A tensile test is done on a tensile specimen with a gauge diameter of 8 mm...

Problem. A cylindrical specimen of a hypothetical metal having a diameter of 7.671 mm and a...

Problem. A cylindrical specimen of a hypothetical metal having a diameter of 7.671 mm and a gauge length of 251.905 mm is pulled in tension. Use the load–elongation characteristics shown in the following table to complete parts (a) through (f). (a) Plot the data as stress (MPa) versus strain (b) Compute the modulus of elasticity in GPa (c) Determine the yield strength at a strain offset of 0.002 (d) Determine the tensile strength of this alloy (e) What is the...

A cylindrical specimen of a metal alloy 45.3 mm long and 9.72 mm in diameter is...

A cylindrical specimen of a metal alloy 45.3 mm long and 9.72 mm in diameter is stressed in tension. A true stress of 372 MPa causes the specimen to plastically elongate to a length of 54.2 mm. If it is known that the strain-hardening exponent for this alloy is 0.2, calculate the true stress (in MPa) necessary to plastically elongate a specimen of this same material from a length of 45.3 mm to a length of 57.6 mm.

A cylindrical specimen of a brass alloy 10.2 mm (0.4016 in.) in diameter and 120.1 mm...

A cylindrical specimen of a brass alloy 10.2 mm (0.4016 in.) in diameter and 120.1 mm (4.728 in.) long is pulled in tension with a force of 12300 N (2765 lbf); the force is subsequently released. The tensile stress-strain behavior for this alloy is shown in the Animated Figure 6.12. Compute the final length of the specimen at this time.

A normal mild steel specimen having 50 mm 2 cross section area and 10 cm long...

A normal mild steel specimen having 50 mm 2 cross section area and 10 cm long gauge length was tested. 1. Draw the stress- strain diagram 2. calculate the final length of the bar compare when the specimen unloaded from 400 MPa? 3. calculate the elastic and plastic deformation when the specimen unloaded from 400 MPa Proportionality limit Ultimate Load Failure Load Stress (MPa) 320////// 500 /////////400 Strain 0.0018 //// 0.06///////// 0.12

A cylindrical specimen of stainless steel having diameter of 12.8 mm and a guage length of...

A cylindrical specimen of stainless steel having diameter of 12.8 mm and a guage length of 50.88 mm(2.000in.) is pulled in tension. Use the load-elongation characterisitcs shown in the following table. Plot the data as engineering stress vs. engineering strain. Then compute the modulus of elasticity, yeild strength at a strain offset of 0.002, determine the tensile strength of this alloy, approximate ductility in percent elongation and the modulus of resilience. N mm 0 50.8 12700 50.825 25400 50.851 38100...

A cable with a diameter of 6 mm is subject to a maximum tensile force of...

A cable with a diameter of 6 mm is subject to a maximum tensile force of 9 kN. The cable must not extend by more than 0.5% and must not yield. Properties of four materials (W, X, Y and Z) are listed in the table below. Which of materials in the table above are suitable for the cable? Material Yield strength (MPa) Tensile strength (MPa) Young’s Modulus (GPa) W 200 450 195 X 320 400 45 Y 640 700 85...

A tensile test sample has a gauge length of 10 cm and a cross-section area of...

A tensile test sample has a gauge length of 10 cm and a cross-section area of 500 mm2. During the test, the sample yields at 0.2 % strain under a load of 1.5 x 105 N and the corresponding gauge length is 10.1 cm. The maximum load of 2 x 105 N is reached at a gauge length of 13 cm and the fracturing cross-section area is 370 mm2. Determine the values of (a) yield strength, (b) modulus of elasticity,...

Problem 1: A round bar with a diameter of 32 mm, and 4012 mm in length...

Problem 1: A round bar with a diameter of 32 mm, and 4012 mm in length was under tensile test to determine the mechanical properties of the material. The following table shows the load versus strain data collected from the testing machine and a strain gauge applied on the bar in the loading direction. The measured percentage elongations were 19.8 % and 14.6 % on gauge lengths of 100 mm and 200 mm respectively. Assume: the elongations include the necking;...

The strength coefficient (K) and the work hardening exponent (n) for a stainless steel were determined...

The strength coefficient (K) and the work hardening exponent (n) for a stainless steel were determined during the analysis of the data from a tensile test using a standard tensile specimen. The flow curve parameters for the stainless steel are K= 1250 MPa and n = 0.4. A compression test is performed on a specimen of the stainless steel. If the starting height and diameter of the specimen are 80 mm and 18 mm, respectively and the final height of...

a tension test was performed on a steel specimen having an original diameter of 0.503in. and...

a tension test was performed on a steel specimen having an original diameter of 0.503in. and gauge length of 2.00in. using the data listed in the table, plot the stress-strain diagram and determine approximately the modulus elasticity load(kip elongation(in) load(kip elongation 0 0 13.0 0.0400 2.5 0.009 14.0 0.1400 6.50 0.0025 14.5 0.2500 8.00 0.0040 13.5 0.3500 9.2 0.0075 13.0 0.5700 9.80 0.0098