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rupture strength
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in Elevated-Temperature Properties of Ferritic Steels
> Properties and Selection: Irons, Steels, and High-Performance Alloys
Published: 01 January 1990
Fig. 4 Creep strength (0.01% 1000 h) and rupture strength (100,000 h) of 1Cr-0.5Mo and 1.25Cr-0.5Mo steel. Source: Ref 1
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Published: 01 June 2016
Fig. 3 Rupture strength in 100 h for selected polycrystalline cast nickel-base superalloys versus temperature
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Published: 01 June 2016
Fig. 8 Effect of aluminum + titanium content on the stress-rupture strength of wrought and cast nickel-base superalloys
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Published: 01 January 2005
Fig. 11 100 h stress rupture strength as a function of near-net-shape die temperature for selected nickel-base alloys
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Published: 01 January 1989
Fig. 25 Comparison of the transverse rupture strength of uncoated and coated carbide tools. Measured by a three-point bend test on 5 × 5 × 19 mm (0.2 × 0.2 × 0.75 in.) specimens of 73WC-19(Ti,Ta,Nb)C-8Co
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Published: 01 January 2005
Fig. 4 Effect of cobalt content and grain size on the transverse rupture strength of WC-Co cemented carbides
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in Dispersion-Strengthened Nickel-Base and Iron-Base Alloys
> Properties and Selection: Nonferrous Alloys and Special-Purpose Materials
Published: 01 January 1990
Fig. 8 Effect of temperature on the 1000-h specific rupture strength of MA 760, MA 6000, DS MAR-M 200, and TD nickel
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Published: 01 January 1990
Fig. 25 Comparison of the transverse rupture strength of uncoated and coated carbide tools. Measured by a three-point bend test on 5 × 5 × 19 mm (0.2 × 0.2 × 0.75 in.) specimens of 73WC-19(Ti,Ta,Nb) C-8Co
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Published: 01 January 1990
Fig. 27 Effect of binder metal composition on the transverse rupture strength of a titanium carbonitride cermet. Source: Ref 64
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in Properties of Pure Metals
> Properties and Selection: Nonferrous Alloys and Special-Purpose Materials
Published: 01 January 1990
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in Properties of Pure Metals
> Properties and Selection: Nonferrous Alloys and Special-Purpose Materials
Published: 01 January 1990
Fig. 122 Temperature dependence of the 1-h rupture strength of tungsten. Sources: Ref 502 , 520 , 521 , 522 , 523 , 524 , 525
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in Elevated-Temperature Properties of Ferritic Steels
> Properties and Selection: Irons, Steels, and High-Performance Alloys
Published: 01 January 1990
Fig. 5 Variation of 10 5 -h creep-rupture strength as a function of temperature for 2 1 4 Cr-1Mo steel, standard 9Cr-1Mo, modified 9Cr-1Mo, and 304 stainless steel. Source: Ref 7
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in Elevated-Temperature Properties of Ferritic Steels
> Properties and Selection: Irons, Steels, and High-Performance Alloys
Published: 01 January 1990
Fig. 39 Variation in stress-rupture strength of 2 1 4 Cr-1Mo steel under different heat treatments. QT, quenched and tempered; NT, normalized and tempered; A, annealed; UTS, ultimate tensile strength. Source: Ref 63
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in Elevated-Temperature Properties of Ferritic Steels
> Properties and Selection: Irons, Steels, and High-Performance Alloys
Published: 01 January 1990
Fig. 40 Influence of heat treatment on 10 5 −h creep-rupture strength of 2 1 4 Cr-1Mo steel. Source: Ref 66
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in Elevated-Temperature Properties of Ferritic Steels
> Properties and Selection: Irons, Steels, and High-Performance Alloys
Published: 01 January 1990
Fig. 44 Effect of spheroidization on the rupture strength of carbon-molybdenum steel (0.17C-0.88Mn-0.20Si-0.42Mo). Source: Ref 73
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in Ferrous Powder Metallurgy Materials
> Properties and Selection: Irons, Steels, and High-Performance Alloys
Published: 01 January 1990
Fig. 11 Effect of infiltration on transverse rupture strength of iron-carbon alloys sintered to a density of 6.4 Mg/m 3 . Combined carbon in the alloys was about 80% of the amount of graphite added to the iron powder. The amount of copper infiltrant was adjusted to fill various fractions
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in Elevated-Temperature Properties of Stainless Steels
> Properties and Selection: Irons, Steels, and High-Performance Alloys
Published: 01 January 1990
Fig. 16 100,000-h creep-rupture strength of various steels used in boiler tubes. TB12 steel has as much as five times the 100,000-h creep-rupture strength of conventional ferritic steels at 600 °C (1110 °F). This allows an increase in boiler tube operating temperature of 120 to 130 °C (215
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