R2021x 3D Experience DELMIA Assembly Simulation Engineer

R2021x 3D Experience DELMIA Assembly Simulation Engineer

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Process Simulation Analyst (MAE) enables users to perform product assembly feasibility studies in 3D. The powerful, intuitive capabilities are used to discover potential assembly issues and communicate these discoveries directly to product or tooling designers, process engineer or other stakeholders early, when changes are easier and less expensive.


MAE can directly access any information regarding process plans and 3D layout. Users can leverage this information by generating the motion tracks. This provides the optimizing and validating the global assembly process in the most efficient way.

 Benefits

Determine feasibility early in the design phase 

Companies can perform assembly and disassembly feasibility studies early in the product and process design phase, when making changes are simpler and not as costly. 

 

Determine assembly process validation during detailed process plan definition 

Provides direct access to the operation sequences and product positions defined upstream by process engineers, eliminating the need to set up the initial state of the visualization before the assembly process detailing and validation. It supports configured product and process cases. This allows the manufacturing engineer to check several product and process configurations and fully validate the feasibility of the process 

 

Improve assembly and maintenance process plans quality 

Create and validate the assembly process in the context of the shop floor environment, with the best possible understanding of how it may impact the manufacturing or maintenance process. 

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 What's New

R2021x 

Formerly Process Simulation Analyst, relaunched in 2021x as Assembly Simulation Engineer (same MAE trigram) 

 

R2021x FD01 & FD02 

 

Associate objects to move along with Kinematic Track 

Kinematic Track (of Operation, on Product or Resource) 

  • User can associate object(s) to a component of the mechanism (Resource, Item, Product) on which kinematic Track is defined 
  • During simulation of the kinematic Track, the associated objects are moved according to the motion defined for the mechanism. 

 

Directly raise ENOVIA Issues from MAE 

The command “Issue Management” is now available in all Manufacturing Engineering native applications, such as MAE. The users is able to directly raise an ENOVIA issue and capture all necessary information by pointing as “Context”, “Reported Against” or “Resolved” elements, any Manufacturing object (eg. Manufacturing Item, Workplan, Operation, Resource…). He can also make a screen capture of the current 3D display and annotate it to clearly identify the issue. 

All this will allow leveraging all the value of ENOVIA Issue facilitate the collaboration between all impacted users and finally get an issue resolution much quicker. 

 

R2020x 

 

Launch swept volume computation in background from interactive session 

Computation of Swept Volume of Track is launched in background from the interactive session 

  • User launches computation in background (as a batch on the current or remote machine) through a command. 
  • User continues to work in the session. He will take into account the computed Swept Volume when computation is over. 
  • Batch management panel allows to follow up the computation status. 
  •  Report is provided through html file 

 

Identify impact on Manufacturing Scenario & Tracks after Product Structure change 

Identify and update Track based on moving object on which structure has changed (add/remove/move sub component or Design geometry change) 

  • User identify Manufacturing Scenario and Track impacted by a moving object pointing to Product on which a Design Change was done 
  • Once identified, user can update the impacted Manufacturing Scenario and Track 
 Highlights

Interactively create assembly trajectories 

View and share the product in its assembled state in 3D with other project stakeholders. Using simple, intuitive commands, they can create interference-free product disassembly trajectories and discover potential design-for-assembly issues earlier. Assembly trajectory creation capabilities cover different levels of assembly simulation and validation, including products, manufacturing items and detailed process plan validation. 

 

Easily edit and modify trajectory paths 

Provides simple, intuitive tools that let users edit a part’s trajectory.  They can add, remove, or re-order points along the part’s trajectory path. Through the display of length and angle editors, users can easily control the distance value when creating linear or rotary motion. 

 

Initialize Track Begin position with previous product position 

Initialize the Track Begin point of the Operation Track from a part bin or a position defined by a previous operation. When the part bin position or a previous operation’s end position is changed, the new point position is automatically taken into account in the Operation Track.   

See the product buildup, operation by operation, in the resource context  

Leverage the work of upstream process engineers who have defined the manufacturing assemblies and the associated sequence of operations. To see the product buildup in the context of the selected operation and 3D layout of assigned resources, just select the desired operation from a Gantt chart, the tree, or an operation thumbnail. Get a clear picture of the state of the assembled product in the current context of the resources without the distraction of other product parts. 

 

Define collections for clash detection 

Within PSR, manufacturing engineers can define different collections of part and assemblies to be considered either as moving or contextual group. Between each of these collections, the user can detail specific clearances to be considered during path computation. This will allow the user to fully specify the clash detection conditions without having to use the Manufacturing Simulation model with related scenarios and probes, and simply rely on the PPR Context model. 

 

Define assembly simulation scenarios 

Define and store assembly scenarios. Select trajectories and analyze the simulation. Multiple scenarios can be defined and saved, which helps users perform feasibility studies and evaluate the impact of product and assembly process changes. Users can play the results of a manufacturing scenario in a simulation or validation context without re-computing the simulation. 

Detect interference during simulation 

Provides interference detection during simulation of the assembly process, making it easy to identify where further analysis is needed. Easily modify trajectories or the order of operations to avoid interferences where possible. Users can also communicate seamlessly with product or resource designers to rectify design-for-assembly or design-for-manufacturing issues. 

Create choreographed simulations 

Define simulations of specific activities such as changing part colors, turning the visibility of parts on and off, displaying text and annotations, and modifying the camera position between trajectory moves.  The MAE interface allows process engineers to use a Gantt chart to manage, track, and choreograph parallel and sequential activities. This helps to define process animations suitable for collaborative reviews and presentations. 

Design in simulation context  

During simulation, users can stop and switch to a design application like Part Design or Sketcher, maintain the current transient state, and facilitate design changes in context. This helps them to modify resource designs with respect to geometrical constraints imposed by the 3D simulation context, and validate resources early in the process. 

 

Perform swept-volume analysis during simulation replay 

Generate swept volumes of part trajectories during animation replay. Swept volume results can be updated when a design or assembly path change occurs, eliminating the need for the creation of a new swept volume. Swept volumes are useful when analyzing the space constraints needed to manipulate a part into its assembled position—and to communicate these requirements to part designers and other stakeholders.

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