如何abaqus中recreatt datum csys
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ABAQUS内部资料-workshop-几何模型建立
Workshop 1 Importing and Editing an Orphan Mesh: Pump Model这个实例中要用到的 cad 模型文件和脚本文件都可以在 abaqus 的 sample 文件夹(或者那个*.zip 文件)里找到。 这个实例涉及到了用 abaqus 进行分析的整个流程中的各个细节,是入门的好帮手。像我这 样的新手一定会喜欢的:) 部件
:泵体+垫片+底盖+螺栓 荷载条件:螺栓预紧+内压IntroductionThe structural response of the pump assembly shown in Figure W3C1 will be determined. The assembly components include the pump housing (imported as an orphan mesh), a gasket, a cover, and eight bolts (all imported as CAD geometry). The analysis involves application of pre-tensioning loads in the bolts followed by internal pressure.pump housingboltsgasketcoverFigure W3C1. Pump assembly In this workshop, you will create the parts of the model. Use the Part module of ABAQUS/CAE to import the mesh of a pump housing. Some modifications of its geometric features follow. The other components of the pump assembly (cover, gasket, and bolts) will be imported as CAD geometry. All of the parts will be halved to take advantage of symmetry.Copyright 2003 ABAQUS, Inc 科研中国
收集 W3.2Note: The parts created in this workshop will be used in subsequent workshops to build the complete model and to perform the analysis. It is important that you use the dimensions stated and not deviate from the w otherwise, you may find it difficult to complete the subsequent workshops.Orphan mesh importFollow the steps below to import the mesh of the pump housing model. 1. Start a new session of ABAQUS/CAE from workshops/pump directory. ABAQUS/CAE automatically loads the Part module. 2. From the main menu bar, select File Import Model. From the list of available models, select pump_ribs.inp. 3. ABAQUS/CAE takes a few seconds to import the model. Once the model is imported, you will be in the Assembly module. Switch back to the Part module. Notice that a new model (named pump_ribs) which contains the imported part (named PUMPC1) has been created. The model appears as shown in Figure W3C 2.Figure W3C2. Orphan mesh of pump housingEditing nodal coordinatesYour first task will be to change the inner diameter of the hole that goes through the top of the pump. The coordinates of the nodes along the inner diameter need to be changed. Since these nodes lie on a circular surface, it will be advantageous to define a cylindrical coordinate system and simply change the radial coordinate of the nodes. Follow the steps below to achieve this task. 1. From the main menu bar, select View Views Toolbox. In the Views dialog box, select the 1C2 view. Turn off the perspective view by clicking the Turn ), and zoom into the component so that the hole is Perspective Off tool ( clearly visible (see Figure W3C3).Copyright 2003 ABAQUS, Inc. W3.3Figure W3C3. Top view of pump housing 2. From the main menu bar, select Tools Datum. The Create Datum dialog box appears (see Figure W3C4). Select CSYS as the datum type. Select the 3 points method, and click OK. When prompted for the type of coordinate system, choose Cylindrical. Place the coordinate system at the origin (0.0, 0.0, 0.0) and click Create Datum. A cylindrical datum coordinate system is created. The origin of the coordinate system coincides with the position of the center of the hole.Figure W3C4. Create Datum dialog box 3. You will now modify the inner diameter of the hole. From the main menu bar, select Tools Edit Mesh. In the Edit Mesh dialog box, select Node as the category and Edit as the method, as shown in Figure W3C5. Click OK to close the dialog box and proceed.Copyright 2003 ABAQUS, Inc. W3.4Figure W3C5. Edit Mesh dialog box 4. You will be prompted to select the nodes to be modified. Begin by setting the selection filters as shown in Figure W3C6 by clicking the Show/Hide Selection Options tool, in the prompt area.Toggle off the selection of entities closest to the screen Circular drag shape Select entities inside the drag shapeFigure W3C6. Selection filters 5. The nodes can be selected in one of two ways: ? Try selecting the nodes individually (the default selection technique) using a Circular Drag Shape. The center of the drag shape should be the center of the cylindrical coordinate system defined earlier (see step 2). Select a perimeter point for the drag shape such that you include all the nodes on the inside surface of the hole. The selected nodes will be highlighted in red after the selection, as shown in Figure W3C7. You may wish to rotate your model to check whether all the nodes have been selected properly. ? You may also select the nodes using the face angle method (i.e., by specifying the maximum deviation in the angle between adjacent element faces). This technique is generally more efficient than selecting the nodes individually: all nodes that pertain to the element faces that satisfy the face angle criterion are automatically selected. In the prompt area, choose by face angle as the method by which the nodes will be selected. Then, click on any element face located on the inner surface of the hole. The nodes on the inner surface areCopyright 2003 ABAQUS, Inc. W3.5highlighted in red after the selection. As before, rotate your model to make sure all the nodes have been selected properly. Once you are satisfied with the selection (using either method), click Done in the prompt area.Figure W3C7. Modified nodes 6. The Edit Nodes dialog box appears, as shown in Figure W3C8. This dialog box will be used to change the diameter of the hole. Click Select in the upper right corner of the dialog box, and choose the cylindrical coordinate system defined in step 2 by clicking on it in the viewport when prompted to choose a local coordinate system. 7. Using the Coordinates specification method, change the 1Ccoordinate (i.e., the radial coordinate) by selecting Specify from the pull down list and entering 0.65. Click OK to close the dialog box and then Done in the prompt area to complete the operation.Figure W3C8. Edit Nodes dialog boxDeleting elementsYou will now remove the ribs on the pump housing and then you will remove half of the part. Begin by removing some of the elements in the rib located near the front of the housing, as shown in Figure W3C9. Use the 1C3 view from the Views Toolbox, and rotate the pump to view one of the front ribs, as shown in Figure W3C9.Copyright 2003 ABAQUS, Inc. W3.61. 2.3. 4.5.Figure W3C9. Rib elements From the main menu bar, select Tools Edit Mesh. In the Edit Mesh dialog box, select Element as the category and Delete as the method. Click OK. When prompted to select the elements to be deleted, use the Show/Hide Selection Options tool to change the drag shape to a Polygon. Select some of the elements located near the 90° bend of the rib, as shown in Figure W3C9. In the prompt area, toggle on Delete associated unreferenced nodes. Zoom out and rotate the view to confirm that only elements pertaining to the ribs have been selected. If any other elements are highlighted, deselect them using [Control]+Click. When you are satisfied with the selection, click Done to delete the elements and their associated nodes. The remaining ribs on the pump housing can be removed by carefully selecting them in a similar fashion. This can be a tedious and time-consuming process for large, complicated models. To facilitate such tasks, elements may also be deleted using sets. A. From the main menu bar, select Tools Edit Mesh. In the Edit Mesh dialog box, click OK to continue deleting elements. B. In the prompt area toggle on Delete associated unreferenced nodes. C. In the prompt area, click Sets to open the Region Selection dialog box. In this dialog box, select the set RIBS and toggle on Highlight selections in viewport to highlight the elements belonging to this set. D. Click Continue to delete the remaining rib elements. E. Click Cancel to close the dialog box. You will now halve the pump housing. Use the 1C2 view from the Views Toolbox to facilitate element selection.6. From the main menu bar, select Tools Edit Mesh. In the Edit Mesh dialog box, click OK to continue deleting elements. 7. In the prompt area, toggle on Delete associated unreferenced nodes.Copyright 2003 ABAQUS, Inc. W3.7Tip: If the Region Selection dialog box appears, click Select in Viewport on the right side of the prompt area so you can select elements in the viewport. 8. Select the upper half of the pump housing for deletion, as shown in W3C10. When you are satisfied with the selection, click Done to delete the elements and their associated nodes. The half pump housing without the ribs is shown in Figure W3C11. 9. Save the model database. Name the model database file PumpAssy.cae.Copyright 2003 ABAQUS, Inc. W3.8selected elementsrectangular drag shapeFigure W3C10. Select half of the pump housing.Figure W3C11. Halved pump housing without ribsImporting CAD geometryYou will now import the remaining components of the assembly into ABAQUS/CAE. 1. From the main menu bar, select File Import Part to open the Import Part dialog box. 2. In this dialog box, set the file type to ACIS SAT. From the list of available files, select cover.sat. Click OK in the dialog box to proceed. 3. In the Create Part from Acis File dialog box, select the Name-Repair tab and toggle on all the available repair options. Click OK to close the dialog box and continue. The imported part is shown in Figure W3C12a. 4. After the part is imported, use the Geometry diagnostics part query tools (Tools Query) to check for any invalid or imprecise entities. 5. Repeat steps 2 through 4 to import the part defined in file gasket.sat. The imported part is shown in Figure W3C12b. 6. Import the part defined in file n_bolts.sat without any repair options turned on. The imported part is shown in Figure W3C12c. 7. Review the different parts of your model. Query the important dimensions using the Query tools and note them for future reference.Copyright 2003 ABAQUS, Inc. W3.98. Save your model database as PumpAssy.cae.(a) cover(b) gasket(c) boltsFigure W3C12. Components of pump assemblyHalving the imported geometryYou will now remove half of each of the imported parts. Begin with the cover. 1. From the Part list located under the tool bar, select cover to access the cover geometry. 2. From the main menu bar, select View Specify. Using the Viewpoint method, enter the coordinates of the viewpoint as 0,0,-1 and the coordinates of the up vector as 0,-1,0. Click OK to apply the view and close the dialog box. Next, create a datum axis using the steps outlined below. This axis will be used to orient the part in the sketch plane when creating the cut profile. From the main menu bar, select Tools Datum. In the Create Datum dialog box, choose Axis as the type and Principal axis as the method. Click OK. Choose the principal Y-Axis as the datum axis. From the main menu bar, select Shape Cut Extrude. Select the top surface of the cover, indicated in Figure W3C13, as the plane on which to sketch.3. 4. 5. 6. 7.Copyright 2003 ABAQUS, Inc. W3.10sketch planedatum axisFigure W3C13. Sketch plane and datum axis 8. Select the datum axis as the edge that will appear vertical and on the right of the sketch. 9. From the main menu bar, select Add Line Rectangle. Sketch a rectangle enclosing the upper half of the cover, as shown in Figure W3C14.cut rectangleFigure W3C14. Cut profile 10. Click mouse button 2 to continue, and click Done in the prompt area. 11. In the Edit Cut Extrusion dialog box, choose the end condition Through All. The direction of extrusion is into the cover. Click OK. The final cover geometry is shown in Figure W3C15.Figure W3C15. CoverCopyright 2003 ABAQUS, Inc. W3.11Similarly, halve the gasket and bolt parts. 12. From the Part list located under the tool bar, select gasket to access the gasket geometry. Use the 1C2 view from the Views Toolbox. 13. As before, define the datum axis to orient the part. From the main menu bar, select Tools Datum. 14. In the Create Datum dialog box, click OK to create another Axis using the Principal axis method. Choose the principal Y-Axis as the datum axis. 15. From the main menu bar, select Shape Cut Extrude. 16. Select the top surface of the gasket as the plane on which to sketch, as shown in Figure W3C16. Select the datum axis as the edge that will appear vertical and on the right of the sketch. 17. From the main menu bar, select Add Line Rectangle. Sketch a rectangle enclosing the upper half of the gasket, as shown in Figure W3C16. surfaces selected as sketch planes(a) gasketcut rectangle Figure W3C16. Cut profiles(b) bolts18. Click mouse button 2 to continue, and click Done in the prompt area. 19. In the Edit Cut Extrusion dialog box, choose the end condition Through All. The direction of extrusion is into the gasket. Click OK. 20. Repeat steps 12 through 19 to remove four of the bolts from the part named n_bolts. Note that the top surface of any of the bolts to the left of the datum axis may be used as the sketch plane for the extruded cut. The final gasket and bolt parts are shown in Figure W3C17. 21. Save the model database as PumpAssy.cae.Copyright 2003 ABAQUS, Inc. W3.12(a) gasket(b) boltsFigure W3C17. Gasket and boltsCopyright 2003 ABAQUS, Inc. Workshop 2 Material and Section Properties: Pump ModelIntroductionIn this workshop you will use the ABAQUS/CAE Property module to define the material and section properties of the components in the pump assembly. The gasket will be defined using gasket material properties. All other components (pump housing, cover, and bolts) are assumed to possess the properties of steel.Defining a linear elastic material and solid section propertiesFollow the steps outlined below to complete the steel property and section assignments for the pump components. Note that the units used in this model are in, lb, and psi. 1. Start a new session of ABAQUS/CAE from the directory containing the pump assembly model. 2. From the main menu bar, select File Open to open the model database file PumpAssy.cae. 3. Switch to the Property module. 4. From the Model list located under the toolbar, select pump_ribs to access the pump_ribs model. 5. From the main menu bar, select Material Create to create a linear elastic material named Steel. Specify a Young’s modulus of 30.E6 psi and a Poisson’s ratio of 0.3. 6. From the main menu bar, select Section Create to create a homogeneous solid section named steelSection that refers to the material named Steel. 7. From the main menu bar, select Assign Section to assign the section named steelSection to the parts named cover, n_bolts, and PUMP-1. Tip: You will need to make the section assi select the different parts by choosing them from the Part pull-down list.Defining the gasket material and section propertiesThe typical specification of gasket material properties in ABAQUS involves a tabular representation of the pressure versus closure relationship in the thickness direction of the gasket. The pressure versus closure models available in ABAQUS allow the modeling of very complex gasket behaviors, including nonlinear elasticity, permanent plastic deformation, and loading/unloading along different paths. These behaviors are usually calibrated from test data. A detailed discussion of gasket material behavior, however, is beyond the scope of this course. For your convenience (and to make the analysis realistic) the gasket properties are defined in a script that you will read directly into ABAQUS/CAE. 1. From the main menu bar, select File Run Script.Copyright 2003 ABAQUS, Inc. 科研中国
收集 W5.22. 3.4. 5.6.The Run Script dialog box appears. Select the file named gasket_material.py. Click OK in the dialog box. From the main menu bar, select Material Manager to open the Material Manager. Notice that the material named Gasket has been added to the model database. Select Gasket, and click Edit. Review the gasket material properties. Note the gasket has membrane elasticity of 12155 psi, shear stiffness of 6435 psi, and a coefficient of thermal expansion of 1.67 E?5 /°F. Select Gasket Thickness Behavior from the list of available Material Options in the dialog box, and notice the tabular specification of the loading and unloading curves for the gasket (see Figure W5C1).Figure W5C1. Edit Material dialog box You can use the plotting capabilities within ABAQUS/CAE to plot the loading and unloading curves. This may help you obtain a better understanding of the material behavior. 7. Open the Loading tabbed page. Right-click your mouse over the column headings of the table, and select Create XY Data from the list of options that appears. Name the curve loading when prompted for a name in the Create XYCopyright 2003 ABAQUS, Inc. W5.3Data dialog box. Repeat the same operation for the unloading curve to create a curve named unloading. 8. Switch to the Visualization module. 9. From the main menu bar, select Tools XY Data Manager. The XY Data Manager appears. 10. Select both the curves (using the shift key), and click Plot. You should see a similar plot in the viewport as that shown in Figure W5C2.Figure W5C2. Loading and unloading gasket behavior 11. Click Dismiss in the XY Data Manager, and switch back to the Property module to continue with the gasket section property specification. 12. From the main menu bar, select Section Create to create a gasket section. 13. In the Create Section dialog box, select Other as the category and Gasket as the type. Name the section gasketSection (see Figure W5C3) and click Continue.Copyright 2003 ABAQUS, Inc. W5.4Figure W5C3. Create Section and Edit Section dialog boxes 14. In the Edit Section dialog box (see Figure W5C3), select Gasket as the material and accept all other defaults. 15. Assign the section named gasketSection to the part named gasket. 16. Save your model database as PumpAssy.cae.Copyright 2003 ABAQUS, Inc. Workshop 3 Pump Model AssemblyIntroductionIn this workshop you will create a single part instance of each component of the pump model and use the different positioning techniques available in ABAQUS/CAE to position the part instances relative to each other in a global coordinate system.Instancing and positioning the pump housing1. From the main menu bar, select File Open and open the model database file PumpAssy.cae. 2. Switch to the Assembly module, and select pump_ribs from the list of available models. Note that since you imported the pump housing as a model, an instance of the part PUMP-1 has already been created. No further positioning of this part instance is required.Instancing and positioning the gasket1. From the main menu bar, select Instance Create to create an instance of the part named gasket. You must position the gasket such that its top surface touches the bottom surface of the pump housing. The most convenient way to do this is to use the Face to Face positioning constraint. 2. From the main menu bar, select Constraint Face to Face. Select any element face on the bottom of the pump housing as the face on the movable part instance. To facilitate the selection of a planar face on the fixed part instance (i.e., the gasket), you will suppress the visibility of the pump housing. 3. From the main menu bar, select View Assembly Display Options and suppress the visibility of instance PUMP-1 in the Instance tabbed page. 4. Select the top face of the gasket as the face on the fixed part instance. You should now see two arrows pointing in opposite directions in the viewport, as shown in Figure W6C1. (You may need to select View Auto-Fit from the main menu bar to see this.)Copyright 2003 ABAQUS, Inc. 科研中国收集 W6.2gasketpump housingFigure W6C1. Housing and gasket arrows initially point in opposite directions The pump housing will be moved so that its arrow points in the same direction as that of the gasket. 5. Click Flip in the prompt area to reverse the direction of the arrow on the pump housing so that both arrows point in the same direction. When both arrows point in the same direction, click OK in the prompt area. 6. Accept 0.0 as the default distance from the fixed plane along its normal. 7. Use the assembly display options to restore the visibility of the pump housing. 8. Verify that the pump housing is now exactly on top of the gasket. Tip: Use the Query tools to calculate the distance between a point on the lower surface of the pump housing and a point on the top surface of the gasket. If the pump is exactly on top of the gasket, the third component of the distance vector should be zero.Instancing and positioning the cover1. Instance the part named cover. The cover must be rotated such that the rounded side of the cover is inside the pump. This requires rotating the cover about the global 1-axis. 2. From the main menu bar, select Instance Rotate. Select the cover when prompted for the instance to be rotated. Tip: Click Instance List in the prompt area to select the cover from a feature list. This is often easier than selecting instances from the viewport. 3. Enter the coordinates of the origin (0.0, 0.0, 0.0) as the start point for the axis of rotation. 4. Enter (1.0, 0.0, 0.0) as the coordinates of the end point for the axis of rotation. 5. Enter 180.0 as the angle of rotation. See Figure W6C2 for the configuration after the rotation operation (note the visibility of the pump housing has been suppressed in this figure).Copyright 2003 ABAQUS, Inc. W6.3Figure W6C2. Gasket and cover 6. The cover also needs to be positioned so that its top touches the bottom of the gasket. Use the Contact constraint to position the top of the cover with respect to the bottom of the gasket. Alternatively, you could also use the Face to Face constraint. 7. From the main menu bar, select Constraint Contact. 8. Select the top face of the cover (shown in Figure W6C3) when prompted for the face of the movable part instance.face of fixed part instance (gasket)face of movable part instance (cover)Figure W6C3. Positioning of cover relative to the gasket 9. Select the bottom face of the gasket (shown in Figure W6C3) when prompted for the face of the fixed part instance. 10. Pick a point on the top surface of the cover as a start point for the direction of contact, as shown in Figure W6C4Copyright 2003 ABAQUS, Inc. W6.4end pointstart pointFigure W6C4. Contact positioning constraint 11. Select a point on the bottom surface of the gasket as the end point for the direction of contact, as shown in Figure W6C4. 12. When prompted for a clearance between the surfaces, enter a value of 0.0. 13. Verify that the gasket is now just in contact with the cover.Instancing and positioning the bolts1. Instance the part n_bolts. 2. The bolts will be in position when their ends are aligned with the bottom of the cover. Use the Face to Face constraint to accomplish this task. The pump assembly with the bolts in their final positions should look similar to that shown in FigureW6C5.Figure W6C5. Final positions of the boltsCopyright 2003 ABAQUS, Inc. W6.5The complete assembly is shown in Figure W6C6.Figure W6C6. Complete pump assembly 3. Save your model as PumpAssy.cae.Copyright 2003 ABAQUS, Inc. Workshop 9 Free and Swept Meshing: Pump ModelIntroductionIn this workshop you will use the Mesh module of ABAQUS/CAE to generate the finite element meshes for the pump assembly model. The required tasks include assigning mesh attributes to each part instance, assigning mesh seeds, and generating the meshes.Modifying the pump housing element type1. Open the model database file PumpAssy.cae. Switch to the M and, from the context bar, select pump_ribs from the list of available models. 2. Use the assembly display options (View Assembly Display Options) to suppress the visibility of all part instances save for the pump housing. In addition, suppress the visibility of all datum planes and axes. 3. Next, create a set that includes all the elements comprising the pump housing. From the main menu bar, select Tools Set Create. 4. In the Create Set dialog box, select Element as the set type. Name the set pump-mesh and click Continue. 5. Select all the elements in pump housing using a rectangular drag window. Use the selection filters if necessary. Click Done when the selection is complete. Use the Query tools to determine the type of element currently assigned to the mesh. 6. From the main menu bar, select Tools Query. The Query dialog box appears. 7. From the list of available General Queries, select Element and click Apply. Click on any element and note that the element’s label, type, and nodal connectivity are listed in the message area, as shown in Figure W9C1. Repeat this for other elements in the mesh.Figure W9C1. Selected element attributes 8. Click Cancel in the Query dialog box to close it. 9. The element type for the pump housing is the linear tetrahedron (C3D4), which is not suited for an analysis involving contact. Thus, change the element type assigned to the pump housing to modified second order tetrahedrons (C3D10M). 10. From the main menu bar, select Mesh Element Type. 11. When prompted for the type of region, click Sets on the right side of the prompt area.Copyright 2003 ABAQUS, Inc. 科研中国收集 W9.212. The Region Selection dialog box appears. Select the set pump-mesh and click Continue. 13. The Element Type dialog box appears. Review the current settings. Toggle on Quadratic under Geometric Order. Notice that the element type message changes to C3D10M. Click OK. 14. Use the Query tools to confirm that the element type associated with the mesh has been updated.Generating the bolt meshUse the assembly display options to restore the visibility of the bolts and suppress the visibility of the pump housing. The bolts are colored yellow, indicating they can be readily meshed with hexahedral elements using a swept mesh technique. Mesh the bolts with a local edge seed of 8 using first-order incompatible mode hexahedral elements (C3D8I). 1. From the main menu bar, select Seed Edge by Number. 2. Select all the edges of the bolts using a rectangular drag window. 3. When prompted for the number of elements along the edges, enter 8. 4. From the main menu bar, select Mesh Element Type to change the element type associated with the bolts. Tip: Click Select in Viewport on the right side of the prompt area to select the bolts directly in the viewport. 5. In the prompt area, select Geometry as the region type. Using a rectangular drag shape, select all the bolts. 6. In the Element Type dialog box, choose Incompatible modes under Element Controls. Click OK. 7. From the main menu bar, select Mesh Instance to mesh the bolts. Click one of the bolts when prompted for the instance to be meshed. 8. Review the mesh when the operation is complete. The mesh of one of the bolts is shown in Figure W9C2.Generating the cover and gasket meshesThe Cover Use the assembly display options to restore the visibility of the cover and suppress the visibility of the bolts. The cover is colored orange, indicating that it cannot be meshed with hexahedral elements without the aid of partitioning. For the purpose of this exercise, mesh the cover using the free tetrahedral mesh technique. Use a global seed size of 0.35 and element type C3D10M. 1. From the main menu bar, select Mesh Controls. Select the cover as the region to which mesh contr and, in the Mesh Controls dialog box, select Tet as the element shape. Click OK to continue.Copyright 2003 ABAQUS, Inc. W9.3The part is now colored pink, indicating it can be meshed with the free mesh technique. 2. Assign a global mesh seed size (Seed Instance) of 0.35 and local edge seeds (Seed Edge By Number) of 8 to the edges comprising the bolt holes. 3. From the main menu bar, select Mesh Element type. Select the cover geometry as the region to which the element type will be assigned and choose the modified quadratic tetrahedron element type (C3D10M). 4. Generate the cover mesh. The mesh on the cover plate is shown in Figure W9C2. The Gasket Use the assembly display options to restore the visibility of the gasket and suppress the visibility of the cover. The gasket is colored yellow, indicating it can be readily meshed with hexahedral elements using a swept mesh technique. 1. Assign a global mesh seed size (Seed Instance) of 0.25. 2. Assign the linear hexahedral gasket element type (GK3D8) to the gasket geometry (Mesh Element type). 3. Generate the gasket mesh. The mesh on the gasket is shown in Figure W9C3.Figure W9C2. Bolt and cover meshesFigure W9C3 Gasket mesh 4. Save the model database as PumpAssy.cae, and exit the ABAQUS/CAE session.Copyright 2003 ABAQUS, Inc. Workshop 13 Nonlinear Static Analysis of a Pump AssemblyIntroductionIn this workshop you will use ABAQUS/CAE to complete the pump assembly model and to submit it for analysis. You will begin by defining the analysis steps and the output requests associated with these steps. Next, you will define the interactions between the different components of the model. You will also apply bolt and pressure loads and boundary conditions to the model. Finally, you will create and submit a job for analysis and evaluate the analysis results.Defining the analysis stepsThe analysis history of the pump assembly consists of two steps: a step that simulates the pre-tensioning in the bolts, followed by a step that simulates the pressurization of the bolted assembly. 1. Open the model database file PumpAssy.cae. Switch to the Step module, and in the context bar select pump_ribs from the list of available models. 2. Create a general static step named PreloadBolts. Activate geometric nonlinearity (toggle on Nlgeom), and specify an initial time increment of 0.05 and a total time period of 1.0. 3. Create a second general static step named Pressure. Insert this step after the step named PreloadBolts. Specify an initial time increment of 0.1 and a total time period of 1.0. 4. Activate the contact diagnostic printout for both the steps. From the main menu bar, select Output Diagnostic Print. In the Diagnostic Print dialog box, click in the blank area under the Contact column for both steps so that tick marks appear, thus activating contact diagnostic output for these steps. 5. Click OK to close the dialog box.Defining contact and constraintsThe mere proximity of the model components does not indicate that the part instances will interact during the analysis. Thus, unless explicitly specified, the individual components of an assembly will not interact with one another. For any loads to be properly transmitted between the components, you must define interactions between the components. In structural analysis problems the most common method of transferring loads between unconnected regions of a model assembly is through contact interactions. To define a contact interaction between any two bodies, however, you must first identify the regions of each body that will be involved in contact (e.g., define surfaces). Your next task in this workshop, therefore, will be to define surfaces on each component that will be involved in contact.Copyright 2003 ABAQUS, Inc. 科研中国收集 W13.2Defining the surfaces In ABAQUS/CAE a surface can be created either on a part that has underlying geometry (such a surface is known as a geometry-based surface) or on a part that does not have underlying geometry (e.g., such a surface is known as a mesh-based surface). Since this assembly consists of both imported geometry and an orphan mesh, you will create both types of surfaces. 1. Switch to the Interaction module. 2. Make only the pump housing visible using the Assembly Display Options dialog box (View Assembly Display Options). 3. Create a surface named PumpBot by following the steps given below: A. From the main menu bar, select Tools Surface Manager. B. In the Surface Manager, click Create. C. The Create Surface dialog box appears. Select Mesh as the surface type. Name the surface PumpBot, and click Continue. D. You will be prompted for the regions to define the surface. For a mesh-based surface, you can either select the elements individually or select a group of elements by specifying the maximum deviation in the face angle between adjacent elements. The face angle method is in general a more efficient way of choosing elements to define a surface. Hence, in the prompt area select by angle as the selection method and enter a face angle of 5 degrees. E. Click any element face on the bottom of the pump. All the element faces on the bottom of the pump will then be highlighted in red, as shown in Figure W13C1. Click Done in the prompt area when you are finished.Figure W13C1. Surface PumpBot 4. Similarly, create a surface named PumpBolts that defines a surface in the region of the pump that will come into contact with the heads of the bolts. Select the surface using a face angle of 5 degrees, as shown in Figure W13C2. 5. Next, define a surface in the region where the internal pressure will be applied to the pump. Name the surface PumpInside. Using the face angle method with aCopyright 2003 ABAQUS, Inc. W13.3maximum deviation of 24.1 degrees, select the element faces shown in Figure W13C3. Tip: Use [Shift]+Click to select more than one item at a time. Select as many regions as possible using the
then select any remaining regions individually. Zoom in as necessary to facilitate your selections. To deselect any unintentionally selected regions, use [Ctrl]+Click.Figure W13C2. Surface PumpBoltsFigure W13C3. Surface PumpInside 6. Use the Assembly Display Options dialog box to restore the visibility of the cover and to suppress the visibility of the pump housing. 7. Define a geometry-based surface named CoverTop on the region of the cover where it contacts the gasket. 8. Define a surface named CoverInside that defines the region where the pressure load will be applied as shown in Figure W13C4. 9. Create a surface for each of the four holes in the cover as shown in Figure W13C5. Name these surfaces BoltHole-1 through BoltHole-4.Copyright 2003 ABAQUS, Inc. W13.4Note: Keep track of the order in which you define the bolt hole surfaces since later you will have to create corresponding surfaces on the bolt shanks. You should save your current view (View Save User 1) to make it easier when defining the bolts surfaces later. 10. Restore the visibility of the gasket and suppress the visibility of the cover using the Assembly Display Options dialog box. Define surfaces on the top and bottom regions of the gasket. Name these surfaces GasketTop and GasketBot, respectively. 11. Suppress the visibility of the gasket, and restore the visibility of the bolts. Set the view to the user-defined view (View Views Toolbox and click 1 in the Views dialog box). 12. Create a surface for each bolt thread corresponding to each bolt hole surface in the cover, as shown in Figure W13C5. Name the surfaces BoltThread-1 through BoltThread-4. 13. Create a single surface that includes the regions directly under the heads of all the bolts as shown in Figure W13C5. Name this surface BoltHeads. 14. Save your model database as PumpAssy.cae.surface CoverInsideFigure W13C4. Surface CoverInsidesurface BoltHeads surface BoltThreadsurface BoltHoleFigure W13C5 Bolt-related surfacesDefining the contact interaction Now that you have defined the surfaces that will be involved in contact, you can define the contact interactions between the different components. Defining contact interactions in ABAQUS/CAE involves choosing the surfaces involved contact and defining contactCopyright 2003 ABAQUS, Inc. W13.5properties (friction, etc.) for each interaction. Follow the steps given below to define the contact interactions for this model. 1. From the main menu bar, select Interaction Property Create to create a contact property named Friction. 2. In the Edit Contact Property dialog box, select Mechanical Tangential Behavior. Choose the Penalty friction formulation, and define a coefficient of friction of 0.2. Click OK to close the dialog box. 3. From the main menu bar, select Interaction Create to create an ABAQUS/Standard surface-to-surface contact interaction in the Initial step. Name the interaction Pump-Bolts. 4. Click Surfaces in the prompt area to select the regions involved in contact using the surfaces defined earlier. In the Region Selection dialog box, choose the surface PumpBolts as the master surface (since it is continuous) and the surface BoltHeads as the slave surface (since it has a relatively finer mesh and is discontinuous). Use the Small sliding formulation, adjust slave nodes within 1.e-5 in. of the master surface to ensure that the surfaces are initially in contact, and accept Friction as the contact property. 5. Create another ABAQUS/Standard surface-to-surface contact interaction in the Initial step between the bottom of the gasket and the top of the cover. Name the interaction named Cover-Gasket. Choose the surface CoverTop as the master surface (since the underlying elements are much stiffer) and GasketBot as the slave surface. Use the Small sliding formulation, adjust slave nodes within 1.e-5 in. of the master surface to ensure that the surfaces are initially in contact, and accept Friction as the contact property. Defining tie constraints Tie constraints will be used to tie the gasket to the pump. You will also define tie constraints to simulate the effect of the bolt threads when fastened to the bolt holes. 1. From the main menu bar, select Constraint Create. Name the constraint PumpGasket. Select Tie as the constraint type and click Continue. 2. The list of previously defined surfaces appears in the Region S select the surface PumpBot as the master surface and the surface GasketTop as the slave surface. Accept all the default settings in the Edit Constraint dialog box, and click OK to close the dialog box. 3. In a similar fashion, define tie constraints between each bolt thread and its corresponding bolt hole. In each case, select the bolt hole to be the master surface and the bolt thread to be the slave surface. Name the constraints Tie-1 through Tie-4. In the Edit Constraint dialog box, specify a distance of 0.07 as the position tolerance and toggle off Adjust slave node initial position for each constraint. Tip: After creating the first tie constraint between the bolt and the bolt holes, copy the constraint and edit the region selections.Copyright 2003 ABAQUS, Inc. W13.64. Save your model database as PumpAssy.cae.Defining loads and boundary conditionsYour next task will be to define the loads and boundary conditions that will act on the structure. Applying bolt loads In ABAQUS/CAE assembly or bolt loads are applied across user-defined pre-tension sections in the bolt. When modeling the bolt with solid elements, the pre-tension section is defined as a surface in the bolt shank that effectively partitions the bolt into two regions. Follow the steps given below to create the pre-tension sections in the bolts. 1. Switch to the Load module. 2. Using the Assembly Display Options dialog box, suppress the visibility of all part instances except for the bolts. Define a datum plane for the purpose of partitioning the bolts at the location where the pre-tension sections will be defined. 3. From the main menu bar, select Tools Datum. In the Create Datum dialog box, select Plane as the datum type. 4. Select Offset from plane as the method, and click OK. Offset the datum plane from the bottom of the bolts (select the bottom face of any bolt). Click Enter Value in the prompt area. Flip the arrow indicating the offset direction if necessary so that it points from the bottom of the bolt toward the bolt head. Enter an offset distance of 0.5. 5. Partition the bolts using this datum plane. From the main menu bar, select Tools Partition. Create a Cell partition using the Use datum plane method. Select all the bolts as the cells to be partitioned. Note: The bolt meshes will have to be regenerated as a result of this partition. Switch to the mesh module after creating the partition. Respecify the edge seeds for the bolts with 8 elements along the edges and recreate the bolt meshes. . 6. To view the partitions, switch the rendering style to wireframe 7. To define the direction along which the bolt load will be applied, create a datum axis along the principal Z-axis. From the main menu bar, select Tools Datum. Select Axis as the type and Principal axis as the method. Click Z-axis in the prompt area. 8. From the main menu bar, select Load Create to define the bolt load. The Create Load dialog box appears. Select the step named PreloadBolts as the step in which the load will be applied. Select Bolt load as the load type as shown in Figure W13C6. Click Continue.Copyright 2003 ABAQUS, Inc. W13.7Figure W13C6. Create Load dialog box 9. In the prompt area, click Geometry as the region type. 10. Select the internal surface of any bolt (e.g., as shown in Figure W13C7). This surface defines the pre-tension section.Figure W13C7. Bolt internal surface 11. Select the datum axis defined earlier when prompted for a datum axis parallel to the bolt centerline. 12. Enter a bolt load of 500 lb in the Edit Load dialog box. Accept all other default settings in the dialog box. 13. Repeat steps 8 through 12 for the other bolts. Tip: After creating the first bolt load, copy the load and edit the region selections. 14. Typically, you want to tighten the bolts to a predefined load level (pre-tensioning) and then “freeze” the deformation in the subsequent load steps (pressure loading, heating up, etc). To do this, proceed as follows:Copyright 2003 ABAQUS, Inc. W13.8A. From the main menu, select Load Manager. The load manager appears in the viewport. B. Select any bolt load in the Pressure step by clicking Propagated and click Edit in the dialog box. C. In the Edit Bolt Load dialog box, select Fix at current length as the method and click OK in the dialog box. D. Repeat steps B and C for the other bolt loads. Applying the pressure load and boundary conditions 1. Display the pump housing using the assembly display options. Switch the render style to shaded . 2. From the main menu bar, select Load Create to define a pressure load named PumpLoad in the step named Pressure. Apply the load to surface PumpInside. Specify a load magnitude of 1000 psi. 3. Similarly, apply a pressure of 1000 psi to the surface CoverInside. Name the load CoverLoad. 4. Assume that the bottom of the cover is welded against a rigid plate. From the main menu bar, select BC Create. 5. In the Create Boundary Condition dialog box, select Symmetry/ Antisymmetry/Encastre as the boundary condition type and the Initial step as the step in which to apply the boundary condition and click Continue. 6. In the prompt area, click Select in Viewport to permit direct selection of the affected region in the viewport. Select the bottom region of the cover and click Done in the prompt area. In the Edit Boundary Condition dialog box, select Encastre as the boundary condition type and click OK to close the dialog box. 7. Apply symmetry boundary conditions to the cover and gasket as follows: A. From the main menu bar, select BC Create. B. In the Create Boundary Condition dialog box, accept Symmetry/ Antisymmetry/Encastre as the boundary condition type and the Initial step as the step in which to apply the boundary condition. Click Continue. C. In the prompt area, select Geometry as the region type. Select the faces on the symmetry planes of the cover and gasket using [Shift]+Click and click Done in the prompt area. In the Edit Boundary Condition dialog box, select YSYMM as the boundary condition type and click OK to close the dialog box. 8. Similarly, apply symmetry boundary conditions to the nodes on the symmetry plane of the pump housing. For this part the region type is Mesh. 9. Save your model database.Copyright 2003 ABAQUS, Inc. W13.9Creating and submitting a job for analysisNow you are ready to create and submit the model for analysis. You will use the Job module to create an analysis job and submit it for analysis. 1. Switch to the Job module. 2. Create a job named PumpAnalysis. Enter any suitable job description. Accept all other default job settings. 3. Submit the job for analysis. Note: This analysis job takes about 30 minutes to complete on a Windows 2000 machine with a 1700 MHz processor. Monitor the job for several minutes to ensure it is running properly. Then proceed with the next lecture before continuing with this workshop.Visualizing the analysis resultsAfter the analysis is complete, you will review the results in the Visualization module. For the kind of analysis you just performed, some of the interesting results would be the distribution of the sealing pressure in the gasket at different stages of operation, the history of the bolt force in the bolts, the deformed shape and stresses in the bolts, etc. 1. Switch to the Visualization module, and open the PumpAnalysis output database file. 2. Look at the undeformed and deformed plot of the model. You will notice that the pump housing does not undergo large deformations because of its stiffness. Most of the deformation takes place in the gaskets and the bolts. Use the Create Display Group dialog box to look at the deformed shape in the bolts and gaskets only. 3. Plot the Mises stresses in the model. Use the Create Display Group dialog box to plot the Mises stresses in the bolts only. 4. Plot a contour of the sealing pressure in the gasket. First use the Create Display Group dialog box to view the gasket only. The sealing pressure in the gasket is the S11 component of the stress tensor. From the main menu bar, select Result Field Output. In the Field Output dialog box select the S11 component and click OK. 5. Plot an animation of the sealing pressure in the gasket. Specify a minimum value of 0.0 and a maximum value of 325 in the Limits tabbed page of the Contour Options dialog box. From the main menu bar, select Animate Time History to animate the results. 6. Create a path plot of the sealing pressure along a critical location in the gasket. Follow the steps given below: A. From the main menu bar, select Tools Path Create. The Create Path dialog box appears in the viewport.Copyright 2003 ABAQUS, Inc. W13.10B. The Node list type is selected by default. Click Continue in the dialog box. C. In the Edit Node List Path dialog box, click Add After. D. You will be prompted to select the nodes from the viewport to be inserted into the path. Pick the nodes as shown in Figure W13C8. Click Done in the prompt area when the selection is complete. Click OK in the Edit Node List Path dialog box.end of pathbeginning of pathFigure W13C8. Node path E. From the main menu bar, select Tools XY Data Create. Select Path in the Create XY data dialog box and click Continue. F. Browse the settings in the XY Data from Path dialog box. In the Y-values frame, click Step/Frame. G. In the Step/frame dialog box, select the last frame of the step named Pressure. Click OK. H. Make sure that Field output variable is set to S11 in the XY Data from Path dialog box. Click Plot in the dialog box to view the path plot. I. Save the plot as Step-2. J. Similarly, create a path plot of the sealing pressure for the same set of nodes for the PreloadBolts step. Save the plot as Step-1. K. View the saved plots. From the main menu bar, select Tools XY Data Manager. In the XY Data Manager dialog box, select both the saved plots using [Shift] +Click and click Plot in the dialog box. The plot should look similar to the one shown in Figure W13C9.Copyright 2003 ABAQUS, Inc. W13.11Figure W13C9. Sealing pressure along the path From this figure it is clear the gasket unloads during the pressurization step. In this exercise, however, nominal bolt and pressure loads were applied. At these load levels, the maximum pressure in the gasket after the bolt load step is approximately 330 psi, which is less than the largest pressure specified in the loading data (6835.4 psi). Thus, during the pressurization step, the gasket i.e., along the loading curve.Optional analysisTo observe the distinct loading and unloading behaviors of the gasket, make the following modifications to the model: 1. Apply a load of 12000 lb to each bolt. 2. Apply a pressure load of 10000 psi. Rerun the analysis and postprocess the results. You will notice that in this case the peak pressure in the gasket after the bolt load step is approximately 8000 psi, which is greater than the largest pressure value specified in the loading data. In the pressurization step, then, the gasket unloads along the unloading curve. To see this, create a pressure vs. closure curve as described below: 1. Using field data, create and save XCY curves of S11 (i.e., pressure) and E11 (i.e., closure) versus time at the integration points of the element indicated in Figure W13C10. Since the element has four integration points, eight curves are created.Copyright 2003 ABAQUS, Inc. W13.12 Choose this elementFigure W13C10. Element used for pressure-closure curve 2. Create a new curve by combining the pressure and closure curves of a given integration point (say integration point 1) into a single curve. The resulting curve is shown in Figure W13C11 and clearly illustrates the distinct loading and unloading behaviors of the gasket. The response predicted by ABAQUS follows the material data very closely.largest pressure specified in dataFigure W13C11. Pressure-closure predicted by ABAQUS at higher load levelsCopyright 2003 ABAQUS, Inc.
lecture5-Abaqus中的接触建... 85页 2财富值喜欢此文档的还喜欢 05 Abaqus中...abaqus资料-建模 隐藏&& Workshop 2 Material and Section Properties: Pump Model...几何体的导入及修理 1.4 练习 2、材料 材料 2.1 材料属性 广泛的材料库包含...每个Abaqus/CAE模型包含一个装配件。 即使用户已经创建一些部件,在没有创建部件...无法通过几何修补将模型改 复杂模型, 模型可能已经枝...里建的模型通过 hypermesh 导入分网后导进 abaqus!...常用金属材料化学浸蚀剂... 27页 免费
3d3s内部教程...在这里,裼 ABAQUS/CAE 建立试验件的有限元模型, AB 问题一: 工字梁弯曲 1...要求如实反映结构的几何形状、 构造形式、材料特性、传力路线、承载方式和边界...0-ABAQUS学习心得_交通运输_工程科技_专业资料。希望能给大家以帮助学习...由于之前我没有接触过 abaqus 对在 abaqus 中建立几何模型很是发怵, 又由于我...ANSYS建模导入abaqus_计算机软件及应用_IT/计算机_专业资料。一、 Ansys 中建模导入 abaqus 中虽然很早就看到有人在 ANSYS 建模, 然后得出几何模型数据, 再进入到 ...材料、 边界条件、 载荷等) 都直接定义在几何模型...每创建一个分析步,ABAQUS/CAE 就会自动生成一个该...(D)使用自有网格不易通过布置种子来控制 实体内部...你所要做的就是正确的建立 node set or element ...很多时候模型是各种复杂材料的混合,如果在 abaqus 里...abaqus/ansys/patran 内部是如何理解几何的,这是个...ABAQUS笔记_建筑/土木_工程科技_专业资料。红色代表翻译...以组成模型;有时多点约束在建立模型中必要的运动...柱体单元是一种三维单元.用于圆形和几何对称模型,...经典问题详解_计算机软件及应用_IT/计算机_专业资料...ABAQUS 入门知识介绍, 几何建模技术与技巧、 分析步...对模型建立、问题求解和结果后处理中需考虑的 关键...
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ABAQUS内部资料-workshop-几何模型建立
Workshop 1 Importing and Editing an Orphan Mesh: Pump Model这个实例中要用到的 cad 模型文件和脚本文件都可以在 abaqus 的 sample 文件夹(或者那个*.zip 文件)里找到。 这个实例涉及到了用 abaqus 进行分析的整个流程中的各个细节,是入门的好帮手。像我这 样的新手一定会喜欢的:) 部件
:泵体+垫片+底盖+螺栓 荷载条件:螺栓预紧+内压IntroductionThe structural response of the pump assembly shown in Figure W3C1 will be determined. The assembly components include the pump housing (imported as an orphan mesh), a gasket, a cover, and eight bolts (all imported as CAD geometry). The analysis involves application of pre-tensioning loads in the bolts followed by internal pressure.pump housingboltsgasketcoverFigure W3C1. Pump assembly In this workshop, you will create the parts of the model. Use the Part module of ABAQUS/CAE to import the mesh of a pump housing. Some modifications of its geometric features follow. The other components of the pump assembly (cover, gasket, and bolts) will be imported as CAD geometry. All of the parts will be halved to take advantage of symmetry.Copyright 2003 ABAQUS, Inc 科研中国
收集 W3.2Note: The parts created in this workshop will be used in subsequent workshops to build the complete model and to perform the analysis. It is important that you use the dimensions stated and not deviate from the w otherwise, you may find it difficult to complete the subsequent workshops.Orphan mesh importFollow the steps below to import the mesh of the pump housing model. 1. Start a new session of ABAQUS/CAE from workshops/pump directory. ABAQUS/CAE automatically loads the Part module. 2. From the main menu bar, select File Import Model. From the list of available models, select pump_ribs.inp. 3. ABAQUS/CAE takes a few seconds to import the model. Once the model is imported, you will be in the Assembly module. Switch back to the Part module. Notice that a new model (named pump_ribs) which contains the imported part (named PUMPC1) has been created. The model appears as shown in Figure W3C 2.Figure W3C2. Orphan mesh of pump housingEditing nodal coordinatesYour first task will be to change the inner diameter of the hole that goes through the top of the pump. The coordinates of the nodes along the inner diameter need to be changed. Since these nodes lie on a circular surface, it will be advantageous to define a cylindrical coordinate system and simply change the radial coordinate of the nodes. Follow the steps below to achieve this task. 1. From the main menu bar, select View Views Toolbox. In the Views dialog box, select the 1C2 view. Turn off the perspective view by clicking the Turn ), and zoom into the component so that the hole is Perspective Off tool ( clearly visible (see Figure W3C3).Copyright 2003 ABAQUS, Inc. W3.3Figure W3C3. Top view of pump housing 2. From the main menu bar, select Tools Datum. The Create Datum dialog box appears (see Figure W3C4). Select CSYS as the datum type. Select the 3 points method, and click OK. When prompted for the type of coordinate system, choose Cylindrical. Place the coordinate system at the origin (0.0, 0.0, 0.0) and click Create Datum. A cylindrical datum coordinate system is created. The origin of the coordinate system coincides with the position of the center of the hole.Figure W3C4. Create Datum dialog box 3. You will now modify the inner diameter of the hole. From the main menu bar, select Tools Edit Mesh. In the Edit Mesh dialog box, select Node as the category and Edit as the method, as shown in Figure W3C5. Click OK to close the dialog box and proceed.Copyright 2003 ABAQUS, Inc. W3.4Figure W3C5. Edit Mesh dialog box 4. You will be prompted to select the nodes to be modified. Begin by setting the selection filters as shown in Figure W3C6 by clicking the Show/Hide Selection Options tool, in the prompt area.Toggle off the selection of entities closest to the screen Circular drag shape Select entities inside the drag shapeFigure W3C6. Selection filters 5. The nodes can be selected in one of two ways: ? Try selecting the nodes individually (the default selection technique) using a Circular Drag Shape. The center of the drag shape should be the center of the cylindrical coordinate system defined earlier (see step 2). Select a perimeter point for the drag shape such that you include all the nodes on the inside surface of the hole. The selected nodes will be highlighted in red after the selection, as shown in Figure W3C7. You may wish to rotate your model to check whether all the nodes have been selected properly. ? You may also select the nodes using the face angle method (i.e., by specifying the maximum deviation in the angle between adjacent element faces). This technique is generally more efficient than selecting the nodes individually: all nodes that pertain to the element faces that satisfy the face angle criterion are automatically selected. In the prompt area, choose by face angle as the method by which the nodes will be selected. Then, click on any element face located on the inner surface of the hole. The nodes on the inner surface areCopyright 2003 ABAQUS, Inc. W3.5highlighted in red after the selection. As before, rotate your model to make sure all the nodes have been selected properly. Once you are satisfied with the selection (using either method), click Done in the prompt area.Figure W3C7. Modified nodes 6. The Edit Nodes dialog box appears, as shown in Figure W3C8. This dialog box will be used to change the diameter of the hole. Click Select in the upper right corner of the dialog box, and choose the cylindrical coordinate system defined in step 2 by clicking on it in the viewport when prompted to choose a local coordinate system. 7. Using the Coordinates specification method, change the 1Ccoordinate (i.e., the radial coordinate) by selecting Specify from the pull down list and entering 0.65. Click OK to close the dialog box and then Done in the prompt area to complete the operation.Figure W3C8. Edit Nodes dialog boxDeleting elementsYou will now remove the ribs on the pump housing and then you will remove half of the part. Begin by removing some of the elements in the rib located near the front of the housing, as shown in Figure W3C9. Use the 1C3 view from the Views Toolbox, and rotate the pump to view one of the front ribs, as shown in Figure W3C9.Copyright 2003 ABAQUS, Inc. W3.61. 2.3. 4.5.Figure W3C9. Rib elements From the main menu bar, select Tools Edit Mesh. In the Edit Mesh dialog box, select Element as the category and Delete as the method. Click OK. When prompted to select the elements to be deleted, use the Show/Hide Selection Options tool to change the drag shape to a Polygon. Select some of the elements located near the 90° bend of the rib, as shown in Figure W3C9. In the prompt area, toggle on Delete associated unreferenced nodes. Zoom out and rotate the view to confirm that only elements pertaining to the ribs have been selected. If any other elements are highlighted, deselect them using [Control]+Click. When you are satisfied with the selection, click Done to delete the elements and their associated nodes. The remaining ribs on the pump housing can be removed by carefully selecting them in a similar fashion. This can be a tedious and time-consuming process for large, complicated models. To facilitate such tasks, elements may also be deleted using sets. A. From the main menu bar, select Tools Edit Mesh. In the Edit Mesh dialog box, click OK to continue deleting elements. B. In the prompt area toggle on Delete associated unreferenced nodes. C. In the prompt area, click Sets to open the Region Selection dialog box. In this dialog box, select the set RIBS and toggle on Highlight selections in viewport to highlight the elements belonging to this set. D. Click Continue to delete the remaining rib elements. E. Click Cancel to close the dialog box. You will now halve the pump housing. Use the 1C2 view from the Views Toolbox to facilitate element selection.6. From the main menu bar, select Tools Edit Mesh. In the Edit Mesh dialog box, click OK to continue deleting elements. 7. In the prompt area, toggle on Delete associated unreferenced nodes.Copyright 2003 ABAQUS, Inc. W3.7Tip: If the Region Selection dialog box appears, click Select in Viewport on the right side of the prompt area so you can select elements in the viewport. 8. Select the upper half of the pump housing for deletion, as shown in W3C10. When you are satisfied with the selection, click Done to delete the elements and their associated nodes. The half pump housing without the ribs is shown in Figure W3C11. 9. Save the model database. Name the model database file PumpAssy.cae.Copyright 2003 ABAQUS, Inc. W3.8selected elementsrectangular drag shapeFigure W3C10. Select half of the pump housing.Figure W3C11. Halved pump housing without ribsImporting CAD geometryYou will now import the remaining components of the assembly into ABAQUS/CAE. 1. From the main menu bar, select File Import Part to open the Import Part dialog box. 2. In this dialog box, set the file type to ACIS SAT. From the list of available files, select cover.sat. Click OK in the dialog box to proceed. 3. In the Create Part from Acis File dialog box, select the Name-Repair tab and toggle on all the available repair options. Click OK to close the dialog box and continue. The imported part is shown in Figure W3C12a. 4. After the part is imported, use the Geometry diagnostics part query tools (Tools Query) to check for any invalid or imprecise entities. 5. Repeat steps 2 through 4 to import the part defined in file gasket.sat. The imported part is shown in Figure W3C12b. 6. Import the part defined in file n_bolts.sat without any repair options turned on. The imported part is shown in Figure W3C12c. 7. Review the different parts of your model. Query the important dimensions using the Query tools and note them for future reference.Copyright 2003 ABAQUS, Inc. W3.98. Save your model database as PumpAssy.cae.(a) cover(b) gasket(c) boltsFigure W3C12. Components of pump assemblyHalving the imported geometryYou will now remove half of each of the imported parts. Begin with the cover. 1. From the Part list located under the tool bar, select cover to access the cover geometry. 2. From the main menu bar, select View Specify. Using the Viewpoint method, enter the coordinates of the viewpoint as 0,0,-1 and the coordinates of the up vector as 0,-1,0. Click OK to apply the view and close the dialog box. Next, create a datum axis using the steps outlined below. This axis will be used to orient the part in the sketch plane when creating the cut profile. From the main menu bar, select Tools Datum. In the Create Datum dialog box, choose Axis as the type and Principal axis as the method. Click OK. Choose the principal Y-Axis as the datum axis. From the main menu bar, select Shape Cut Extrude. Select the top surface of the cover, indicated in Figure W3C13, as the plane on which to sketch.3. 4. 5. 6. 7.Copyright 2003 ABAQUS, Inc. W3.10sketch planedatum axisFigure W3C13. Sketch plane and datum axis 8. Select the datum axis as the edge that will appear vertical and on the right of the sketch. 9. From the main menu bar, select Add Line Rectangle. Sketch a rectangle enclosing the upper half of the cover, as shown in Figure W3C14.cut rectangleFigure W3C14. Cut profile 10. Click mouse button 2 to continue, and click Done in the prompt area. 11. In the Edit Cut Extrusion dialog box, choose the end condition Through All. The direction of extrusion is into the cover. Click OK. The final cover geometry is shown in Figure W3C15.Figure W3C15. CoverCopyright 2003 ABAQUS, Inc. W3.11Similarly, halve the gasket and bolt parts. 12. From the Part list located under the tool bar, select gasket to access the gasket geometry. Use the 1C2 view from the Views Toolbox. 13. As before, define the datum axis to orient the part. From the main menu bar, select Tools Datum. 14. In the Create Datum dialog box, click OK to create another Axis using the Principal axis method. Choose the principal Y-Axis as the datum axis. 15. From the main menu bar, select Shape Cut Extrude. 16. Select the top surface of the gasket as the plane on which to sketch, as shown in Figure W3C16. Select the datum axis as the edge that will appear vertical and on the right of the sketch. 17. From the main menu bar, select Add Line Rectangle. Sketch a rectangle enclosing the upper half of the gasket, as shown in Figure W3C16. surfaces selected as sketch planes(a) gasketcut rectangle Figure W3C16. Cut profiles(b) bolts18. Click mouse button 2 to continue, and click Done in the prompt area. 19. In the Edit Cut Extrusion dialog box, choose the end condition Through All. The direction of extrusion is into the gasket. Click OK. 20. Repeat steps 12 through 19 to remove four of the bolts from the part named n_bolts. Note that the top surface of any of the bolts to the left of the datum axis may be used as the sketch plane for the extruded cut. The final gasket and bolt parts are shown in Figure W3C17. 21. Save the model database as PumpAssy.cae.Copyright 2003 ABAQUS, Inc. W3.12(a) gasket(b) boltsFigure W3C17. Gasket and boltsCopyright 2003 ABAQUS, Inc. Workshop 2 Material and Section Properties: Pump ModelIntroductionIn this workshop you will use the ABAQUS/CAE Property module to define the material and section properties of the components in the pump assembly. The gasket will be defined using gasket material properties. All other components (pump housing, cover, and bolts) are assumed to possess the properties of steel.Defining a linear elastic material and solid section propertiesFollow the steps outlined below to complete the steel property and section assignments for the pump components. Note that the units used in this model are in, lb, and psi. 1. Start a new session of ABAQUS/CAE from the directory containing the pump assembly model. 2. From the main menu bar, select File Open to open the model database file PumpAssy.cae. 3. Switch to the Property module. 4. From the Model list located under the toolbar, select pump_ribs to access the pump_ribs model. 5. From the main menu bar, select Material Create to create a linear elastic material named Steel. Specify a Young’s modulus of 30.E6 psi and a Poisson’s ratio of 0.3. 6. From the main menu bar, select Section Create to create a homogeneous solid section named steelSection that refers to the material named Steel. 7. From the main menu bar, select Assign Section to assign the section named steelSection to the parts named cover, n_bolts, and PUMP-1. Tip: You will need to make the section assi select the different parts by choosing them from the Part pull-down list.Defining the gasket material and section propertiesThe typical specification of gasket material properties in ABAQUS involves a tabular representation of the pressure versus closure relationship in the thickness direction of the gasket. The pressure versus closure models available in ABAQUS allow the modeling of very complex gasket behaviors, including nonlinear elasticity, permanent plastic deformation, and loading/unloading along different paths. These behaviors are usually calibrated from test data. A detailed discussion of gasket material behavior, however, is beyond the scope of this course. For your convenience (and to make the analysis realistic) the gasket properties are defined in a script that you will read directly into ABAQUS/CAE. 1. From the main menu bar, select File Run Script.Copyright 2003 ABAQUS, Inc. 科研中国
收集 W5.22. 3.4. 5.6.The Run Script dialog box appears. Select the file named gasket_material.py. Click OK in the dialog box. From the main menu bar, select Material Manager to open the Material Manager. Notice that the material named Gasket has been added to the model database. Select Gasket, and click Edit. Review the gasket material properties. Note the gasket has membrane elasticity of 12155 psi, shear stiffness of 6435 psi, and a coefficient of thermal expansion of 1.67 E?5 /°F. Select Gasket Thickness Behavior from the list of available Material Options in the dialog box, and notice the tabular specification of the loading and unloading curves for the gasket (see Figure W5C1).Figure W5C1. Edit Material dialog box You can use the plotting capabilities within ABAQUS/CAE to plot the loading and unloading curves. This may help you obtain a better understanding of the material behavior. 7. Open the Loading tabbed page. Right-click your mouse over the column headings of the table, and select Create XY Data from the list of options that appears. Name the curve loading when prompted for a name in the Create XYCopyright 2003 ABAQUS, Inc. W5.3Data dialog box. Repeat the same operation for the unloading curve to create a curve named unloading. 8. Switch to the Visualization module. 9. From the main menu bar, select Tools XY Data Manager. The XY Data Manager appears. 10. Select both the curves (using the shift key), and click Plot. You should see a similar plot in the viewport as that shown in Figure W5C2.Figure W5C2. Loading and unloading gasket behavior 11. Click Dismiss in the XY Data Manager, and switch back to the Property module to continue with the gasket section property specification. 12. From the main menu bar, select Section Create to create a gasket section. 13. In the Create Section dialog box, select Other as the category and Gasket as the type. Name the section gasketSection (see Figure W5C3) and click Continue.Copyright 2003 ABAQUS, Inc. W5.4Figure W5C3. Create Section and Edit Section dialog boxes 14. In the Edit Section dialog box (see Figure W5C3), select Gasket as the material and accept all other defaults. 15. Assign the section named gasketSection to the part named gasket. 16. Save your model database as PumpAssy.cae.Copyright 2003 ABAQUS, Inc. Workshop 3 Pump Model AssemblyIntroductionIn this workshop you will create a single part instance of each component of the pump model and use the different positioning techniques available in ABAQUS/CAE to position the part instances relative to each other in a global coordinate system.Instancing and positioning the pump housing1. From the main menu bar, select File Open and open the model database file PumpAssy.cae. 2. Switch to the Assembly module, and select pump_ribs from the list of available models. Note that since you imported the pump housing as a model, an instance of the part PUMP-1 has already been created. No further positioning of this part instance is required.Instancing and positioning the gasket1. From the main menu bar, select Instance Create to create an instance of the part named gasket. You must position the gasket such that its top surface touches the bottom surface of the pump housing. The most convenient way to do this is to use the Face to Face positioning constraint. 2. From the main menu bar, select Constraint Face to Face. Select any element face on the bottom of the pump housing as the face on the movable part instance. To facilitate the selection of a planar face on the fixed part instance (i.e., the gasket), you will suppress the visibility of the pump housing. 3. From the main menu bar, select View Assembly Display Options and suppress the visibility of instance PUMP-1 in the Instance tabbed page. 4. Select the top face of the gasket as the face on the fixed part instance. You should now see two arrows pointing in opposite directions in the viewport, as shown in Figure W6C1. (You may need to select View Auto-Fit from the main menu bar to see this.)Copyright 2003 ABAQUS, Inc. 科研中国收集 W6.2gasketpump housingFigure W6C1. Housing and gasket arrows initially point in opposite directions The pump housing will be moved so that its arrow points in the same direction as that of the gasket. 5. Click Flip in the prompt area to reverse the direction of the arrow on the pump housing so that both arrows point in the same direction. When both arrows point in the same direction, click OK in the prompt area. 6. Accept 0.0 as the default distance from the fixed plane along its normal. 7. Use the assembly display options to restore the visibility of the pump housing. 8. Verify that the pump housing is now exactly on top of the gasket. Tip: Use the Query tools to calculate the distance between a point on the lower surface of the pump housing and a point on the top surface of the gasket. If the pump is exactly on top of the gasket, the third component of the distance vector should be zero.Instancing and positioning the cover1. Instance the part named cover. The cover must be rotated such that the rounded side of the cover is inside the pump. This requires rotating the cover about the global 1-axis. 2. From the main menu bar, select Instance Rotate. Select the cover when prompted for the instance to be rotated. Tip: Click Instance List in the prompt area to select the cover from a feature list. This is often easier than selecting instances from the viewport. 3. Enter the coordinates of the origin (0.0, 0.0, 0.0) as the start point for the axis of rotation. 4. Enter (1.0, 0.0, 0.0) as the coordinates of the end point for the axis of rotation. 5. Enter 180.0 as the angle of rotation. See Figure W6C2 for the configuration after the rotation operation (note the visibility of the pump housing has been suppressed in this figure).Copyright 2003 ABAQUS, Inc. W6.3Figure W6C2. Gasket and cover 6. The cover also needs to be positioned so that its top touches the bottom of the gasket. Use the Contact constraint to position the top of the cover with respect to the bottom of the gasket. Alternatively, you could also use the Face to Face constraint. 7. From the main menu bar, select Constraint Contact. 8. Select the top face of the cover (shown in Figure W6C3) when prompted for the face of the movable part instance.face of fixed part instance (gasket)face of movable part instance (cover)Figure W6C3. Positioning of cover relative to the gasket 9. Select the bottom face of the gasket (shown in Figure W6C3) when prompted for the face of the fixed part instance. 10. Pick a point on the top surface of the cover as a start point for the direction of contact, as shown in Figure W6C4Copyright 2003 ABAQUS, Inc. W6.4end pointstart pointFigure W6C4. Contact positioning constraint 11. Select a point on the bottom surface of the gasket as the end point for the direction of contact, as shown in Figure W6C4. 12. When prompted for a clearance between the surfaces, enter a value of 0.0. 13. Verify that the gasket is now just in contact with the cover.Instancing and positioning the bolts1. Instance the part n_bolts. 2. The bolts will be in position when their ends are aligned with the bottom of the cover. Use the Face to Face constraint to accomplish this task. The pump assembly with the bolts in their final positions should look similar to that shown in FigureW6C5.Figure W6C5. Final positions of the boltsCopyright 2003 ABAQUS, Inc. W6.5The complete assembly is shown in Figure W6C6.Figure W6C6. Complete pump assembly 3. Save your model as PumpAssy.cae.Copyright 2003 ABAQUS, Inc. Workshop 9 Free and Swept Meshing: Pump ModelIntroductionIn this workshop you will use the Mesh module of ABAQUS/CAE to generate the finite element meshes for the pump assembly model. The required tasks include assigning mesh attributes to each part instance, assigning mesh seeds, and generating the meshes.Modifying the pump housing element type1. Open the model database file PumpAssy.cae. Switch to the M and, from the context bar, select pump_ribs from the list of available models. 2. Use the assembly display options (View Assembly Display Options) to suppress the visibility of all part instances save for the pump housing. In addition, suppress the visibility of all datum planes and axes. 3. Next, create a set that includes all the elements comprising the pump housing. From the main menu bar, select Tools Set Create. 4. In the Create Set dialog box, select Element as the set type. Name the set pump-mesh and click Continue. 5. Select all the elements in pump housing using a rectangular drag window. Use the selection filters if necessary. Click Done when the selection is complete. Use the Query tools to determine the type of element currently assigned to the mesh. 6. From the main menu bar, select Tools Query. The Query dialog box appears. 7. From the list of available General Queries, select Element and click Apply. Click on any element and note that the element’s label, type, and nodal connectivity are listed in the message area, as shown in Figure W9C1. Repeat this for other elements in the mesh.Figure W9C1. Selected element attributes 8. Click Cancel in the Query dialog box to close it. 9. The element type for the pump housing is the linear tetrahedron (C3D4), which is not suited for an analysis involving contact. Thus, change the element type assigned to the pump housing to modified second order tetrahedrons (C3D10M). 10. From the main menu bar, select Mesh Element Type. 11. When prompted for the type of region, click Sets on the right side of the prompt area.Copyright 2003 ABAQUS, Inc. 科研中国收集 W9.212. The Region Selection dialog box appears. Select the set pump-mesh and click Continue. 13. The Element Type dialog box appears. Review the current settings. Toggle on Quadratic under Geometric Order. Notice that the element type message changes to C3D10M. Click OK. 14. Use the Query tools to confirm that the element type associated with the mesh has been updated.Generating the bolt meshUse the assembly display options to restore the visibility of the bolts and suppress the visibility of the pump housing. The bolts are colored yellow, indicating they can be readily meshed with hexahedral elements using a swept mesh technique. Mesh the bolts with a local edge seed of 8 using first-order incompatible mode hexahedral elements (C3D8I). 1. From the main menu bar, select Seed Edge by Number. 2. Select all the edges of the bolts using a rectangular drag window. 3. When prompted for the number of elements along the edges, enter 8. 4. From the main menu bar, select Mesh Element Type to change the element type associated with the bolts. Tip: Click Select in Viewport on the right side of the prompt area to select the bolts directly in the viewport. 5. In the prompt area, select Geometry as the region type. Using a rectangular drag shape, select all the bolts. 6. In the Element Type dialog box, choose Incompatible modes under Element Controls. Click OK. 7. From the main menu bar, select Mesh Instance to mesh the bolts. Click one of the bolts when prompted for the instance to be meshed. 8. Review the mesh when the operation is complete. The mesh of one of the bolts is shown in Figure W9C2.Generating the cover and gasket meshesThe Cover Use the assembly display options to restore the visibility of the cover and suppress the visibility of the bolts. The cover is colored orange, indicating that it cannot be meshed with hexahedral elements without the aid of partitioning. For the purpose of this exercise, mesh the cover using the free tetrahedral mesh technique. Use a global seed size of 0.35 and element type C3D10M. 1. From the main menu bar, select Mesh Controls. Select the cover as the region to which mesh contr and, in the Mesh Controls dialog box, select Tet as the element shape. Click OK to continue.Copyright 2003 ABAQUS, Inc. W9.3The part is now colored pink, indicating it can be meshed with the free mesh technique. 2. Assign a global mesh seed size (Seed Instance) of 0.35 and local edge seeds (Seed Edge By Number) of 8 to the edges comprising the bolt holes. 3. From the main menu bar, select Mesh Element type. Select the cover geometry as the region to which the element type will be assigned and choose the modified quadratic tetrahedron element type (C3D10M). 4. Generate the cover mesh. The mesh on the cover plate is shown in Figure W9C2. The Gasket Use the assembly display options to restore the visibility of the gasket and suppress the visibility of the cover. The gasket is colored yellow, indicating it can be readily meshed with hexahedral elements using a swept mesh technique. 1. Assign a global mesh seed size (Seed Instance) of 0.25. 2. Assign the linear hexahedral gasket element type (GK3D8) to the gasket geometry (Mesh Element type). 3. Generate the gasket mesh. The mesh on the gasket is shown in Figure W9C3.Figure W9C2. Bolt and cover meshesFigure W9C3 Gasket mesh 4. Save the model database as PumpAssy.cae, and exit the ABAQUS/CAE session.Copyright 2003 ABAQUS, Inc. Workshop 13 Nonlinear Static Analysis of a Pump AssemblyIntroductionIn this workshop you will use ABAQUS/CAE to complete the pump assembly model and to submit it for analysis. You will begin by defining the analysis steps and the output requests associated with these steps. Next, you will define the interactions between the different components of the model. You will also apply bolt and pressure loads and boundary conditions to the model. Finally, you will create and submit a job for analysis and evaluate the analysis results.Defining the analysis stepsThe analysis history of the pump assembly consists of two steps: a step that simulates the pre-tensioning in the bolts, followed by a step that simulates the pressurization of the bolted assembly. 1. Open the model database file PumpAssy.cae. Switch to the Step module, and in the context bar select pump_ribs from the list of available models. 2. Create a general static step named PreloadBolts. Activate geometric nonlinearity (toggle on Nlgeom), and specify an initial time increment of 0.05 and a total time period of 1.0. 3. Create a second general static step named Pressure. Insert this step after the step named PreloadBolts. Specify an initial time increment of 0.1 and a total time period of 1.0. 4. Activate the contact diagnostic printout for both the steps. From the main menu bar, select Output Diagnostic Print. In the Diagnostic Print dialog box, click in the blank area under the Contact column for both steps so that tick marks appear, thus activating contact diagnostic output for these steps. 5. Click OK to close the dialog box.Defining contact and constraintsThe mere proximity of the model components does not indicate that the part instances will interact during the analysis. Thus, unless explicitly specified, the individual components of an assembly will not interact with one another. For any loads to be properly transmitted between the components, you must define interactions between the components. In structural analysis problems the most common method of transferring loads between unconnected regions of a model assembly is through contact interactions. To define a contact interaction between any two bodies, however, you must first identify the regions of each body that will be involved in contact (e.g., define surfaces). Your next task in this workshop, therefore, will be to define surfaces on each component that will be involved in contact.Copyright 2003 ABAQUS, Inc. 科研中国收集 W13.2Defining the surfaces In ABAQUS/CAE a surface can be created either on a part that has underlying geometry (such a surface is known as a geometry-based surface) or on a part that does not have underlying geometry (e.g., such a surface is known as a mesh-based surface). Since this assembly consists of both imported geometry and an orphan mesh, you will create both types of surfaces. 1. Switch to the Interaction module. 2. Make only the pump housing visible using the Assembly Display Options dialog box (View Assembly Display Options). 3. Create a surface named PumpBot by following the steps given below: A. From the main menu bar, select Tools Surface Manager. B. In the Surface Manager, click Create. C. The Create Surface dialog box appears. Select Mesh as the surface type. Name the surface PumpBot, and click Continue. D. You will be prompted for the regions to define the surface. For a mesh-based surface, you can either select the elements individually or select a group of elements by specifying the maximum deviation in the face angle between adjacent elements. The face angle method is in general a more efficient way of choosing elements to define a surface. Hence, in the prompt area select by angle as the selection method and enter a face angle of 5 degrees. E. Click any element face on the bottom of the pump. All the element faces on the bottom of the pump will then be highlighted in red, as shown in Figure W13C1. Click Done in the prompt area when you are finished.Figure W13C1. Surface PumpBot 4. Similarly, create a surface named PumpBolts that defines a surface in the region of the pump that will come into contact with the heads of the bolts. Select the surface using a face angle of 5 degrees, as shown in Figure W13C2. 5. Next, define a surface in the region where the internal pressure will be applied to the pump. Name the surface PumpInside. Using the face angle method with aCopyright 2003 ABAQUS, Inc. W13.3maximum deviation of 24.1 degrees, select the element faces shown in Figure W13C3. Tip: Use [Shift]+Click to select more than one item at a time. Select as many regions as possible using the
then select any remaining regions individually. Zoom in as necessary to facilitate your selections. To deselect any unintentionally selected regions, use [Ctrl]+Click.Figure W13C2. Surface PumpBoltsFigure W13C3. Surface PumpInside 6. Use the Assembly Display Options dialog box to restore the visibility of the cover and to suppress the visibility of the pump housing. 7. Define a geometry-based surface named CoverTop on the region of the cover where it contacts the gasket. 8. Define a surface named CoverInside that defines the region where the pressure load will be applied as shown in Figure W13C4. 9. Create a surface for each of the four holes in the cover as shown in Figure W13C5. Name these surfaces BoltHole-1 through BoltHole-4.Copyright 2003 ABAQUS, Inc. W13.4Note: Keep track of the order in which you define the bolt hole surfaces since later you will have to create corresponding surfaces on the bolt shanks. You should save your current view (View Save User 1) to make it easier when defining the bolts surfaces later. 10. Restore the visibility of the gasket and suppress the visibility of the cover using the Assembly Display Options dialog box. Define surfaces on the top and bottom regions of the gasket. Name these surfaces GasketTop and GasketBot, respectively. 11. Suppress the visibility of the gasket, and restore the visibility of the bolts. Set the view to the user-defined view (View Views Toolbox and click 1 in the Views dialog box). 12. Create a surface for each bolt thread corresponding to each bolt hole surface in the cover, as shown in Figure W13C5. Name the surfaces BoltThread-1 through BoltThread-4. 13. Create a single surface that includes the regions directly under the heads of all the bolts as shown in Figure W13C5. Name this surface BoltHeads. 14. Save your model database as PumpAssy.cae.surface CoverInsideFigure W13C4. Surface CoverInsidesurface BoltHeads surface BoltThreadsurface BoltHoleFigure W13C5 Bolt-related surfacesDefining the contact interaction Now that you have defined the surfaces that will be involved in contact, you can define the contact interactions between the different components. Defining contact interactions in ABAQUS/CAE involves choosing the surfaces involved contact and defining contactCopyright 2003 ABAQUS, Inc. W13.5properties (friction, etc.) for each interaction. Follow the steps given below to define the contact interactions for this model. 1. From the main menu bar, select Interaction Property Create to create a contact property named Friction. 2. In the Edit Contact Property dialog box, select Mechanical Tangential Behavior. Choose the Penalty friction formulation, and define a coefficient of friction of 0.2. Click OK to close the dialog box. 3. From the main menu bar, select Interaction Create to create an ABAQUS/Standard surface-to-surface contact interaction in the Initial step. Name the interaction Pump-Bolts. 4. Click Surfaces in the prompt area to select the regions involved in contact using the surfaces defined earlier. In the Region Selection dialog box, choose the surface PumpBolts as the master surface (since it is continuous) and the surface BoltHeads as the slave surface (since it has a relatively finer mesh and is discontinuous). Use the Small sliding formulation, adjust slave nodes within 1.e-5 in. of the master surface to ensure that the surfaces are initially in contact, and accept Friction as the contact property. 5. Create another ABAQUS/Standard surface-to-surface contact interaction in the Initial step between the bottom of the gasket and the top of the cover. Name the interaction named Cover-Gasket. Choose the surface CoverTop as the master surface (since the underlying elements are much stiffer) and GasketBot as the slave surface. Use the Small sliding formulation, adjust slave nodes within 1.e-5 in. of the master surface to ensure that the surfaces are initially in contact, and accept Friction as the contact property. Defining tie constraints Tie constraints will be used to tie the gasket to the pump. You will also define tie constraints to simulate the effect of the bolt threads when fastened to the bolt holes. 1. From the main menu bar, select Constraint Create. Name the constraint PumpGasket. Select Tie as the constraint type and click Continue. 2. The list of previously defined surfaces appears in the Region S select the surface PumpBot as the master surface and the surface GasketTop as the slave surface. Accept all the default settings in the Edit Constraint dialog box, and click OK to close the dialog box. 3. In a similar fashion, define tie constraints between each bolt thread and its corresponding bolt hole. In each case, select the bolt hole to be the master surface and the bolt thread to be the slave surface. Name the constraints Tie-1 through Tie-4. In the Edit Constraint dialog box, specify a distance of 0.07 as the position tolerance and toggle off Adjust slave node initial position for each constraint. Tip: After creating the first tie constraint between the bolt and the bolt holes, copy the constraint and edit the region selections.Copyright 2003 ABAQUS, Inc. W13.64. Save your model database as PumpAssy.cae.Defining loads and boundary conditionsYour next task will be to define the loads and boundary conditions that will act on the structure. Applying bolt loads In ABAQUS/CAE assembly or bolt loads are applied across user-defined pre-tension sections in the bolt. When modeling the bolt with solid elements, the pre-tension section is defined as a surface in the bolt shank that effectively partitions the bolt into two regions. Follow the steps given below to create the pre-tension sections in the bolts. 1. Switch to the Load module. 2. Using the Assembly Display Options dialog box, suppress the visibility of all part instances except for the bolts. Define a datum plane for the purpose of partitioning the bolts at the location where the pre-tension sections will be defined. 3. From the main menu bar, select Tools Datum. In the Create Datum dialog box, select Plane as the datum type. 4. Select Offset from plane as the method, and click OK. Offset the datum plane from the bottom of the bolts (select the bottom face of any bolt). Click Enter Value in the prompt area. Flip the arrow indicating the offset direction if necessary so that it points from the bottom of the bolt toward the bolt head. Enter an offset distance of 0.5. 5. Partition the bolts using this datum plane. From the main menu bar, select Tools Partition. Create a Cell partition using the Use datum plane method. Select all the bolts as the cells to be partitioned. Note: The bolt meshes will have to be regenerated as a result of this partition. Switch to the mesh module after creating the partition. Respecify the edge seeds for the bolts with 8 elements along the edges and recreate the bolt meshes. . 6. To view the partitions, switch the rendering style to wireframe 7. To define the direction along which the bolt load will be applied, create a datum axis along the principal Z-axis. From the main menu bar, select Tools Datum. Select Axis as the type and Principal axis as the method. Click Z-axis in the prompt area. 8. From the main menu bar, select Load Create to define the bolt load. The Create Load dialog box appears. Select the step named PreloadBolts as the step in which the load will be applied. Select Bolt load as the load type as shown in Figure W13C6. Click Continue.Copyright 2003 ABAQUS, Inc. W13.7Figure W13C6. Create Load dialog box 9. In the prompt area, click Geometry as the region type. 10. Select the internal surface of any bolt (e.g., as shown in Figure W13C7). This surface defines the pre-tension section.Figure W13C7. Bolt internal surface 11. Select the datum axis defined earlier when prompted for a datum axis parallel to the bolt centerline. 12. Enter a bolt load of 500 lb in the Edit Load dialog box. Accept all other default settings in the dialog box. 13. Repeat steps 8 through 12 for the other bolts. Tip: After creating the first bolt load, copy the load and edit the region selections. 14. Typically, you want to tighten the bolts to a predefined load level (pre-tensioning) and then “freeze” the deformation in the subsequent load steps (pressure loading, heating up, etc). To do this, proceed as follows:Copyright 2003 ABAQUS, Inc. W13.8A. From the main menu, select Load Manager. The load manager appears in the viewport. B. Select any bolt load in the Pressure step by clicking Propagated and click Edit in the dialog box. C. In the Edit Bolt Load dialog box, select Fix at current length as the method and click OK in the dialog box. D. Repeat steps B and C for the other bolt loads. Applying the pressure load and boundary conditions 1. Display the pump housing using the assembly display options. Switch the render style to shaded . 2. From the main menu bar, select Load Create to define a pressure load named PumpLoad in the step named Pressure. Apply the load to surface PumpInside. Specify a load magnitude of 1000 psi. 3. Similarly, apply a pressure of 1000 psi to the surface CoverInside. Name the load CoverLoad. 4. Assume that the bottom of the cover is welded against a rigid plate. From the main menu bar, select BC Create. 5. In the Create Boundary Condition dialog box, select Symmetry/ Antisymmetry/Encastre as the boundary condition type and the Initial step as the step in which to apply the boundary condition and click Continue. 6. In the prompt area, click Select in Viewport to permit direct selection of the affected region in the viewport. Select the bottom region of the cover and click Done in the prompt area. In the Edit Boundary Condition dialog box, select Encastre as the boundary condition type and click OK to close the dialog box. 7. Apply symmetry boundary conditions to the cover and gasket as follows: A. From the main menu bar, select BC Create. B. In the Create Boundary Condition dialog box, accept Symmetry/ Antisymmetry/Encastre as the boundary condition type and the Initial step as the step in which to apply the boundary condition. Click Continue. C. In the prompt area, select Geometry as the region type. Select the faces on the symmetry planes of the cover and gasket using [Shift]+Click and click Done in the prompt area. In the Edit Boundary Condition dialog box, select YSYMM as the boundary condition type and click OK to close the dialog box. 8. Similarly, apply symmetry boundary conditions to the nodes on the symmetry plane of the pump housing. For this part the region type is Mesh. 9. Save your model database.Copyright 2003 ABAQUS, Inc. W13.9Creating and submitting a job for analysisNow you are ready to create and submit the model for analysis. You will use the Job module to create an analysis job and submit it for analysis. 1. Switch to the Job module. 2. Create a job named PumpAnalysis. Enter any suitable job description. Accept all other default job settings. 3. Submit the job for analysis. Note: This analysis job takes about 30 minutes to complete on a Windows 2000 machine with a 1700 MHz processor. Monitor the job for several minutes to ensure it is running properly. Then proceed with the next lecture before continuing with this workshop.Visualizing the analysis resultsAfter the analysis is complete, you will review the results in the Visualization module. For the kind of analysis you just performed, some of the interesting results would be the distribution of the sealing pressure in the gasket at different stages of operation, the history of the bolt force in the bolts, the deformed shape and stresses in the bolts, etc. 1. Switch to the Visualization module, and open the PumpAnalysis output database file. 2. Look at the undeformed and deformed plot of the model. You will notice that the pump housing does not undergo large deformations because of its stiffness. Most of the deformation takes place in the gaskets and the bolts. Use the Create Display Group dialog box to look at the deformed shape in the bolts and gaskets only. 3. Plot the Mises stresses in the model. Use the Create Display Group dialog box to plot the Mises stresses in the bolts only. 4. Plot a contour of the sealing pressure in the gasket. First use the Create Display Group dialog box to view the gasket only. The sealing pressure in the gasket is the S11 component of the stress tensor. From the main menu bar, select Result Field Output. In the Field Output dialog box select the S11 component and click OK. 5. Plot an animation of the sealing pressure in the gasket. Specify a minimum value of 0.0 and a maximum value of 325 in the Limits tabbed page of the Contour Options dialog box. From the main menu bar, select Animate Time History to animate the results. 6. Create a path plot of the sealing pressure along a critical location in the gasket. Follow the steps given below: A. From the main menu bar, select Tools Path Create. The Create Path dialog box appears in the viewport.Copyright 2003 ABAQUS, Inc. W13.10B. The Node list type is selected by default. Click Continue in the dialog box. C. In the Edit Node List Path dialog box, click Add After. D. You will be prompted to select the nodes from the viewport to be inserted into the path. Pick the nodes as shown in Figure W13C8. Click Done in the prompt area when the selection is complete. Click OK in the Edit Node List Path dialog box.end of pathbeginning of pathFigure W13C8. Node path E. From the main menu bar, select Tools XY Data Create. Select Path in the Create XY data dialog box and click Continue. F. Browse the settings in the XY Data from Path dialog box. In the Y-values frame, click Step/Frame. G. In the Step/frame dialog box, select the last frame of the step named Pressure. Click OK. H. Make sure that Field output variable is set to S11 in the XY Data from Path dialog box. Click Plot in the dialog box to view the path plot. I. Save the plot as Step-2. J. Similarly, create a path plot of the sealing pressure for the same set of nodes for the PreloadBolts step. Save the plot as Step-1. K. View the saved plots. From the main menu bar, select Tools XY Data Manager. In the XY Data Manager dialog box, select both the saved plots using [Shift] +Click and click Plot in the dialog box. The plot should look similar to the one shown in Figure W13C9.Copyright 2003 ABAQUS, Inc. W13.11Figure W13C9. Sealing pressure along the path From this figure it is clear the gasket unloads during the pressurization step. In this exercise, however, nominal bolt and pressure loads were applied. At these load levels, the maximum pressure in the gasket after the bolt load step is approximately 330 psi, which is less than the largest pressure specified in the loading data (6835.4 psi). Thus, during the pressurization step, the gasket i.e., along the loading curve.Optional analysisTo observe the distinct loading and unloading behaviors of the gasket, make the following modifications to the model: 1. Apply a load of 12000 lb to each bolt. 2. Apply a pressure load of 10000 psi. Rerun the analysis and postprocess the results. You will notice that in this case the peak pressure in the gasket after the bolt load step is approximately 8000 psi, which is greater than the largest pressure value specified in the loading data. In the pressurization step, then, the gasket unloads along the unloading curve. To see this, create a pressure vs. closure curve as described below: 1. Using field data, create and save XCY curves of S11 (i.e., pressure) and E11 (i.e., closure) versus time at the integration points of the element indicated in Figure W13C10. Since the element has four integration points, eight curves are created.Copyright 2003 ABAQUS, Inc. W13.12 Choose this elementFigure W13C10. Element used for pressure-closure curve 2. Create a new curve by combining the pressure and closure curves of a given integration point (say integration point 1) into a single curve. The resulting curve is shown in Figure W13C11 and clearly illustrates the distinct loading and unloading behaviors of the gasket. The response predicted by ABAQUS follows the material data very closely.largest pressure specified in dataFigure W13C11. Pressure-closure predicted by ABAQUS at higher load levelsCopyright 2003 ABAQUS, Inc.
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