Assessment of Creep Rupture Strength for New Martensitic 9% Cr Steels

Bendick, W.; Gabrel, J.; Vandenberghe, B.

doi:10.1115/creep2007-26332

Cited by 5 publications

(7 citation statements)

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“…Subsequently, Viswanathan et al [2,3] recommended 9-12%Cr martensitic stain less steel as the casting material for steam turbine cylinders. Hald [4] and Bendick et al [5] experimentally studied 9-12%Cr mar tensitic stainless steel, containing W, and confirmed that this mate rial met the design requirements for these steam turbine cylinders. Ernst [6], adding B and Co elements to 9-12%Cr martensitic stainless steel, found that the creep rupture strength of 9-12%Cr martensitic stainless steel after 1 x 105 h could reach 90-100 MPa under 6200 °C.…”

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confidence: 55%

Analysis of Multi-Axial Creep–Fatigue Damage on an Outer Cylinder of a 1000 MW Supercritical Steam Turbine

Wang

2014

Journal of Engineering for Gas Turbines and Power

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A multi-axial continuum damage mechanics (CDM) model was proposed to calculate the multi-axial creep-fatigue damage o f a high temperature component. A specific outer cyl inder o f a 1000M W supercritical steam turbine was used in this study, and the interac tion o f the creep and fatigue behavior o f the outer cylinder was numerically investigated under a startup-running-shutdown process. To this end, the multi-axial stress-strain behavior o f the outer cylinder was numerically studied using A baqus. The in-site meas ured temperatures were provided to validate the heat transfer coefficients, which were used to calculate the temperature field o f the outer cylinder. The multi-axial mechanics behavior o f the outer cylinder was investigated in detail, with regard to the temperature, Mises stress, hydrostatic stress, multi-axial toughness factor, multi-axial creep strain, and damage. The results demonstrated that multi-axial mechanics behavior reduced the total damage.

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confidence: 55%

Analysis of Multi-Axial Creep–Fatigue Damage on an Outer Cylinder of a 1000 MW Supercritical Steam Turbine

Wang

2014

Journal of Engineering for Gas Turbines and Power

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“…Efforts included testing sponsored by the Metals Properties Council and the U.S. Atomic Energy Commission for all of the materials in the Class 1 components nuclear construction code cases. Further, collection of data from overseas sources was undertaken by Booker and co-workers, among others [11,12]. Booker performed an evaluation of newer data for 304H stainless steel, 316 stainless steel, and alloy 800H [12].…”

Section: Availability Of the Original And Augmented Databases Needed mentioning

confidence: 99%

“…Further, collection of data from overseas sources was undertaken by Booker and co-workers, among others [11,12]. Booker performed an evaluation of newer data for 304H stainless steel, 316 stainless steel, and alloy 800H [12]. He produced a table that summarized the database that produced the ASME III Code Case N-47 stress allowables and compared the database with a new database as shown in Table 6.…”

Section: Availability Of the Original And Augmented Databases Needed mentioning

confidence: 99%

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A Review & Assessment of Current Operating Conditions Allowable Stresses in ASME Section III Subsection NH

Swindeman¹

2009

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The current operating condition allowable stresses provided in ASME Section III, Subsection NH were reviewed for consistency with the criteria used to establish the stress allowables and with the allowable stresses provided in ASME Section II, Part D. It was found that the S o values in ASME III-NH were consistent with the S values in ASME II-D for the five materials of interest. However, it was found that 0.80S r was less than S o for some temperatures for four of the materials. Only values for alloy 800H appeared to be consistent with the criteria on which S o values are established. With the intent of undertaking a more detailed evaluation of issues related to the allowable stresses in ASME III-NH, the availabilities of databases for the five materials were reviewed and augmented databases were assembled.

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“…A series of studies have already been carried out to investigate creep behavior, and oxidation resistant properties of T/P92 steel [3,4,5]. But there has been few information of Proceedings of the ASME Symposium on Elevated Temperature Application of Materials for Fossil, Nuclear, and Petrochemical Industries March 25-27, 2014…”

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confidence: 99%

The Microstructure Stability of the 10Cr9MoW2VNbBN Heat Resistant Steel

Shou

et al. 2014

ASME 2014 Symposium on Elevated Temperature Application of Materials for Fossil, Nuclear, and Petrochemical Industries

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Abstract:In this paper, the microstructure of 9%Cr steel 10Cr9MoW2VNbBN under different heat treatment or creep testing was investigated. The morphology of tempered martensite microstructure varies after different heat treatment. After the creep test at 620°C or 650°C, the martensite lath microstructure kept unchanged, although the amounts and the sizes of precipitates, such as the carbides M23C6, carbonitrides MX, and Laves phase, increased with the creep time. The martensite laths microstructure morphology changed after the creep test at 700°C, with the carbides coarsened severely at grain boundaries.

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Assessment of Creep Rupture Strength for New Martensitic 9% Cr Steels

Cited by 5 publications

References 0 publications

Analysis of Multi-Axial Creep–Fatigue Damage on an Outer Cylinder of a 1000 MW Supercritical Steam Turbine

Analysis of Multi-Axial Creep–Fatigue Damage on an Outer Cylinder of a 1000 MW Supercritical Steam Turbine

A Review & Assessment of Current Operating Conditions Allowable Stresses in ASME Section III Subsection NH

The Microstructure Stability of the 10Cr9MoW2VNbBN Heat Resistant Steel

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