Elasticity/Body force potential: Difference between revisions

How do we find the body force potential? Before we proceed let us examine what conservative vector fields are.

• Work done in moving a particle from point A to point B in the field should be path independent.
• The local potential at point P in the field is defined as the work done to move a particle from infinity to P.
• For a vector field to be conservative

Template:Center top${\displaystyle f_{2,1}-f_{1,2}=0;f_{3,2}-f_{2,3}=0;f_{1,3}-f_{3,1}=0\text{(28)}}$Template:Center bottom or Template:Center top${\displaystyle \mathrm{\nabla }\times 𝐟=0\text{(29)}}$Template:Center bottom The field has to be irrotational.

Suppose a body is rotating with an angular velocity ${\displaystyle \dot{\theta }}$ and an angular acceleration of ${\displaystyle \ddot{\theta }}$. Then,

${\displaystyle \text{(30)}{𝐚}_r=-{\dot{\theta }}^{2}r{\widehat{𝐞}}_r;{𝐚}_{\theta }=-\ddot{\theta }r{\widehat{𝐞}}_{\theta }}$

Let us assume that the ${\displaystyle (r,\theta )}$ coordinate system is oriented at an angle ${\displaystyle \theta }$ to the ${\displaystyle (x_1,x_2)}$ system. Then,

${\displaystyle \text{(31)}\left[\begin{array}{c}{a}_1\\ a_2\end{array}\right]=\left[\begin{array}{cc}\cos \theta & -\sin \theta \\ \sin \theta & \cos \theta \end{array}\right]\left[\begin{array}{c}{a}_r\\ a_{\theta }\end{array}\right]}$

or,

${\displaystyle \text{(32)}\left[\begin{array}{c}{a}_1\\ a_2\end{array}\right]=\left[\begin{array}{cc}\cos \theta & -\sin \theta \\ \sin \theta & \cos \theta \end{array}\right]\left[\begin{array}{c}-{\dot{\theta }}^{2}r\\ -\ddot{\theta }r\end{array}\right]}$

or,

${\displaystyle \begin{array}{cc}\text{(33)}{a}_1& =-{\dot{\theta }}^{2}r\cos \theta +\ddot{\theta }r\sin \theta \\ \text{(34)}{a}_2& =-{\dot{\theta }}^{2}r\sin \theta -\ddot{\theta }r\cos \theta \end{array}}$

or,

${\displaystyle \begin{array}{cc}\text{(35)}{a}_1& =-{\dot{\theta }}^2{x}_1+\ddot{\theta }{x}_2\\ \text{(36)}{a}_2& =-{\dot{\theta }}^2{x}_2-\ddot{\theta }{x}_1\end{array}}$

If the origin is accelerating with an acceleration ${\displaystyle {𝐚}_0}$ (for example, due to gravity), we have,

${\displaystyle \begin{array}{cc}\text{(37)}{a}_1& =a_{01}-{\dot{\theta }}^2{x}_1+\ddot{\theta }{x}_2\\ \text{(38)}{a}_2& =a_{02}-{\dot{\theta }}^2{x}_2-\ddot{\theta }{x}_1\end{array}}$:

The body force field is given by

${\displaystyle \begin{array}{cc}\text{(39)}{f}_1& =-\rho (a_{01}-{\dot{\theta }}^2{x}_1+\ddot{\theta }{x}_2)\\ \text{(40)}{f}_2& =-\rho (a_{02}-{\dot{\theta }}^2{x}_2-\ddot{\theta }{x}_1)\end{array}}$

For this vector body force field to be conservative, we require that,

${\displaystyle f_{1,2}-f_{2,1}=0\Rightarrow 2\ddot{\theta }=0}$

Hence, the field ${\displaystyle 𝐟}$ is conservative only if the rotational acceleration is zero, i.e. = the rotational velocity is constant.=

${\displaystyle \begin{array}{cc}\text{(41)}{f}_1& =-\rho (a_{01}-{\dot{\theta }}^2{x}_1)\\ \text{(42)}{f}_2& =-\rho (a_{02}-{\dot{\theta }}^2{x}_2)\end{array}}$

Now,

${\displaystyle f_1=-V_{,1};f_2=-V_{,2}}$

Hence,

${\displaystyle \begin{array}{cc}\text{(43)}{V}_{,1}& =\rho (a_{01}-{\dot{\theta }}^2{x}_1)\\ \text{(44)}{V}_{,2}& =\rho (a_{02}-{\dot{\theta }}^2{x}_2)\end{array}}$

Integrating equation (43),

${\displaystyle \text{(45)}V=\rho (a_{01}{x}_1-{\dot{\theta }}^2\frac{x_1^2}{2})+h(x_2)}$

Hence,

${\displaystyle (\text{46)}{V}_{,2}=h^{\text{'}}(x_2)=\rho (a_{02}-{\dot{\theta }}^2{x}_2)}$

Integrating,

${\displaystyle \text{(47)}h(x_2)=\rho (a_{02}{x}_2-{\dot{\theta }}^2\frac{x_2^2}{2})+C}$

Without loss of generality, we can set ${\displaystyle C=0}$. Then,

${\displaystyle \text{(48)}V=\rho (a_{01}{x}_1-{\dot{\theta }}^2\frac{x_1^2}{2})+\rho (a_{02}{x}_2-{\dot{\theta }}^2\frac{x_2^2}{2})}$

or,

${\displaystyle \text{(49)}V=\rho [a_{01}{x}_1+a_{02}{x}_2-\frac{{\dot{\theta }}^2}{2}(x_1^2+x_2^2)]}$

For a body loaded by gravity only, we can set ${\displaystyle a_{01}=0}$, ${\displaystyle a_{02}=-g}$ and ${\displaystyle \dot{\theta }=0}$, to get

${\displaystyle \text{(50)}V=-\rho g{x}_2}$

For a body loaded by rotational inertia only, we can set ${\displaystyle a_{01}=0}$, and ${\displaystyle a_{02}=0}$, and get

${\displaystyle \text{(51)}V=-\frac{\rho {\dot{\theta }}^2}{2}(x_1^2+x_2^2)}$

We can see that an Airy stress function + a body force potential of the form shown in equation (49) can be used to solve two-dimensional elasticity problems of plane stress/plane strain.

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