Catia Mold Tooling Design Student Version
Increase Competitiveness Through Integrated Mold & Tool Design
The pressure on mold and tool-makers is relentless. Time is always of the essence, and as cycle times reduce, further demands are made. Mold & tool production that took 4 months last year is now demanded in 3 months this year. And so it goes on. Even when a part design is delivered late, the completion target for the mold or tool often remains unchanged
With these ever decreasing design-to-manufacturing cycle times and increasing complexity of the parts to be produced, toolmakers need to maximize the efficiency of the complete mold and tool design process
To do this toolmakers need to be able to:
- Accelerate the design of molds & tools and ensure that that can produce the most complex of parts, reliably and to the required cost and quality targets.
- Simulate, early in the design process, and compensate for the effect of deformation introduced by the manufacturing process such as material shrinkage, warping or spring-back.
- Respond quickly to change requests – whether through late changes to the design of the part to be produced, or the need to address problems found during the manufacturing process itself.
To addresses these challenges, the CATIA Mold & Tool design solution from Dassault Systèmes provides comprehensive and fully integrated capabilities specifically developed to meet the needs of mold and tool designers. These capabilities include the following features:
- Rapid design of molds and tools
- Process specific mold & tool design capabilities such as semi-automatic creation of parting surfaces, mold cores, cavities, runners, lifters and inserts.
- Faster and safer design of complex tool assemblies through 'smart' components and standardized resources that embed custom behavior.
- Advanced simulation & validation: Simulate the part forming process in order to quickly and accurately compensate for material deformation.
- Integrated change management – Quickly identify the impact of a part change on the mold or tool, with full associativity between the part the mold and tool forming surfaces so that design changes can be propagated to the mold & tool designs.
Many leading companies have gained significant competitive advantage through these capabilities, with typical benefits being:
• Improved the whole mold & tool design process time by 70%.
• Achieved time savings of 30% across the initial mold design process.
• Reduced the time for manufacturability analysis from DAYS to hours
• Accelerated mold core & cavity design by 70 %.
Tata Technologies can help you get set up with CATIA Mold and Tooling. Contact us for a demonstration or visit our website www.tatatechnologies.com
In today's post, I would like to focus on Functional Modeling.
Plastic Part
I've always wondered why this workbench never really caught on. Speaking purely from an FM1 trigram standpoint, it comes with the MCE add-on that most people who have PLM Express have added on to their CAC (CAC+MCE).
CAC+MCE
FM1gets you the Functional Modeling Part Workbench.
Functional Modeling Part Workbench
First let's talk about what it was created for, which is plastic parts or parts with draft, because it could also be used for core-cavity type parts like castings. This workbench is very unique in that you do not necessarily model in a particular sequence order like you would in the Part Design workbench. Modeling in the Part Design workbench is what we would call traditional feature modeling, i.e. create a sketch then make a pad, then add some dress up features like draft, fillets, then shell it out, etc.
Feature Based Modeling
There is nothing at all wrong with modeling this way – in fact, it is how most of this work is done today! Now let's look at what we call Functional modeling which looks at a shape and incorporates a behavior for a specific requirement. […]
Today we will continue our series on the hidden intelligence of CATIA V5. It is important to note that I am using a standard Classic HD2 license for this series In my last post, we discussed building a catalog of parts based on a single part that has a spreadsheet that drives the parameters with part numbers. What about features? If CATIA V5 is powerful enough to generate entire parts based on parameters, shouldn't it also be able to be able to generate repetitive features? For instance, take a boss feature that appears on the B-Side of a plastic part. As a leader, I would not be interested in paying my designer his rates to keep repeatedly modeling a feature that may only change slightly throughout the backside! Model smarter: make once, use many times.
To do this successfully, you must address a few things – the first being how it may change. Of course you may not anticipate all changes, but a good rule of thumb is to try to model with maximum flexibility (big slabs for surfaces, overbuild everything, pay close attention to design intent) and do not use B-reps for your design. Avoid creating and building off of features CATIA builds, meaning whenever possible build your own and pick only from the tree to link to them. The second issue to address is – what are going to be the parametric numerical inputs to drive the design? See my first post in this series on how to set these up. i.e. Draft Angle, Wall thickness, Outer Diameter, etc.
Finally, what are going to be the geometric inputsto drive the design? i.e. Location point, Pull Line, Slide Line, Mating Surface, etc. A good rule of thumb here is to limit these features to as few as possible that are needed to get the job done. Sometimes it may be beneficial to sketch all this out on paper before you build it; I suggest gathering input from all the possible parties to help you in your definition.
In the example below, I have constructed a boss. Let's review what I did. […]
This is Part 3 in my series on the hidden intelligence of CATIA V5. To quickly recap what we have already talked about, in my first post I discussed the importance of setting up and using parameters and formulas to capture your design intent and quickly modify things that you know are likely to change. We took those principles a bit farther in my second post and discussed the value of building a design table in those situations when you may have a design with parameters that will vary and that you want to use many times. In that case you could see that we had our rectangular tubing part and could modify its wall thickness, height, and width to make several iterations of basically any size of tubing one would ever need! You would simply keeping doing a Save as… and placing those parts in your working directory to be added into an assembly at some time (I assume).
This methodology would work fine, but today I want to focus on a very cool spin on this theory by building a catalog of your most commonly used parts which are similar enough to be captured in a single model. Using our tubing model, and picking up where we left off, we have a spreadsheet that defines the parameters that change. All we would need to do to build a catalog of each iteration of the design table is add a column to the spreadsheet named PartNumber just as I have it with no spaces in the name and then associate that to the 'Part Number' intrinsic parameter that is created automatically when you being a model.
Let's get started. I will open both the model and the spreadsheet, edit the spreadsheet with the column, and then add in some part numbers.
Part numbers added
When you save the file, the field should appear in CATIA when you click on the Associations tab. […]
This is an exciting post for me! Dassault has just come out with a couple of new bundles that blow the doors off anything I have seen previously.
CATMEE – Mechanical Engineering Excellence
The first package is named CATMEE; this would be the "Mechanical" version of the package. In Classic terms, previously for this purpose I would have recommended an MD2 trigram. In PLM Express bundles, I would have recommended a CAC+MCE bundle to these types of users. They are typically heavy on the mechanical solid modeling portion of CATIA, and do not do very much surfacing. CATMEE is a CAC+MCE on steroids! It includes CAT3DX (which I talked more about in my last post) AND also includes bundles for FPE (Fabricated Product), JTE (Jig and Tool Creation), PRX (Animated Product Review), FTX (3D Master), and TRE (Technical Specifications Review).
CATMEE Package Bundle
I realize that this sounds like a bunch of trigram soup. What does it really mean in CATIA V5? Well from a workbench standpoint, the CAC+MCE add-on looks like this:
CAC+MCE Workbenches
From a workbench standpoint, CATMEE looks like this:
CATMEE Bundle Workbenches
Take a closer look: you get Sheet Metal, 3D GD&T functionality (the good one, FTA!), Mold Tooling, Structure Design, and also DMU! In fact Kinematics, Space Analysis and Fitting Simulation alone can get expensive as an add-on, but here it comes with the bundle. Imagine cutting a section and it actually still being there when you click OK, and being available in the specification tree and updates when you change your part, as well as clearance checks, interference checks, etc. MD2 and/or CAC+MCE users know exactly what I am talking about!
If you are in the market for a new seat or two this year and you are a mechanical customer, you should talk to your account manager and ask about this package; the new configurations not only help your productivity, but also help you expand your capabilities of what kinds of parts and markets you can get into.
CATMSE – Mechanical and Shape Engineering Excellence
This package is where you will really get your bang for the buck! CATMSE is a package we would have previously bundled as either an HD2 (Classic) or CAC+MCE+HDX (PLM Express). It is designed more for the mechanical and surfacing (Hybrid) type of role as a designer. Traditionally CAC+MCE+HDX overall gave you the GSD version of the Generative Shape Design workbench (better sweep functions, laws, etc) as well as a DL1 (Developed Shapes Toolbar in GSD) and a light version of Freestyle workbench (FS1). […]
This is a second look at the hidden intelligence of CATIA V5. Our topic today will focus on the creation and use of design tables. As I talked about in my last blog post, parameters and formulas can be used to drive your design from the specification tree based on your design intent. We will continue on using the rectangular tubing part and build several variations of that tubing that can be driven from a spreadsheet.
Design Table Icon
Most of the work has been already done, and although it is not necessary to have pre-defined parameters and formulas existing, the process is faster. We will begin by again looking at the Knowledge toolbar, this time focusing on the Design Table icon.
When the command is selected, a dialog appears asking for the name of the design table and also gives you a choice on whether or not you want to use a pre existing file or create one from the current parameter values. The differences being whether or not you have an existing spreadsheet filled out already with all the tabulated values of what changes in each iteration of the design.
Design Table Dialog
In our case, to show the functionality we will choose the create with current parameter values option. Once that is decided, you choose which parameters you want to be driven by the spreadsheet. In our case, we had some already created, so we changed the filter to User parameters, chose the values that were NOT driven by formulas (INSIDE and OUTSIDE RADII) and moved them to the inserted side by highlighting and clicking the arrow.
Parameters to Insert
At this point, we have defined that we want a spreadsheet to use columns for Height, Width, and Wall Thickness based on the current values in the model as it is at this moment. When we click OK on the dialog, it will ask us where we want to save the spreadsheet. I suggest that you do this in a place where anyone who uses the model can has at least read access to (i.e. a network drive). Note that I can also change the type of file to a .txt if I do not have access to Excel® or any other software that can edit .xls files.
Read Access Directory
Once this has been defined, your design table is created, linked to your 3D model, and ready to be edited to include your alternate sizes. This is confirmed by the next dialog. To add in the other sizes, simply click on the Edit table… button and your editor (Excel or Notepad) should launch and simply fill in rows with your values.
Linked and ready to edit
Once you have edited and saved the values, you can close that software and CATIA will update based on your values.
Excel Modifications
CATIA Updated
Now you would just pick the value set you want and click OK for the change to appear on the screen.
File Updated
At any time, you can always go to make the changes by finding the Design Table under the Relations section of the specification tree and double-clicking on it.
Design Table under Relations
As you can see, it's pretty easy to create a design table and drive your parametric file with multiple values. The world of CATIA V5 is all about re-use of data and capturing business intelligence we already know exists in all companies. How can we help you? Tata Technologies has helped many companies time and again.
Stay tuned for Part 3!
CATIA has many naming conventions and packaging options. In this post, we'll be looking specifically at CATIA V5, with future posts examining CATIA V6 and 3DEXPERIENCE.
Version 5 began back in the late 90s as a complete re-write of the previous version. As development progressed, new releases were produced. A release indicates enhanced or new functionality over prior releases – however, still on the same version. A collection of bug fixes would be referred to s Service Pack, and specific bug fixes are referred to as a Hot Fix. Putting it all together we would see something like:
V5 R19 SP 9 HF 108
This would translate to:
Version CATIA 5, release 19, service pack 9, hot fix 108
Why is this important? Because many OEMs require their suppliers to deliver designs that specifically match their own.
Classic vs. PLM Express
When looking for a seat of CATIA, you would be looking for what Dassault calls a configuration. Configurations are commonly referred to by their trigram (a character letter acronym) that is specific to the type of design required. For instance, a mechanical designer would be interested in either an "MD1" or "MD2" – "Mechanical Design 1" or "Mechanical Design 2," respectively – depending on level of complexity. We call these configurations Classic.
Later, to support their data management solution, SmarTeam, Dassault came up with new bundles called "CATIA PLM Express." These bundles included licenses for SmarTeam, encouraging use by lowering the cost of entry. This also the first time we see the idea of roles. Rather than bundling functionality by the type of design, in CATIA PLM Express, the bundles are made more intuitive by considering the role of the designer. You could get these bundles, or modules, specific to Manufacturing Engineers, or Layout Engineers. The idea is to gather the modules required by the desired outcome (lathe machined parts, structural steel frames), rather than the methodology (mechanical design). You can build your own PLM Express here.
The next level of bundles are called Enablers. Enablers form the starting point of the role-based package. A designer that needs to produce structural steel frames would start their selection in the "Layout Engineer" group of enablers, and would select the one named "CATIA Structure & Steelwork Layout," or "SSE." A tooling engineer would look at the group "Mechanical Product Engineer," and the enabler of choice would be "CATIA Jigs & Tooling Creation," or "JTE." In the tooling example, the common way of referring to the package is "CAT+JTE."
If enablers start the specialization bundles, the next level called Extensions round out. These bundles are very specific to a role or outcome. Case in point is "CATIA Composites Design," or "CPX." Another example would be "CATIA Electrical Cable Layout," or "ECX" found in the "Layout Engineer" grouping, and could be added to the enabler "CATIA Layout & Annotations," or "LOE." That would create the final package of "CAT+LOE+ECX."
A special note: in order to get access to an extension bundle, an enabler bundle must accompany it. In turn, to access an enabler, you must first start with CAT. Think of them as levels of a house: CAT, the base configuration, would be the first floor. The second floor consists of enablers, and the third floor are enablers. You can't get to the third floor without the second. You can have any combination of enablers and extensions, regardless of the role grouping. So our tooling designer (CAT+JTE), may, for some reason, need access to the Electrical Cable Layout extension (ECX), found in the "Layout Engineer" grouping.
One final note, and this is a biggie.
When an OEM specifies a version level, say V5 R22 SP5 HF 16, they may also prescribe a classic configuration like MD2. This is not gospel. You may use a PLM Express bundle instead; both use the same file formats. They are both V5, and are interchangeable.
This can be extremely confusing, especially for new people just entering the CATIA world, and all these trigrams and bundles can be daunting. Our team can help you determine what you need and put together the bundle that makes the most sense for your situation. Just let us know how we can be of service.
Composites always had a well-defined place in the aerospace industry because of their properties: lightweight to make overall design lighter and toughness to make overall design bear the aero structural loads. At present, from aircraft fairing to train noses, boat hulls and wind turbines, composites offer dramatic opportunities to meet increasing cost-driven market requirements and environmental concerns. However, modeling of composites in a seamless collaborative environment has always been a challenge. This is because of multiple aspects of composites modeling such as design, simulation, and manufacturing that made it quite a tough task on a single platform.
CATIA composites workbench now offers a solution to address various aspects of composites modeling in a unified manner. The objective of this blog post is to provide information on composites workbench capabilities with respect to design, simulation, and manufacturability of composites.
DESIGN IN ANALYSIS CONTEXT
There are different ways to start the preliminary design of a composite part, but the zone-based design is ideal to capture analysis constraints and predict the behavior of the part inside the design environment by importing thickness laws. The thickness laws are calculated as a result of FEA analysis. The composites part design workbench in CATIA provides easy-to-use dedicated zone creation and modification features. Zone-based modeling contributes to significant time savings with the ability to perform concurrent engineering with mating parts. The image below shows a wing panel with a grid created from ribs and spars in assembly context and thickness law for each cell mapped on the grid from a spreadsheet.
Once the grid information is ready, Composites workbench provides highly productive automatic ply generation from zone capabilities with automatic management of the ply staggering and stacking rules. The ability to quickly and automatically transition from zones to plies while keeping full associativity, allows the designer to focus on the design intent and helps dramatically reduce the number of geometrical tasks required to design the part.
To further check the viability of a design from the structural strength perspective, it is possible to perform the FEA simulation within the CATIA environment using the Elifini solver of CATIA analysis. The full associativity with composites workbench is maintained and true fiber angles are taken into account. To address the non-linear aspect of FEA, is it possible to export the plies data in the form of layup files to Abaqus CAE using the composites fiber modeler plug-in. In case design modifications are needed, it is possible to edit and modify any ply or sequence in the composites workbench and instantly export the modified layup file to simulation workbench or Abaqus CAE for validation. Thus designers and analysts can work together in collaboration during the composites development process, saving time, improving product quality, and preventing costly error. […]
Previously, my colleague Mark Van DeBogert touched in an earlier blog post on the business side of CATIA 3D Master. Today, we are going to go a little further into understanding what is available to purchase from the Dassault CATIA V5 product line. As with a lot of Dassault CATIA products, there are two levels of the Functional Tolerancing & Annotation offering. The licenses are FT1 and FTA respectively.
The FT1 license allows you to easily create your 3D annotations, tolerances, and specifications, as it does provide a pretty comprehensive set of dress up features, text and flag note features. 3D Dimensioning can be done in both part and assembly levels. You display and manage your annotations by simply setting up various annotation planes, and you can easily switch a mirrored annotation with the click of a button, as shown below.
The number one and most significant difference between FT1 and FTA is theTolerancing Advisor. The advisor guides the user through the creation of annotations and dimensions according to the selected geometrical element, plus an existing annotation and the selected standard (ANSI, ASME, ISO, etc.) the user is working to. For the novice user, it will usually prevent making gross mistakes; it's pretty much the all-purpose tool for creating annotations, dimensions, and tolerances – it can't necessarily do everything, but it certainly goes a long way. Everything created using the tolerance advisor is what's referred to as Semantic .
In order for something to be Semantic it needs to meet two criteria: […]
In this blog post, we will look into the basics of surface development and gain an understanding of what continuity is. Years ago when I used to teach full time I would tell my students that I called it "continue-ity," the reason being that you are essentially describing how one surface continues or flows into another surface. Technically, you could describe curves and how they flow with one another as well. So let's get started.
G0 or Point Continuity is simply when one surface or curve touches another and they share the same boundary. In the examples below, you can see what this could look like on both curves and surfaces.
G0 Continuity
G0 Curve Continuity
As we progress up the numbers on continuity, keep in mind that the previous number(s) before must exist in order for it to be true. In other words, you cant have G1 continuity unless you at least have G0 continuity. In a sense, it's a prerequisite.G1 or Tangent continuity or Angular continuity implies that two faces/surfaces meet along a common edge and that the tangent plane, at each point along the edge, is equal for both faces/surfaces. They share a common angle; the best example of this is a fillet, or a blend with Tangent Continuity or in some cases a Conic. In the examples below, you can see what this could look like on both curves and surfaces. […]
Catia Mold Tooling Design Student Version
Source: http://blog.myigetit.com/tag/catia/
Posted by: diazfaciabove.blogspot.com
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