TABLE 1 Forces in Truss Members (Fig. 4)
Force
Member kips kN
AJ +6.1 +29.8
BK +9.5 +42.2
CTV +19.8 +88.0
DE +30.2 -134.2
HJ -6.0 -26.7
GM -13.0 -57.8
FP -20.0 -88.9
JK -4.5 20.0
KM +8.1 +36.0
MN -8.6 -38.2
NP +10.4 +46.2
PE -12.6 56.0closes that they are tensile forces. Force NM is directed toward the joint; therefore, it is
compressive.
The validity of this procedure lies in the drawing of the vectors representing external
forces while proceeding around the truss in a clockwise direction. Tensile forces are
shown with a positive sign in Table 1; compressive forces are shown with a negative sign.
Related Calculations: Use this general method for any type of truss.TRUSS ANALYSIS BY THE METHOD
OFJOINTS
Applying the method of joints, determine the forces in the truss in Fig. 5a. The load at
joint 4 has a horizontal component of 4 kips (17.8 kN) and a vertical component of 3 kips
(13.3 kN).
Calculation Procedure:- Compute the reactions at the supports
Using the usual analysis techniques, we find RLV =19 kips (84.5 kN); RLH = 4 kips (17.8
kN); RR = 21 kips (93.4 kN). - List each truss member and its slope
Table 2 shows each truss member and its slope. - Determine the forces at a principal joint
Draw a free-body diagram, Fig. 5b, of the pin at joint 1. For the free-body diagram, as-
sume that the unknown internal forces AJ and HJ are tensile. Apply the equations of equi-
librium to evaluate these forces, using the subscripts H and V, respectively, to identify the
horizontal and vertical components. Thus ^FH = 4.0 + AJn + HJ = O and ^Fv = 19.0 +