STATICS & STRENGTH OF MATERIALS - Example

A loaded, simply supported beam is shown below. For this beam:

A. Draw a Free Body Diagram of the beam, showing all external loads and support forces (reactions).
B
. Determine expressions for the internal shear forces and bending moments in each section of the beam.
C
. Make shear force and bending moment diagrams for the beam.
Unless otherwise indicated, all joints and support points are assumed to be pinned or hinged joints.

Solution:

Part A:
STEP 1: Draw a free body diagram showing and labeling all load forces and support (reaction) forces, as well as any needed angles and dimensions.
STEP 2
: Break any forces not already in x and y direction into their x and y components.
STEP 3
: Apply the equilibrium conditions.

Sum Fy = -4,000 lbs - (1,000 lbs/ft)(8 ft) - 6,000 lbs + By + Dy = 0
Sum TB = (Dy)(8 ft) - (6,000 lbs)(4 ft) + (1,000 lbs/ft)(8 ft)(4 ft) + (4,000 lbs)(8 ft) = 0
Solving for the unknowns:
By =23,000 lbs; Dy = -5,000 lbs

Part B: Determine the Shear Forces and Bending Moments expressions for each section of the loaded beam. For this process we will ‘cut’ the beam into sections, and then use Statics - Sum of Forces to determine the Shear Force expressions, and Integration to determine the Bending Moment expressions in each section of the beam.

Section 1: Cut the beam at x, where 0 <>

1. FBD. (Shown in Diagram)
2
. All forces in x & y components (yes)
3
. Apply translational equilibrium conditions (forces only):

Sum Fx = 0 (no net external x- forces)
Sum Fy = -4,000 lbs - 1,000 lbs/ft(x)ft - V1 = 0
Solving:
V1 = [-4,000 - 1,000x] lbs

4. Integration

M1 = -500x2 - 4,000x + C1

a)Boundary condition to find C1: at x=0 M=0
Apply BC: 0 = -500(0)2 - 4,000(0) + C1
Solving
:
C1 = 0
Therefore…
M1 = [-500x2 - 4,000x] ft-lbs for 0 <>

Section 2: Cut the beam at x, where 8 <>

1. FBD. (Shown in Diagram)
2
. All forces in x & y components (yes)
3
. Apply translational equilibrium conditions (forces only):

Sum Fx = 0 (no net external x- forces)
Sum Fy = -4,000 lbs - 1,000 lbs/ft(8 ft) + 23,000 lbs - V2 = 0
Solving:
V2 = 11,000 lbs

4. Integration

M2 = 11,000x + C2

a)Boundary condition to find C2: at x=8 ft M=-64,000 ft-lbs (from equation M1)
Apply BC: -64,000 ft-lbs = 11,000 lbs (8) + C2
Solving:
C2 = -152,000 ft-lbs
Therefore…
M2 = [11,000x - 152,000] ft-lbs for 8 <>

Section 3: Cut the beam at x, where 12 <>

1. FBD. (Shown in Diagram)
2
. All forces in x & y components (yes)
3
. Apply translational equilibrium conditions (forces only):

Sum Fx = 0 (no net external x- forces)
Sum Fy = -4,000 lbs - 1,000 lbs/ft(8 ft) + 23,000 lbs -6,000 lbs - V3 = 0
Solving
:
V3 = 5,000 lbs

4. Integration

M3 = 5,000x + C3

a)Boundary condition to find C3: at x=16 ft M=0 ft-lbs (end of beam, no external torque so M3=0)
Apply BC: 0 = 5,000(16) + C3
Solving:
C3 = -80,000 ft-lbs
Therefore…
M3 = [5,000x - 80,000] ft-lbs for 12 <>

Part C: Shear Force and Bending Moment Diagrams: Now using the expressions found in Part B above, we can draw the shear force and bending moment diagrams for our loaded beam.

V1 = -1,000x+4,000 lb, V2 = 11,000 lb, V3 = 5,000 lb
M1 =-
500x2+4,000x ft-lb, M2 = 11,000x -152,000 ft-lb, M3 = 5,000x-80,000 ft-lb

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