Mechanical Properties of Fast Reactor Fuel Cladding for Transient Analysis

Hunter, C.W.; Johnson, George

doi:10.1520/stp38043s

Cited by 6 publications

(5 citation statements)

References 4 publications

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“…As with the steady-state fuel pin performance, there is also a Fuel Adjacency Effect exhibited under transient conditions for some cladding materials [16,17]. Both the Larson-Miller parameter and the Dorn parameter, as well as other correlation approaches, have been used to describe the dependence of fast reactor irradiated 20% cold worked 316 stainless steel cladding on the irradiation and transient conditions.…”

Section: Correlations For Time-to-failurementioning

confidence: 99%

Fuel Pin and Assembly Design

Waltar

Todd²

2011

Fast Spectrum Reactors

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This chapter deals with the mechanical designs of fuel pins and assemblies. These core components must be designed to withstand the high temperature, high flux environment of a fast spectrum reactor for a long irradiation exposure time. In this chapter we will describe many of the factors that influence this design, and we will examine in some detail the stress analysis of the fuel pin.We begin in Section 8.2 with the basic geometric and heat transfer relationships for the fuel pin, and then discuss some topics related to fuel and fission gas that must be considered in analysis of steady-state fuel-pin performance. The discussion of fuel-pin design is continued in Section 8.3, in which failure criteria and stress analysis are presented. Discussion is then shifted in Section 8.4 to grouping the pins into a fuel assembly. This will include discussion of mechanical design problems such as fuel-pin spacing and duct swelling. Limited attention is then directed to the design of other assemblies, including blanket, control and shielding assemblies. The final section of the chapter will provide a description of methods to restrain the assemblies and to control duct bowing. Fuel Pin Design ConsiderationsFuel pin design is a complex process that involves an integration of a wide range of phenomena. The design procedure must integrate the thermal analysis of the pin with an assessment of the characteristics of the fuel and cladding as a function of temperature and irradiation history and with the stress analysis of the fuel-cladding system. Many of the phenomena that affect fuel pin performance are illustrated schematically in Fig. 8.1. Each of these will be treated in Chapters 8 and 9, with additional discussions in Chapter 11. It should be readily apparent that there is no single way to order the examination of so many interacting phenomena. Each sequence selected to cover these tightly coupled processes will inherently suffer from the need for input from processes not yet discussed. In actual design practice, all of the governing processes are integrated in large time-dependent pin analysis codes such as LIFE [1].Our presentation will begin with the geometrical arrangement of the various sections of a fuel pin, including the function of each section. We will then extend the discussion of pin geometry to the selection of pin diameter. This will involve the concept of linear power. Fuel restructuring is then introduced, followed by fission gas release and the associated length of the gas plenum to establish A. Waltar (B) Pacific Northwest

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Section: Correlations For Time-to-failurementioning

confidence: 99%

Fuel Pin and Assembly Design

Waltar

Todd²

2011

Fast Spectrum Reactors

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“…Analyses using the LIFE-3 computer code (Ref. [3][4][5][6][7][8][9][10][11][12][13][14][15][16][17] indicate that, in the GCFR rod design, the pellet-to-clad diametrical gap never completely closes during steady-state lifetime operation. The presence of the relatively high primary system pressure within the rod suppresses the gaseous fission product component of fuel swelling.…”

Section: -29mentioning

confidence: 99%

“…(1) it reduces the oxygen available in the coolant for reaction with the stainless steel cladding, and (2) it affects the oxidation rate (Ref, [3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19].…”

Section: 49 Coolant-clad Chemical Reactionsmentioning

confidence: 99%

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Gas-Cooled Fast Breeder Reactor preliminary safety information document, Amendment 9. GCFR fuel cladding PC-5 (faulted) temperature limit

1980

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“…The knowledge about ageing-induced changes in terms of microstructure of the structural materials and in the fuel cladding [2,3] is not sufficient for the Gen IV reactors. Therefore, structural materials (included those developed for the Gen IV) have to be tested and the results of these tests need to provide microstructural interpretation.…”

Section: Introductionmentioning

confidence: 99%

Vacancy Type Defects in Oxide Dispersion Strengthened Steels

Slugeň

Veterníková

Degmová

et al. 2012

MSF

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This study was focused on commercial oxide-dispersion strengthened (ODS) steels - MA 956 (20%Cr), PM 2000 (19%Cr), ODM 751 (16%Cr) and MA 957 (14%Cr) developed for fuel cladding of GEN IV reactors. The ODS steels are described in order to comparison of their microstructure features. Vacancy defects were observed by Doppler Broadening Spectroscopy (DBS) and Positron Annihilation Lifetime Spectroscopy (PALS). Residual stress proportional to all kinds of defects was investigated by Magnetic Barkhausen Noise (MBN) measurement. The highest presence of open volume defects was found in MA 956 and the lowest defect concentration in MA 957, although this steel contains the largest defects (six-vacancies together with dislocations). Other investigated steels demonstrated probably three- or four-vacancy clusters. Further, results from positron technique indicated proportionality of chromium content to defect concentration. Magnetic Barkhausen noise results also showed that Hpeak value (describing grain size) increased with growth of chromium content. However residual stress was independent on chromium level.

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Mechanical Properties of Fast Reactor Fuel Cladding for Transient Analysis

Cited by 6 publications

References 4 publications

Fuel Pin and Assembly Design

Fuel Pin and Assembly Design

Gas-Cooled Fast Breeder Reactor preliminary safety information document, Amendment 9. GCFR fuel cladding PC-5 (faulted) temperature limit

Vacancy Type Defects in Oxide Dispersion Strengthened Steels

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