Browsers provide a structured view of model data, which you can use to review, modify, create, and manage
the contents of a model. In addition to visualization, browsers offer features like search, filtering, and sorting,
which enhance your ability to navigate and interact with the model data.
FE geometry is topology on top of mesh, meaning CAD and mesh exist as a single entity. The purpose of FE geometry
is to add vertices, edges, surfaces, and solids on FE models which have no CAD geometry.
Tools and workflows that are dedicated to rapidly creating new parts for specific use cases, or amending existing
parts. The current capabilities are focused on stiffening parts.
Use PhysicsAI to build fast predictive models from CAE data. PhysicsAI can be trained on data with any physics or
remeshing and without design variables.
Explore, organize and manage your personal data, collaborate in teams, and connect to other data sources, such as
corporate PLM systems to access CAD data or publish simulation data.
Create and accelerations by applying a load, representing accelerations, to nodes or
sets.
Configuration 9 - Acceleration loads allow for an
acceleration (length/time2) to be defined on the model.
Accelerations are displayed as a vector with the
letter A at the tail end in the modeling window.
Note: In the Radioss, Abaqus, and LS-DYNA profiles,
load entities are created immediately upon entering the tool. Use the Entity Editor to modify any properties. In all other solver
profiles, load entities aren't created until you make your selections then click
Create.
From the Analyze ribbon, click the Accelerations
tool.
Note: In the OptiStruct,
Nastran, and Abaqus profiles, click the Body
Accelerations tool.
The Accelerations tool is in a tool group with Body Rotational Force
and Body Gravity. Click the arrow to the right of the icon to cycle between
the three.
Select the keyword to create from the Load Type menu.
The available types depend on the current solver interface.
If necessary, choose the entities to which the acceleration will be
applied.
Define the acceleration's direction relative to a local coordinate system or
the default global system.
Specify the magnitude and direction of the acceleration.
Constant Components
Specify the direction and magnitude of the load by entering the X,
Y, and Z values of the components.
Constant Vector
Specify the magnitude, then use the plane and vector tool to specify
the vector along which the load should act.
Curve Components
Specify the X, Y, and Z components to define the direction and
magnitude, for example, (2,2,2) will be twice the magnitude of
(1,1,1). Next, select an existing curve. Last, specify a factor for
the curve’s xscale to use the same curve for many different cases,
but vary the scale of its intensity or time to match the needs of
your current load.
Curve Vector
When working with loads that are time dependent, use this method to
first specify a magnitude (yscale) for the curve. Next, select an
existing curve, then use the plane and vector tool to specify a
direction, if necessary. Last, specify a factor for the curve's
xscale to use the same curve for many different cases, but vary the
scale of its intensity or time to match the needs of your current
moment.