Use the Physical Dynamics options when moving components to allow realistic interaction between assembly components. Physical dynamics identifies collisions between faces and allows components to push one another when they come into contact. Understand options within the Move Component command. Use the Physical Dynamics option to simulate interaction between components being moved. Understand the limitations of using Physical Dynamics versus a Motion Study. Learn how to troubleshoot issues when using the physical dynamics option.
Exploded views can be created in assemblies to assist in detailing and visualizing components. Learn how to create an exploded view in an assembly. Use the options within the Exploded View command to explode single and multiple components. Understand the options for exploding sub-assemblies. Automate spacing for multiple components in a chain explode step. Learn how to animate explode steps.
Use the Interference Detection tool to identify any overlap between parts in an assembly. Clearance between parts can also be detected using the Clearance Verification tool. Use the Interference Detection tool to identify interferences between assembly components. Explore the options available within the Interference Detection tool. Use the Clearance Verification tool to identify clearances between assembly components. Explore the options available with the Clearance Verification tool.
Mirror Component creates opposite-hand, but otherwise identical, versions of parts or subassembies. Specify which components are mirrored and which are purely copied (i.e. fasteners, which should not be mirrored). The geometry of a mirrored component changes to create a truly mirrored version, known as an \"opposite-hand\" version. Mirror components about an assembly plane. Create mirrored versions of parts in an assembly. Create opposite-hand versions of parts.
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.
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.
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.
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.
The linear coupler mate links the translation of one component to the translation of another component. The translation occurs along an axis you define relative to the assembly origin or a reference component. Select the faces and reference components to define a linear coupler mate. Set the ratio of motion of one component relative to another.
Constrain a point or a vertex of a component to a path in an assembly. Then, control the pitch, yaw, and roll of the component as it moves along the path. Specify the entities for a path mate. Edit a path mate to control pitch, yaw, and roll of the component.
Center a component relative to two faces of a groove using a width mate. Add a width mate to center a component relative to two faces of another component. Understand the degrees of freedom that are constrained by a width mate.
Define mated entities and mate types for components that you use frequently. When you add the component to the assembly, some mates can automatically be added for you. Define the mate entities and mate types for a frequently used component. Add a component with mate references to an assembly. Select the configuration of a component that you drag into an assembly.
The Belt/Chain assembly feature links idlers, pulleys, or sprockets together to achieve the intended rotation of several components simultaneously. Optionally, you can create a belt or chain component part. Select edges of pulleys and idlers for a belt/chain assembly feature. Set the properties of a belt/chain assembly feature.
The Hole Series feature adds holes to multiple components in an assembly. Unlike a typical assembly feature, the Hole Series adds part-level features to the individual components. Create a Hole Series feature in an assembly. Create a Hole Series feature from an existing hole feature. Understand the difference between the Hole Series feature and a typical assembly feature.
Use both bottom-up and top-down assembly modeling design techniques to insert and modify components in an assembly. Insert components into an assembly using a bottom-up approach. Modify a component using a top-down approach. Create a new component using a top-down approach.
Edit the values of distance, angle, and limit mates. Add distance and angle mates according to the specifications in a drawing table. Edit the values of the distance and angle mates that you create.
Use global variables and equations in assemblies to control dimensions of components or values of mates. Set dimension names. Define global variables. Add equations that link dimension values of one component to values in another component.
Constrain two similar entities (points, edges, faces, etc) to be symmetric about a plane or planar face. A symmetry mate does not force the components to be symmetric, just the entities you select. Understand the acceptable selections for a symmetry mate. Constrain two planar faces to be symmetric about a reference plane.
Use limit mates to restrict the movement of components within a specified range of linear or angular values. Add coincident and limit mates to restrict the degrees of freedom of a component. Set the starting, minimum, and maximum values for a limit mate.
Use multiple mate mode within the Mate command as a shortcut to create many mate relations to one common reference. Create multiple mates to a common reference using multiple mate mode. Toggle alignment of mates. Explore different techniques to edit mate features.
Apply color, material and texture appearances to components, part features, or faces in an assembly. Control how those appearances propagate through the model. Appearances applied at the assembly component level do not affect the individual part file. Apply an appearance to several componets in an assembly. Apply a material appearance and change how it is displayed. Understand the hierarchy of appearance application in an assembly.
Smart Mates can be used to automate mates while adding a component to an assembly as well as for mating existing components. Different mate relations can be created based on the geometry that is specified for the Smart Mate. Automate mates while adding a component to an assembly. Use Smart Mates to mate existing components. Use Smart Mates with circular edges to generate multiple mates simultaneously.
Create display states to control the visibility and display style of components. Display states can be linked to configurations of an assembly. Display states can control hide/show state, display mode, appearance, and transparency of components. Add display states to an assembly. Modify visual properties of components with display states. Explore component selection techniques. Use the display pane. Open an assembly to a specific configuration and display state. Link display states to configurations.
