Alternatives to SIMHEAT

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.

Simcenter MAGNET serves as an advanced simulation tool for analyzing electromagnetic fields, enabling users to predict the performance of various components such as motors, generators, sensors, transformers, actuators, and solenoids that involve permanent magnets or coils. By facilitating low-frequency electromagnetic field simulations, Simcenter MAGNET offers comprehensive modeling capabilities that accurately represent the underlying physics of electromagnetic devices. Among its features are the modeling of manufacturing processes, temperature-sensitive material properties, and the intricate behavior of magnetization and de-magnetization, along with vector hysteresis models. The software’s built-in motion solver incorporates a six-degree-of-freedom functionality, which allows for the precise modeling and analysis of complex scenarios such as magnetic levitation and intricate motion dynamics. This advanced capability is bolstered by innovative smart re-meshing technology, ensuring that even the most challenging electromagnetic problems can be effectively addressed. Consequently, Simcenter MAGNET stands out as an essential tool for engineers and designers looking to optimize electromagnetic systems in a range of applications.

Ansys Motor-CAD serves as a specialized tool for the design of electric machines, facilitating rapid multiphysics simulations throughout the entire torque-speed operating range. It allows design engineers to assess various motor configurations and concepts to create designs that maximize performance, efficiency, and compactness. With its four integrated modules—EMag, Therm, Lab, and Mech—Motor-CAD enables quick and iterative multiphysics calculations, significantly reducing the time from initial concept to finalized design. This efficiency in calculations and streamlined data input processes provides users with the opportunity to investigate a broader array of motor topologies and thoroughly evaluate the effects of advanced loss mechanisms in the early phases of electromechanical design. The latest release boasts enhanced capabilities for design optimization, multiphysics analysis, and system modeling tailored specifically for electric motors, ensuring that engineers have the tools they need for cutting-edge development. Ultimately, Motor-CAD's fast multiphysics simulation capabilities across the full torque-speed range empower engineers to innovate and refine electric motor designs with unprecedented efficiency.

Ansys Maxwell serves as a powerful electromagnetic field solver tailored for electric machines, transformers, wireless charging systems, permanent magnet latches, actuators, and various electromechanical devices. It adeptly addresses the challenges of static, frequency-domain, and time-varying electric and magnetic fields. Additionally, Maxwell comes equipped with specialized design interfaces specifically for electric machines and power converters. With the capabilities of Maxwell, users can accurately analyze the nonlinear and transient behaviors of electromechanical components, as well as their impact on drive circuits and control system designs. By utilizing Maxwell’s state-of-the-art electromagnetic field solvers in conjunction with integrated circuit and systems simulation technologies, engineers can gain insights into the performance of electromechanical systems well before any physical prototypes are created. Moreover, Maxwell is recognized for delivering reliable simulations of low-frequency electromagnetic fields pertinent to industrial components, making it a valuable tool in the design and analysis process. This comprehensive approach not only enhances design efficiency but also aids in minimizing potential issues during the development stage.

ColdStream is a cutting-edge cloud-based platform for thermal simulation engineering that streamlines every aspect of your thermal management and cooling design workflow, covering everything from thermal analysis to the creation of thermal designs. With Diabatix's advanced thermal simulation software, your organization can accelerate product development by leveraging the latest technology available. Gain crucial insights into heat transfer, including temperature distribution, heat dissipation, fluid dynamics, thermal resistance, thermal radiation, cooling capacity, and much more. Instead of wasting time searching for the most effective heat sinks to manage the cooling of your electronic devices and products, allow ColdStream to handle the process for you. You can simply upload your geometry, configure the necessary operating conditions for the thermal simulation, and establish your heat sink design goals with just a few clicks, making the process remarkably efficient and user-friendly. This innovative approach not only saves time but also enhances the accuracy and effectiveness of your thermal management solutions.

FORGE® serves as a premier software solution for simulating both hot and cold forming processes, having established itself as the flagship product of Transvalor for nearly 35 years while gaining a global customer base. This software effectively addresses the requirements of companies that manufacture forged components across various industrial domains. Among its standout features is point tracking, which facilitates the identification of cold-shut regions within the component and predicts metal fibering, a critical aspect for ensuring that the forgings exhibit excellent mechanical characteristics. It also employs advanced marking techniques to visualize segregations found at the core of the billet and to pinpoint flow-through anomalies. Furthermore, FORGE® provides forecasts for forging loads, energy consumption, torques, and the power required during each deformation process, enabling users to assess whether the demands on their equipment are acceptable, optimize the distribution of forging loads across different phases, and identify potential issues related to die balancing and deflection. With its comprehensive capabilities, FORGE® empowers manufacturers to enhance their production efficiency and product quality significantly.

ENVI-met is a three-dimensional microclimate simulation tool designed for various purposes, including urban development, architectural design, and enhancing energy efficiency, by taking into account all relevant climate factors rather than focusing on just one. This software can model different climate scenarios, encompassing both daytime and nighttime temperatures, humidity levels, wind speeds, and solar radiation in urban areas. Additionally, it allows for the exploration of how various building materials, like glass and stone, impact the microclimate of their surroundings. By predicting how alterations in urban design influence both the microclimate and the thermal comfort of urban dwellers, ENVI-met serves as a vital resource for cities around the globe. Given the significant challenges posed by climate change, developing healthier and more resilient urban environments has become increasingly important. Therefore, ENVI-met is instrumental in evaluating the potential impacts of new constructions, green spaces, and urban planning initiatives, enabling stakeholders to make well-informed decisions that promote sustainability and improve community well-being. This capability underscores the software's relevance in fostering innovative solutions for contemporary urban challenges.

Subjecting your designs to real-world scenarios can significantly enhance product quality while simultaneously minimizing the costs associated with prototyping and physical testing. The SOLIDWORKS® Simulation suite offers a user-friendly collection of structural analysis tools that employ Finite Element Analysis (FEA) to forecast how a product will behave in actual physical conditions by virtually evaluating CAD models. This comprehensive portfolio is equipped with capabilities for both linear and non-linear static and dynamic analyses. With SOLIDWORKS Simulation Professional, you can refine your designs by assessing mechanical resistance, durability, topology, natural frequencies, as well as examining heat transfer and potential buckling issues. Additionally, it facilitates sequential multi-physics simulations to enhance design accuracy. On the other hand, SOLIDWORKS Simulation Premium allows for an in-depth assessment of designs concerning nonlinear and dynamic responses, dynamic loading conditions, and composite materials. This advanced tier also features three specialized studies: Non-Linear Static, Non-Linear Dynamic, and Linear Dynamics, ensuring a thorough evaluation of your engineering projects. By leveraging these powerful tools, engineers can achieve greater design confidence and innovation.

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.

Energy2D is an interactive multiphysics simulation program grounded in computational physics, designed to model the three primary modes of heat transfer: conduction, convection, and radiation, while also integrating particle dynamics. This software operates efficiently on a wide range of computers, simplifying the process by removing the need for switches between preprocessors, solvers, and postprocessors that are usually necessary for computational fluid dynamics simulations. Users can create "computational experiments" to explore scientific hypotheses or address engineering challenges without the need for intricate mathematical formulations. Additionally, development is ongoing to introduce various energy transformation types and to enhance support for different fluid types. While Energy2D excels in accurately modeling conduction, its representations of convection and radiation are not entirely precise, which means results involving these elements should be regarded as qualitative. Over 40 scientific papers have utilized Energy2D as a valuable research instrument, showcasing its adoption in the academic community. As the program evolves, its capabilities are expected to expand further, potentially offering more comprehensive insights into complex physical interactions.

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.

FEATool Multiphysics – "Physics Simulator Made Easy" – a fully integrated physics simulation, FEA and CFD toolbox. FEATool Multiphysics provides a fully integrated simulation platform that includes a unified user interface for several multi-physics solvers such as OpenFOAM and Computational fluid dynamics (CFD), including SU2 Code and FEniCS. This allows users to model coupled physics phenomena, such as those found in fluid flow and heat transfer, structural, electromagnetics acoustics and chemical engineering applications. FEATool multiphysics is a trusted tool for engineers and researchers in the energy, automotive and semi-conductor industries.

MantiumFlow offers a command line mode that allows users to specify the case location and select their desired template, after which it generates the case and notifies the user of any problems or confirms success. This method is the quickest way to create multiple cases efficiently. Alternatively, the graphical user interface (GUI) enhances the experience by enabling users to navigate through options with ease and view a list of customizable settings. The GUI also has the benefit of displaying imported CAD files, ensuring that all components are correctly positioned. Designed primarily for incompressible external aerodynamics simulations, MantiumFlow produces a report that includes plots illustrating convergence, forces, and various flow field visualizations. Additionally, the software automatically generates the mesh, incorporating a specific level of automated refinement region selection. For geometries that require rotation, users can implement a rotating wall boundary condition on the relevant surfaces for accurate modeling. This combination of features makes MantiumFlow a powerful tool for engineers and researchers in the field.

Inventor® Nastran® is a finite element analysis (FEA) tool integrated within CAD software, enabling engineers and analysts to perform a diverse range of studies using various materials. This software provides comprehensive simulation capabilities that encompass both linear and nonlinear stress analysis, dynamic simulations, and heat transfer assessments. It is exclusively accessible through the Product Design & Manufacturing Collection, which includes a suite of powerful tools designed to enhance workflows within Inventor. In addition to advanced simulation features, this collection also offers 5-axis CAM, nesting tools, and access to software like AutoCAD and Fusion 360, ensuring a holistic approach to product design and manufacturing processes. By utilizing Inventor Nastran, professionals can streamline their analysis and improve their design outcomes significantly.

In industries where the integrity of welded structures is critical, TRANSWELD® provides a cutting-edge and comprehensive solution for predicting potential welding imperfections. This advanced simulation software employs multi-physical models to accurately reflect the actual behavior of metal in both liquid and mushy phases, enabling an in-depth analysis of material transformations. Furthermore, TRANSWELD® facilitates the examination of the microstructure in solid-state assemblies. With this tool, you can ensure that your welded components meet required standards without the need for physical prototypes. Our software is entirely predictive, allowing users to digitally observe welding processes under realistic conditions. For instance, it enables the visualization of the heat source movement during simulations of techniques such as laser welding or arc welding, enhancing understanding and efficiency in the welding process. Such capabilities not only streamline production but also significantly reduce the risk of defects in the final product.

DWSIM is a versatile and free chemical process simulator that adheres to CAPE-OPEN standards, functioning seamlessly on multiple operating systems like Windows, Linux, macOS, Android, and iOS. Its user-friendly graphical interface allows for features that were once only available in paid software. The simulator excels in both steady-state and dynamic modeling by employing a parallel modular solver for enhanced efficiency. Additionally, DWSIM comes equipped with sophisticated property packages. Users can access an extensive array of unit operations, such as mixers, splitters, separators, pumps, compressors, expanders, heaters, coolers, valves, pipe segments, shortcut columns, heat exchangers, a variety of reactors, distillation and absorption columns, solids separators, and cake filters, alongside spreadsheets, Python scripts, and flowsheet unit operations. Furthermore, it includes an Excel Add-In for executing thermodynamic calculations directly within spreadsheets, as well as an automation API that facilitates the creation, modification, execution, and saving of flowsheets, making it an all-encompassing tool for chemical engineering. With its robust capabilities and user-centric design, DWSIM stands out as an invaluable resource for professionals in the field.

Metariver Technology Co., Ltd. develops innovative and creative computer-aided engineering (CAE) analysis S/W based upon the most recent HPC technology and S/W technologies including CUDA technology. We are changing the paradigm in CAE technology by using particle-based CAE technology, high-speed computation technology with GPUs, and CAE analysis software. Here is an introduction to our products. 1. Samadii-DEM: works with discrete element method and solid particles. 2. Samadii-SCIV (Statistical Contact In Vacuum): working with high vacuum system gas-flow simulation. 3. Samadii-EM (Electromagnetics) : For full-field interpretation 4. Samadii-Plasma: For Analysis of ion and electron behavior in an electromagnetic field. 5. Vampire (Virtual Additive Manufacturing System): Specializes in transient heat transfer analysis.

MuSES achieves unparalleled accuracy in electro-optic and infrared renderings through a systematic process that starts with the identification of heat sources like engines, exhaust systems, bearings, and electronic components, followed by a comprehensive in-band diffuse radiosity solution. After establishing your sensor at a specified range, you can render multi-bounce radiance values that have been spectrally summed, utilizing DeltaT-RSS contrast metrics for detailed analysis. If you have a sensor response curve available, simply import it to uncover insights you may have overlooked. With MuSES, you can explore reality in unprecedented detail. The software’s capability extends to comprehensively address physics from heat sources to environmental influences, enabling you to effectively manage thermal signature contrasts and assess control kits essential for low observable design in any geographical context. You can rigorously evaluate heat shields, cooling methods, and camouflage surface treatments for in-band radiance while accounting for atmospheric attenuation along the sensor’s line-of-sight. By prioritizing engineering tasks with MuSES early in your project development cycle, you empower your team to make informed decisions that enhance overall design effectiveness. This foresight can significantly streamline the development process and improve project outcomes.

EMWorks offers top-tier electromagnetic simulation software designed for electrical and electronics engineering, incorporating multiphysics features. Their solutions are fully integrated into SOLIDWORKS and Autodesk Inventor®, catering to a wide range of applications such as electromechanical systems, power electronics, antennas, RF and microwave components, as well as ensuring power and signal integrity in high-speed interconnects. One of their flagship products, EMS, serves as a powerful tool for simulating and optimizing electromagnetic and electromechanical devices like transformers, electric motors, actuators, and sensors within the SOLIDWORKS® and Autodesk® Inventor® environments. Additionally, EMWorks2D is a specialized 2D electromagnetic simulation software that focuses on planar and axis-symmetric geometries, also fully embedded in SOLIDWORKS, allowing users to perform quick simulations prior to transitioning to 3D models. This functionality not only enhances the design process but also accelerates overall product development, making it easier for engineers to refine their designs efficiently. By leveraging these advanced tools, users can achieve optimal performance in their electronic designs while saving valuable time in the engineering workflow.

VPS-MICRO estimates the lifespan of manufactured components by modeling the characteristics of their constituent materials. This innovative software is founded on three fundamental principles. First, durability is influenced not just by the stress applied but also by how the material responds to that stress. Second, the materials used in creating intricate components and systems often exhibit non-uniform properties. Lastly, computational resources are more cost-effective and quicker compared to traditional physical testing or prototyping methods. Building upon these concepts, VEXTEC’s VPS-MICRO® serves as a sophisticated computational tool that effectively considers a material’s response to imposed stress, its inherent variability, various damage mechanisms, geometric factors, and the operational conditions over time. Consequently, it produces a three-dimensional, time-sensitive simulation that reliably mirrors the real-world physics behind the onset, progression, and reasons for material damage, offering valuable insights for engineers and designers alike. This capability not only enhances understanding but also aids in improving the design and reliability of future products.

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.

As power systems continue to advance, there is an increasing demand for precise and user-friendly simulation tools. PSCAD enables users to effortlessly design, simulate, and model their systems, unlocking endless opportunities for power system simulation. The software features an extensive library that includes a variety of system models, from basic passive components and control functions to intricate electric machines and other sophisticated devices. With over four decades of dedicated research and development, PSCAD has evolved significantly. The insights and suggestions from our worldwide user community have been a driving force behind this progress. This approach has solidified PSCAD's reputation as the leading choice for power system transient simulation available in the market today. Maintaining your software is the most economically sound method to safeguard, support, and enhance your investment, ensuring you derive maximum value from your tools. Additionally, regular updates and support help users stay abreast of the latest advancements and features, further enhancing their simulation experience.

ProModel serves as a sophisticated tool for discrete event simulation and predictive analytics, offering valuable insights for navigating intricate decision-making processes. By utilizing ProModel AI simulation software, you can enhance your system's efficiency while simultaneously mitigating risks. Our solutions, driven by data, cater to industries that demand meticulous planning and forecasting to maintain seamless, effective, and optimal operations. Understanding the implications of operational changes on production and scheduling is critical for both current and future scenarios. Our AI simulation software empowers organizations to create, simulate, and refine factory layouts using a digital twin, quickly project patient counts and bed availability, identify and avert operational bottlenecks, and improve capacity planning and scheduling to facilitate smoother production workflows. With dynamic simulation models, you can achieve superior process management and utilize visual insights to pinpoint the origins and reasons behind bottlenecks, ultimately leading to more informed decision-making and enhanced operational efficiency.

Explore a versatile, scalable, and modular virtual driving simulator that facilitates testing across diverse objectives and performance metrics. The Ansys VRXPERIENCE Driving Simulator, powered by SCANeR™, allows users to create scenarios, evaluate software, analyze vehicle dynamics, and engage with sensors all within a virtual driving framework. This simulator provides a complete virtual driving laboratory for scrutinizing performance outcomes. The VRXPERIENCE Driving Simulator delivers an engaging simulated driving experience situated in a realistic environment. Conduct thorough safety evaluations that enable the simulation of millions of virtual miles in just a few days, significantly accelerating development by a factor of 1,000 when compared to traditional road testing methods. As the landscape of passenger vehicles evolves to become increasingly digital and autonomous, the demand for an array of advanced technologies, including various sensors like cameras, radar, and lidar, as well as sophisticated embedded software for automated control systems, continues to grow. This advancement underscores the necessity for innovative tools in vehicle development and testing.

Fusion 360 seamlessly integrates design, engineering, electronics, and manufacturing into one cohesive software environment. It offers a comprehensive suite that combines CAD, CAM, CAE, and PCB capabilities within a single development platform. Additionally, users benefit from features like EAGLE Premium, HSMWorks, Team Participant, and various cloud-based services, including generative design and cloud simulation. With an extensive range of modeling tools, engineers can effectively design products while ensuring their form, fit, and function through multiple analysis techniques. Users can create and modify sketches using constraints, dimensions, and advanced sketching tools. It also allows for editing or fixing imported geometry from other file formats with ease. Design modifications can be made without concern for time-dependent features, enabling flexibility in the workflow. Furthermore, the software supports the creation of intricate parametric surfaces for tasks such as repairing or designing geometry, while history-based features like extrude, revolve, loft, and sweep dynamically adapt to any design alterations made. This versatility makes Fusion 360 an essential tool for modern engineering practices.

Utilizing a local density map, REM3D® delivers dependable predictions regarding the resistance of components along with their insulating, noise, and comfort characteristics. By simulating a ‘dual foam’ pouring process, one can observe the transitional areas between foams with varying rigidities. Incorporating "mold tilting" into the simulation replicates realistic process conditions, ensuring they are as accurate as possible. The inclusion of features like automatic mold tilting and the influence of gravity on melt flow enables an analysis of genuine process conditions, thereby ensuring uniformity in your components. Additionally, investigating the placement of injectors minimizes the occurrence of defects. Consequently, you gain trustworthy forecasts related to not only the durability of your components but also their insulating and comfort attributes. For fiber-reinforced plastics, REM3D® also assesses the orientation of the fibers throughout the filling phase and after the cooling process has completed. This comprehensive analysis enhances the overall quality of the final products.

DIGIMU® creates digital polycrystalline microstructures that accurately reflect the material's heterogeneities, ensuring compliance with the intricate topological features of the microstructure. The boundary conditions applied to the Representative Elementary Volume (REV) mimic the experiences of a material point at the macroscopic level, particularly during the thermomechanical cycles relevant to that specific point. Utilizing a Finite Element formulation, the software simulates the various physical phenomena occurring in metal forming processes, such as recrystallization, grain growth, and Zener pinning caused by second phase particles. To enhance digital accuracy and minimize computation times, DIGIMU® employs advanced automated anisotropic meshing and remeshing adaptation technology, which allows for a detailed representation of grain boundaries while optimizing the number of elements used. This innovative approach not only streamlines the computational process but also improves the reliability of the simulations, making it a powerful tool for material scientists.

AVEVA PRO/II™ Simulation serves as a steady-state simulator that enhances plant efficiency by refining process design, conducting operational analyses, and executing engineering studies. By offering a comprehensive approach to optimization, AVEVA PRO/II Simulation focuses on enhancing plant performance through the improvement of process design and operational analysis while also conducting in-depth engineering studies. Capable of performing complex heat and material balance calculations for an extensive array of chemical processes, this simulation tool presents a diverse selection of thermodynamic models applicable across multiple industries. It allows users to devise new processes and assess alternative plant configurations to achieve the most economical operations. Now accessible via the cloud, AVEVA PRO/II Simulation provides on-demand availability, straightforward maintenance, and adaptable usage options. Additionally, users can benefit from a highly experienced support team with over 15 years in the field, ensuring assistance whenever needed. Overall, AVEVA PRO/II Simulation stands out as a robust solution for optimizing plant performance, streamlining design processes, and enhancing operational efficiency.

Electromagnetic sensors are composed of two main components: a "front-end" that both generates and detects electromagnetic waves via a subsystem known as the Receiver/Exciter (REX), and a "back-end" responsible for signal and data processing, which is generally carried out through software. Each of these subsystems must be developed independently before they can be seamlessly integrated. The process of creating the complete sensor becomes increasingly complex and time-consuming due to unforeseen challenges that arise during integration testing. This complexity largely stems from the interdependencies between the subsystems that are not easily testable during their individual development phases. As a result, any necessary software updates, configuration adjustments, waveform modifications, and technology upgrades can incur significantly higher costs since they often require on-site verification with the actual front-end hardware. To mitigate these issues, the Virtual Receiver/Exciter (VREX) utilizes a simulated front-end, thus streamlining the testing and integration process. By employing a virtual model, developers can identify and address potential integration issues much earlier in the development cycle.

The sixth-generation DYNAFORM Die Simulation Software presents an advanced platform that boasts a user-friendly and visually appealing interface designed for ease of use. Focused on the stamping process, this software minimizes the need for extensive CAE expertise and simplifies geometry and element tasks. Among its notable enhancements, users will find a well-structured tree management system for operations, a dedicated simulation data manager, and customizable icon groupings for quick access to drop-down menu features. Additionally, it offers distinct applications that operate independently, integrated pre- and post-processing capabilities, a multi-window view for better analysis, and the convenience of accessing functions with right-click options. Supporting large-scale forming simulations, the software includes a geometry management tool, a process wizard for optimizing blank sizes, a comprehensive material library, new draw bead shapes, and an efficient coordinate system manager. The combination of these features enhances the overall simulation experience, making it a powerful tool for engineers and designers alike.

CADSIM Plus is an innovative software designed for chemical process simulation, integrating a dynamic simulator based on first principles with a comprehensive Computer Assisted Drawing (CAD) interface all in one solution. It excels in conducting accurate heat and material balances across various chemical processes and is capable of creating intricate dynamic simulations that incorporate control logic and batch operations. The software is equipped with an extensive array of generic process modules and provides optional libraries tailored for diverse applications. CADSIM Plus accommodates a broad spectrum of drawing complexities, ranging from straightforward block diagrams to intricate engineering schematics, and facilitates the export of designs to AutoCAD and other conventional CAD software. With its 'electronic flowsheet' runtime simulation mode, users are provided with interactive and animated tools for simulation, allowing real-time adjustments to process conditions during operation. This versatile software finds applications in process design, troubleshooting, forecasting future process scenarios, and addressing challenges related to dynamic control, making it a valuable asset for engineers and researchers alike. Furthermore, its user-friendly interface ensures that even those new to process simulation can effectively harness its powerful capabilities.

Frost 3D software enables users to create scientific models that accurately represent the thermal behavior of permafrost influenced by various structures such as pipelines, production wells, and hydraulic facilities, while also considering the thermal stabilization of the soil. This software suite is built upon a decade of expertise in programming, computational geometry, numerical methods, 3D visualization, and the optimization of computational algorithms through parallel processing. It allows for the construction of a 3D computational domain that accurately reflects surface topography and soil composition; facilitates the 3D modeling of pipelines, boreholes, and the foundations of structures; and supports the importation of various 3D object formats like Wavefront (OBJ), StereoLitho (STL), 3D Studio Max (3DS), and Frost 3D Objects (F3O). Additionally, it includes a comprehensive library of thermophysical properties related to soil, building components, climatic influences, and cooling unit specifications, along with the capability to define the thermal and hydrological characteristics of 3D objects and the heat transfer properties on their surfaces. The software thus represents a sophisticated tool for engineers and scientists working in fields related to permafrost and thermal dynamics.

Tackle intricate engineering problems by improving the efficiency of simulations. Simcenter 3D stands out as one of the most thorough and seamlessly integrated CAE solutions available. It allows you to create and assess the performance of complex products through groundbreaking advancements in simulation efficiency. By bringing together various physics domains within a single modeling environment, you can quickly gain deeper insights into how your product performs. This integrated platform facilitates all aspects of CAE pre- and post-processing, allowing for a streamlined workflow. With unmatched tools for geometry manipulation, you can easily defeature and simplify CAD geometry from any origin. Additionally, its extensive meshing and modeling capabilities cater to diverse simulation needs, granting you the exceptional ability to connect your analysis model with design data seamlessly. This connection not only accelerates the often tedious modeling process but also ensures that your analysis models remain aligned with the most current design iterations, ultimately enhancing productivity and accuracy in your engineering projects. By adopting Simcenter 3D, you can significantly reduce development time while improving the quality of your simulations.

ETAP®, a full-strength analytical engineering software company, specializes in the analysis, simulation monitoring, control, optimization and automation of electrical power system. ETAP's electrical engineering software is the most complete and comprehensive integrated power system enterprise solution.

CAESES® serves as a versatile and robust parametric 3D modeling tool designed to streamline variable geometry with a minimized set of parameters. Its primary aim is to facilitate the creation of clean, durable parametric geometries that lend themselves well to automated meshing and thorough analysis. Users can seamlessly integrate, initiate, and oversee their simulation processes, making it an excellent graphical user interface for process automation, complete with 3D post-processing features. The software provides built-in techniques for automated design exploration and shape optimization, allowing for the enhancement of imported geometries through CAESES' advanced shape deformation and morphing capabilities. As a fully command-driven platform, CAESES® can be extensively scripted and tailored to meet specific project requirements, and it also supports batch mode operations. You can significantly expedite your shape optimization workflow by applying the outcomes of adjoint flow analyses directly to geometry parameters. In just a few days, you can have your adaptable CAESES model ready, tailored to your specifications and designed for ease of use, requiring no prior expertise in CAESES. The platform’s intuitive nature ensures that even newcomers can effectively harness its powerful capabilities.

Complex technical systems, such as machinery and manufacturing facilities, are characterized by their intricate nature, as they include a wide array of components and subsystems drawn from various technical fields and are increasingly equipped with sensors and control mechanisms. The interactions among these components play a crucial role in influencing safety, efficiency, and user comfort. SimulationX provides a unified platform for the modeling, simulation, and analysis of these technical systems, covering areas like mechanics, hydraulics, pneumatics, electronics, controls, and various physical behaviors including thermal and magnetic effects. With extensive libraries of components that feature application-specific model elements, you can easily access the necessary tools tailored to your project requirements, making the process more streamlined and effective. This versatility allows for thorough examination and optimization of complex systems across multiple disciplines.

Simcad Pro allows you to visualize, analyze, and optimize process flow systems within an interactive simulation modeling environment. Optimize, plan, optimize, and reorganize processes and procedures, while optimizing layouts, automation, scheduling, and facility improvement. Simcad Pro integrates historical and live data to offer the best simulation tool on the marketplace. Multiple industries can use these applications, including manufacturing, automation and logistics, distribution warehouse, food & beverage, and services. Multi-Threaded – 64 bit Engine Simulator-on-the-fly - You can make real-time modifications to the model as the simulation is running. You can animated the model in 3D, 2D, and VR using Ray Tracing, light effects, and shadows. Singular model building environment. Smart, Spatially Aware Agents. Sub-Flows. Collision Avoidance. Real-Time Connectivity. Spaghetti Diagrams and Congestion Analysis, Heat Maps Efficiency, OEE. Extensive reporting and analysis tools. Scenario Analyzer.

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.

Cold forming tools experience significant mechanical and tribological stresses throughout their operational lifespan, which in some instances can result in premature damage to the tools. Given that these tools constitute a substantial portion of the manufacturing costs for components, it is crucial to proactively address potential issues during the design phase. The COLDFORM® software offers the ability to assess the mechanical strength of dies, thereby enhancing their longevity. It calculates stress distribution within the die, as well as monitoring deformations, wear, temperature variations, and any damage that may occur throughout the process. Furthermore, COLDFORM® can perform quick analyses by applying the stresses derived from the forming process to the tools. Additionally, the software supports coupled part/tool simulations, yielding highly accurate outcomes. With features focused on pre-stressed dies, it allows for precise assessment of the required pre-stressing for the interference fit of the tools. This capability ultimately aids manufacturers in optimizing tool performance and reducing costs associated with tool replacements.

Powersim Solutions offers the premier system dynamics simulation software known as Powersim Studio™, available through a partnership with Powersim Software AS. This company provides a comprehensive range of simulation tools designed to meet diverse requirements for constructing simulations, conducting thorough analyses, and sharing solutions. The product lineup from Powersim is divided into four distinct categories, ensuring that there is something for everyone. Their tools are tailored to support various tasks, including simulation creation, detailed analysis, risk assessment, and optimization. Among the offerings, the Studio Developer Tools empower developers to integrate simulations into bespoke software applications, allowing for the distribution of personalized simulations or applications. Additionally, Powersim Software provides user-friendly tools that enable users to perform detailed analyses using simulations developed in their advanced modeling tool, Powersim Studio Premium, enhancing the overall analytical capabilities available to users.

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.

WaveFarer is an advanced radar simulation tool that effectively models multipath effects and scattering caused by nearby structures and vehicles, as well as crucial atmospheric impacts for frequencies that can exceed 100 GHz. Its diverse applications range from simulating automotive driving conditions to enhancing indoor sensor functionalities and analyzing far-field radar cross sections (RCS). The capabilities of WaveFarer facilitate prompt and precise evaluations of scenarios where radars are situated in close quarters with various structures, targets, and environmental features. Tailored to meet the needs of radar system simulation, WaveFarer aids in assessing the optimal placement of automotive radar sensors and interpreting target returns in virtual driving environments. Additionally, it provides valuable insights for surveillance radar applications by examining the RCS of targets and how different materials can influence measurement outcomes, ensuring a comprehensive understanding of radar interactions in various contexts. With its robust features, WaveFarer stands out as a vital tool for radar analysis and simulation across multiple domains.

Dynamic simulations, highly regarded by corporate trainers and educators in business schools, offer unparalleled experiential learning opportunities. These simulations have been effective in highlighting the connections between strategic choices, operational decisions, and performance results. Furthermore, the simulation acts as a practice environment for honing skills in observation, assessment, and engaging in productive dialogues. For an optimal hands-on learning experience in management, business simulations should closely reflect real-world scenarios. Our simulations leverage a dynamic modeling platform that accurately depicts non-linear relationships, time delays, and causal interactions to realistically assess the impacts of team decisions on business results. This innovative approach ensures that participants are well-prepared to navigate complex business challenges.

Currently, engineering teams frequently rely on specialized simulation tools from various vendors to assess different design characteristics, which can lead to inefficiencies and higher costs due to the use of multiple software solutions. To address these challenges, SIMULIA offers a comprehensive suite of cohesive analysis products that enable users with varying levels of simulation knowledge and expertise to collaborate effectively while sharing simulation data and approved methodologies without compromising information integrity. The Abaqus Unified FEA product suite provides robust and comprehensive solutions for both standard and advanced engineering challenges, catering to a wide range of industrial applications. In the automotive sector, engineering teams can analyze complete vehicle loads, dynamic vibrations, multibody systems, impact and crash scenarios, nonlinear static situations, thermal interactions, and acoustic-structural relationships, all while utilizing a unified model data structure and integrated solver technology. This seamless integration enhances collaboration and improves the overall efficiency of the engineering process, allowing teams to innovate more rapidly.

Simpack is a versatile multibody system simulation (MBS) software that allows engineers and analysts to model and simulate the complex non-linear movements of various mechanical and mechatronic systems. This tool empowers users to create and analyze virtual 3D representations, facilitating the prediction and visualization of dynamic behaviors, along with associated forces and stresses. While primarily utilized in sectors such as automotive, engine, HIL/SIL/MIL, power transmission, railway, and wind energy, its applications extend across all fields of mechanical engineering. Notably, Simpack excels in conducting high-frequency transient analyses, including those in the acoustic range, making it a valuable asset for engineers. Originally designed to address intricate non-linear models featuring flexible bodies and severe shock interactions, Simpack continues to evolve to meet the demands of modern engineering challenges. Its adaptability ensures that a wide array of engineering problems can be effectively tackled using this advanced simulation tool.