A standard 0.505-in.-diameter tensile bar was machined to a 2.00-in.-gage length from copper-nickel alloy and the following data were collected: Load (Ibs) Gage Length (in.) 2.00000 1,000 2.00045 2,000 2.00091 3,000 2.00136 4,000 2.0020 6,000 2.020 8,000 2.052 10,000 2.112 11,000 2.280 (maximum load) 9,000 2.750 (fracture) After fracture, the gage length was 2.75 in. and the diameter was 0.365 in. Plot the engineering stress strain curve and calculate (a) the 0.2% offset yield strength; (b) the tensile strength; (c) the modulus of elasticity;

Elements Of Electromagnetics
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A standard 0.505-in.-diameter tensile bar was machined to a 2.00-in.-gage length from
copper-nickel alloy and the following data were collected:
Load (Ibs)
Gage Length (in.)
2.00000
1,000
2.00045
2,000
2.00091
3,000
2.00136
4,000
2.0020
6,000
2.020
8,000
2.052
10,000
2.112
11,000
2.280 (maximum load)
9,000
2.750 (fracture)
After fracture, the gage length was 2.75 in. and the diameter was 0.365 in. Plot the
engineering stress strain curve and calculate
(a) the 0.2% offset yield strength;
(b) the tensile strength;
(c) the modulus of elasticity;
(d) the % elongation;
(e) the % reduction in area;
(f) the engineering stress at fracture;
(g) the true stress at necking; and
(h) the modulus of resilience.
Transcribed Image Text:A standard 0.505-in.-diameter tensile bar was machined to a 2.00-in.-gage length from copper-nickel alloy and the following data were collected: Load (Ibs) Gage Length (in.) 2.00000 1,000 2.00045 2,000 2.00091 3,000 2.00136 4,000 2.0020 6,000 2.020 8,000 2.052 10,000 2.112 11,000 2.280 (maximum load) 9,000 2.750 (fracture) After fracture, the gage length was 2.75 in. and the diameter was 0.365 in. Plot the engineering stress strain curve and calculate (a) the 0.2% offset yield strength; (b) the tensile strength; (c) the modulus of elasticity; (d) the % elongation; (e) the % reduction in area; (f) the engineering stress at fracture; (g) the true stress at necking; and (h) the modulus of resilience.
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