Application of Probabilistic Fracture Mechanics in Structural Design of Magnet Component Parts Operating Under Cyclic Loads at Cryogenic Temperatures

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Volume 1, Issue 8 (September 2004)

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ISSN: 1546-962X
Page Count: 21

Application of Probabilistic Fracture Mechanics in Structural Design of Magnet Component Parts Operating Under Cyclic Loads at Cryogenic Temperatures
Yatomi, M
Imperial College,

Nyilas, A
Forschungszentrum Karlsruhe, Institut für Technische Physik,

Portone, A
EFDA (European Fusion Development Association), Max Planck Institute for Plasma Physics,

Sborchia, C
ITER Joint Central Team,

Mitchell, N

Nikbin, K

Abstract

This paper presents a methodology for the use of probabilistic fracture mechanics concepts to estimate the design fatigue life and reliability of structural materials used in superconducting coils and magnet intercoil components of the International Thermonuclear Experimental Reactor (ITER). The orbitally welded conductor jackets of superconducting coils are subjected to fluctuating tensile stresses. The paper uses fatigue crack growth (FCGR) data at 7K from type 316LN stainless steel, in parent and weld material conditions, to predict fatigue crack growth rates using Monte Carlo analysis. Two stages are considered in which scatter could be quantified in the analysis. Initially, the unknown in crack length is taken as a stochastic variable. Secondly, the model assumes that the scatter observed in the correlation of the FCGR data versus ΔK is directly due to factors such as testing methods, measurement, material, and geometric variability and can therefore be quantified statistically. Either a normal or lognormal distribution of the scatter is assumed depending on the parameter. The purpose of this approach is to illustrate some of the advantages over a deterministic approach that most design codes use. An example is presented that compares the design life of a conductor jacket section containing a single crack and multiple cracks. A comparison of a sensitivity analysis for multiple cracks, for failure times at probabilities of 1 % and 0.001 %, with times calculated from a deterministic analysis using appropriate safety factors, suggests that the deterministic analysis give less conservative failure times.

Keywords:
ITER, fatigue crack, life prediction, 316LN, probabilistic fracture mechanics

Paper ID: JAI11575
DOI: 10.1520/JAI11575
ASTM International is a member of CrossRef.

Author Title Application of Probabilistic Fracture Mechanics in Structural Design of Magnet Component Parts Operating Under Cyclic Loads at Cryogenic Temperatures Symposium Probabilistic Aspects of Life Prediction, 2002-11-06 Committee E08

		Home Journals STPs Manuals Topics Subscriptions/Pricing Digital Library / Journals / Journal of ASTM International (JAI) / Citation Page Volume 1, Issue 8 (September 2004) Click here to download this paper now for $25 PDF (480K) View License Agreement ISSN: 1546-962X Page Count: 21 Application of Probabilistic Fracture Mechanics in Structural Design of Magnet Component Parts Operating Under Cyclic Loads at Cryogenic Temperatures Yatomi, M Imperial College, Nyilas, A Forschungszentrum Karlsruhe, Institut für Technische Physik, Portone, A EFDA (European Fusion Development Association), Max Planck Institute for Plasma Physics, Sborchia, C ITER Joint Central Team, Mitchell, N Nikbin, K Abstract This paper presents a methodology for the use of probabilistic fracture mechanics concepts to estimate the design fatigue life and reliability of structural materials used in superconducting coils and magnet intercoil components of the International Thermonuclear Experimental Reactor (ITER). The orbitally welded conductor jackets of superconducting coils are subjected to fluctuating tensile stresses. The paper uses fatigue crack growth (FCGR) data at 7K from type 316LN stainless steel, in parent and weld material conditions, to predict fatigue crack growth rates using Monte Carlo analysis. Two stages are considered in which scatter could be quantified in the analysis. Initially, the unknown in crack length is taken as a stochastic variable. Secondly, the model assumes that the scatter observed in the correlation of the FCGR data versus ΔK is directly due to factors such as testing methods, measurement, material, and geometric variability and can therefore be quantified statistically. Either a normal or lognormal distribution of the scatter is assumed depending on the parameter. The purpose of this approach is to illustrate some of the advantages over a deterministic approach that most design codes use. An example is presented that compares the design life of a conductor jacket section containing a single crack and multiple cracks. A comparison of a sensitivity analysis for multiple cracks, for failure times at probabilities of 1 % and 0.001 %, with times calculated from a deterministic analysis using appropriate safety factors, suggests that the deterministic analysis give less conservative failure times. Keywords: ITER, fatigue crack, life prediction, 316LN, probabilistic fracture mechanics Paper ID: JAI11575 DOI: 10.1520/JAI11575 ASTM International is a member of CrossRef. Author Title Application of Probabilistic Fracture Mechanics in Structural Design of Magnet Component Parts Operating Under Cyclic Loads at Cryogenic Temperatures Symposium Probabilistic Aspects of Life Prediction, 2002-11-06 Committee E08