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.
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.
Le animazioni forniscono una rappresentazione visiva aggiuntiva del modo in cui un assieme può essere assemblato e smontato, e mostrano l'ordine in cui vengono aggiunte le parti. Le animazioni si integrano perfettamente con le viste esplose e aiutano i produttori e gli assemblatori a capire esattamente come si uniscono i componenti. Le animazioni sono anche un ottimo strumento di marketing, poiché possono mostrare le complessità del progetto e il livello di perfezionamento del prodotto finale. In questa lezione verrà creata un'animazione in SOLIDWORKS Composer con l'esplosione di altri componenti in questo assieme.
Informazioni su come utilizzare Discover FloXpress per eseguire un'analisi del flusso dei fluidi al primo passaggio su un modello, utilizzando la fluidodinamica computazionale (CFD). Illustrazione di alcune ipotesi alla base all'utilizzo di FloXpress. Esplorazione dell'interfaccia di FloXpress. Percorso guidato
Come iniziare un instradamento e utilizzare un sottoassieme di percorso per organizzare e memorizzare i componenti di un percorso. Attivazione dell'aggiunta Routing. Individuazione dei menu Condotti, Tubazioni ed Elettrico. Che cos'è un sottoassieme di instradamento. Identificazione dei componenti della libreria di Routing. Uso di Routing Library Manager per caricare le impostazioni.
Scoprite come ottimizzare i design per ridurre il peso del modello variandone le quote. Applicazione di parametri e vincoli per ottimizzare il design in base agli obiettivi prefissati. Come utilizzare gli studi di design con Simulation.
Le viste esplose possono essere create in SOLIDWORKS Composer e sono incredibilmente utili quando si tenta di mostrare tutti i componenti utilizzati in un assieme o per mostrare come assemblare, disassemblare o riparare l'assieme. Le viste esplose possono essere utilizzate anche per altri scopi, come la visualizzazione di un progetto da parte di un team di marketing. In questa lezione, una vista esplosa e i dettagli dei singoli componenti saranno visualizzati aggiungendo etichette a ciascuna parte nell'assieme.
È possibile osservare l'analisi delle sollecitazioni con SimulationXpress per determinare la deformazione della parte sotto l'influenza di un carico (forza o pressione). Ipotesi e limitazioni di SimulationXpress. Esecuzione di un'analisi delle sollecitazioni su una parte.
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.
Esplorate tutti i moduli per scoprire la suite di prodotti SOLIDWORKS Simulation. Analisi del trasferimento del calore e del flusso dei fluidi con SOLIDWORKS Flow. Uso di Sustainability per ridurre l'impatto ambientale dei design realizzati. Analisi di sollecitazione-deformazione tramite SOLIDWORKS Simulation. Analisi della dinamica di un corpo rigido tramite SOLIDWORKS Motion. Visualizzazione delle ripetizioni di riempimento delle parti stampate a iniezione plastica tramite SOLIDWORKS Plastics.
Understand the components of SOLIDWORKS PDM Standard, the role of each component, and how the components interact with each other. These components include: Microsoft® SQL Server® Express. SOLIDWORKS PDM Database Server. SOLIDWORKS PDM Archive Server. The three SOLIDWORKS PDM Client types.
Learn how to a create SOLIDWORKS PDM Standard vault and setup a local client view. Create and configure a SOLIDWORKS PDM Standard vault. Setup a local client view connection to the newly created vault.
Understand how to validate a newly created PDM vault by performing standard PDM operations. Add and share files and folders via the Windows Explorer vault view. Version a SOLIDWORKS part file and transition through a workflow to release.
Understand the steps to perform as complete backup of PDM. Use Microsoft® SQL Server® Management Studio to backup PDM vault databases. Use the SOLIDWORKS PDM Archive Server configuration tool to backup vault user credentials. Locate and backup the vaults file archives.
Understand how to install and configure the components of SOLIDWORKS PDM Standard. Install and configure Microsoft® SQL Server® Express. Install Microsoft® SQL Server® Management Studio. Install the SOLIDWORKS PDM Database Server. Install the SOLIDWORKS PDM Archive Server. Install the SOLIDWORKS PDM CAD Editor client.
Automate the conversion of imported part geometry into a SOLIDWORKS feature-based, parametric model. Open an imported data file in SOLIDWORKS. Use the Import Diagnostics tool to repair imported geometry. View the FeatureWorks options. Use the Automatic feature Recognition Mode. Map the features to the part model. Guide the Automatic Recognition Mode for the best results.
Control the conversion of imported part geometry into a SOLIDWORKS feature-based parametric model by converting specific features interactively. Interactively convert feature types. Convert features types that cannot be used with automated methods. Recognize multiple similar features at the same time. Re-recognize geometry and change it to a different type. Add patterns from the list of recognized features.
