Get the models closer to the finished geometry by learning to modify, remove, combine, slice or replicate the 3D geometries. Use Boolean operations such as Union and Subtract. Reshape the edges of 3D geometries using Fillet Edges or Chamfer Edges with different options. Remove or split the material of 3D geometries using the Slice tool Replicate geometry in multiple instances throughout the design with Mirror 3D and Pattern 3D
此單元涵蓋發佈及使用 3D PDF 及 eDrawing 檔案。 加入自訂屬性和文字欄位。 將零件發佈為 3D PDF 檔案。 將組合件發佈為 3D PDF 及 eDrawing 檔案。 調整 DimXpert 註記的大小,然後再發佈為 3D PDF 檔案。 檢視 3D PDF 及 eDrawing 檔案。
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.
Use Volume features to recognize geometry that does not match any other feature type. The volume feature can be replaced with a standard SOLIDWORKS feature. Recognize volume features. Recognize boss and cut revolve features. Use the Up To Face option with cut extrudes. Replace volume features with standard cut features. Edit the mapped features.
Convert imported sheet metal part geometry into SOLIDWORKS feature-based, sheet metal, parametric models. Recognize common sheet metal features such as Base Flanges and Sketched Bends. Flatten the result to view the flat pattern. Use a hybrid approach combining the automatic and interactive methods.
Convert imported assembly and multibody geometry into SOLIDWORKS feature-based, parametric models. Recognize imported assembly geometry as multiple parts. Use Edit Feature to recognize only selected features from the part. Use child features to recognize multiple features with a single selection.
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.
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.
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.