Ansys Fluids provides a comprehensive set of simulation tools for analyzing fluid dynamics, enabling engineers to design and optimize a wide range of fluid systems. From aerodynamics to thermal management, Ansys Fluids offers high-fidelity simulations and advanced solver technologies to tackle complex fluid flow challenges. With a user-friendly interface and robust capabilities, Ansys Fluids helps engineers innovate and optimize designs for improved performance and efficiency.
Choose from a wide range of industry leading RANS, LES & hybrid models. Fluent offers GEKO turbulence model that can be adjusted for different flow regimes with tunable coefficients.
Engineers must account for interactions between liquids, solids and gases for accurate simulations of Industrial applications. Ansys provides accurate models like VOF, Eulerian and DPM models to account for gas-liquid, liquid-liquid, gas-solid, particle flows and even DEM.
Undertake accurate & rapid aeromechanical simulations of rotating components by reducing the geometry to a single passage with Transient Blade Row methods, solve the problems with time marching or harmonic balance methods.
Easily model complex 3D blade geometries with turbo-designer language. Control blade angles & thickness on 2D span-wise layers.
Ice accretion on aircraft surfaces like pitot probes and wings can be calculated while accounting for roughness distributions of glaze, rime or mixed-type ice.
Prevention of damage to products requires efficient packing. Apart from a sustainability perspective, packing is an additional cost. Design, evaluate and test the design’s durability and behaviour with Ansys Polyflow. Take corrective actions with greater insights during the manufacturing phase and create efficient lighter packaging.
Ansys TurboGrid automates mesh generation for complex blade geometries with exceptional quality. Users specify final mesh size, triggering automatic execution for high-quality results. It ensures excellent grid angles, smooth mesh transitions, and efficient resolution of boundary layer flows.
Ansys Fluent provides the opportunity for greater innovation and optimization of product performance. Rely on simulation results from software that has undergone extensive validation across diverse applications. With Ansys Fluent, explore advanced physics models and analyze various fluid phenomena, all within a customizable and intuitive environment.
Renowned for its exceptional robustness, CFX stands as the premier CFD software for turbomachinery applications. Its solver and models are enveloped within a modern, user-friendly, and adaptable GUI, offering extensive customization and automation capabilities through session files, scripting, and a potent expression language. Highly scalable high-performance computing accelerates simulations, encompassing pumps, fans, compressors, and turbines.
Ansys Blademodeler aids in the design of a wide range of rotating machinery. This software for blade design provides comprehensive control over 3D geometry modeling, and it also supports the import of non-bladed equipment from other CAD software, with compatibility across all major CAD vendors.
Ice accretion presents a complex phenomenon that proves exceedingly challenging to replicate through physical testing. However, comprehending and mitigating it is crucial for safety, product performance, and adherence to strict regulations. FENSAP-ICE offers convenience by addressing all major aspects of in-flight icing. With no significant geometric constraints, it finds application across aircraft, rotorcraft, UAVs, jet engines, nacelles, probes, detectors, and other installed systems.
Ansys Polyflow expedites the design process while reducing energy consumption and raw material requirements in manufacturing processes. It aids in the examination of the performance of novel plastics and elastomers. Through virtual prototyping, optimization, and design exploration, Polyflow facilitates waste reduction and minimizes overdesign.
Ansys TurboGrid stands out as top-notch turbomachinery meshing software, boasting innovative automated mesh generation features within an intuitive, streamlined workspace. These versatile tools are applicable across a diverse range of turbomachinery equipment, enhancing the quality of simulation outcomes.
2D through flow simulation represents a crucial phase in the design process of rotating machinery. Vista TF offers rapid solutions, providing valuable insights into your design and uncovering unforeseen issues. Conducting initial design iterations in 2D before transitioning to detailed 3D analysis can significantly diminish development time and alleviate engineering resource burdens.
Ansys EnSight stands as the industry-leading data visualization tool, known for its user-friendly interface. It excels in managing vast simulation datasets across various physics and engineering domains. This software is adept at integrating data from diverse engineering simulations, aiding in the analysis and elucidation of intricate systems and processes.
CHEMKIN-Pro is a used for modeling complex reaction engineering real time problems created by Ansys. It is commonly used for precise chemical kinetics modeling and analysis in the process of combustion, chemical science, and environmental applications. CHEMKIN-Pro includes tools for creating comprehensive chemical kinetic processes, simulating chemical reactions, and examining reaction pathways. Users can import chemical mechanisms from databases such as GRI-Mech, as well as precise mechanisms for specific fuels and reactions, or design their own mechanisms. CHEMKIN-Pro can be used in conjunction with CFD software such as Ansys Fluent to simulate comprehensive combustion with complex chemical kinetics.
Ansys Forte is a specialized computational fluid dynamics (CFD) software tool developed by Ansys, Inc. It is specifically designed for positive simulating displacement compressor internal combustion engine processes, including gasoline, diesel, natural gas, and hydrogen-fueled engines. Ansys Forte offers advanced modeling capabilities to accurately predict engine performance, emissions, and combustion characteristics under various operating conditions. Ansys Forte leverages Ansys Chemkin-Pro solver technology for validation of gas phase and surface chemistry. Users can choose from various combustion models depending on the complexity of the combustion process and the level of detail required. Ansys Forte supports multiphase flow modeling to simulate the complex interactions between fuel spray, air, and combustion products within the engine cylinder. The software includes models for fuel injection, atomization, vaporization, and turbulent mixing of fuel and air.
The Model Fuels Library (MFL) includes detailed and validated reaction mechanisms for over 70 fuel components that are relevant to combustion simulations in a wide variety of industrial and commercial applications. The fuel components can be used to represent gaseous or liquid fuel combustion for petroleum-derived or alternative fuels. Gaseous components include natural gas, synthetic gas, biofuels and blends. For liquid fuels, the fuel components can be used in formulating surrogates for a wide range of real-world fuels, including gasoline, diesel, jet fuel, alternative fuels, fuel blends and additives.
It is specifically designed to address the challenges associated with simulating the behavior of particles and powders in industrial processes such as bulk material handling, mixing, milling, crushing, and granulation. Ansys Rocky offers advanced modeling capabilities to accurately predict particle behavior, particle-particle interactions, and equipment performance under various operating conditions. Ansys Rocky is based on the Discrete Element Method (DEM), which simulates the behavior of individual particles or discrete elements within a bulk material. Users can define particle properties such as size, shape, density, and material properties to accurately represent different types of particles and materials and also an customize equipment geometry, operating conditions, and material properties to simulate specific industrial processes and equipment configurations.
Thermal engineers can build models of small parts and entire systems with Thermal Desktop. Due to its general-purpose nature, it can be used for a wide range of applications, including planetary exploration systems and commercial submarine components. In the 3D design environment of AutoCAD, environment definitions are integrated with objects that are finite difference and finite element. In addition to launching SINDA/FLUINT for the solution and generating the node and conduction network.
