Dassault Announces ABAQUS for CATIA V5 Version 2.4
Dassault announces the availability of ABAQUS for CATIA V5
Version 2.4 software for finite element analysis (FEA) within the
PLM process. This is the latest release from SIMULIA, the Dassault
Syst¨¨mes brand responsible for developing a unified and
scalable portfolio of realistic simulation solutions.
ABAQUS for CATIA V5 Version 2.4 integrates a broad spectrum of advanced linear and nonlinear FEA capabilities within the CATIA V5 environment. The new version introduces several advanced analysis capabilities, such as dynamic analysis, self-contact, submodeling, and cyclic symmetry, expanding the functional capabilities and benefits for CATIA users. The tight integration between ABAQUS and CATIA V5 allows product design engineers and expert analysts to use the same FEA methods and models, ensuring repeatability and accuracy.
¡°This new version of ABAQUS for CATIA V5 enables our customers to deploy sophisticated FEA methods to the enterprise as proven analysis workflows,¡± says Steve Crowley, director of product management, SIMULIA. ¡°Virtual testing and validation of product performance is accelerated without leaving the CATIA environment. Version 2.4 of ABAQUS for CATIA V5 provides the competitive edge to engineering companies that put a premium on development speed.¡±
ABAQUS for CATIA V5 Version 2.4 builds on the SIMULIA strategy of providing scalable simulation solutions and an open framework for performing multidisciplinary analysis within the PLM process. Global leaders in the automotive and aerospace industries help set the development direction for ABAQUS for CATIA V5 by specifying and evaluating new features.
Version 2.4 offers the following major advancements:
¡ö Dynamic simulation capabilities are based on ABAQUS/Explicit. Explicit dynamic analysis is well suited for large models with relatively short response times and for modeling extremely discontinuous events, such as impact. A new capability enables the definition of very general contact conditions, including contact between many or all regions of the model with a single interaction definition.
¡ö Self-contact modeling simulates surface folding. Self-contact is typically the result of large deformation in a model, such as a complex rubber seal that folds over on itself. It is often difficult to predict which regions will be involved or how they will move relative to each other. A new capability in the software allows users to easily define self-contact for selected surfaces.
¡ö Submodeling targets regions of interest for detailed stress analysis. When analyzing large, complex models such as automotive engines or transmission housings, it is often important to focus on specific, critical areas of the model. A new submodeling tool makes it easy to obtain accurate, detailed solutions in a local region. Users are able to target a region with a refined mesh and apply submodel boundary conditions in both mechanical and thermal steps.
¡ö Cyclic symmetry modeling improves analysis efficiency and reduces model size. Cyclic symmetry modeling is useful for automotive brake disc analysis or turbomachinery simulation. When analyzing a body whose geometry, loads, prescribed conditions, and response are symmetric about an axis of revolution, users no longer need to model the entire body. With cyclic symmetry they can simply model a repeating sector of the body and set fastened pairs to define the sector boundaries. The software simulates the rest of the unmodeled body.
Date: December 11, 2006