The modulus of elasticity for a ceramic material having 5.6 vol% porosity is 329 GPa. (a)...

3. Composites with fiber-reinforced structures with continuous and aligned fiber properties are made of 45 vol%...

3. Composites with fiber-reinforced structures with continuous and aligned fiber properties are made of 45 vol% aramid fiber and 55 vol% polycarbonate matrix. The mechanical characteristics of the two materials can be shown in the following table Modulus of Elasticity [GPa (psi)] Tensile Strength [MPa (psi)] Aramid fiber 131 (19 × 106) 3600 (520000) Polycarbonate 2.4 (3.5 × 105) 65 (9425) When the aramid fiber breaks, the stress on the polycarbonate matrix will be 35 MPa (5075 psi). Determine it...

The elastic modulus, yield strength and ultimate strength of a certain material are 110 GPa, 240...

The elastic modulus, yield strength and ultimate strength of a certain material are 110 GPa, 240 MPa and 265 MPa, respectively. If a cylindrical bar of this material 380 mm long is subjected to a uniaxial tension test and its length is increased by an amount of 0.50 mm under a tensile load of 6660 N. At the same time its diameter decreased by 0.28 mm. Calculate; a) The initial diameter of the bar,

4. (a) Illustrate the stress-strain curve in elasticity. (b)A Steel rod with Young’s modulus Y=200 GPa...

4. (a) Illustrate the stress-strain curve in elasticity. (b)A Steel rod with Young’s modulus Y=200 GPa has a circular cross section and is 10 m long. Determine the minimum diameter if the rod must hold a 30 kN tensile force without deforming more than 5 mm. Assume the steel stays in the elastic region. Note, 1 GPa = 10^9 Pa.

Young's modulus is a quantitative measure of stiffness of an elastic material. Suppose that for metal...

Young's modulus is a quantitative measure of stiffness of an elastic material. Suppose that for metal sheets of a particular type, its mean value and standard deviation are 90 GPa and 2.1 GPa, respectively. Suppose the distribution is normal. a) Calculate P(89 ≤ X ≤ 91) when n = 9. b) How likely is it that the sample mean diameter exceeds 91 when n = 25?

Young's modulus is a quantitative measure of stiffness of an elastic material. Suppose that for aluminum...

Young's modulus is a quantitative measure of stiffness of an elastic material. Suppose that for aluminum alloy sheets of a particular type, its mean value and standard deviation are 70 GPa and 1.6 GPa, respectively (values given in the article "Influence of Material Properties Variability on Springback and Thinning in Sheet Stamping Processes: A Stochastic Analysis" (Intl. J. of Advanced Manuf. Tech., 2010: 117–134)). (a) If X is the sample mean Young's modulus for a random sample of n =...

Young's modulus is a quantitative measure of stiffness of an elastic material. Suppose that for metal...

Young's modulus is a quantitative measure of stiffness of an elastic material. Suppose that for metal sheets of a particular type, its mean value and standard deviation are 75 GPa and 2.4 GPa,respectively. Suppose the distribution is normal. (Round your answers to four decimal places.) a. calculate P(74 ≤ X ≤ 76) when n = 25. b. How likely is it that the sample mean diameter exceeds 76 when n = 36?

Young's modulus is a quantitative measure of stiffness of an elastic material. Suppose that for metal...

Young's modulus is a quantitative measure of stiffness of an elastic material. Suppose that for metal sheets of a particular type, its mean value and standard deviation are 75 GPa and 2.1 GPa, respectively. Suppose the distribution is normal. (Round your answers to four decimal places.) (a) Calculate P(74 ≤ X ≤ 76) when n = 16. (b) How likely is it that the sample mean diameter exceeds 76 when n = 25?

(A) Explain the atomic origins of elasticity in a metal, polymer and ceramic material. Use atomic...

(A) Explain the atomic origins of elasticity in a metal, polymer and ceramic material. Use atomic force diagram to illustrate your answer. (B) Explain why powder diffraction is often used as an analytical tool in materials research. What is the information can it provide? ( C)Sketch and label the basic cubic Perovskite structure and briefly explain how it can be used for the following applications: i. Sonar or ultrasound ii. Superconductivity iii. Microwave dielectrics iv. Ionic conduction With regard to...

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-Calculate conventional yield effort at 0.2% (0.002 in./in.) b- Tensile strength. c- The modulus of elasticity....

a-Calculate conventional yield effort at 0.2% (0.002 in./in.) b- Tensile strength. c- The modulus of elasticity. d- Elongation e- The reduction in area. f- The engineering effort to fracture g- The real stress to fracture h- The modulus of resilience Copper alloy Load (N) Calibrated length (mm) 0 40.00000 25000 20.01850 50000 40.037 75000 40.0555 90000 40.2000 105000 40.6 120000 41.56 131000 44 125000 47.52 - Initial diameter of the test tube: 20mm - Initial calibrated length: 40mm - Calibrated...