1 / 15

DMU: Kinematics Workbench

DMU: Kinematics Workbench. By: Michael Johnson Kyle Pflueger Paul Sowiniski . Overview. Mechanisms Joints Commands Simulations Animate Speeds and Accelerations Data Analysis. Basic Assembly. The following is a simple example of a piston engine In the assembly design workbench:

zan
Download Presentation

DMU: Kinematics Workbench

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. DMU: Kinematics Workbench By: Michael Johnson Kyle Pflueger Paul Sowiniski

  2. Overview • Mechanisms • Joints • Commands • Simulations • Animate • Speeds and Accelerations • Data Analysis

  3. Basic Assembly • The following is a simple example of a piston engine • In the assembly design workbench: • Add basic concentric, planer and surface contact mates

  4. Converting Constraints • While still looking the assembly open the DMU: kinematics workbench • Click the assembly constraint conversion button • Click new Mechanism and name it

  5. Joints • Once the mechanism has been created, go through the joints in the tree and double click on the • joints that need to be defined to limit the DOF’s (degrees of freedom). • One you have double clicked on the particular joints, it will then create a command. • If you are defining a revolute joint, select angle driven in the menu and set the boundaries.

  6. Commands • Now you can select the Simulation button and slide the Commands previously created through their range of movement. • By simply sliding the bars you can determine which Command will drive the simulation. • Also, remember which Command it is, so later it will be easy to define a time based formula.

  7. Simulation • Now you can select the Simulation button and slide the Commands previously created through their range of movement. • By simply sliding the bars you can determine which Command will drive the simulation. • Also, remember which Command it is, so later it will be easy to define a time based formula. • Here is the Mechanism Analysis menu. It will tell you the status of the mechanism and whether enough Commands have been added to fully define it.

  8. Animating • Select the Command which you want to be the focus of the Simulation by either clicking or dragging the slide that corresponds with the Command • Then in the window on the right select insert • The button below the “skip to start” button can be toggled to three different settings • The current setting plays through once and stops at the end • The drop down box on the right allows you to set how quickly the animation plays

  9. Creating a Point • To output the data for a point we must first have a point to track. To create one just double click on a component and define a point.

  10. Speeds and Accelerations • Click on the “Speed and Acceleration” button to access this menu. • Select a stationary part as a “reference product”, in this case the engine block. • Then select the point you wish to track, the point that was just created. • Now click “Simulation with Laws”, the window on the right will appear.

  11. CATIA: Acquiring Data • Placing and activating sensors • Having selected the appropriate mechanism to simulate, click activate sensor in the kinematics simulation player • It is important that once the sensors activated that the appropriate point of analysis is selected • Having activated the sensors and selected the point to analyze the type of data collected must be selected • Makes sure to toggle the Sensors to Yes for in order to activate them

  12. Sensors • Another key step prior to simulation is defining the number of samples desired over the course of the simulation • This is done in the number of samples drop down in the kinematic player • One can either used the predefined numbers in the drop down or manually input the value

  13. Analysis in CATIA • Each line represents a sensor • Here we show the acceleration, speed and displacements • Data can be exported to excel

  14. Processing • Once you check “Activate sensors the window on the left will appear; now you can select which pieces of data you want to output data for • “Graphics” will show you a graph within CATIA, “File” will allow you to export the data to Excel

  15. Conclusion • Now you should be able do run kinematic dialogistic on an assembly in CATIA.

More Related