The frame in (Figure 1) is subjected to a horizontal force of P = 370 N...

A cylindrical storage tank contains liquefied propane under a pressure of 1.5 MPa (gage pressure P=1.5...

A cylindrical storage tank contains liquefied propane under a pressure of 1.5 MPa (gage pressure P=1.5 MPa) and is subjected to an axial force F=60 kN. Knowing that the tank has an inner diameter of 320 mm and a wall thickness of 3 mm, find the principal stresses and determine the maximum shear stress.

True false: 1) When subjected to bending, a beam only develops normal stress in tension and...

True false: 1) When subjected to bending, a beam only develops normal stress in tension and compression 2)the shear flow is defined as an average force per unit length for each cross-section. 3)due to bending shear flow develops only along the beam length. 4)) shear center is defined as the point through which force can be applied without causing torsion Fill in the blank: the shear stress induced by bending in a beam is ............ Solve the question problem: A...

The A-36 steel pipe in (Figure 1) has a 6061-T6 aluminum core. It is subjected to...

The A-36 steel pipe in (Figure 1) has a 6061-T6 aluminum core. It is subjected to a tensile force of 200 kN k N . The pipe has an outer diameter of 96 mm m m and an inner diameter of 86 mm m m . For A-36 steel, Est=200GPa E s t = 200 G P a , and for 6061-T6 aluminum, Eal=68.9GPa E a l = 68.9 G P a . A)Determine the average normal stress in the...

A simply supported polymer thin-walled vessel is subjected to the internal pressure P, as shown in...

A simply supported polymer thin-walled vessel is subjected to the internal pressure P, as shown in Figure 3. The tank is 6 m long, 2 m in outer diameter. The wall thickness of the tank is 20 mm. The tank and its contents have a weight distribution of q = 400 kN/m. If the pressure P = 200 kPa and the allowable stress of the polymer is allow = 30 MPa, determine the factor of safety against yielding according to...

1. A steady horizontal force F of magnitude 100 N is applied at the axle of...

1. A steady horizontal force F of magnitude 100 N is applied at the axle of a solid disk as shown. The disk has mass of 5.0 kg and a diameter of 0.40m. Calculate the linear speed of the center of the disk after it has moved 10m. (moment of inertia is 1/2 Mr^2) I have the answer as 16 m/s. 2. A solid sphere of a radius 0.2 m is released from rest from a height of 2.0 m...

Two spheres are pressed together with a force of 800 N. Each sphere is 25.4 mm...

Two spheres are pressed together with a force of 800 N. Each sphere is 25.4 mm in diameter and made of a material having a Young’s modulus of 220 MN/M^2, and a Poisson’s ratio of 0.275. Determine: Contact area dimensions, maximum pressure, and principal stresses.

In the figure, a force P→ acts on a block weighing 47.0 N. The block is...

In the figure, a force P→ acts on a block weighing 47.0 N. The block is initially at rest on a plane inclined at angle θ = 17.0° to the horizontal. The positive direction of the x axis is up the plane. The coefficients of friction between block and plane are μs = 0.520 and μk = 0.350. In unit-vector notation, what is the frictional force on the block from the plane when P→ is (a) (-5.40 N) î ,...

A steady horizontal force F of magnitude 100 N is applied at the axle of a...

A steady horizontal force F of magnitude 100 N is applied at the axle of a solid disk as shown. The disk has mass of 5.0 kg and a diameter of 0.40m. Calculate the linear speed of the center of the disk after it has moved 10m. (moment of inertia is 1/2 Mr^2)

A steel wire has the following properties: Length = 5.00 m Cross-sectional area = 4.60×10−2 cm2...

A steel wire has the following properties: Length = 5.00 m Cross-sectional area = 4.60×10−2 cm2 Young's modulus = 2.0×1011Pa Shear modulus = 0.84×1011Pa Proportional limit = 3.60×108Pa Breaking stress = 11.0×108Pa The proportional limit is the maximum stress for which the wire still obeys Hooke's law (point B in (Figure 1)). The wire is fastened at its upper end and hangs vertically. A) How great a weight can be hung from the wire without exceeding the proportional limit? B)...

Truss Analysis 1.      Select a material and a cross section for the members. 2.      Choose four...

Truss Analysis 1.      Select a material and a cross section for the members. 2.      Choose four arbitrarily placed points. Connect them as two triangles. No members can be vertical or horizontal and none can be aligned. 3.      Draw the truss and label the measured lengths. 4.      Select two support points and two load points. 5.      Load the truss vertically with a load at each load point. 6.      Calculate the reactions and the forces within the members. 7.      Calculate the change...