Nonlinear finite elements/Steady state heat conduction: Difference between revisions

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If the problem does not depend on time and the material is isotropic, we get the boundary value problem for steady state heat conduction.

${\displaystyle \begin{array}{ccc}& & 𝖳𝗁𝖾𝖻𝗈𝗎𝗇𝖽𝖺𝗋𝗒𝗏𝖺𝗅𝗎𝖾𝗉𝗋𝗈𝖻𝗅𝖾𝗆𝖿𝗈𝗋𝗌𝗍𝖾𝖺𝖽𝗒𝗁𝖾𝖺𝗍𝖼𝗈𝗇𝖽𝗎𝖼𝗍𝗂𝗈𝗇\\ & & \\ & \text{PDE:}& -\frac{1}{C_v\rho }\mathrm{\nabla }\bullet (\mathit{\kappa }\bullet \mathrm{\nabla }𝑻\mathit{)}=Q\text{in}\mathrm{\Omega }\\ & \text{BCs:}& T=\bar{T}(𝐱)\text{on}{\mathrm{\Gamma }}_T\text{and}\frac{\partial T}{\partial n}=g(𝐱)\text{on}{\mathrm{\Gamma }}_q\\ \end{array}}$

If the material is homogeneous the density, heat capacity, and the thermal conductivity are constant. Define the thermal diffusivity as

${\displaystyle k:=\frac{\kappa }{C_v\rho }}$

Then, the boundary value problem becomes

${\displaystyle \begin{array}{ccc}& & 𝖯𝗈𝗂𝗌𝗌𝗈{𝗇}^{\prime }𝗌𝖾𝗊𝗎𝖺𝗍𝗂𝗈𝗇\\ & & \\ & \text{PDE:}& -k{\mathrm{\nabla }}^{2}T=Q\text{in}\mathrm{\Omega }\\ & \text{BCs:}& T=\bar{T}(𝐱)\text{on}{\mathrm{\Gamma }}_T\text{and}\frac{\partial T}{\partial n}=g(𝐱)\text{on}{\mathrm{\Gamma }}_q\\ \end{array}}$

where ${\displaystyle {\mathrm{\nabla }}^{2}T}$ is the Laplacian

${\displaystyle {\mathrm{\nabla }}^{2}T:=\mathrm{\nabla }\bullet \mathrm{\nabla }𝑻}$

Finally, if there is no internal source of heat, the value of ${\displaystyle Q}$ is zero, and we get Laplace's equation.

${\displaystyle \begin{array}{ccc}& & 𝖫𝖺𝗉𝗅𝖺𝖼{𝖾}^{\prime }𝗌𝖾𝗊𝗎𝖺𝗍𝗂𝗈𝗇\\ & & \\ & \text{PDE:}& {\mathrm{\nabla }}^{2}T=0\text{in}\mathrm{\Omega }\\ & \text{BCs:}& T=\bar{T}(𝐱)\text{on}{\mathrm{\Gamma }}_T\text{and}\frac{\partial T}{\partial n}=g(𝐱)\text{on}{\mathrm{\Gamma }}_q\\ \end{array}}$

The thin elastic membrane problem is another similar problem. See Figure 1 for the geometry of the membrane.

The membrane is thin and elastic. It is initially planar and occupies the 2D domain ${\displaystyle \mathrm{\Omega }}$. It is fixed along part of its boundary ${\displaystyle {\mathrm{\Gamma }}_u}$. A transverse force ${\displaystyle 𝐟}$ per unit area is applied. The final shape at equilibrium is nonplanar. The final displacement of a point ${\displaystyle 𝐱}$ on the membrane is ${\displaystyle 𝐮(𝐱)}$. There is no dependence on time.

The goal is to find the displacement ${\displaystyle 𝐮(𝐱)}$ at equilibrium.

It turns out that the equations for this problem are the same as those for the heat conduction problem - with the following changes:

• The time derivatives vanish.
• The balance of energy is replaced by the balance of forces.
• The constitutive equation is replaced by a relation that states that the vertical force depends on the displacement gradient (${\displaystyle \mathrm{\nabla }𝐮}$).

If the membrane if inhomogeneous, the boundary value problem is:

${\displaystyle \begin{array}{ccc}& & 𝖳𝗁𝖾𝖻𝗈𝗎𝗇𝖽𝖺𝗋𝗒𝗏𝖺𝗅𝗎𝖾𝗉𝗋𝗈𝖻𝗅𝖾𝗆𝖿𝗈𝗋𝗆𝖾𝗆𝖻𝗋𝖺𝗇𝖾𝖽𝖾𝖿𝗈𝗋𝗆𝖺𝗍𝗂𝗈𝗇\\ & & \\ & \text{PDE:}& -\mathrm{\nabla }\bullet (E\mathrm{\nabla }𝐮\mathit{)}=Q\text{in}\mathrm{\Omega }\\ & \text{BCs:}& 𝐮=\overline{𝐮}(𝐱)\text{on}{\mathrm{\Gamma }}_u\text{and}\frac{\partial u}{\partial n}=g(𝐱)\text{on}{\mathrm{\Gamma }}_t\\ \end{array}}$

For a homogeneous membrane, we get

${\displaystyle \begin{array}{ccc}& & 𝖯𝗈𝗂𝗌𝗌𝗈{𝗇}^{\prime }𝗌𝖤𝗊𝗎𝖺𝗍𝗂𝗈𝗇\\ & & \\ & \text{PDE:}& -E{\mathrm{\nabla }}^2𝐮=Q\text{in}\mathrm{\Omega }\\ & \text{BCs:}& 𝐮=\overline{𝐮}(𝐱)\text{on}{\mathrm{\Gamma }}_u\text{and}\frac{\partial u}{\partial n}=g(𝐱)\text{on}{\mathrm{\Gamma }}_t\\ \end{array}}$

Note that the membrane problem can be formulated in terms of a problem of minimization of potential energy.

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