Engineering Analysis With ANSYS Software
Engineering Analysis With ANSYS Software >>> https://urlca.com/2tD9Er
Digital mission engineering is the use of digital modeling, simulation, and analysis to incorporate the operational environment and evaluate mission outcomes and effectiveness at every phase of the life cycle.
STK's Analyzer capability blends the engineering analysis capabilities of ModelCenter with STK. Explore the design space of your systems with parametric studies, carpet plots, Design of Experiments (DOE) tests, probabilistic analysis, and optimization algorithms.
Join Dr. James Woodburn, Chief Orbital Scientist for Ansys, as he discusses the new ODTK features. Dr. Woodburn specializes in software development focusing on visibility analysis, orbital conjunctions, orbit propagation, and orbit determination. He'll review the new features that extend capabilities in deep space mission planning and execution, surface vehicle positioning, and satellite deployment from a tracked host vehicle.
Ansys Mechanical enables you to solve complex structural engineering problems and make better, faster design decisions. With the finite element analysis (FEA) solvers available in the suite, you can customize and automate solutions for your structural mechanics problems and parameterize them to analyze multiple design scenarios. Ansys Mechanical is a dynamic tool that has a complete range of analysis tools.
Ansys Mechanical is your solution for finite element analysis (FEA) software for structural engineering. From CAD integration to advanced solver technology, Ansys Mechanical can tackle your toughest engineering challenges.
Ansys Mechanical offers a dynamic environment with a complete range of analysis tools, from preparing geometry for analysis to connecting additional physics for even greater fidelity. The intuitive and customizable user interface enables engineers of all levels to get answers fast and with confidence.
Ansys Mechanical creates an integrated platform that uses finite element analysis (FEA) for structural analysis. Mechanical is a dynamic environment that has a complete range of analysis tools, from preparing geometry for analysis to connecting additional physics for even greater fidelity. The intuitive and customizable user interface enables engineers of all levels to get answers fast and with confidence.
Ansys Mechanical covers all your needs for linear dynamic analysis, including modal, harmonic, spectrum response and random vibration with pre-stress, along with advanced solver options for rapid solutions.
You can generate composite models for implicit and explicit structural, thermal and fluid simulations. Ansys Composite PrepPost (ACP) is the Ansys dedicated tool for modeling composite layups and failure analysis. ACP provides efficient layup and best-in-class solid element modeling capabilities and a platform that offers many ways to exchange model information. It supports the vendor-independent HDF5 composite CAE file format for communication with third-party tools, many of them dedicated and related to composites manufacturing. Beyond the modeling of composite structures, Ansys Composite Cure Simulation (ACCS), simulates curing during manufacturing processes. ACCS is an extension for Ansys Mechanical and it helps you to simulate the curing process of a part and predicts residual stresses and process-induced distortions for realizing compensation analyses.
Ansys has teamed up with various software vendors to provide a complete workflow for composite manufacturing, design and analysis. This webinar series focuses on reducing modeling uncertainties when designing with composites.
Ansys Mechanical is a finite element analysis (FEA) software used to perform structural analysis using advanced solver options, including linear dynamics, nonlinearities, thermal analysis, materials, composites, hydrodynamic, explicit, and more. Mechanical offers a user-friendly, dynamic environment with a complete range of analysis tools, from preparing geometry to connecting other physics for high-fidelity simulations and optimization.
Ansys Parametric Design Language, or APDL, is a powerful, structured scripting language used to interact with the Ansys Mechanical solver. Mechanical APDL, or MAPDL, is a finite element analysis program driven by APDL.
Ansys, Inc. is an American multinational company with its headquarters based in Canonsburg, Pennsylvania. It develops and markets CAE/multiphysics engineering simulation software for product design, testing and operation and offers its products and services to customers worldwide.
Ansys was founded in 1970 by John Swanson, who sold his interest in the company to venture capitalists in 1993. Ansys went public on NASDAQ in 1996. In the 2000s, the company acquired other engineering design companies, obtaining additional technology for fluid dynamics, electronics design, and physics analysis. Ansys became a component of the NASDAQ-100 index on December 23, 2019.[2]
The idea for Ansys was first conceived by John Swanson while working at the Westinghouse Astronuclear Laboratory in the 1960s.[3] At the time, engineers performed finite element analysis (FEA) by hand.[3] Westinghouse rejected Swanson's idea to automate FEA by developing general purpose engineering software, so Swanson left the company in 1969 to develop the software on his own.[3] He founded Ansys under the name Swanson Analysis Systems Inc. (SASI) the next year, working out of his farmhouse in Pittsburgh.[4][5]
By 1991 SASI had 153 employees and $29 million in annual revenue,[6] controlling 10 percent of the market for finite element analysis software.[6] According to The Engineering Design Revolution, the company became \"well-respected\" among engineering circles, but remained small.[7]
In November 2020, South China Morning Post reported that Ansys software had been used for Chinese military research in the development of hypersonic missile technology.[11] In October 2022, Washington Post reviewed procurement documents and confirmed that Ansys technology had been acquired by seven Chinese entities present on either the export blacklist or with known links to Chinese missile technology.[12]
Ansys develops and markets engineering simulation software for use across the product life cycle.[8] Ansys Mechanical finite element analysis software is used to simulate computer models of structures, electronics, or machine components for analyzing the strength, toughness, elasticity, temperature distribution, electromagnetism, fluid flow, and other attributes.[8] Ansys is used to determine how a product will function with different specifications, without building test products or conducting crash tests.[6] For example, Ansys software may simulate how a bridge will hold up after years of traffic, how to best process salmon in a cannery to reduce waste, or how to design a slide that uses less material without sacrificing safety.[5]
In 1980, Apple II was released, allowing Ansys to convert to a graphical user interface in version 4 later that year.[45] Version 4 of the Ansys software was easier to use and added features to simulate electromagnetism.[4] In 1989, Ansys began working with Compuflo.[4] Compuflo's Flotran fluid dynamics software was integrated into Ansys by version 5, which was released in 1993.[4] Performance improvements in version 5.1 shortened processing time two to four-fold, and was followed by a series of performance improvements to keep pace with advancements in computing.[7] Ansys also began integrating its software with CAD software, such as Autodesk.[7]
In 1996, Ansys released the DesignSpace structural analysis software, the LS-DYNA crash and drop test simulation product, and the Ansys Computational Fluid Dynamics (CFD) simulator.[13] Ansys also added parallel processing support for PCs with multiple processors.[13] The educational product Ansys/ed was introduced in 1998.[4] Version 6.0 of the main Ansys product was released in December 2001.[4] Version 6.0 made large-scale modeling practical for the first time, but many users were frustrated by a new blue user interface.[4] The interface was redone a few months later in 6.1.[4] Version 8.0 introduced the Ansys multi-field solver, which allows users to simulate how multiple physics problems would interact with one another.[46]
Version 15 of Ansys was released in 2014.[43] It added a new features for composites, bolted connections, and better mesh tools.[43] In February 2015, version 16 introduced the AIM physics engine and Electronics Desktop, which is for semiconductor design.[49] The following year, version 17 introduced a new user interface and performance improvement for computing fluid dynamics problems.[50] In January 2017, Ansys released version 18.[51] Version 18 allowed users to collect real-world data from products and then incorporate that data into future simulations.[51] The Ansys Application Builder, which allows engineers to build, use, and sell custom engineering tools, was also introduced with version 18.[51]
For over four decades, Ansys trainings, on-demand webinars, and whitepapers has helped engineers improve their engineering analysis skills. In addition, acting as a reliable resource for engineers to increase their productive use of Ansys software.
We'll solve textbook examples to understand the fundamental principles of finite-element analysis and computational fluid dynamics. Then we'll apply these principles to simulate real-world examples in the tool including a bolted rocket assembly and a wind turbine rotor.We'll discuss current industry practices with a SpaceX engineer. By working through examples in a leading simulation tool that professionals use, you'll learn to move beyond button pushing and start thinking like an expert.
ANSYS is a general purpose finite element program for engineering analysis. It can solve a wide range of structural, electromagnetic and heat transfer problems, computing the values of displacements, forces, stresses, strains, temperatures and magnetic fields. Analysis types available are: static, eig