Create a cut list to organize the bodies in a weldment part. Add custom properties to the components of a weldment structure so the propertie appear in the cut list. Similar to a BOM in an assembly, the cut list provides details of the weldment members. Create and edit a cut list. Edit custom properties. Edit the material of the bodies in a weldment part.
Create cuts on both folded and flattened sheet metal parts. Utilize the link to thickness and normal cut options. Convert a part to sheet metal and use a curve pattern to make multiple cuts on a cone. Create cuts on both folded and flattened sheet metal parts. Convert a part to sheet metal. Use a curve pattern to make multiple cuts on a cone. Utilize the link to thickness and normal cut options.
Explore the Miter Flange feature, including sketching the profile, edge selection, and other pertinent options. Create a miter flange. Learn and understand the different options for miter flange.
Explore flat pattern feature options including parameters, corner options, grain direction, and faces to exclude. Create a drawing from a flat pattern, adding dimensions and other annotations. Explore flat pattern options. Create a drawing from a flat pattern.
Use several direct editing techniques for working with imported geometry using surfacing tools. Explore the Delete Face tool, the Delete Hole command, and the Untrim Surface tool. Use the Delete Face tool to remove an unwanted imported geometry feature. Use Delete Hole and Untrim Surface to remove an unwanted imported geometry feature. Convert a surface body into a solid body using the Thicken command.
Use extruded, revolved, and swept surfaces to create geometry. Trim, extend, knit, and thicken the surfaces to finish the thin-walled model. Extrude a sketch to create a surface. Revolve a sketch about an axis to create a surface. Trim a surface using a sketch or another surface as the trim tool. Sweep an open profile along a path to create a surface. Combine multiple surfaces into a single body using knit surfaces. Thicken a surface body to create a solid body.
Learn to create tube drawings with appropriate dimensioning, a bill of materials, and multiple orthographic views and projections. Create a tube drawing from an existing part. Add additional views and a bill of materials to the drawing. Create centerlines and driven dimensions on the additional views of the part.
Create flexible tubing routes between existing components in an assembly. Edit tubing routes to accomodate tubing clips and cylindrical envelopes. Use the Repair Route command and the Re-route Spline option to resolve any errors. Create flexible tube routes. Edit routes using tubing clips and envelopes.
Create piping drawings with orthographic views, bills of materials, detailed views, and annotations by using the piping drawing and standard drawing tools. Add annotations and dimensions to drawings. Create piping drawings. Add bill of materials to drawing.
Make changes to route geometry using 3D sketches. Edit routes by deleting, trimming, and adding sketch geometry. Delete existing fittings and add replacements fittings. Edit existing routes. Delete existing fittings. Add replacement fittings.
Use the Split Route tool to add junction points to existing routes. Create geometry at the J-point to orient an in-line fitting. Use the Split Route tool to add a junction point to an existing route. Create 3D geometry at a junction point. Use 3D geometry to orient an in-line fitting.
Manually create a 3D-sketched route using angled guides, lines, elbows, and the merge command for a case where Auto Route is ineffective. Use angled guides, lines, elbows, and the merge command to create a 3D sketch. Use a 3D sketch to manually create a route.
Create a pipe coupling using the Routing Component Wizard. Create a fitting with the Routing Component Wizard. Select and create C-points and R-points. Use design tables to configure fittings. Save created fittings to the Design Library.
Compare the features of two parts and classify the differences into two categories: unique features that exist in only one part and modified features that exist in both parts. Find differences between the features of similar parts. Classify the features as unique or modified.
Improve system and graphical performance of drawings. Use lightweight models, large assembly mode, detached drawings, and more to reduce the required system resources. Use lightweight models and large assembly mode to improve performance. Open drawings without the model files in memory using detached drawings. Fix assembly interference issues to correct display issues.
Create sheet formats and templates. Sheet formats specify the appearance of the drawing sheet, including sheet size, title block, and more. A drawing template is the starting point for all drawings, including drawing properties, pre-defined views, and more. Understand the difference between a sheet format and a drawing template. Create a custom drawing template. Customize and save a standard sheet format. Insert an OLE object, such as a logo, into the sheet format. Link annotations to custom properties of the drawing or the model referenced by the drawing.
Create basic, aligned, offset, and partial or half-section views, including scope and advanced properties. Add several types of section views to a drawing. Define section view properties. Modify section views.
Insert annotations into existing drawing views, including custom notes, geometric tolerances, and blocks. Create annotations and symbols. Create blocks from geometry and notes. Save a block to a file. Insert a block into a drawing.
Select components according to their position relative to assembly envelopes and hide, suppress, or delete the selected components. Utilize assembly envelopes as reference components that are ignored by bills of materials and mass property calculations. Convert components to assembly envelopes. Select components based on their position relative to an assembly envelope. Hide or show components selected using an assembly envelope.
Create smart components by selecting components and features in a defining assembly. Then, insert smart components into an assembly to add the components and create the features. Create smart components in a defining assembly. Insert smart components into an assembly to create components and features. Select reference faces for the features of a smart component.
Large Design Review mode offers faster performance and enhanced visual features while limiting access to details of constituent parts and subassemblies. Large Design Review mode is ideal for visual presentations, rough measurements, and section views. Open an assembly in Large Design Review mode. Review the available tools and features in Large Design Review mode. Explore the limitations of Large Design Review mode.
Use the Assembly Visualization tool to display, sort, and select components by property. Navigate the assembly visualization pane to sort or group components. Change the color of components to improve visualization in the graphics area. Add custom columns to the assembly visualization pane. Export the information in the assembly visualization pane.
Add each of the six mechanical mate types to control the degrees of freedom of components when designing mechanisms. Mate a cylinder, plane, or point to a series of tangent faces with a cam follower mate. Limit the rotational movement between two components with a hinge mate. Move one component linearly to move another component rotationally with a rack and pinion mate. Add a pitch relation between the rotation of one component and the translation of another with a screw mate. Rotate two components relative to one another with a gear mate or a universal joint mate.
