Post on 30-Oct-2014
1
! Cable Subjected to Concentrated Loads! Cable Subjected to Uniform Distributed
Loads! Arches! Three-Hinged Arch
Cables and Arches
2
Cable Subjected to Concentrated Loads
L
BC
D
L1 L2 L3
P1 P2
θ
yC yD
C
P2
TCDTCB x
y
Ay
Ax
TCD
B
P1
x
y
TBC
TBA
ΣFx = 0:+
ΣFy = 0:+
+ Σ MA = 0: Obtain TCD
L
A
BC
D
L1 L2 L3
P1 P2
θ
yC yD
3
Example 5-1
Determine the tension in each segment of the cable shown in the figure below.Also, what is the dimension h ?
2 m
2 m
h
2 m 2 m 1.5 m
A
BC
D
3 kN8 kN
4
2 mh
2 m 2 m 1.5 m
A
BC
D
3 kN8 kN
SOLUTION
+ ΣMA = 0:
Ay
Ax
5TCD
34
TCD(3/5)(2 m) + TCD(4/5)(5.5 m) - 3kN(2 m) - 8 kN(4 m) = 0
TCD = 6.79 kN
5
6.79(3/5) - TCB cos θBC = 0
θBC = 32.3o TCB = 4.82 kN
Joint C
ΣFx = 0:+
ΣFy = 0:+ 6.79(4/5) - 8 + TCB sin θCB = 0C
8 kN
5
34TCD = 6.79 kN
TCB
θBC
x
y
Joint B
ΣFx = 0:+ - TBA cos θBA + 4.82 cos 32.3o = 0B
3 kN
x
y
TBC = 4.82 kN
TBA
θBA32.3o
ΣFy = 0:+ TBA sin θBA - 4.82 sin 32.3o - 3 = 0
θBA = 53.8o TBA = 6.90 kN
h = 2 tanθBA = 2 tan53.8o = 2.74 m
A
B C
D
3 kN 8 kN
h
6
y
x
x = L
To
Cable Subjected to Distributed Load
θ
WTo
WT
θ
T cos θ = To = FH = Constant
T sin θ = W
oTW
dxdy
== θtan
Concepts & Conclusion:
T
7
wo = force / horizontal distance
Tθx
To
x
y
x
wo x
2x
To
wox
o
o
Txw
dxdy
== θtan
∫= dxT
xwyo
o
1
2
2C
Txwyo
o +=
at x = L , T = TB = Tmax
22max )( LwTT oo +=
yxwT o
o 2
2
=
0
To
woLTmax
θΒ
x
A
B
T
θx
Parabolic Cable: Subjected to Linear Uniform distributed Load
y
xL
8
wo
y
x
h
L
x∆x
wo(∆x)2x∆
∆x∆s
O∆y
θT
θ+ ∆θT + ∆T
ΣFx = 0:+
ΣFy = 0:+
+ ΣMO = 0:
-T cosθ + (T + ∆T) cos (θ + ∆θ) = 0
-Tsinθ + wo(∆x) + (T + ∆T) sin(θ + ∆θ) = 0
wo(∆x)(∆x/2) - T cos θ(∆y) - T sinθ(∆x) = 0
Derivation:
9
Dividing each of these equations by ∆x and taking the limit as ∆x 0, and hence ∆y 0, ∆θ 0, and ∆T 0, we obtain
0)cos(=
dxTd θ
----------(5-1)
owdx
Td=
)sin( θ----------(5-2)
θtan=dxdy
----------(5-3)
Integrating Eq. 5-1, where T = FH at x = 0, we have:
HFT =θcos ----------(5-4)
Integrating Eq. 5-2, where T sin θ = 0 at x = 0, gives
xwT o=θsin ----------(5-5)
Dividing Eq. 5-5 by Eq. 5-4 eliminates T. Then using Eq. 5-3, we can obtain the slope at any point,
H
o
Fxw
dxdy
==θtan ----------(5-6)
To
woxT
θ
10
Performing a second integration with y = 0 at x = 0 yields
2
2x
Fwy
H
o= ----------(5-7)
This is the equation of a parabola. The constant FHmay be obtained by using the boundary condition y =h at x = L. Thus,
hLwF o
H 2
2
= ----------(5-8)
Finally, substituting into Eq. 5-7 yeilds
22 x
Lhy = ----------(5-9)
From Eq. 5-4, the maximum tension in the cable occurs when θ is maximum; i.e., at x = L. Hence, from Eqs. 5-4 and 5-5,
2max )(2 LwFT oH += ----------(5-10)
To
woLTmax
θΒ
wo
y
x
h
L
11
Example 5-2
The cable shown supports a girder which weighs 12kN/m. Determine the tensionin the cable at points A, B, and C.
12 m
30 m
6 m
A
B
C
12
SOLUTION
L´30 - L´
12 m
30 m
6 m
A
B
C
y
xwo = 12 kN/m
x1x2
TC
θC
TA
θA
13
12x1
TC
θC
wo = 12 kN/m
L´
x1
6 mB
C
y
x
12 L´
To
To
Tx1
θ
oTx
dxdy 1
1
1 12tan == θ
∫= 11
112 dxT
xyo
0
oTL
2'1262
=
----------(1)2'LTo =
1
21
1 212 C
Txyo
+=
14
12 m
A
B
y
x
wo = 12 kN/m
30 - L´
x2
To
TA
θA
12 (30 - L´)
12 x2
To
Tx2
θ
oTx
dxdy 2
2
2 12tan == θ
2
22
22
2 21212 C
Txdx
Txy
oo
+== ∫0
oTL
2)'30(1212
2−=
oTxy
212 2
22=
----------(2)oTL
2)'30(1
2−=
15
----------(1)2'LTo =
----------(2)oTL
2)'30(1
2−=
From (1) and (2), L´ = 12.43 m, To = 154.5 kN
12 L´
To
TC
θC
TB = To = 154.5 kN
12 (30 - L´ )
To
TA
θA
22 )'12( LTT oC +=
22 )43.1212()50.154( ×+=
22 )]'30(12[ LTT oA −+=
22 )]43.1230(12[)50.154( −+== 214.8 kN
= 261.4 kN
16
Example 5-3
The suspension bridge in the figure below is constructed using the two stiffeningtrusses that are pin connected at their ends C and supported by a pin at A and arocker at B. Determine the maximum tension in the cable IH. The cable has aparabolic shape and the bridge is subjected to the single load of 50 kN.
I H
A B
D
F G C
8 m
6 m
50 kN
4 @ 3 m = 12 m 4 @ 3 m = 12 m
Pin rocker
E
17
----------(1)
SOLUTION
I
A
D
F G C
E
12 m
8 m
6 m
+ ΣMA = 0:
0812 =+− oy TC
yo CT 5.1=
To
Cy
Cx
To
Iy
Ay
Ax
H
BC
8 m
6 m
50 kN
9 m3 m
To
To
Hy
ByCy
Cx
+ ΣMB = 0:
----------(2)
08)9(5012 =−+− oy TC
25.565.1 +−= yo CT
From (1) and (2), Cy = 18.75 kN, To = 28.125 kN
18
I
12 m
wo
8 m
x
y
wox
To = 28.12 kN
From (1) and (2), Cy = 18.75 kN, To = 28.12 kN
x
θI
TI
28.12 kN
woxTx
θ
12.28tan xw
dxdy o== θ
∫= dxxwy o
12.280
1
2
12.28Cxwy o +=
)12.28(2)12(8
2ow
=
wo = 3.125 kN/m
19
8 m
H
8 m
I
12 m 12 m
37.5 kN
12wo = 37.5 kN12wo = 37.5 kN
To = 28.12 kN To = 28.12 kN
TH
θH
22 )12.28()5.37( +=IT
= 46.88 kN
Tmax = TI = TH = 46.88 kN
Tmin= To = 28.12 kN
28.12 kN
TI
θI
TI
θΙ
20
A B
D
F G C50 kN
4 @ 3 m = 12 m 4 @ 3 m = 12 m
E
ByAy
Ax
TTTTTTT 3125.33 ×=×= owT
= 9.375 kN0
+ ΣMA = 0: 0)24()15(50)21181512963(375.9 =+−++++++ yB
ΣFy = 0:+ 056.150)375.9(7 =−−+yA
Ay = -14.07 kN,
By = -1.56 kN,
21
Example 5-4
For the structure shown:(a) Determine the maximum tension of the cable(b) Draw quantitative shear & bending-moment diagrams of the beam.
8 m
8 m
0.5 m
AB
C
5 m 20 m
D
E
1 kN/m
Hinge
22
8 m
0.5 m
A B
5 m
D
1 kN/m
5 kN
To
By
Bx
Ay
Ax
To
Dy
8 m
B C
20 m
E
1 kN/m
20 kN
To
To
Ey
CyBy
Bx
+ ΣMA = 0:
0)5.0()5.2(5)5( =+− oy TB
+ ΣMC = 0:
0)8()10(20)20( =−+ oy TB
From (1) and (2), By = 0, To = 25 kN
SOLUTION
23
θ
20wo
To= 25 kN
8 m
20 m
E
x
y
TE = Tmax
22max )20()25( +== ETT
Tmax = 32.02 kN
θ
TE = Tmax
To= 25 kN
20wo = 20 kN
25tan xw
dxdy o== θ
1
2
)25(2
25
Cxw
dxxwy
o
o
+=
= ∫0
)25(2)20(8
2ow
=
wo = 1 kN/m
θ
Tx
To= 25 kN
wox
24
A BC
1 kN/m
CyAy
Ax
5 m 20 m
10 @ 2.5 m = 25 m
T = wo(2.5 m) = (1kN/m)(2.5 m) = 2.5 kN
2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5 2.5
=1.25 kN = 1.25 kN
1.25
-1.25
1.25
-1.25
1.25
-1.25
1.25
-1.25
1.25
-1.25
x (m)
V (kN)
x (m)
M (kN�m) 0.78 0.78 0.78 0.78 0.78 0.78 0.78 0.78 0.78 0.78
25
Example 5-5
The cable AB is subjected to a uniform loading of 200 N/m. If the weight of thecable is neglected and the slope angles at points A and B are 30o and 60o,respectively, determine the curve that defines the cable shape and the maximumtension developed in the cable.
30o
60o
A
B
15 m200 N/m
x
y
26
SOLUTION
(0.2 kN)(15 m) = 3 kN30o
60o
A
B
15 m
TA
60o
TB
3 kN
TA30o
TB
60o
30o
30o 30o
120o
oA
ooB TT
30sin30sin3
120sin==
TB = 5.20 kN
TA = 3 kN
27
30o
3 kN
30o
Ax
y
TA = 3 kN
0.2x
x
Tθ
0.2x
3 sin 30o = 1.5
3 cos 30o = 2.6
T
θ
6.25.12.0tan +
==x
dxdy θ
0∫ += 577.00769.0 xy
577.00769.0 += xdxdy
1
2
577.02
0769.0 Cxxy ++=
y = 0.0385x2 + 0.577x
28
Example 5-6
The three-hinged open-spandrel arch bridge shown in the figure below has aparabolic shape and supports the uniform load . Show that the parabolic arch issubjected only to axial compression at an intermediate point D along its axis.Assume the load is uniformly transmitted to the arch ribs.
7 kN/m
15 m 7.5 m 7.5 m
7.5 m
A C
B2
2)15(5.7 xy −
=
y
xD
29
210 kN
15 m
B2
2)15(5.7 xy −
=
15 m
SOLUTION
Ax
Ay Cy
Cx
Entire arch :
+ ΣMA = 0: 0)15(210)30( =−yC
ΣFy = 0:+ 0105210 =+−yA
Ay = 105 kN
Cy = 105 kN
30
105 kN
B
7.5 m 7.5 m 105 kN
CxB
Arch segment BC :
+ ΣMB = 0:
ΣFy = 0:+ 0105105 =+−yB
Bx
By
ΣFx = 0:+
Cx = 105 kN
Bx = 105 kN
By = 0
0)5.7()15(105)5.7(105 =−+− xC
31
52.5 kN
B
D
105 kN
0
3.75 m
26.6o
26.6o
A section of the arch taken through point D, x = 7.5 m, y = -7.5(7.52)/(15)2 = -1.875 m,is shown in the figure. The slope of the segment at D is
ΣFy = 0:+
ND = 117.40 kN, VD = 0, MD = 0 kN
ΣFx = 0:+ 105 - ND cos 26.6o - VD sin 26.6o = 0
Arch segment BD :
VD
ND
MD
5.0)15(
15tan5.7
2 −=−
===x
xdxdyθ
+ ΣMD = 0: MD + 52.5(3.75) - 105(1.875) = 0
-52.5 + ND sin 26.6o - VD cos 26.6o = 0
, θ = 26.6o
32
52.5 kN
B
D
105 kN
0
3.75 m
26.6o
26.6o
A section of the arch taken through point D, x = 7.5 m, y = -7.5(7.52)/(15)2 = -1.875 m,is shown in the figure. The slope of the segment at D is
Arch segment BD :
VD
ND
MD
5.0)15(
15tan 5.72 −=−
== =xxdxdyθ , θ = 26.6o
θNo= 25 kN
7.5 wo = (7.5)(7)= 52.5 kNND
22max )5.52()105( +== ETT
Tmax = 117.4 kNNotes : Since the arch is a parabola, there are noshear and bending moment, only ND is present
Alternate Method
33
Example 5-7
The three-hinged tied arch is subjected to the loading shown in the figure below.Determine the force in members CH and CB. The dashed member GF of the trussis intended to carry no force.
E
15 kN20 kN
15 kN
A
BC
D
FG
H
3 m 3 m 3 m 3 m
4 m
1 m
34
E
15 kN20 kN
15 kN
AB
CD
FG
H
3 m 3 m 3 m 3 m
4 m
1 m
SOLUTION
+ ΣMA = 0:
ΣFy = 0:+
ΣFx = 0:+
025152015 =+−−−yA
0)9(15)6(20)3(15)12( =−−−yE
Ax
Ay Ey
Ax = 0
Ay = 25 kN
Ey = 25 kN
35
15 kN20 kN
AB
C
GH
3 m 3 m
5 m0
25 kN
+ ΣMC = 0:
ΣFy = 0:+
ΣFx = 0:+
0201525 =+−− yC
0)3(15)6(25)5( =+−AEF
0Cx
Cy
FAE
-Cx + 21= 0Cx = 21.0 kN
Cy = 10 kN
FAE = 21.0 kN
36
ΣFy = 0:+
ΣFx = 0:+
020 =−GCF
FGC = 20 kN (C)
FHG = 0
20 kN
0
FGC
FHG G
Joint G :
ΣFy = 0:+
ΣFx = 0:+
FCH = 4.75 kN (T),
Joint C :
20 kN
21 kN
10 kNFCB
C18.43o
18.43o
FCH
-FCH cos18.43 - FCB cos18.43 - 21= 0
FCH sin18.43 - FCB cos18.43 - 20 + 10 = 0
FCB = -26.88 kN (C)
Thus,
37
Archescrownextrados
(or back)
Intrados(or soffit)
huanch
centerline rise
abutment
springline
fixed arch two-hinged arch
three-hinged archtied arch
38
P1
A
C
P2
B
C
Three-Hinged ArchP1
P2
AB
C
Bx
By
Cx
Cy
Ax
Ay
Cx
Cy
D
NDMD
VDAx
Ay
D
39
Example 5-8
The tied three-hinged arch is subjected to the loading shown. Determine thecomponents of reaction at A and C and the tension in the cable.
10 kN
15 kN B
A
C
0.5 m 1 m
2 m 2 m
D
2 m
40
SOLUTION
10 kN
15 kN B
A
C
0.5 m 1 m
2 m 2 m
D
2 m
Cy
Ax
Ay
Entire arch :
+ ΣMA = 0: 0)5.0(15)5.4(10)5.5( =−−yC
Cy = 9.545 kN
ΣFy = 0:+ 0545.91015 =+−−yA
Ay = 15.46 kN
0
41
TD
10 kN
C
1 m
2 m
D
BBx
By
Cy = 9.545 kN
15 kN B
A
0.5 m
2 m
2 m
Bx
By
TA
Ay = 15.46 kN
Member AB :
+ ΣMB = 0: 0)2()5.2(455.15)2(15 =+− AT TA = 4.319 kN
ΣFy = 0:+ 015455.15 =−− yB By = 0.455 kN
ΣFx = 0:+ 0319.4 =− xB Bx = 4.319 kN
Member AB :
ΣFx = 0:+ 0319.4 =− DT TD = 4.319 kN