使用 SimulationXpress 通过应用夹具和载荷并定义材料来分析零件的变形。 改变载荷和/或压力并自定义材料。 了解如何启动并运行 SimulationXpress 以分析单个几何体零件。 您可以在设计树中方便地处理各项目。 了解压力和/或载荷只能均匀连续地应用到面。 了解自定义材料属性必须准确地表示零件材料。
调整网格密度以调整模拟的精确度。运行模拟。使用 SimulationXpress 向导来查看诸如应力、位移、变形和安全系数等模拟结果。 生成和保存都显示有模拟结果的 eDrawings 文件或 word 文档。 调整模拟中的网格。 运行模拟。 解释模拟的结果。 生成包含结果的 eDrawing 文件或 Microsoft Word 文档。
基于分析结果,将安全系数、最大应力或最大位移值优化为可接受的值。在尺寸范围内更改尺寸以尝试使其满足要求。 如果设计满足或超过安全系数要求,则可以使设计更精简或降低材料成本。 通过优化设计来满足安全系数。 使用内置自动化功能来优化模型。 运行模拟。
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.
Examine the motion of a catapult as it is loaded and throws a projectile. Add solid bodies contact, add a spring and apply friction. Determine torque required to rotate the crank and load the catapult. Determine the displacement of the loading spring. Study the effect of contact friction on the motion of the projectile.
Review the basic functionality of the SOLIDWORKS Dynamics module. Show activation of SOLIDWORKS Simulation Add-In. Review the available modules for specific dynamic load times.
Setup initial dynamic simulation, solve and postprocess the results. Understand the importance of natural frequencies in dynamic simulations. Compare the dynamic and static results. Setup, run and postprocess a basic transient study Calculate a sufficient number of natural frequencies Use the mass participation factor to estimate a sufficient number of natural frequencies Run dynamic simulation for slow and fast forces, and compare their results
Setup, run and postprocess a dynamic simulation with the base motion shock excitation. Understand the optimum mesh design, and get more familiar with the estimation of the minimum number of natural frequencies. Understand the basics of damping. Setup, run and postprocess a transient study Define base excitation shock load Use the mass participation factor to select a sufficient number of natural frequencies Optimize the finite element mesh for dynamic simulation Define structural damping Calculate the maximum time step Use remote mass to simplify the model
Setup, run and postprocess a harmonic simulation. Understand and practice the frequency domain excitation definition. Practice postprocessing results from the harmonic study. Setup, run and postprocess a harmonic study Use the mass participation factor to select a sufficient number of natural frequencies Optimize the finite element mesh for dynamic simulation Define the harmonic load in the frequency domain Postprocess results from the harmonic study
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.