ABAQUS_TutorialCantilever Beam
Contents
1. You will now generate the finite element mesh You can choose the meshing technique that Abaqus CAE will use to create the mesh the element shape and the element type Abaqus CAE uses a number of different meshing techniques The default meshing technique assigned to the model is indicated by the color of the model when you enter the Mesh module if Abaqus CAE displays the model in orange it cannot be meshed without assistance from you Appendix B Abaqus CAE A BASIC TUTORIAL Assigning mesh controls In this section you will use the Mesh Controls dialog box to examine the technique that Abaqus CAE will use to mesh the model and the shape of the elements that Abaqus CAE will generate To assign the mesh controls 1 In the Model Tree expand the Beam item underneath the Parts container and double click Mesh in the list that appears Abaqus CAE switches to the Mesh module The Mesh module functionality is available only through menu bar items or toolbox icons 2 From the main menu bar select Mesh Controls The Mesh Controls dialog box appears Abaqus CAE colors the regions of your model to indicate which technique it will use to mesh that region Abaqus CAE will use structured meshing to mesh your cantilever beam and displays the beam in green 3 In the dialog box accept Hex as the default Element Shape selection 4 Accept Structured as the default Technique selection 5 Click OK to assign the mesh controls and to close the dialo2. Abaqus CAE switches to the Property module and the Edit Material dialog box appears Name the material Steel Use the menu bar under the browser area of the material editor to reveal menus containing all the available material options Some of the menu items contain submenus for example Figure B 7 shows the options available under the Mechanical Elasticity menu item When you select a material option the appropriate data entry form appears below the menu From the material editor s menu bar select Mechanical Elasticity Elastic Abaqus CAE displays the Elastic data form Type a value of 209 3 for Young s modulus and a value of 0 3 for Poisson s ratio in the respective fields as shown in Figure B 8 Use Tab to move between cells Click OK to exit the material editor B 8 Appendix B Abaqus CAE A BASIC TUTORIAL Delete General Mechanical Thermal Other Elasticity Plasticity Damage for Ductile Metals Damage for Traction Separation Laws Damage for Fiber Reinforced Composites Deformation Plasticity Damping Expansion Brittle Cracking Hyperelastic Hyperfoam Hypoelastic Porous Elastic YYYY Y Viscoelastic Figure B 7 Submenus available under the Mechanical menu Data Young s Poisson s Modulus Ratio 1 209 E3 0 3 Figure B 8 Entering data values for the elastic material properties B 5 Defining and assigning section properties You define the properti
3. Plane stress strain thickness c Click OK Assigning the section to the cantilever beam The section BeamSection must be assigned to the part To assign the section to the cantilever beam 1 In the Model Tree expand the branch for the part named Beam by clicking the symbol to expand the Parts container and then clicking the symbol to expand the Beam item Double click Section Assignments in the list of part attributes that appears Abaqus CAE displays prompts in the prompt area to guide you through the procedure Click anywhere on the beam to select the region to which the section will be applied Abaqus CAE highlights the entire beam Click mouse button 2 in the viewport or click Done in the prompt area to accept the selected geometry The Edit Section Assignment dialog box appears containing a list of existing sections Accept the default selection of BeamSection as the section and click OK Abaqus CAE assigns the solid section to the beam colors the entire beam aqua to indicate that the region has a section assignment and closes the Edit Section Assignment dialog box Note the following key point When you assign a section to a region of a part the region takes on the material properties associated with the section B 6 Assembling the model Each part that you create is oriented in its own coordinate system and is independent of the other parts in the model Although a model may contain
4. can create parts that are native to Abaqus CAE or you can import parts created by other applications either as a geometric representation or as a finite element mesh You will start the cantilever beam tutorial by creating a three dimensional deformable solid body You do this by sketching the two dimensional profile of the beam a rectangle and extruding it Abaqus CAE automatically enters the Sketcher when you create a part Abaqus CAE often displays a short message in the prompt area indicating what it expects you to do next as shown in Figure B 4 previous prompt el X Sketch the section for the solid extrusion cancel Figure B 4 Messages and instructions are displayed in the prompt area Click the Cancel button to cancel the current task Click the Previous button to cancel the current step in the task and return to the previous step To create the cantilever beam 1 If you did not already start Abaqus CAE type abaqus cae Resize your windows so that you can follow the tutorial and see the Abaqus CAE main window 2 From the Start Session dialog box that appears select Create Model Database If you are already in an Abaqus CAE session select File New from the main menu bar Abaqus CAE enters the Part module The Model Tree appears in the left side of the main window Between the Model Tree and the canvas is the Part module toolbox A toolbox contains a set of icons that allow expert users to bypass the menus in the main men
5. plot the default variable displayed depends on the analysis procedure in this case the default variable is the von Mises stress From the main menu bar select Result Field Output to examine the variables that are available for display Abaqus CAE displays the Field Output dialog box click the Primary Variable tab to choose which variable to display and to select the invariant or component of interest By default the Mises invariant of the Stress components at integration points variable is selected Click Cancel to close the Field Output dialog box You have now finished this tutorial Appendix C Using Additional Techniques to Create and Analyze a Model in Abaqus CAE introduces additional techniques to create and analyze a model for example you will create and assemble multiple part instances and define contact Appendix D Viewing the Output from Your Analysis covers the capabilities of the Visualization module in more detail B 12 Summary When you create a part you name it and choose its type modeling space base feature and approximate size Abaqus CAE automatically enters the Sketcher when you create or edit a part You use the Sketcher to draw the two dimensional profiles of parts Click and drag toolbox icons to reveal and select hidden icons Click mouse button 2 in the viewport to indicate you have finished selecting items or using a tool B 23 Appendix B Abaqus CAE A BASIC TUTORIAL e You can cr
6. select the depth Optional parameters to modify the extrusion shape are also available In the Depth field erase the default value of 30 and type a value of 25 0 Click OK to accept this value Abaqus CAE displays an isometric view of the new part as shown in Figure B 6 To help you orient the cantilever beam during the modeling process Abaqus CAE displays a triad in the lower left corner indicating the orientation of the X Y and Z axes 11 Before you continue the tutorial save your model in a model database file a From the main menu bar select File Save The Save Model Database As dialog box appears b Type a name for the new model database in the File Name field and click OK You do not need to include the file extension Abaqus CAE automatically appends cae to the file name Appendix B Abaqus CAE A BASIC TUTORIAL Figure B 6 Isometric view of the beam Abaqus CAE stores the model database in a new file and returns to the Part module The title bar of the Abaqus CAE window displays the path and name of the model database You should always save your model database at regular intervals for example each time you switch modules B 4 Creating a material For the cantilever beam tutorial you will create a single linear elastic material with Young s modulus of 209 x 10 MPa and Poisson s ratio of 0 3 To define a material 1 In the Model Tree double click the Materials container to create a new material
7. shown in Figure B 12 Figure B 12 Meshing the part B 10 Creating and submitting an analysis job Now that you have configured your analysis you will create a job that is associated with your model and to submit the job for analysis To create and submit an analysis job 1 In the Model Tree double click the Jobs container to create a job Abaqus CAE switches to the Job module and the Create Job dialog box appears with a list of the models in the model database 2 Name the job Deform 3 Click Continue to create the job The Edit Job dialog box appears 4 In the Description field type Cantilever beam tutorial 5 Click the tabs to review the default settings in the job editor Click OK to accept all the default job settings and to close the dialog box 6 In the Model Tree expand the Jobs container click mouse button 3 on the job named Deform and select Submit from the menu that appears to submit your job for analysis B 20 Appendix B Abaqus CAE A BASIC TUTORIAL After you submit your job information appears next to the job name indicating the job s status The status of the cantilever beam tutorial shows one of the following e Submitted while the analysis input file is being generated e Running while Abaqus analyzes the model e Completed when the analysis is complete and the output has been written to the output database e Aborted if Abaqus CAE finds a problem with the input file or the analysis
8. the Model Tree click mouse button 3 on the Field Output Requests container and select Manager from the menu that appears Abaqus CAE displays the Field Output Requests Manager This manager displays an alphabetical list of existing output requests along the left side of the dialog box The names of all the steps in the analysis appear along the top of the dialog box in the order of execution The table formed by these two lists displays the status of each output request in each step 2 Review the default output request that Abaqus CAE generates for the Static General step you created and named BeamLoad Click the cell in the table labeled Created that cell becomes highlighted and the following information related to the cell appears in the legend at the bottom of the manager e The type of analysis procedure carried out in the step in that column e The list of output request variables e The output request status 3 On the right side of the Field Output Requests Manager click Edit to view more detailed information about the output request The field output editor appears In the Output Variables region of the dialog box a text box lists all the variables that will be output If you change an output request you can always return to the default settings by clicking Preselected defaults above the text box 4 Click the arrows next to each output variable category to see exactly which variables will be output The check boxes next to each ca
9. this case the four corners of the rectangle are assigned perpendicular constraints and one edge is designated as horizontal d Use the dimension tool e to dimension the top and left edges of the rectangle The top edge should have a horizontal dimension of 200 mm and the left edge should have a vertical dimension of 20 mm When dimensioning each edge simply select the line click mouse button 1 to position the dimension text and then enter the new dimension in the prompt area e The final sketch is shown in Figure B 5 B 6 Appendix B Abaqus CAE A BASIC TUTORIAL Figure B 5 Sketch of the rectangle 8 If you make a mistake while using the Sketcher you can delete lines in your sketch as explained in the following procedure a From the Sketcher toolbox click the Delete tool he b From the sketch click a line to select it Abaqus CAE highlights the selected line in red c Click mouse button 2 in the viewport to delete the selected line d Repeat steps b and c as often as necessary e Click mouse button 2 in the viewport to finish using the Delete tool 9 From the prompt area near the bottom of the main window click Done to exit the Sketcher Note If you don t see the Done button in the prompt area continue to click mouse button 2 in the viewport until it appears 10 Because you are creating an extruded part Abaqus CAE displays the Edit Base Extrusion dialog box for you to
10. Appendix B Abaqus CAE A BASIC TUTORIAL Appendix B Creating and Analyzing a Simple Model in Abaqus CAE The following section is a basic tutorial for the experienced Abaqus user It leads you through the Abaqus CAE modeling process by visiting each of the modules and showing you the basic steps to create and analyze a simple model To illustrate each of the steps you will first create a model of a steel cantilever beam and load its top surface see Figure B 1 20 mm 4 25mm Figure B 1 A loaded cantilever beam You will then analyze the beam and plot the resulting stresses and displacements The entire tutorial takes approximately 90 minutes to complete The following topics are covered e Understanding Abaqus CAE modules Section B 1 e Understanding the Model Tree Section B 2 e Creating a part Section B 3 e Creating a material Section B 4 e Defining and assigning section properties Section B 5 e Assembling the model Section B 6 e Defining your analysis steps Section B 7 e Applying a boundary condition and a load to the model Section B 8 e Meshing the model Section B 9 e Creating and submitting an analysis job Section B 10 e Viewing the results of your analysis Section B 11 Appendix B Abaqus CAE A BASIC TUTORIAL B 1 Understanding Abaqus CAE modules Abaqus CAE is divided into modules where each module defines an aspect of t
11. Load dialog box a Name the load Pressure b From the list of steps select BeamLoad as the step in which the load will be applied c In the Category list accept Mechanical as the default category selection d In the Types for Selected Step list select Pressure and click Continue Abaqus CAE displays prompts in the prompt area to guide you through the procedure 3 In the viewport select the top face of the beam as the surface to which the load will be applied The desired face is shown by the gridded face in Figure B 10 Appendix B Abaqus CAE A BASIC TUTORIAL Figure B 10 Selecting the region on which to apply a pressure load 4 Click mouse button 2 or click Done in the prompt area in the viewport to indicate that you have finished selecting regions The Edit Load dialog box appears 5 In the dialog box a Enter a magnitude of 0 5 for the load b Accept the default Distribution selection Abaqus will apply the load uniformly over the face c Accept the default Amplitude selection Abaqus will ramp up the load during the step d Click OK to create the load and to close the dialog box Abaqus CAE displays downward pointing arrows along the top face of the beam to indicate the load applied in the negative 2 direction 6 Examine the Load Manager and note that the new load is Created activated in the general analysis step BeamLoad 7 Click Dismiss to close the Load Manager B 9 Meshing the model
12. The increment within the step e The step time e When you are viewing a deformed plot the deformed variable and the deformation scale factor B 21 Appendix B Abaqus CAE A BASIC TUTORIAL 2 oe step BeamLoad Load the top of the beam Increment 1 Step Time 1 000 Figure B 13 Undeformed shape plot of model title block suppressed By default Abaqus CAE plots the last step and the last frame of your analysis Buttons that allow you to control which analysis results are plotted are available in the prompt area 2 From the main menu bar select Plot Deformed Shape to view a deformed shape plot 3 Click the auto fit tool E so that the entire plot is rescaled to fit in the viewport as shown in Figure B 14 2 A ep BeamLoad Load the top of the beam ad 1 S i 3 1 000 st Tncrement tep Time Deformed Var U Deformation Scale Factor 2 806e Figure B 14 Deformed shape plot of model title block suppressed B 22 4 5 Appendix B Abaqus CAE A BASIC TUTORIAL From the main menu bar select Plot Contours On Deformed Shape to view a contour plot of the von Mises stress as shown in Figure B 15 Mises 1 200e 01 2 475e 01 2 we Step BeamLoad Load the top of the beam 3 Tncrement 1 Step Time 1 000 Primary Var S Mises Deformed Var U Deformation Scale Factor 2 806e 01 Figure B 15 Contour plot of Mises stress title block suppressed For a contour
13. and aborts the analysis In addition Abaqus CAE reports the problem in the message area 7 When the job completes successfully you are ready to view the results of the analysis with the Visualization module In the Model Tree click mouse button 3 on the job named Deform and select Results to enter the Visualization module Abaqus CAE enters the Visualization module opens the output database created by the job and displays a representation of the model B 11 Viewing the results of your analysis You use the Visualization module to read the output database that Abaqus CAE generated during the analysis and to view the results of the analysis Because you named the job Deform when you created the job Abaqus CAE names the output database Deform odb For the tutorial you will view the undeformed and deformed shapes of the cantilever beam model and create a contour plot To view the results of your analysis 1 After you select Results in the Model Tree Abaqus CAE enters the Visualization module opens Deform odb and displays the undeformed shape of the model as shown in Figure B 13 The title block indicates the following e The job description e The output database from which Abaqus CAE read the data e The version of Abaqus Standard or Abaqus Explicit that was used to generate the output database e The date the output database was generated The state block indicates the following e The step name and the step description e
14. cted and click Continue The Edit Step dialog box appears with the default settings for a general static step 4 The Basic tab is selected by default In the Description field type Load the top of the beam 5 Click the Incrementation tab and accept the default time incrementation settings 6 Click the Other tab to see its contents you can accept the default values provided for the step 7 Click OK to create the step and to exit the Edit Step dialog box Appendix B Abaqus CAE A BASIC TUTORIAL Requesting data output When you submit your job for analysis Abaqus Standard or Abaqus Explicit writes the results of the analysis to the output database For each step you create you can use the Field Output Requests Manager and the History Output Requests Manager to do the following e Select the region of the model for which Abaqus will generate data e Select the variables that Abaqus will write to the output database e Select the section points of beams or shells for which Abaqus will generate data e Change the frequency at which Abaqus will write data to the output database When you create a step Abaqus CAE generates a default output request for the step See Which variables are in the output database Section D 2 for more information on field and history output For the cantilever beam tutorial you will simply examine the output requests and accept the default configuration To examine your output requests 1 In
15. eate a material and define its properties and create a section and define its category and type Since the section refers to the material the material must be defined first e A model contains only one assembly The assembly is composed of instances of parts positioned in a global coordinate system e Abaqus CAE generates the initial step automatically but you must create analysis steps You use the step editor to define each analysis step e When you create a step Abaqus CAE generates a default output request for the step You use the Field Output Requests Manager and the History Output Requests Manager to examine which categories of data will be output e You invoke the field and history output editors from the Field Output Requests Manager and the History Output Requests Manager to select the variables that Abaqus CAE will write to the output database during the analysis as well as the frequency at which they are written and the regions and section points from which they are written e Prescribed conditions such as loads and boundary conditions are step dependent objects which means that you must specify the step or steps in which they become active e Managers are useful for reviewing and modifying the status of prescribed conditions in each step e You create loads and define where the load is applied to the assembly in the Load module e Although you can create a mesh at any point after creating the assembly you typically do it after c
16. er toolbox for a short time a small window appears that gives a brief description of the tool The following aspects of the Sketcher help you sketch the desired geometry e The Sketcher grid helps you position the cursor and align objects in the viewport e Dashed lines indicate the X and Y axes of the sketch and intersect at the origin of the sketch e A triad in the lower left corner of the viewport indicates the relationship between the sketch plane and the orientation of the part e When you select a sketching tool Abaqus CAE displays the X and Y coordinates of the cursor in the upper left corner of the viewport tI 6 To sketch the profile of the cantilever beam you need to select the rectangle drawing tool i The rectangle drawing tool appears in the Sketcher toolbox with a white background indicating that you selected it Abaqus CAE displays prompts in the prompt area to guide you through the procedure 7 In the viewport sketch the rectangle using the following steps a You will first sketch a rough approximation of the beam and then use constraints and dimensions to refine the sketch Select any two points as the opposite corners of the rectangle b Click mouse button 2 anywhere in the viewport to exit the rectangle tool Note If you are a Windows user with a 2 button mouse press both mouse buttons simultaneously whenever you are asked to press mouse button 2 c The Sketcher automatically adds constraints to the sketch in
17. es of a part through sections After you create the section you can use one of the following two methods to assign the section to the part in the current viewport e You can simply select the region from the part and assign the section to the selected region e You can use the Set toolset to create a homogeneous set containing the region and assign the section to the set For the cantilever beam tutorial you will create a single homogeneous solid section that you will assign to the beam by selecting the beam from the viewport The solid section will contain a reference to the material Steel that you just created Defining a homogeneous solid section A homogeneous solid section is the simplest section type that you can define it includes only a material reference and a plane stress plane strain thickness To define the homogeneous solid section 1 In the Model Tree double click the Sections container to create a section The Create Section dialog box appears Appendix B Abaqus CAE A BASIC TUTORIAL 2 3 In the Create Section dialog box Name the section BeamSection In the Category list accept Solid as the default category selection In the Type list accept Homogeneous as the default type selection aa r Click Continue The Edit Section dialog box appears In the dialog box a Accept the default selection of Steel for the Material associated with the section b Accept the default value of 1 for the
18. g box Abaqus CAE will use the structured meshing technique to create a mesh of hexahedral shaped elements Assigning an Abaqus element type In this section you will use the Element Type dialog box to assign a particular Abaqus element type to the model Although you will assign the element type now you could also wait until after the mesh has been created To assign an Abaqus element type 1 From the main menu bar select Mesh Element Type The Element Type dialog box appears 2 Inthe dialog box accept the following default selections that control the elements that are available for selection e Standard is the default Element Library selection e Linear is the default Geometric Order e 3D Stress is the default Family of elements 3 In the lower portion of the dialog box examine the element shape options A brief description of the default element selection is available at the bottom of each tabbed page Appendix B Abaqus CAE A BASIC TUTORIAL Since the model is a _ three dimensional solid only three dimensional solid element types hexahedral on the Hex tabbed page triangular prism on the Wedge page and tetrahedral on the Tet page are shown 4 Click the Hex tab and choose Incompatible modes from the list of Element Controls A description of the element type C3D8I appears at the bottom of the dialog box Abaqus CAE will now associate C3D8I elements with the elements in the mesh 5 Click OK to assign the element
19. he Edit Boundary Condition dialog box appears 5 In the dialog box a Toggle on ENCASTRE b Click OK to create the boundary condition and to close the dialog box Abaqus CAE displays arrows at each corner and midpoint on the selected face to indicate the constrained degrees of freedom Single headed arrows represent a constraint that is applied to a translational degree of freedom Double headed arrows represent a constraint that is applied to a rotational degree of freedom An ENCASTRE boundary condition constrains all six degrees of freedom however in this model Abaqus CAE ignores the rotational constraints indicated by the double headed arrows 6 In the Model Tree click mouse button 3 on the BCs container and select Manager from the menu that appears Abaqus CAE displays the Boundary Condition Manager The manager indicates that the boundary condition is Created activated in the initial step and is Propagated continues to be active in the general analysis step BeamLoad 7 Click Dismiss to close the Boundary Condition Manager Applying a load to the top of the cantilever beam Now that you have fixed one end of the cantilever beam you can apply a distributed load to the top face of the beam The load is applied during the general static step you created earlier To apply a load to the top of the cantilever beam 1 In the Model Tree double click the Loads container The Create Load dialog box appears 2 In the Create
20. he modeling process for example defining the geometry defining material properties and generating a mesh As you move from module to module you build the model from which Abaqus CAE generates an input file that you submit to Abaqus Standard or Abaqus Explicit for analysis For example you use the Property module to define material and section properties and the Step module to choose an analysis procedure The Abaqus CAE postprocessor is called the Visualization module and is also licensed as a separate product called Abaqus Viewer You enter a module by selecting it from the Module list in the context bar as shown in Figure B 2 Wis Ak Module Part Figure B 2 Selecting a module For the cantilever beam tutorial you will enter the following Abaqus CAE modules and perform the following tasks Part Sketch a two dimensional profile and create a part representing the cantilever beam Property Define the material properties and other section properties of the beam Assembly Assemble the model and create sets Appendix B Abaqus CAE A BASIC TUTORIAL Step Configure the analysis procedure and output requests Load Apply loads and boundary conditions to the beam Mesh Mesh the beam Job Create a job and submit it for analysis Visualization View the results of the analysis Although the Module list in the context bar lists the modules in a logical sequence you can move back and forth between modules at w
21. he procedure 3 You will fix the face at the left end of the cantilever beam the desired face is shown in Figure B 9 2 3 1 Highlighting Beam 1 Face 3 Figure B 9 Selecting the region on which to apply a boundary condition By default when you position the cursor over a region that overlaps more than one face Abaqus CAE highlights the face that is closest to the screen To select the face at the left end of the cantilever beam without changing your view of the beam you need to turn off this default behavior and cycle through the valid selections Do the following O a From the prompt area click the selection options tool Bone b From the Options dialog box that appears toggle off the closest object tool a c Position the cursor over the desired face When you stop moving the cursor Abaqus CAE highlights all faces that overlap at the cursor position Ellipsis marks appear to the right of the cursor arrow to indicate that the current selection is ambiguous d Click mouse button 1 to accept the highlighted faces Abaqus CAE displays Next Previous and OK buttons in the prompt area e Click Next and Previous until the desired face is highlighted f Click OK to confirm your choice Appendix B Abaqus CAE A BASIC TUTORIAL 4 Click mouse button 2 in the viewport or click Done in the prompt area to indicate that you have finished selecting The selection options return to their default behavior T
22. ill However certain obvious restrictions apply for example you cannot assign section properties to geometry that has not yet been created A completed model contains everything that Abaqus CAE needs to generate an input file and start the analysis Abaqus CAE uses a model database to store your models When you start Abaqus CAE the Start Session dialog box allows you to create a new empty model database in memory After you start Abaqus CAE you can save your model database to a disk by selecting File Save from the main menu bar to retrieve it from a disk select File Open For a complete listing of which module generates a particular keyword see Abaqus keyword browser table Section A 1 of the Abaqus CAE User s Manual in the online HTML version of this manual B 2 Understanding the Model Tree The Model Tree provides a visual description of the hierarchy of items in a model Figure B 3 shows a typical Model Tree Items in the Model Tree are represented by small icons for example the Steps icon oba Steps 2 In addition parentheses next to an item indicate that the item is a container and the number in the parentheses indicates the number of items in the container You can click on the and signs in the Model Tree to expand and collapse a container The right and left arrow keys perform the same operation The arrangement of the containers and items in the Model Tree reflects the order in which you are ex
23. many parts it contains only one assembly You define the Appendix B Abaqus CAE A BASIC TUTORIAL geometry of the assembly by creating instances of a part and then positioning the instances relative to each other in a global coordinate system An instance may be independent or dependent Independent part instances are meshed individually while the mesh of a dependent part instance is associated the mesh of the original part This issue is discussed further in Working with part instances Section 13 3 of the Abaqus CAE User s Manual For the cantilever beam tutorial you will create a single instance of your cantilever beam Abaqus CAE positions the instance so that the origin of the sketch that defined the rectangular profile of the beam overlays the origin of the assembly s default coordinate system To assemble the model 1 In the Model Tree expand the Assembly container Then double click Instances in the list that appears Abaqus CAE switches to the Assembly module and the Create Instance dialog box appears In the dialog box select Beam and click OK Abaqus CAE creates an instance of the cantilever beam and displays it using an isometric orientation In this example the single instance of the beam defines the assembly A second triad in the viewport indicates the origin and orientation of the global coordinate system In the View Manipulation toolbar click the rotate view manipulation tool When you move
24. n and a load to the model Prescribed conditions such as loads and boundary conditions are step dependent which means that you must specify the step or steps in which they become active Now that you have defined the steps in the analysis you can define the following prescribed conditions e A boundary condition that constrains one end of the cantilever beam in the X Y and Z directions the boundary condition is applied during the initial step e A load that you apply to the top face of the beam the load is applied during the general analysis step Applying a boundary condition to one end of the cantilever beam Create a boundary condition that constrains the cantilever beam to be built in at one end of the beam To apply boundary conditions to one end of the cantilever beam 1 In the Model Tree double click the BCs container Abaqus CAE switches to the Load module and the Create Boundary Condition dialog box appears 2 In the Create Boundary Condition dialog box a Name the boundary condition Fixed b From the list of steps select Initial as the step in which the boundary condition will be activated c In the Category list accept Mechanical as the default category selection Appendix B Abaqus CAE A BASIC TUTORIAL d In the Types for Selected Step list accept Symmetry Antisymmetry Encastre as the default type selection and click Continue Abaqus CAE displays prompts in the prompt area to guide you through t
25. n the 3D compass to select a predefined view the selected axis is perpendicular to the plane of the viewport e Double click anywhere on the 3D compass to specify a view The 3D compass is discussed further in The 3D compass Section 5 3 of the Abaqus CAE User s Manual B 7 Defining your analysis steps Now that you have created your part you can define your analysis steps For the cantilever beam tutorial the analysis will consist of two steps e An initial step in which you will apply a boundary condition that constrains one end of the cantilever beam e A general static analysis step in which you will apply a pressure load to the top face of the beam Abaqus CAE generates the initial step automatically but you must create the analysis step yourself You may also request output for any steps in the analysis Creating an analysis step Create a general static step that follows the initial step of the analysis To create a general static analysis step 1 In the Model Tree double click the Steps container to create a step Abaqus CAE switches to the Step module The Create Step dialog box appears with a list of all the general procedures and a default step name of Step 1 General procedures are those that can be used to analyze linear or nonlinear response 2 Name the step BeamLoad 3 From the list of available general procedures in the Create Step dialog box select Static General if it is not already sele
26. onfiguring the rest of the model since items such as loads boundary conditions and steps depend on the underlying geometry not the mesh e You can assign the element type either before or after you create the mesh The available element types depend on the geometry of your model e You use seeds to define the approximate position of nodes in your final mesh You select the number of seeds based on the element size or on the number of elements that you want along an edge e You can use the Model Tree to submit jobs and to monitor the status of a job e Inthe Visualization module you read the output database generated by your analysis and view the results You can select the variable to display from the data in the output database and you can also select the increment being displayed e You can display the results in several modes undeformed deformed and contour You can control the appearance of the display in each mode independent of other modes B 24
27. pected to create your model As noted earlier a similar logic governs the order of modules in the module menu you create parts before you create the assembly and you create steps before you create loads This arrangement is fixed you cannot move items in the Model Tree B 3 Appendix B Abaqus CAE A BASIC TUTORIAL ag Models 1 Model 1 fl Parts 2 Fe Materials 1 i Sections 1 ae Profiles as Assembly off Steps 2 B Field Output Requests 1 Fa History Output Requests 1 a Time Points E eb E ba ALE Adaptive Mesh Constraints 4 Interactions Interaction Properties H Contact Controls J Constraints E Connector Sections F Fields iS Amplitudes 4 Loads 1 H Ly BCs 1 fla Predefined Fields Remeshing Rules IL Sketches A Annotations xi Analysis Jobs g Adaptivity Processes Figure B 3 Model Tree The Model Tree provides most of the functionality of the main menu bar and the module managers For example if you double click on the Parts container you can create a new part the equivalent of selecting Part Create from the main menu bar The instructions for the examples that follow will focus on using the Model Tree to access the functionality of Abaqus CAE Menu bar actions will be considered only when necessary e g when creating a finite element mesh or postprocessing results Appendix B Abaqus CAE A BASIC TUTORIAL B 3 Creating a part You
28. tegory title allow you to see at a glance whether all variables in that category will be output A black check mark on a white background indicates that all variables will be output while a dark gray check mark on a light gray background indicates that only some variables will be output Appendix B Abaqus CAE A BASIC TUTORIAL Based on the selections shown at the bottom of the dialog box data will be generated at every default section point in the model and will be written to the output database after every increment during the analysis 5 Click Cancel to close the field output editor since you do not wish to make any changes to the default choice 6 Click Dismiss to close the Field Output Requests Manager Note What is the difference between the Dismiss and Cancel buttons Dismiss buttons appear in dialog boxes that contain data that you cannot modify For example the Field Output Requests Manager allows you to view output requests but you must use the field output editor to modify those requests Clicking the Dismiss button simply closes the Field Output Requests Manager Conversely Cancel buttons appear in dialog boxes that allow you to make changes Clicking Cancel closes the dialog box without saving your changes 7 Review the history output requests in a similar manner by clicking mouse button 3 on the History Output Requests container in the Model Tree and then opening the history output editor B 8 Applying a boundary conditio
29. the mouse back into the viewport a circle appears Drag the mouse in the viewport to rotate the model and examine it from all sides You can also pick a center of rotation by clicking Select in the prompt area your selected center of rotation is retained for the current object and viewport Click Use Default to return to the default center of viewport rotation method Click mouse button 2 to exit rotate mode lt L Several other tools pan p magnify S zoom and auto fit eal are also available in the View Manipulation toolbar to help you examine your model Experiment with each of these a tools until you are comfortable with them Use the context sensitive help system R to obtain any additional information you require about these tools Direct view manipulation is available using the 3D compass The compass allows you to pan or rotate your model by clicking and dragging on it For example e Click and drag one of the straight axes of the 3D compass to pan along an axis e Click and drag any of the quarter circular faces on the 3D compass to pan along a plane e Click and drag one of the three arcs along the perimeter of the 3D compass to rotate the model about the axis that is perpendicular to the plane containing the arc e Click and drag the free rotation handle on the 3D compass to rotate the model freely about its pivot point Appendix B Abaqus CAE A BASIC TUTORIAL e Click the label for any of the axes o
30. type and to close the dialog box Creating the mesh Basic meshing is a two stage operation first you seed the edges of the part instance and then you mesh the part instance You select the number of seeds based on the desired element size or on the number of elements that you want along an edge and Abaqus CAE places the nodes of the mesh at the seeds whenever possible For the cantilever beam tutorial the default seeding will generate a mesh with square hexahedral elements To mesh the model 1 From the main menu bar select Seed Part to seed the part instance The Global Seeds dialog box appears The dialog box displays the default element size that Abaqus CAE will use to seed the part instance This default element size is based on the size of the part instance 2 In the dialog box enter an approximate global size of 10 0 and click OK Abaqus CAE applies the seeds to the part instance as shown in Figure B 11 You can gain more control of the resulting mesh by seeding each edge of the part instance individually oe ee Figure B 11 Seeding the mesh Appendix B Abaqus CAE A BASIC TUTORIAL 3 From the main menu bar select Mesh Part to mesh the part instance 4 From the buttons in the prompt area click Yes to confirm that you want to mesh the part instance Abaqus CAE meshes the part instance and displays the resulting mesh as
31. u bar For many tools as you select an item from the main menu bar or the Model Tree the corresponding tool is highlighted in the module toolbox so you can learn its location 3 In the Model Tree double click the Parts container to create a new part The Create Part dialog box appears Abaqus CAE also displays text in the prompt area near the bottom of the window to guide you through the procedure You use the Create Part dialog box to name the part to choose its modeling space type and base feature and to set the approximate size You can edit and rename a part after you create it you can also change its modeling space and type but not its base feature B 5 Appendix B Abaqus CAE A BASIC TUTORIAL 4 Name the part Beam Accept the default settings of a three dimensional deformable body and a solid extruded base feature In the Approximate size text field type 300 5 Click Continue to exit the Create Part dialog box Abaqus CAE automatically enters the Sketcher The Sketcher toolbox appears in the left side of the main window and the Sketcher grid appears in the viewport The Sketcher contains a set of basic tools that allow you to sketch the two dimensional profile of your part Abaqus CAE enters the Sketcher whenever you create or edit a part To finish using a Sketcher tool click mouse button 2 in the viewport or select a new tool Tip Like all tools in Abaqus CAE if you simply position the cursor over a tool in the Sketch
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