1.9.1. Composition, properties and technology.- 9.1.9.2. Properties of commonly used ceramics.- 9.1.9.3. Properties of special ceramics for shielding.- 9.1.9.4. Shapes of shielding ceramic products.- 9.1.9.5. Utilization of ceramics.- 9.1.10. Water.- 9.1.10.1. Mechanical and technological properties of water.- 9.1.10.2. Decomposition of water by radiation.- 9.1.10.3. Corrosion problems in water.- 9.1.10.4. Gamma-ray attenuation in water.- 9.1.10.5. Photonuclear reactions in water.- 9.1.11. Transparent shielding materials.- 9.1.11.1. Silicate and lead glasses.- 9.1.11.2. Zinc bromide solution.- 9.1.12. Concretes, cements, mortars, and grouts.- 9.1.12.1. General discussion of concrete properties, composition, and technology.- 9.1.12.2. New trends in concrete construction.- 9.1.12.3. Concretes for shielding.- 9.1.12.4. The technology of concrete.- 9.1.12.5. Nuclear heating, radiation damage, and protection of concretes.- 9.1.12.6. Design criteria.- 9.1.12.7. Responsibilities of the concrete engineer and shield designer in undertaking the design and proportioning of concrete for shields.- 9.1.12.8. Ordinary (Portland) concrete.- 9.1.12.9. Serpentine concrete.- 9.1.12.10. The desirability and use of heavy concrete.- 9.1.12.11. Ferrophosphorus concrete.- 9.1.12.12. Iron ore concretes (hematite, goethite, limonite, magnetite).- 9.1.12.13. Limonite and magnetite concretes.- 9.1.12.14. A study of heavy concrete using magnetite from the Dielette mine in France.- 9.1.12.15. Barytes (barite) concretes.- 9.1.12.16. Special concretes based on barytes.- 9.1.12.17. Iron-Portland (scrap-based) very heavy concrete.- 9.1.12.18. Iron-based concretes with addition of a dense mineral, developed at Saclay.- 9.1.12.19. Boron containing, scrap-based, very heavy concretes developed at Saclay.- 9.1.12.20. Ilmenite concrete.- 9.1.12.21. Magnesium oxychloride (MO and Ml) concretes.- 9.1.12.22. Other borated concretes.- 9.1.12.23. Making concretes with desired physical properties.- 9.1.12.24. Prepacked concrete design data for U.S. reactor shields.- 9.1.12.25. Elemental compositions of concretes.- 9.1.12.26. Nuclear properties and constants for concretes.- 9.1.12.27. Technical specification for very heavy concrete.- 9.1.12.28. Cost data for concrete.- 9.1.12.29. Cements.- 9.1.12.31. Mortars.- 9.1.12.32. Grouts.- 9.1.12.33. Sand.- 9.1.13. Air.- 9.2. Materials for shielding against neutrons and gamma rays.- 9.2.1. Lead and Lead alloys.- 9.2.1.1. Introduction.- 9.2.1.2. Applications and design considerations.- 9.2.2. Steel (iron and iron alloys).- 9.2.2.1. Introduction.- 9.2.2.2. Applications and design considerations.- 9.2.3. Uranium.- 9.2.3.1. Introduction.- 9.2.3.2. Applications and design considerations.- 9.2.4. Tungsten.- 9.2.4.1.

Sponsored by International Atomic Energy Agency, Vienna

Artikelnummer: 4369689 Kategorie: Wärme-, Energie- und Kraftwerktechnik

Beschreibung

Beschreibung

The utilization of nuclear energy makes great demands on the knowledge of the engineers engaged in design work and calculations relating to construction in nuclear industry. Apart, of course, from nuclear reactors themselves, a great deal of nuclear experience is involved in the design and construction of radiotherapy centres, non destructive testing laboratories, particle accelerators, radioisotope laboratories and nuclear research plants. Whereas in the USA there appears to be no great difference in the methods of training personnel for fundamental or for applied science, European universities draw a sharp dividing line between the two fields. However, if we consider graduates solely from the point of view of their activities at their place of employment, two types of personnel can be distinguished: scientifically oriented research workers and those with a more technical and practical background who are looking for rational and rapid methods and solutions, even at some expense in terms of accuracy. The Engineering Compendium on Radiation Shielding endeavours to cover both approaches, the scientific and the technical. Volume I was devoted to the fundamental aspects of shielding, while Volumes II and III discuss its technology.