Castigliano’s Method
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Elastic Deflection Castigliano’s Method If deflection is not covered by simple cases in Table 5.1 (p186) Stored Elastic Energy U Complementary Energy U’ 2 Q ∆ U U ' ⋅ = = dQ ∆ U dU ' ⋅ = = d Incremental: dQ dU ∆ = Deflection: Castiglino’s Theorem: When a body is elastically deflected by any combination of loads, the deflection at any point and in any direction is equal to the partial derivative of strain energy (computed with all loads acting) with respect to a load located at that point and acting in that direction Q U ∆ ∂ ∂ =
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Transcript of Castigliano’s Method
Elastic DeflectionCastigliano’s Method
If deflection is not covered by simple cases in Table 5.1 (p186)
Stored Elastic Energy
U
Complementary Energy U’
2Q∆UU ' ⋅==dQ∆UdU ' ⋅== dIncremental:
dQdU∆ =Deflection:
Castiglino’s Theorem:
When a body is elastically deflected by any combination of loads, the deflection at any point and in any direction is equal to the partial derivative of strain energy (computed with all loads acting) with respect to a load located at that point and acting in that direction
QU∆ ∂∂=
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Texto
http://www.egr.msu.edu/classes/me471/thompson/
Elastic DeflectionCastigliano’s Method
Table 5.3 (p193): Energy and Deflection Equations
Example: Axial TensionStored Elastic Energy:
Case 1 from Table 5.1:
gives:
For varying E and A:
A1
Texto
http://www.egr.msu.edu/classes/me471/thompson/
Elastic DeflectionCastigliano’s Method
(1) Obtain expression for all components of energyTable 5.3
(2) Take partial derivative to obtain deflection
QU∆ ∂∂=Castiglino’s Theorem:
Table 5.3 (p193): Energy and Deflection Equations
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Texto
http://www.egr.msu.edu/classes/me471/thompson/
Elastic Deflection: Castigliano’s Method
Table 5.3
Here 2 types of loading: Bending and Shear
magnitude @ x:
1. Energy: here it has two components:
first compute Energy, then Partial Derivative to get deflection
2. Partial Derivatives for deflection:(23=8)*3*4 = 96
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Texto
http://www.egr.msu.edu/classes/me471/thompson/
Table 5.3
Elastic Deflection: Castigliano’s Method
TWO METHODS
Differentiate after Integral Differentiate under Integral
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Texto
http://www.egr.msu.edu/classes/me471/thompson/
Elastic Deflection: Castigliano’s Method
Transverse shear contributes only <5% to deflection
m
m
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Texto
http://www.egr.msu.edu/classes/me471/thompson/
Elastic Deflection: Castigliano’s Method
Use of “Dummy Load” Q=0
•90° bend cantilever beam•shear neglected
•Shear neglected => only 4 energy components:
1) BENDING portion a_b: Mab=Py2) BENDING portion b_c: Mbc=Qx +Ph
3) TENSION portion a_b: Q4) COMPRESSION portion b_c: P
(Tension and Compression mostly negligible if torsion and bending are present)
:
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Texto
http://www.egr.msu.edu/classes/me471/thompson/
Elastic Deflection: Castigliano’s Method
•Eccentrically Load Column•No Buckling
Redundant Support
500kg x 9.8m/s2
=4900 N
•Now Deflection known (δ=0) •Find necessary Tension Force F
Guy wire
•Hence partial derivative of total elastic energy with respect to F must be zero
•Omit zero derivatives- all energy terms above a- compression term below a
•Only bending term is left: M= (4900 N)(1.2m)-Fy = 5880 Nm - Fy
=! 0 finite value F=2940 N
(Nm)2 m Nm3 m3
(Nm)2 Nm
Nm3 m3
A1
Texto
http://www.egr.msu.edu/classes/me471/thompson/
