SimCafe

Space shortcuts

Child pages
  • Bike Crank - Numerical Results

Versions Compared

Old Version 8

changes.mady.by.user user-0108f

Saved on

compared with

New Version Current

changes.mady.by.user user-a4c52

Saved on

Key

  • This line was added.
  • This line was removed.
  • Formatting was changed.
Comment: Migration of unmigrated content due to installation of a new plugin

Include Page
ANSYS Google Analytics
ANSYS Google Analytics
Include Page
Bike Crank - Panel
Bike Crank - Panel

Numerical Results

Deformed Shape

The following video shows how to plot the deformed shape and use it to check if the displacement constraints have been applied correctly.

HTML
<iframe width="600" height="338" src="
Wiki Markup
{include: ANSYS Google Analytics}
{include: Bike Crank - Panel}

h1. Numerical Results

h3. Deformed Shape

The following video shows how to plot the deformed shape and use it to check if the displacement constraints have been applied correctly.
\\
{widget:url=http://www.youtube.com/watchembed/yVtxuL9Nxy8?v=yVtxuL9Nxy8|width=600|height=370}
\\

h3. {latex} {\bf $\sigma_x$}{latex} Contours

We next take a look at {latex}rel=0" frameborder="0" allowfullscreen></iframe>

Summary of steps in the above video:

  1. Under the tree, highlight Solution
  2. Select Deformation > Total Deformation
  3. Solve

Sigma_x Contours

We next take a look at

Latex
 $\sigma_x$

...

 variation 
...
 in 
...
 the model.
 HTML
<iframe width="600" height="338" src=" model.
\\
{widget:url=http://www.youtube.com/embed/watch35YXCKqC1Ng?v=35YXCKqC1Ng|width=600|height=370}
\\

You can save an image of the contours to a file using the instructions below.
\\
{widget:url=rel=0" frameborder="0" allowfullscreen></iframe>
Summary of steps in the above video:
  1. Under the tree, highlight Solution
  2. Select Stress > Normal Stress
  3. Check that it is in the X direction and rename to sigma_x
  4. Solve
You can save an image of the contours to a file using the instructions below.
 HTML
<iframe width="600" height="338" src="http://www.youtube.com/watch?v=embed/4PGJ90-lg0o|width=600|height=370}
\\

Below, we take a closer look at the {latex}?rel=0" frameborder="0" allowfullscreen></iframe>
It's incredibly hard to describe in words where this button is located. Watch the video and skip to 0:18 for the location. OR use the snipping tool.
 
Below, we take a closer look at the 
 Latex
 $\sigma_x$
...
 variation 
...
 on 
...
 the 
...
 front 
...
 face 
...
 and 
...
 compare 
...
 it 
...
 to 
...
 what 
...
 we 
...
 expect 
...
 from 
...
 beam 
...
 bending theory.
 HTML
<iframe width="600" height="338" src=" theory.
\\
{widget:url=http://www.youtube.com/embed/watch1YSyadkkzms?v=1YSyadkkzms|width=600|height=370}
\\

We interrogate {latex}rel=0" frameborder="0" allowfullscreen></iframe>
Summary of steps in the above video:
  1. Next to Probe, click on Max and Min to enable the location of highest and lowest normal stress in the x direction
 
We interrogate 
 Latex
 $\sigma_x$
...
 variation 
...
 in 
...
 the 
...
 interior 
...
 of 
...
 the 
...
 model 
...
 using 
...
 "section 
...
 planes".
 HTML
<iframe width="600" height="338" src="
\\
{widget:url=http://www.youtube.com/embed/watch?v=YM_YUta3-78|width=600|height=370}
\\

h3. {latex} ${\bf \sigma_x}${latex} along a Line using "Path" Operations

First, we create two coordinate systems which we'll use to define the start and end points of the line.
\\
{widget:url=?rel=0" frameborder="0" allowfullscreen></iframe>
 
Sigma_x along a Line using "Path" Operations
First, we create two coordinate systems which we'll use to define the start and end points of the line.
 HTML
<iframe width="600" height="338" src="http://www.youtube.com/embed/watch?v=R-w8mA2MzSk|width=600|height=370}
\\

Second, we create the desired line on the front face.
\\
{widget:url?rel=0" frameborder="0" allowfullscreen></iframe>
 
Second, we create the desired line on the front face.
 HTML
<iframe width="600" height="338" src="=http://www.youtube.com/embed/watchdDPSyw6dNXE?v=MW2jSeEfHpw|width=600|height=370}
\\

Last, we extract {latex}rel=0" frameborder="0" allowfullscreen></iframe>
 
Last, we extract 
 Latex
 $\sigma_x$
...
 along 
...
 the 
...
 line 
...
 and 
...
 export 
...
 the 
...
 results 
...
 to 
...
 an 
...
 Excel file.
 HTML
<iframe width="600" height="338" src=" file.
\\
{widget:url=http://www.youtube.com/watchembed/kJfABDOVfIo?v=kJfABDOVfIo|width=600|height=370}
\\

\\
[*Go to Step 7: Verification & Validation*|Bike Crank - Verification & Validation]

[Go to all ANSYS Learning Modules|ANSYS Learning Modules]\\
\\rel=0" frameborder="0" allowfullscreen></iframe>
 

  Go to Step 7: Verification & Validation 
Go to all ANSYS Learning Modules