Problem 1 The composite shaft, consisting of aluminum, copper, and steel sections, is subjected to the loading shown. Determine the displacement of end A with respect to end D and the normal stress i...
The composite shaft, consisting of aluminum, copper, and steel sections, is subjected to the loading shown. Determine the displacement of end A with respect to end D and the normal stress in each section. The cross-sectional Aluminum Соpper Steel E=10(10') ksi AAB 0.09 in2 Eg=18(10') ksi ARc 0.12 in2 E-29(10) ksi ACD 0.06 in 1.75 kip 3.50 kip 1.50 kip 2.00 kip area and modulus of elasticity for each section are shown in the figure. Neglect the size of the...
The composite shaft, consisting of aluminum, copper, and steel sections, is subjected to the loading shown. The cross-sectional areas of sections AB, BC ,and CD are AAB 0.10 in2 , ABC 0.11 in2 , and AcD =0.07 in2 , respectively. The modulus of elasticity for each section are shown in the figure. Neglect the size of the collars at B and C Part A Determine the displacement of B with respect to C of the composite shaft. Express your answer...
The composite shaft, consisting of aluminum, copper, and steel sections, is subjected to the loading shown. The cross-sectional areas of sections AB, BC ,and CD are AAB 0.10 in2 , ABC 0.11 in2 , and AcD =0.07 in2 , respectively. The modulus of elasticity for each section are shown in the figure. Neglect the size of the collars at B and C Part A Determine the displacement of B with respect to C of the composite shaft. Express your answer...
The composite shaft, consisting of aluminum, copper, and steel sections, is subjected to the loading shown. The cross-sectional areas of sections AB, BC , and CD are AAB = 0.08 in2 , ABC = 0.15 in2 , and ACD = 0.05 in2 , respectively. The modulus of elasticity for each section are shown in the figure. Neglect the size of the collars at B and C. (Figure 1) Part A Determine the normal stress in section AB. Express your answer...
Problem 4.3 The composite shaft, consisting of aluminum, copper, and steel sections, is subjected to the loading shown. The cross-sectional areas of sections AB, BC and CD are A AB = 0.10 in?. ABC = 0.14 in?, and Acp = 0.06 in?, respectively. The modulus of elasticity for each section are shown in the figure. Neglect the size of the collars at B and C. (Figure 1) Figure 1 of 1 Aluminum El = 10(10) ksi Copper E = 18(10)...
Q4. The composite shaft, consisting of aluminum, copper, and steel sections, is subjected to the loading shown in the figure below. (Hint: tension is positive, compression is negative) (20 pts) Aluminum Copper E = 10(10) ksi Wec. = 18(10) ksi A =0.09 in? Ac 0.12 in Steel E, = 29(10-) ksi Acp = 0.06 in- 4.50 kip -1.75 kip 3.00 kip 2.50 kip B4.50 kip -12 in.- 1.75 kip -16 in. 18 in a. Determine the internal axial load distributions...
(15%) The shaft show below consists of parts AB (Aluminum- Diameter .25") BC (Copper- Diameter.375") and CD(A36-steel -Diameter .35 "). Find the displacement of B with regards to C. Neglect the collars at b and C. 5. 1.75 kip 3.50 kip 150 kip 2.00 kip 1.75 kip 3.50 kip -16 in- 12 in.- -18 in- (15%) The shaft show below consists of parts AB (Aluminum- Diameter .25") BC (Copper- Diameter.375") and CD(A36-steel -Diameter .35 "). Find the displacement of B...
14-2. The copper shaft is subjected to the axial loads shown. Determine the displacement of end A with respect to end D if the diameters of each segment are dal = 0.75 in., dec=1 in., and dcp=0.5 in. Take Ecu = 18(109) ksi. -80 in.-- 5 kip 150 in.- +-100 in.--- 8 kip 2 kip 6 kip D 5 kip B C 2 kip Prob. 4-2
Aluminum Steel 22 Kip.ft 20 Kip.ft Question A 4 inch diameter composite shaft is subjected to the torques as shown. The section are perfectly bonded rigidly together. Use Gsteel = 11,600 ksi and Galuminum = 4000 ksi. Determine the maximum shearing stress in the shaft and the magnitude of the angle of twist of point D with respect to point A. 7.4 Kip.ft T - - 4.9ft 6.6 ft 3.3ft TP Shear Stress: t = Angle of Twist: Ø= Polar...
The gears attached to the fixed-end steel shaft are subjected to the torques shown in the figure. If the shear modulus of elasticity is 150 GPa a determine the following: nd the shaft has a diameter of 14 mm, a. Sketch the torque diagram along the steel shaft. b. Determine the maximum shear stress at Tmax and specify location. c. Sketch the shear stress distribution along the radial line at location specified in (b). d. Determine the displacement of the...