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{{For|the construction machine|plate compactor}}
[[Image:ESPIvibration.jpg|thumb | 250px | right| Vibration mode of a clamped square plate]]
The '''vibration of plates''' is a special case of the more general problem of mechanical [[vibration]]s. The equations governing the motion of plates are simpler than those for general three-dimensional objects because one of the dimensions of a plate is much smaller than the other two.  This suggests that a two-dimensional [[plate theory]] will give an excellent approximation to the actual three-dimensional motion of a plate-like object, and indeed that is found to be true.<ref name=Reddy>Reddy, J. N., 2007, '''Theory and analysis of elastic plates and shells''', CRC Press, Taylor and Francis.</ref>
 
There are several theories that have been developed to describe the motion of plates.  The most commonly used are the [[Kirchhoff–Love plate theory|Kirchhoff-Love theory]]<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> and the
[[Mindlin–Reissner plate theory|Mindlin-Reissner theory]].  Solutions to the governing equations predicted by these theories can give us insight into the behavior of plate-like objects both under [[free vibration|free]] and [[forced vibration|forced]] conditions.  This includes
the propagation of waves and the study of standing waves and vibration modes in plates.
 
==Kirchhoff-Love plates==
{{main|Kirchhoff–Love plate theory#Dynamics of Kirchhoff-Love plates}}
The governing equations for the dynamics of a Kirchhoff-Love plate are
:<math>
  \begin{align}
    N_{\alpha\beta,\beta} & = J_1~\ddot{u}_\alpha \\
    M_{\alpha\beta,\alpha\beta} - q(x,t) & = J_1~\ddot{w} - J_3~\ddot{w}_{,\alpha\alpha}
  \end{align}
</math>
where <math>u_\alpha</math> are the in-plane displacements of the mid-surface of the plate, <math>w</math> is the transverse (out-of-plane) displacement of the mid-surface of the plate, <math>q</math> is an applied transverse load, and the resultant forces and moments are defined as
:<math>
  N_{\alpha\beta} := \int_{-h}^h \sigma_{\alpha\beta}~dx_3 \quad \text{and} \quad
  M_{\alpha\beta} := \int_{-h}^h x_3~\sigma_{\alpha\beta}~dx_3 \,.
</math>
Note that the thickness of the plate is <math>2h</math> and that the resultants are defined as weighted averages of the in-plane stresses <math>\sigma_{\alpha\beta}</math>. The derivatives in the governing equations are defined as
:<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>
where the Latin indices go from 1 to 3 while the Greek indices go from 1 to 2.  Summation over repeated indices is implied.  The <math>x_3</math> coordinates is out-of-plane while the coordinates <math>x_1</math> and <math>x_2</math> are in plane.
For a uniformly thick plate of thickness <math>2h</math> and homogeneous mass density <math>\rho</math>
:<math>
  J_1 := \int_{-h}^h \rho~dx_3 = 2\rho h \quad \text{and} \quad
  J_3 := \int_{-h}^h x_3^2~\rho~dx_3 = \frac{2}{3}\rho h^3 \,.
</math>
 
==Isotropic Kirchhoff–Love plates==
{{main|Kirchhoff–Love plate theory#Isotropic plates}}
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>
where <math>\varepsilon_{\alpha\beta}</math> are the in-plane strains.  The strain-displacement relations
for Kirchhoff-Love plates are
:<math>
  \varepsilon_{\alpha\beta} = \frac{1}{2}(u_{\alpha,\beta}+u_{\beta,\alpha})
      - x_3\,w_{,\alpha\beta} \,.
</math>
Therefore, the resultant 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_{,11} \\ w_{,22} \\ w_{,12} \end{bmatrix}
</math>
If we ignore the in-plane displacements <math>u_{\alpha\beta}</math>, the governing equations reduce to
:<math>
  D\nabla^2\nabla^2 w = -q(x,t) - 2\rho h\ddot{w} \,.
</math>
The above equation can also be written in an alternative notation:
:<math>
  \mu \Delta\Delta w + \hat{q} + \rho w_{tt}= 0\,.
</math>
In [[solid mechanics]], a plate is often modeled as a two-dimensional elastic body whose potential energy depends on how it is bent from a planar configuration, rather than how it is stretched (which is the instead the case for a membrane such as a drumhead).  In such situations, a '''vibrating plate''' can be modeled in a manner analogous to a [[Vibrations of a circular drum|vibrating drum]].  However, the resulting [[partial differential equation]] for the vertical displacement ''w'' of a plate from its equilibrium position is fourth order, involving the square of the [[Laplacian]] of ''w'', rather than second order, and its qualitative behavior is fundamentally different from that of the circular membrane drum.
 
==Free vibrations of isotropic plates==
For free vibrations, the external force ''q'' is zero, and the governing equation of an isotropic plate reduces to
:<math>
  D\nabla^2\nabla^2 w = - 2\rho h\ddot{w}
</math>
or
:<math>
  \mu \Delta\Delta w + \rho w_{tt}= 0\,.
</math>
This relation can be derived in an alternative manner by considering the curvature of the plate.<ref>{{Citation | last1=Courant | first1=Richard | last2=Hilbert | first2=David | author2-link=David Hilbert | title=Methods of mathematical physics. Vol. I | publisher=Interscience Publishers, Inc., New York, N.Y. | id={{MathSciNet | id = 0065391}} | year=1953}}</ref>  The potential energy density of a plate depends how the plate is deformed, and so on the [[mean curvature]] and [[Gaussian curvature]] of the plate. For small deformations, the mean curvature is expressed in terms of ''w'', the vertical displacement of the plate from kinetic equilibrium, as Δ''w'', the Laplacian of ''w'', and the Gaussian curvature is the [[Monge–Ampère equation|Monge–Ampère operator]] ''w<sub>xx</sub>w<sub>yy</sub>''&minus;''w''{{su|b=''xy''|p=2}}.  The total potential energy of a plate Ω therefore has the form
:<math>U = \int_\Omega [(\Delta w)^2 +(1-\mu)(w_{xx}w_{yy}-w_{xy}^2)]\,dx\,dy</math>
apart from an overall inessential normalization constant.  Here μ is a constant depending on the properties of the material.
 
The kinetic energy is given by an integral of the form
:<math>T = \frac{\rho}{2}\int_\Omega w_t^2\, dx\, dy.</math>
[[Hamilton's principle]] asserts that ''w'' is a stationary point with respect to [[calculus of variations|variations]] of the total energy ''T''+''U''.  The resulting partial differential equation is
:<math>\rho w_{tt} + \mu \Delta\Delta w = 0.\,</math>
 
===Circular plates===
For freely vibrating circular plates, <math> w = w(r,t)</math>, and the Laplacian in cylindrical coordinates has the form
:<math>
  \nabla^2 w \equiv \frac{1}{r}\frac{\partial }{\partial r}\left(r \frac{\partial w}{\partial r}\right) \,.
</math>
Therefore, the governing equation for free vibrations of a circular plate of thickness <math>2h</math> is
:<math>
  \frac{1}{r}\frac{\partial }{\partial r}\left[r \frac{\partial }{\partial r}\left\{\frac{1}{r}\frac{\partial }{\partial r}\left(r \frac{\partial w}{\partial r}\right)\right\}\right] = -\frac{2\rho h}{D}\frac{\partial^2 w}{\partial t^2}\,.
</math>
Expanded out,
:<math>
  \frac{\partial^4 w}{\partial r^4} + \frac{2}{r} \frac{\partial^3 w}{\partial r^3} - \frac{1}{r^2} \frac{\partial^2 w}{\partial r^2} + \frac{1}{r^3} \frac{\partial w}{\partial r} = -\frac{2\rho h}{D}\frac{\partial^2 w}{\partial t^2}\,.
</math>
To solve this equation we use the idea of [[separation of variables]] and assume a solution of the form
:<math>
  w(r,t) = W(r)F(t) \,.
</math>
Plugging this assumed solution into the governing equation gives us
:<math>
  \frac{1}{\beta W}\left[\frac{d^4 W}{dr^4} + \frac{2}{r}\frac{d^3 W}{dr^3} - \frac{1}{r^2}\frac{d^2W}{dr^2}
  + \frac{1}{r^3} \frac{d W}{dr}\right] = -\frac{1}{F}\cfrac{d^2 F}{d t^2} = \omega^2
</math>
where <math>\omega^2</math> is a constant and <math>\beta := 2\rho h/D</math>.  The solution of the right hand equation is
:<math>
  F(t) = \text{Re}[ A e^{i\omega t} + B e^{-i\omega t}] \,.
</math>
The left hand side equation can be written as
:<math>
  \frac{d^4 W}{dr^4} + \frac{2}{r}\frac{d^3 W}{dr^3} - \frac{1}{r^2}\frac{d^2W}{dr^2}
    + \frac{1}{r^3} \cfrac{d W}{d r} = \lambda^4 W
</math>
where <math>\lambda^4 := \beta\omega^2</math>.  The general solution of this [[eigenvalue]] problem that is
appropriate for plates has the form
:<math>
  W(r) = C_1 J_0(\lambda r) + C_2 I_0(\lambda r)
</math>
where <math>J_0</math> is the order 0 [[Bessel function]] of the first kind and <math>I_0</math> is the order 0 [[modified Bessel function]] of the first kind.  The constants <math>C_1</math> and <math>C_2</math> are determined from the boundary conditions.  For a plate of radius <math>a</math> with a clamped circumference, the boundary conditions are
:<math>
  W(r) = 0 \quad \text{and} \quad \cfrac{d W}{d r} = 0 \quad \text{at} \quad r = a \,.
</math>
From these boundary conditions we find that
:<math>
  J_0(\lambda a)I_1(\lambda a) + I_0(\lambda a)J_1(\lambda a) = 0 \,.
</math>
We can solve this equation for <math>\lambda_n</math> (and there are an infinite number of roots) and from that find the modal frequencies <math>\omega_n = \lambda_n^2/\beta</math>.  We can also express the displacement in the form
:<math>
  w(r,t) = \sum_{n=1}^\infty C_n\left[J_0(\lambda_n r) - \frac{J_0(\lambda_n a)}{I_0(\lambda_n a)}I_0(\lambda_n r)\right]
    [A_n e^{i\omega_n t} + B_n e^{-i\omega_n t}] \,.
</math>
For a given frequency <math>\omega_n</math> the first term inside the sum in the above equation gives the mode shape.  We can find the value
of <math>C_1</math> using the appropriate boundary condition at <math>r = 0</math> and the coefficients <math>A_n</math> and <math>B_n</math> from the initial conditions by taking advantage of the orthogonality of Fourier components.
<gallery widths="250px">
Image:Drum vibration mode01.gif|mode ''n'' = 1
Image:Drum vibration mode02.gif|mode ''n'' = 2
</gallery>
 
=== Rectangular plates ===
Consider a rectangular plate which has dimensions <math>a\times b</math> in the <math>(x_1,x_2)</math>-plane and thickness <math>2h</math> in the <math>x_3</math>-direction.  We seek to find the free vibration modes of the plate.
 
Assume a displacement field of the form
:<math>
  w(x_1,x_2,t) = W(x_1,x_2) F(t) \,.
</math>
Then,
:<math>
  \nabla^2\nabla^2 w = w_{,1111} + 2w_{,1212} + w_{,2222}
    = \left[\frac{\partial^4 W}{\partial x_1^4} + 2\frac{\partial^4 W}{\partial x_1^2 \partial x_2^2} + \frac{\partial^4W}{\partial x_2^4}\right] F(t)
</math>
and
:<math>
  \ddot{w} = W(x_1,x_2)\frac{d^2F}{dt^2} \,.
</math>
Plugging these into the governing equation gives
:<math>
  \frac{D}{2\rho h W}\left[\frac{\partial^4 W}{\partial x_1^4} + 2\frac{\partial^4 W}{\partial x_1^2 \partial x_2^2} + \frac{\partial^4W}{\partial x_2^4}\right] 
  = -\frac{1}{F}\frac{d^2F}{dt^2} = \omega^2
</math>
where <math>\omega^2</math> is a constant because the left hand side is independent of <math>t</math> while the right hand side is independent of <math>x_1,x_2</math>.  From the right hand side, we then have
:<math>
  F(t) = A e^{i\omega t} + B e^{-i\omega t} \,.
</math>
From the left hand side,
:<math>
  \frac{\partial^4 W}{\partial x_1^4} + 2\frac{\partial^4 W}{\partial x_1^2 \partial x_2^2} + \frac{\partial^4W}{\partial x_2^4}
  = \frac{2\rho h \omega^2}{D} W =: \lambda^4 W
</math>
where
:<math>
  \lambda^2 = \omega\sqrt{\frac{2\rho h}{D}} \,.
</math>
Since the above equation is a [[biharmonic]] eigenvalue problem, we look for Fourier expansion
solutions of the form
:<math>
  W_{mn}(x_1,x_2) = \sin\frac{m\pi x_1}{a}\sin\frac{n\pi x_2}{b} \,.
</math>
We can check and see that this solution satisfies the boundary conditions for a freely vibrating
rectangular plate with simply supported edges:
:<math>
  \begin{align}
    w(x_1,x_2,t) = 0 & \quad \text{at}\quad x_1 = 0, a \quad \text{and} \quad x_2 = 0, b \\
    M_{11} = D\left(\frac{\partial^2 w}{\partial x_1^2} + \nu\frac{\partial^2 w}{\partial x_2^2}\right) = 0
      & \quad \text{at}\quad x_1 = 0, a \\
    M_{22} = D\left(\frac{\partial^2 w}{\partial x_2^2} + \nu\frac{\partial^2 w}{\partial x_1^2}\right) = 0
      & \quad \text{at}\quad x_2 = 0, b \,.
  \end{align}
</math>
Plugging the solution into the biharmonic equation gives us
:<math>
  \lambda^2 = \pi^2\left(\frac{m^2}{a^2} + \frac{n^2}{b^2}\right) \,.
</math>
Comparison with the previous expression for <math>\lambda^2</math> indicates that we can have an infinite
number of solutions with
:<math>
  \omega_{mn} = \sqrt{\frac{D\pi^4}{2\rho h}}\left(\frac{m^2}{a^2} + \frac{n^2}{b^2}\right) \,.
</math>
Therefore the general solution for the plate equation is
:<math>
  w(x_1,x_2,t) = \sum_{m=1}^\infty \sum_{n=1}^\infty \sin\frac{m\pi x_1}{a}\sin\frac{n\pi x_2}{b}
    \left( A_{mn} e^{i\omega_{mn} t} + B_{mn} e^{-i\omega_{mn} t}\right) \,.
</math>
To find the values of <math>A_{mn}</math> and <math>B_{mn}</math> we use initial conditions and the orthogonality of Fourier components.  For example, if
:<math>
  w(x_1,x_2,0) = \varphi(x_1,x_2) \quad \text{on} \quad x_1 \in [0,a] \quad \text{and} \quad
  \frac{\partial w}{\partial t}(x_1,x_2,0) = \psi(x_1,x_2)\quad \text{on} \quad x_2 \in [0,b] 
</math>
we get,
:<math>
  \begin{align}
    A_{mn} & = \frac{4}{ab}\int_0^a \int_0^b \varphi(x_1,x_2)
                \sin\frac{m\pi x_1}{a}\sin\frac{n\pi x_2}{b} dx_1 dx_2 \\
    B_{mn} & = \frac{4}{ab\omega_{mn}}\int_0^a \int_0^b \psi(x_1,x_2)
                \sin\frac{m\pi x_1}{a}\sin\frac{n\pi x_2}{b}  dx_1 dx_2\,.
  \end{align}
</math>
 
== References ==
<references/>
 
== See also ==
*[[Bending]]
*[[Bending of plates]]
*[[Infinitesimal strain theory]]
*[[Kirchhoff–Love plate theory]]
*[[Linear elasticity]]
*[[Mindlin–Reissner plate theory]]
*[[Plate theory]]
*[[Stress (mechanics)]]
*[[Stress resultants]]
*[[Structural acoustics]]
 
{{DEFAULTSORT:Vibration Of Plates}}
[[Category:Continuum mechanics]]

Latest revision as of 19:28, 5 August 2013

28 year-old Painting Investments Worker Truman from Regina, usually spends time with pastimes for instance interior design, property developers in new launch ec Singapore and writing. Last month just traveled to City of the Renaissance.

Vibration mode of a clamped square plate

The vibration of plates is a special case of the more general problem of mechanical vibrations. The equations governing the motion of plates are simpler than those for general three-dimensional objects because one of the dimensions of a plate is much smaller than the other two. This suggests that a two-dimensional plate theory will give an excellent approximation to the actual three-dimensional motion of a plate-like object, and indeed that is found to be true.[1]

There are several theories that have been developed to describe the motion of plates. The most commonly used are the Kirchhoff-Love theory[2] and the Mindlin-Reissner theory. Solutions to the governing equations predicted by these theories can give us insight into the behavior of plate-like objects both under free and forced conditions. This includes the propagation of waves and the study of standing waves and vibration modes in plates.

Kirchhoff-Love 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 governing equations for the dynamics of a Kirchhoff-Love plate are

Nαβ,β=J1u¨αMαβ,αβq(x,t)=J1w¨J3w¨,αα

where uα are the in-plane displacements of the mid-surface of the plate, w is the transverse (out-of-plane) displacement of the mid-surface of the plate, q is an applied transverse load, and the resultant forces and moments are defined as

Nαβ:=hhσαβdx3andMαβ:=hhx3σαβdx3.

Note that the thickness of the plate is 2h and that the resultants are defined as weighted averages of the in-plane stresses σαβ. The derivatives in the governing equations are defined as

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

where the Latin indices go from 1 to 3 while the Greek indices go from 1 to 2. Summation over repeated indices is implied. The x3 coordinates is out-of-plane while the coordinates x1 and x2 are in plane. For a uniformly thick plate of thickness 2h and homogeneous mass density ρ

J1:=hhρdx3=2ρhandJ3:=hhx32ρdx3=23ρh3.

Isotropic Kirchhoff–Love 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 an isotropic and homogeneous plate, the stress-strain relations are

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

where εαβ are the in-plane strains. The strain-displacement relations for Kirchhoff-Love plates are

εαβ=12(uα,β+uβ,α)x3w,αβ.

Therefore, the resultant moments corresponding to these stresses are

[M11M22M12]=2h3E3(1ν2)[1ν0ν10001ν][w,11w,22w,12]

If we ignore the in-plane displacements uαβ, the governing equations reduce to

D22w=q(x,t)2ρhw¨.

The above equation can also be written in an alternative notation:

μΔΔw+q^+ρwtt=0.

In solid mechanics, a plate is often modeled as a two-dimensional elastic body whose potential energy depends on how it is bent from a planar configuration, rather than how it is stretched (which is the instead the case for a membrane such as a drumhead). In such situations, a vibrating plate can be modeled in a manner analogous to a vibrating drum. However, the resulting partial differential equation for the vertical displacement w of a plate from its equilibrium position is fourth order, involving the square of the Laplacian of w, rather than second order, and its qualitative behavior is fundamentally different from that of the circular membrane drum.

Free vibrations of isotropic plates

For free vibrations, the external force q is zero, and the governing equation of an isotropic plate reduces to

D22w=2ρhw¨

or

μΔΔw+ρwtt=0.

This relation can be derived in an alternative manner by considering the curvature of the plate.[3] The potential energy density of a plate depends how the plate is deformed, and so on the mean curvature and Gaussian curvature of the plate. For small deformations, the mean curvature is expressed in terms of w, the vertical displacement of the plate from kinetic equilibrium, as Δw, the Laplacian of w, and the Gaussian curvature is the Monge–Ampère operator wxxwyywTemplate:Su. The total potential energy of a plate Ω therefore has the form

U=Ω[(Δw)2+(1μ)(wxxwyywxy2)]dxdy

apart from an overall inessential normalization constant. Here μ is a constant depending on the properties of the material.

The kinetic energy is given by an integral of the form

T=ρ2Ωwt2dxdy.

Hamilton's principle asserts that w is a stationary point with respect to variations of the total energy T+U. The resulting partial differential equation is

ρwtt+μΔΔw=0.

Circular plates

For freely vibrating circular plates, w=w(r,t), and the Laplacian in cylindrical coordinates has the form

2w1rr(rwr).

Therefore, the governing equation for free vibrations of a circular plate of thickness 2h is

1rr[rr{1rr(rwr)}]=2ρhD2wt2.

Expanded out,

4wr4+2r3wr31r22wr2+1r3wr=2ρhD2wt2.

To solve this equation we use the idea of separation of variables and assume a solution of the form

w(r,t)=W(r)F(t).

Plugging this assumed solution into the governing equation gives us

1βW[d4Wdr4+2rd3Wdr31r2d2Wdr2+1r3dWdr]=1Fd2Fdt2=ω2

where ω2 is a constant and β:=2ρh/D. The solution of the right hand equation is

F(t)=Re[Aeiωt+Beiωt].

The left hand side equation can be written as

d4Wdr4+2rd3Wdr31r2d2Wdr2+1r3dWdr=λ4W

where λ4:=βω2. The general solution of this eigenvalue problem that is appropriate for plates has the form

W(r)=C1J0(λr)+C2I0(λr)

where J0 is the order 0 Bessel function of the first kind and I0 is the order 0 modified Bessel function of the first kind. The constants C1 and C2 are determined from the boundary conditions. For a plate of radius a with a clamped circumference, the boundary conditions are

W(r)=0anddWdr=0atr=a.

From these boundary conditions we find that

J0(λa)I1(λa)+I0(λa)J1(λa)=0.

We can solve this equation for λn (and there are an infinite number of roots) and from that find the modal frequencies ωn=λn2/β. We can also express the displacement in the form

w(r,t)=n=1Cn[J0(λnr)J0(λna)I0(λna)I0(λnr)][Aneiωnt+Bneiωnt].

For a given frequency ωn the first term inside the sum in the above equation gives the mode shape. We can find the value of C1 using the appropriate boundary condition at r=0 and the coefficients An and Bn from the initial conditions by taking advantage of the orthogonality of Fourier components.

Rectangular plates

Consider a rectangular plate which has dimensions a×b in the (x1,x2)-plane and thickness 2h in the x3-direction. We seek to find the free vibration modes of the plate.

Assume a displacement field of the form

w(x1,x2,t)=W(x1,x2)F(t).

Then,

22w=w,1111+2w,1212+w,2222=[4Wx14+24Wx12x22+4Wx24]F(t)

and

w¨=W(x1,x2)d2Fdt2.

Plugging these into the governing equation gives

D2ρhW[4Wx14+24Wx12x22+4Wx24]=1Fd2Fdt2=ω2

where ω2 is a constant because the left hand side is independent of t while the right hand side is independent of x1,x2. From the right hand side, we then have

F(t)=Aeiωt+Beiωt.

From the left hand side,

4Wx14+24Wx12x22+4Wx24=2ρhω2DW=:λ4W

where

λ2=ω2ρhD.

Since the above equation is a biharmonic eigenvalue problem, we look for Fourier expansion solutions of the form

Wmn(x1,x2)=sinmπx1asinnπx2b.

We can check and see that this solution satisfies the boundary conditions for a freely vibrating rectangular plate with simply supported edges:

w(x1,x2,t)=0atx1=0,aandx2=0,bM11=D(2wx12+ν2wx22)=0atx1=0,aM22=D(2wx22+ν2wx12)=0atx2=0,b.

Plugging the solution into the biharmonic equation gives us

λ2=π2(m2a2+n2b2).

Comparison with the previous expression for λ2 indicates that we can have an infinite number of solutions with

ωmn=Dπ42ρh(m2a2+n2b2).

Therefore the general solution for the plate equation is

w(x1,x2,t)=m=1n=1sinmπx1asinnπx2b(Amneiωmnt+Bmneiωmnt).

To find the values of Amn and Bmn we use initial conditions and the orthogonality of Fourier components. For example, if

w(x1,x2,0)=φ(x1,x2)onx1[0,a]andwt(x1,x2,0)=ψ(x1,x2)onx2[0,b]

we get,

Amn=4ab0a0bφ(x1,x2)sinmπx1asinnπx2bdx1dx2Bmn=4abωmn0a0bψ(x1,x2)sinmπx1asinnπx2bdx1dx2.

References

  1. Reddy, J. N., 2007, Theory and analysis of elastic plates and shells, CRC Press, Taylor and Francis.
  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.
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