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.
When the internal cut features of a model are of most importance in a design, one approach is to create solid features that represent the negative space of a part. Once the negative space is complete, the Combine command can be used to subtract the volume from another solid body. Use solid geometry representing the interior space of a manifold to create the negative space of the part. Create a separate solid body surrounding the geometry as the main body of the manifold. Combine the solid bodies in the part using a subtract operation.
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.
Create several types of derived drawing views and understand the unique characteristics of each view type. A derived drawing view is created by referencing an existing drawing view. Create a projected view by folding off an existing drawing view. Project a view normal to a selected edge to create an auxiliary view. Show a portion of a view at an enlarged scale using detail views. Create a drawing view relative to planes or planar faces in the model. Focus on a portion of a drawing view by cropping and hiding the unwanted entities. Shorten an existing drawing view using broken 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.
Create a weldment frame from a series of layout sketches. The weldment environment uses standard weldment profiles to define the type of structural members in the weldment. Members of the same type and size are created in one feature. Create a weldment frame. Insert structural members. Relocate the profile sketch. Change corner treatments.
Understand various software options for creating designs for use with 3D printers. Learn about the different tools that SOLIDWORKS offers to make 3D printing easy. Learn about Augmented Intelligence tools that can help design complicated parts. Learn about products like 3DXpert to assist in printing assemblies. Learn about new 3D printing technology.
Model parts in the context of an assembly, using references to other components to complete the design. The design intent for new parts (sizes of features, placement of components in the assembly, etc.) comes from other components in the assembly. Build a virtual part in the context of an assembly by employing Top-Down assembly modeling techniques. Create features in the assembly context by referencing geometry in mating parts. Understand InPlace mates and external references. Identify external references in the FeatureManager design tree.
Install and use the testing software that you use to take any of the SOLIDWORKS certification exams. Download the Tester Pro Client software. Explore the user interface and critical aspects of the test taking experience.
A structural member profile is a cross-section of a beam, tube, channel, or other structural member type. Sweeping this profile along segments of a layout sketch creates the structural member\'s geometry. There are full collections of profiles and sizes available for download, and it is also possible to create customized profiles. Learn how to access the additional content for standard structural member profile sizes. Create a custom weldment profile by saving a sketch as a Library Feature Part. Use the Structural Member command to create a structural member from a structural member profile. Use the Locate Profile option to choose a sketch point for aligning a structural member.
Structure System is an advanced weldment environment that lets you create and modify structural members of different profiles in a single feature. Add primary members using sketches, points, edges, reference planes, and surfaces. Add secondary members using primary members and reference planes.
The Hole Wizard feature creates standard-sized holes according to ANSI, ISO, and other international standards. Hole type, size, and placement location are input by the user. Create hole wizard holes. Learn the elements and options of a wizard hole. Create multiple holes in the same feature.
Create a pattern of one or more features or bodies in one or two linear directions. Unwanted instances can be left out of the pattern, and spacing and other dimensions may be varied. Create bi-directional linear patterns of existing features. Skip instances in a pattern. Vary parameters of pattern instances.
Create a pattern of one or more features or bodies in one or two circular directions. The circular direction is based on a cylindrical or conical face, a circular or linear edge, centerline or axis. Spacing of instances can be controlled in different ways. Create circular patterns of existing features. Vary spacing and range.
Copy instances of one or more features or bodies by mirroring them across a reference plane or planar face. The resultant copy is reversed, as if seen in a mirror, maintaining symmetry. Create mirror patterns of features and bodies. Control results with geometry pattern option.
Interrogate a part using rollback to understand how it was created. Change the sequence of features and edit features, sketches, and sketch planes. Roll forward through an existing part. Reorder a feature in the FeatureManager design tree. Understand parent/child relationships. Edit sketches and features.
Diagnose and repair issues with sketches including extraneous geometry, dangling dimensions, and dangling relations. Diagnose problems in a part. Repair sketch geometry problems. Repair dangling relations and dimensions. Use the What\'s Wrong dialog. Edit the plane used by a sketch.
Create a sketch driven pattern, table driven pattern, curve driven pattern, and a fill pattern. These patterns allow you to pattern features in non-linear or non-circular directions. Use sketch points to define a sketch driven pattern. Specify coordinates for a table driven pattern. Convert entities to create a sketch for a curve driven pattern. Distribute features within a boundary using a fill pattern.
Review the various end condition options for extruded features. Examine the end conditions defined by distance from the sketch: Blind, Through All, and Midplane. Examine the end conditions defined by existing 3D geometry: Up to Next, Up to Vertex, Up to Surface, Offset from Surface, and Up to Body. Identify geometry differences based on the selected end condition.
