Professor Terje Haukaas University of British Columbia, Vancouver www.inrisk.ubc.ca
2D Elastic Beams Updated February 21, 2014 Page 1
2D Elastic Beams In other documents on this website, the Euler-Bernoulli and Timoshenko beam theories are described. Both those theories are based on the assumption that “plane sections remain plane.” That is not an exact description of reality and this document describes an alternative, based on the 2D theory of elasticity. In particular, a cantilevered beam in the x-z-plane is considered in the following, as shown in Figure 1. In another document on 2D elasticity theory, the 4th-order differential equation for the stress function is derived. Written in terms of x and z it reads
∂4 F∂x4 + ∂4 F
∂z4 + ∂4 F∂x2 ∂z2 = 0 (1)
Figure 1: Beam on elastic foundation.
The solution for specific problems is established by formulating a stress function that satisfies the unique boundary conditions for each problem. As a demonstration, the cantilever in Figure 1 is considered in this section. To simplify the mathematical expressions, the fixed support is on the right-hand side and the load is applied on the left-hand side. A solution for this problem, where the horizontal edges are stress-free and the edge at x=0 has a shear stress resultant P, is obtained by combining the stress function for pure shear and a stress function with a 3rd-order term (Timoshenko and Goodier 1969):
F(x, z) = C1 ⋅ x ⋅ z +C2 ⋅ x ⋅ z3 (2)
This stress function yields the following stresses:
σ xx =
∂2 F∂z2 = 6 ⋅C2 ⋅ x ⋅ z (3)
σ zz =
∂2 F∂x2 = 0 (4)
x
z
P
L
h
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2D Elastic Beams Updated February 21, 2014 Page 2
τ xz = − ∂2 F
∂x∂z= −C1 − 3⋅C2 ⋅ z
2 (5)
Zero stress on the horizontal edges implies that
τ xz (z = ± h
2 ) = −C1 − 3⋅C2 ⋅h2
⎛⎝⎜
⎞⎠⎟
2
= 0 ⇒ C2 = − 43h2 ⋅C1 (6)
Shear stress resultant P at x=0 implies that
τ xz (x = 0)dz− h
2
h2
∫ = −C1 − 3⋅C2 ⋅ z2 dz
− h2
h2
∫ = − 2h3
C1 = −P ⇒ C1 =3P2h
(7)
which implies that
C2 = − 4
3⋅h2 ⋅3P2h
= − 2Ph3 (8)
Substitution of C1 and C2 into Eq. (3) yields the axial stress
σ xx = 6 ⋅C2 ⋅ x ⋅ z = −12P
h3 ⋅ x ⋅ z = − PI⋅ x ⋅ z (9)
where I=h3/12 is introduced for this unit-width beam to echo the notation in elementary beam theory. In fact, the axial stress is distributed exactly as in elementary beam theory. Substitution of C1 and C2 into Eq. (5) yields the shear stress
τ xz = −C1 − 3⋅C2 ⋅ z
2 = − 3P2h
+ 6Ph3 z2 = − 3P
2h1− 2z
h⎛⎝⎜
⎞⎠⎟
2⎛
⎝⎜
⎞
⎠⎟ (10)
where it is observed again that the solution is exactly as in the elementary beam theory, assuming that the load P is applied on the edge distributed according to the parabola in Eq. (10). However, more information is available from this elasticity solution than beam theory. In particular, displacements can be calculated, and these reveal that plane sections do not remain plane during bending. To see this, i.e., to compute the displacements associated with the stresses above, the general kinematics equations are invoked, which read
ε xx =
∂u∂x
(11)
ε zz =
∂w∂z
(12)
γ xz =
∂u∂z
+ ∂w∂x
(13)
The material law is also needed, which for plane stress (thin beam in the y-direction) read
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2D Elastic Beams Updated February 21, 2014 Page 3
ε xx =
1E⋅ σ xx −ν ⋅σ zz( ) (14)
ε zz =
1E⋅ σ zz −ν ⋅σ xx( ) (15)
γ xz =
τ xz
G (16)
where G=E(2(1+ν)) is the shear modulus. The material law for plane strain (infinitely thick beam in the y-direction) is obtained by replacing E by E/(1–ν2) and ν by ν/(1–ν) (Timoshenko and Goodier 1969), which yields
ε xx =
1E⋅ (1−ν 2 ) ⋅σ xx −ν ⋅(1+ν ) ⋅σ zz( ) (17)
ε zz =
1E⋅ (1−ν 2 ) ⋅σ zz −ν ⋅(1+ν ) ⋅σ xx( ) (18)
γ xz =
τ xz
G (19)
For the plane stress case, the combination of the kinematics equations (11) to (13) with the material law equations (14) to (16), and substitution of stresses from Eqs. (9) and (10) together with σzz=0 yields
ε xx =
∂u∂x
= 1E⋅ σ xx −ν ⋅σ zz( ) = σ xx
E= − P
EI⋅ x ⋅ z (20)
ε zz =
∂w∂z
= 1E⋅ σ zz −ν ⋅σ xx( ) = − 1
E⋅ν ⋅σ xx =
PEI
⋅ν ⋅ x ⋅ z (21)
γ xz =
∂u∂z
+ ∂w∂x
=τ xz
G= − 3P
2Gh1− 2z
h⎛⎝⎜
⎞⎠⎟
2⎛
⎝⎜
⎞
⎠⎟ (22)
Integration of Eqs. (20) and (21) yields the general displacement expressions
u(x, z) = − P
EI⋅ x ⋅ z dx∫ = − Pzx2
2EI+ hz (z) (23)
w(x, z) = P
EI⋅ν ⋅ x ⋅ z dz∫ = Pνxz2
2EI+ hx (x) (24)
where hx(x) and hz(z) are functions that represent the integration constants. Substitution of Eqs. (23) and (24) into Eq. (22) yields
∂u∂z
+ ∂w∂x
= − Px2
2EI+∂hz (z)∂z
+ Pν z2
2EI+∂hx (x)∂x
= − 3P2Gh
1− 2zh
⎛⎝⎜
⎞⎠⎟
2⎛
⎝⎜
⎞
⎠⎟ (25)
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2D Elastic Beams Updated February 21, 2014 Page 4
By separating terms that depend on x and z, the following reorganized equation is obtained:
− Px2
2EI+∂hx (x)∂x
F ( x )! "## $##
+ Pν z2
2EI+∂hz (z)∂z
− 6Pz2
Gh3
G( z )! "### $###
= − 3P2Gh
K!"$
(26)
where F(x), G(z), and K are defined so that Eq. (25) can be written (Timoshenko and Goodier 1969) F(x)+G(z) = K (27)
Because the right-hand side is constant, F(x) and G(z) must also be constants, here named C3 and C4:
F(x) = − Px2
2EI+∂hx (x)∂x
= C3 ⇒ ∂hx (x)∂x
= Px2
2EI+C3 (28)
G(z) = Pν z2
2EI+∂hz (z)∂z
− 6Pz2
Gh3 = C4 ⇒ ∂hz (z)∂z
= 6Pz2
Gh3 − Pν z2
2EI+C4 (29)
Integration yields hx(x) and hz(z) expressed in terms of unknown constants:
hx (x) = Px2
2EI+C3
⎛⎝⎜
⎞⎠⎟
dx∫ = Px3
6EI+C3x +C5 (30)
hz (z) = 6Pz2
Gh3 − Pν z2
2EI+C4
⎛⎝⎜
⎞⎠⎟
dz∫ = 2Pz3
Gh3 − Pν z3
6EI+C4z +C6 (31)
Substitution of the functions hx(x) and hz(z) in Eqs. (30) and (31) into the displacements in Eqs. (23) and (24) yields
u(x, z) = − Pzx2
2EI+ 2Pz3
Gh3 − Pν z3
6EI+C4z +C6 (32)
w(x, z) = Pνxz2
2EI+ Px3
6EI+C3x +C5 (33)
The constants C3, C4, C5, and C6 are determined from Eq. (27), which says that
C3 +C4 = − 3P
2Gh (34)
and from three boundary conditions that prevent the beam from displacing as a rigid body. For the beam in Figure 1, it is natural to enforce zero displacements and zero rotation at the point where x=L and z=0. According to Eqs. (32) and (33), zero displacement implies that
u(L,0) = C6 = 0 (35)
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2D Elastic Beams Updated February 21, 2014 Page 5
w(L,0) = PL3
6EI+C3L+C5 = 0 (36)
Interestingly, the zero-rotation-requirement can be imposed in several ways because plane sections do not remain plane and perpendicular to the neutral axis. One option is to require that a vertical line remains vertical:
∂u(L,0)
∂z= − PL2
2EI+C4 = 0 ⇒ C4 =
PL2
2EI (37)
Eq. (34) then yields
C3 = − 3P
2Gh− PL2
2EI (38)
Eq. (36) then yields
C5 = − PL3
6EI+ 3PL
2Gh+ PL3
2EI= PL3
3EI+ 3PL
2Gh (39)
which means that all the constants C3, C4, C5, and C6 are determined and the final displacement expressions are:
u(x, z) = − Pzx2
2EI+ 2Pz3
Gh3 − Pν z3
6EI+ PL2
2EI⋅ z (40)
w(x, z) = Pνxz2
2EI+ Px3
6EI+ − 3P
2Gh− PL2
2EI⎛⎝⎜
⎞⎠⎟
x + PL3
3EI+ 3PL
2Gh (41)
Another option for enforcing zero rotation at the end is the classical requirement that a horizontal line remains horizontal:
∂w(L,0)∂x
= PL2
2EI+C3 = 0 ⇒ C3 = − PL2
2EI (42)
Eq. (34) then yields
C4 =
PL2
2EI− 3P
2Gh (43)
Eq. (36) then yields
C5 = − PL3
6EI+ PL3
2EI= PL3
3EI (44)
which means that all the constants C3, C4, C5, and C6 are determined and the final displacement expressions are:
u(x, z) = − Pzx2
2EI+ 2Pz3
Gh3 − Pν z3
6EI+ PL2
2EI− 3P
2Gh⎛⎝⎜
⎞⎠⎟
z (45)
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2D Elastic Beams Updated February 21, 2014 Page 6
w(x, z) = Pνxz2
2EI+ Px3
6EI− PL2
2EIx + PL3
3EI (46)
It is interesting to note that the tip-deflection of the cantilever equals the classical result PL3/3EI for Eq. (46) while for the solution in Eq. (41) it is
w(x, z) = PL3
3EI+ 3PL
2Gh (47)
To observe the distortion of a plane cross-section during bending, the deformed shape of an extreme-case beam (h=1m, L=1m, E=200,000N/mm2, ν=0.3, P=10MN) is plotted in Figure 2. The solid line shows the solution given by Eq. (40) and shows that the cross-section remains vertical at x=L and z=0. However, for other z-values it has clearly distorted from being a straight line. The dashed line shows the solution given by Eq. (45), where the horizontal line at x=L and z=0 remains horizontal. Note that the angle between the neutral axis and the cross-section at z=0 is obtained from Eq. (41):
∂w(L,0)∂x
= − 3P2Gh
(48)
Figure 2: Cross-section distortion in the x-z-plane.
References
Timoshenko, S., and Goodier, J. N. (1969). Theory of elasticity. McGraw-Hill.