The beam shown below is acted upon by a constant distributed load, a couple moment, and a point force as shown. It is supported by a pin at A and a roller at B. F A B L2 The applied forces/moments are: w = 40 kN/m from A to B F= 20 kN at C M = 150 kN * m at C Allow: L1 = 8 m L2 = 3 m i. Determine the reaction forces at A and B. il. Find the location of zero shear between A and B. lil. Determine the absolute maximum bending moment for the beam.
The beam shown below is acted upon by a constant distributed load, a couple moment, and a point force as shown. It is supported by a pin at A and a roller at B. F A B L2 The applied forces/moments are: w = 40 kN/m from A to B F= 20 kN at C M = 150 kN * m at C Allow: L1 = 8 m L2 = 3 m i. Determine the reaction forces at A and B. il. Find the location of zero shear between A and B. lil. Determine the absolute maximum bending moment for the beam.
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Transcribed Image Text:The beam shown below is acted upon by a constant distributed load, a couple moment, and a point force as shown. It is supported by a pin at A and a roller at B.
F
A
B
L2
The applied forces/moments are:
w = 40 kN/m from A to B
F= 20 kN at C
M = 150 kN * m at C
Allow:
L = 8 m
L2 = 3 m
I. Determine the reaction forces at A and B.
il. Find the location of zero shear between A and B.
il. Determine the absolute maximum bending moment for the beam.
iv. Draw the shear force diagram for the beam.
v. Draw the bending moment diagram for the beam.
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