FORCES IN STRUCTURES 49Resolving forces vertically:
F 2 sin 60°+R 2 = 0i.e. R 2 =−F 2 sin 60° ( 4. 11 )
Substituting equation (4.6) into equation (4.11) gives:
R 2 =−(− 2 )× 0. 866i.e. R 2 = 1 .732 kN(acting upwards)
Resolving forces horizontally:
F 3 +F 2 cos 60°+H 2 = 0i.e. H 2 =−F 3 −F 2 × 0. 5 ( 4. 12 )
Substituting equations (4.6) and (4.10) into equa-
tion (4.12) gives:
H 2 =−(− 3 )–(− 2 )× 0. 5i.e. H 2 =4kN
These calculated forces are of similar value to those
obtained by the graphical solution for Problem 6, as
shown in the table below.
Member Force (kN)F 1 3.47
F 2 −2.0
F 3 −3.0
R 1 −1.73
R 2 1.73
H 2 4.0Problem 10. Solve Problem 7, Figure 4.20
on page 45, by the method of joints.Firstly, assume all unknown member forces are in
tension, as shown in Figure 4.34.
30 ° 30 ° 30 ° 30 °60 ° 60 °3 kN4 kN 5 kNR 1 = 5.75 kN R 2 = 6.25 kN
Joint 1Joint 3Joint^4Joint^5Joint 2Figure 4.34
Next, we will isolate the forces acting at each
joint by making imaginary cuts around each of the
five joints as shown in Figure 4.34.
As there are no joints with two or less unknown
forces, it will be necessary to calculate the unknown
reactionsR 1 andR 2 prior to using the method of
joints.
Using the same method as that described for the
solution of Problem 7, we haveR 1 = 5 .75 kNandR 2 = 6 .25 kNNow either joint (1) or joint (2) can be considered,
as each of these joints has two or less unknown
forces.
Consider joint (1); see Figure 4.35.R 1 = 5.75 kNF 2F 130 °Figure 4.35Resolving forces vertically:5. 75 +F 1 sin 30°= 0i.e. F 1 sin 30°=− 5. 75or 0. 5 F 1 =− 5. 75i.e. F 1 =−5. 75
0. 5
i.e. F 1 =− 11 .5kN(compressive)
( 4. 13 )Resolving forces horizontally:0 =F 2 +F 1 cos 30°i.e. F 2 =−F 1 cos 30° ( 4. 14 )Substituting equation (4.13) into equation (4.14)
gives:F 2 =−F 1 cos 30°=−(− 11. 5 )× 0. 866i.e. F 2 = 9 .96 kN(tensile)Consider joint (2); see Figure 4.36.