Föppl–von Kármán Equations
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The Föppl–von Kármán equations, named after August Föppl and
Theodore von Kármán Theodore von Kármán ( hu, ( szőllőskislaki) Kármán Tódor ; born Tivadar Mihály Kármán; 11 May 18816 May 1963) was a Hungarian-American mathematician, aerospace engineer, and physicist who was active primarily in the fields of aeronaut ...
, are a set of nonlinear
partial differential equation In mathematics, a partial differential equation (PDE) is an equation which imposes relations between the various partial derivatives of a multivariable function. The function is often thought of as an "unknown" to be solved for, similarly to ...
s describing the large deflections of thin flat plates. With applications ranging from the design of submarine hulls to the mechanical properties of cell wall, the equations are notoriously difficult to solve, and take the following form: "Theory of Elasticity". L. D. Landau, E. M. Lifshitz, (3rd ed. ) : \begin (1) \qquad & \frac\nabla^4 w-h\frac\left(\sigma_\frac\right)=P \\ (2) \qquad & \frac=0 \end where is the
Young's modulus Young's modulus E, the Young modulus, or the modulus of elasticity in tension or compression (i.e., negative tension), is a mechanical property that measures the tensile or compressive stiffness of a solid material when the force is applied ...
of the plate material (assumed homogeneous and isotropic), is the
Poisson's ratio In materials science and solid mechanics, Poisson's ratio \nu ( nu) is a measure of the Poisson effect, the deformation (expansion or contraction) of a material in directions perpendicular to the specific direction of loading. The value of Po ...
, is the thickness of the plate, is the out–of–plane deflection of the plate, is the external normal force per unit area of the plate, is the
Cauchy stress tensor In continuum mechanics, the Cauchy stress tensor \boldsymbol\sigma, true stress tensor, or simply called the stress tensor is a second order tensor named after Augustin-Louis Cauchy. The tensor consists of nine components \sigma_ that completely ...
, and are indices that take values of 1 and 2 (the two orthogonal in-plane directions). The 2-dimensional biharmonic operator is defined as : \nabla^4 w := \frac\left frac\right = \frac + \frac + 2\frac \,. Equation (1) above can be derived from
kinematic Kinematics is a subfield of physics, developed in classical mechanics, that describes the motion of points, bodies (objects), and systems of bodies (groups of objects) without considering the forces that cause them to move. Kinematics, as a fiel ...
assumptions and the constitutive relations for the plate. Equations (2) are the two equations for the conservation of linear momentum in two dimensions where it is assumed that the out–of–plane stresses () are zero.


Validity of the Föppl–von Kármán equations

While the Föppl–von Kármán equations are of interest from a purely mathematical point of view, the physical validity of these equations is questionable. Ciarlet states: ''The two-dimensional von Karman equations for plates, originally proposed by von Karman 910 play a mythical role in applied mathematics. While they have been abundantly, and satisfactorily, studied from the mathematical standpoint, as regards notably various questions of existence, regularity, and bifurcation, of their solutions, their physical soundness has been often seriously questioned.'' Reasons include the facts that # the theory depends on an approximate geometry which is not clearly defined # a given variation of stress over a cross-section is assumed arbitrarily # a linear constitutive relation is used that does not correspond to a known relation between well defined measures of stress and strain # some components of strain are arbitrarily ignored # there is a confusion between reference and deformed configurations which makes the theory inapplicable to the large deformations for which it was apparently devised. Conditions under which these equations are actually applicable and will give reasonable results when solved are discussed in Ciarlet.


Equations in terms of Airy stress function

The three Föppl–von Kármán equations can be reduced to two by introducing the Airy stress function \varphi where : \sigma_ = \frac ~,~~ \sigma_ = \frac ~,~~ \sigma_ = - \frac \,. Equation (1) becomes : \frac\Delta^2 w-h\left(\frac\frac+\frac\frac-2\frac\frac\right)=P while the Airy function satisfies, by construction the force balance equation (2). An equation for \varphi is obtained enforcing the representation of the strain as a function of the stress. One gets "Theory of Elasticity". L. D. Landau, E. M. Lifshitz, (3rd ed. ) : \Delta^2\varphi+E\left\=0 \,.


Pure bending

For the
pure bending Pure bending ( Theory of simple bending) is a condition of stress where a bending moment is applied to a beam without the simultaneous presence of Cylinder stress, axial, Shear stress, shear, or Deformation (mechanics), torsional forces. Pure bendin ...
of thin plates the equation of equilibrium is D\Delta^2\ w=P, where : D :=\frac is called flexural or ''cylindrical rigidity'' of the plate.


Kinematic assumptions (Kirchhoff hypothesis)

In the derivation of the Föppl–von Kármán equations the main kinematic assumption (also known as the Kirchhoff hypothesis) is that
surface normal In geometry, a normal is an object such as a line, ray, or vector that is perpendicular to a given object. For example, the normal line to a plane curve at a given point is the (infinite) line perpendicular to the tangent line to the curve ...
s to the plane of the plate remain perpendicular to the plate after deformation. It is also assumed that the in-plane (membrane) displacements are small and the change in thickness of the plate is negligible. These assumptions imply that the displacement field in the plate can be expressed as : u_1(x_1,x_2,x_3) = v_1(x_1,x_2)-x_3\,\frac ~,~~ u_2(x_1,x_2,x_3) = v_2(x_1,x_2)-x_3\,\frac ~,~~ u_3(x_1, x_2, x_3) = w(x_1,x_2) in which is the in-plane (membrane) displacement. This form of the displacement field implicitly assumes that the amount of rotation of the plate is small.


Strain-displacement relations (von Kármán strains)

The components of the three-dimensional Lagrangian Green strain tensor are defined as : E_ := \frac\left frac + \frac + \frac\,\frac\right\,. Substitution of the expressions for the displacement field into the above gives : \begin E_ & = \frac + \frac\left left(\frac\right)^2 + \left(\frac\right)^2 + \left(\frac\right)^2\right\ &= \frac - x_3\,\frac + \frac\left _3^2\left(\frac\right)^2 + x_3^2\left(\frac\right)^2 + \left(\frac\right)^2\right\ E_ & = \frac + \frac\left left(\frac\right)^2 + \left(\frac\right)^2 + \left(\frac\right)^2\right\ &= \frac-x_3\,\frac + \frac\left _3^2\left(\frac\right)^2 + x_3^2\left(\frac\right)^2 + \left(\frac\right)^2\right\ E_ & = \frac + \frac\left left(\frac\right)^2 + \left(\frac\right)^2 + \left(\frac\right)^2\right\ &= \frac\left left(\frac\right)^2 + \left(\frac\right)^2 \right\ E_ & = \frac\left frac + \frac + \frac\,\frac + \frac\,\frac + \frac\,\frac\right\ & = \frac\frac + \frac\frac -x_3\frac + \frac\left _3^2\left(\frac\right)\left(\frac\right) + x_3^2\left(\frac\right)\left(\frac\right) + \frac\,\frac\right\ E_ & = \frac\left frac + \frac + \frac\,\frac + \frac\,\frac + \frac\,\frac\right\ & = \frac\left _3\left(\frac\right)\left(\frac\right) + x_3\left(\frac\right)\left(\frac\right) \right\ E_ & = \frac\left frac + \frac + \frac\,\frac + \frac\,\frac + \frac\,\frac\right\\ & = \frac\left _3\left(\frac\right)\left(\frac\right) + x_3\left(\frac\right)\left(\frac\right) \right \end For small strains but moderate rotations, the higher order terms that cannot be neglected are : \left(\frac\right)^2 ~,~~ \left(\frac\right)^2 ~,~~ \frac\,\frac \,. Neglecting all other higher order terms, and enforcing the requirement that the plate does not change its thickness, the strain tensor components reduce to the von Kármán strains : \begin E_ & = \frac + \frac\left(\frac\right)^2 -x_3\,\frac \\ E_ & = \frac + \frac\left(\frac\right)^2 -x_3\,\frac \\ E_ & = \frac\left(\frac+\frac\right) + \frac\,\frac\,\frac -x_3\frac \\ E_ & = 0 ~,~~ E_ = 0 ~,~~ E_ = 0 \,. \end The first terms are the usual small-strains, for the mid-surface. The second terms, involving squares of displacement gradients, are non-linear, and need to be considered when the plate bending is fairly large (when the rotations are about 10 – 15 degrees). These first two terms together are called the membrane strains. The last terms, involving second derivatives, are the flexural (bending) strains. They involve the curvatures. These zero terms are due to the assumptions of the classical plate theory, which assume elements normal to the mid-plane remain inextensible and line elements perpendicular to the mid-plane remain normal to the mid-plane after deformation.


Stress–strain relations

If we assume that the
Cauchy stress tensor In continuum mechanics, the Cauchy stress tensor \boldsymbol\sigma, true stress tensor, or simply called the stress tensor is a second order tensor named after Augustin-Louis Cauchy. The tensor consists of nine components \sigma_ that completely ...
components are linearly related to the von Kármán strains by
Hooke's law In physics, Hooke's law is an empirical law which states that the force () needed to extend or compress a spring by some distance () scales linearly with respect to that distance—that is, where is a constant factor characteristic of ...
, the plate is isotropic and homogeneous, and that the plate is under a plane stress condition,Typically, an assumption of zero out-of-plane stress is made at this point. we have = = = 0 and : \begin\sigma_ \\ \sigma_ \\ \sigma_ \end = \cfrac \begin 1 & \nu & 0 \\ \nu & 1 & 0 \\ 0 & 0 & 1-\nu \end \begin E_ \\ E_ \\ E_ \end Expanding the terms, the three non-zero stresses are : \begin \sigma_ &= \cfrac\left[\left(\frac + \frac\left(\frac\right)^2 -x_3\,\frac \right) + \nu\left(\frac + \frac\left(\frac\right)^2 -x_3\,\frac \right) \right] \\ \sigma_ &= \cfrac\left[\nu\left(\frac + \frac\left(\frac\right)^2 -x_3\,\frac \right) + \left(\frac + \frac\left(\frac\right)^2 -x_3\,\frac \right) \right] \\ \sigma_ &= \cfrac\left frac\left(\frac+\frac\right) + \frac\,\frac\,\frac -x_3\frac \right\,. \end


Stress resultants

The
stress resultants Stress resultants are simplified representations of the stress state in structural elements such as beams, plates, or shells. The geometry of typical structural elements allows the internal stress state to be simplified because of the existen ...
in the plate are defined as : N_ := \int_^ \sigma_\, d x_3 ~,~~ M_ := \int_^ x_3\,\sigma_\, d x_3 \,. Therefore, : \begin N_ &= \cfrac\left \frac + \left(\frac\right)^2 + 2\nu\frac + \nu\left(\frac\right)^2 \right\\ N_ &= \cfrac\left \nu\frac + \nu\left(\frac\right)^2 + 2\frac + \left(\frac\right)^2 \right\\ N_ &= \cfrac\left frac + \frac + \frac\,\frac \right \end the elimination of the in-plane displacements leads to \begin \frac\left (1 + \nu)\frac - \frac + \nu\frac - \frac + \nu\frac\right = \left frac\frac - \left(\frac\right)^2\right\end and : \begin M_ &= -\cfrac\left frac +\nu \,\frac \right\\ M_ &= -\cfrac\left nu \,\frac +\frac \right\\ M_ &= -\cfrac\,\frac \,. \end Solutions are easier to find when the governing equations are expressed in terms of stress resultants rather than the in-plane stresses.


Equations of Equilibrium

The weak form of the Kirchhoff plate is : \int_\int_^\rho \ddot_i\delta u_i \,d\Omega dx_3+ \int_\int_^ \sigma_\delta E_\,d\Omega dx_3 + \int_\int_^ p_i \delta u_i \,d\Omega dx_3 =0 here Ω denotes the mid-plane. The weak form leads to : \begin \int_\rho h \ddot_1 \delta v_1 \,d\Omega &+ \int_ N_\frac + N_\frac\,d\Omega = -\int_ p_1 \delta v_1 \,d\Omega \\ \int_\rho h \ddot_2 \delta v_2 \,d\Omega &+ \int_ N_\frac + N_\frac\,d\Omega = -\int_ p_2 \delta v_2 \,d\Omega \\ \int_\rho h \ddot \delta w \,d\Omega &+ \int_ N_\frac\frac - M_\frac \,d\Omega\\ &+ \int_ N_\frac\frac - M_\frac \,d\Omega\\ &+ \int_ N_\left(\frac\frac + \frac\frac\right) - 2M_\frac \,d\Omega = -\int_ p_3 \delta w \,d\Omega\\ \end The resulting governing equations are \begin &\rho h \ddot - \frac - \frac - 2\frac - \frac\left(N_\,\frac + N_\,\frac\right) - \frac\left(N_\,\frac + N_\,\frac\right) = -p_3 \\ & \rho h \ddot_1 - \frac- \frac = -p_1\\ & \rho h \ddot_2 - \frac- \frac = -p_2 \,. \end


Föppl–von Kármán equations in terms of stress resultants

The Föppl–von Kármán equations are typically derived with an energy approach by considering
variation Variation or Variations may refer to: Science and mathematics * Variation (astronomy), any perturbation of the mean motion or orbit of a planet or satellite, particularly of the moon * Genetic variation, the difference in DNA among individual ...
s of internal energy and the virtual work done by external forces. The resulting static governing equations (Equations of Equilibrium) are : \begin &\frac + \frac + 2\frac + \frac\left(N_\,\frac + N_\,\frac\right) + \frac\left(N_\,\frac + N_\,\frac\right) = P \\ & \frac = 0 \,. \end When the deflections are small compared to the overall dimensions of the plate, and the mid-surface strains are neglected, \begin \frac \approx 0 ,\frac \approx 0, v_1 \approx 0, v_2\approx 0 \end . The equations of equilibrium are reduced (
pure bending Pure bending ( Theory of simple bending) is a condition of stress where a bending moment is applied to a beam without the simultaneous presence of Cylinder stress, axial, Shear stress, shear, or Deformation (mechanics), torsional forces. Pure bendin ...
of thin plates) to : \frac + \frac + 2\frac = P .


References


See also

*
Plate theory 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. ...
{{DEFAULTSORT:Foppl-Von Karman Equations Partial differential equations Continuum mechanics