Link between results of small- and large-scale toughness tests on irradiated zr-2.5nb pressure tube material
Author : P. H. Davies
Publisher :
Page : 0 pages
File Size : 25,61 MB
Release : 1997
Category :
ISBN :
Link Between Results of Small- and Large-Scale Toughness Tests on Irradiated Zr-2.5Nb Pressure Tube Material
Author : PH. Davies
Publisher :
Page : 26 pages
File Size : 16,53 MB
Release : 1996
Category : Congress
ISBN :
Book Description
The link between the results of small- (curved compact) and large-scale (burst) toughness tests on irradiated Zr-2.5Nb pressure tube material was investigated using material from tubes of different toughness values. Comparison between the crack growth resistance (deformation J-R) curves from the small- and large-scale specimens reveals the material dependence of geometry effects and shows that the crack-tip constraint in the compact specimen is generally higher than that in the burst specimen. For higher toughness material, the crack-extension region over which there is good correspondence between the J-R curves from the small- and large-scale specimens is in agreement with current knowledge of validity requirements for J-controlled crack growth of bend-type specimens. Fractographic studies were conducted and the results shown to be consistent with the observed geometry effects, a larger proportion of highly constrained, flat fracture being produced with the small bend-type specimens than with the burst tests. The results are discussed using a volume-controlled fracture model for bend-type specimens in which it is assumed that the toughness is governed by the development of the plastic zone associated with an intermediate-constraint, transition region between the central, flat-fracture zone and surfaceshear or slant-fracture zone. Applying scaling factors from the volume-controlled fracture model, good agreement is obtained between scaled values of the maximum pressure/load toughness from the small- and large-scale tests over a range of normalized plastic zone size of 0.4 to 1.
Link between results of small- and large-scale toughness tests on irradiated zr-2.5nb pressure tube material : phase 2
Author : P. H. Davies
Publisher :
Page : 0 pages
File Size : 42,62 MB
Release : 1996
Category :
ISBN :
Book Description
Size, geometry and material effects in fracture toughness testing of irradiated zr-2.5nb pressure tube material
Author : P. H. Davies
Publisher :
Page : 0 pages
File Size : 39,29 MB
Release : 1998
Category :
ISBN :
Book Description
Fracture toughness of hydrided zr-2.5nb pressure tube material irradiated in the NRU test reactor
Author : P. H. Davies
Publisher :
Page : 0 pages
File Size : 43,65 MB
Release : 1995
Category :
ISBN :
Book Description
A study was completed on hydrided specimens of zr-2.5 nb pressure tube material irradiated in the nru test reactor to fluences up to 5 x 10 sup(24) n.m. sup(-2). material with three different mixed hydride morphologies (m1, m2 and m3 with hydrogen concentrations in the range of 42 to 61 wt ppm, 62 to 75 wt ppm and 183 to 216 wt ppm, respectively, and hydride continuity coefficients (hccs) in the range 0.1 to 0.3) was supplied by ontario hydro technologies for irradiation. the morphologies consisted of mixed hydrides of different orientations (m1/m2) as well as predominantly circumferential hydrides (m3). the joint effect of irradiation and zirconium hydride significantly reduces the toughness of the material at all test temperatures up to the operating temperature range, 240 degrees c, and results in an increased incidence of discontinuous crack growth (crack jumping) and unstable fracture. after irradiation the transition temperature for upper shelf fracture behaviour is above 240 degrees c for all three hydride morphologies. the reduction in the maximum load toughness, k sub(ml), at 240 degrees c is about 30 mpa square root of m due to irradiation and up to a further 18 mpa square root of m (m2) and 22 mpa square root of m (m3) due to the zirconium hydride. fractographic evidence is presented which shows that the increased incidence of discontinuous crack growth and unstable fracture after irradiation is due not only to an increase in the number of hydride sites activated close to the radial-axial plane but also to changes in the ability of the remaining material to arrest the crack. in particular, material containing a high concentration of microsegregated species (zr-cl-c complex) promotes unstable fracture due to the reduced area and width of dimpled rupture zones (between fissures) available for crack arrest.
Stress-Triaxiality in Zr-2.5Nb Pressure Tube Materials
Author : B. W. Leitch
Publisher :
Page : 18 pages
File Size : 26,56 MB
Release : 2009
Category : Burst test
ISBN :
Book Description
The crack growth resistance of irradiated Zr-2.5Nb pressure tubes is controlled by the initiation of voids and their subsequent growth and coalescence. The presence of particles that contribute to void nucleation is determined by the operating conditions/history of the pressure tube and by the concentration of pre-existing species, which is a function of the manufacturing process. The susceptibility of the pressure tubes to void nucleation is determined by the number and distribution of particles, the deformation properties of the matrix, and the stress state at the crack tip. The effect of irradiation on zirconium material is to increase the yield stress but to reduce the work hardening ability of the matrix and to promote strain localization, which, in turn, leads to void nucleation. Void nucleation is also enhanced by high values of stress triaxiality at or near the crack tip. For irradiated pressure tube material, both small-scale curved compact tension specimens and large-scale burst test sections are used to characterize the crack growth resistance. However, the measured fracture toughness can depend on the specimen geometry due to differences in constraint. The present investigation uses three-dimensional finite element analyses to characterize stress triaxiality at the crack tip in these different specimen geometries. Results of the numerical analyses are compared to the experimental evidence that provide qualitative evidence of differences in stress triaxiality at the crack tip for different specimen geometries.
Effect of Long-Term Irradiation on the Fracture Properties of Zr-2.5Nb Pressure Tubes
Author : S. Sagat
Publisher :
Page : 17 pages
File Size : 17,25 MB
Release : 2000
Category : Fracture
ISBN :
Book Description
Results from fracture toughness and tensile and delayed hydride cracking (DHC) tests on Zr-2.5Nb pressure tubes removed from CANDU power reactors in the 1970s and 80s for surveillance showed considerable scatter. At that time, the cause of the scatter was unknown and prediction of fracture toughness to the end of the design life of a CANDU reactor using the surveillance data was difficult. To eliminate the heat-to-heat variability and to determine end-of-life mechanical properties, a program was undertaken to irradiate, in a high-flux reactor, fracture toughness, DHC, and transverse tensile specimens from a single "typical" pressure tube. Two inserts were placed in the OSIRIS reactor at CEA, Saclay, in 1988. Each insert held 16 of each type of specimen. The first insert, ERABLE 1, was designed so that half the specimens could be replaced at intervals and the properties could be measured as a function of fluence. All the specimens would be removed after a total fluence of 15 x 1025 n . m-2, E > 1 MeV. The second insert, ERABLE 2, was designed to run without interruption to a fluence of 30 x 1025 n . m-2, the fluence corresponding to 30 years' operation of a CANDU reactor at 90% capacity factor. The irradiation temperature was chosen to be 250°C, the inlet temperature of early CANDU reactors. The irradiation of ERABLE 1 has been completed and sets of specimens have been removed and tested with maximum fluences of approximately 0.7, 1.7, 2.8, 12, and 17 x 1025 n . m-2, E > 1 MeV. X-ray and TEM examinations have been performed on the material from fractured specimens to characterize the irradiation damage. Results showed that there is, initially, a large change in the mechanical properties before a fluence of 0.6 x 1025 n . m-2, E > 1 MeV (corresponding to an initial rapid increase in a-type dislocation density), followed by a gradual change. As expected, the fracture toughness decreased with fluence, whereas the yield strength, UTS, and DHC crack velocities all increased. Z-ray analysis showed that, although the a-type dislocation density remained constant after the initial increase, the number of c-component dislocations showed a steady increase, agreeing with the behavior seen in the mechanical specimens. Because the flux in OSIRIS is different from that in a CANDU reactor, specimens were also irradiated in NRU, a heavy water moderated test reactor with approximately the same flux as a CANDU reactor, to fluences of 0.3, 0.6, and 1.0 x 1025 n.m-2, E > 1 MeV for comparison. These initial results show that, once past the initial transient, one can have confidence that there will be little further degradation with fluence, with the results from the NRU specimens being similar to those from OSIRIS.
Size, Geometry, and Material Effects in Fracture Toughness Testing of Irradiated Zr-2.5Nb Pressure Tube Material
Author : RSW Shewfelt
Publisher :
Page : 21 pages
File Size : 23,89 MB
Release : 2000
Category : Crack growth resistance (J-R) curve
ISBN :
Book Description
The effect of initial crack size on the crack growth resistance (J-R) curves determined from burst tests on irradiated Zr-2.5Nb pressure tubes has been studied and the results compared with those obtained from matched curved compact specimens. The study used sections from three different tubes representative of material of low, intermediate, and high toughness. In each case a series of burst tests was conducted at 250°C with different starting crack sizes (from 35 to 85 mm) followed by small specimen testing. The toughness was characterized by means of deformation J-R curves using the d-c potential drop method to measure stable crack growth. Fractographic studies were also conducted in support of the J-R curve results.
Crack Growth Resistance of Irradiated Zr-2.5Nb Pressure Tube Material at Low Hydrogen Levels
Author : RSW Shewfelt
Publisher :
Page : 23 pages
File Size : 27,33 MB
Release : 2001
Category : Crack growth resistance (J-R) curve
ISBN :
Book Description
The primary factors influencing the crack growth resistance of irradiated Zr-2.5Nb pressure tube material at low concentrations of hydrogen/deuterium are reviewed. These factors include the initial characteristics of the material, which have brought about improvements in the toughness, and the operating conditions in reactor. The paper presents an update on the current status of this work using J-R curves. Such curves are determined from curved compact and rising-pressure burst test specimens at 250°C, i.e., the lower end of the operating temperature range. Some of the challenges encountered in assessing the crack growth toughness of this high-strength, thin-walled material are discussed. The role of chlorine, known to be responsible for the presence of Zr-Cl-C particles and preferential decohesion and fissuring, is also highlighted. The results from the curved compact specimens suggest a limiting level of chlorine above which no further significant degradation in crack growth resistance occurs. This level of chlorine is about 3 wt ppm for material having a low concentration of zirconium phosphide (P
Radial fracture toughness of irradiated zr-2.5nb pressure tube material
Author : D. D. Himbeault
Publisher :
Page : 0 pages
File Size : 39,69 MB
Release : 1995
Category :
ISBN :
