m For this example, we will use the 2D spar element as selected in the above figure. Select the element shown and click 'OK'.
You should see 'Type 1 LINK1' in the 'Element Types' window.
m Click on 'Close' in the 'Element Types' dialog box.
5. Define Geometric Properties
We now need to specify geometric properties for our elements:
m In the Preprocessor menu, select Real Constants > Add/Edit/Delete
m m Click Add... and select 'Type 1 LINK1' (actually it is already selected). Click on 'OK'. The following window will appear:
m As shown in the window above, enter the cross-sectional area (3250mm):
m Click on 'OK'.
m 'Set 1' now appears in the dialog box. Click on 'Close' in the 'Real Constants' window.
6. Element Material Properties
You then need to specify material properties:
m In the 'Preprocessor' menu select Material Props > Material Models
m Double
m Double click on Structural > Linear > Elastic > Isotropic
We are going to give the properties of Steel. Enter the following field:
EX 200000
m Set these properties and click on 'OK'. Note: You may obtain the note 'PRXY will be set to 0.0'. This is poisson's ratio and is
not required for this element type. Click 'OK' on the window to continue. Close the "Define Material Model Behavior" by
clicking on the 'X' box in the upper right hand corner.
7. Mesh Size
The last step before meshing is to tell ANSYS what size the elements should be. There are a variety of ways to do this but we will
just deal with one method for now.
m In the Preprocessor menu select Meshing > Size Cntrls > ManualSize > Lines > All Lines
m In the size 'NDIV' field, enter the desired number of divisions per line. For this example we want only 1 division per line,
therefore, enter '1' and then click 'OK'. Note that we have not yet meshed the geometry, we have simply defined the element
sizes.
8. Mesh
Now the frame can be meshed.
m In the 'Preprocessor' menu select Meshing > Mesh > Lines and click 'Pick All' in the 'Mesh Lines' Window
Your model should now appear as shown in the following window
Plot Numbering
To show the line numbers, keypoint numbers, node numbers...
l From the Utility Menu (top of screen) select PlotCtrls > Numbering...
l Fill in the Window as shown below and click 'OK'
Now you can turn numbering on or off at your discretion
Saving Your Work
Save the model at this time, so if you make some mistakes later on, you will at least be able to come back to this point. To do this, on the
Utility Menu select File > Save as.... Select the name and location where you want to save your file.
It is a good idea to save your job at different times throughout the building and analysis of the model to backup your work in case of a
system crash or what have you.
Solution Phase: Assigning Loads and Solving
You have now defined your model. It is now time to apply the load(s) and constraint(s) and solve the the resulting system of equations.
Open up the 'Solution' menu (from the same 'ANSYS Main Menu').
1. Define Analysis Type
2. First you must tell ANSYS how you want it to solve this problem:
3. m From the Solution Menu, select Analysis Type > New Analysis.
m Ensure that 'Static' is selected; i.e. you are going to do a static analysis on the truss as opposed to a dynamic analysis, for
example.
m Click 'OK'.
2. Apply Constraints
It is necessary to apply constraints to the model otherwise the model is not tied down or grounded and a singular solution will
result. In mechanical structures, these constraints will typically be fixed, pinned and roller-type connections. As shown above, the
left end of the truss bridge is pinned while the right end has a roller connection.
m In the Solution menu, select Define Loads > Apply > Structural > Displacement > On Keypoints
m Select the left end of the bridge (Keypoint 1) by clicking on it in the Graphics Window and click on 'OK' in the 'Apply U,
ROT on KPs' window.
m
m This location is fixed which means that all translational and rotational degrees of freedom (DOFs) are constrained.
Therefore, select 'All DOF' by clicking on it and enter '0' in the Value field and click 'OK'.
You will see some blue triangles in the graphics window indicating the displacement contraints.
m Using the same method, apply the roller connection to the right end (UY constrained). Note that more than one DOF
constraint can be selected at a time in the "Apply U,ROT on KPs" window. Therefore, you may need to 'deselect' the 'All
DOF' option to select just the 'UY' option.
3. Apply Loads
As shown in the diagram, there are four downward loads of 280kN, 210kN, 280kN, and 360kN at keypoints 1, 3, 5, and 7
respectively.
m Select Define Loads > Apply > Structural > Force/Moment > on Keypoints.
m Select the first Keypoint (left end of the truss) and click 'OK' in the 'Apply F/M on KPs' window.
m Select FY in the 'Direction of force/mom'. This indicate that we will be applying the load in the 'y' direction
m Enter a value of -280000 in the 'Force/moment value' box and click 'OK'. Note that we are using units of N here, this is
consistent with the previous values input.
m The force will appear in the graphics window as a red arrow.
m Apply the remaining loads in the same manner.
The applied loads and constraints should now appear as shown below.
4. Solving the System
We now tell ANSYS to find the solution:
m In the 'Solution' menu select Solve > Current LS. This indicates that we desire the solution under the current Load Step
(LS).
m The above windows will appear. Ensure that your solution options are the same as shown above and click 'OK'.
m Once the solution is done the following window will pop up. Click 'Close' and close the /STATUS Command Window..
Postprocessing: Viewing the Results
1. Hand Calculations
We will
We will first calculate the forces and stress in element 1 (as labeled in the problem description).
2. Results Using ANSYS
Reaction Forces
A list of the resulting reaction forces can be obtained for this element
m from the Main Menu select General Postproc > List Results > Reaction Solu.
m Select 'All struc forc F' as shown above and click 'OK'
These values agree with the reaction forces claculated by hand above.
Deformation
m In the General Postproc menu, select Plot Results > Deformed Shape. The following window will appear.
m Select 'Def + undef edge' and click 'OK' to view both the deformed and the undeformed object.
m Observe the value of the maximum deflection in the upper left hand corner (DMX=7.409). One should also observe that the
constrained degrees of freedom appear to have a deflection of 0 (as expected!)
Deflection
For a more detailed version of the deflection of the beam,
m From the 'General Postproc' menu select Plot results > Contour Plot > Nodal Solution. The following window will
appear.
m Select 'DOF solution' and 'USUM' as shown in the above window. Leave the other selections as the default values. Click
'OK'.
m Looking at the scale, you may want to use more useful intervals. From the Utility Menu select Plot Controls > Style >
Contours > Uniform Contours...
m Fill in the following window as shown and click 'OK'.
You should obtain the following.
m The deflection can also be obtained as a list as shown below. General Postproc > List Results > Nodal Solution select
'DOF Solution' and 'ALL DOFs' from the lists in the 'List Nodal Solution' window and click 'OK'. This means that we want
to see a listing of all degrees of freedom from the solution.
m Are these results what you expected? Note that all the degrees of freedom were constrained to zero at node 1, while UY was
constrained to zero at node 7.
m If you wanted to save these results to a file, select 'File' within the results window (at the upper left-hand corner of this list
window) and select 'Save as'.
Axial Stress
For line elements (ie links, beams, spars, and pipes) you will often need to use the Element Table to gain access to derived data (ie
stresses, strains). For this example we should obtain axial stress to compare with the hand calculations. The Element Table is
different for each element, therefore, we need to look at the help file for LINK1 (Type help link1 into the Input Line). From
Table 1.2 in the Help file, we can see that SAXL can be obtained through the ETABLE, using the item 'LS,1'
m From the General Postprocessor menu select Element Table > Define Table
m Click on 'Add...'
m As shown above, enter 'SAXL' in the 'Lab' box. This specifies the name of the item you are defining. Next, in the 'Item,
Comp' boxes, select 'By sequence number' and 'LS,'. Then enter 1 after LS, in the selection box
m Click on 'OK' and close the 'Element Table Data' window.
m Plot the Stresses by selecting Element Table > Plot Elem Table
m The following window will appear. Ensure that 'SAXL' is selected and click 'OK'
m Because you changed the contour intervals for the Displacement plot to "User Specified" - you need to switch this back to
"Auto calculated" to obtain new values for VMIN/VMAX.
Utility Menu > PlotCtrls > Style > Contours > Uniform Contours ...
Again, you may wish to select more appropriate intervals for the contour plot
m List the Stresses
n ...
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