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.
Learn about SOLIDWORKS Flow Simulation software. View sample applications from the real world. View sample real world examples where the software was used.
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.
Build the SOLIDWORKS Flow Simulation project. Use Wizard to define Flow Simulation project. Define boundary conditions. Define goals. Mesh the model geometry.
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.
SOLIDWORKS Motion is a virtual prototyping tool for engineers and designers interested in understanding the performance of their assemblies. Perform a basic motion analysis using SOLIDWORKS Motion. Simulate the weight of a vehicle on the jack. Determine toque and power required to lift it.
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.
SOLIDWORKS includes a suite of specialized tools for surfacing, sheet metal, weldments, mold design, and routing. This learning path provides a brief introduction to these additional areas of the software.
The Structural Designer role delivers linear static, natural frequency, buckling and steady-state thermal simulation capabilities for fast and efficient product testing experience. In this learning path, you learn how to access the role and the Linear Structural Validation app. You also learn how to perform a linear static analysis on a part and on an assembly.
이 학습 모듈은 DELMIA Shop Floor Machining 앱을 빠르게 설정하고 실행할 수 있도록 설계되었습니다. SOLIDWORKS에서 CAD 데이터 준비부터 DELMIA Shop Floor Machining에서 G 코드 생성에 이르기까지 모든 기본 사항을 다룹니다.
In this learning path, you will learn how to use the platform management tools and the Platform Manager role to setup and configure the 3DEXPERIENCE platform for SOLIDWORKS users. You will create and configure a design environment, review setup and permissions, map properties, configure revisions, and control lifecycle status.
Get familiar with the Structural Designer role and understand the user interface of the Linear Structural Validation app. Learn how to access the Linear Structural Validation app from the 3DEXPEREINCE platform. Learn how to access the Linear Structural Validation app directly from the 3DEXPERIENCE SOLIDWORKS. Understand the key assumptions of the Linear Structural Validation app.
Get familiar with the Structural Designer role and understand the user interface of the Linear Structural Validation app. Learn how to access the Linear Structural Validation app from the 3DEXPEREINCE platform. Learn how to access the Linear Structural Validation app directly from SOLIDWORKS using the Collaborative Designer for SOLIDWORKS role. Understand the key assumptions of the Linear Structural Validation app.
Become familiar with the SOLIDWORKS Electrical product and its user interface. Understand the main elements of SOLIDWORKS Electrical. Get to know the user interface and learn how to customize it. Learn about user rights management. Create an environment archive to backup or share data.