Alternatives to AM PravaH

Azore is software for computational fluid dynamics. It analyzes fluid flow and heat transfers. CFD allows engineers and scientists to analyze a wide range of fluid mechanics problems, thermal and chemical problems numerically using a computer. Azore can simulate a wide range of fluid dynamics situations, including air, liquids, gases, and particulate-laden flow. Azore is commonly used to model the flow of liquids through a piping or evaluate water velocity profiles around submerged items. Azore can also analyze the flow of gases or air, such as simulating ambient air velocity profiles as they pass around buildings, or investigating the flow, heat transfer, and mechanical equipment inside a room. Azore CFD is able to simulate virtually any incompressible fluid flow model. This includes problems involving conjugate heat transfer, species transport, and steady-state or transient fluid flows.

Enhance engineering processes with the only comprehensive and user-friendly CFD platform designed for multidisciplinary design and optimization. Computational fluid dynamics (CFD) plays a crucial role in multiphysics system analysis, allowing for the simulation of fluid behavior and thermodynamic characteristics through advanced numerical models. Engineers leverage the Cadence Fidelity CFD platform for various design tasks, including propulsion, aerodynamics, hydrodynamics, and combustion, to enhance product efficiency while minimizing the need for costly and time-intensive physical testing. This robust Fidelity CFD platform offers a seamless end-to-end solution tailored for applications across aerospace, automotive, turbomachinery, and marine sectors. With its efficient workflows, massively parallel architecture, and cutting-edge solver technology, the platform delivers remarkable performance and accuracy, significantly boosting engineering productivity in addressing contemporary design challenges. Ultimately, Fidelity stands out by not only simplifying complex processes but also enabling engineers to innovate rapidly and effectively.

Orbital Stack, an AI and CFD web-based program, provides earlier qualitative guidance. It compares a wide range of land-use options and shapes, and highlights any red flags. It allows for climate-conscious, high performance developments that are not possible with traditional studies. Orbital Stack was developed by world-renowned experts in microclimate engineering and wind. It is a game-changer in the architecture and building design industry, providing our clients direct access for wind comfort and safety analysis as well as thermal comfort and shadowing analysis and cladding pressure simulations. This allows architects to quickly understand the climate effects of their proposed building designs and make better decisions, resulting in more resilient and high-performing projects.

Utilize COMSOL's multiphysics software to replicate real-world designs, devices, and processes effectively. This versatile simulation tool is grounded in sophisticated numerical techniques. It boasts comprehensive capabilities for both fully coupled multiphysics and single-physics modeling. Users can navigate a complete modeling workflow, starting from geometry creation all the way to postprocessing. The software provides intuitive tools for the development and deployment of simulation applications. COMSOL Multiphysics® ensures a consistent user interface and experience across various engineering applications and physical phenomena. Additionally, specialized functionality is available through add-on modules that cater to fields such as electromagnetics, structural mechanics, acoustics, fluid dynamics, thermal transfer, and chemical engineering. Users can select from a range of LiveLink™ products to seamlessly connect with CAD systems and other third-party software. Furthermore, applications can be deployed using COMSOL Compiler™ and COMSOL Server™, enabling the creation of physics-driven models and simulation applications within this robust software ecosystem. With such extensive capabilities, it empowers engineers to innovate and enhance their projects effectively.

Dive CAE is a cloud-based software platform designed for computational fluid dynamics that empowers engineers to model intricate fluid dynamics phenomena, including free-surface flows, multiphase interactions, heat transfer, and the dynamics of moving machinery, all through a mesh-free Smoothed Particle Hydrodynamics approach. Accessible directly from a web browser and optimized for high-performance computing systems, it eliminates the need for local hardware or installation processes. This innovative mesh-free method facilitates the modeling of complex geometries, accounts for surface tension, handles non-Newtonian fluids, and addresses transient flow scenarios without the cumbersome meshing and adjustments typical of traditional CFD methods. Users can quickly onboard, usually within a single day, while the software is designed to support parallel design-of-experiment workflows, allowing for numerous iterations to be completed in just hours rather than days. Dive CAE prioritizes collaboration among users, offers a straightforward licensing model (a single license for all), ensures transparent cost management, adheres to data usage governance, and provides scalability through its cloud-based architecture, making it an attractive choice for engineering teams looking to enhance their fluid dynamics simulations. This combination of features not only streamlines the simulation process but also fosters efficient teamwork and innovation in project development.

SimFlow is a desktop Computational Fluid Dynamics analysis software for Windows OS and Linux OS. It is based upon OpenFOAM libraries and acts as an OpenFOAM GUI. It is a professional CAE package that engineers can use to create 3D simulations. SimFlow is a powerful CFD software that can be used for all purposes. SimFlow combines the intuitive graphical user interface of OpenFOAM®, with the benefits of the open-source OpenFOAM®. SimFlow is free to download and you can use it in an evaluation mode to solve some of the most difficult problems that you face as an engineer or scientist. Perhaps you use CFD software every day or just want to get started on your adventure. SimFlow is a powerful fluid simulation software that allows you to rediscover CFD without any time limits.

Renowned for its exceptional durability, CFX stands out as the premier CFD software for turbomachinery applications. Its solvers and models are integrated into a sleek, user-friendly, and adaptable graphical interface that offers extensive options for customization and automation through session files, scripting, and an advanced expression language. The software's highly scalable high-performance computing capabilities significantly accelerate simulations for various equipment, including pumps, fans, compressors, and turbines. Recent advancements in manufacturing techniques have enabled the development of more efficient turbine cooling channel geometries, which, while more intricate, promise enhanced performance and efficiency. In pursuit of precise results, a group of engineers from Purdue University opted for Ansys CFX to conduct their simulations. They executed critical calculations with minimal delay, allowing them to delve deeper into comparative analyses and run additional simulations, which ultimately led to a more thorough optimization of their product. This efficiency not only improved their workflow but also contributed to innovative solutions in turbine design.

Kombyne™ represents a cutting-edge Software as a Service (SaaS) tool designed for high-performance computing (HPC) workflows, originally tailored for clients in sectors such as defense, automotive, aerospace, and academic research. This platform empowers users to access a diverse array of workflow solutions specifically for HPC computational fluid dynamics (CFD) tasks, encompassing features like on-the-fly extract generation, rendering capabilities, and simulation steering options. Users can benefit from interactive monitoring and control functionalities, all while ensuring minimal disruption to simulations and eliminating reliance on VTK. By employing extract workflows, the necessity for handling large files is significantly reduced, allowing for real-time visualization. The system incorporates an in-transit workflow that utilizes a distinct process to swiftly receive data from the solver code, enabling visualization and analysis without hindering the operation of the running solver. This specialized process, referred to as an endpoint, facilitates the direct output of extracts, cutting planes, or point samples useful for data science, in addition to rendering images. Furthermore, the Endpoint serves as a conduit to widely-used visualization software, enhancing the overall usability and integration of the tool within various workflows. With its versatile features and ease of use, Kombyne™ is set to revolutionize the way HPC tasks are managed and executed across multiple industries.

Enhance product development and accelerate the launch process with FLOW-3D, an exceptionally precise CFD software adept at addressing transient, free-surface challenges. Accompanied by our cutting-edge postprocessor, FlowSight, FLOW-3D offers a comprehensive multiphysics suite. This versatile CFD simulation platform empowers engineers to explore the dynamic interactions of liquids and gases across a diverse array of industrial sectors and physical phenomena. With a strong emphasis on multi-phase and free surface applications, FLOW-3D caters to various industries, including microfluidics, biomedical technology, civil water infrastructure, aerospace, consumer goods, additive manufacturing, inkjet printing, laser welding, automotive, offshore enterprises, and energy sectors. As a remarkably effective multiphysics resource, FLOW-3D combines functionality, user-friendliness, and robust capabilities to support engineers in achieving their modeling goals, ultimately driving innovation and efficiency in their projects. By leveraging FLOW-3D, organizations can overcome complex challenges and ensure that their designs are optimized for success in competitive markets.

Adaptive Research is excited to unveil the CAESIM 2024 simulation platform, which is now available for immediate use, featuring enhanced computational fluid dynamics modeling along with multi-physics functionalities. This latest software version introduces innovative tools and features designed to streamline the modeling process, enabling CFD engineers to achieve rapid simulation results with greater efficiency. Additionally, the platform aims to enhance user experience through improved interfaces and capabilities.

Simcenter STAR-CCM+ is an advanced multiphysics computational fluid dynamics (CFD) software that enables the simulation of products in conditions that mimic real-life scenarios. This software stands out by incorporating automated design exploration and optimization into the CFD toolkit accessible to engineers. With a unified platform that encompasses CAD, automated meshing, multiphysics CFD capabilities, and advanced postprocessing, it empowers engineers to thoroughly investigate the entire design landscape, facilitating quicker and more informed design choices. By leveraging the insights offered by Simcenter STAR-CCM+, the design process becomes more strategic, ultimately resulting in innovative products that surpass customer expectations. Enhancing a battery's performance across its complete operating spectrum is a complex endeavor that necessitates the concurrent optimization of various parameters. In this context, Simcenter delivers a comprehensive simulation environment tailored for the analysis and design of electrochemical systems, fostering a deeper understanding of their behavior. This holistic approach allows engineers to tackle intricate challenges with confidence and precision.

Ingrid Cloud is an online tool which automates the entire process for wind simulations. Our computational model requires virtually no human intervention. It is easy to use and accurate. CFD is easy and affordable with us. This unique technology is based upon research at KTH Royal Institute for Technology over the past 15 years.

Simcenter X is a Siemens SaaS simulation solution built to give engineering teams flexible, cloud-based access to advanced multi-domain simulation tools. It combines Simcenter’s established simulation technology with cloud-powered deployment, scalable HPC resources, and collaborative workflows. The platform supports key engineering domains such as CFD, mechanical simulation, systems simulation, and multidisciplinary design analysis and optimization. Simcenter X helps teams break down technical silos by giving users unified access to simulation capabilities and shared data management tools. Its cloud-managed entitlement model allows organizations to manage users, tokens, and simulation resources from a centralized console. Simcenter X Advanced expands this flexibility by providing access to major simulation domains under a single license. Universal tokens allow engineers to run solvers and unlock features across different areas, giving teams more freedom to explore complex studies and new methods. One-click HPC and browser-based CFD access help organizations scale quickly without heavy capital investment in infrastructure. Simcenter X gives engineering, IT, and simulation management teams a faster and more collaborative way to handle modern simulation workloads.

Utilizing the distinctive and inherently dynamic Lattice Boltzmann-based physics, the PowerFLOW CFD solution conducts simulations that effectively replicate real-world scenarios. With the PowerFLOW suite, engineers can assess product performance at the early stages of design, before any prototypes are constructed—this is when alterations can have the most substantial effects on both design and budget. The PowerFLOW system seamlessly imports intricate model geometries and conducts aerodynamic, aeroacoustic, and thermal management simulations with high accuracy and efficiency. By automating domain discretization and turbulence modeling along with wall treatment, it removes the need for manual volume meshing and boundary layer meshing. Users can confidently execute PowerFLOW simulations using a large number of compute cores on widely utilized High Performance Computing (HPC) platforms, enhancing productivity and reliability in the simulation process. This capability not only accelerates product development timelines but also ensures that potential issues are identified and addressed early in the design phase.

Ansys Icepak serves as a computational fluid dynamics (CFD) solver specifically designed for managing thermal issues in electronic devices. It offers insights into airflow, temperature distributions, and heat transfer phenomena within integrated circuit packages, printed circuit boards (PCBs), electronic assemblies, and power electronics. By leveraging the top-tier Ansys Fluent CFD solver, Ansys Icepak delivers robust cooling solutions tailored for electronic components, allowing for thorough thermal and fluid flow evaluations. The software operates through the Ansys Electronics Desktop (AEDT) graphical user interface (GUI), facilitating comprehensive analyses of heat transfer involving conduction, convection, and radiation. Moreover, it boasts sophisticated features for modeling both laminar and turbulent flow conditions, as well as conducting species analysis that incorporates radiation and convection effects. Ansys’ extensive PCB design platform empowers users to perform simulations on PCBs, ICs, and packages, enabling a precise assessment of complete electronic systems, thereby enhancing design efficiency and performance optimization. Thus, Ansys Icepak stands out as an essential tool for engineers aiming to improve thermal management in their electronic designs.

SimScale, a web-based cloud application, plays an important role in simulation software for many industries. The platform supports Computational Fluid Dynamics, Finite Element Analysis (FEA), as well as Thermal Simulation. It also provides 3D simulation, continuous modeling, motion & dynamic modelling.

iGRAF is a comprehensive simulation tool that integrates powder and multiphase flow dynamics, effectively bridging the gap between these two domains. This innovative solution is tailored to accurately replicate a diverse array of powder behaviors while setting new benchmarks in simulation technology. With its advanced DEM-CFD solver, iGRAF provides users with the capability to perform precise analyses of both single-phase and multiphase flows, thereby enhancing the understanding of particle-fluid interactions within a unified platform. The tool's dynamic geometry control features allow for translations, rotations, vibrations, and customizable motion, enabling teams to effectively capture the intricate dynamics of complex systems. Additionally, it incorporates validated models for liquid bridging and van der Waals forces to evaluate the effects of moisture and adhesion on particle behavior, with its liquid bridge force model confirmed for moisture levels of up to 15%. Furthermore, iGRAF employs the Signed Distance Function along with the Immersed Boundary Method to adeptly identify and manage arbitrary solid geometries, ensuring flexibility in various applications. This versatility makes iGRAF an invaluable asset for researchers and engineers working with complex multiphase systems.

MFiX, which stands for Multiphase Flow with Interphase eXchanges, serves as an open-source solver designed for multiphase flow and is recognized as NETL’s primary suite of computational fluid dynamics tools for simulating reacting multiphase flows. It has established itself as a benchmark for the comparison, implementation, and assessment of constitutive models in multiphase flow scenarios and has been utilized across a wide variety of multiphase flow devices and industrial applications. Offering various modeling techniques, MFiX includes the Two-Fluid Model, Discrete Element Model, Coarse-Grained Particle DEM, Superquadric Particle DEM, Glued-Sphere Particle DEM, Particle-in-Cell model, hybrid approaches, and a dedicated single-phase solver tailored for granular flows. These advanced models enable the simulation of numerous systems such as gasifiers, circulating fluidized bed combustors, fluidized beds, fluid catalytic crackers, and chemical looping combustion systems, addressing complex interactions involving hydrodynamics, heat transfer, species transport, and various chemical reactions. As a result, MFiX contributes significantly to the understanding and optimization of these intricate processes in both research and industrial settings.

6SigmaET is a sophisticated tool for thermal modeling in electronics that employs cutting-edge computational fluid dynamics (CFD) to produce precise simulations of electronic devices. Tailored for the electronics sector, our thermal simulation software brings unmatched intelligence, automation, and precision to assist you in fulfilling your requirements and addressing thermal design obstacles. Since its launch in 2009, 6SigmaET has rapidly emerged as the leading thermal simulation software within the electronics cooling industry. Its flexibility enables users to assess the thermal characteristics of a wide array of electronic components, from the tiniest integrated circuits to the largest, most robust servers. You can discover more about the benefits 6SigmaET offers your field by watching our informative videos or reviewing our comprehensive case studies. Additionally, 6SigmaET allows for the seamless import of complete CAD geometry and PCB designs, significantly cutting down the time needed for model creation and enhancing overall efficiency in thermal analysis. This capability streamlines the process, enabling engineers to focus more on optimization rather than on initial setup.

SpectreUQ™ enhances the advanced DAKOTA software created by Sandia National Laboratories by incorporating a user-friendly wizard that assists engineers throughout the uncertainty quantification (UQ) process. The intricate details of the UQ method are managed seamlessly in the background. It employs a database to systematically organize results from both experiments and simulations, along with offering interactive visualization and graphing capabilities. Available through an annual subscription without any limits on the number of users, it also comes in source code format. Unlike many other techniques, SpectreUQ™ operates in a non-intrusive manner, allowing it to run alongside existing simulations rather than integrating directly within them. Users can leverage their own high-performance computing resources to assess numerous flight conditions and develop the built-in surrogate models. It is designed to be intuitive and user-friendly, having been refined through extensive real-world applications in UQ studies. The process of incorporating experimental data and computational fluid dynamics (CFD) results is guided by the Oberkampf-Roy method, ensuring a robust approach. Additionally, the interactive plots generated facilitate easy exploration and sharing of results, enhancing collaboration and communication among engineers. This comprehensive capability makes SpectreUQ™ a valuable tool for any engineer looking to integrate UQ into their workflow.

GASP is a versatile flow solver that handles both structured and unstructured multi-block configurations, effectively addressing the Reynolds Averaged Navier-Stokes (RANS) equations along with the heat conduction equations pertinent to solid structures. It utilizes a hierarchical-tree architecture for its organization, enabling seamless pre- and post-processing within a single interface. Capable of solving both steady and unsteady three-dimensional RANS equations and their various subsets, it employs a multi-block grid topology that accommodates unstructured meshes composed of tetrahedra, hexahedra, prisms, and pyramids. Additionally, it integrates with a portable extensible toolkit designed for scientific computation, which enhances its versatility. The system achieves improved computational efficiency by uncoupling turbulence and chemistry processes. GASP is compatible with a wide array of parallel computing systems, including clusters, and ensures that the integrated domain decomposition remains user-friendly and transparent. Its robust design makes it suitable for a wide range of fluid dynamics applications.

AKL FlowDesigner is an advanced computational fluid dynamics (CFD) software that facilitates wind analysis by allowing users to effortlessly import 3D models of structures or urban blocks created with modeling applications like Autodesk Revit, GRAPHISOFT ARCHICAD, Rhinoceros, and SketchUp. This software supports BIM capabilities in IFC format, making it a valuable tool for architects, designers, engineers, and consultants who can leverage it early in the design phase to comprehend and visualize airflow around their projects. By conducting early analyses, professionals can significantly decrease design time while also making a strong impression on their clients. The CFD simulations offered by AKL FlowDesigner provide substantial advantages in the architecture, engineering, and construction (AEC) sectors. Previously, simulating airflow was a daunting and time-intensive process that necessitated extensive technical expertise; however, with AKL FlowDesigner, users can easily create simulations and analyze airflow within minutes, eliminating the need for an engineering background or intricate calculations. This user-friendly approach opens up the world of CFD to a broader audience, empowering more individuals to enhance their design projects.

Ansys Fluent stands out as the premier fluid simulation software, distinguished by its cutting-edge physics modeling features and unmatched precision. By utilizing Ansys Fluent, you can dedicate more time to innovation and enhancing product efficiency. This software is backed by extensive validation across diverse applications, ensuring you can rely on its simulation outcomes. With Ansys Fluent, creating sophisticated physics models and evaluating various fluid dynamics phenomena is seamless within a user-friendly and customizable interface. This robust simulation tool significantly expedites your design process, allowing for quicker iterations and improvements. Boasting top-tier physics models, Ansys Fluent can effectively and accurately tackle intricate, large-scale simulations. The software unveils new possibilities for computational fluid dynamics (CFD) analysis. Additionally, its rapid pre-processing capabilities and swift solving times empower you to be the quickest in bringing your products to market. Fluent's unmatched features foster boundless innovation while maintaining a steadfast commitment to precision and reliability. Ultimately, Ansys Fluent not only enhances your design capabilities but also positions you ahead of the competition in a fast-paced industry.

Experience the simulation of fluid dynamics, thermal transfer, and fluidic forces that are essential for achieving the desired outcomes of your projects. SOLIDWORKS® Flow Simulation is a user-friendly Computational Fluid Dynamics (CFD) tool integrated within SOLIDWORKS 3D CAD, allowing you to swiftly and effortlessly model the behavior of liquids and gases flowing through and around your designs to assess product efficacy and functionality. The SOLIDWORKS® suite is designed for ease of use, promoting a seamless collaboration that enhances your ability to create products in a more efficient and cost-effective manner. Through SOLIDWORKS Flow Simulation, you and your colleagues can replicate fluid movement, heat distribution, and the associated forces critical for your product's triumph. Organizations of varying sizes require cohesive solutions to foster innovation and advance their operations. By employing integrated CFD capabilities, you can effectively evaluate the impacts of fluid dynamics, thermal exchange, and associated forces on your projects, while also enabling the exploration of multiple "what if" scenarios to facilitate rapid design optimization. This approach not only enhances product quality but also accelerates the overall development process.

Autodesk CFD is a sophisticated software for computational fluid dynamics that allows engineers and analysts to forecast the behavior of liquids and gases with high accuracy. This tool significantly reduces the reliance on physical prototypes while enhancing understanding of fluid flow performance in various designs. It equips engineers with an extensive suite of robust tools aimed at optimizing system designs, managing thermal issues particularly in electronics cooling, and integrating Building Information Modeling (BIM) to improve occupant comfort in HVAC systems within Architecture, Engineering, and Construction (AEC) and Mechanical, Electrical, and Plumbing (MEP) sectors. Furthermore, the Application Programming Interface (API) and scripting capabilities enhance Autodesk CFD's functionalities, enabling customization and automation of routine tasks through the Decision Center. Additionally, the Decision Center streamlines the process of comparing system designs, thereby accelerating decision-making in design processes. This comprehensive approach not only improves efficiency but also empowers engineers to make more informed decisions in their projects.

Part of the TotalSim family, bramble is an online platform for CFD simulations. It can be accessed by any web-enabled computer. It speeds up the pre- and post-simulation process, increasing productivity and creating consistency between simulations. The platform includes customised data management tools and analysis tools as well as CFD and because it uses OpenFOAM, there are no subscription or license charges. Bramble Offers 1. Productivity increases 2. Reliable results 3. Customized data management 4. Simulations that are cost-effective 5. A platform that is easy to use 6. Scalable simulations Bramble also rents and sells the hardware required to run CFD simulations.

Ansys Sherlock stands out as the sole reliability physics-based tool for electronics design that delivers quick and precise life expectancy assessments for electronic components, boards, and systems during the initial design phases. By automating the design analysis process, Ansys Sherlock enables the rapid generation of life predictions, thus eliminating the "test-fail-fix-repeat" cycle that often hampers development. Designers can effectively model the interactions between silicon–metal layers, semiconductor packaging, printed circuit boards (PCBs), and assemblies, allowing for accurate predictions of potential failure risks stemming from thermal, mechanical, and manufacturing stresses, all prior to creating prototypes. Additionally, Sherlock's extensive libraries, which house over 500,000 components, facilitate the seamless transformation of electronic computer-aided design (ECAD) files into computational fluid dynamics (CFD) and finite element analysis (FEA) models. Each of these models is equipped with precise geometries and material properties, ensuring that stress information is accurately conveyed for reliable predictions. This capability not only enhances design efficiency but also significantly reduces the risk of costly errors in the later stages of product development.

CF-MESH+, the latest version of Creative Fields' CFD meshing software, is available. It combines advanced meshing workflows and an easy-to use front-end interface to provide a superior user experience. It has a powerful set tools and functionalities to generate quality CFD meshes for complex geometries. The software is robust, which will allow you to increase your productivity and gain a competitive edge in your simulation efforts.

By utilizing CONSELF, you can harness the power of Computational Fluid Dynamics (CFD) and Finite Element Analysis (FEA) to enhance your product designs: reduce drag and losses related to fluid dynamics, boost efficiency, optimize heat exchange capabilities, assess pressure loads, confirm material strength, analyze deformation in component shapes, compute natural frequencies and modes, among various other functions. The platform offers both static and dynamic simulations for Structural Mechanics, accommodating the behavior of materials under elastic and plastic conditions. Additionally, it enables modal and frequency analyses, starting from widely used CAD neutral file formats, ensuring a seamless integration into your design workflow. This comprehensive approach allows for innovative solutions to complex engineering challenges.

The engineering standard pipe flow software allows you to manage the entire fluid system's lifecycle. Pipe flow analysis software that is industry leading in accuracy, functionality, and usability. No spreadsheets or hidden costs. Must-read for those who manage, design or operate mission critical fluid processing environments. The cornerstone of the digital transformation journey towards Industry 4.0/Digital Twin Operations Management.

ESS has gained significant traction in the automotive sector due to our specialized solutions tailored for this niche market. As our offerings thrived in a highly competitive landscape, ESS expanded into the “on-demand” sector. With the introduction of the alsim cloud, we are accomplishing unprecedented feats in the realm of simulation technology. Our pay-per-use simulation tools are accessible to all users, regardless of their CFD background, allowing students, engineers, and businesses to leverage our advanced techniques to enhance their projects. In addition to our offline products, we cater to diverse industries by providing solutions and detailed reports derived from our simulation outputs. We engage in close collaboration with our clients to understand their specific needs and challenges, ensuring they receive precise simulation results tailored to their requirements. Drawing from our extensive experience with industrial processes and our powerful solvers, we have successfully supported several leading OEMs around the globe. This dedication to customer satisfaction and innovation continues to drive our growth and influence in the industry.

Enhance your decision-making process with Tecplot 360, the ultimate CFD post-processing tool. As more CFD simulations are conducted and grid sizes expand, the necessity for effective handling of large data sets and automated workflows becomes increasingly important. With Tecplot 360, you can reduce idle time and focus on discovering new insights. The software allows for seamless integration of XY, 2D, and 3D plots, giving you the flexibility to design visuals according to your specifications. Present your findings through stunning images and dynamic animations to captivate your audience. Simplify repetitive tasks using PyTecplot Python scripting to enhance productivity. Ensure that you never overlook important results while analyzing parametric data with the powerful Chorus tool. Access vast remote data securely through the SZL-Server client-server connection. Tecplot 360 supports a wide array of data formats including Tecplot, FLUENT, Plot3D, CGNS, OpenFOAM, FVCOM, VTU, and over 22 others related to CFD, FEA, and structural analysis. Additionally, you can efficiently report and compare multiple solutions in a multi-frame setup with various pages, allowing for comprehensive analysis and presentation. The software's versatility makes it an indispensable asset for any data-driven professional.

ParaView is a versatile, open-source application designed for data analysis and visualization across multiple platforms, allowing users to create visual representations for both qualitative and quantitative data analysis. It features interactive 3D exploration capabilities alongside programmatic data processing through its batch processing functionality. Engineered to manage extremely large datasets, ParaView leverages distributed memory computing resources, making it ideal for use on supercomputers that process terascale data as well as on laptops for smaller datasets. The application is built with a client-server architecture, enabling remote visualization of data while generating level-of-detail models to ensure smooth interactive performance even with extensive data. Its extensible framework is grounded in open standards, promoting customization and integration with existing tools and workflows. ParaView supports a wide array of well-known file formats and boasts over 200 filters and tools for effective data processing and visualization. This extensive feature set allows users to tailor their analysis experiences to meet specific needs and enhances collaboration in data-intensive projects.

Stallion 3D rapidly produces aerodynamic performance metrics, including lift, drag, and moments, for both new and existing CAD models. It offers exceptional RANS results without the need for manual grid creation, as the grid generation process within Stallion 3D is entirely automated. This feature effectively removes one of the most time-consuming challenges in computational fluid dynamics (CFD). Utilizing its unique CFD algorithm known as HIST, Stallion 3D accurately forecasts the aerodynamic characteristics of your designs. The software seamlessly imports CAD models and generates the necessary 3D aerodynamic data to validate your designs and support your success. It provides detailed reports on lift and drag forces, as well as yaw, roll, and pitch moments along specified coordinate directions. Additionally, it includes 2D line graphs that illustrate Cp, velocity, Mach number, density, and temperature at constant coordinate locations across the STL surface, allowing users to visualize parameters such as Cp (x) at various span locations along the wing. Overall, Stallion 3D streamlines the aerodynamic analysis process, making it more efficient for designers to achieve optimal performance.

Wind is a challenging element to understand fully. In city landscapes, its dynamics become increasingly intricate due to interactions with structures, leading to various phenomena such as accelerations (Venturi effect), swirling patterns, descending flows, and disruptions. The constructed environment thus generates a localized climate that frequently results in discomfort for individuals. To foster sustainable architecture and urban design, it is vital to analyze these aerodynamic effects and incorporate them early in the planning stages. This analysis is increasingly sought after by developers in numerous nations. Addressing wind dynamics is essential for the effective creation of outdoor public spaces that enhance user comfort. Furthermore, UrbaWind provides a tool for assessing pedestrian wind comfort by aligning with the comfort standards of different regions, ensuring a more livable urban environment. Ultimately, understanding wind behavior is crucial for improving overall urban quality and enhancing the experience of those who inhabit these spaces.

Calculate fluid flow quickly and accurately. The Pipe Flow Calculator will be a valuable tool for engineers, students and professionals who work with fluid dynamics. It solves fluid flow problems, both simple and complex, in under a second. Why Choose Pipe Flow Calculator? Easy to Use: Just enter values to get instant results. Trusted worldwide - used daily by thousands professionals. Reliable and Updated - Bug fixes in 1-2 days. Transparent Calculations: All formulas are provided. Key Features Change between imperial and metric units. Choose pipes, materials and fluids on predefined lists. Export results to Excel & Word. Save, print and continue where you left. Copy/paste the full calculation reports. Available Calculators Pressure Drop, Pump Performance, Pipe Diameter and Reynolds Number Orifice Plates, Venturi Tubes, Nozzles, Prandtl Probe Control Valve, LPG, Thermal Energy

OpenFOAM is a free and open-source computational fluid dynamics (CFD) software that has been developed by OpenCFD Ltd since its inception in 2004. It boasts a vast user community spanning various engineering and scientific fields, including users from both industry and academia. The software offers a comprehensive suite of features capable of addressing a wide array of challenges, such as intricate fluid dynamics involving chemical reactions, turbulence, heat transfer, as well as applications in acoustics, solid mechanics, and electromagnetics. To ensure continuous improvement, OpenFOAM is released biannually, incorporating enhancements funded by users and contributions from the wider community. The software undergoes thorough testing conducted by ESI-OpenCFD's application specialists, development collaborators, and select customers, all supported by ESI's global network and commitment to quality. The assurance of quality is maintained through a stringent testing regime, which entails hundreds of daily unit tests, a moderate set of tests carried out weekly, and an extensive industry-focused test suite. This meticulous approach ensures that OpenFOAM remains reliable and effective for its diverse user base. Moreover, the collaborative nature of its development fosters a vibrant community that continually drives innovation within the software.

VSim is a sophisticated Multiphysics Simulation Software tailored for design engineers and research scientists who seek accurate solutions for complex challenges. Its exceptional integration of Finite-Difference Time-Domain (FDTD), Particle-in-Cell (PIC), and Charged Fluid (Finite Volume) methodologies ensures reliable outcomes across various applications, including plasma modeling. As a parallel software tool, VSim adeptly tackles large-scale problems, with simulations that execute rapidly thanks to algorithms optimized for high-performance computing environments. Renowned by researchers in over 30 countries and utilized by professionals across fields such as aerospace and semiconductor manufacturing, VSim guarantees results with verified accuracy that users can depend on. Developed by a dedicated group of computational scientists, Tech-X’s software has garnered thousands of citations in scientific literature, and VSim is prominently featured in many leading research institutions worldwide. Furthermore, its continued evolution reflects the commitment to meeting the ever-growing demands of modern scientific inquiry.

NAMD is a high-performance parallel molecular dynamics software specifically developed for the simulation of extensive biomolecular systems. Utilizing Charm++ parallel objects, it effectively scales from personal computing devices to advanced parallel systems, accommodating hundreds of cores for standard simulations and exceeding 500,000 cores for the most demanding cases. This software is tailored for researchers aiming to perform efficient simulations of large molecular systems while ensuring integration with commonly utilized molecular modeling workflows. It collaborates with the well-known molecular graphics tool VMD for both simulation setup and trajectory analysis, maintaining compatibility with file formats from AMBER, CHARMM, and X-PLOR. Furthermore, it is engineered to facilitate biomolecular simulations that encompass proteins, membranes, nucleic acids, solvents, ions, and other molecular systems, allowing for an in-depth exploration of atomic interactions and time-dependent movements. Researchers can therefore rely on NAMD to provide comprehensive insights into complex molecular dynamics.

XPS, short for eXtended Particle Simulations, represents an advanced Discrete Element Method simulation tool crafted by RCPE and made available worldwide by InSilicoTrials, specifically tailored for high-precision particle-based process simulations. This software is particularly focused on the pharmaceutical sector, enabling accurate forecasting of powder and granular material behavior, which aids teams in gaining insights, enhancing predictions, and managing pharmaceutical unit operations more effectively. Utilizing sophisticated contact models, XPS characterizes the flow dynamics of granular materials and employs highly parallel algorithms that are fine-tuned for contemporary GPUs, thereby expediting simulations involving as many as 100 million particles. By providing unparalleled detail in process configuration assessments, XPS empowers pharmaceutical engineers to navigate decision-making spaces virtually, significantly curtail the need for expensive and lengthy physical experiments, and bolster data-driven approaches to process development. As a result, this innovative software not only streamlines operations but also fosters a deeper understanding of material behaviors within pharmaceutical manufacturing environments.

Yade is a versatile and open-source framework aimed at discrete numerical modeling, particularly utilizing the Discrete Element Method. The core computational components are developed in C++, leveraging a flexible object model that facilitates the standalone implementation of new algorithms and interfaces. Meanwhile, Python serves as the language for quick and efficient construction of scenes, control of simulations, postprocessing tasks, and debugging processes. This framework is particularly suited for researchers and engineers who require the ability to create, execute, analyze, adjust, and expand particle-based simulations through scripts, interactive commands, graphical interfaces, and reusable simulation elements. Users can construct simulations using specialized generators or directly through Python scripts, offering considerable freedom in developing custom models, importing geometries, reusing code, and managing the entire simulation loop. Each simulation is represented as a scene that encompasses bodies, interactions, and the forces resulting from them, with the bodies characterized by their geometry, material properties, and state variables. Additionally, Yade's architecture promotes collaboration and sharing of advancements within the research community, enabling continuous improvement of simulation techniques.

DigitalClone for Additive Manufacturing (DCAM) is a comprehensive suite of metal additive manufacturing simulation and modeling capabilities that allows for seamless design and analysis support. DC-AM uses a multiscale, multi-physics analysis approach to link the process - microstructure and fatigue relationship of additively produced parts to enable computational assessment for quality and performance. DC-AM encourages the adoption of AM in safety-critical sectors by providing unprecedented insight into build conditions and the characteristics and final parts. This allows for a reduction in time and cost, as well as allowing for a reduction in the time and costs required to qualify parts.

ENCY is a CAD/CAM of a new generation. It combines advanced CAM technologies with an intuitive interface and a natural workflow. It supports multi-axis milling, G-code generation and 2D and 3-dimensional CAD modeling. Core Features - Advanced Toolpath calculation: Customized toolpaths maximize the machine's capabilities and safety - High-Resolution Simulator: Realistic solid-voxel simulations of material removal, collision-checking, additive and painting processes - Seamless Integration with ENCY Clouds and ENCY Tuner Highlights: - Dark theme with a modern interface - A wide range of technological capabilities - Multiaxis Milling and Swiss Turning Additive and hybrid manufacturing - Machine-Aware Technology : toolpath calculations considering the digital twins of the machine Direct toolpath editing - State-of the-art simulation - Postprocessor generator

The industrial application of Metal Additive Manufacturing (AM) presents a fresh set of challenges for numerous enterprises. In the initial stages of integrating AM technology, many companies invest weeks in trial and error to refine their build configurations, leading to inefficiencies and unnecessary expenditures. To mitigate these issues, the software AdditiveLab employs advanced simulation technology that forecasts the results of metal-deposition AM processes, thereby minimizing the need for extensive testing. This innovative tool allows for the rapid identification of areas prone to failure, enabling the optimization of manufacturing setups to boost success rates and ultimately conserve both time and financial resources. Designed with the specific engineering requirements of AM professionals in mind, AdditiveLab eliminates the necessity for in-depth simulation expertise. Its intuitive user interface and automated model preparation streamline the simulation process, allowing users to achieve results with just a few clicks. Furthermore, the integration of AdditiveLab into the AM workflow can significantly enhance overall productivity and efficiency in manufacturing operations.

LAMMPS, which stands for Large-scale Atomic/Molecular Massively Parallel Simulator, is a powerful molecular dynamics software tailored for materials modeling. It has the capability to simulate various particle ensembles across liquid, solid, and gas phases, accommodating a diverse range of systems including atomic, polymeric, biological, solid-state, granular, coarse-grained, mesoscopic, and macroscopic forms by utilizing numerous interatomic potentials, force fields, and boundary conditions. Designed for two or three-dimensional simulations, LAMMPS can handle systems ranging from a handful of particles to billions, ensuring efficient performance on parallel computing architectures while also being user-friendly for modifications and extensions. The software incorporates potentials that cater to solid-state materials like metals and semiconductors, soft matter such as biomolecules and polymers, as well as coarse-grained or mesoscopic systems. Additionally, it serves as a versatile tool for modeling atomic interactions or, more broadly, as a parallel particle simulator applicable across atomic, meso, or continuum scales, making it a valuable resource in computational materials science.