Use SimulationXpress to analyze deformation of parts by applying fixtures and loads and defining materials. Vary load and/or pressure and customize materials. Learn to start and run SimulationXpress to analyze a single body part. Get comfortable working with items on design tree. Understand that pressure and/or load can be applied only to faces uniformly and constantly. Understand that custom materials properties must accurately represent part materials.
Adjust the mesh density to adjust accuracy of a simulation. Run a simulation. Use the SimulationXpress wizard to view results such as the stress, displacement, deformation, and factor of safety of the simulation. Generate and save an eDrawings file or word document both of which display the results of the simulation. Adjust a mesh in a simulation. Run a simulation. Interpret the results of a simulation. Generate an eDrawing file or Microsoft Word document with the results.
Based on analyses result, optimize factor of safety, maximum stress or maximum displacement value to an acceptable value. Vary a dimension within the range to try to meet the requirement. Make the design leaner or reduce material cost if it meets or exceeds the factor of safety. Achieve factor of safety through optimizing design. Use built-in automation capability to optimize a model. Run simulation.
This module covers how to use Annotation Views to organize Product and Manufacturing Information (PMI). View PMI using the Dynamic Annotation Views tool. Insert orthogonal Annotation Views and add a custom Annotation View using the By Selection option. Reassign PMI to different Annotation Views to organize the display. Use viewports to view the model from multiple perspectives at the same time.
This module covers three technical summaries for using SOLIDWORKS MBD. For drafted parts: Create DimXpert Location dimensions between drafted surfaces by suppressing draft or using intersection geometry. For sheet metal: Use a separate configuration for the flat pattern of a sheet metal part. Use reference dimensions to dimension between sheet metal bend lines. For weldment structures: Use cut lists to display dimensions for structural members of weldment structures. Add 3D Notes to the weldment structure and apply weldment symbols.
Review the basic functionality of the SOLIDWORKS Nonlinear module. Show activation of SOLIDWORKS Simulation Add-In. Learn three basic nonlinear phenomena in engineering calculations. Review of control methods available in the module. Review of basic material models available in the module.
Review the difference between small displacement linear, and large displacement nonlinear analyses. Introduce the concept of time curves, and discuss basic options. Solve small displacement linear analysis to demonstrate inaccurate solution. Define a nonlinear simulation study. Use time curves to control variation of the nonlinear loading. Use fixed increment stepping, and autostepping stepping procedures to solve the nonlinear problem. Postprocess results of the nonlinear simulation. Compare results from nonlinear studies with various setup parameters.
Introduction to the force control and displacement control methods in nonlinear module. Experience and resolve solution instabilities when solving nonlinear problems. Define nonlinear study boundary conditions and loads. Stabilize force control method to arrive to a final solution. Solve the problem using the displacement control method. Adjust boundary conditions for the displacement control method. Compare nonlinear results from the force control, and the displacement control methods.
Introduction to the material nonlinearity, namely metal plasticity. Effect of mesh quality on the quality of the numerical stress results. Solve problem with linear small displacement solution and identify a need for the nonlinear solution due to high stress. Define nonlinear study boundary conditions and loads. Define nonlinear material model with von Mises plasticity. Use simplified bi-linear plasticity material model. Review the stress and displacement results at various times. Study effect of mesh quality on the quality of the stress results. Use the mesh sectioning feature to review stress distribution within the bodies.
Animations provide an extra visual representation of how an assembly can be put together, taken apart, and shows the order in which parts are added. Animations compliment exploded views incredibly well and help manufacturers and assemblers understand exactly how the components come together. Animations also serve as a great marketing tool, as they can show off the complexities of the design as well as how refined the final product is. In this lesson, an Animation will be created in SOLIDWORKS Composer by exploding additional components in this assembly.
Understand how to start routing and how the route subassembly organizes and stores the components of a route. Enable the Routing add-in. Locate the Piping, Tubing and Electrical menus. Understand a routing subassembly. Identify routing library components. Use the routing library manager to load settings.
Learn how to optimize designs to reduce model weight by varying model dimensions. Apply parameters and constraints to optimize your design to meet goals. Learn how design studies are used with Simulation.
Exploded views can be created in SOLIDWORKS Composer and are incredibly helpful when trying to show all the components used in an assembly, or for showing how to assemble, disassemble, or repair the assembly. Exploded views can also be used for other purposes such as showing off a design by a marketing team. In this lesson, an exploded view and detailing the individual components will be shown by adding labels to each part in the assembly.
Observe stress analysis of a part using SimulationXpress to determine the deformation of the part under the influence of a load (force or pressure). Understand the assumptions and limitations of SimulationXpress. Observe stress analysis being performed on a part.
Use the Machine dialog to define the parameters of the machine tool used to manufacture the part. Set machine properties to select machine type and duty for manufacturing. Select tool crib to be used by machine. Select the post processor used to generate NC code. Set posting parameters for post processor.
Generate a cam profile based on an input follower displacement from a data set. Define a motion of a follower using Data Points. Generate a cam profile using Trace Path. Verify the generated cam profile.
Simulate a mechanism placing an object into a box and a cover on the box. Apply servo motors. Add proximity sensors. Create and run event based motion study.
Use the Post Process command to generate NC code from the parts toolpath and operation information. Select the post processor within the machine dialog. Run the Post Process command and set a file name and location for saving. Generate the NC code and select the option to Open G-Code in the SOLIDWORKS CAM NC Editor. Review the NC code within the SOLIDWORKS CAM NC Editor.
Blocks group sketch entities and dimensions together so that they move as one in a sketch. Together with a layout sketch, you can go directly from an assembly sketch to the full assembly. Create, edit and save blocks. Create a layout sketch of an assembly using blocks. Build assembly components based on the existing blocks.
Use the Stock Manager to define the material, stock type and size to machine the part from. Select the stock material. Select stock type to define size and shape. Set the stock size options. View the stock preview.
Use Automatic Feature Regognition (AFR) to automatically extract the machinable features to be machined. Set options to define feature types to extract. Review the hole recognition and feature groups options. Review options to automatically generate operations and toolpaths. Extract machineable features and review the features in the CAM Feature Tree.
Use the edit definition command to modify contouring (finish) operations. Review contour operation parameters. Review side parameters settings. Review feeds and speeds tab.
Use the Edit Definition command to modify contouring operation leadin and leadout parameters. Modify leadin type. Modify leadin amount and overlap. Modify arc radius and arc angle.
Use Interactive Feature Regognition (IFR) to manually create a machinable feature. Create a corner slot feature using the 2.5 axis feature command. Review geometry selection options to define the feature. Set the feature end condition. Modify the machining strategy for the feature.
