For the simply supported beam subjected to the loading shown, derive equations for the shear force V and the bending moment M for any location in the beam. (Place the origin at point A.) Let a=12.0 ft, b=6.5 ft, c= 7.0 ft, w = 7 kips/ft and M = 230 kip-ft. Construct the shear-force and bending-moment diagrams on paper and use the results to answer the questions in the subsequent parts of this GO exercise.


Calculate the reaction forces A_y and C_y acting on the beam. Positive values for the reactions are indicated by the directions of the red arrows shown on the free-body diagram below. (Note: Since A_x = 0, it has been omitted from the free-body diagram.)

Determine the shear force acting at each of the following locations:

(a) x = 0+ ft (i.e., just to the right of support A)
(b) x = 12.0 ft (i,e., at point B)
(c) x = 18.5- ft (i.e., just to the left of the support C)
(d) x = 18.5+ ft (i.e., just to the right of the support (C)
(e) x = 24.5 ft

Note that x = 0 at support A. 

Determine the bending moment acting at each of the following locations:

(a) x = 12.0- ft (i.e., just to the left of point B)
(b) x = 12.0+ ft(i.e., just to the right of point B)
(c) x = 18.5 ft (i.e. at point C)
(d) x = 24.5 ft

Note that x = 0 at support A.

 

Use your shear-force and bending-moment diagrams to determine the maximum positive bending moment, M_{max, pos}, the maximum negative bending moment, M_{max, neg}, and their respective locations, x_{max, pos} and x_{max, neg}. When entering your answers for the maximum bending moments, use the shear-force and bending-moment sign conventions detailed in Section 7.2. The maximum negative bending moment is the negative moment with the largest absolute value. Enter the maximum negative bending moment as a negative value.

Transcribed Image Text:

A M B D a b Ay Cy