Elasticity/Concentrated force on half plane

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File:Concentrated force on half plane.png

From the Flamant Solution

${\displaystyle \begin{array}{cc}{F}_1+2{\displaystyle \underset{\alpha }{\overset{\beta }{\int }}}\left(\frac{C_1\cos \theta -C_3\sin \theta }{a}\right)a\cos \theta d\theta & =0\\ F_2+2{\displaystyle \underset{\alpha }{\overset{\beta }{\int }}}\left(\frac{C_1\cos \theta -C_3\sin \theta }{a}\right)a\sin \theta d\theta & =0\end{array}}$

and

${\displaystyle {\sigma }_{rr}=\frac{2C_1\cos \theta }{r}+\frac{2C_3\sin \theta }{r};{\sigma }_{r\theta }={\sigma }_{\theta \theta }=0}$

If ${\displaystyle \alpha =-\pi }$ and${\displaystyle \beta =0}$, we obtain the special case of a concentrated force acting on a half-plane. Then,

${\displaystyle \begin{array}{cc}{F}_1+2{\displaystyle \underset{-\pi }{\overset{0}{\int }}}(C_1{\cos }^2\theta -\frac{C_3}{2}\sin (2\theta ))d\theta & =0\\ F_2+2{\displaystyle \underset{-\pi }{\overset{0}{\int }}}(\frac{C_1}{2}\sin (2\theta )-C_3{\sin }^2\theta )d\theta & =0\end{array}}$

or,

${\displaystyle \begin{array}{cc}{F}_1+\pi C_1& =0\\ F_2-\pi C_3& =0\end{array}}$

Therefore,

${\displaystyle C_1=-\frac{F_1}{\pi };C_3=\frac{F_2}{\pi }}$

The stresses are

${\displaystyle {\sigma }_{rr}=-\frac{2F_1\cos \theta }{\pi r}-\frac{2F_2\sin \theta }{\pi r};{\sigma }_{r\theta }={\sigma }_{\theta \theta }=0}$

The stress ${\displaystyle {\sigma }_{rr}}$ is obviously the superposition of the stresses due to ${\displaystyle F_1}$ and ${\displaystyle F_2}$, applied separately to the half-plane.

The tensile force ${\displaystyle F_2}$ produces the stress field

${\displaystyle {\sigma }_{rr}=-\frac{2F_2\sin \theta }{\pi r};{\sigma }_{r\theta }={\sigma }_{\theta \theta }=0}$

File:Stress conc force half plane.png

The stress function is

${\displaystyle \phi =\frac{F_2}{\pi }r\theta \cos \theta }$

Hence, the displacements from Michell's solution are

${\displaystyle \begin{array}{cc}2\mu u_r& =\frac{F_2}{2\pi }[(\kappa -1)\theta \cos \theta +\sin \theta -(\kappa +1)\ln (r)\sin \theta ]\\ 2\mu u_{\theta }& =\frac{F_2}{2\pi }[-(\kappa -1)\theta \sin \theta -\cos \theta -(\kappa +1)\ln (r)\cos \theta ]\end{array}}$

At ${\displaystyle \theta =0}$, (${\displaystyle x_1>0}$, ${\displaystyle x_2=0}$),

${\displaystyle \begin{array}{cc}2\mu u_r=2\mu u_1& =0\\ 2\mu u_{\theta }=2\mu u_2& =\frac{F_2}{2\pi }[-1-(\kappa +1)\ln (r)]\end{array}}$

At ${\displaystyle \theta =-\pi }$, (${\displaystyle x_1<0}$, ${\displaystyle x_2=0}$),

${\displaystyle \begin{array}{cc}2\mu u_r=-2\mu u_1& =\frac{F_2}{2\pi }(\kappa -1)\\ 2\mu u_{\theta }=-2\mu u_2& =\frac{F_2}{2\pi }[1+(\kappa +1)\ln (r)]\end{array}}$

where

${\displaystyle \begin{array}{ccc}\kappa =3-4\nu & & \text{plane strain}\\ \kappa =\frac{3-\nu }{1+\nu }& & \text{plane stress}\end{array}}$

Since we expect the solution to be symmetric about ${\displaystyle x=0}$, we superpose a rigid body displacement

${\displaystyle \begin{array}{cc}2\mu u_1& =\frac{F_2}{4\pi }(\kappa -1)\\ 2\mu u_2& =\frac{F_2}{2\pi }\end{array}}$

The displacements are

${\displaystyle \begin{array}{cc}{u}_1& =\frac{F_2(\kappa -1)\text{sign}(x_1)}{8\mu }\\ u_2& =-\frac{F_2(\kappa +1)\ln |x_1|}{4\pi \mu }\end{array}}$

where

${\displaystyle \text{sign}(x)=\{\begin{array}{cc}+1& x>0\\ -1& x<0\end{array}}$

and ${\displaystyle r=|x|}$ on ${\displaystyle y=0}$.

The tensile force ${\displaystyle F_1}$ produces the stress field

${\displaystyle {\sigma }_{rr}=-\frac{2F_2\cos \theta }{\pi r};{\sigma }_{r\theta }={\sigma }_{\theta \theta }=0}$

File:Stress1 conc force half plane.png

The displacements are

${\displaystyle \begin{array}{cc}{u}_1& =-\frac{F_1(\kappa +1)\ln |x_1|}{4\pi \mu }\\ u_2& =-\frac{F_1(\kappa -1)\text{sign}(x_1)}{8\mu }\end{array}}$

Superpose the two solutions. The stresses are

${\displaystyle {\sigma }_{rr}=-\frac{2F_1\cos \theta }{\pi r}-\frac{2F_2\sin \theta }{\pi r};{\sigma }_{r\theta }={\sigma }_{\theta \theta }=0}$

The displacements are

${\displaystyle \begin{array}{cc}{u}_1& =-\frac{F_1(\kappa +1)\ln |x_1|}{4\pi \mu }+\frac{F_2(\kappa -1)\text{sign}(x_1)}{8\mu }\\ u_2& =-\frac{F_2(\kappa +1)\ln |x_1|}{4\pi \mu }-\frac{F_1(\kappa -1)\text{sign}(x_1)}{8\mu }\end{array}}$

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