Prediction of Fracture Toughness KIC Transition Curves of Pressure Vessel Steels From Charpy V-Notch Impact Test Results

A single and generalized prediction method of fracture toughness KIC transition curves of pressure vessel steels has been greatly desired by engineers in the petro-chemical and nuclear power industries, especially from the viewpoint of life extension of reactor pressure vessels. In this paper, the toughness degradation of Cr-Mo steels during long-term service was examined and the two prediction methods of fracture toughness KIC transition curves were studied using the data of 54 heats. 1) The toughness degradation of 2 1/4Cr-1Mo steels levels off within around 50,000 h service. 2) The FATT versus J-factor (=(Si+Mn)(P+Sn)×104) and/or X (=(10P+5Sb+4Sn+As)x10−2) relationships to estimate the maximum embrittlement of Cr-Mo steels were obtained. 3) A master curve method developed by authors et al.; that is, the method using a KIC/KIC−US versus excess temperature master curve of each material was presented for 2 1/4Cr-1Mo, 1 1/4Cr-1/2Mo, 1Cr and 1/2Mo chemical pressure vessel steels and ASTM A508 C1.1, A508 C1.2, A508 C1.3 and A533 Gr.B C1.1 nuclear pressure vessel steels, where KIC−US is the upper-shelf fracture toughness and excess temperature is test temperature minus FATT. 4) A generalized prediction method to predict the KIC transition curves of any low-alloy steels was developed. This method consists of KIC/KIC−US versus T–T0 master curve and temperature shift ΔT between fracture toughness and CVN impact transition curves versus yield strength relationship, where To is the temperature showing 50 percent KIC−US of the material. 5) The KIC transition curves predicted using both methods showed a good agreement with the lower bound of measured KJC values obtained from JC tests.

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Fracture Toughness of Highly Irradiated Pressure Vessel Steels in the Upper Shelf Temperature

Volume 1: Codes and Standards ◽

10.1115/pvp2006-icpvt-11-93032 ◽

2006 ◽

Author(s):

Hiroshi Matsuzawa ◽

Toru Osaki

Keyword(s):

Fracture Toughness ◽

Chemical Composition ◽

Reference Material ◽

Fast Neutron ◽

Pressure Vessel ◽

Charpy Impact ◽

Pressure Vessels ◽

Shelf Energy ◽

Pressure Vessel Steels ◽

Reactor Pressure

Nine Reactor Pressure Vessel (RPV) Steels and four RPV weld were irradiated up to 1.2 × 1024n/m2 fast neutron fluence (E>1MeV), and their fracture toughness and Charpy impact energy were measured. As chemical compositions, such as Cu, are known to affect the fracture toughness reduction due to neutron exposure, the above steels were fabricated by changing chemical composition widely to cover the chemical composition of the RPV materials of the operating Japanese nuclear power plants. 2.7 mm thick compact specimens were used to measure the upper shelf fracture toughness of highly irradiated materials, and their Charpy upper shelf energy was also measured. By correlating Charpy upper shelf energy to fracture toughness, the upper shelf fracture toughness evaluation formulae for highly irradiated reactor pressure vessel steels were developed. Both compact and V-notched Charpy impact specimens were irradiated in a test reactor. The fast neutron flux above 1MeV was about 5 × 1016n/(m2s). Charpy impact specimens made of Japanese PWR reference material containing 0.09w% Cu were irradiated simultaneously. The upper shelf energy of the reference material up to the medium fluence level showed little difference in the reduction of upper shelf energy to that which had been in the operating plant and which was irradiated to the same fluence. The developed correlation formulae have been adopted in the Japan Electric Association Code as new formulae to predict the fracture toughness in the upper shelf region of reactor pressure vessels. They will be applied to time limited ageing analysis of low upper shelf reactor pressure vessels in Japan, on a concrete technical basis in very high fluence regions.

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Estimation of Master Curve Based RTTo Reference Temperature From CVN Data

Volume 6: Materials and Fabrication ◽

10.1115/pvp2005-71135 ◽

2005 ◽

Author(s):

Kim R. W. Wallin ◽

Gerhard Nagel ◽

Elisabeth Keim ◽

Dieter Siegele

Keyword(s):

Fracture Toughness ◽

Pressure Vessel ◽

Brittle Failure ◽

Master Curve ◽

Simple Relation ◽

Systematic Evaluation ◽

Data Sets ◽

Irradiation Embrittlement ◽

Pressure Vessel Steels ◽

Asme Code

The ASME code cases N-629 and N-631 permits the use of a Master Curve-based index temperature (RTTo ≡ T0 + 19.4°C) as an alternative to traditional RTNDT-based methods of positioning the ASME KIc, and KIR curves. This approach was adopted to enable use of Master Curve technology without requiring the wholesale changes to the structure of the ASME Code that would be needed to use all aspects of Master Curve technology. For the brittle failure analysis considering irradiation embrittlement additionally a procedure to predict the adjustment of fracture toughness for EOL from irradiation surveillance results must be available as by NRC R.G. 1.99 Rev. 2 e.g.: ART = Initial RTNDT + ΔRTNDT + Margin. The conservatism of this procedure when RTNDT is replaced by RTTo is investigated for western nuclear grade pressure vessel steels and their welds. Based on a systematic evaluation of nearly 100 different irradiated material data sets, a simple relation between RTToirr, RTToref and ΔT41JRG is proposed. The relation makes use of the R.G. 1.99 Rev. 2 and enables the minimizing of margins, necessary for conventional correlations based on temperature shifts. As an example, the method is used to assess the RTTo as a function of fluence for several German pressure vessel steels and corresponding welds. It is shown that the method is robust and well suited for codification.

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Master Curve Approach for Some Japanese Reactor Pressure Vessel Steels

Volume 6: Materials and Fabrication, Parts A and B ◽

10.1115/pvp2008-61494 ◽

2008 ◽

Cited By ~ 2

Author(s):

Minoru Tomimatsu ◽

Takashi Hirano ◽

Seiji Asada ◽

Ryoichi Saeki ◽

Naoki Miura ◽

...

Keyword(s):

Fracture Toughness ◽

Power Plant ◽

Pressure Vessel ◽

Nuclear Power ◽

Master Curve ◽

Reactor Pressure Vessel ◽

Pressure Vessel Steels ◽

The World ◽

Reactor Pressure ◽

Plant Components

The Master Curve Approach for assessing fracture toughness of reactor pressure vessel (RPV) steels has been accepted throughout the world. The Master Curve Approach using fracture toughness data obtained from RPV steels in Japan has been investigated in order to incorporate this approach into the Japanese Electric Association (JEA) Code 4206, “Method of Verification Tests of the Fracture Toughness for Nuclear Power Plant Components”. This paper presents the applicability of the Master Curve Approach for Japanese RPV steels.

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Weibull statistical models of KIc/KIa fracture toughness databases for pressure vessel steels with an application to pressurized thermal shock assessments of nuclear reactor pressure vessels

International Journal of Pressure Vessels and Piping ◽

10.1016/s0308-0161(01)00031-x ◽

2001 ◽

Vol 78 (2-3) ◽

pp. 165-178 ◽

Cited By ~ 9

Author(s):

P.T. Williams ◽

K.O. Bowman ◽

B.R. Bass ◽

T.L. Dickson

Keyword(s):

Fracture Toughness ◽

Thermal Shock ◽

Pressure Vessel ◽

Statistical Models ◽

Nuclear Reactor ◽

Pressure Vessels ◽

Pressurized Thermal Shock ◽

Pressure Vessel Steels ◽

Reactor Pressure

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Brittle Fracture Prevention Model for Pressure Based on Master Curve Approach

Journal of Pressure Vessel Technology ◽

10.1115/1.4033599 ◽

2016 ◽

Vol 139 (1) ◽

Cited By ~ 1

Author(s):

QingFeng Cui ◽

Hu Hui ◽

PeiNing Li ◽

Feng Wang

Keyword(s):

Fracture Toughness ◽

Brittle Fracture ◽

Impact Toughness ◽

Pressure Vessel ◽

Master Curve ◽

Fracture Prevention ◽

Pressure Vessels ◽

New Model ◽

Prevention Model ◽

The Impact

The brittle fracture prevention model is of great importance to the safety of pressure vessels. Compared to the semi-empirical approach adopted in various pressure vessel standards, a model based on Master Curve technique is developed in this paper. Referring to ASME nuclear code, the safety features including the lower bound fracture toughness and a margin factor equal to 2 for the stress intensity factor produced by primary stress are adopted in the new model. The technical background of the brittle fracture model in ASME VIII-2 has been analyzed and discussed, and then its inappropriate items have been modified in the new model. Minimum design temperature curves, impact toughness requirements, and temperature adjustment for low stress condition are established on the basis of new model. The comparison with the relevant curves in ASME VIII-2 is also made. The applicability of the new model is verified by the measured fracture toughness and impact toughness data of several kinds of pressure vessel steels. The results suggest that the minimum design temperature and the impact test requirements derived by the new model are compatible with each other. More testing data of different steels to check this model is necessary for further engineering application.

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