このモジュールでは、要素のサイズによる応力、ひずみや変位への影響を確認して、メッシュ収束の概念を学びます。 グローバル要素サイズの変更が結果にどのように影響するかを学ぶ。 指定の位置にメッシュ コントロールを適用する方法を学ぶ。 シャープ コーナーが応力の集中を生むようすを確認する。

Prepare SOLIDWORKS geometry for Flow Simulation analysis. Create lids manually. Create lids using the Lid Creation tool. Check if the geometry is water tight for internal flow analysis. Detect leaks in improperly sealed geometry.

荷重定義マネージャーを使用して、異なコンフィギュレーションの荷重を結合する方法を学ぶ。 異なる荷重条件の組み合わせが設計にどのように影響するかを知る。 活荷重/死荷重を組み合わせて解析を行う。 荷重を簡単に組み合わせるため方程式を使用する。

Learn about SOLIDWORKS Flow Simulation software. View sample applications from the real world. View sample real world examples where the software was used.

Build the SOLIDWORKS Flow Simulation project. Use Wizard to define Flow Simulation project. Define boundary conditions. Define goals. Mesh the model geometry.

Mesh the Flow Simulation geometry using automated meshing approach. Understand the Basic mesh, and Initial mesh concepts. Control the Global Initial mesh refinement level. Analyze the Minimum Gap Size feature value as the project settings change. Plot mesh on cut plots.

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.

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.

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 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

Run SOLIDWORKS Flow simulation and monitor it. Postprocess Flow simulation results. Launch the SOLIDWORKS Flow simulation and monitor it in the solver window. Monitor execution of the simulation in the solver window. Postprocess results using cut plots, surface plots, flow trajectories. Create 2D graphs from the calculated results, extract results on desired geometrical entities.

Mesh the Flow Simulation geometry using manual meshing approach. Control Basic mesh settings. Apply manual mesh setting and options. Define control planes. Define and apply local mesh controls. Plot mesh on cut plots.

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 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.

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.

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.

このシリーズでは、接触の概念と、ボルトおよびリモート荷重について紹介します。 アセンブリ内の接触を解析する。 コネクタとリモート荷重を使用して表される部品を排除して、モデルを簡略化する。

アセンブリ構造の固有振動を解析するときの接触の使用方法を学びます。 アセンブリ構造の固有振動の形とモードを解析する。 各種の接触条件をテストして、構造の強度を解析する。

このシリーズでは、接触の階層、ピン コネクタ、スプリング コネクタについて扱います。 ピン コネクタに材料を適用して、強度を解析する。 スプリングの張力を表す予荷重を使用してスプリングを作成する。 接触改正を使用して、接触を制御する。
