Introduction
This tutorial was completed using ANSYS 7.0. The purpose of this tutorial is to explain how to apply distributed loads and use element tables to extract data. Please note that this material was also covered in the 'Bicycle Space Frame' tutorial under 'Basic Tutorials'.
A distributed load of 1000 N/m (1 N/mm) will be applied to a solid steel beam with a rectangular cross section as shown in the figure below. The cross-section of the beam is 10mm x 10mm while the modulus of elasticity of the steel is 200GPa.
Preprocessing: Defining the Problem
- Open preprocessor menu
/PREP7 - Give example a Title
Utility Menu > File > Change Title ...
/title, Distributed Loading - Create Keypoints
Preprocessor > Modeling > Create > Keypoints > In Active CS
K,#,x,yWe are going to define 2 keypoints (the beam vertices) for this structure as given in the following table:Keypoint Coordinates (x,y) 1 (0,0) 2 (1000,0) - Define Lines
Preprocessor > Modeling > Create > Lines > Lines > Straight Line
L,K#,K#Create a line between Keypoint 1 and Keypoint 2. - Define Element Types
- Define Real Constants
- Cross-sectional area AREA: 100
- Area Moment of Inertia IZZ: 833.333
- Total beam height HEIGHT: 10
- Define Element Material Properties
Preprocessor > Material Props > Material Models > Structural > Linear > Elastic > IsotropicIn the window that appears, enter the following geometric properties for steel: - Young's modulus EX: 200000
- Poisson's Ratio PRXY: 0.3
- Define Mesh Size
Preprocessor > Meshing > Size Cntrls > ManualSize > Lines > All Lines...For this example we will use an element length of 100mm. - Mesh the frame
Preprocessor > Meshing > Mesh > Lines > click 'Pick All' - Plot Elements
Utility Menu > Plot > Elements You may also wish to turn on element numbering and turn off keypoint numberingUtility Menu > PlotCtrls > Numbering ...
Solution Phase: Assigning Loads and Solving
- Define Analysis Type
- Apply Constraints
- Apply Loads We will apply a distributed load, of 1000 N/m or 1 N/mm, over the entire length of the beam.
- Select Solution > Define Loads > Apply > Structural > Pressure > On Beams
- Click 'Pick All' in the 'Apply F/M' window.
- As shown in the following figure, enter a value of 1 in the field 'VALI Pressure value at node I' then click 'OK'.
- Solve the System
ANTYPE,0
Note:
SOLVE
Postprocessing: Viewing the Results
- Plot Deformed Shape
General Postproc > Plot Results > Deformed Shape
PLDISP.2 - Plot Principle stress distributionAs shown previously, we need to use element tables to obtain principle stresses for line elements.
- Select General Postproc > Element Table > Define Table
- Click 'Add...'
- In the window that appears
- enter 'SMAXI' in the 'User Label for Item' section
- In the first window in the 'Results Data Item' section scroll down and select 'By sequence num'
- In the second window of the same section, select 'NMISC, '
- In the third window enter '1' anywhere after the comma
- click 'Apply'
- Repeat steps 2 to 4 but change 'SMAXI' to 'SMAXJ' in step 3a and change '1' to '3' in step 3d.
- Click 'OK'. The 'Element Table Data' window should now have two variables in it.
- Click 'Close' in the 'Element Table Data' window.
- Select: General Postproc > Plot Results > Line Elem Res...
- Select 'SMAXI' from the 'LabI' pull down menu and 'SMAXJ' from the 'LabJ' pull down menu
- ANSYS can only calculate the stress at a single location on the element. For this example, we decided to extract the stresses from the I and J nodes of each element. These are the nodes that are at the ends of each element.
- For this problem, we wanted the principal stresses for the elements. For the BEAM3 element this is categorized as NMISC, 1 for the 'I' nodes and NMISC, 3 for the 'J' nodes. A list of available codes for each element can be found in the ANSYS help files. (ie. type help BEAM3 in the ANSYS Input window).
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