indeterminate analysis force methodgebland/ce 382/ce 382 pdf lecture slides/ce 38… · of...
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Indeterminate AnalysisForce Method1
• The force (flexibility) method expresses the relationships between displacements and forces that exist in a structure.
• Primary objective of the force method is to determine the chosen set of excess unknown forces and/or couples –redundants.
• The number of redundants is equal to the degree of static indeterminacy of the structure.
1Also see pages 115 – 141 in your class notes.
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Description of the Force Method Procedure
1. Determine the degree of static indeterminacy.
Number of releases* equal to the degree of static indeterminacy are applied to the structure.
Released structure is referred to as the primary structure.
Primary structure must be chosen such that it is geometrically stable and statically determinate.
Redundant forces should be carefully chosen so that the primary structure is easy to analyze
* Details on releases are given later in these notes.
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Force Method – con’t
2. Calculate “errors” (displacements) at the primary structure redundants. These displacements are calculated using the method of virtual forces.
3. Determine displacements in the primary structure due to unit values of redundants (method of virtual forces). These displacements are required at the same location and in the same direction as the displacement errors determined in step 2.
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Force Method – con’t
4. Calculate redundant forces to eliminate displacement errors.
Use superposition equations in which the effects of the separate redundants are added to the displacements of the released structure.
Displacement superposition results in a set of n linear equations (n = number of releases) that express the fact that there is zero relative displacement at each release.
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Force Method – con’t These compatibility equations
guarantee a final displaced shape consistent with known support conditions, i.e., the structure fits together at the n releases with no relative displacements.
5. Hence, we find the forces on the original indeterminate structure. They are the sum of the correction forces (redundants) and forces on the released structure.
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Flexibility Analysis
R1R2
(1)
=
1 (R1)
1 (R2)
+
+
f21 (x R1)f11 (x R1)
f12 (x R2)
f22 (x R2)
D1D2
(2)
(3)
(3)
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11 1 12 2 1
21 1 22 2 2
(4f R f R D 0
f R f 0)
R D
+ + =
+ + =
Solve for R1 and R2.
Using matrix methods:
[F] {R} = -{D}
⇒ {R} = -[F]-1 {D}
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[F] = 11 12
21 22
f ff f
≡ flexibilitymatrix
[F]-1 (≡ inverse flexibility matrix)
22 12
21 1111 22 12 21
f f1f ff f f f
− = −−
1
2
D{D}
D
=
≡ primarystructuredisplacementvector
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det [F] =
(5)
With R1 and R2 known, remaining structure is statically determinate.
1
2
R{R}
R
=
≡ redundantforcevector
1 22 1 12 2
2 21 1 11 2
R f D f D1R f D f Ddet[F]
− −= − +
11 22 12 21f f f f−
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Releases
Release is a break in the continuity of the elastic (displacement) curve.
One release only breaks a single type of continuity.
Figure 1 shows several types of releases.
Common release is the support reaction, particularly for continuous beams.
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Flexibility Equations Primary structure displacements at the releases are related to the unknown redundant forces via
i ij jD f R− = (1)
displacement at release i due to a unit force in the direction of and at release j; flexibility coefficients.
ijf ≡
Equation 1 for the case of three redundant forces is expressed as
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1 11 1 12 2 13 3
2 21 1 22 2 23 3
3 31 1 32 2 33 3
D f R f R f RD f R f R f RD f R f R f R
− = + +
− = + +
− = + +
(2a)
Matrix form of (2a)
-{D} = [F] {R}
{D} = = <D1 D2 D3>T
= displacement vector at theredundant degrees of freedom
(2b)
1
2
3
DDD
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{R} = = <R1 R2 R3>T
= redundant force vector
11 12 13
21 22 23
31 32 33
f f ff f ff f f
[F] =
= flexibility matrix
1
2
3
RRR
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Displacement Calculations –Method of Virtual Forces
i Vi ViD F d M d= + φ∫ ∫
subscript i direction of Ri atrelease i
⇒
d = differential axial displacement
dφ = differential rotational displ
(3)
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Flexibility Coefficients –Method of Virtual Forces
a bij ij ijf f f= + (4)
Vjaij Vi
Ff F dx
EA(x)= ∫≡ axial deformation influence
coefficient
Vjbij Vi
Mf M dx
EI(x)= ∫≡ bending deformation
influence coefficient
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Force Method Examples
1. Calculate the support reactions for the two-span continuous beam, EI = constant. w
L L
w
1 (x R1)
Primary Structure w/ Load
=
+
Primary Structure w/ Redundant
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2. Calculate the support reactions for the two-span continuous beam, EI = constant.
w
L L
w
R2
Primary Structure w/ Load
=
+
R1
Primary Structure w/ Redundant Forces
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Prismatic Member Displacements
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3. Calculate the support reactions for the two-span continuous beam using the internal moment at B as the redundant force, IAB = 2I and IBC = I; E = constant.
Primary Structure w/ Loading
PL2
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Primary Structure w/ Redundant
MB
DB = __________________
fBB = _________________
MB = _________________
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4. Calculate the bar forces for the statically indeterminate truss.
Statically Indeterminate
Truss
Statically Determinate
Released Truss(Redundant X)
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Nonmechanical Loading
[F]{R} ({D} {D })∆= − + (5)
T2 n1{D } D D D∆∆ ∆ ∆= < >
= relative dimensional change displacements calculated using principle of virtual forces
Displacements due to dimension changes are all relative displace-ments, as are all displacements corresponding to releases. They are positive when they are in the same vector direction as the corres-ponding release (redundant).
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Structure Forces
Once the redundant forces arecalculated from Eq. (5), all othersupport reactions and internalmember forces can be calculatedusing static equilibrium along withthe appropriate free body diagrams.
This is possible since the forcemethod of analysis has been used todetermine the redundant forces orthe forces in excess of thoserequired for static determinacy.
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Mathematical Expressions
piA
Calculation of the non-redundant forces Ai (support reactions, internal shears and moments, truss member forces) can be expressed using superposition as
RNp
i ui j jij 1
A A (A ) R=
= + ∑where = desired action Ai on the primary structure due to the applied loading; = action Ai on the primary structure due to a unit virtual force at redundant Rj and NR = number of redundants.
ui j(A )
(6)
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Example Beam Problem –Nonmechanical Loading
E = 30,000 ksiI = 288 in4
(a) Given structure
(b) Primary structure
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The interesting point of this example is that the flexibility equation will have a nonzero right hand side since the redundant displacement is prescribed to equal 0.72” downward. Thus the flexibility equation is
fBB RB = dB - (7)
wheredB = prescribed displacement
at redundant B= -0.72" since RB is
positive upward= -0.24"
relative displacementat redundant B
BD∆
BD∆
B Bd D∆− =
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Truss Example –Nonmechanical Loading
For the truss structure on the next page, compute the redundant bar EC member force if the temperature in bar EF is increased 50 oF and member BF is fabricated 0.3 in. too short. EA = constant = 60,000 kips and
= 6x10-6 /oF.α
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Truss Example
C
D
E F
A
B
15’
3 @ 20’ = 60’
A 1
B C
D
E F
Primary Structure Subjectedto FCE = 1
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Mem L FV FV FVL
AB 240" 0 0
AE 300" 0 0
BC 240" -4/5 153.6
BE 180" -3/5 64.8
BF 300" 1 300
CD 240" 0 0
CE 300" 1 300
CF 180" -3/5 64.8
DF 300" 0 0
EF 240" -4/5 153.6
Truss Example Calculations
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mCE,CE Vi Vi i
i 1
1f F F LEA =
= ∑
mCE Vi i
i 1D F∆ ∆
== δ∑
CE,CE CE CEf F D 0∆+ =
EF EF EF
BF BF
T L 0.072"
0.3"
∆
∆
δ = α∆ =
δ = ∆ = −
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Displacements for the staticallyindeterminate structure can becalculated using the exact memberdeformations for a truss or exactshear and moment expressionsalong with the virtual force expres-sions on the primary structure.
For a truss structure, calculation of a joint displacement using theprinciple of virtual forces results in
Displacement Calculations
∆
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m
Vi i
i 1
F ∆
=
δ + ∆∑1 (∆) =
minti i
Vi ii
i 1
F LFEA
∆
=
+ δ + ∆
∑=
ViF = primary structure member forces due to the application of a unit virtual force at the joint for which the displacement is desired and in the direction of
(8)
∆
∆
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∆∆ = primary structure displace-ment at desired displacement due to nonmechanical effects
iδ = exact member displacements that are obtained for the sta-tically indeterminate structure using the calculated redundant forces to determine all the member forces within the truss structure
intiδ = member displacements due
to nonmechanical loading on the member
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For a frame structure, in which shear and axial deformations are ignored, the displacements are calculated as
1( )∆ =Lm
intiVi i
ii 1 0
MM dxEI
∆
=
+κ
∑ ∫(9a)
1( )θ =
Lminti
Vi ii
i 1 0
MM dxEI
θ
=
+ κ
∑ ∫(9b)
∆+ ∆
∆+ θ
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Vi ViM , M∆ θ = primary structure virtual moments based on the desired displacement ∆ or rotation θ
,∆ ∆∆ θ = primary structure displace-ments at ∆ or rotation θ due to environmental loads or causes
intiκ = primary structure initial
curvature strain caused by nonmechanical loading
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In Eqs. (9a) and (9b) the moment expressions are exact based on the statically indeterminate structure subjected to the external loads with the redundant forces known from the flexibility analysis.
Equations (8), (9a), and (9b) are cor-rect only because exact real member forces are used in the calculation of the desired displacements.
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Calculate the horizontal displace-ment at joint B for the statically indeterminate truss.
40 k
A B
CD
R1
CD
BA 1
Primary Structure Subjected to Virtual Loading
12’
16’
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Calculate the rotation at the center support for the two-span continuous beam, EI = constant.
w
L L
Primary Structure w/ Virtual Load at Desired Displacement
Location
L L
1R1 R2
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Alternatively, you can express the desired displacement calculations also in matrix form following the usual superposition process of the force method of analysis:
(10)
where {δ} = vector of desired displacements; = vector of desired displacements for the primary structure for both mechanical and non-mechanical loadings, respectively; [Fδ] =
{D }, {D }∆δ δ
{ } [F ]{R} {D } {D }∆δ δ δδ = + +
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matrix of displacement influence coefficients at the desired displacement locations due to unit values of the redundant forces {R}. Stated mathematically, the coefficients of [Fδ] are
(11)
which simply states that the dis-placement influence coefficients equal the displacement at desired displacement i on the primary structure due to a unit force at redundant j on the primary structure.
jij i R 1Fδ == δ