1. Determine the Zero-Force Members in the plane truss.
1
2. Determine the force in each member of the loaded truss. Make use of the symmetry of
the truss and of the loading. Use the Method of Joints.
2
3. Determine the force in member GM by the Method of Section.
3
4. Determine the forces in members BC and FG.
4
CutFBC
FCJ FFJ
FFG
FBC
FCJFFJ
FFG
1200 N
800 N C
CNFFM FGFGC 60002120040
Cut (Upper Side)
TNFFFF BCFGBCy 60000
600
+
EK, EF
Zero-Force Members:
5
5. Determine the forces in members FG, CG, BC, and EF for the loaded crane truss.
25 kN
D
E
CF
GB
50 kN
25 kN25 kN
25 kN
25 kN
25 kN
25 kN
BGZero-Force Members:
6
25 kN
DE
CF
GB
50 kN
25 kN25 kN
25 kN
25 kN
25 kN
25 kN
1st Cut
1st Cut (Upper part) E
F
25 kN
D
50 kN
25 kN25 kN25 kN
25 kN
25 kN
BCFG
G
C
CG
00 CGFx+ CkNBCBCM F 1000)4()8(500
TkNFGBCFGFy 25050250100
Joint F: EF
FCF
25 kN
25 kN
FG
TkNEF
FGEF
Fy
7.45
045cos45cos2525
0
25
7
6. Calculate the forces in members DE, GJ and DG of the simple truss. State
whether they are in tension or compression.
8
7. The truss shown consists of 45° triangles. The cross members in the two center panels that
do not touch each other are slender bars which are incapable of carrying compressive loads.
Determine the forces in members GM and FL.
By=40 kN
Ax=80 kN
Ay=60 kN
From equilibrium of whole truss;
Reactions at the supports
9
Ax=80 kN
Ay=60 kN
I. Cut
GF
LM
GM
FL
I. Cut (Left Side)
10
8. If it is known that the center pin A supports one-half of the vertical loading shown,
determine the force in member BF.
11
From equilibrium of whole truss; 00 xx AF
Reactions at the supports
Center pin A supports one-half of the vertical loading.
kNAy 262
10284
Ay
Gy
Ax
Hy
Because of symmetry, kNHG yy 13
12
DE
DF
BF
AF
I. Cut
Hy=13 kN
DE
DF
BF
AF
Hy=13 kN
Ay
Gy
I. Cut (Right side)
There are four unknowns.
13
Joint AAB AF
Ay=26 kN
45o 45o
AFABAFABFx 045cos45cos0
I. Cut (Right side)
DE
DFBF
AF
Hy=13 kN
TkNBF
AFAFBF
M D
24.24
0)12(45sin)16(45cos)16()48(13)36(8)24(8)12(10
0
38.1838.18
+45o
CkNAFABAFABFy 38.1802645sin45sin0
A
D
14
9. Determine the forces acting in members DE, DI, KJ, AJ.
JK
A
L
M
DCB
I
E F
G
H
20 kN
37o
4 m 4 m 4 m
3 m
3 m
6 m
15
JK
A
L
M
DCB
I
E F
G
H
20 kN
37o
4 m 4 m 4 m
3 m
3 m
6 m
kNAATF xxx 4037cos200
From equilibrium of whole truss; kNAAF yyy 12037sin200
Reactions at the supports
+
EF, FG
Zero-Force Members:
Ax
Ay
T
kNTTM A 200)12(37sin20)6(37cos20)12(0
16
JK
A
L
M
DCB
I
E F
G
H
20 kN
37o
4 m 4 m 4 m
3 m
3 m
6 m
J
E
20 kN37o
CkNAJ
AJA
F
x
x
5
086
8
0
22
Joint A:
Ax
Ay
T
AL
Ay=12 kN
AJ
Ax=4 kN
1st Cut (Right side)
AJ
KJ
DEEI
IJ
1st Cut
+
TkNDEDE
M J
80437sin206
0
17
JK
A
L
M
DC
I
E F
G
H
20 kN
37o
4 m 4 m 4 m
3 m
6 m
E
20 kN
37o
3 mI
JK
Ax
Ay
T
2nd Cut (Right side)
AJ
KJ
DE
DI
2nd Cut
+
TkNKJAJKJDE
M I
120437sin20337cos20337cos33
0
58
KI
TkNDIDIDIAJDE
M K
5.70437sin337cos837sin20437sin6
0
58
+
18
10. Determine the forces in members DE, EI, FI, and HI of the arched roof truss.
19
Gx
GyAy
kNAAGF
kNGGM
yyyy
yyA
15001007522520
1500)36(25)30(75)20(100)10(75)4(25)40(0
From equilibrium of whole truss;
00 xx GF
Reactions at the supports
kNGA yy 150
Because of symmetry of the truss:
+
BK, HF
Zero-Force Members:
20
Ay=150 kN Gy=150 kN
1st Cut (Right side)
1st Cut
Gy=150 kN
FI
25 kN
F
EF
HI
H
G
+
I
CkNEFEFM I 48.31501615012251264
40
22
TkNHIHIEFFy 93.750251501614
14
64
40
222248.315
TkNFIHIFIEFFx 356.20501614
16
64
60
2293.75
2248.315
21
Ay=150 kN Gy=150 kN
2nd Cut (Right side)
2nd Cut
Gy=150 kN
IF
E
DE
IH
G
+
I
EI25 kN
F
75 kN
CkNDEDEDE
M I
008.29701615067512254103
106
103
3
0
2222
TkNEI
HIDEEIFy
4.26
015025751614
14
103
3
64
40
2293.75
22008.297
22
22
11. The hinged frames ACE and DFB are connected by two hinged bars, AB and CD,
which cross without being connected. Compute the force in AB.
B
A
3.5 m
2 m
a
o.
.tan
7429
53
2
a
a
23
I. Cut (Left Side)
AB
CD
Ex
Ey
a a
AB
CDB
A
3.5 m
2 m
a
ABCD
CDCDABABM E
3
03sin4cos5.1sin6cos0
aaaa
o.
.tan
7429
53
2
a
a
I. Cut (Right Side)
I. Cut (Left Side)
I. Cut (Right Side)
05.1sin6cos3sin4cos6100 aaaa CDCDABABM F
+
+
CkNABABCD 78.3098.195.560 24