Statically Determinate Structures
Transcript of Statically Determinate Structures
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Analysis of Statically Determinate Structures
Classification of structures for stability and redundancy.
Definition of support conditions.
A roller support has one unknown, a hinged support two unknowns and a fixed support three unknowns.
Mono-planar structures are divided into three groups, namely trusses, frames and a combination of the two.
Trusses: One assumes that the members are hinged at the ends and can thus only take axial forces in thedirection of the line that joins the two hinges. These are called bar-hinged members. Any force that has acomponent vertical to that direction will cause the member to rotate. The members are connected to eachother at nodes. As the whole structure is in equilibrium, every part of the structure must be in equilibrium andthus every node is in equilibrium.
Let us call the number of reaction components, r, and the number of bar hinged members, m, and thenumber of nodes, n.
We know that the unknowns are the reactions (support forces) and the forces in the members. Total numberof unknowns = r + m
Every node is in vertical and horizontal equilibrium and therefore we have two equations at every node,
namely Y = 0 and X = 0. Number of equations = 2 n.
If: r + m > 2 n we have more unknowns than possible equations so the truss is statically indeterminate.If: r + m = 2 n we have as many unknowns as possible equations so the truss is statically determinate.If: r + m < 2 n we have more equations than unknowns so the truss is statically unstable.
Example 1:
The following roof structure is used for a factory building. The trusses are spaced at 4 m spacing and thepurlin are spaced at 1,8 m. The roof covering is of galvanized sheeting with a mass of 10 kg/m
2. There is an
external imposed load of 0,3 kN/m2
to allow for servicing, rain, hail etc. Assume the trusses and purlin tohave a self-weight of 18 kg/m
2. Determine:
a) The point loads at each of the nodesb) The reactionsc) The forces in the members AB, AF, BF, FC, FG and GH
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Definition of sin and cos .
Length
projectionY =sin
Length
projectionX =cos
Equilibrium of Forces
For equilibrium we can write the following:
0= Y
0= X
0= M
This allows us to solve 3 unknowns and only 3.
Solution to Questions:
a) Load from the sheeting:
A one metre length when seen vertically from the top has a length of 1/cos which in this case is equal to1/cos 20 = 1,064 m. The load is then equal 10 kg/m
2x gravity acceleration x 1,064 m. Assume gravity
acceleration to be = 10 m/s2. The load in when seen vertically from the top = 106,4 N/m
2= 0,1064 kN/m
2.
Total vertical load =Sheeting 0,106 kN/m
2
Trusses 0,180 kN/m2
Additional imposed 0,300 kN/m2
Total 0,586 kN/m2
Load at each node = load intensity times the area carried by the node= 0,586 kN/m
2x 4 m x 1,8 m
= 4,22 kN
b) Reactions as a result of the symmetrical structure and loading are equal to 4 x 4,22 kN
Reactions = 16,88 kN
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Member X-projection, x Y- projection, y Length
AB 1,800 0,655 1,9155
AF 2,038 0 2,038
BF 0,238 0,655 0,6969
BC 1,800 0,655 1,9155
FC 1,562 1,310 2,0386
FG 2,038 0 2,038
GH 6,248 0 6,248
For node AAssume that all members are in tension
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= 0Y 011,288,16 =+++ AFAB YY
0sinsin11,288,16 =+++ AFAB FF
011,288,16 =
+
++Length
projectionYF
Length
projectionYF AFAB
0038,1
0
9155,1
655,011,288,16 =+++ AFAB FF
+ 14,77 + 0,34195 FAB = 0FAB = - 43,194 kN
= 0X
0=+ AFAB XX
0=+AFAFAF
ABABAB
L
xXL
xF
0038,2
038,2
9155,1
800,1194,43 =+ AFX
FAF = + 40,590 kN
Equilibrium of node B
= 0Y 022,4 =+ BFBCBA YYY
022,4 =+BF
BFBF
BC
BCBC
BA
BABA
L
yF
L
yF
L
yF
0
6969,0
655,0
9155,1
655,0
9155,1
655,0194,4322,4 =++ BFBC FF
0,34195 FBC 0,93988 FBF = - 10,550 (1)
= 0X 0=++ BFBCBA XXX
06969,0
238,0
9155,1
80,1194,43
9155,1
80,1=++ BFBC FF
0,9397 FBC + 0,3415 FBF = - 40,5895 (2)
FBC = - 41,753 KNFBF = - 3,968 kN
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Alternative method is to use the moment equilibrium of a portion of the structure. This enables us to solvethree unknown forces. It is usual to choose a section where two of the forces cut in a point so that theirmoment is equal to zero, thereby we can solve one of the unknowns immediately.
= 0CM 16,88 x 3,6 2,11 x 3,6 4,22 x 1,8 FFG x 1,310 = 0FFG= 34,791 kN
= 0Y 022,411,288,16 =++ FCBC YY
0036,2
310,1
9155,1
655,055,10 =++ FCBC FF
0,34195 FBC + 0,64342 FFC = - 10,55 (3)
= 0X 0=++ FGFCBC XXX
0791,34038,2
038,2
036,2
562,1
9155,1
8,1=++ FCBC FF
0,9397 FBC + 0,76719 FFC = - 34,791 (4)
FBC = - 41,753 kNFFC = 5,793 kN
Parallel Chord Trusses
Parallel chord trusses may be treated in the same way as beams. The top andbottom chords resist the bending moment and the diagonal and vertical membersresist the shear forces.
Examples of parallel chord trusses
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The second truss must have a very small slope otherwise one underestimates the forces in the top andbottom chords.
Example:
Determine the member forces in the following trusses. The roof sheeting has a unit mass of 12 kg/m2, the
ceiling 15 kg/m2, the trusses 15 kg/m
2and there is a live load of 0,4 kN/m
2. The loads are to be increased
with load factors of 1,2 on the permanent (dead load) and 1,6 on the imposed (live load).
The dead load is equal to:
Roof sheeting: 12 kg/m2
x 10 m/s2
= 120 N/m2
= 0,12 kN/m2
Ceiling: 15 kg/m2
x 10 m/s2
= 150 N/m2
= 0,15 kN/m2
Trusses and purlin 15 kg/m2
x 10 m/s2
= 150 N/m2
= 0,15 kN/m2
Total dead load = 0,42 kN/m2
Total live load = 0,40 kN/m2
Factored Load 1,2 x DL + 1,6 x LL = 1,2 x 0,42 + 1,6 x 0,40 = 1,144 kN/m2
Load at each node intensity x tributary area = 1,144 x 2 x 3,5 = 8,008 kN
Draw the Shear force and bending moment diagrammes:
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Solve the forces in the members through using sections.
Section 1:
In the panel between A and C the vertical shear force of 17,333 kN must be carried by the diagonal memberBC. Therefore:
YBC = 17,333 kN kNFL
yBC
BC
BC 333,17= kNFBC 684,332,1
332,2333,17 ==
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The bending moment from the external forces must be in equilibrium with theinternal forces in the top and bottom members. The bending moment from theexternal forces is shown in the bending moment diagramme.
Take moments about C.
FBD x 1,2 + 34,666 = 0
kNFBD 888,282,1
666,34=
=
All the sections may be tackled in a similar fashion.
Section 2:
To solve for the force in member CE take moments about D.
- FCE x 1,2 + 34,666 = 0 FCE = + 28,888 kN
The vertical force in member CD must be equal to the vertical component of theforce in BC. The vertical component of the force in BC is equal to the shear betweenA and C. FCD = 17,333 kN.
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Frames: One assumes that the members are connected rigidly and can thus transfer axial force, shear forceand moment. These are called beam members and each beam has three unknown forces. The members areconnected to each other at nodes. As the whole structure is in equilibrium, every part of the structure mustbe in equilibrium and thus every node is in equilibrium, i.e. forces in X direction, forces in Y direction andmoments.
Let us call the number of reaction components, r, and the number of beam members, m, and the number ofnodes, n.
We know that the unknowns are the reactions (support forces) and the forces in the members. Total numberof unknowns = r + 3 m
Every node is in vertical, horizontal and moment equilibrium and therefore we have three equations at every
node, namely Y = 0, X = 0 and M = 0. Number of equations = 3 n.
If: r + 3 m > 3 n we have more unknowns than possible equations so the truss is statically indeterminate.If: r + 3 m = 3 n we have as many unknowns as possible equations so the truss is statically determinate.If: r + 3 m < 3 n we have more equations than unknowns so the truss is statically unstable.
We could also have additional equations, called, t, where for instance the end of a member is not rigidlyconnected to another member. These then reduce the number of unknowns or increase the number ofequations.
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In the above structure, the three equations for the equilibrium of node B are:XBA + XBC + XBD = 0 (1)YBA + YBC + YBD = 0 (2)MBA + MBC + MBD = 0 (3)
The additional equation in this case would be MBD = 0.
In this case the additional equations would be MBA = 0 and MBC = 0 and from equation (3) above MBD is equalto 0. There are thus only 2 additional equations and not 3.
It is thus possible to combine truss elements and beam elements and still determine the degree ofredundancy of the structure.
Three-pinned Portal Frame Analysis
Determine the bending moment diagramme of the following structure.
Plywood unit weight = 7 kN/m3
Portal unit weight = 7 kN/m3
Tiles have a mass of 55 kg/m
2
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Purlin have a unit weight of 5 N/m3
Imposed or live load = 0,3 kN/m2
We would like to convert these loads into a uniformly distributed load on the portal frame. Remember that the
tiles, plywood and the portal itself are at an angle of 20,556. We would like to have the loading horizontal.
Dead Loads
Tiles = 55 x 10 /1000 = 0,55 kN/m2
on the slope = 0,55/cos 20,556 = 0,587 kN/m2
horizontalPlywood = 0,022 x 7 = 0,154 kN/m
2on slope = 0,154/cos 20,556 = 0,164 kN/m
2
Portal = 0,1 x 0,5 x 7 = 0,350 kN/m on the slope = 0,35/cos 20,556 = 0,374 kN/m
Purlin = 0,075 x 0,225 x 5 = 0,084 kN/m length of purlin
Tributary length = the spacing of the portals = 4 m.
Total dead load: Tiles = 0,587 x 4 = 2,348 kN/mPlywood = 0,164 x 4 = 0,656 kN/mPortal = 0,374 = 0,374 kN/mPurlin = 0,084 x 4 / 1,1= 0,305 kN/m
Total = 3,683 kN/m
Live load Imposed = 0,3 x 4 = 1,2 kN/m
Factored Loads 1,2 x DL + 1,6 x LL1,2 x 3,683 + 1,6 x 1,2 = 6,340 kN/m
Line sketch of portal frame:
= 0AM 0162
1634,6
2
= EY
YE = 50,72 kN
In a similar fashionYA = 50,72 kN
= 0CM 02
834,678
2
= AA XY
02
834,67872,50
2
= AX
XA = 28,983 kN
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Additional Statically Determinate Structures
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The following is an extract from ELEMENTARY STRUCTURAL ANALYSIS, NORRIS& WILBUR
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Virtual Work Used to Calculate Deflection of Trusses.
Example 1:
The following timber truss has loads as shown. The sections have an area of 2700 mm2 and a modulus ofelasticity, E = 7800 MPa. Determine the vertical deflection of the node G and of the node F.
Solution to the forces in the members.
Member L P0 pv P0pvLAB 2,207 -7,238 -1,183 18,898
BC 2,207 -4,825 -1,183 12,598
CD 2,207 -4,825 -1,183 12,598
DE 2,207 -7,238 -1,183 18,898
AH 2,000 +6,559 +1,072 14,062
HG 2,000 +6,559 +1,072 14,062
GF 2,000 +6,559 +1,072 14,062
FE 2,000 +6,559 +1,072 14,062
BH 0,933 0 0 0
DF 0,933 0 0 0
CG 1,866 +2,040 +1,000 3,807
BG 2,207 -2,413 0 0GD 2,207 -2,413 0 0
P0pvL (kN.m) 123,047
External virtual work = internal virtual work
1,0 x =
EA
LpP v0
= mmx
x
78002700
10047,123 6= 5,84 mm
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For the deflection at F:
Member L P0 pv P0pvL
AB 2,207 -7,238 -0,591 9,441
BC 2,207 -4,825 -0,591 6,293
CD 2,207 -4,825 -0,591 6,293
DE 2,207 -7,238 -1,774 28,338
AH 2,000 +6,559 +0,536 7,031
HG 2,000 +6,559 +0,536 7,031
GF 2,000 +6,559 +1,608 21,094
FE 2,000 +6,559 +1,608 21,094
BH 0,933 0 0 0
DF 0,933 0 +1,000 0
CG 1,866 +2,040 +0,500 1,903
BG 2,207 -2,413 0 0
GD 2,207 -2,413 -1,183 6,300
P0pvL (kN.m) 114,818
External virtual work = internal virtual work
1,0 x =
EA
LpP v0
= mmx
x
78002700
10818,114 6= 5,45 mm
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Virtual work applied to bending members:
Example 1:
Determine the deflection in the middle of the following beam.
External Virtual work = Internal virtual work
1,0 x = dsIE
mML v
0
0
= dsIE
mML v
20
02
22
2
0xwxLw
M
= xmv = 5,0
1,0 x = dxIE
xwxLwL
20
32
22
=2
0
43
86
1L
xwxLw
EI
=
12848
1 44 LwLw
EI
=
EI
Lw 4
384
5
Instead of integrating the bending moment equations one can use standard integration equations.
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Apply the table to the previous problem:
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[ ]0 1 2 20
2 26
L
vM m hds a a c EI
= +
h =2
La1 =
4
La2 =
8
2Lwc2 =
32
3 2Lw
= +
2 2
0
0
32 212 4 8 32
L
vM m L L w L w LdsEI
IE
Lw
=
4
384
51
Example 2:
Determine the deflection in the middle of the following beam. E = 200 GPa and I = 43,60 x 10-6
m4:
External Virtual work = Internal virtual work
EI * 1,0 x = dsmML
v 0 0
= 213
aah
+ [ ]21122121 226
bbbabaaah
+++ + [ ]21122121 226
bbbabaaah
+++ + 213
aah
= 505,13
3 + [ ]4525,2225,250455,1505,12
6
5,1+++
+ [ ]405,125,1454025,24525,226
5,1+++ + 405,1
3
3
= 388,125 kN.m
=EI
125,388 =66 1060,4310200
125,388 xx
= 0,0445 m = 44,5 mm
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