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{{Continuum mechanics|cTopic=[[Solid mechanics]]}}
[[Image:ESPIvibration.jpg|thumb | 250px | right| Vibration mode of a clamped square plate]]
In [[continuum mechanics]], ''' plate theories''' are mathematical descriptions of the mechanics of flat plates that draws on the [[bending|theory of beams]]. Plates are defined as plane [[List of structural elements|structural elements]] with a small thickness compared to the planar dimensions.<ref name=timo>Timoshenko, S. and Woinowsky-Krieger, S. "Theory of plates and shells". McGraw–Hill New York, 1959.</ref> The typical thickness to width ratio of a plate structure is less than 0.1.  A plate theory takes advantage of this disparity in length scale to reduce the full three-dimensional [[continuum mechanics|solid mechanics]] problem to a two-dimensional problemThe aim of plate theory is to calculate the [[Deformation (mechanics)|deformation]] and [[stress (mechanics)|stress]]es in a plate subjected to loads.
 
Of the numerous plate theories that have been developed since the late 19th century, two are widely accepted and used in engineering. These are
* the [[Gustav Kirchhoff|Kirchhoff]]–[[Augustus Edward Hough Love|Love]] theory of plates (classical plate theory)
* The [[Raymond Mindlin|Mindlin]]–[[Eric Reissner|Reissner]] theory of plates (first-order shear plate theory)
 
== Kirchhoff–Love theory for thin plates ==
{{main|Kirchhoff–Love plate theory}}
{{Einstein_summation_convention}}
 
[[Image:Plaque mince deplacement element matiere.svg|thumb | 250px | Deformation of a thin plate highlighting the displacement, the mid-surface (red) and the normal to the mid-surface (blue)]]
The [[Gustav Kirchhoff|Kirchhoff]]–[[Augustus Edward Hough Love|Love]] theory is an extension of [[beam theory|Euler–Bernoulli beam theory]] to thin plates. The theory was developed in 1888 by Love<ref>A. E. H. Love, ''On the small free vibrations and deformations of elastic shells'', Philosophical trans. of the Royal Society (London), 1888, Vol. série A, N° 17 p. 491–549.</ref> using assumptions proposed by Kirchhoff. It is assumed that a mid-surface plane can be used to represent the three-dimensional plate in two-dimensional form.
 
The following kinematic assumptions that are made in this theory:<ref name=Reddy>Reddy, J. N., 2007, '''Theory and analysis of elastic plates and shells''', CRC Press, Taylor and Francis.</ref>
* straight lines normal to the mid-surface remain straight after deformation
* straight lines normal to the mid-surface remain normal to the mid-surface after deformation
* the thickness of the plate does not change during a deformation.
 
=== Displacement field ===
The Kirchhoff hypothesis implies that the [[Displacement (vector)|displacement]] field has the form
:<math>
  \begin{align}
    u_\alpha(\mathbf{x}) & = u^0_\alpha(x_1,x_2) - x_3~\frac{\partial w^0}{\partial x_\alpha}
        = u^0_\alpha - x_3~w^0_{,\alpha} ~;~~\alpha=1,2 \\
    u_3(\mathbf{x}) & = w^0(x_1, x_2)
  \end{align}
</math>
where <math>x_1</math> and <math>x_2</math> are the Cartesian coordinates on the mid-surface of the undeformed plate, <math>x_3</math> is the coordinate for the thickness direction, <math>u^0_1, u^0_2</math> are the in-plane displacements of the mid-surface, and <math>w^0</math> is the displacement of the mid-surface in the <math>x_3</math> direction.
 
If <math>\varphi_\alpha</math> are the angles of rotation of the [[Surface normal|normal]] to the mid-surface, then in the Kirchhoff–Love theory
<math>
  \varphi_\alpha = w^0_{,\alpha} \,.
</math>
{|
|[[Image:Plaque mince deplacement rotation fibre neutre new.svg|thumb|600px|Displacement of the mid-surface (left) and of a normal (right)]]
|}
 
=== Strain-displacement relations ===
For the situation where the strains in the plate are infinitesimal and the rotations of the mid-surface normals are less than 10<math>^\circ</math> the [[infinitesimal strain theory|strains-displacement]] relations are
:<math>
   \begin{align}
    \varepsilon_{\alpha\beta} & = \tfrac{1}{2}(u^0_{\alpha,\beta}+u^0_{\beta,\alpha})
      - x_3~w^0_{,\alpha\beta} \\
    \varepsilon_{\alpha 3} & = - w^0_{,\alpha} + w^0_{,\alpha} = 0 \\
    \varepsilon_{33} & = 0
  \end{align}
</math>
Therefore the only non-zero strains are in the in-plane directions.
 
If the rotations of the normals to the mid-surface are in the range of 10<math>~^{\circ}</math> to 15<math>^\circ</math>, the strain-displacement relations can be approximated using the [[Theodore von Kármán|von Kármán]] strains.  Then the kinematic assumptions of Kirchhoff-Love theory lead to the following strain-displacement relations
:<math>
  \begin{align}
    \varepsilon_{\alpha\beta} & = \frac{1}{2}(u^0_{\alpha,\beta}+u^0_{\beta,\alpha}+w^0_{,\alpha}~w^0_{,\beta})
      - x_3~w^0_{,\alpha\beta} \\
    \varepsilon_{\alpha 3} & = - w^0_{,\alpha} + w^0_{,\alpha} = 0 \\
    \varepsilon_{33} & = 0
  \end{align}
</math>
This theory is nonlinear because of the quadratic terms in the strain-displacement relations.
 
=== Equilibrium equations ===
The equilibrium equations for the plate can be derived from the [[principle of virtual work]].  For the situation where the strains and rotations of the plate are small, the equilibrium equations for an unloaded plate are given by
:<math>
  \begin{align}
    N_{\alpha\beta,\alpha} & = 0 \\
    M_{\alpha\beta,\alpha\beta} & = 0
  \end{align}
</math>
where the stress resultants and stress moment resultants are defined as
:<math>
  N_{\alpha\beta} := \int_{-h}^h \sigma_{\alpha\beta}~dx_3 ~;~~
  M_{\alpha\beta} := \int_{-h}^h x_3~\sigma_{\alpha\beta}~dx_3
</math>
and the thickness of the plate is <math>2h</math>.  The quantities <math>\sigma_{\alpha\beta}</math> are the stresses.
 
If the plate is loaded by an external distributed load <math>q(x)</math> that is normal to the mid-surface and directed in the positive <math>x_3</math> direction, the principle of virtual work then leads to the equilibrium equations
<blockquote style="border: 1px solid black; padding:10px; width:180px">
:<math>
  \begin{align}
    N_{\alpha\beta,\alpha} & = 0 \\
    M_{\alpha\beta,\alpha\beta} - q & = 0
  \end{align}
</math>
</blockquote>
 
For moderate rotations, the strain-displacement relations take the von Karman form and the equilibrium equations can be expressed as
:<math>
  \begin{align}
    N_{\alpha\beta,\alpha} & = 0 \\
    M_{\alpha\beta,\alpha\beta} + [N_{\alpha\beta}~w^0_{,\beta}]_{,\alpha} - q & = 0
  \end{align}
</math>
 
=== Boundary conditions ===
The boundary conditions that are needed to solve the equilibrium equations of plate theory can be obtained from the boundary terms in the principle of virtual work.
 
For small strains and small rotations, the boundary conditions are
:<math>
  \begin{align}
      n_\alpha~N_{\alpha\beta} & \quad \mathrm{or} \quad u^0_\beta \\
      n_\alpha~M_{\alpha\beta,\beta} & \quad \mathrm{or} \quad w^0 \\
      n_\beta~M_{\alpha\beta} & \quad \mathrm{or} \quad w^0_{,\alpha}
  \end{align}
</math>
Note that the quantity <math> n_\alpha~M_{\alpha\beta,\beta}</math> is an effective shear force.
 
=== Stress-strain relations ===
The stress-strain relations for a linear elastic Kirchhoff plate are given by
:<math>
  \begin{bmatrix}\sigma_{11} \\ \sigma_{22} \\ \sigma_{12} \end{bmatrix} =
  \begin{bmatrix} C_{11} & C_{12} & C_{13} \\ C_{12} & C_{22} & C_{23} \\
                  C_{13} & C_{23} & C_{33} \end{bmatrix}
  \begin{bmatrix}\varepsilon_{11} \\ \varepsilon_{22} \\ \varepsilon_{12} \end{bmatrix}
</math>
Since <math>\sigma_{\alpha 3}</math> and <math>\sigma_{33}</math> do not appear in the equilibrium equations it is implicitly assumed that these quantities do not have any effect on the momentum balance and are neglected.
 
It is more convenient to work with the stress and moment results that enter the equilibrium equations.  These are related to the displacements by
:<math>
  \begin{bmatrix}N_{11} \\ N_{22} \\ N_{12} \end{bmatrix} =
  \left\{
  \int_{-h}^h \begin{bmatrix} C_{11} & C_{12} & C_{13} \\ C_{12} & C_{22} & C_{23} \\
                  C_{13} & C_{23} & C_{33} \end{bmatrix}~dx_3 \right\}
  \begin{bmatrix} u^0_{1,1} \\ u^0_{2,2} \\ \frac{1}{2}~(u^0_{1,2}+u^0_{2,1}) \end{bmatrix}
</math>
and
:<math>
  \begin{bmatrix}M_{11} \\ M_{22} \\ M_{12} \end{bmatrix}  = -\left\{
  \int_{-h}^h x_3^2~\begin{bmatrix} C_{11} & C_{12} & C_{13} \\ C_{12} & C_{22} & C_{23} \\
                  C_{13} & C_{23} & C_{33} \end{bmatrix}~dx_3 \right\}
  \begin{bmatrix} w^0_{,11} \\ w^0_{,22} \\ w^0_{,12} \end{bmatrix} \,.
</math>
The ''' extensional stiffnesses''' are the quantities
:<math>
  A_{\alpha\beta} := \int_{-h}^h C_{\alpha\beta}~dx_3
</math>
The ''' bending stiffnesses''' (also called '''flexural rigidity''') are the quantities
:<math>
  D_{\alpha\beta} := \int_{-h}^h x_3^2~C_{\alpha\beta}~dx_3
</math>
 
== Isotropic and homogeneous Kirchhoff plate ==
{{main|Kirchhoff–Love plate theory}}
For an isotropic and  homogeneous plate, the stress-strain relations are
:<math>
  \begin{bmatrix}\sigma_{11} \\ \sigma_{22} \\ \sigma_{12} \end{bmatrix}
  = \cfrac{E}{1-\nu^2}
  \begin{bmatrix} 1 & \nu & 0 \\
                  \nu & 1 & 0 \\
                  0 & 0 & 1-\nu \end{bmatrix}
    \begin{bmatrix}\varepsilon_{11} \\ \varepsilon_{22} \\ \varepsilon_{12} \end{bmatrix} \,.
</math>
The moments corresponding to these stresses are
:<math>
  \begin{bmatrix}M_{11} \\ M_{22} \\ M_{12} \end{bmatrix} =
  -\cfrac{2h^3E}{3(1-\nu^2)}~\begin{bmatrix} 1 & \nu & 0 \\
                  \nu & 1 & 0 \\
                  0 & 0 & 1-\nu \end{bmatrix}
  \begin{bmatrix} w^0_{,11} \\ w^0_{,22} \\ w^0_{,12} \end{bmatrix}
</math>
 
=== Pure bending ===
The displacements <math>u^0_1</math> and <math>u^0_2</math> are zero under [[pure bending]] conditions.  For an isotropic, homogeneous plate under pure bending the governing equation is
:<math>
  \frac{\partial^4 w}{\partial x_1^4} + 2 \frac{\partial^4 w}{\partial x_1^2 \partial x_2^2} + \frac{\partial^4 w}{\partial x_2^4} = 0 \quad \text{where} \quad w := w^0\,.
</math>
In index notation,
:<math>
  w^0_{,1111} + 2~w^0_{,1212} +  w^0_{,2222} = 0 \,.
</math>
In direct tensor notation, the governing equation is
<blockquote style="border: 1px solid black; padding:10px; width:180px">
:<math>
  \nabla^2\nabla^2 w = 0 \,.
</math>
</blockquote>
 
=== Transverse loading ===
For a transversely loaded plate without axial deformations, the governing equation has the form
:<math>
  \frac{\partial^4 w}{\partial x_1^4} + 2 \frac{\partial^4 w}{\partial x_1^2 \partial x_2^2} + \frac{\partial^4 w}{\partial x_2^4} = -\frac{q}{D}
</math>
where
:<math>
  D := \cfrac{2h^3E}{3(1-\nu^2)} \,.
</math>
In index notation,
:<math>
  w^0_{,1111} + 2\,w^0_{,1212} + w^0_{,2222} = -\frac{q}{D}
</math>
and in direct notation
<blockquote style="border: 1px solid black; padding:10px; width:180px">
:<math>
  \nabla^2\nabla^2 w = -\frac{q}{D} \,.
</math>
</blockquote>
In cylindrical coordinates <math>(r, \theta, z)</math>, the governing equation is
:<math>
  \frac{1}{r}\cfrac{d }{d r}\left[r \cfrac{d }{d r}\left\{\frac{1}{r}\cfrac{d }{d r}\left(r \cfrac{d w}{d r}\right)\right\}\right] = - \frac{q}{D}\,.
</math>
 
== Orthotropic and homogeneous Kirchhoff plate ==
For an [[orthotropic material|orthotropic]] plate
:<math>
  \begin{bmatrix} C_{11} & C_{12} & C_{13} \\ C_{12} & C_{22} & C_{23} \\
                  C_{13} & C_{23} & C_{33} \end{bmatrix}
  = \cfrac{1}{1-\nu_{12}\nu_{21}}
  \begin{bmatrix} E_1 & \nu_{12}E_2 & 0 \\
                  \nu_{21}E_1 & E_2 & 0 \\
                  0 & 0 & 2G_{12}(1-\nu_{12}\nu_{21}) \end{bmatrix}
    \,.
</math>
Therefore,
:<math>
  \begin{bmatrix} A_{11} & A_{12} & A_{13} \\ A_{21} & A_{22} & A_{23} \\
                  A_{31} & A_{32} & A_{33} \end{bmatrix}
  = \cfrac{2h}{1-\nu_{12}\nu_{21}}
  \begin{bmatrix} E_1 & \nu_{12}E_2 & 0 \\
                  \nu_{21}E_1 & E_2 & 0 \\
                  0 & 0 & 2G_{12}(1-\nu_{12}\nu_{21}) \end{bmatrix}
</math>
and
:<math>
  \begin{bmatrix} D_{11} & D_{12} & D_{13} \\ D_{21} & D_{22} & D_{23} \\
                  D_{31} & D_{32} & D_{33} \end{bmatrix}
  = \cfrac{2h^3}{3(1-\nu_{12}\nu_{21})}
  \begin{bmatrix} E_1 & \nu_{12}E_2 & 0 \\
                  \nu_{21}E_1 & E_2 & 0 \\
                  0 & 0 & 2G_{12}(1-\nu_{12}\nu_{21}) \end{bmatrix}
    \,.
</math>
 
=== Transverse loading ===
The governing equation of an orthotropic Kirchhoff plate loaded transversely by a distributed load <math>q</math> per unit area is
:<math>
  D_x w^0_{,1111} + 2 D_{xy} w^0_{,1122} + D_y w^0_{,2222} = -q
</math>
where
:<math>
  \begin{align}
    D_x & = D_{11} = \frac{2h^3 E_1}{3(1 - \nu_{12}\nu_{21})} \\
    D_y & = D_{22} = \frac{2h^3 E_2}{3(1 - \nu_{12}\nu_{21})} \\
    D_{xy} & = D_{33} + \tfrac{1}{2}(\nu_{21} D_{11} + \nu_{12} D_{22}) = D_{33} + \nu_{21} D_{11} = \frac{4h^3 G_{12}}{3} + \frac{2h^3 \nu_{21} E_1}{3(1 - \nu_{12}\nu_{21})} \,.
  \end{align}
</math>
 
== Dynamics of thin Kirchhoff plates ==
{{main|Kirchhoff–Love plate theory}}
The dynamic theory of plates determines the propagation of waves in the plates, and the study of standing waves and vibration modes.
 
=== Governing equations ===
The governing equations for the dynamics of a Kirchhoff–Love plate are
<blockquote style="border: 1px solid black; padding:10px; width:330px">
:<math>
  \begin{align}
    N_{\alpha\beta,\beta} & = J_1~\ddot{u}^0_\alpha \\
    M_{\alpha\beta,\alpha\beta} - q(x,t) & = J_1~\ddot{w}^0 - J_3~\ddot{w}^0_{,\alpha\alpha}
  \end{align}
</math>
</blockquote>
where, for a plate with density <math>\rho = \rho(x)</math>,
:<math>
  J_1 := \int_{-h}^h \rho~dx_3 = 2~\rho~h ~;~~
  J_3 := \int_{-h}^h x_3^2~\rho~dx_3 = \frac{2}{3}~\rho~h^3
</math>
and
:<math>
  \dot{u}_i = \frac{\partial u_i}{\partial t} ~;~~ \ddot{u}_i = \frac{\partial^2 u_i}{\partial t^2} ~;~~
  u_{i,\alpha} = \frac{\partial u_i}{\partial x_\alpha} ~;~~ u_{i,\alpha\beta} = \frac{\partial^2 u_i}{\partial x_\alpha \partial x_\beta}
</math>
 
The figures below show some vibrational modes of a circular plate.
<gallery widths="250px">
Image:Drum vibration mode01.gif|mode ''k'' = 0, ''p'' = 1
Image:Drum vibration mode12.gif|mode ''k'' = 1, ''p'' = 2
</gallery>
 
=== Isotropic plates ===
The governing equations simplify considerably for isotropic and homogeneous plates for which the in-plane deformations can be neglected and have the form
:<math>
  D\,\left(\frac{\partial^4 w^0}{\partial x_1^4} + 2\frac{\partial^4 w^0}{\partial x_1^2\partial x_2^2} + \frac{\partial^4 w^0}{\partial x_2^4}\right) = -q(x_1, x_2, t) - 2\rho h\, \frac{\partial^2 w^0}{\partial t^2} \,.
</math>
where <math>D</math> is the bending stiffness of the plate.  For a uniform plate of thickness <math>2h</math>,
:<math>
  D := \cfrac{2h^3E}{3(1-\nu^2)} \,.
</math>
In direct notation
<blockquote style="border: 1px solid black; padding:10px; width:350px">
:<math>
  D\,\nabla^2\nabla^2 w^0 = -q(x, y, t) - 2\rho h \, \ddot{w}^0 \,.
</math>
</blockquote>
 
== Mindlin–Reissner theory for thick plates ==
{{main|Mindlin–Reissner plate theory}}
{{Einstein_summation_convention}}
In the theory of thick plates, or theory of [[Raymond Mindlin]]<ref>R. D. Mindlin, ''Influence of rotatory inertia and shear on flexural motions of isotropic, elastic plates'', Journal of Applied Mechanics, 1951, Vol. 18 p. 31–38.</ref> and [[Eric Reissner]], the normal to the mid-surface remains straight but not necessarily perpendicular to the mid-surface.  If <math>\varphi_1</math> and <math>\varphi_2</math> designate the angles which the mid-surface makes with the <math>x_3</math> axis then
:<math>
    \varphi_1 \ne w_{,1} ~;~~ \varphi_2 \ne w_{,2}
</math>
 
Then the Mindlin–Reissner hypothesis implies that
<blockquote style="border: 1px solid black; padding:10px; width:400px">
:<math>
  \begin{align}
    u_\alpha(\mathbf{x}) & = u^0_\alpha(x_1,x_2) - x_3~\varphi_\alpha  ~;~~\alpha=1,2 \\
    u_3(\mathbf{x}) & = w^0(x_1, x_2)
  \end{align}
</math>
</blockquote>
 
=== Strain-displacement relations ===
Depending on the amount of rotation of the plate normals two different approximations for the strains can be derived from the basic kinematic assumptions.
 
For small strains and small rotations the strain-displacement relations for Mindlin–Reissner plates are
:<math>
  \begin{align}
    \varepsilon_{\alpha\beta} & = \frac{1}{2}(u^0_{\alpha,\beta}+u^0_{\beta,\alpha})
      - \frac{x_3}{2}~(\varphi_{\alpha,\beta} + \varphi_{\beta,\alpha})\\
    \varepsilon_{\alpha 3} & = \cfrac{1}{2}\left(w^0_{,\alpha}- \varphi_\alpha\right) \\
    \varepsilon_{33} & = 0
  \end{align}
</math>
The shear strain, and hence the shear stress, across the thickness of the plate is not neglected in this theory.  However, the shear strain is constant across the thickness of the plate.  This cannot be accurate since the shear stress is known to be parabolic even for simple plate geometries.  To account for the inaccuracy in the shear strain, a '''shear correction factor''' (<math>\kappa</math>) is applied so that the correct amount of internal energy is predicted by the theory.  Then
:<math>
  \varepsilon_{\alpha 3} = \cfrac{1}{2}~\kappa~\left(w^0_{,\alpha}- \varphi_\alpha\right)
</math>
 
=== Equilibrium equations ===
The equilibrium equations have slightly different forms depending on the amount of bending expected in the plate.  For the situation where the strains and rotations of the plate are smallthe equilibrium equations for a Mindlin–Reissner plate are
<blockquote style="border: 1px solid black; padding:10px; width:180px">
:<math>
  \begin{align}
    & N_{\alpha\beta,\alpha} = 0 \\
    & M_{\alpha\beta,\beta}-Q_\alpha = 0 \\
    & Q_{\alpha,\alpha}+q = 0 \,.
  \end{align}
</math>
</blockquote>
The resultant shear forces in the above equations are defined as
:<math>
  Q_\alpha := \kappa~\int_{-h}^h \sigma_{\alpha 3}~dx_3 \,.
</math>
 
=== Boundary conditions ===
The boundary conditions are indicated by the boundary terms in the principle of virtual work.
 
If the only external force is a vertical force on the top surface of the plate, the boundary conditions are
:<math>
  \begin{align}
      n_\alpha~N_{\alpha\beta} & \quad \mathrm{or} \quad u^0_\beta \\
      n_\alpha~M_{\alpha\beta} & \quad \mathrm{or} \quad \varphi_\alpha \\
      n_\alpha~Q_\alpha & \quad \mathrm{or} \quad w^0
  \end{align}
</math>
 
=== Constitutive relations ===
The stress-strain relations for a linear elastic Mindlin–Reissner plate are given by
:<math>
  \begin{align}
    \sigma_{\alpha\beta} & = C_{\alpha\beta\gamma\theta}~\varepsilon_{\gamma\theta} \\
    \sigma_{\alpha 3} & = C_{\alpha 3\gamma\theta}~\varepsilon_{\gamma\theta} \\
    \sigma_{33} & = C_{33\gamma\theta}~\varepsilon_{\gamma\theta}
  \end{align}
</math>
Since <math>\sigma_{33}</math> does not appear in the equilibrium equations it is implicitly assumed that it do not have any effect on the momentum balance and is neglected.  This assumption is also called the '''plane stress''' assumption.  The remaining stress-strain relations for an [[orthotropic material]], in matrix form, can be written as
:<math>
  \begin{bmatrix}\sigma_{11} \\ \sigma_{22} \\ \sigma_{23} \\ \sigma_{31} \\ \sigma_{12} \end{bmatrix} =
  \begin{bmatrix} C_{11} & C_{12} & 0 & 0 & 0 \\ C_{12} & C_{22} & 0 & 0 & 0 \\
                  0 & 0 & C_{44} & 0 & 0 \\
                  0 & 0 & 0 & C_{55} & 0 \\ 0 & 0 & 0 & 0 & C_{66}\end{bmatrix}
  \begin{bmatrix}\varepsilon_{11} \\ \varepsilon_{22} \\ \varepsilon_{23} \\ \varepsilon_{31} \\ \varepsilon_{12}\end{bmatrix}
</math>
Then,
:<math>
  \begin{bmatrix}N_{11} \\ N_{22} \\ N_{12} \end{bmatrix} =
  \left\{
  \int_{-h}^h \begin{bmatrix} C_{11} & C_{12} & 0 \\ C_{12} & C_{22} & 0 \\
                  0 & 0 & C_{66} \end{bmatrix}~dx_3 \right\}
  \begin{bmatrix} u^0_{1,1} \\ u^0_{2,2} \\ \frac{1}{2}~(u^0_{1,2}+u^0_{2,1}) \end{bmatrix}
</math>
and
:<math>
  \begin{bmatrix}M_{11} \\ M_{22} \\ M_{12} \end{bmatrix} = -\left\{
  \int_{-h}^h x_3^2~\begin{bmatrix} C_{11} & C_{12} & 0 \\ C_{12} & C_{22} & 0 \\
                  0 & 0 & C_{66} \end{bmatrix}~dx_3 \right\}
  \begin{bmatrix} \varphi_{1,1} \\ \varphi_{2,2} \\ \frac{1}{2}~(\varphi_{1,2}+\varphi_{2,1}) \end{bmatrix}
</math>
For the shear terms
:<math>
  \begin{bmatrix}Q_1 \\ Q_2 \end{bmatrix} = \cfrac{\kappa}{2}\left\{
  \int_{-h}^h \begin{bmatrix} C_{55} & 0 \\ 0 & C_{44}  \end{bmatrix}~dx_3 \right\}
  \begin{bmatrix} w^0_{,1} - \varphi_1 \\ w^0_{,2} - \varphi_2 \end{bmatrix}
</math>
The ''' extensional stiffnesses''' are the quantities
:<math>
  A_{\alpha\beta} := \int_{-h}^h C_{\alpha\beta}~dx_3
</math>
The ''' bending stiffnesses''' are the quantities
:<math>
  D_{\alpha\beta} := \int_{-h}^h x_3^2~C_{\alpha\beta}~dx_3
</math>
 
== Isotropic and homogeneous Mindlin-Reissner plates ==
{{main|Mindlin–Reissner plate theory}}
For uniformly thick, homogeneous, and isotropic plates, the stress-strain relations in the plane of the plate are
:<math>
  \begin{bmatrix}\sigma_{11} \\ \sigma_{22} \\ \sigma_{12} \end{bmatrix}
  = \cfrac{E}{1-\nu^2}
  \begin{bmatrix} 1 & \nu & 0 \\
                  \nu & 1 & 0 \\
                  0 & 0 & 1-\nu \end{bmatrix}
    \begin{bmatrix}\varepsilon_{11} \\ \varepsilon_{22} \\ \varepsilon_{12} \end{bmatrix} \,.
</math>
where <math>E</math> is the Young's modulus, <math>\nu</math> is the Poisson's ratio, and <math>\varepsilon_{\alpha\beta}</math> are the in-plane strains.  The through-the-thickness shear stresses and strains are related by
:<math>
  \sigma_{31} = 2G\varepsilon_{31} \quad \text{and} \quad
  \sigma_{32} = 2G\varepsilon_{32}
</math>
where <math>G = E/(2(1+\nu))</math> is the [[shear modulus]].
 
=== Constitutive relations ===
The relations between the stress resultants and the generalized displacements for an isotropic Mindlin–Reissner plate are:
:<math>
  \begin{bmatrix}N_{11} \\ N_{22} \\ N_{12} \end{bmatrix} =
    \cfrac{2Eh}{1-\nu^2} \begin{bmatrix} 1 & \nu & 0 \\ \nu & 1 & 0 \\
                  0 & 0 & 1-\nu \end{bmatrix}
  \begin{bmatrix} u^0_{1,1} \\ u^0_{2,2} \\ \frac{1}{2}~(u^0_{1,2}+u^0_{2,1}) \end{bmatrix} \,,
</math>
:<math>
  \begin{bmatrix}M_{11} \\ M_{22} \\ M_{12} \end{bmatrix} =
    -\cfrac{2Eh^3}{3(1-\nu^2)} \begin{bmatrix} 1 & \nu & 0 \\ \nu & 1 & 0 \\
                  0 & 0 & 1-\nu \end{bmatrix}
  \begin{bmatrix} \varphi_{1,1} \\ \varphi_{2,2} \\ \frac{1}{2}(\varphi_{1,2}+\varphi_{2,1}) \end{bmatrix} \,,
</math>
and
:<math>
  \begin{bmatrix}Q_1 \\ Q_2 \end{bmatrix} = \kappa G h
  \begin{bmatrix} w^0_{,1} - \varphi_1 \\ w^0_{,2} - \varphi_2 \end{bmatrix} \,.
</math>
The [[bending rigidity]] is defined as the quantity
:<math>
  D = \cfrac{2Eh^3}{3(1-\nu^2)}  \,.
</math>
For a plate of thickness <math>h</math>, the bending rigidity has the form
:<math>
  D = \cfrac{Eh^3}{12(1-\nu^2)}  \,.
</math>
 
=== Governing equations ===
If we ignore the in-plane extension of the plate, the governing equations are
:<math>
  \begin{align}
    M_{\alpha\beta,\beta}-Q_\alpha & = 0 \\
    Q_{\alpha,\alpha}+q & = 0 \,.
  \end{align}
</math>
In terms of the generalized deformations <math>w^0, \varphi_1, \varphi_2</math>, the three governing equations are
<blockquote style="border: 1px solid black; padding:10px; width:450px">
:<math>
  \begin{align}
    &\nabla^2 \left(\frac{\partial \varphi_1}{\partial x_1} + \frac{\partial \varphi_2}{\partial x_2}\right) = -\frac{q}{D} \\
  &\nabla^2 w^0 - \frac{\partial \varphi_1}{\partial x_1} - \frac{\partial \varphi_2}{\partial x_2} = -\frac{q}{\kappa G h} \\
  &\nabla^2 \left(\frac{\partial \varphi_1}{\partial x_2} - \frac{\partial \varphi_2}{\partial x_1}\right) = -\frac{2\kappa G h}{D(1-\nu)}\left(\frac{\partial \varphi_1}{\partial x_2} - \frac{\partial \varphi_2}{\partial x_1}\right) \,.
  \end{align}
</math>
</blockquote>
The boundary conditions along the edges of a rectangular plate are
:<math>
  \begin{align}
    \text{simply supported} \quad & \quad w^0 = 0, M_{11} = 0 ~(\text{or}~M_{22} = 0),
    \varphi_1 = 0 ~(\text{or}~\varphi_2 = 0) \\
    \text{clamped} \quad & \quad w^0 = 0, \varphi_1 = 0,  \varphi_{2} = 0  \,.
  \end{align}
</math>
 
== Reissner–Stein theory for isotropic cantilever plates ==
In general, exact solutions for cantilever plates using plate theory are quite involved and few exact solutions can be found in the literature.  Reissner and Stein<ref name=Reissner51>E. Reissner and M. Stein. Torsion and transverse bending of cantilever plates. Technical Note 2369, National Advisory Committee for Aeronautics,Washington, 1951.</ref> provide a simplified theory for cantilever plates that is an improvement over older theories such as Saint-Venant plate theory.
 
The Reissner-Stein theory assumes a transverse displacement field of the form
:<math>
  w(x,y) = w_x(x) + y\,\theta_x(x) \,.
</math>
The governing equations for the plate then reduce to two coupled ordinary differential equations:
<blockquote style="border: 1px solid black; padding:10px; width:800px">
:<math>
  \begin{align}
  & bD \frac{\mathrm{d}^4w_x}{\mathrm{d}x^4}
  = q_1(x) - n_1(x)\cfrac{d^2 w_x}{d x^2} - \cfrac{d n_1}{d x}\,\cfrac{d w_x}{d x}
    - \frac{1}{2}\cfrac{d n_2}{d x}\,\cfrac{d \theta_x}{d x} - \frac{n_2(x)}{2}\cfrac{d^2 \theta_x}{d x^2} \\
  &\frac{b^3D}{12}\,\frac{\mathrm{d}^4\theta_x}{\mathrm{d}x^4} - 2bD(1-\nu)\cfrac{d^2 \theta_x}{d x^2}
  = q_2(x) - n_3(x)\cfrac{d^2 \theta_x}{d x^2} - \cfrac{d n_3}{d x}\,\cfrac{d \theta_x}{d x}
    - \frac{n_2(x)}{2}\,\cfrac{d^2 w_x}{d x^2} - \frac{1}{2}\cfrac{d n_2}{d x}\,\cfrac{d w_x}{d x}
  \end{align}
</math>
</blockquote>
where
:<math>
  \begin{align}
    q_1(x) & = \int_{-b/2}^{b/2}q(x,y)\,\text{d}y ~,~~ q_2(x) = \int_{-b/2}^{b/2}y\,q(x,y)\,\text{d}y~,~~
    n_1(x) = \int_{-b/2}^{b/2}n_x(x,y)\,\text{d}y \\
    n_2(x) & = \int_{-b/2}^{b/2}y\,n_x(x,y)\,\text{d}y ~,~~ n_3(x)  = \int_{-b/2}^{b/2}y^2\,n_x(x,y)\,\text{d}y  \,.
  \end{align}
</math>
At <math>x = 0</math>, since the beam is clamped, the boundary conditions are
:<math>
  w(0,y) = \cfrac{d w}{d x}\Bigr|_{x=0} = 0 \qquad \implies \qquad
  w_x(0) = \cfrac{d w_x}{d x}\Bigr|_{x=0} = \theta_x(0) = \cfrac{d \theta_x}{d x}\Bigr|_{x=0} = 0 \,.
</math>
The boundary conditions at <math>x = a</math> are
:<math>
  \begin{align}
  & bD\cfrac{d^3 w_x}{d x^3} + n_1(x)\cfrac{d w_x}{d x} + n_2(x)\cfrac{d \theta_x}{d x} + q_{x1} = 0 \\
  & \frac{b^3D}{12}\cfrac{d^3 \theta_x}{d x^3} + \left[n_3(x) -2bD(1-\nu)\right]\cfrac{d \theta_x}{d x}
    + n_2(x)\cfrac{d w_x}{d x} + t = 0 \\
  & bD\cfrac{d^2 w_x}{d x^2} + m_1 = 0 \quad,\quad  \frac{b^3D}{12}\cfrac{d^2 \theta_x}{d x^2} + m_2 = 0
  \end{align}
</math>
where
:<math>
  \begin{align}
    m_1 & = \int_{-b/2}^{b/2}m_x(y)\,\text{d}y ~,~~ m_2 = \int_{-b/2}^{b/2}y\,m_x(y)\,\text{d}y ~,~~
    q_{x1} = \int_{-b/2}^{b/2}q_x(y)\,\text{d}y \\
    t  & = q_{x2} + m_3 = \int_{-b/2}^{b/2}y\,q_x(y)\,\text{d}y + \int_{-b/2}^{b/2}m_{xy}(y)\,\text{d}y  \,.
  \end{align}
</math>
:{| class="toccolours collapsible collapsed" width="60%" style="text-align:left"
!Derivation of Reissner–Stein cantilever plate equations
|-
|The strain energy of bending of a thin rectangular plate of uniform thickness <math>h</math> is given by
:<math>
  U = \frac{1}{2} \int_0^a \int_{-b/2}^{b/2}D\left\{\left(\frac{\partial^2 w}{\partial x^2} + \frac{\partial^2 w}{\partial y^2}\right)^2 +
    2(1-\nu)\left[\left(\frac{\partial^2 w}{\partial x \partial y}\right)^2 - \frac{\partial^2 w}{\partial x^2}\frac{\partial^2 w}{\partial y^2}\right]
    \right\}\text{d}x\text{d}y
</math>
where <math>w</math> is the transverse displacement, <math>a</math> is the length, <math>b</math> is the width, <math>\nu</math> is the Poisson's
ratio, <math>E</math> is the Young's modulus, and
:<math>
  D = \frac{Eh^3}{12(1-\nu)}.
</math>
The potential energy of transverse loads <math>q(x,y)</math> (per unit length) is
:<math>
  P_q = \int_0^a \int_{-b/2}^{b/2}q(x,y)\, w(x,y)\,\text{d}x\text{d}y \,.
</math>
The potential energy of in-plane loads <math>n_x(x,y)</math> (per unit width) is
:<math>
  P_n = \frac{1}{2} \int_0^a \int_{-b/2}^{b/2}n_x(x,y)\,\left(\frac{\partial w}{\partial x}\right)^2\,\text{d}x\text{d}y \,.
</math>
The potential energy of tip forces <math>q_x(y)</math> (per unit width), and bending moments <math>m_x(y)</math> and <math>m_{xy}(y)</math>
(per unit width) is
:<math>
  P_t = \int_{-b/2}^{b/2}\left(q_x(y)\,w(x,y) - m_x(y)\,\frac{\partial w}{\partial x} + m_{xy}(y)\,\frac{\partial w}{\partial y}\right)\text{d}x\text{d}y \,.
</math>
A balance of energy requires that the total energy is
:<math>
  W = U - (P_q + P_n + P_t) \,.
</math>
With the Reissener–Stein assumption for the displacement, we have
:<math>
  U = \int_0^a\frac{bD}{24}\left[12\left(\cfrac{d^2 w_x}{d x^2}\right)^2 +
      b^2\left(\cfrac{d^2 \theta_x}{d x^2}\right)^2 + 24(1-\nu)\left(\cfrac{d \theta_x}{d x}\right)^2\right]\,\text{d}x\,,
</math>
:<math>
  P_q = \int_0^a\left[\left(\int_{-b/2}^{b/2}q(x,y)\,\text{d}y\right)w_x + \left(\int_{-b/2}^{b/2}yq(x,y)\,\text{d}y\right)\theta_x\right]\,dx \,,
</math>
:<math>
  \begin{align}
  P_n & = \frac{1}{2}\int_0^a\left[\left(\int_{-b/2}^{b/2}n_x(x,y)\,\text{d}y\right)\left(\cfrac{d w_x}{d x}\right)^2 +
    \left(\int_{-b/2}^{b/2}y n_x(x,y)\,\text{d}y\right)\cfrac{d w_x}{d x}\,\cfrac{d \theta_x}{d x} \right.\\
    & \left. \qquad\qquad +\left(\int_{-b/2}^{b/2}y^2 n_x(x,y)\,\text{d}y\right)\left(\cfrac{d \theta_x}{d x}\right)^2\right]\text{d}x\,,
  \end{align}
</math>
and
:<math>
  \begin{align}
  P_t & = \left(\int_{-b/2}^{b/2}q_x(y)\,\text{d}y\right)w_x -
        \left(\int_{-b/2}^{b/2}m_x(y)\,\text{d}y\right)\cfrac{d w_x}{d x} +
        \left[\int_{-b/2}^{b/2}\left(y q_x(y) + m_{xy}(y)\right)\,\text{d}y\right]\theta_x  \\
      & \qquad \qquad  -\left(\int_{-b/2}^{b/2}y m_x(y)\,\text{d}y\right)\cfrac{d \theta_x}{d x} \,.
  \end{align}
</math>
Taking the first variation of <math>W</math> with respect to <math>(w_x, \theta_x, x)</math> and
setting it to zero gives us the Euler equations
:<math> \text{(1)} \qquad
  bD \frac{\mathrm{d}^4w_x}{\mathrm{d}x^4}
  = q_1(x) - n_1(x)\cfrac{d^2 w_x}{d x^2} - \cfrac{d n_1}{d x}\,\cfrac{d w_x}{d x}
    - \frac{1}{2}\cfrac{d n_2}{d x}\,\cfrac{d \theta_x}{d x} - \frac{n_2(x)}{2}\cfrac{d^2 \theta_x}{d x^2}
</math>
and
:<math> \text{(2)} \qquad
  \frac{b^3D}{12}\,\frac{\mathrm{d}^4\theta_x}{\mathrm{d}x^4} - 2bD(1-\nu)\cfrac{d^2 \theta_x}{d x^2}
  = q_2(x) - n_3(x)\cfrac{d^2 \theta_x}{d x^2} - \cfrac{d n_3}{d x}\,\cfrac{d \theta_x}{d x}
    - \frac{n_2(x)}{2}\,\cfrac{d^2 w_x}{d x^2} - \frac{1}{2}\cfrac{d n_2}{d x}\,\cfrac{d w_x}{d x}
</math>
where
:<math>
  \begin{align}
    q_1(x) & = \int_{-b/2}^{b/2}q(x,y)\,\text{d}y ~,~~ q_2(x) = \int_{-b/2}^{b/2}y\,q(x,y)\,\text{d}y~,~~
    n_1(x) = \int_{-b/2}^{b/2}n_x(x,y)\,\text{d}y \\
    n_2(x) & = \int_{-b/2}^{b/2}y\,n_x(x,y)\,\text{d}y ~,~~ n_3(x)  = \int_{-b/2}^{b/2}y^2\,n_x(x,y)\,\text{d}y.
  \end{align}
</math>
Since the beam is clamped at <math>x = 0</math>, we have
:<math>
  w(0,y) = \cfrac{d w}{d x}\Bigr|_{x=0} = 0 \qquad \implies \qquad
  w_x(0) = \cfrac{d w_x}{d x}\Bigr|_{x=0} = \theta_x(0) = \cfrac{d \theta_x}{d x}\Bigr|_{x=0} = 0 \,.
</math>
The boundary conditions at <math>x = a</math> can be found by integration by parts:
:<math>
  \begin{align}
  & bD\cfrac{d^3 w_x}{d x^3} + n_1(x)\cfrac{d w_x}{d x} + n_2(x)\cfrac{d \theta_x}{d x} + q_{x1} = 0 \\
  & \frac{b^3D}{12}\cfrac{d^3 \theta_x}{d x^3} + \left[n_3(x) -2bD(1-\nu)\right]\cfrac{d \theta_x}{d x}
    + n_2(x)\cfrac{d w_x}{d x} + t = 0 \\
  & bD\cfrac{d^2 w_x}{d x^2} + m_1 = 0 \quad,\quad  \frac{b^3D}{12}\cfrac{d^2 \theta_x}{d x^2} + m_2 = 0
  \end{align}
</math>
where
:<math>
  \begin{align}
    m_1 & = \int_{-b/2}^{b/2}m_x(y)\,\text{d}y ~,~~ m_2 = \int_{-b/2}^{b/2}y\,m_x(y)\,\text{d}y ~,~~
    q_{x1} = \int_{-b/2}^{b/2}q_x(y)\,\text{d}y \\
    t  & = q_{x2} + m_3 = \int_{-b/2}^{b/2}y\,q_x(y)\,\text{d}y + \int_{-b/2}^{b/2}m_{xy}(y)\,\text{d}y.
  \end{align}
</math>
|}
 
== References ==
<references/>
 
== See also ==
* [[Bending of plates]]
* [[Vibration of plates]]
* [[Infinitesimal strain theory]]
*[[Finite strain theory]]
*[[Stress (mechanics)]]
*[[Stress resultants]]
*[[Linear elasticity]]
*[[Bending]]
*[[Euler–Bernoulli beam equation]]
*[[Timoshenko beam theory]]
 
{{DEFAULTSORT:Plate Theory}}
[[Category:Continuum mechanics]]
 
[[ca:Teoria de plaques i làmines]]
[[de:Plattentheorie]]
[[gl:Laxe (construción)]]

Revision as of 05:03, 21 March 2013

Template:Continuum mechanics

File:ESPIvibration.jpg
Vibration mode of a clamped square plate

In continuum mechanics, plate theories are mathematical descriptions of the mechanics of flat plates that draws on the theory of beams. Plates are defined as plane structural elements with a small thickness compared to the planar dimensions.[1] The typical thickness to width ratio of a plate structure is less than 0.1. A plate theory takes advantage of this disparity in length scale to reduce the full three-dimensional solid mechanics problem to a two-dimensional problem. The aim of plate theory is to calculate the deformation and stresses in a plate subjected to loads.

Of the numerous plate theories that have been developed since the late 19th century, two are widely accepted and used in engineering. These are

Kirchhoff–Love theory for thin plates

Mining Engineer (Excluding Oil ) Truman from Alma, loves to spend time knotting, largest property developers in singapore developers in singapore and stamp collecting. Recently had a family visit to Urnes Stave Church. Template:Einstein summation convention

File:Plaque mince deplacement element matiere.svg
Deformation of a thin plate highlighting the displacement, the mid-surface (red) and the normal to the mid-surface (blue)

The KirchhoffLove theory is an extension of Euler–Bernoulli beam theory to thin plates. The theory was developed in 1888 by Love[2] using assumptions proposed by Kirchhoff. It is assumed that a mid-surface plane can be used to represent the three-dimensional plate in two-dimensional form.

The following kinematic assumptions that are made in this theory:[3]

  • straight lines normal to the mid-surface remain straight after deformation
  • straight lines normal to the mid-surface remain normal to the mid-surface after deformation
  • the thickness of the plate does not change during a deformation.

Displacement field

The Kirchhoff hypothesis implies that the displacement field has the form

uα(𝐱)=uα0(x1,x2)x3w0xα=uα0x3w,α0;α=1,2u3(𝐱)=w0(x1,x2)

where x1 and x2 are the Cartesian coordinates on the mid-surface of the undeformed plate, x3 is the coordinate for the thickness direction, u10,u20 are the in-plane displacements of the mid-surface, and w0 is the displacement of the mid-surface in the x3 direction.

If φα are the angles of rotation of the normal to the mid-surface, then in the Kirchhoff–Love theory φα=w,α0.

File:Plaque mince deplacement rotation fibre neutre new.svg
Displacement of the mid-surface (left) and of a normal (right)

Strain-displacement relations

For the situation where the strains in the plate are infinitesimal and the rotations of the mid-surface normals are less than 10 the strains-displacement relations are

εαβ=12(uα,β0+uβ,α0)x3w,αβ0εα3=w,α0+w,α0=0ε33=0

Therefore the only non-zero strains are in the in-plane directions.

If the rotations of the normals to the mid-surface are in the range of 10 to 15, the strain-displacement relations can be approximated using the von Kármán strains. Then the kinematic assumptions of Kirchhoff-Love theory lead to the following strain-displacement relations

εαβ=12(uα,β0+uβ,α0+w,α0w,β0)x3w,αβ0εα3=w,α0+w,α0=0ε33=0

This theory is nonlinear because of the quadratic terms in the strain-displacement relations.

Equilibrium equations

The equilibrium equations for the plate can be derived from the principle of virtual work. For the situation where the strains and rotations of the plate are small, the equilibrium equations for an unloaded plate are given by

Nαβ,α=0Mαβ,αβ=0

where the stress resultants and stress moment resultants are defined as

Nαβ:=hhσαβdx3;Mαβ:=hhx3σαβdx3

and the thickness of the plate is 2h. The quantities σαβ are the stresses.

If the plate is loaded by an external distributed load q(x) that is normal to the mid-surface and directed in the positive x3 direction, the principle of virtual work then leads to the equilibrium equations

Nαβ,α=0Mαβ,αβq=0

For moderate rotations, the strain-displacement relations take the von Karman form and the equilibrium equations can be expressed as

Nαβ,α=0Mαβ,αβ+[Nαβw,β0],αq=0

Boundary conditions

The boundary conditions that are needed to solve the equilibrium equations of plate theory can be obtained from the boundary terms in the principle of virtual work.

For small strains and small rotations, the boundary conditions are

nαNαβoruβ0nαMαβ,βorw0nβMαβorw,α0

Note that the quantity nαMαβ,β is an effective shear force.

Stress-strain relations

The stress-strain relations for a linear elastic Kirchhoff plate are given by

[σ11σ22σ12]=[C11C12C13C12C22C23C13C23C33][ε11ε22ε12]

Since σα3 and σ33 do not appear in the equilibrium equations it is implicitly assumed that these quantities do not have any effect on the momentum balance and are neglected.

It is more convenient to work with the stress and moment results that enter the equilibrium equations. These are related to the displacements by

[N11N22N12]={hh[C11C12C13C12C22C23C13C23C33]dx3}[u1,10u2,2012(u1,20+u2,10)]

and

[M11M22M12]={hhx32[C11C12C13C12C22C23C13C23C33]dx3}[w,110w,220w,120].

The extensional stiffnesses are the quantities

Aαβ:=hhCαβdx3

The bending stiffnesses (also called flexural rigidity) are the quantities

Dαβ:=hhx32Cαβdx3

Isotropic and homogeneous Kirchhoff plate

Mining Engineer (Excluding Oil ) Truman from Alma, loves to spend time knotting, largest property developers in singapore developers in singapore and stamp collecting. Recently had a family visit to Urnes Stave Church. For an isotropic and homogeneous plate, the stress-strain relations are

[σ11σ22σ12]=E1ν2[1ν0ν10001ν][ε11ε22ε12].

The moments corresponding to these stresses are

[M11M22M12]=2h3E3(1ν2)[1ν0ν10001ν][w,110w,220w,120]

Pure bending

The displacements u10 and u20 are zero under pure bending conditions. For an isotropic, homogeneous plate under pure bending the governing equation is

4wx14+24wx12x22+4wx24=0wherew:=w0.

In index notation,

w,11110+2w,12120+w,22220=0.

In direct tensor notation, the governing equation is

22w=0.

Transverse loading

For a transversely loaded plate without axial deformations, the governing equation has the form

4wx14+24wx12x22+4wx24=qD

where

D:=2h3E3(1ν2).

In index notation,

w,11110+2w,12120+w,22220=qD

and in direct notation

22w=qD.

In cylindrical coordinates (r,θ,z), the governing equation is

1rddr[rddr{1rddr(rdwdr)}]=qD.

Orthotropic and homogeneous Kirchhoff plate

For an orthotropic plate

[C11C12C13C12C22C23C13C23C33]=11ν12ν21[E1ν12E20ν21E1E20002G12(1ν12ν21)].

Therefore,

[A11A12A13A21A22A23A31A32A33]=2h1ν12ν21[E1ν12E20ν21E1E20002G12(1ν12ν21)]

and

[D11D12D13D21D22D23D31D32D33]=2h33(1ν12ν21)[E1ν12E20ν21E1E20002G12(1ν12ν21)].

Transverse loading

The governing equation of an orthotropic Kirchhoff plate loaded transversely by a distributed load q per unit area is

Dxw,11110+2Dxyw,11220+Dyw,22220=q

where

Dx=D11=2h3E13(1ν12ν21)Dy=D22=2h3E23(1ν12ν21)Dxy=D33+12(ν21D11+ν12D22)=D33+ν21D11=4h3G123+2h3ν21E13(1ν12ν21).

Dynamics of thin Kirchhoff plates

Mining Engineer (Excluding Oil ) Truman from Alma, loves to spend time knotting, largest property developers in singapore developers in singapore and stamp collecting. Recently had a family visit to Urnes Stave Church. The dynamic theory of plates determines the propagation of waves in the plates, and the study of standing waves and vibration modes.

Governing equations

The governing equations for the dynamics of a Kirchhoff–Love plate are

Nαβ,β=J1u¨α0Mαβ,αβq(x,t)=J1w¨0J3w¨,αα0

where, for a plate with density ρ=ρ(x),

J1:=hhρdx3=2ρh;J3:=hhx32ρdx3=23ρh3

and

u˙i=uit;u¨i=2uit2;ui,α=uixα;ui,αβ=2uixαxβ

The figures below show some vibrational modes of a circular plate.

Isotropic plates

The governing equations simplify considerably for isotropic and homogeneous plates for which the in-plane deformations can be neglected and have the form

D(4w0x14+24w0x12x22+4w0x24)=q(x1,x2,t)2ρh2w0t2.

where D is the bending stiffness of the plate. For a uniform plate of thickness 2h,

D:=2h3E3(1ν2).

In direct notation

D22w0=q(x,y,t)2ρhw¨0.

Mindlin–Reissner theory for thick plates

Mining Engineer (Excluding Oil ) Truman from Alma, loves to spend time knotting, largest property developers in singapore developers in singapore and stamp collecting. Recently had a family visit to Urnes Stave Church. Template:Einstein summation convention In the theory of thick plates, or theory of Raymond Mindlin[4] and Eric Reissner, the normal to the mid-surface remains straight but not necessarily perpendicular to the mid-surface. If φ1 and φ2 designate the angles which the mid-surface makes with the x3 axis then

φ1w,1;φ2w,2

Then the Mindlin–Reissner hypothesis implies that

uα(𝐱)=uα0(x1,x2)x3φα;α=1,2u3(𝐱)=w0(x1,x2)

Strain-displacement relations

Depending on the amount of rotation of the plate normals two different approximations for the strains can be derived from the basic kinematic assumptions.

For small strains and small rotations the strain-displacement relations for Mindlin–Reissner plates are

εαβ=12(uα,β0+uβ,α0)x32(φα,β+φβ,α)εα3=12(w,α0φα)ε33=0

The shear strain, and hence the shear stress, across the thickness of the plate is not neglected in this theory. However, the shear strain is constant across the thickness of the plate. This cannot be accurate since the shear stress is known to be parabolic even for simple plate geometries. To account for the inaccuracy in the shear strain, a shear correction factor (κ) is applied so that the correct amount of internal energy is predicted by the theory. Then

εα3=12κ(w,α0φα)

Equilibrium equations

The equilibrium equations have slightly different forms depending on the amount of bending expected in the plate. For the situation where the strains and rotations of the plate are smallthe equilibrium equations for a Mindlin–Reissner plate are

Nαβ,α=0Mαβ,βQα=0Qα,α+q=0.

The resultant shear forces in the above equations are defined as

Qα:=κhhσα3dx3.

Boundary conditions

The boundary conditions are indicated by the boundary terms in the principle of virtual work.

If the only external force is a vertical force on the top surface of the plate, the boundary conditions are

nαNαβoruβ0nαMαβorφαnαQαorw0

Constitutive relations

The stress-strain relations for a linear elastic Mindlin–Reissner plate are given by

σαβ=Cαβγθεγθσα3=Cα3γθεγθσ33=C33γθεγθ

Since σ33 does not appear in the equilibrium equations it is implicitly assumed that it do not have any effect on the momentum balance and is neglected. This assumption is also called the plane stress assumption. The remaining stress-strain relations for an orthotropic material, in matrix form, can be written as

[σ11σ22σ23σ31σ12]=[C11C12000C12C2200000C4400000C5500000C66][ε11ε22ε23ε31ε12]

Then,

[N11N22N12]={hh[C11C120C12C22000C66]dx3}[u1,10u2,2012(u1,20+u2,10)]

and

[M11M22M12]={hhx32[C11C120C12C22000C66]dx3}[φ1,1φ2,212(φ1,2+φ2,1)]

For the shear terms

[Q1Q2]=κ2{hh[C5500C44]dx3}[w,10φ1w,20φ2]

The extensional stiffnesses are the quantities

Aαβ:=hhCαβdx3

The bending stiffnesses are the quantities

Dαβ:=hhx32Cαβdx3

Isotropic and homogeneous Mindlin-Reissner plates

Mining Engineer (Excluding Oil ) Truman from Alma, loves to spend time knotting, largest property developers in singapore developers in singapore and stamp collecting. Recently had a family visit to Urnes Stave Church. For uniformly thick, homogeneous, and isotropic plates, the stress-strain relations in the plane of the plate are

[σ11σ22σ12]=E1ν2[1ν0ν10001ν][ε11ε22ε12].

where E is the Young's modulus, ν is the Poisson's ratio, and εαβ are the in-plane strains. The through-the-thickness shear stresses and strains are related by

σ31=2Gε31andσ32=2Gε32

where G=E/(2(1+ν)) is the shear modulus.

Constitutive relations

The relations between the stress resultants and the generalized displacements for an isotropic Mindlin–Reissner plate are:

[N11N22N12]=2Eh1ν2[1ν0ν10001ν][u1,10u2,2012(u1,20+u2,10)],
[M11M22M12]=2Eh33(1ν2)[1ν0ν10001ν][φ1,1φ2,212(φ1,2+φ2,1)],

and

[Q1Q2]=κGh[w,10φ1w,20φ2].

The bending rigidity is defined as the quantity

D=2Eh33(1ν2).

For a plate of thickness h, the bending rigidity has the form

D=Eh312(1ν2).

Governing equations

If we ignore the in-plane extension of the plate, the governing equations are

Mαβ,βQα=0Qα,α+q=0.

In terms of the generalized deformations w0,φ1,φ2, the three governing equations are

2(φ1x1+φ2x2)=qD2w0φ1x1φ2x2=qκGh2(φ1x2φ2x1)=2κGhD(1ν)(φ1x2φ2x1).

The boundary conditions along the edges of a rectangular plate are

simply supportedw0=0,M11=0(orM22=0),φ1=0(orφ2=0)clampedw0=0,φ1=0,φ2=0.

Reissner–Stein theory for isotropic cantilever plates

In general, exact solutions for cantilever plates using plate theory are quite involved and few exact solutions can be found in the literature. Reissner and Stein[5] provide a simplified theory for cantilever plates that is an improvement over older theories such as Saint-Venant plate theory.

The Reissner-Stein theory assumes a transverse displacement field of the form

w(x,y)=wx(x)+yθx(x).

The governing equations for the plate then reduce to two coupled ordinary differential equations:

bDd4wxdx4=q1(x)n1(x)d2wxdx2dn1dxdwxdx12dn2dxdθxdxn2(x)2d2θxdx2b3D12d4θxdx42bD(1ν)d2θxdx2=q2(x)n3(x)d2θxdx2dn3dxdθxdxn2(x)2d2wxdx212dn2dxdwxdx

where

q1(x)=b/2b/2q(x,y)dy,q2(x)=b/2b/2yq(x,y)dy,n1(x)=b/2b/2nx(x,y)dyn2(x)=b/2b/2ynx(x,y)dy,n3(x)=b/2b/2y2nx(x,y)dy.

At x=0, since the beam is clamped, the boundary conditions are

w(0,y)=dwdx|x=0=0wx(0)=dwxdx|x=0=θx(0)=dθxdx|x=0=0.

The boundary conditions at x=a are

bDd3wxdx3+n1(x)dwxdx+n2(x)dθxdx+qx1=0b3D12d3θxdx3+[n3(x)2bD(1ν)]dθxdx+n2(x)dwxdx+t=0bDd2wxdx2+m1=0,b3D12d2θxdx2+m2=0

where

m1=b/2b/2mx(y)dy,m2=b/2b/2ymx(y)dy,qx1=b/2b/2qx(y)dyt=qx2+m3=b/2b/2yqx(y)dy+b/2b/2mxy(y)dy.

References

  1. Timoshenko, S. and Woinowsky-Krieger, S. "Theory of plates and shells". McGraw–Hill New York, 1959.
  2. A. E. H. Love, On the small free vibrations and deformations of elastic shells, Philosophical trans. of the Royal Society (London), 1888, Vol. série A, N° 17 p. 491–549.
  3. Reddy, J. N., 2007, Theory and analysis of elastic plates and shells, CRC Press, Taylor and Francis.
  4. R. D. Mindlin, Influence of rotatory inertia and shear on flexural motions of isotropic, elastic plates, Journal of Applied Mechanics, 1951, Vol. 18 p. 31–38.
  5. E. Reissner and M. Stein. Torsion and transverse bending of cantilever plates. Technical Note 2369, National Advisory Committee for Aeronautics,Washington, 1951.

See also

ca:Teoria de plaques i làmines de:Plattentheorie gl:Laxe (construción)