The fracture toughness master curve shows the relationship between the median of fracture toughness and temperature in the ductile–brittle transition temperature region of ferritic steels such as reactor pressure vessel (RPV) steels. The master curve approach specified in the ASTM standard theoretically provides the confidence levels of fracture toughness in consideration with the inherent scatter of fracture toughness. The authors have conducted several fracture toughness tests for typical Japanese RPV steels with various specimen sizes and shapes and ascertained that the master curve can be accurately applied to the specimens with a thickness of 0.4-in. or larger. With respect to using the master curve method with the current surveillance program for operating RPVs, the utilization of miniature specimens is important. Miniature specimens, which can be taken from the broken halves of surveillance specimens, are necessary for the efficient determination of the master curve from the limited volume of the available materials. In this study, fracture toughness tests were conducted for typical Japanese RPV steels, particularly SFVQ1A forged and SQV2A plate materials, using the miniature C(T) specimens with a thickness of 4 mm, following the procedure in the ASTM standard. The results show that the differences in the test temperature, evaluation method, and specimen size did not affect the master curves, and the fracture toughness indexed by the reference temperature, To, obtained from miniature C(T) specimens were consistent with those obtained from the standard and larger C(T) specimens. It was also found that valid reference temperatures can be determined with a realistic number of miniature C(T) specimens, i.e., less than ten, if the test temperature was appropriately selected. Thus, the master curve method using miniature C(T) specimens could be a practical method to determine the fracture toughness of actual RPV steels.

Issue Section:
Materials and Fabrication
Keywords:
ductile-brittle transition, forging, fracture toughness, fracture toughness testing, pressure vessels, steel
Topics:
Fracture toughness, Temperature, ASTM International, Steel

References

1.
The Japan Electric Association, 2007, “
Method of Verification Tests of the Fracture Toughness for Nuclear Power Plant Components
,” JEAC
4206
2007.
2.
American Society of Mechanical Engineers, 2007, “Boiler and Pressure Vessel Code Section III, Rules for Construction of Nuclear Facility Components.”
3.
American Society of Mechanical Engineers, 2007, “Boiler and Pressure Vessel Code Section XI, Rules for Inservice Inspection of Nuclear Power Plant Components.”
4.
Wallin
,
K.
, 1984, “
The Scatter in KIC Results
,”
Eng. Fract. Mech.
,
19
, pp.
1085
1093
.
Crossref
Search ADS
 
5.
Wallin
,
K.
,
Saario
,
T.
, and
Torronen
,
K.
, 1984, “
Statistical Model for Carbide Induced Brittle Fracture in Steel
,”
Met. Sci.
,
18
, pp.
13
16
.
Crossref
Search ADS
 
6.
American Standard for Testing and Materials, 2002,
“Standard Test Method for Determination of Reference Temperature, To, for Ferritic Steels in the Transition Range,”
ASTM E1921–02.
7.
Miura
,
N.
,
Soneda
,
N.
, and
Hiranuma
,
N.
, 2003,
“Application of Master Curve Method to Japanese Reactor Pressure Vessel Steels—Effect of Specimen Size on Master Curve,”
Proceedings of the 30th MPA Seminar in Conjunction With the 9th German-Japanese Seminar
, pp.
1.1
1.11
.
8.
Miura
,
N.
,
Soneda
,
N
,
Arai
,
T.
, and
Dohi
,
K.
, 2006,
“Applicability of Master Curve Method to Japanese Reactor Pressure Vessel Steels,”
ASME PVP2006-ICPVT11-93792.
9.
International Atomic Energy Agency, 2005,
“Application of Surveillance Programme Results to Reactor Pressure Vessel Integrity Assessment,”
IAEA-TECDOC-1435.
10.
Scibetta
,
M.
,
Lucon
,
E.
, and
van Walle
,
E.
, 2002,
“Optimal Use of Broken Charpy Specimens From Surveillance Programs for the Application of the Master Curve Approach,”
Int. J. Fract.
,
116
, pp.
231
244
.
Crossref
Search ADS
 
11.
Scibetta
,
M.
,
Lucon
,
E.
,
Chaouadi
,
R.
,
van Walle
,
E.
, and
Gérard
,
R.
, 2006,
“Use of Broken Charpy V-Notch Specimens From a Surveillance Program for Fracture Toughness Determination,”
J. ASTM Int.
,
3
(
2
), pp.
1
7
.
12.
Miura
,
N.
,
Soneda
,
N.
,
Sawai
,
S.
, and
Sakai
,
S.
, 2009,
“Proposal of Rational Determination of Fracture Toughness Lower-Bound Curves by Master Curve Approach,”
ASME PVP2009-77360.
13.
Miura
,
N.
, and
Soneda
,
N.
, 2009,
“Evaluation of Fracture Toughness by Master Curve Approach Using Miniature Specimens,”
CRIEPI Report No. Q08025 (in Japanese).
14.
American Standard for Testing and Materials, 2008, “Standard Test Method for Measurement of Fracture Toughness,” ASTM E1820-08.
15.
Nanstad
,
R. K.
,
McCabe
,
D. E.
,
Sokolov
,
M. A.
, and
Merkle
,
J. G.
, 2007,
“Experimental Evaluation of Deformation and Constraint Characteristics in Precracked Charpy and Other Three-Point Bend Specimens,”
ASME PVP2007-26651.
16.
American Society of Mechanical Engineers, 1999, “Use of Fracture Toughness Test Data to Establish Reference Temperature for Pressure Retaining Materials Section IX, Division 1,” ASME Code Case N-629.
17.
American Society of Mechanical Engineers, 1999, “Use of Fracture Toughness Test Data to Establish Reference Temperature for Pressure Retaining Materials Other Than Bolting for Class 1 Vessels Section III, Division 1,” ASME Code Case N-631.
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