This means that your modeling workflow remains the same regardless of what you are modeling. The add-on modules and LiveLink™ products connect seamlessly via one integrated software environment. You can use the core package on its own or expand its functionality with any combination of add-on modules for simulating designs and processes based on electromagnetics, structural mechanics, acoustics, fluid flow, heat transfer, and chemical engineering behavior.
Use this tool to make apps accessible to colleagues, partners, or customers worldwide.Multiphysics for IronCAD add-on is a seamlessly integrated multiphysics FEA simulation tool that works directly in the IRONCAD interface. You can run apps using COMSOL Multiphysics® or COMSOL Server™, which is a product for deploying, managing, and running apps that were made with the Application Builder. Powerful, Integrated Multiphysics Promptly verify your design for structural integrity with our integrated multiphysics supporting static stress, thermal, fluid, electrical, dynamics, and much more.The Application Builder in COMSOL Multiphysics® makes it possible for simulation experts to create intuitive and dedicated user interfaces for their otherwise general computer models — ready-to-use custom apps. See all IronCAD tutorials relating to Add-on MultiPhysics.Seamlessly built into IronCAD, MultiPhysics lets you stress test and retest your IronCAD models in a matter of minutes. IronCAD Training and Support Tutorials.
Ironcad Multiphysics Full Functionality Limited
OOFELIE::UI, the parametric graphical user interface2. - Fluid Structure Interaction)The OOFELIE::Multiphysics Suite is composed of three major components:1. Once installed, users have access to the full functionality limited to 2000 mesh nodes that can be used to get started with the analysis application.The OOFELIE::Multiphysics Suite provides you with unique capabilities to analyze industrial applications such as:-Sensors and actuators, including MEMS (Micro-Electro-Mechanical Systems)-Optomechanical systems including MOEMS (Micro-Opto-Electro-Mechanical Systems-Multidisciplinary systems where an interaction exists between a fluid medium and a structure (F.S.I.
MOOSE provides a comprehensive set of finite element support capabilities (libMesh) and provides for mesh adaptation and parallel execution. The physics Kernels are designed to contribute to the nonlinear residual, which is then minimized inside of MOOSE. Inside MOOSE, the Jacobian-Free Newton Krylov (JFNK) method is implemented as a parallel nonlinear solver that naturally supports effective coupling between physics equation systems (or Kernels). The systems are generally represented (modeled) as a system of fully coupled nonlinear partial differential equation systems (an example of a multi-physics system is the thermal feedback effect upon neutronics cross-sections where the cross-sections are a function of the heat transfer). Fully and strongly coupled FEM/BEM/FMM simulations between relevant physical phenomena yield fast convergence and efficient handling of supersized problems.The OOFELIE::Multiphysics Solver combines thermics, mechanics, acoustics, electrics fields and couplings (electrostatics, piezoresitive, vibro-acoustics, piezoelectric, peltier, circuits, FEM fluids, Optics links, MEMS and electromagnetic features in one single CAE environment.MOOSE (Multiphysics Object Oriented Simulation Environment) is an object-oriented C++ finite element framework for the development of tightly coupled multiphysics solvers from Idaho National Laboratory. MOOSE makes use of the PETSc non-linear solver package and libmesh to provide the finite element discretization.MOOSE is a development and run-time environment for the solution of multi-physics systems that involve multiple physical models or multiple simultaneous physical phenomena. OOFELIE::ADX, the solution to explore the design space and optimize your modelThe OOFELIE::Multiphysics Solver is integrated in an engineering standard, intuitive user interface providing time-saving design flow including scripting parameterization and optimization.
Ironcad Multiphysics Free Solution Techniques
ASL can be used to model various coupled physical and chemical phenomena and employed in a multitude of fields: computational fluid dynamics, virtual sensing, industrial process data validation and reconciliation, image-guided surgery, computer-aided engineering, design space exploration, crystallography, etc.LS-DYNA is a general-purpose finite element program capable of simulating complex real world problems. Mesh-free, immersed boundary approach allows one to move from CAD directly to simulation drastically reducing pre-processing efforts and amount of potential errors. The engine is hidden entirely behind simple C++ classes, so that no OpenCL knowledge is required from application programmers. Its computational engine is written in OpenCL and utilizes matrix-free solution techniques which enable extraordinarily high performance, memory efficiency and deployability on a variety of massively parallel architectures, ranging from inexpensive FPGAs, DSPs and GPUs up to heterogeneous clusters and supercomputers.
Typical uses include:-Automotive crash (deformation of chassis, airbag inflation, seatbelt tensioning)-Explosions (underwater Naval mine, shaped charges)LS-DYNA's potential applications are numerous and can be tailored to many fields. The code's origins lie in highly nonlinear, transient dynamic finite element analysis using explicit time integration."Nonlinear" means at least one (and sometimes all) of the following complications:-Changing boundary conditions (such as contact between parts that changes over time)-Large deformations (for example the crumpling of sheet metal parts)-Nonlinear materials that do not exhibit ideally elastic behavior (for example thermoplastic polymers)"Transient dynamic" means analyzing high speed, short duration events where inertial forces are important. LS-DYNA is optimized for shared and distributed memory Unix, Linux, and Windows based, platforms, and it is fully QA'd by LSTC.
All input files are in simple ASCII format and thus can be prepared using any text editor. Therefore all that is required to run LS-DYNA is a command shell, the executable, an input file, and enough free disk space to run the calculation. LS-DYNA is one of the most flexible finite element analysis software packages available.LS-DYNA consists of a single executable file and is entirely command line driven. An example of a simulation, which involves a unique combination of features, is the NASA JPL Mars Pathfinder landing simulation which simulated the space probe's use of airbags to aid in its landing.
These capabilities, developed over many years and fully integrated as core Abaqus functionality, have been used extensively for many engineering applications on products and engineering projects in use today.Multiphysics technology has been a part of Abaqus from the beginning. Furthermore, they have full use of LS-OPT, a standalone design optimization and probabilistic analysis package with an interface to LS-DYNA.The Abaqus Unified FEA product suite has significant capabilities that are used to solve multiphysics problems. Licensees of LS-DYNA automatically have access to all of the program's capabilities, from simple linear static mechanical analysis up to advanced thermal and flow solving methods. LSTC also develops its own preprocessor, LS-PrePost, which is freely distributed and runs without a license.
Elmer comprises of several different parts: The geometry, boundary conditions and physical models are defined in ElmerFront. These are described by partial differential equations which Elmer solves by the Finite Element Method (FEM). It includes physical models of fluid dynamics, structural mechanics, electromagnetics and heat transfer. No additional tools, interfaces, or simulation methodology are needed.Elmer is a computational tool for multi-physics problems. From the same model, same element library, same material data, and same load history, an Abaqus structural FEA model can easily be extended to include additional physics interaction. Through the years additional multiphysics capabilities have been added, such as fluid, thermal, and electrical couplings, to name a few.The advantage of Abaqus Multiphysics is the ease with which Multiphysics problems can be solved by the Abaqus structural FEA user.
The strongest of the components is ElmerSolver which includes many sophisticated features. The different parts of Elmer software may also be used independently. Additionally a utility ElmerGrid may be used for simple mesh manipulation. Finally the results are visualized by ElmerPost.
The solver can also be used in parallel mode on platforms that support MPI.Computational Fluid Dynamics or CFD is a technology that simulates the flow of liquids and gases by performing millions of numerical calculations. The software runs on unix and windows platforms and can be compiled on a large variety of compilers.