Define an accurate 2D profile or sketch using Geometric and/or Dimensional Constraints. Geometric Constraints create and uphold relationships between sketch entities while Dimensional Constraints specify distances or angles between the sketch entities. Assign Geometric Constraints such as Horizontal, Vertical, Coincident, Perpendicular, Parallel, Tangent, etc. Create Dimensional Constraints with numeric values with labels. Manage Dimensional Constraints for edit, delete and create user-defined parameters.
Manipulate the 3D Model view properly to work on the geometry as intended. Use a variety of tools to enable rotating the model freely, updating the model view type and to add custom coordinates systems to get the right location and angle. View the 3D model at different angles such as Top, Bottom, Left and various isometric angles. Use the computer mouse or orbit command to freely pan, zoom and rotate the 3D model. Learn to view with different view types such as Wireframe, Hidden, Gouraud, Flat with Edges, etc. Setup custom coordinates systems with CCS defining based on a view or entity.
Create some very complex 3D surfaces or geometries by defining a mesh with custom contours and numerous editable points for better control and design. Create basic primitive mesh shapes as a starting point to the design. Generate individual mesh faces using 3D Face tool. Control a network of mesh points by defining an outer perimeter with the Edge Mesh tool to fill it in. Use the 3D Mesh command allowing to define the location of every point in a mesh.
Review a variety of 3D solid modeling tools exclusively for DraftSight Premium. Learn to use some common 3D tools to create simple primitive shapes and complex custom 3D geometries. Create 3D basic geometric forms such as Box, Wedge, Cylinder, Sphere, and Torus. Generate sketch-based or complex 3D shapes using Extrude, Revolve, Sweep, PolySolid, Push and Pull, and Loft.
Setup, run and postprocess a harmonic simulation. Understand and practice the frequency domain excitation definition. Practice postprocessing results from the harmonic study. Setup, run and postprocess a harmonic study Use the mass participation factor to select a sufficient number of natural frequencies Optimize the finite element mesh for dynamic simulation Define the harmonic load in the frequency domain Postprocess results from the harmonic study
Setup, run and postprocess a dynamic simulation with the base motion shock excitation. Understand the optimum mesh design, and get more familiar with the estimation of the minimum number of natural frequencies. Understand the basics of damping. Setup, run and postprocess a transient study Define base excitation shock load Use the mass participation factor to select a sufficient number of natural frequencies Optimize the finite element mesh for dynamic simulation Define structural damping Calculate the maximum time step Use remote mass to simplify the model
Setup initial dynamic simulation, solve and postprocess the results. Understand the importance of natural frequencies in dynamic simulations. Compare the dynamic and static results. Setup, run and postprocess a basic transient study Calculate a sufficient number of natural frequencies Use the mass participation factor to estimate a sufficient number of natural frequencies Run dynamic simulation for slow and fast forces, and compare their results
Review the basic functionality of the SOLIDWORKS Dynamics module. Show activation of SOLIDWORKS Simulation Add-In. Review the available modules for specific dynamic load times.