Fig. 30 Effect of strain rate on the ratio of dynamic yield-stress and static yield-stress level of A36 structural steel. Source: Ref 12 More

Fig. 45 Temperature dependence of the tensile yield stress of iron. (a) Stress at 0.1% strain. (b) Stress at 0.5% strain. The solid and open circles represent samples zone refined to residual resistivity ratio values of 3600 and >5000, respectively. Data from three other investigations More

Fig. 2 Relationship between yield stress and stress intensity for either unstable fast fracture ( K Ic ) or stress-corrosion cracking ( K Iscc ) of Ti-6Al-4V in salt water. Source: A.W. Thompson and I.M. Bernstein, The Role of Metallurgical Variables in Hydrogen-Assisted Environmental More

Fig. 31 Values of 0.2% yield stress of aluminum alloys after exposure for 1000 h at temperatures between 0 and 350 °C More

Fig. 4 Average yield stress versus aging time for aluminum-lithium alloy 2090 (2.4% Li, 2.4% Cu, 0.18% Zr, balance aluminum) with various amounts of prior deformation More

Fig. 16 General combinations of yield stress and impact transition temperatures available in controlled-rolled steels of various (a) compositions and (b) section sizes. Source: Ref 24 More

Fig. 4 0.2% yield stress and ultimate tensile strength of 9Cr-1MoVNb steel as a function of test temperature for irradiated specimens (12 dpa), as-heat-treated controls, and thermally aged controls. The test temperature equals the irradiation and aging temperatures; specimens were aged 5000 h More

Fig. 20 K Iscc limits for support bolting as a function of yield stress. Source: Ref 103 More

Fig. 4 Yield stress of GR A356 and MHD A356 alloys as a function of temperature. Source: Ref 4 More

Fig. 5 Yield stress of GR 357 and MHD 357 alloys as a function of temperature. Source: Ref 4 More

Fig. 24 Measured and calculated variations of the normalized yield stress and r -value as a function of the angle between rolling and tensile direction for aluminum alloy 2090-T3. Source: Ref 195 More

Fig. 1 General combinations of yield stress and impact transition temperatures available in controlled-rolled steels of various (a) compositions and (b) section sizes More

Fig. 21 Effect of material yield stress on crack growth retardation by overload cycles in HP-9Ni-4Co-30C (0.34C-7.5Ni-1.1Cr-1.1Mo-4.5Co). t = 9 mm. Heat treated to three different stress levels (675, 1235, and 1400 MPa). Source: Ref 46 More

Fig. 10 The 0.2% yield stress at 1000 °C (1830 °F) for single-crystal MAR-M 247 alloys More

Fig. 18 Predicted yield stress of modeled elastic-plastic material as a function of temperature. More

Fig. 16 Predicted change in overall room-temperature yield stress, σ y , and individual strength components solid-solution hardening, σ ss , and precipitation hardening, σ p , with time for the industrial case study presented in Fig. 15 . The ordinate to the right in the diagram indicates More

Fig. 5 Comparison of the effect of temperature on yield stress for selected engineering materials More

Fig. 1 Effects of environment on the yield stress and strain-hardening rate on various iron-aluminum alloys tested in air and mercury-indium solutions More

Fig. 15 Relationship between Vickers hardness of steels and (a) yield stress and (b) tensile strength. Source: Ref 13 More

Fig. 8 Hardness versus yield stress at 8% strain for metals under (a) static loading and (b) dynamic loading. The numbers next to the data points refer to metals and alloys listed in Fig. 6 . More