Use of the Wilshire Equations to Correlate and Extrapolate Creep Data of Inconel 617 and Nimonic 105

Advanced power plant alloys must endure high temperatures and pressures for durations at which creep data are often not available, necessitating the extrapolation of creep life. A recently developed creep life extrapolation method is the Wilshire equations, with which multiple approaches can be used to increase the goodness of fit of available experimental data and improve the confidence level of calculating long-term creep strength at times well beyond the available experimental data. In this article, the Wilshire equation is used to extrapolate the creep life of Inconel 617 and Nimonic 105 to 100,000 h. The use of (a) different methods to determine creep activation energy, (b) region splitting, (c) heat- and processing-specific tensile strength data, and (d) short-duration test data were investigated to determine their effects on correlation and extrapolation. For Inconel 617, using the activation energy of lattice self-diffusion as Q C * resulted in a poor fit with the experimental data. Additionally, the error of calculated rupture times worsened when splitting regions. For Nimonic 105, the error was reduced when heat- and processing-specific tensile strengths were used. Extrapolating Inconel 617 creep strength to 100,000 h life gave conservative results when compared to values calculated by the European Creep Collaborative Committee.

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Use of the Wilshire Equations to Correlate and Extrapolate Creep Data of HR6W and Sanicro 25

Materials ◽

10.3390/ma11091585 ◽

2018 ◽

Vol 11 (9) ◽

pp. 1585 ◽

Cited By ~ 3

Author(s):

Vito Cedro ◽

Christian Garcia ◽

Mark Render

Keyword(s):

Experimental Data ◽

Activation Energy ◽

Goodness Of Fit ◽

Creep Data ◽

Creep Life ◽

Short Term ◽

Data Set ◽

Creep Activation Energy ◽

Region Splitting ◽

Term Data

Advanced power plant alloys must endure high temperatures and pressures for durations at which creep data are often not available, necessitating the extrapolation of creep life. Many methods have been proposed to extrapolate creep life, and one of recent significance is a set of equations known as the Wilshire equations. With this method, multiple approaches can be used to determine creep activation energy, increase the goodness of fit of available experimental data, and improve the confidence level of calculating long-term creep strength at times well beyond the available experimental data. In this article, the Wilshire equation is used to extrapolate the creep life of HR6W and Sanicro 25, and different methods to determine creep activation energy, region splitting, the use of short-duration test data, and the omission of very-short-term data are investigated to determine their effect on correlation and calculations. It was found that using a known value of the activation energy of lattice self-diffusion, rather than calculating Q C * from each data set, is both the simplest and most viable method to determine Q C * . Region-splitting improved rupture time calculations for both alloys. Extrapolating creep life from short-term data for these alloys was found to be reasonable.

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Microstructures of Grade 91 Steels Under Long-Term Creep Conditions

ASME 2018 Symposium on Elevated Temperature Application of Materials for Fossil, Nuclear, and Petrochemical Industries ◽

10.1115/etam2018-6712 ◽

2018 ◽

Author(s):

Kenji Kako ◽

Susumu Yamada ◽

Masatsugu Yaguchi ◽

Yusuke Minami

Keyword(s):

Remaining Life ◽

Martensitic Steels ◽

Creep Data ◽

Creep Life ◽

Creep Tests ◽

Microstructural Observation ◽

Type Iv ◽

Grade 91 ◽

Term Creep

Type IV damage has been found at several ultra-supercritical (USC) plants that used high-chromium martensitic steels in Japan, and the assessment of the remaining life of the steels is important for electric power companies. The assessment of the remaining life needs long-term creep data for over 10 years, but such data are limited. We have attempted to assess the remaining life by creep tests and by microstructural observation of Grade 91 steels welded pipes which were used in USC plants for over 10 years. Following the results of microstructural observation of USC plant pipes, we find that microstructures, especially distribution of MX precipitates, have large effect on the creep life of Grade 91 steels.

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Short-Term Creep Data Based Long-Term Creep Life Predictability for Grade 92 Steels and Its Microstructural Basis

Metals and Materials International ◽

10.1007/s12540-018-00214-x ◽

2018 ◽

Vol 25 (3) ◽

pp. 713-722 ◽

Cited By ~ 1

Author(s):

Seen Chan Kim ◽

Jae-Hyeok Shim ◽

Woo-Sang Jung ◽

Yoon Suk Choi

Keyword(s):

Creep Data ◽

Creep Life ◽

Short Term ◽

Term Creep ◽

Short Term Creep

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Creep Properties of Hastelloy-X Alloy for the High Temperature Gas-Cooled Reactor

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.326-328.1105 ◽

2006 ◽

Vol 326-328 ◽

pp. 1105-1108 ◽

Cited By ~ 5

Author(s):

Woo Gon Kim ◽

Sang Nan Yin ◽

Woo Seog Ryu ◽

Jong Hwa Chang

Keyword(s):

High Temperature ◽

Creep Data ◽

Creep Life ◽

Statistical Process ◽

Hastelloy X ◽

Creep Properties ◽

Rupture Data ◽

Term Creep ◽

High Temperature Gas

The creep properties for the Hastelloy-X alloy which is one of candidate alloys for a high temperature gas-cooled reactor are presented. The creep data was obtained with different stresses at 950oC, and a number of the creep data was collected through literature surveys. All of the creep data were combined together to obtain the creep constants and to predict a long-term creep life. In the Norton’s creep law and the Monkman-Grant relationship, the creep constants, A, n, m, and m’ were obtained. Creep master curves based on the Larson-Miller parameter were presented for the standard deviations of 1σ, 2σ and 3σ. Creep life at each temperature was predicted for a longer-time rupture above 105 hours. Failure probability was also estimated by a statistical process of all the creep rupture data.

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Prediction of Long Term Stress Rupture Data for 2124

Materials Science Forum ◽

10.4028/www.scientific.net/msf.519-521.1041 ◽

2006 ◽

Vol 519-521 ◽

pp. 1041-1046 ◽

Cited By ~ 6

Author(s):

Brian Wilshire ◽

H. Burt ◽

N.P. Lavery

Keyword(s):

Q Methodology ◽

Fracture Behavior ◽

Stress Rupture ◽

Creep Data ◽

Short Term ◽

Rupture Data ◽

Term Creep ◽

Term Data ◽

Short Term Creep

The standard power law approaches widely used to describe creep and creep fracture behavior have not led to theories capable of predicting long-term data. Similarly, traditional parametric methods for property rationalization also have limited predictive capabilities. In contrast, quantifying the shapes of short-term creep curves using the q methodology introduces several physically-meaningful procedures for creep data rationalization and prediction, which allow straightforward estimation of the 100,000 hour stress rupture values for the aluminum alloy, 2124.

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EXTRAPOLATION OF SHORT TERM CREEP DATA INTO LONG TERM RUPTURE TIME PREDICTIONS VIA CAVITY NUCLEATION MEASUREMENTS

Materials at High Temperatures ◽

10.1080/09603409.2021.1979744 ◽

2021 ◽

pp. 1-7

Author(s):

Kostas Davanas

Keyword(s):

Rupture Time ◽

Creep Data ◽

Short Term ◽

Cavity Nucleation ◽

Term Creep ◽

Short Term Creep

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Modified Dyson Continuum Damage Model for Austenitic Steel Alloy

Journal of Pressure Vessel Technology ◽

10.1115/1.4039883 ◽

2018 ◽

Vol 140 (4) ◽

Author(s):

Seok Jun Kang ◽

Hoomin Lee ◽

Jae Boong Choi ◽

Moon Ki Kim

Keyword(s):

Damage Model ◽

Life Time ◽

Continuum Damage ◽

Creep Life ◽

Creep Tests ◽

Continuum Damage Model ◽

Thermal Plant ◽

Uniaxial Creep ◽

Term Creep

Ultrasuper critical (USC) thermal plants are now in operation around the globe. Their applications include superheaters and reheaters, which generally require high temperature/pressure conditions. To withstand these harsh conditions, an austenitic heat-resistant HR3C (ASME TP310NbN) steel was developed for metal creep resistance. As the designed life time of a typical thermal plant is 150,000 h, it is very important to predict long-term creep behavior. In this study, a three-state variable continuum damage model (CDM) was modified for better estimation of long-term creep life. Accelerated uniaxial creep tests were performed to determine the material parameters. Also, the rupture type and microstructural precipitation were observed by scanning electron microscopy. The creep life of HR3C steel was predicted using only relatively short-term creep test data and was then successfully verified by comparison with the long-term creep data.

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