The stress-strain diagram for a steel alloy having an original diameter of 0.5 in. and a gauge length of 2 in. is given in the figure. Deterinine approx- imately: (a) the Modulus of Elasticity for the material (b) the load on the specimen that will canse yielding (c) the ultimate load the specimen will support (d) the Modulus of Resilience (e) the Modulus of Toughness Note that the lower scale supports the lower curve and the upper scale supports the upper curve. The lower curve is the initial portion of the entire stress-strain curve that is picked up by the upper curve. The two eurves together represent one complete stress-strain curve. For part (e) you can approximate the area under the curves by counting boxes. a (ksi) 80 70 60- 50 40 30 - 20 10 E () upper scale lower scale 0.28– 0.0035 0.24- 0.0030 0.20- 0.0025 0.16- 0.0020 0.12-0.0015 0.08-0.0010 0.04- 0.0005

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The stress-strain diagram for a steel alloy having an original diameter of 0.5 in. and a gauge length of 2 in. is given in the figure. Deterinine approx- imately: (a) the Modulus of Elasticity for the material (b) the load on the specimen that will canse yielding (c) the ultimate load the specimen will support (d) the Modulus of Resilience (e) the Modulus of Toughness Note that the lower scale supports the lower curve and the upper scale supports the upper curve. The lower eurve is the initial portion of the entire stress-strain curve that is picked up by the upper curve. The two eurves together represent one complete stress-strain curve. For part (e) you can approximate the area under the curves counting boxes. o (ksi) 80 70 - 60- 50 40 30 - 20 10 0. E () Iower scale F0.28- 0.0035 - 0.24– 0.0030 -0.20- 0.0025 -0.16- 0.0020 - 0.12- 0.0015 -0.08- 0.0010 -0.04-0.0005