Zeile 151:
Zeile 151: \underline{Q}_{k,0}
\underline{Q}_{k,0}
</math>
</math>
Die resultierenden Element-Steifigkeitsmatrizen sind im folgenden aufgeschreiben:
<table class="wikitable mw-collapsible mw-collapsed" style="background-color:white; float: none; margin-right:14px;">
<tr><th>Element-Steigigkeitsmatrizen mit globalen Koordinaten</th></tr>
<tr><th>Element #1</th></tr>
<tr><td>
<math>
\underline{\underline{K}}_{1,0} = \begin{pmatrix}\frac{8 {{A}^{2}} E \eta }{{\ell_{0}^{3}}} & 0 & \frac{2 {{A}^{2}} E \eta }{{\ell_{0}^{2}}} & -\left( \frac{8 {{A}^{2}} E \eta }{{\ell_{0}^{3}}}\right) & 0 & \frac{2 {{A}^{2}} E \eta }{{\ell_{0}^{2}}}\\
0 & \frac{2 A E}{{\ell_0}} & 0 & 0 & -\left( \frac{2 A E}{{\ell_0}}\right) & 0\\
\frac{2 {{A}^{2}} E \eta }{{\ell_{0}^{2}}} & 0 & \frac{2 {{A}^{2}} E \eta }{3 {\ell_0}} & -\left( \frac{2 {{A}^{2}} E \eta }{{\ell_{0}^{2}}}\right) & 0 & \frac{{{A}^{2}} E \eta }{3 {\ell_0}}\\
-\left( \frac{8 {{A}^{2}} E \eta }{{\ell_{0}^{3}}}\right) & 0 & -\left( \frac{2 {{A}^{2}} E \eta }{{\ell_{0}^{2}}}\right) & \frac{8 {{A}^{2}} E \eta }{{\ell_{0}^{3}}} & 0 & -\left( \frac{2 {{A}^{2}} E \eta }{{\ell_{0}^{2}}}\right) \\
0 & -\left( \frac{2 A E}{{\ell_0}}\right) & 0 & 0 & \frac{2 A E}{{\ell_0}} & 0\\
\frac{2 {{A}^{2}} E \eta }{{\ell_{0}^{2}}} & 0 & \frac{{{A}^{2}} E \eta }{3 {\ell_0}} & -\left( \frac{2 {{A}^{2}} E \eta }{{\ell_{0}^{2}}}\right) & 0 & \frac{2 {{A}^{2}} E \eta }{3 {\ell_0}}\end{pmatrix}
</math>
</td></tr>
<tr><th>Element #2</th></tr>
<tr><td>
<math>
\underline{\underline{K}}_{2,0} = \begin{pmatrix}\frac{{{A}^{2}} E \eta +3 {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & -\left( \frac{{{A}^{2}} E \eta +3 {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\\
\frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & \frac{3 {{A}^{2}} E \eta +{\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & -\left( \frac{3 {{A}^{2}} E \eta +{\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\\
\frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & \frac{{{A}^{2}} E \eta }{3 {\ell_0}} & -\left( \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & \frac{{{A}^{2}} E \eta }{6 {\ell_0}}\\
-\left( \frac{{{A}^{2}} E \eta +3 {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & -\left( \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & \frac{{{A}^{2}} E \eta +3 {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & -\left( \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) \\
-\left( \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & -\left( \frac{3 {{A}^{2}} E \eta +{\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & \frac{3 {{A}^{2}} E \eta +{\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) \\
\frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & \frac{{{A}^{2}} E \eta }{6 {\ell_0}} & -\left( \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & \frac{{{A}^{2}} E \eta }{3 {\ell_0}}\end{pmatrix}
</math>
</td></tr>
<tr><th>Element #3</th></tr>
<tr><td>
<math>
\underline{\underline{K}}_{3,0} = \begin{pmatrix}\frac{{{A}^{2}} E \eta +3 {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & -\left( \frac{{{A}^{2}} E \eta +3 {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\\
-\left( \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & \frac{3 {{A}^{2}} E \eta +{\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & -\left( \frac{3 {{A}^{2}} E \eta +{\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) \\
\frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & \frac{{{A}^{2}} E \eta }{3 {\ell_0}} & -\left( \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & \frac{{{A}^{2}} E \eta }{6 {\ell_0}}\\
-\left( \frac{{{A}^{2}} E \eta +3 {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & -\left( \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & \frac{{{A}^{2}} E \eta +3 {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & -\left( \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) \\
\frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & -\left( \frac{3 {{A}^{2}} E \eta +{\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & \frac{3 {{A}^{2}} E \eta +{\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\\
\frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & \frac{{{A}^{2}} E \eta }{6 {\ell_0}} & -\left( \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & \frac{{{A}^{2}} E \eta }{3 {\ell_0}}\end{pmatrix}
</math>
</td></tr>
<tr><th>Element #4</th></tr>
<tr><td>
<math>
\underline{\underline{K}}_{4,0} = \begin{pmatrix}\frac{{{A}^{2}} E \eta }{{\ell_{0}^{3}}} & 0 & \frac{{{A}^{2}} E \eta }{2 {\ell_{0}^{2}}} & -\left( \frac{{{A}^{2}} E \eta }{{\ell_{0}^{3}}}\right) & 0 & \frac{{{A}^{2}} E \eta }{2 {\ell_{0}^{2}}}\\
0 & \frac{A E}{{\ell_0}} & 0 & 0 & -\left( \frac{A E}{{\ell_0}}\right) & 0\\
\frac{{{A}^{2}} E \eta }{2 {\ell_{0}^{2}}} & 0 & \frac{{{A}^{2}} E \eta }{3 {\ell_0}} & -\left( \frac{{{A}^{2}} E \eta }{2 {\ell_{0}^{2}}}\right) & 0 & \frac{{{A}^{2}} E \eta }{6 {\ell_0}}\\
-\left( \frac{{{A}^{2}} E \eta }{{\ell_{0}^{3}}}\right) & 0 & -\left( \frac{{{A}^{2}} E \eta }{2 {\ell_{0}^{2}}}\right) & \frac{{{A}^{2}} E \eta }{{\ell_{0}^{3}}} & 0 & -\left( \frac{{{A}^{2}} E \eta }{2 {\ell_{0}^{2}}}\right) \\
0 & -\left( \frac{A E}{{\ell_0}}\right) & 0 & 0 & \frac{A E}{{\ell_0}} & 0\\
\frac{{{A}^{2}} E \eta }{2 {\ell_{0}^{2}}} & 0 & \frac{{{A}^{2}} E \eta }{6 {\ell_0}} & -\left( \frac{{{A}^{2}} E \eta }{2 {\ell_{0}^{2}}}\right) & 0 & \frac{{{A}^{2}} E \eta }{3 {\ell_0}}\end{pmatrix}
</math>
</td></tr>
</table>
Wir sammeln alle Koordianten der Knoten im ''0''-System in
Wir sammeln alle Koordianten der Knoten im ''0''-System in
<math>\underline{Q}_{0}</math> und schreiben die Gleichgewichtsbedingungen in der Form
<math>\underline{Q}_{0}</math> und schreiben die Gleichgewichtsbedingungen in der Form
Zeile 158:
Zeile 208: </math>
</math>
an. Die Randbedingungen arbeiten wir hier durch das Streichen der passenden Zeilen für <math>\delta U_{1,0},\delta W_{1,0},\delta U_{2,0},\delta W_{2,0}</math> sowie der passenden Spalten für <math>U_{1,0},W_{1,0},U_{2,0},W_{2,0}</math> ein.
an.
===Einarbeitung der Randbedingungen===
Die Randbedingungen arbeiten wir hier durch das Streichen der passenden Zeilen für <math>\delta U_{1,0},\delta W_{1,0},\delta U_{2,0},\delta W_{2,0}</math> sowie der passenden Spalten für <math>U_{1,0},W_{1,0},U_{2,0},W_{2,0}</math> ein.
Das resultierende Gleichungssystem ist dies:
Das resultierende Gleichungssystem ist dies:
Zeile 195:
Zeile 248: \end{pmatrix}
\end{pmatrix}
</math>
</math>
Hier kommt jetzt irgendein Text.
===Solving===
Das Ergebnis ist - für die gleichen Parameter wie in [https://numpedia.rzbt.haw-hamburg.de/index.php?title=Gel%C3%B6ste_Aufgaben/Stab Stab] -
::<math>
::<math>
Some Text
\begin{array}{l}
U_{1,0}=0\\
W_{1,0}=0\\
\Phi_{1,0}=3.97 \frac{F}{E a^2}\\
U_{2,0}=0\\
W_{2,0}=0\\
\Phi_{2,0}=2.45 \frac{F}{E a^2}\\
U_{3,0}=57.7 \frac{F}{E a}\\
W_{3,0}=1.67\cdot 10^2 \frac{F}{E a}\\
\Phi_{3,0}=2.06 \frac{F}{E a^2}\\
U_{4,0}=-57.7 \frac{F}{E a}\\
W_{4,0}= 3.67\cdot 10^2 \frac{F}{E a}\\
\Phi_{4,0}=3.12 \frac{F}{E a^2}
\end{array}
</math>
</math>
Und damit sind auch die Verläufe der Schnittlasten in den Stäben identisch - wir brauchen also die Ergebnisse nicht noch einmal auftragen.
<!-------------------------------------------------------------------------------->
<!-------------------------------------------------------------------------------->
Zeile 209:
Zeile 277: </syntaxhighlight>
</syntaxhighlight>
}}
}}
<table class="wikitable mw-collapsible mw-collapsed" style="background-color:white; float: none; margin-right:14px;">
<tr><th>Element-Steigigkeitsmatrizen mit globalen Koordinaten</th></tr>
<tr><th>Element #1</th></tr>
<tr><td>
<math>
{k_1} = \begin{pmatrix}\frac{8 {{A}^{2}} E \eta }{{\ell_{0}^{3}}} & 0 & \frac{2 {{A}^{2}} E \eta }{{\ell_{0}^{2}}} & -\left( \frac{8 {{A}^{2}} E \eta }{{\ell_{0}^{3}}}\right) & 0 & \frac{2 {{A}^{2}} E \eta }{{\ell_{0}^{2}}}\\
0 & \frac{2 A E}{{\ell_0}} & 0 & 0 & -\left( \frac{2 A E}{{\ell_0}}\right) & 0\\
\frac{2 {{A}^{2}} E \eta }{{\ell_{0}^{2}}} & 0 & \frac{2 {{A}^{2}} E \eta }{3 {\ell_0}} & -\left( \frac{2 {{A}^{2}} E \eta }{{\ell_{0}^{2}}}\right) & 0 & \frac{{{A}^{2}} E \eta }{3 {\ell_0}}\\
-\left( \frac{8 {{A}^{2}} E \eta }{{\ell_{0}^{3}}}\right) & 0 & -\left( \frac{2 {{A}^{2}} E \eta }{{\ell_{0}^{2}}}\right) & \frac{8 {{A}^{2}} E \eta }{{\ell_{0}^{3}}} & 0 & -\left( \frac{2 {{A}^{2}} E \eta }{{\ell_{0}^{2}}}\right) \\
0 & -\left( \frac{2 A E}{{\ell_0}}\right) & 0 & 0 & \frac{2 A E}{{\ell_0}} & 0\\
\frac{2 {{A}^{2}} E \eta }{{\ell_{0}^{2}}} & 0 & \frac{{{A}^{2}} E \eta }{3 {\ell_0}} & -\left( \frac{2 {{A}^{2}} E \eta }{{\ell_{0}^{2}}}\right) & 0 & \frac{2 {{A}^{2}} E \eta }{3 {\ell_0}}\end{pmatrix}
</math>
</td></tr>
<tr><th>Element #2</th></tr>
<tr><td>
<math>
{k_2} = \begin{pmatrix}\frac{{{A}^{2}} E \eta +3 {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & -\left( \frac{{{A}^{2}} E \eta +3 {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\\
\frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & \frac{3 {{A}^{2}} E \eta +{\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & -\left( \frac{3 {{A}^{2}} E \eta +{\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\\
\frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & \frac{{{A}^{2}} E \eta }{3 {\ell_0}} & -\left( \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & \frac{{{A}^{2}} E \eta }{6 {\ell_0}}\\
-\left( \frac{{{A}^{2}} E \eta +3 {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & -\left( \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & \frac{{{A}^{2}} E \eta +3 {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & -\left( \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) \\
-\left( \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & -\left( \frac{3 {{A}^{2}} E \eta +{\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & \frac{3 {{A}^{2}} E \eta +{\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) \\
\frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & \frac{{{A}^{2}} E \eta }{6 {\ell_0}} & -\left( \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & \frac{{{A}^{2}} E \eta }{3 {\ell_0}}\end{pmatrix}
</math>
</td></tr>
<tr><th>Element #3</th></tr>
<tr><td>
<math>
{k_3} = \begin{pmatrix}\frac{{{A}^{2}} E \eta +3 {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & -\left( \frac{{{A}^{2}} E \eta +3 {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\\
-\left( \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & \frac{3 {{A}^{2}} E \eta +{\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & -\left( \frac{3 {{A}^{2}} E \eta +{\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) \\
\frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & \frac{{{A}^{2}} E \eta }{3 {\ell_0}} & -\left( \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & \frac{{{A}^{2}} E \eta }{6 {\ell_0}}\\
-\left( \frac{{{A}^{2}} E \eta +3 {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & -\left( \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & \frac{{{A}^{2}} E \eta +3 {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & -\left( \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) \\
\frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & -\left( \frac{3 {{A}^{2}} E \eta +{\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta -\sqrt{3} {\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}}\right) & \frac{3 {{A}^{2}} E \eta +{\ell_{0}^{2}} A E}{4 {\ell_{0}^{3}}} & \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\\
\frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & -\left( \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & \frac{{{A}^{2}} E \eta }{6 {\ell_0}} & -\left( \frac{{{A}^{2}} E \eta }{4 {\ell_{0}^{2}}}\right) & \frac{\sqrt{3} {{A}^{2}} E \eta }{4 {\ell_{0}^{2}}} & \frac{{{A}^{2}} E \eta }{3 {\ell_0}}\end{pmatrix}
</math>
</td></tr>
<tr><th>Element #4</th></tr>
<tr><td>
<math>
{k_4} = \begin{pmatrix}\frac{{{A}^{2}} E \eta }{{\ell_{0}^{3}}} & 0 & \frac{{{A}^{2}} E \eta }{2 {\ell_{0}^{2}}} & -\left( \frac{{{A}^{2}} E \eta }{{\ell_{0}^{3}}}\right) & 0 & \frac{{{A}^{2}} E \eta }{2 {\ell_{0}^{2}}}\\
0 & \frac{A E}{{\ell_0}} & 0 & 0 & -\left( \frac{A E}{{\ell_0}}\right) & 0\\
\frac{{{A}^{2}} E \eta }{2 {\ell_{0}^{2}}} & 0 & \frac{{{A}^{2}} E \eta }{3 {\ell_0}} & -\left( \frac{{{A}^{2}} E \eta }{2 {\ell_{0}^{2}}}\right) & 0 & \frac{{{A}^{2}} E \eta }{6 {\ell_0}}\\
-\left( \frac{{{A}^{2}} E \eta }{{\ell_{0}^{3}}}\right) & 0 & -\left( \frac{{{A}^{2}} E \eta }{2 {\ell_{0}^{2}}}\right) & \frac{{{A}^{2}} E \eta }{{\ell_{0}^{3}}} & 0 & -\left( \frac{{{A}^{2}} E \eta }{2 {\ell_{0}^{2}}}\right) \\
0 & -\left( \frac{A E}{{\ell_0}}\right) & 0 & 0 & \frac{A E}{{\ell_0}} & 0\\
\frac{{{A}^{2}} E \eta }{2 {\ell_{0}^{2}}} & 0 & \frac{{{A}^{2}} E \eta }{6 {\ell_0}} & -\left( \frac{{{A}^{2}} E \eta }{2 {\ell_{0}^{2}}}\right) & 0 & \frac{{{A}^{2}} E \eta }{3 {\ell_0}}\end{pmatrix}
</math>
</td></tr>
</table>
<hr/>
<hr/>
Aufgabenstellung Wir untersuchen die Belastung eines ebenen Stabwerks. Die Stäbe haben wie skizziert die Länge ℓ bzw. ℓ/2.
Die Struktur wird mit der Kraft F belastet.
Caption Gesucht ist ein Vergleich zwischen der klassischen Stabwerkstheorie und einer Herangehensweise, bei der wir eine feste Verbindung der Stäbe in den Knoten ansetzten. Grundlage des Modells ist die FEM-Lösung der Felddifferentialgleichung im Vergleich zur Lösung in Problemstellung „Stab“.
Wir stellen das Modell des Stabwerks mit dem Prinzip der virtuellen Verrückungen auf und vergleichen, wie sich diese von der Herangehensweise aus „Stab “ mit der analytischen Lösung unterscheidet.
Lösung mit Maxima Wir nutzen das Computer-Algebra-System Maxima zur Lösung. Das macht hier Sinn, weil wir die Herangehensweise mit der aus Stab vergleichen wollen – für die wir ebenfalls Maxima eingesetzt haben.
Declarations Wir übernehmen alle Vereinbarungen und Parameter aus der Problemformulierung „Stab “.
Gleichgewichtsbedingungen Für die Gleichgewichtsbedingung nach dem Prinzip der virtuellen Verrückungen
δ
W
=
!
0
=
δ
Π
−
δ
W
a
{\displaystyle {\begin{array}{ccc}\delta W&{\stackrel {!}{=}}&0\\&=&\delta \Pi -\delta W^{a}\end{array}}}
benötigen wir die virtuelle Formänderungsenergie
δ
Π
{\displaystyle \delta \Pi }
δ
W
a
{\displaystyle \delta W^{a}}
Mit den Konventionen für die Knoten-Verschiebungen aus Stab ist
δ
W
a
=
−
δ
W
4
,
0
⋅
F
{\displaystyle \delta W^{a}=-\delta W_{4,0}\cdot F}
Für
δ
Π
{\displaystyle \delta \Pi }
δ
Π
=
∑
i
=
0
4
δ
Π
i
{\displaystyle \delta \Pi =\sum _{i=0}^{4}\delta \Pi _{i}}
mit den virtuellen Formänderungsarbeiten der vier Stäbe.
Dabei haben wir Anteile der Arbeit aus der [Biegung ] und der Längs-Dehnung des Stabes.
Für den Stab k mit den Knoten I und J haben wir als Koodinaten der Knoten
U
I
,
k
,
W
I
,
k
,
Φ
I
,
k
{\displaystyle U_{I,k},W_{I,k},\Phi _{I,k}}
U
J
,
k
,
W
J
,
k
,
Φ
J
,
k
{\displaystyle U_{J,k},W_{J,k},\Phi _{J,k}}
Damit haben wir
δ
Π
k
=
(
δ
W
I
,
k
,
δ
Φ
I
,
k
,
δ
Φ
J
,
k
,
δ
W
J
,
k
)
⋅
E
I
ℓ
i
3
⋅
(
12
6
ℓ
i
−
12
6
ℓ
i
6
ℓ
i
4
ℓ
i
2
−
6
ℓ
i
2
ℓ
i
2
−
12
−
6
ℓ
i
12
−
6
ℓ
i
6
ℓ
i
2
ℓ
i
2
−
6
ℓ
i
4
ℓ
i
2
)
⋅
(
W
I
,
k
Φ
I
,
k
W
J
,
k
Φ
J
,
k
)
+
(
δ
U
I
,
k
,
δ
U
J
,
k
)
⋅
E
A
ℓ
i
⋅
(
1
−
1
−
1
1
)
⋅
(
U
I
,
k
U
J
,
k
)
{\displaystyle \delta \Pi _{k}=\left(\delta W_{I,k},\delta \Phi _{I,k},\delta \Phi _{J,k},\delta W_{J,k}\right)\cdot {\frac {EI}{\ell _{i}^{3}}}\cdot {\begin{pmatrix}12&6\,{\ell _{i}}&-12&6\,{\ell _{i}}\\6\,{\ell _{i}}&4\,{\ell _{i}^{2}}&-6\,{\ell _{i}}&2\,{\ell _{i}^{2}}\\-12&-6\,{\ell _{i}}&12&-6\,{\ell _{i}}\\6\,{\ell _{i}}&2\,{\ell _{i}^{2}}&-6\,{\ell _{i}}&4\,{\ell _{i}^{2}}\end{pmatrix}}\cdot \left({\begin{array}{c}W_{I,k}\\\Phi _{I,k}\\W_{J,k}\\\Phi _{J,k}\end{array}}\right)+\left(\delta U_{I,k},\delta U_{J,k}\right)\cdot {\frac {EA}{\ell _{i}}}\cdot {\begin{pmatrix}1&-1\\-1&1\end{pmatrix}}\cdot \left({\begin{array}{c}U_{I,k}\\U_{J,k}\end{array}}\right)}
Für den Stab k definieren wir
Q
_
k
,
k
=
(
U
I
,
k
W
I
,
k
Φ
I
,
k
U
J
,
k
W
J
,
k
Φ
J
,
k
)
{\displaystyle {\underline {Q}}_{k,k}=\left({\begin{array}{c}U_{I,k}\\W_{I,k}\\\Phi _{I,k}\\U_{J,k}\\W_{J,k}\\\Phi _{J,k}\\\end{array}}\right)}
δ
Q
_
k
,
k
=
(
δ
U
I
,
k
δ
W
I
,
k
δ
Φ
I
,
k
δ
U
J
,
k
δ
W
J
,
k
δ
Φ
J
,
k
)
{\displaystyle \delta {\underline {Q}}_{k,k}=\left({\begin{array}{c}\delta U_{I,k}\\\delta W_{I,k}\\\delta \Phi _{I,k}\\\delta U_{J,k}\\\delta W_{J,k}\\\delta \Phi _{J,k}\\\end{array}}\right)}
und finden damit
δ
Π
k
=
δ
Q
_
k
,
k
T
⋅
K
_
_
k
,
k
⋅
Q
_
k
,
k
{\displaystyle \delta \Pi _{k}=\delta {\underline {Q}}_{k,k}^{T}\cdot {\underline {\underline {K}}}_{k,k}\cdot {\underline {Q}}_{k,k}}
mit der Element-Steifigkeitsmatrix des Elements k im k -Koordinatensystem
K
_
_
k
,
k
=
E
I
ℓ
i
3
⋅
(
0
0
0
0
0
0
0
12
6
ℓ
i
0
−
12
6
ℓ
i
0
6
ℓ
i
4
ℓ
i
2
0
−
6
ℓ
i
2
ℓ
i
2
0
0
0
0
0
0
0
−
12
−
6
ℓ
i
0
12
−
6
ℓ
i
0
6
ℓ
i
2
ℓ
i
2
−
0
6
ℓ
i
4
ℓ
i
2
)
+
E
A
ℓ
i
⋅
(
1
0
0
−
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
−
1
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
)
{\displaystyle {\underline {\underline {K}}}_{k,k}={\frac {EI}{\ell _{i}^{3}}}\cdot {\begin{pmatrix}0&0&0&0&0&0\\0&12&6\,{\ell _{i}}&0&-12&6\,{\ell _{i}}\\0&6\,{\ell _{i}}&4\,{\ell _{i}^{2}}&0&-6\,{\ell _{i}}&2\,{\ell _{i}^{2}}\\0&0&0&0&0&0\\0&-12&-6\,{\ell _{i}}&0&12&-6\,{\ell _{i}}\\0&6\,{\ell _{i}}&2\,{\ell _{i}^{2}}&-0&6\,{\ell _{i}}&4\,{\ell _{i}^{2}}\end{pmatrix}}+{\frac {EA}{\ell _{i}}}\cdot {\begin{pmatrix}1&0&0&-1&0&0\\0&0&0&0&0&0\\0&0&0&0&0&0\\-1&0&0&1&0&0\\0&0&0&0&0&0\\0&0&0&0&0&0\end{pmatrix}}}
Transformation der Koordinaten in das globale System In den Ausdrücken der virtuellen Formänderungsenergie stehen die Koordinaten des lokalen Koordinatensystems von k . Die müssen wir, wie in Stab mit der Euler-Drehmatrix ineinander überführen.
Dafür haben wir
(
U
I
,
0
W
I
,
0
Φ
I
,
0
)
=
D
_
_
R
(
α
)
⋅
(
U
I
,
k
W
I
,
k
Φ
I
,
k
)
{\displaystyle \left({\begin{array}{c}U_{I,0}\\W_{I,0}\\\Phi _{I,0}\end{array}}\right)={\underline {\underline {D}}}_{R}(\alpha )\cdot \left({\begin{array}{c}U_{I,k}\\W_{I,k}\\\Phi _{I,k}\end{array}}\right)}
mit der Transformationsmatrix
D
_
_
R
(
α
)
=
(
cos
(
α
)
sin
(
α
)
0
−
sin
(
α
)
cos
(
α
)
0
0
0
1
)
{\displaystyle {\underline {\underline {D}}}_{R}(\alpha )=\left({\begin{array}{c}\cos(\alpha )&\sin(\alpha )&0\\-\sin(\alpha )&\cos(\alpha )&0\\0&0&1\end{array}}\right)}
Damit wir für die Elementsteifigkeitsmatrix - mit beiden Anfangs- und Endknoten des Elements - vom "0"-System ins "k"-System transformieren, brauchen wir die neue Matrix
D
_
_
T
(
α
)
=
(
D
_
_
R
T
(
α
)
0
_
_
0
_
_
D
_
_
R
T
(
α
)
)
{\displaystyle {\underline {\underline {D}}}_{T}(\alpha )=\left({\begin{array}{c}{\underline {\underline {D}}}_{R}^{T}(\alpha )&{\underline {\underline {0}}}\\{\underline {\underline {0}}}&{\underline {\underline {D}}}_{R}^{T}(\alpha )\end{array}}\right)}
Mit diesen Transformationsmatrizen ist
δ
Π
=
∑
k
=
1
4
δ
Q
_
k
,
0
T
⋅
D
_
_
T
T
(
α
k
)
⋅
K
_
_
k
,
k
⋅
D
_
_
T
(
α
k
)
⏟
:=
K
_
_
k
,
0
⋅
Q
_
k
,
0
{\displaystyle \delta \Pi =\sum _{k=1}^{4}\delta {\underline {Q}}_{k,0}^{T}\cdot \underbrace {{\underline {\underline {D}}}_{T}^{T}(\alpha _{k})\cdot {\underline {\underline {K}}}_{k,k}\cdot {\underline {\underline {D}}}_{T}(\alpha _{k})} _{:={\underline {\underline {K}}}_{k,0}}\cdot {\underline {Q}}_{k,0}}
Die resultierenden Element-Steifigkeitsmatrizen sind im folgenden aufgeschreiben:
Element-Steigigkeitsmatrizen mit globalen Koordinaten Element #1
K
_
_
1
,
0
=
(
8
A
2
E
η
ℓ
0
3
0
2
A
2
E
η
ℓ
0
2
−
(
8
A
2
E
η
ℓ
0
3
)
0
2
A
2
E
η
ℓ
0
2
0
2
A
E
ℓ
0
0
0
−
(
2
A
E
ℓ
0
)
0
2
A
2
E
η
ℓ
0
2
0
2
A
2
E
η
3
ℓ
0
−
(
2
A
2
E
η
ℓ
0
2
)
0
A
2
E
η
3
ℓ
0
−
(
8
A
2
E
η
ℓ
0
3
)
0
−
(
2
A
2
E
η
ℓ
0
2
)
8
A
2
E
η
ℓ
0
3
0
−
(
2
A
2
E
η
ℓ
0
2
)
0
−
(
2
A
E
ℓ
0
)
0
0
2
A
E
ℓ
0
0
2
A
2
E
η
ℓ
0
2
0
A
2
E
η
3
ℓ
0
−
(
2
A
2
E
η
ℓ
0
2
)
0
2
A
2
E
η
3
ℓ
0
)
{\displaystyle {\underline {\underline {K}}}_{1,0}={\begin{pmatrix}{\frac {8{{A}^{2}}E\eta }{\ell _{0}^{3}}}&0&{\frac {2{{A}^{2}}E\eta }{\ell _{0}^{2}}}&-\left({\frac {8{{A}^{2}}E\eta }{\ell _{0}^{3}}}\right)&0&{\frac {2{{A}^{2}}E\eta }{\ell _{0}^{2}}}\\0&{\frac {2AE}{\ell _{0}}}&0&0&-\left({\frac {2AE}{\ell _{0}}}\right)&0\\{\frac {2{{A}^{2}}E\eta }{\ell _{0}^{2}}}&0&{\frac {2{{A}^{2}}E\eta }{3{\ell _{0}}}}&-\left({\frac {2{{A}^{2}}E\eta }{\ell _{0}^{2}}}\right)&0&{\frac {{{A}^{2}}E\eta }{3{\ell _{0}}}}\\-\left({\frac {8{{A}^{2}}E\eta }{\ell _{0}^{3}}}\right)&0&-\left({\frac {2{{A}^{2}}E\eta }{\ell _{0}^{2}}}\right)&{\frac {8{{A}^{2}}E\eta }{\ell _{0}^{3}}}&0&-\left({\frac {2{{A}^{2}}E\eta }{\ell _{0}^{2}}}\right)\\0&-\left({\frac {2AE}{\ell _{0}}}\right)&0&0&{\frac {2AE}{\ell _{0}}}&0\\{\frac {2{{A}^{2}}E\eta }{\ell _{0}^{2}}}&0&{\frac {{{A}^{2}}E\eta }{3{\ell _{0}}}}&-\left({\frac {2{{A}^{2}}E\eta }{\ell _{0}^{2}}}\right)&0&{\frac {2{{A}^{2}}E\eta }{3{\ell _{0}}}}\end{pmatrix}}}
Element #2
K
_
_
2
,
0
=
(
A
2
E
η
+
3
ℓ
0
2
A
E
4
ℓ
0
3
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
A
2
E
η
4
ℓ
0
2
−
(
A
2
E
η
+
3
ℓ
0
2
A
E
4
ℓ
0
3
)
−
(
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
)
A
2
E
η
4
ℓ
0
2
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
3
A
2
E
η
+
ℓ
0
2
A
E
4
ℓ
0
3
3
A
2
E
η
4
ℓ
0
2
−
(
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
)
−
(
3
A
2
E
η
+
ℓ
0
2
A
E
4
ℓ
0
3
)
3
A
2
E
η
4
ℓ
0
2
A
2
E
η
4
ℓ
0
2
3
A
2
E
η
4
ℓ
0
2
A
2
E
η
3
ℓ
0
−
(
A
2
E
η
4
ℓ
0
2
)
−
(
3
A
2
E
η
4
ℓ
0
2
)
A
2
E
η
6
ℓ
0
−
(
A
2
E
η
+
3
ℓ
0
2
A
E
4
ℓ
0
3
)
−
(
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
)
−
(
A
2
E
η
4
ℓ
0
2
)
A
2
E
η
+
3
ℓ
0
2
A
E
4
ℓ
0
3
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
−
(
A
2
E
η
4
ℓ
0
2
)
−
(
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
)
−
(
3
A
2
E
η
+
ℓ
0
2
A
E
4
ℓ
0
3
)
−
(
3
A
2
E
η
4
ℓ
0
2
)
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
3
A
2
E
η
+
ℓ
0
2
A
E
4
ℓ
0
3
−
(
3
A
2
E
η
4
ℓ
0
2
)
A
2
E
η
4
ℓ
0
2
3
A
2
E
η
4
ℓ
0
2
A
2
E
η
6
ℓ
0
−
(
A
2
E
η
4
ℓ
0
2
)
−
(
3
A
2
E
η
4
ℓ
0
2
)
A
2
E
η
3
ℓ
0
)
{\displaystyle {\underline {\underline {K}}}_{2,0}={\begin{pmatrix}{\frac {{{A}^{2}}E\eta +3{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}&{\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}&{\frac {{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}&-\left({\frac {{{A}^{2}}E\eta +3{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}\right)&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}\right)&{\frac {{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}\\{\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}&{\frac {3{{A}^{2}}E\eta +{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}&{\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}\right)&-\left({\frac {3{{A}^{2}}E\eta +{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}\right)&{\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}\\{\frac {{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}&{\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}&{\frac {{{A}^{2}}E\eta }{3{\ell _{0}}}}&-\left({\frac {{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}\right)&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}\right)&{\frac {{{A}^{2}}E\eta }{6{\ell _{0}}}}\\-\left({\frac {{{A}^{2}}E\eta +3{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}\right)&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}\right)&-\left({\frac {{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}\right)&{\frac {{{A}^{2}}E\eta +3{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}&{\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}&-\left({\frac {{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}\right)\\-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}\right)&-\left({\frac {3{{A}^{2}}E\eta +{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}\right)&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}\right)&{\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}&{\frac {3{{A}^{2}}E\eta +{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}\right)\\{\frac {{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}&{\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}&{\frac {{{A}^{2}}E\eta }{6{\ell _{0}}}}&-\left({\frac {{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}\right)&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}\right)&{\frac {{{A}^{2}}E\eta }{3{\ell _{0}}}}\end{pmatrix}}}
Element #3
K
_
_
3
,
0
=
(
A
2
E
η
+
3
ℓ
0
2
A
E
4
ℓ
0
3
−
(
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
)
A
2
E
η
4
ℓ
0
2
−
(
A
2
E
η
+
3
ℓ
0
2
A
E
4
ℓ
0
3
)
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
A
2
E
η
4
ℓ
0
2
−
(
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
)
3
A
2
E
η
+
ℓ
0
2
A
E
4
ℓ
0
3
−
(
3
A
2
E
η
4
ℓ
0
2
)
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
−
(
3
A
2
E
η
+
ℓ
0
2
A
E
4
ℓ
0
3
)
−
(
3
A
2
E
η
4
ℓ
0
2
)
A
2
E
η
4
ℓ
0
2
−
(
3
A
2
E
η
4
ℓ
0
2
)
A
2
E
η
3
ℓ
0
−
(
A
2
E
η
4
ℓ
0
2
)
3
A
2
E
η
4
ℓ
0
2
A
2
E
η
6
ℓ
0
−
(
A
2
E
η
+
3
ℓ
0
2
A
E
4
ℓ
0
3
)
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
−
(
A
2
E
η
4
ℓ
0
2
)
A
2
E
η
+
3
ℓ
0
2
A
E
4
ℓ
0
3
−
(
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
)
−
(
A
2
E
η
4
ℓ
0
2
)
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
−
(
3
A
2
E
η
+
ℓ
0
2
A
E
4
ℓ
0
3
)
3
A
2
E
η
4
ℓ
0
2
−
(
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
)
3
A
2
E
η
+
ℓ
0
2
A
E
4
ℓ
0
3
3
A
2
E
η
4
ℓ
0
2
A
2
E
η
4
ℓ
0
2
−
(
3
A
2
E
η
4
ℓ
0
2
)
A
2
E
η
6
ℓ
0
−
(
A
2
E
η
4
ℓ
0
2
)
3
A
2
E
η
4
ℓ
0
2
A
2
E
η
3
ℓ
0
)
{\displaystyle {\underline {\underline {K}}}_{3,0}={\begin{pmatrix}{\frac {{{A}^{2}}E\eta +3{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}\right)&{\frac {{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}&-\left({\frac {{{A}^{2}}E\eta +3{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}\right)&{\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}&{\frac {{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}\\-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}\right)&{\frac {3{{A}^{2}}E\eta +{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}\right)&{\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}&-\left({\frac {3{{A}^{2}}E\eta +{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}\right)&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}\right)\\{\frac {{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}\right)&{\frac {{{A}^{2}}E\eta }{3{\ell _{0}}}}&-\left({\frac {{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}\right)&{\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}&{\frac {{{A}^{2}}E\eta }{6{\ell _{0}}}}\\-\left({\frac {{{A}^{2}}E\eta +3{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}\right)&{\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}&-\left({\frac {{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}\right)&{\frac {{{A}^{2}}E\eta +3{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}\right)&-\left({\frac {{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}\right)\\{\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}&-\left({\frac {3{{A}^{2}}E\eta +{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}\right)&{\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}\right)&{\frac {3{{A}^{2}}E\eta +{\ell _{0}^{2}}AE}{4{\ell _{0}^{3}}}}&{\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}\\{\frac {{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}\right)&{\frac {{{A}^{2}}E\eta }{6{\ell _{0}}}}&-\left({\frac {{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}\right)&{\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{\ell _{0}^{2}}}}&{\frac {{{A}^{2}}E\eta }{3{\ell _{0}}}}\end{pmatrix}}}
Element #4
K
_
_
4
,
0
=
(
A
2
E
η
ℓ
0
3
0
A
2
E
η
2
ℓ
0
2
−
(
A
2
E
η
ℓ
0
3
)
0
A
2
E
η
2
ℓ
0
2
0
A
E
ℓ
0
0
0
−
(
A
E
ℓ
0
)
0
A
2
E
η
2
ℓ
0
2
0
A
2
E
η
3
ℓ
0
−
(
A
2
E
η
2
ℓ
0
2
)
0
A
2
E
η
6
ℓ
0
−
(
A
2
E
η
ℓ
0
3
)
0
−
(
A
2
E
η
2
ℓ
0
2
)
A
2
E
η
ℓ
0
3
0
−
(
A
2
E
η
2
ℓ
0
2
)
0
−
(
A
E
ℓ
0
)
0
0
A
E
ℓ
0
0
A
2
E
η
2
ℓ
0
2
0
A
2
E
η
6
ℓ
0
−
(
A
2
E
η
2
ℓ
0
2
)
0
A
2
E
η
3
ℓ
0
)
{\displaystyle {\underline {\underline {K}}}_{4,0}={\begin{pmatrix}{\frac {{{A}^{2}}E\eta }{\ell _{0}^{3}}}&0&{\frac {{{A}^{2}}E\eta }{2{\ell _{0}^{2}}}}&-\left({\frac {{{A}^{2}}E\eta }{\ell _{0}^{3}}}\right)&0&{\frac {{{A}^{2}}E\eta }{2{\ell _{0}^{2}}}}\\0&{\frac {AE}{\ell _{0}}}&0&0&-\left({\frac {AE}{\ell _{0}}}\right)&0\\{\frac {{{A}^{2}}E\eta }{2{\ell _{0}^{2}}}}&0&{\frac {{{A}^{2}}E\eta }{3{\ell _{0}}}}&-\left({\frac {{{A}^{2}}E\eta }{2{\ell _{0}^{2}}}}\right)&0&{\frac {{{A}^{2}}E\eta }{6{\ell _{0}}}}\\-\left({\frac {{{A}^{2}}E\eta }{\ell _{0}^{3}}}\right)&0&-\left({\frac {{{A}^{2}}E\eta }{2{\ell _{0}^{2}}}}\right)&{\frac {{{A}^{2}}E\eta }{\ell _{0}^{3}}}&0&-\left({\frac {{{A}^{2}}E\eta }{2{\ell _{0}^{2}}}}\right)\\0&-\left({\frac {AE}{\ell _{0}}}\right)&0&0&{\frac {AE}{\ell _{0}}}&0\\{\frac {{{A}^{2}}E\eta }{2{\ell _{0}^{2}}}}&0&{\frac {{{A}^{2}}E\eta }{6{\ell _{0}}}}&-\left({\frac {{{A}^{2}}E\eta }{2{\ell _{0}^{2}}}}\right)&0&{\frac {{{A}^{2}}E\eta }{3{\ell _{0}}}}\end{pmatrix}}}
Wir sammeln alle Koordianten der Knoten im 0 -System in
Q
_
0
{\displaystyle {\underline {Q}}_{0}}
δ
Q
_
0
T
⋅
(
K
_
_
0
⋅
Q
_
0
−
P
_
)
=
0
{\displaystyle \delta {\underline {Q}}_{0}^{T}\cdot \left({\underline {\underline {K}}}_{0}\cdot {\underline {Q}}_{0}-{\underline {P}}\right)=0}
an.
Einarbeitung der Randbedingungen Die Randbedingungen arbeiten wir hier durch das Streichen der passenden Zeilen für
δ
U
1
,
0
,
δ
W
1
,
0
,
δ
U
2
,
0
,
δ
W
2
,
0
{\displaystyle \delta U_{1,0},\delta W_{1,0},\delta U_{2,0},\delta W_{2,0}}
U
1
,
0
,
W
1
,
0
,
U
2
,
0
,
W
2
,
0
{\displaystyle U_{1,0},W_{1,0},U_{2,0},W_{2,0}}
Das resultierende Gleichungssystem ist dies:
(
2
A
2
E
η
3
ℓ
0
0
0
−
(
2
A
2
E
η
ℓ
0
2
)
A
2
E
η
3
ℓ
0
0
0
0
0
2
A
2
E
η
3
ℓ
0
−
(
3
A
2
E
η
4
ℓ
0
2
)
−
(
A
2
E
η
4
ℓ
0
2
)
A
2
E
η
6
ℓ
0
0
−
(
A
2
E
η
2
ℓ
0
2
)
A
2
E
η
6
ℓ
0
0
−
(
3
A
2
E
η
4
ℓ
0
2
)
3
A
2
E
η
+
ℓ
0
2
A
E
2
ℓ
0
3
+
2
A
E
ℓ
0
0
−
(
3
A
2
E
η
2
ℓ
0
2
)
−
(
3
A
2
E
η
+
ℓ
0
2
A
E
4
ℓ
0
3
)
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
−
(
3
A
2
E
η
4
ℓ
0
2
)
−
(
2
A
2
E
η
ℓ
0
2
)
−
(
A
2
E
η
4
ℓ
0
2
)
0
A
2
E
η
+
3
ℓ
0
2
A
E
2
ℓ
0
3
+
8
A
2
E
η
ℓ
0
3
−
(
2
A
2
E
η
ℓ
0
2
)
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
−
(
A
2
E
η
+
3
ℓ
0
2
A
E
4
ℓ
0
3
)
A
2
E
η
4
ℓ
0
2
A
2
E
η
3
ℓ
0
A
2
E
η
6
ℓ
0
−
(
3
A
2
E
η
2
ℓ
0
2
)
−
(
2
A
2
E
η
ℓ
0
2
)
4
A
2
E
η
3
ℓ
0
3
A
2
E
η
4
ℓ
0
2
−
(
A
2
E
η
4
ℓ
0
2
)
A
2
E
η
6
ℓ
0
0
0
−
(
3
A
2
E
η
+
ℓ
0
2
A
E
4
ℓ
0
3
)
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
3
A
2
E
η
4
ℓ
0
2
3
A
2
E
η
+
ℓ
0
2
A
E
4
ℓ
0
3
+
A
E
ℓ
0
−
(
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
)
3
A
2
E
η
4
ℓ
0
2
0
−
(
A
2
E
η
2
ℓ
0
2
)
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
−
(
A
2
E
η
+
3
ℓ
0
2
A
E
4
ℓ
0
3
)
−
(
A
2
E
η
4
ℓ
0
2
)
−
(
3
A
2
E
η
−
3
ℓ
0
2
A
E
4
ℓ
0
3
)
A
2
E
η
+
3
ℓ
0
2
A
E
4
ℓ
0
3
+
A
2
E
η
ℓ
0
3
−
(
3
A
2
E
η
4
ℓ
0
2
)
0
A
2
E
η
6
ℓ
0
−
(
3
A
2
E
η
4
ℓ
0
2
)
A
2
E
η
4
ℓ
0
2
A
2
E
η
6
ℓ
0
3
A
2
E
η
4
ℓ
0
2
−
(
3
A
2
E
η
4
ℓ
0
2
)
2
A
2
E
η
3
ℓ
0
)
⋅
(
Φ
1
,
0
Φ
2
,
0
W
3
,
0
U
3
,
0
Φ
3
,
0
W
4
,
0
U
4
,
0
Φ
4
,
0
)
=
(
0
0
0
0
0
F
0
0
)
{\displaystyle {\begin{pmatrix}{\frac {2{{A}^{2}}E\eta }{3{\ell _{0}}}}&0&0&-\left({\frac {2{{A}^{2}}E\eta }{{\ell }_{0}^{2}}}\right)&{\frac {{{A}^{2}}E\eta }{3{\ell _{0}}}}&0&0&0\\0&{\frac {2{{A}^{2}}E\eta }{3{\ell _{0}}}}&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{{\ell }_{0}^{2}}}}\right)&-\left({\frac {{{A}^{2}}E\eta }{4{{\ell }_{0}^{2}}}}\right)&{\frac {{{A}^{2}}E\eta }{6{\ell _{0}}}}&0&-\left({\frac {{{A}^{2}}E\eta }{2{{\ell }_{0}^{2}}}}\right)&{\frac {{{A}^{2}}E\eta }{6{\ell _{0}}}}\\0&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{{\ell }_{0}^{2}}}}\right)&{\frac {3{{A}^{2}}E\eta +{{\ell }_{0}^{2}}AE}{2{{\ell }_{0}^{3}}}}+{\frac {2AE}{\ell _{0}}}&0&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta }{2{{\ell }_{0}^{2}}}}\right)&-\left({\frac {3{{A}^{2}}E\eta +{{\ell }_{0}^{2}}AE}{4{{\ell }_{0}^{3}}}}\right)&{\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{{\ell }_{0}^{2}}AE}{4{{\ell }_{0}^{3}}}}&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{{\ell }_{0}^{2}}}}\right)\\-\left({\frac {2{{A}^{2}}E\eta }{{\ell }_{0}^{2}}}\right)&-\left({\frac {{{A}^{2}}E\eta }{4{{\ell }_{0}^{2}}}}\right)&0&{\frac {{{A}^{2}}E\eta +3{{\ell }_{0}^{2}}AE}{2{{\ell }_{0}^{3}}}}+{\frac {8{{A}^{2}}E\eta }{{\ell }_{0}^{3}}}&-\left({\frac {2{{A}^{2}}E\eta }{{\ell }_{0}^{2}}}\right)&{\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{{\ell }_{0}^{2}}AE}{4{{\ell }_{0}^{3}}}}&-\left({\frac {{{A}^{2}}E\eta +3{{\ell }_{0}^{2}}AE}{4{{\ell }_{0}^{3}}}}\right)&{\frac {{{A}^{2}}E\eta }{4{{\ell }_{0}^{2}}}}\\{\frac {{{A}^{2}}E\eta }{3{\ell _{0}}}}&{\frac {{{A}^{2}}E\eta }{6{\ell _{0}}}}&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta }{2{{\ell }_{0}^{2}}}}\right)&-\left({\frac {2{{A}^{2}}E\eta }{{\ell }_{0}^{2}}}\right)&{\frac {4{{A}^{2}}E\eta }{3{\ell _{0}}}}&{\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{{\ell }_{0}^{2}}}}&-\left({\frac {{{A}^{2}}E\eta }{4{{\ell }_{0}^{2}}}}\right)&{\frac {{{A}^{2}}E\eta }{6{\ell _{0}}}}\\0&0&-\left({\frac {3{{A}^{2}}E\eta +{{\ell }_{0}^{2}}AE}{4{{\ell }_{0}^{3}}}}\right)&{\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{{\ell }_{0}^{2}}AE}{4{{\ell }_{0}^{3}}}}&{\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{{\ell }_{0}^{2}}}}&{\frac {3{{A}^{2}}E\eta +{{\ell }_{0}^{2}}AE}{4{{\ell }_{0}^{3}}}}+{\frac {AE}{\ell _{0}}}&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{{\ell }_{0}^{2}}AE}{4{{\ell }_{0}^{3}}}}\right)&{\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{{\ell }_{0}^{2}}}}\\0&-\left({\frac {{{A}^{2}}E\eta }{2{{\ell }_{0}^{2}}}}\right)&{\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{{\ell }_{0}^{2}}AE}{4{{\ell }_{0}^{3}}}}&-\left({\frac {{{A}^{2}}E\eta +3{{\ell }_{0}^{2}}AE}{4{{\ell }_{0}^{3}}}}\right)&-\left({\frac {{{A}^{2}}E\eta }{4{{\ell }_{0}^{2}}}}\right)&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta -{\sqrt {3}}{{\ell }_{0}^{2}}AE}{4{{\ell }_{0}^{3}}}}\right)&{\frac {{{A}^{2}}E\eta +3{{\ell }_{0}^{2}}AE}{4{{\ell }_{0}^{3}}}}+{\frac {{{A}^{2}}E\eta }{{\ell }_{0}^{3}}}&-\left({\frac {3{{A}^{2}}E\eta }{4{{\ell }_{0}^{2}}}}\right)\\0&{\frac {{{A}^{2}}E\eta }{6{\ell _{0}}}}&-\left({\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{{\ell }_{0}^{2}}}}\right)&{\frac {{{A}^{2}}E\eta }{4{{\ell }_{0}^{2}}}}&{\frac {{{A}^{2}}E\eta }{6{\ell _{0}}}}&{\frac {{\sqrt {3}}{{A}^{2}}E\eta }{4{{\ell }_{0}^{2}}}}&-\left({\frac {3{{A}^{2}}E\eta }{4{{\ell }_{0}^{2}}}}\right)&{\frac {2{{A}^{2}}E\eta }{3{\ell _{0}}}}\end{pmatrix}}\cdot {\begin{pmatrix}{{\Phi }_{1,0}}\\{{\Phi }_{2,0}}\\{W_{3,0}}\\{U_{3,0}}\\{{\Phi }_{3,0}}\\{W_{4,0}}\\{U_{4,0}}\\{{\Phi }_{4,0}}\end{pmatrix}}={\begin{pmatrix}0\\0\\0\\0\\0\\F\\0\\0\end{pmatrix}}}
Solving Das Ergebnis ist - für die gleichen Parameter wie in Stab -
U
1
,
0
=
0
W
1
,
0
=
0
Φ
1
,
0
=
3.97
F
E
a
2
U
2
,
0
=
0
W
2
,
0
=
0
Φ
2
,
0
=
2.45
F
E
a
2
U
3
,
0
=
57.7
F
E
a
W
3
,
0
=
1.67
⋅
10
2
F
E
a
Φ
3
,
0
=
2.06
F
E
a
2
U
4
,
0
=
−
57.7
F
E
a
W
4
,
0
=
3.67
⋅
10
2
F
E
a
Φ
4
,
0
=
3.12
F
E
a
2
{\displaystyle {\begin{array}{l}U_{1,0}=0\\W_{1,0}=0\\\Phi _{1,0}=3.97{\frac {F}{Ea^{2}}}\\U_{2,0}=0\\W_{2,0}=0\\\Phi _{2,0}=2.45{\frac {F}{Ea^{2}}}\\U_{3,0}=57.7{\frac {F}{Ea}}\\W_{3,0}=1.67\cdot 10^{2}{\frac {F}{Ea}}\\\Phi _{3,0}=2.06{\frac {F}{Ea^{2}}}\\U_{4,0}=-57.7{\frac {F}{Ea}}\\W_{4,0}=3.67\cdot 10^{2}{\frac {F}{Ea}}\\\Phi _{4,0}=3.12{\frac {F}{Ea^{2}}}\end{array}}}
Und damit sind auch die Verläufe der Schnittlasten in den Stäben identisch - wir brauchen also die Ergebnisse nicht noch einmal auftragen.
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Literature
