Handbook of Civil Engineering Calculations

(singke) #1
0.20(76.6 - 0.259P) - 15.32 - 0.052P. Substituting for Rx from step 4 yields 64.3 -
0.966P - 15.32 - 0.052P; so P = 53.6 Ib (238.4 N).


  1. Draw a second free-body diagram
    In Fig. 2c, draw a free-body diagram of the bar, with Rx being directed downward.

  2. Solve as In steps 1 through 5
    As before, Ry = 76.6 - 0.259P. Also the absolute value of Rx = 0.966P - 64.3. But Rx =
    0.20^, = 15.32 x 0.052P. Then 0.966P - 64.3 = 15.32 - 0.052P; so P = 78 2 Ib (347 6N).


ANALYSIS OFA STRUCTURAL FRAME


The frame in Fig. 30 consists of two inclined members and a tie rod. What is the tension
in the rod when a load of 1000 Ib (4448.0 N) is applied at the hinged apex? Neglect the
weight of the frame and consider the supports to be smooth.

Calculation Procedure:


  1. Draw a free-body diagram of
    the frame
    Since friction is absent in this frame, the
    reactions at the supports are vertical.
    Draw a free-body diagram as in Fig. 3b.
    With the free-body diagram shown,
    compute the distances X 1 and Jc 2. Since
    the frame forms a 3-4-5 right triangle, X 1
    = 16(4/5) = 12.8 ft (3.9 m) and X 2 =
    12(3/5) -7.2 ft (2.2m).

  2. Determine the reactions on
    the frame
    Take moments with respect to A and B to
    obtain the reactions:


^MB = 20/^-1000(7.2) = O
SM 4 = 1000(12.8) - 20RR = O
R 1 = 360 Ib (1601.2 N)
RR = 640 Ib (2646.7 N)


  1. Determine the distance y in
    Fig. 3c
    Draw a free-body diagram of member A C
    in Fig. 3c. Compute y = 13(3/5) = 7.8 ft
    (2.4 m).
    4. Compute the tension in the
    tie rod
    Take moments with respect to C to find
    the tension Tin the tie rod:
    ^Mc= 360(12.8) -7.8f= O
    T= 591 Ib (2628.8 N) FIGURE 3


Tie rod
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