1-20 of 845

Search Results for rupture strength

Follow your search
Access your saved searches in your account

Would you like to receive an alert when new items match your search?
Close Modal
Sort by
Image
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 More
Image
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 More
Image
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 More
Image
Published: 01 January 1990
Fig. 28 Stress-rupture strength of type 347H stainless steel treated at different solution-annealing temperatures More
Image
Published: 01 January 1990
Fig. 9 1000-h creep rupture strength of turbine rotor and compressor blade alloys. Source: Ref 14 More
Image
Published: 01 January 1990
Fig. 4 The relationship between γ′ volume percent and stress-rupture strength for nickel-base superalloys. Source: Ref 6 More
Image
Published: 01 January 1990
Fig. 5 Larson-Miller stress-rupture strength of DS CM 247 LC versus DS and equiaxed MAR-M 247. MFB, machined from blade; GFQ, gas fan quenched; AC, air cooled More
Image
Published: 01 January 1990
Fig. 9 Larson-Miller stress-rupture strength of CMSX-2/CMSX-3 versus DS MAR-M 247, using 1.8 mm (0.070 in.) specimens machined from blades More
Image
Published: 01 January 1990
Fig. 10 Larson-Miller specific stress-rupture strength of CMSX-6 versus CMSX-2/3. MFB, machined from blade; GFQ, gas fan quenched; AC, air cooled More
Image
Published: 01 January 1990
Fig. 13 Larson-Miller stress-rupture strength of CMSX-4 versus CMSX-2/3 More
Image
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 More
Image
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 More
Image
Published: 01 January 1990
Fig. 82 Rupture strength of molybdenum More
Image
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 More
Image
Published: 30 September 2015
Fig. 1 Increase in transverse rupture strength of sintered steel due to infiltration as a function of amount of graphite added More
Image
Published: 30 September 2015
Fig. 4 Effect of combined carbon content on the transverse rupture strength of sintered steel. Test bars were pressed to density of 6.3 g/cm 3 , then sintered for 30 min at 1120 °C (2050 °F) in dissociated ammonia. Source: Ref 4 More
Image
Published: 30 September 2015
Fig. 5 Effect of sintering temperature on transverse rupture strength of iron plus 1.25% graphite test bars. Compacted to a density of 6.1 g/cm 3 and sintered for 30 min at temperature. Source: Ref 4 More
Image
Published: 30 September 2015
Fig. 10 Transverse rupture strength of iron, copper, and graphite powder compacts. Sintered to a density of 6.8 g/cm 3 in endothermic gas. Lines represent compositions having the same transverse rupture strength, given in MPa with ksi equivalent values in parentheses; combined carbon More
Image
Published: 30 September 2015
Fig. 9 Transverse rupture strength of F-0008 atomized plus free-machining steels More
Image
Published: 30 September 2015
Fig. 12 Transverse rupture strength of FC-0208 atomized plus free-machining agents More