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Webnar Projeto de Tanques Agitados Inscreva-se e tenha a chance de ganhar uma prova de conceito CAE gratuitamente! Quer aprender mais sobre Projeto de Tanques Agitados e ainda ter a chance de ganhar uma prova de conceito feita para os seu caso especifico?! No dia 27 de Agosto, terça-feira, às 19:30 apresentaremos nosso webinar sobre Projeto de Tanques Agitados , apresentando cases de simulações CAE e um workflow exclusivo do Simcenter STAR-CCM+ especialmente desenvolvido para este tipo de equipamento, e ainda daremos aos participantes interessados a chance de ganhar uma prova de conceito CAE personalizada! Para ter a chance de ter esta prova de conceito de forma gratuita siga a CAEXPERTS no LinkedIn, se cadastre aqui ao lado e, é claro, esteja conosco em nosso Webinar! Dia 27 de Agosto, ás 19:30 Inscreva-se! Nome Telefone Empresa Email Finalidade da prova de conceito Me inscrever Obrigado por enviar!

Simcenter Flomaster provides a suite of simulation tools for designing, commissioning and operating thermofluid piping systems. The system's digital twin from the engineering stage can be utilized during operation for online detection and monitoring. security efficiency; propulsion; steam; Flomaster Reduce operating costs while ensuring the safety of complex thermofluid piping systems of any scale and complexity. Simcenter Flomaster is the leading simulation tool for fluid engineering and offers reliable, accurate solvers and best-in-class built-in correlations. This means you can effectively size gas, liquid, and two-phase systems and components for maximum efficiency. With the same virtual model, you can simulate and analyze dynamic events such as different operating conditions, failure scenarios and emergencies to ensure safety. Simcenter Flomaster offers a comprehensive simulation toolset for designing, commissioning and operating thermofluid piping systems. This means that the digital twin of the system developed in the engineering phase can be reused during operation for virtual detection and online monitoring to improve efficiency and ensure safety. Simcenter Flomaster can connect to other relevant tools and platforms, including PLM, CAD, Simulation and Industrial IoT, enabling you to embrace digital transformation and innovate quickly. Contact an Expert Thermofluid systems engineering Simulation of the propulsion system System integration Thermofluid system simulation Simcenter Flomaster offers simulation solutions for thermofluid systems, helping you reduce cost and accelerate time to market. Analyze complex physical phenomena, which are critical to ensuring the safe and efficient operation of your systems, maximize return on investment by leveraging the digital twin of your thermofluid systems by controlling maintenance, repairs and operation throughout their lifecycle. Our program has a large library of components used in fluid transport, as well as a large database with information on the physical properties of Newtonian and non-Newtonian fluids. Thanks to your solverfast, reliable and rigorously tested, you can simulate the dynamic behavior of thermofluid systems of any size and complexity. Reuse the same templates you used during initial design for sizing systems and components in detailed designs for transient analysis. Address the growing complexity of propulsion systems for the automotive, aerospace, and marine industries. Gain the ability to model a wide range of propulsion technologies. Embrace model-driven design for a streamlined user experience. From components to the entire system, Simcenter Flomaster helps you focus on your engineering model and solve it as quickly as possible with the data available within the tool. Optimize the efficiency of your thermofluid systems, ensuring they always operate safely. Fluid systems play key roles in all industries. ⇐ Back to Tools

State-of-the-art software; 3D Multiphysics Simulation; SIMCENTER 3D; STAR CCM+; FloEFD; FEMAP; Simulation Systems; Flomaster; AMESIM; Simulation and Electromagnetic Design; Magnet; SPEED; Motorsolve; Mentor; Multidisciplinary Optimization; HEEDS; CAD / ECAD design; NX Design Simulation; Solid Edge Mechanical and Electrical and PCB Simcenter 3D Complete and integrated CAE solution Pre/Post Processing Efficient meshing Structural analysis Durability and fatigue analysis Electromagnetic simulations Composite materials Motion simulation Thermal and acoustic simulation Parameterization Know more STAR CCM+ Computational fluid dynamics Particle flow Electrochemical simulation Moving objects Multiphase flow simulation Reactive flow Thermal simulation Battery simulation Electric machines Mechanics of Solids Know more FloEFD Computational fluid dynamics Friendly and intuitive interface Integrated with CAD Cartesian mesh generation Innovative workflow Engineering database Analysis "What-IF" Integration with FloMASTER Compressible flows Combustion processes Know more Products State-of-the-art software, with the Siemens quality seal. Entre em contato WhatsApp 3D Multiphysics Simulation Âncora 1 Femap Inspect finite elements Pre/Post-processing Comprehensive mesh generation FE mount management A multi-CAE solver Meshing 1, 2 and 3D (manual/auto.) Composite materials Basic fluid simulation Thermal simulation Optimization Know more Âncora 2 1D Systems Simulation Âncora 3 Flomaster Simulation of fluid systems Eng. of thermofluid systems Simulation of the propulsion system System integration Piping systems Connection to PLM, CAD and IoT Cost reduction Project acceleration Extensive library and database Model based design Know more Amesim Systems simulation Performance optimization Multiphysics libraries Virtual prototyping Mechanical and electrical systems Fluid and propulsion systems Thermal management systems ROM builder System integration Coupling with CAD software Know more Simulation and Electromagnetic Design Magnet Low frequency simulation AC electromagnetic simulations Hotspot analysis Virtual prototyping Advanced material modeling Effects of hysteresis embedding Modeling of circuits and systems Electric Field Simulations Electromag Movement Simulation. Transient simulation Know more Motorsolve Electric motor design Electric motor winding Importable engine profiles FEA automation Thermal analysis of the engine Performance analysis Extensive template export Model based interface Automated typical operations Hassle-free customization Know more SPEED Electric machine design 2D magnetostatic analysis Includes theoretical and physical models Link to multiphysics software Supports various machine types Exploration and Optimization Automated design space Model based design Model based design Integration with HEEDS Know more Âncora 4 Otimização Multidisciplinar Âncora 5 HEEDS Interface design and optimization Integration to all CAD/CAE Process automation Distributed execution polycarbonate Collaboration Efficient search Insight & Discovery Performance comparison Digital twin Know more Design CAD / ECAD Âncora 6 NX Intuitive design environment Define, reuse and validate Generative Engineering Integrated simulation and manufacturing Electromechanical design Collaborative processes Industrial Additive Manufacturing Mold and die design Electrode design Reverse engineering Know more Solid Edge Multi CAD platform Design, simulation and manufacturing Synchronous and Ordered Technology 2D/3D, sheet metal and assembly PCB design Rendering Additive/subtractive manufacturing Automatic template correction Structural/fluid dynamic analysis Reverse engineering Know more Solid Edge Electrical Wiring project Electrical whip Electrical routing Simulation of electrical systems Collaborative PCB design 2D control panel layout Electrical/mechanical integration Robust library Adjustable and reusable layout Sync with Teamcenter Know more

Simcenter 3D Additive Manufacturing Simulation - Print it right the first time; Predict distortions and defects before parts are printed; Improved inherent strain approach; NX workflow; Additive Manufacturing; Simcenter 3D Engineering Desktop; Omnimesh; printing process parameters. Additive Manufacturing It is increasingly common to use 3D printers in the production of various products, with the most varied materials. 3D printing by Fused Deposition Modeling (FDM ), for example, uses polymer in the form of a filament in printers. The Selective Laser Sintering (SLS ) type, on the other hand, is a method that produces 3D objects from granulated materials of ceramics, plastics and metals. There is also Stereolithography, a method that solidifies certain liquid resins with ultraviolet light. Due to the advancement of technology in recent years, additive manufacturing has gained applicability in industries, mainly in the automotive and aerospace sectors, in addition to the evolution in the production of dental implants. Contact an Expert Advantages of Additive Manufacturing Industrial additive manufacturing Generative Engineering Additive Manufacturing Project Construction preparation Construction simulation Project validation Machine Connectivity Post processing Solid Edge features Explore new concepts with generative design Geometry preparation for additive techniques Direct output of models to your 3D printer Cost: allows parts to be produced in small quantities, reducing the unit cost; Speed: efficient production from the digital design to the physical model enables rapid prototyping; Complexity: allows the creation of parts with complex geometries; Customization: products are fully customizable according to needs; Economy/Sustainability: the reduced use of material generates less waste and consumes little electricity. NX provides all the capabilities to analyze from design to print and post-press. This allows you to rethink your product, reinvent the manufacturing process, and even reimagine business models with additive manufacturing technology. NX enables you to create part designs ideal for additive manufacturing with built-in generative engineering tools such as design space exploration and various types of topology optimization. AM ( Additive Manufacturing) solutions from Siemens Digital Industries Software allow you to design and print complex geometries at scale. Efficient and quality output from the process requires proper setup. The built-in build prep tools in NX assist in placing, orienting part holders on the build tray as efficiently as possible. Simulating the construction process can help your designers generate quality 3D prints at scale. From building orientation optimization to meso-scale deposition path optimization, NX has the tools your business needs to print successfully the first time. NX allows the designer and manufacturer to validate their parts at every step of the process. Validate your part's printability, then simulate its performance in the field with built-in tools, getting support for printing production-ready parts. Connect to the widest range of 3D printing hardware with Siemens NX. Whether you're printing on a flat powder deposition system or a multi-material, multi-axis system, NX has you covered. Industrialized 3D printing requires robust post-processing software like NX. Printing is not the last step in the additive manufacturing process. Dust removal, part removal from the build tray, and post-process machining are all aspects of the complete additive manufacturing process, and all of these functions form part of Siemens' Additive Manufacturing (AM) suite of solutions. Solid Edge supports your end-to-end workflow, from design to 3D printing techniques from the STL format, having tools for print setup and manipulation of the STL. Generative design combines powerful design tools with topology optimization, allowing you to quickly create complex, lightweight shapes and highly customized lattices uniquely suited for 3D printing. Seamlessly combine traditional solid “ b-rep ” models with triangular mesh models without time-consuming and error-prone conversions, reducing rework and supporting additive manufacturing processes for complex shapes. Solid Edge supports outputting its part models to 3D printers using the 3D Print command . Name your parts in .stl and .3MF formats or send your parts directly to the Microsoft 3D Builder application . This allows you to print in-house with automated press preparation, including color printing capability. NX Simcenter 3D Solid Edge Siemens NX software is a flexible and powerful integrated solution that helps you deliver better products faster and more efficiently. NX delivers the next generation of design , simulation and manufacturing solutions, supporting all aspects of product development from conceptual design to engineering and manufacturing with an integrated toolset that coordinates disciplines, preserves data integrity and design intent, and streamlines the entire process. The software has tools for simulating the 3D printing process as well as being able to simulate post-printing conditions such as thermal distortions, material shrinkage, among others. Solid Edge is an accessible, easy-to-use platform of software tools that handle all aspects of the product development process. It combines the speed and simplicity of direct modeling with the flexibility and control of parametric design – thanks to synchronous technology. Solid Edge has an intelligent, multi-CAD interface and deals not only with modeling in a simple and agile way, due to the synchronous technology applied, but also with the entire process of product development and 3D projects, simulation, manufacturing, reverse engineering, data, among others, without leaving aside the flexibility and parametric control of the projects. ⇐ Back to Disciplines

The best way to predict a product's strength and durability; predict fatigue life quickly and accurately; eliminate over- or under-engineered components; Include manufacturing and assembly aspects in the durability analysis; structural optimization Simcenter 3D Durability Simulation Simcenter™ 3D software offers a distinct set of tools to support fatigue design at all stages of development. This includes easy-to-use wizards for strength and fatigue in the design phase, fatigue information in the actual simulated part, detailed analysis of complex load scenarios including welds and connections, and new materials and manufacturing processes. Benefits of the solution The best way to predict a product's strength and durability Eliminate over- or under-engineered components Possibility of a more efficient and secure physical validation Include manufacturing and assembly aspects in the durability analysis Design it right the first time Providing a platform for multidisciplinary simulation Explore multiple design options and optimize your design for endurance and fatigue performance Perform fatigue life prediction analyzes quickly and accurately, considering realistic loading conditions Get insightful and fast feedback on critical areas of durability Realistically simulate the durability performance of complex connections and welded joints Predict component loads and optimize fatigue performance at the system level through the load transfer path approach Take advantage of new materials and manufacturing processes using precise fatigue methods Shorter development cycles and ever-increasing quality requirements have pushed the test-based approach to durability to the limits. Evaluating and refining durability performance by simulation methods is the only valid alternative. Siemens Digital Industries Software's Simcenter 3D durability modules provide access to state-of-the-art analysis methods, allowing engineers to interactively assign loads to a model. The solution enables efficient analysis of seam and spot welds, as well as new methodologies for composite materials. Analyze the loads acting in the critical regions and improve the load flow of the application points that have the most influence in the critical areas, which is much better than just reinforcing around the critical area. Virtual testbed experiments make it easy to analyze the impact of individual load events on component damage. This analysis also allows you the flexibility to define your specific load scenarios for each of your components, saving testing time. New materials and manufacturing processes often have an important influence on fatigue behavior. With Simcenter 3D, you can take these manufacturing influences into account when performing durability analysis. To perform fatigue analysis efficiently, durability modules provide access to: Test data such as load data, test schedule definitions, etc. Simulation data such as multibody results and digital twin finite element simulations State-of-the-art fatigue simulation methods Fatigue-specific post-processing The Simcenter 3D Durability Solution is part of a larger multidisciplinary simulation environment and is integrated with Simcenter 3D Engineering Desktop at the core for centralized pre/post processing for all Simcenter 3D solutions. This integrated environment helps you achieve faster CAE processes and streamline multidisciplinary simulations that integrate durability and other disciplines such as stress and strain of structural solutions, load prediction using motion solution, and prediction of nonlinear behavior of short or long fiber composites. to tight integration for damage-tolerant design. Aerospace and Defense Automotive and transport Industrial machinery Medicinal Marine Simcenter 3D is used to predict the service life of mechanical systems such as landing gear, control mechanisms, slat mats and other critical assemblies, but especially also for turbines. Local stress concentrations are identified based on all possible combinations of local load conditions to resolve durability issues long before prototypes are built. A wide range of methods can locate weaknesses and assess fatigue life. Simcenter 3D is used to perform fatigue assessments on body structures, panels, cross members and door systems, as well as sunroofs, latches and locking systems. The Simcenter 3D Durability module also allows a high degree of accuracy for specific seam and spot weld analysis. Advanced numerical durability predictions can be applied to engines, power train parts, engine mounts, gearbox chain jumps and exhaust lines. In industrial applications, achieving cost efficiencies depends on critical parts that are typically subjected to large dynamic multiaxial load cases. Any metal component subjected to dynamic loading cycles can be optimized efficiently. Simcenter 3D Durability can be used to determine rotor base fatigue life on large rotating machines. Durability and full function are especially important for medical devices. Simcenter 3D Specialist Durability is used to prevent failure of civic systems. Simcenter 3D Specialist Durability connection modeling allows you to have a digital twin for miles of welds performed on ship structures. For high-end yachts with many composite materials, the Simcenter 3D Specialist Durability Composite Fatigue module facilitates state-of-the-art analysis. Sectors Modules The Simcenter 3D Durability wizard is a simulation wizard for calculating the fatigue life of mechanical components subjected to load cycles. This solution is performed after users have calculated a state of stress from static loading using a finite element (FE) solver . The durability algorithms in the wizard are based on the crack initiation method for fatigue analysis. Simcenter 3D Advanced Durability software helps validate the product's structural integrity throughout its lifecycle under simple or complex loading conditions. Expert analysts use this solution to perform in-depth fatigue analysis and life calculations to help them determine product durability based on Simcenter Nastran, Simcenter 3D Response Dynamics, MSC Nastran, ANSYS and Abaqus solutions. Based on the crack initiation method for fatigue calculation, the user can choose various service life criteria and can take into account mean stress effects, notch effects, case hardening effects and biaxial stress effects. Fatigue and strength safety factors, fatigue life, and damage results are visualized as contour plots. Simcenter 3D Specialist Durability Modeling provides a rich and intuitive toolset for preparing solutions, submitting them to the solver , and post-processing durability results. It allows the configuration of complex durability scenarios with many finite element cases and load history. Durability solutions can be configured using supplied parameters or configured to follow standard user procedures. Simcenter 3D Specialist Durability Solver is the basic solver for specialist fatigue analysis. It can be run on the same computer or independently in batch mode . It provides all standard durability methodologies but can be easily extended with any fatigue methodology due to the unique aperture through user defined fatigue methods. Simcenter 3D Specialist Durability Composite Fatigue provides a unique methodology for analyzing short and continuous fiber composites. It can incorporate stiffness reduction and stress redistribution during the fatigue life of composites under complex load situations. New technologies reduce the effort needed to test the parameterization of methods. Simcenter 3D Specialist Durability for Connections allows you to configure and conduct special spot welds and seam weld analysis runs. Welds are made from connections modeled in Simcenter 3D, defined in xMCF format, or detected in existing meshes. Configuration and load analysis are performed using the same tools as Simcenter 3D Specialist Durability Modeling and can even be mixed in an analysis case. Module benefits: Improves robustness by predicting the lifetime of product designs and determining which design features are over- or under-engineered Reduces physical testing costs by allowing you to analyze product lifespan in a virtual environment Accelerates product design by allowing designers to quickly perform what-if re-analysis of new designs Understand the impact of changes on product durability Main feat ures: Use linear stress or strain results in static solutions with stress assistant from NX™ software , Simcenter Nastran®, MSC Nastran, Abaqus and ANSYS Define the cyclic loads that define the duty cycle of the part throughout its service life Calculate static factors of safety, fatigue factors of safety and fatigue life Available fatigue criteria: Smith-Watson-Topper , strain or life Display contour plots for strength factor of safety, fatigue factor of safety, or fatigue life Prepare a technical durability report Module benefits: Save time with what-if redesigns Improves product design robustness by determining the lifetime of product designs Reduces physical testing costs by allowing you to analyze product lifespan in a virtual environment Main features: Simcenter 3D integration leverages geometry associativity to quickly assess the impact of changing geometric features on durability Industry standard life criteria, stress direction approaches, average stress effects, notch effects, cyclic stress-stress relationships, and rain flow cycle count Static, transient (including flexible body) and random events Tension gauge durability Module benefits: Intuitive and flexible parameter-based configuration Quickly isolate critical fatigue events, locations, and load cases in complex work cycles Understand the cause of fatigue issues Main features: Parameter driven analysis models, solver profiles and durability simulation objects Direct component load import from prototype measurements or Simcenter 3D multibody simulation and third-party timing data formats Integration with Simcenter Testlab™ software load data processing tools for durability load case selection Assign complex work cycles to assemblies and their connections, including seams and spot welds Dedicated 2D and 3D post-processing scenarios Module benefits: Reduce fatigue analysis time Fast and accurate fatigue life predictions based on realistic loading conditions Explore multiple design options and optimize design for fatigue performance Main features: Industry standard fatigue life solver with proven accuracy and speed Parallel processing enabled with the standard license All industry standard methods New and unique user-defined methods interface batch processing Module benefits: Know the real progressive damage behavior of your composite material Enables damage tolerant design Ability to predict fatigue damage in composite materials Defined parameter identification processes available Main features: Unique workflow that allows for stiffness reduction and stress redistribution Variable amplitude and multiaxial loads Modeled layer-based fatigue behavior without the need for full stacking tests Master SN curve approach for arbitrary short-fiber orientations Intra and interlaminar methods for continuous fiber composites Integrated with continuous damage models and analysis with Simcenter Samcef® software solvers User defined methods including stiffness reduction and stress redistribution Module benefits: Comprehensive software to predict fatigue of seams and spot welds under arbitrary load conditions Provides the most accurate prediction of fatigue life for seam welds without refurbishment Increases engineers' throughput by enabling automatic detection of weld topologies Powerful software to handle welded assemblies regardless of size and number of welds Efficiently handles traditional approaches and more accurate approaches in the same model Validate more weld variants and their fatigue life in shorter development cycles Understanding and improving fatigue testing for seam welded assemblies Main features: Innovatively designed algorithms: Automatic detection of welds and weld geometry of FE models and groups based on joint types, degree of penetration and sheet thickness Supports industry-typical FE connection modeling for seam and spot welds Handles all load cases: transient, random, harmonic, proportional and non-proportional and timing Special tools for seam welds: Mesh independent notch stress method (R1MS, R03MS, R005MS) including notch effects (effective notch stress method) using microstructural length ρ* User defined methodologies can access all weld data ___________________________________________________________________________ Simcenter 3D Advanced Durability ___________________________________________________________________________ Simcenter 3D Specialist Durability Modeling ___________________________________________________________________________ Simcenter 3D Specialist Durability Solver ___________________________________________________________________________ Simcenter 3D Specialist Durability Composite Fatigue ___________________________________________________________________________ Simcenter 3D Specialist Durability Modeling ___________________________________________________________________________ Simcenter 3D Durability Wizard ⇐ Back to Simcenter

Simcenter Femap is an advanced simulation tool for creating, editing and inspecting finite element models of complex products or systems. Pre/Post-processing; mesh; composites; Structural simulation; Thermal simulation; Structural Optimization; capture CAE processes, standardize and automate them Simcenter Femap Simcenter Femap is an advanced simulation tool for creating, editing and inspecting finite element models of complex products or systems. You can use advanced workflows in Simcenter Femap to model components, assemblies, or systems to then determine a model's behavioral response when subjected to real-world conditions. In addition, Simcenter Femap offers a powerful data-driven graphical results visualization and evaluation tool, which, in combination with industry-leading Simcenter Nastran, provides a complete CAE solution, ensuring that products reproduce design performance in the real environments and makes it possible to improve this performance. Contact an Expert Pre /Post Processing Mesh Composites Basic fluid simulation Structural simulation Thermal simulation Optimization Simulation of automation and scalability Reduce time spent preparing analysis models and get more time to evaluate results. Rapidly advance manipulation of multi-CAD geometries to prompt execution of CAE models, comprehensive meshing, FE assembly management, multi-CAE solver environments, and simulation data post-processing. Efficiently mesh your models using comprehensive automatic and/or manual modeling functions of 1D, 2D, and 3D elements, as well as numerous techniques for applying loads and boundary conditions. User-defined geometry edits, meshes, and boundary conditions are all tied to the base design, which means that when the base design geometry changes, you can quickly update your model. This approach greatly reduces downstream modeling time , which results in huge time savings in the many iterations of analysis and design of a product. In their quest to create lighter yet stronger products, manufacturers are increasingly using composite materials. It is at the forefront of component analysis through the continuous development of material models and element types. Simcenter accelerates the entire laminated composite simulation process through a seamless connection to composite design, accurate solvers , and comprehensive post-processing. Simcenter Femap allows a view of the basic behavior of a fluid together with all associated physics in the FEA model. Understanding how a product component or assembly reacts under stress or vibration is critical in any industry. However, as products and materials become increasingly complex, engineers need tools that go beyond linear-static analyses. Simcenter Femap provides the structural analysis software you need to simulate a wide range of applications in a single environment and in conjunction with industry-leading Simcenter Nastran. Simcenter Femap includes first-class and complete thermal simulation capabilities that can help you understand your product's thermal characteristics and subsequently tailor your thermal management solution for optimal performance. How can I reduce material in a component or change its properties, ensuring it continues to meet performance targets? Simcenter Femap offers engineering optimization techniques that can help you answer these questions by systematically looking for the best design that satisfies certain criteria. Reduce component weight or find the right combination of parameters to improve product performance through full topology, geometry and parameter optimization capabilities. As companies increase their reliance on simulation, they are looking for ways to speed up the analysis process and increase simulation throughput. One of the ways to increase simulation throughput is to capture repetitive CAE processes, standardize and automate them. Simcenter allows you to capture the experience of senior analysts and make it available to junior engineers in your organization for use in the form of wizards or templates. ⇐ Voltar para Produtos

Acoustic simulations help analyze noise quality in designs, Productive tools for designing, refining and validating prototypes throughout the development cycle. Aeroacoustics; Boundary Element, Ray Acoustics, FEM/BEM solvers; acoustic modeling; 3D Meshing for Acoustics; SIMCENTER 3D; SIEMENS Acoustics There are products which have requirements that require manufacturers to limit noise levels and meet environmental and government standards. Engineers need productive tools to design, refine, and validate prototypes throughout the development cycle. Covering the widest range of industry applications and engineering tasks and meeting the latest international standards, our vibroacoustic simulation solutions help analyze noise quality in designs. Simcenter offers indoor and outdoor acoustic simulation in an integrated solution that guides your team to make informed decisions during the early stages of design so you can optimize your product's acoustic performance. A unified and scalable modeling environment, combined with efficient solvers based on NASTRAN technology and easy-to-interpret visualization capabilities, allow you to quickly obtain information about the acoustic performance of your product. Contact an Expert Aeroacoustics Simcenter offers an extensive library of accurate models for predicting aeroacoustic noise sources, including steady-state models, direct models (DES/LES), propagation models, and acoustic perturbation equation solver (APE). Create aeroacoustic sources close to noise emitting turbulent flows as calculated from a CFD solution and calculate their acoustic response in the external or internal environment. For example, you can predict cabin noise inside cars and aircraft due to wind loads acting on the windows and structural body of the vehicle. In addition, other apps also allow you to assess noise from heating, ventilation, and air conditioning (HVAC) and environmental control system (ECS) pipelines, train boogies and pantographs, cooling fans, ship and aircraft propellers, and much more. more. Boundary Element Method Often used for outdoor acoustics problems, the boundary element method (BEM) is ideal for problems involving very complex geometries that can be challenging to model for the FEM method. The BEM method helps to simplify the external acoustic simulation as only the external surface mesh of the geometry is required. This simplifies the modeling process and reduces degrees of freedom in the simulation model, which will result in easier analysis. Ray Acoustics Performing acoustic simulations in high frequency ranges is not always possible with standard finite element method (FEM) and boundary element method (BEM) technologies. In response to this, Ray Acoustics enables you to competently and accurately perform acoustic analysis for high frequencies and efficiently and accurately perform various acoustic and audio comfort simulations in vehicles, covering the entire auditory frequency range. Parking sensors and near-field ADAS sensors are a good example of a use case where lightning acoustics can cooperate with your project, as it gives you the opportunity to quickly evaluate the performance of these ultrasonic transducers and sensors that operate at frequencies of 40 kHz and beyond. Simcenter 3D Complete simulation software . Simcenter's 3D acoustic modules provide the capabilities needed to evaluate radiated noise, including capturing the effect of encapsulations with sound treatments. ⇐ Back to Disciplines

FloEFD is a multiphysics and fluid dynamics (CFD) software natively integrated into CAD, capable of analyzing a wide variety of phenomena involving Fluid Mechanics. Heat Transfer, Optical Analysis; Electronics; HVAC; Structural; Electromagnetism; Expedition, Cadence, Zuken and Altium Coupling FloEFD FloEFD is a commercial software for computational fluid dynamics (CFD), capable of analyzing a wide variety of phenomena involving Fluid Mechanics, Heat Transfer, Optical Analysis, among many other functionalities. Its development, together with several CAD packages such as Solid Edge, NX, SolidWorks, Catia, Creo/Pro-E, facilitates CAD/CAE integration in the most diverse projects focused on fluid dynamics, such as aerodynamics, flow machines and heat exchangers. heat, covering several industrial applications. Contact an Expert Integrated with CAD Innovative workflow Mesh generation Engineering database Integration with FloMASTER Cooling of electronic components HVAC Compressible flows and combustion processes FloEDA module Because it is integrated into CAD packages, FloEFD offers a friendly and intuitive interface that allows the designer to select and change simulation parameters such as dimensions, boundary conditions, mesh generation, analysis types and material properties in a simple and fast way. . Mesh generation in FloEFD is one of the software 's differentials , as it works with Cartesian meshes due to its robust and simplified algorithm, which requires less computational time. This mesh, despite having a simplified construction, respects the conditions imposed by the simulation. The mesh has three different types of elements: solid materials, fluid cells and partial cells – which aim to optimize wall effects at the solid-fluid interface, which gives a good advantage to the simulation. In addition, simulation options interact directly with Excel, allowing instant acquisition of simulation data into an automatically generated spreadsheet; it also offers the possibility of working via external algorithms through the VBS language. The FloEFD has the Front Loading software feature , which refers to the ability to practice CFD during the design process, i.e., model and simulate simultaneously. Through FloEFD and its interchangeability between CAD software , the design process becomes leaner compared to traditional design. In this way, it allows the optimization of the product, since it integrates geometric modeling, simulation and data analysis in just one software , avoiding rework, whether in geometric modeling or simulations, obtaining greater dynamism for those who work in projects and simulations engineering and ensuring safety and accuracy of results. Unlike other CFD software , which use tetrahedral meshes, FloEFD features a body-immersed Cartesian mesh structure . This type of mesh allows the designer to reduce the process of trial and error, common to CFD simulation processes, in which an attempt is made to obtain a precise mesh for boundary conditions close to the walls, where the fluid velocity gradients are very high. Such a mesh ensures fast convergence and the number of cells is considerably less, as there is no need to match the mesh with the CAD. Offering an extensive library for applications in material selection, boundary conditions, porosity, radiative properties, among others, FloEFD also has the option of creating custom materials or conditions, adapting them to the physical properties favorable to the simulation, such as density, conductivity, specific heat, and saving them in the library for future applications. In practice, the flows that occur in pipes, flow machines, heat exchangers are too complex for an analytical analysis, like traditional 1D flow models. With FloEFD, it is possible to obtain views of the 3D flow in components, which, from a parametric analysis of the results, can be exported in data for analysis in the FloMaster software. Furthermore, FloMaster works with statistical algorithms that combine several configurations ( Latin-Square ), given input values, making the combination of 1D and 3D simulations a powerful tool in the quest to obtain the best performance of thermal systems.ting at steady state. For this, it has an extensive library of materials aimed at the application of electronics by the Engineering Data Base , which can be applied to the components of the analyzed system. FloEFD is enabled to calculate the effects of heat dissipation on electronic components operating at steady state. For this, it has an extensive library of materials aimed at the application of electronics by the Engineering Data Base , which can be applied to the components of the analyzed system. For the HVAC designer, FloEFD allows setting boundary conditions according to the situation obtained, be it in industrial operations, where you want to cool equipment by ventilation, or in hospitals, where you have a cooled air network for health reasons. Flow with complex conditions, fan models, simulation of relative humidity and condensation, performance of heat exchangers, pressure drops in pipe networks, and radiative models for analysis of the incidence of radiation are some of the devices that FloEFD offers to engineers. This module makes it possible to understand phenomena related to combustion reactions, such as burning propagation, post-burning gas formation, fuel-air mixture effects and mass fractions of gases from combustion; in addition to aspects related to compressible flows, whether subsonic, transonic, supersonic or hypersonic, in order to analyze the effects of Mach numbers, atomic dissociation and ionization by hypersonic flows at high temperatures. This extension allows you to carry out a thermal analysis of integrated circuit boards, by importing material data, power maps , thermal regions and connection networks from software such as Mentor Expedition, Cadence, Zuken and Altium, avoiding the use of IDF files. FloEDA allows detailing PCB's with materials and thermal properties for the model to be passed to FloEFD for subsequent thermal analysis. ⇐ Back to Tools

SIEMENS Simcenter Flomaster and Amesim. Reduce operating costs while ensuring the safety of complex thermofluid piping systems of any scale and complexity. Engineering of thermofluid systems; NIST library of properties; Systems from CAD; From design to real-time system. Thermofluid Dynamic Systems Thermofluid dynamic systems are those involving the transfer of thermal energy and the transport of fluids through pipes and equipment. They are widely used in a variety of industrial applications, such as power generation, refrigeration, heating systems, vehicles, chemical industry, aerospace industry, oil and gas industry, among others. The main advantage of using a thermofluid dynamic analysis is the possibility of predicting the one-dimensional (1D) behavior of a piping system under different conditions, which can be very useful in optimizing performance. In addition, this approach allows for accurate computer simulations to be carried out, which can be very useful in decision-making and in the design of new facilities. This can lead to an improvement in energy efficiency, a reduction in operating costs and even increased facility safety. Contact an Expert Power generation HVAC Chemical industry Automotive industry Aerospace Industry Oil and Gas Industry They are fundamental for designing and optimizing large complex power generation systems. They make it possible to study and evaluate the performance of different applications, such as hydroelectric, thermoelectric, geothermal plants, solar plants of various types, steam production, boilers, thermodynamic cycles, thermal machines, pumping, heat exchangers, cooling towers, reservoirs and storage. thermal. This helps design and optimize these systems more quickly and efficiently, and facilitates innovation and sustainability. With the simulators, it is possible to evaluate the best options and optimize global performance, reducing costs and improving energy efficiency. Allow HVAC designers and engineers to evaluate the performance of HVAC systems prior to construction. They are valuable tools for sizing, equipment selection and balancing of complex piping networks, optimizing energy consumption and operational stability. In addition, simulators also help to design innovative HVAC systems, meeting established sustainability goals, evaluating alternatives and simulating critical scenarios, making the project more intelligent and efficient, both in terms of implementation and operation costs. They are used in all stages of the transformation process of a chemical industry. They are useful for the design, optimization and control of chemical processes, and can be used to improve mixing of reagents and find optimal operating conditions to improve reaction kinetics and increase conversion of reactants to products. Furthermore, these tools can also be used to simulate critical scenarios and test different conditions before implementing changes in production, which ensures process safety and efficiency. They can also be used to optimize resource utilization and minimize operating costs. The use of simulators also allows the innovation of new processes and projects, helping the chemical industry to remain competitive. Necessary for designing and optimizing combustion, lubrication, cooling and other systems. They allow you to evaluate different design options, identifying potential problems before mass production, allowing you to implement solutions and choose those that offer the best performance in the most efficient way. Furthermore, these simulations can also be used to optimize energy efficiency, minimize costs and improve vehicle safety. The use of simulators is an important tool for the automotive industry, as it allows the development of new projects and technologies, helping to maintain competitiveness in the market. The aerospace industry uses simulation tools to design, optimize and predict problems in aeronautical systems such as propulsion, climate control, refrigeration, cooling and armament. These tools make it possible to evaluate different design options and identify potential problems before mass production, ensuring the safety and efficiency of aerospace devices and allowing the innovation of new designs and technologies. They also make it possible to predict the need to replace devices before failures occur and optimize overall performance, in addition to minimizing operating costs. They assist engineers in the design, equipment sizing, optimization and control of important processes such as fluid transport, heat transfer, refining, chemical reactions and energy production. This allows for energy integration of plant streams and increases production yields, as well as reducing operating costs and increasing safety. The simulations also make it possible to identify and prevent failures in the process, extending the useful life of the equipment and preventing failures that cause the plant to stop unexpectedly. In addition, operators can use these tools to train industrial plant control, ensuring process safety and efficiency. Simcenter FloMASTER Simcenter FloEFD Simcenter Flomaster is an advanced simulation tool for the design and operation of 1D thermofluid dynamic systems such as piping systems. It allows you to create detailed virtual models of systems of any scale and complexity, including piping, pumps, valves, heat exchangers and other components. With this tool, it is possible to simulate the operation of the system under different conditions, evaluate the performance in terms of flow, pressure, temperature and other variables, and simulate dynamic/transient events, such as failures or emergencies, to assess the system's safety and take Preventive measures. Simcenter Flomaster can also be integrated with other tools and platforms such as PLM, CAD, Simulation and Industrial IoT, which facilitates decision-making and implementation of system improvements. It also allows you to create a detailed digital model of the system and reuse it during operation for virtual monitoring and online sensors, which increases efficiency and ensures system security. In summary, it is a fundamental tool to create and use digital twins of processes, guaranteeing efficiency and operational security. Simcenter FLOEFD is an advanced 3D CFD (computational fluid dynamics) tool that allows designers to explore the potential of their ideas directly in their CAD software. It is capable of simulating the impact of changes to geometry or boundary conditions quickly and easily, enabling frequent "what if" analysis. In addition, Simcenter FLOEFD generates detailed reports within the CAD platform chosen by the user. When integrated with Simcenter Flomaster, this software allows the generation of reduced order models that can be included as additional components to the flowchart, improving the accuracy of the simulations of the processes under study and allowing a more detailed and accurate analysis of the system's performance. The combination of Simcenter FLOEFD and Simcenter Flomaster allows obtaining a complete and accurate view of the operation of a process and making more assertive decisions about the design and operation of the analyzed system. ⇐ Back to Disciplines

SIEMENS NX delivers the next generation of design, simulation and manufacturing solutions that enable companies to realize the value of the digital twin. NX for Design; Automate electrode design; Additive Manufacturing; Tool Design; Mold; Headquarters; Stamping; Generative Engineering; Direct and Synchronous Modeling NX NX is a flexible and powerful integrated solution that helps you deliver better products faster and more efficiently. It offers the next generation of design , simulation and manufacturing solutions that enable companies to realize the value of the digital twin. Supporting all aspects of product development, from conceptual design to engineering and manufacturing, NX offers an integrated toolset that coordinates disciplines, preserves data integrity, design intent, and streamlines the entire process. Contact an Expert NX for Design NX for manufacturing Automate electrode design Additive Manufacturing Tools and accessories design Mold design Progressive matrix design Stamping die design Generative Engineering The industry's most powerful, flexible and innovative product development solution, NX has the performance and features to help you get your product to market faster than ever before. Drive efficient end-to-end part manufacturing operations and deliver high-precision parts through digitalization. Program CNC machine tools, control robotic cells, 3D printers and monitor quality using one software system. Digitally transform your parts manufacturing business to gain productivity and increase profitability. The electrode design software application in NX simplifies electrode modeling and design for any tool design that requires electrical discharge machining (EDM). NX electrode design software offers a time - saving, step-by-step solution that automates the entire EDM process, from design to production. It even helps manage even the most complex and challenging electrodes. Industrialize additive manufacturing and create revolutionary products using our integrated software . Design, simulate, prepare, print and validate prototypes or production parts on a wide range of 3D printing equipment. Automate the design of associative molds, fixtures, and stamping and progressive dies using process-based design applications. Accelerate the entire mold development process, including part design, tooling design, and motion validation. Ensure rapid response to design changes and high quality molds. Improve productivity by automating the most tedious tasks and streamlining complex progressive die design processes. Use a comprehensive solution for free-form and straight-break sheet metal parts. Use advanced features to design automotive stamping dies, including formability analysis, die planning, die face design, detailed die structure design, and die validation. A generative design process is one that engineers can adopt to rapidly develop new products based on meeting design constraints. It is an iterative process that produces quick results that the engineer can refine through constraint variation to find the best design to meet the requirements. As companies face increasing pressure to get products to market faster, designgenerative is now a necessity in product development. Engineers, constrained by time constraints, often choose the first viable design over the ideal one. It is imperative that companies adopt tools that empower engineers to find the best design to meet requirements earlier in the development process in order to stay competitive. ⇐ Back to Tools

Simcenter 3D - Minimize noise and optimize the sound quality of products. quickly gain insights into a project's acoustic performance, coupled vibroacoustics, and aeroacoustics. FEM/BEM solvers; Meshing for Acoustics; Nastran Advanced; Acoustic Transfer Vector; Acoustics HPC; Ray Acoustics – SIEMENS Simcenter 3D Acoustic Simulation Simcenter™ 3D software offers a comprehensive solution to minimize noise and optimize product sound quality. Dedicated acoustic modeling features, efficient solvers , and easy-to-interpret visualization tools allow you to quickly gain insight into a design's acoustic performance for decoupled acoustic, coupled vibroacoustics, and aeroacoustics applications. Solution Benefits Accelerate acoustic generation and modeling Deliver high-fidelity vibroacoustic simulations in the most efficient way Faster design analysis iterations with CAD-CAE test associativity Gain instant insights with specific acoustic post-processing Providing a platform for multidisciplinary simulation Accelerate acoustic simulation model creation from complex geometries, whether structural mesh model, CAD geometry or from scratch Use fast and efficient FEM/BEM solvers to provide acoustic calculations faster Effectively solve acoustics, vibroacoustics, and flow-induced noise issues from a single interface Simulate acoustic performance for indoor, outdoor or mixed interiors Accelerate various acoustic RPM calculations involving engines, gearboxes, and rotating components Perform realistic acoustic simulation: anechoic boundary condition, porous finishing materials (hard and soft frames), acoustic source, lightning noise and more Advanced features such as surface wrapping, convex meshing, mesh thickening, and the ability to create hybrid (hexa-tetra) meshes help speed up acoustic meshing processes more than traditional preprocessors. The availability of multiple material models for structure and fluid and the wide range of boundary conditions and structural and acoustic loads allow you to configure your analysis efficiently. Simcenter 3D increases realism in your simulations by providing support for loading or font creation from test data and predecessor simulations of multibody or computational fluid dynamics (CFD). Simcenter Nastran® software is used to quickly solve complex indoor and outdoor acoustics problems, thanks to key features such as Automatically Blended Layer (AML) technology and Finite Element Adaptive Ordering (FEMAO), which allows using small fluid meshes with an ideal number of Degrees of Freedom (DoF) per frequency. Simcenter 3D connects seamlessly to computer-aided design (CAD), computer-aided engineering (CAE), and even test data. Any design modification can be easily introduced into the structural and/or acoustic model, eliminating multiple conversions between file formats and recreating models. Simcenter 3D provides intuitive, easy-to-interpret post-processing tools for investigating noise such as sound pressure level (SPL), acoustic power, or directivity. Path, modal, and panel contribution analysis helps you quickly identify important noise sources and their propagation. The Simcenter 3D acoustics solution is part of a larger multidisciplinary simulation environment and is integrated with the Simcenter 3D Engineering Desktop at the core for centralized pre- and post-processing for all Simcenter 3D solutions. This integrated environment helps you achieve faster CAE processes and streamline multidisciplinary simulations that integrate acoustics and other disciplines, such as gear noise analysis from motion solutions, or NVH and vibroacoustics analysis that require structural or flow-induced loads. Sectors Industry applications Aerospace and Defense Automotive and transport Consumer goods Industrial machinery Marinho As noise can affect health and a silent product is often perceived as superior quality, companies are adopting efficient processes and tools to optimize the noise performance of their products. With Simcenter 3D, aviation engineers can predict cabin noise generated by turbulent boundary layers (TBL) in the fuselage or by aeroacoustic noise coming from the environmental control system (ECS). External noise can be solved using Edge Boundary Element Method (BEM) and FEM solvers . Spacecraft engineers can reduce the risk of their acoustic verification tests by virtually evaluating them in Simcenter 3D. During vehicle development and enhancement programs, Simcenter 3D capabilities can provide noise, vibration, and harshness (NVH) engineers with valuable insight into acoustic, vibroacoustic, and aeroacoustic noise contributions in the vehicle cabin and external environment. Building high-quality, powerful speakers, quiet vacuums and washing machines, and other noiseless consumer goods requires advanced noise engineering and sound characterization capabilities provided by Simcenter 3D. Simcenter's 3D acoustic modules provide the capabilities needed to evaluate the noise radiated by the machine, including capturing the effect of encapsulations with sound treatments. The acoustic capabilities of Simcenter 3D can be used to study complex underwater radiation from ship hulls, propellers, and submarine hull reflections of sonar waves. Módulos Simcenter 3D Meshing for Acoustics software helps create meshes for FEM and BEM acoustic analysis. The module provides advanced, easy-to-use functionality for creating an acoustic fluid mesh for both indoor and outdoor acoustic applications from an existing structural mesh or CAD geometry. Simcenter Nastran Advanced Acoustics software provides support for standard loads and boundary conditions and key technologies such as AML and FEMAO to quickly solve acoustic simulations. It is suitable for studying component acoustic radiation and pass-by noise from complete vehicles, transmission loss from pipeline systems such as intakes and exhausts or mufflers, and transmission loss from panels. Simcenter 3D Acoustic Transfer Vector software supports acoustic transfer vector (ATV) computation, expressing the sensitivity of the pressure response in a virtual microphone per unit normal velocity at field points on a radiating surface. It can be reused to quickly predict the acoustic response to any surface vibrations. Likewise, vibroacoustic transfer vectors (VATV) express the sensitivity of microphone pressures to the unitary force applied at points in a structure. Furthermore, VATV can be quickly reused to predict the acoustic response to any force load. Modal participation factors (MPFs) can also be used with ATVs in the context of modal acoustic transfer vector (MATV). Simcenter 3D Aero-Vibro-Acoustics software supports the creation of aeroacoustic sources close to turbulent noise emitting flows and allows to calculate their acoustic response in the external or internal environment; for example, for noise from heating, ventilation, and air conditioning (HVAC) and environmental control system (ECS) ductwork, train boogies and pantographs, cooling fans, ship and aircraft propellers, and much more. The product also allows defining the wind loads that act on the structural panels, leading to a vibroacoustic response; for example, in a car or airplane cabin. Simcenter 3D Load Identification allows to obtain accurate dynamic loads of a structure. Operational loads are very important for accurate response prediction, but are often impossible or difficult to measure directly. This product offers several ways to identify operating forces from measured data, either by the mounting stiffness method or the inverse matrix method. For example, in an inverse matrix method, operational vibration data can be measured under operating conditions and transfer func tions (FRFs) can be measured under controlled laboratory conditions or obtained from simulations. This data is then combined into a reverse load identification case. In addition, Simcenter 3D Load Identification supports a modal expansion solution to create enriched vibration results in a complete FE model based on measured vibrations at just a few points. Finally, a second method for deriving structural surface vibrations is provided through inverse numerical acoustics, in which pressure responses measured at just a few points close to the structure are used together with acoustic transfer vectors to identify total surface vibrations. The obtained vibration field can then be used for acoustic radiation analysis. The Simcenter 3D Environment for BEM Acoustics software supports the generation of a ready-to-run acoustic or vibroacoustic simulation model for direct BEM and indirect BEM and provides comprehensive post-processing tools to analyze the acoustic or vibroacoustic results. The Simcenter 3D Acoustics BEM solver is used to predict the acoustic response in closed and unbounded domains using a mesh only for the boundary of the fluid domain. The vibroacoustic analysis is supported by coupling the acoustic fluid with a structural modal model. Structural vibrations can also be imposed on the BEM fluid using weak vibroacoustic coupling. Simcenter 3D Acoustics Accelerated BEM software provides hierarchical matrix (H-Matrix) BEM and fast multipole (FM) BEM solvers to extend the computational limits of standard solvers . These solvers are suitable for outdoor acoustics of large structures such as vehicles and large engines, aircraft, ships, submarines, as well as high frequency applications such a ultrasonic sensors. Simcenter 3D Acoustics' time domain BEM software enables BEM solutions to resolve transient acoustic and vibroacoustic phenomena. In opposition to frequency domain based BEM solvers , Simcenter 3D Acoustics Time Domain BEM Solver offers the possibility to solve problems involving short term excitation impulsive signals in time domain. This BEM solver is suitable for applications such as parking sensor design and door slam analysis, for example. Simcenter 3D Acoustics HPC software allows you to run acoustic FEM or BEM calculations in multiprocessing mode on the parallel hardware of your choice. Parallel calculation sequences are implemented using the message passing interface (MPI) communication standard. In the case of FEM vibroacoustics, this product incorporates Simcenter Nastran's Distributed Memory Parallelization (DMP) feature. Simcenter 3D Ray Acoustics is used to predict acoustic responses up to very high frequencies and very large geometries, in closed and unlimited domains. Unlike finite element method (FEM) or boundary element method (BEM) acoustic solvers , ray acoustic solutions are not based on a fine domain discretization. Therefore, the solution is not limited by an upper frequency limit or the size of the model and the resolution is done orders of magnitude faster compared to FEM or BEM. Simcenter 3D Ray Acoustics integrates an engineering environment into Simcenter 3D to generate and post-process a ray acoustic model, as well as a ray acoustic solver , which is the CSTB ICARE solver. Module benefits: Start from a structural FEM model or CAD geometry Accelerate the acoustic meshing process for complex geometries Main features: Hybrid polygon-based thickening, hole filling, and rib removal tools Interior and exterior surface wrapping technology based on CAD or CAE model input Easy creation of convex outer boundary surface to build FEM meshes for outdoor acoustics Dominant hexadecimal hybrid hexa and tetra mesher for fluid volumes facilitating efficient solution Shell mesh thickening (reverse of mid-surface) to derive boundary surfaces of fluid cavities, which is useful for muffler and other fluid FEM meshes Module benefits: Runs vibroacoustic simulations (SOL108/SOL111) for indoor or outdoor noise Study outdoor acoustics with lean FEM models thanks to built-in AML technology Efficiently simulate broadband acoustic problems using the adaptive FEMAO solver Main features: Supports standard loads and boundary conditions, as well as specific acoustic boundary conditions such as duct modes and acoustic diffuse field (random) loads Pressure loads on structural surfaces from other acoustic or CFD analysis Porous and temperature-dependent fluid materials, average convective flow effects, frequency-dependent surface impedance, and transfer admittance between pairs of surfaces Calculate sound pressure, intensity, and power for virtual microphones located inside or outside the mesh fluid volume Module benefits: Use ATV to calculate the noise of rotating machines with loads of several revolutions per minute (RPM) up to 100 times faster Use VATV to quickly assess cabin noise due to various flow-induced pressure loads load cases such as wind loads and turbulent boundary layers Main features: ATV results are efficiently stored in a Nastran (op2) or Sysnoise (ssndb) result file ATV can be interpolated when used in a forced response context Evaluate acoustic pressure and power and panel, network, and mode contributions to ATV response Module benefits: Conservative mapping of CFD pressure results to acoustic or structural mesh Equivalent aeroacoustic surface dipole sources Equivalent aeroacoustic fan sources for tonal and broadband noise Wind loads, using semi-empirical turbulent boundary layer models or pressure loads mapped from CFD results Derive aeroacoustic sources based on lean surface pressure for stationary and rotating surfaces Provides easy-to-use, scalable load preparation for aerovibroacoustic wind noise simulations Import binary files with load data directly into Simcenter Nastran for response calculation Main features: Conservative mapping of CFD pressure results to acoustic or structural mesh Equivalent aeroacoustic surface dipole sources Equivalent aeroacoustic fan sources for tonal and broadband noise Wind loads, using semi-empirical turbulent boundary layer models or pressure loads mapped from CFD results Module benefits: Determine operating forces or vibrations that are difficult or impossible to measure directly Get a more realistic simulation by applying more accurate loading Combine measured loading data with FE simulations Main features: Assembly method for estimating assembly forces by combining operational vibration data on each side of the assembly and assembly stiffness data Inverse matrix method by combining operational measurements and transfer functions based on all measured data or a combination of operational measurements and simulation data Simple application and reuse of forces or vibrations identified in the simulation model Module benefits: Provide a user-friendly interface to simplify the creation of acoustic BEM models for standard and accelerated BEM solvers Supports pure acoustic issues as well as weak or fully coupled vibroacoustic response via modal-based framework definition Leverage dedicated post-processing capabilities to improve engineering insight and user productivity Main features: Provide all standard structural and acoustic loads and boundary conditions to accurately describe your vibroacoustic issues Prepare deterministic and random acoustic and vibro-acoustic analysis Standard post-processing of acoustic results such as acoustic pressure and power and structural vibrations Dedicated diagnostic graphs showing panel contributions and structural modal contributions to acoustic pressure or power Module benefits: BEM solvers , fast and efficient to solve purely acoustic and vibroacoustic problems A multitude of acoustic and structural loads and boundary conditions are supported for an accurate description of your vibroacoustic simulation model Automatic BEM model corrections for free and seam edges Main features: Direct and indirect decoupled acoustic solutions Indirect, loosely coupled and strongly coupled vibroacoustic solutions Deterministic and random acoustic and vibroacoustic analysis Returns standard acoustic and structural response results Provides structural panel contributions and modal contributions to acoustic pressure or power Solutions Guide | Simcenter 3D for acoustic simulation Module benefits: Provides faster calculations for large BEM models (larger geometry and/or higher frequencies) Requires less system memory than standard BEM Supports uncoupled acoustic response as well as coupled vibro-acoustic response simulation Main features: Includes a fast iterative multipole solver as well as a direct hierarchical H-Matrix solver Both solvers support parallel computing, including up to four processes for free, or using more than four processes, when combined with Simcenter 3D Acoustics High Performance Computing (HPC) software Supports the convection effect of a medium (uniform) flow on acoustic wave propagation Module benefits: Allows accurate modeling of transient infinite domain problem Provides solutions to purely acoustic and vibroacoustic problems Provides fast and efficient time-domain solver , also for large models Main features: Dedicated Simcenter 3D Acoustics Transient BEM solver environment for time-domain BEM calculations, i ncluding two analysis types: acoustic transient and vibro-acoustic transient Supports various loads and boundary conditions: Acoustic transient: acoustic monopole, plane wave, infinite plane, acoustic absorber, transfer admittance Transient vibro-acoustics: force applied to the structure (with defined mode representation), pre-computed vibrations, infinite plane, acoustic absorber, transfer admittance, panel Solutions guide | Simcenter 3D for acoustic simulation Module benefits: Accelerates acoustic calculations using multithreading , shared memory parallelization (SMP), multiprocessing, and DMP This product supports high performance computing for Simcenter 3D Acoustics FEM and BEM solvers Main features: Solvers can run in high-performance computing mode on multi-node clusters as well as on multi-core workstations Allows you to solve high frequency problems with DMP for which near linear parallel speed can be expected Module benefits: Solve high-frequency acoustic simulations for large models in a fraction of the time required with FEM or BEM solvers A coarse mesh can be used as it captures model geometry, simplifying model creation Standard acoustic loads and boundary conditions are supported for accurate description of the simulation model Advanced results and post-processing to explore ray path arrivals or sound quality criteria Main features: Returns acoustic results in both frequency and time domains Simulates ray propagation of acoustic waves with adaptive beam-tracking technology Accurately simulates reflections on curved surfaces despite coarse mesh discretization Capture multi-order diffraction effects and creeping waves Captures late reflections and diffusion effects with particle tracking technology Supports standard acoustic loads including point source directivity ___________________________________________________________________________ Simcenter 3D Meshing for Acoustics ___________________________________________________________________________ Simcenter Nastran Advanced Acoustics ___________________________________________________________________________ Simcenter 3D Acoustic Transfer Vector ___________________________________________________________________________ Simcenter 3D Aero-Vibro-Acoustics ___________________________________________________________________________ Simcenter 3D Load Identification ___________________________________________________________________________ Simcenter 3D Environment for BEM Acoustics ___________________________________________________________________________ Simcenter 3D Acoustics BEM solver ___________________________________________________________________________ Simcenter 3D Acoustics Accelerated BEM solver ___________________________________________________________________________ Simcenter 3D Acoustics Time Domain BEM solver ___________________________________________________________________________ Simcenter 3D Acoustics HPC ___________________________________________________________________________ Simcenter 3D Ray Acoustics ⇐ Back to Simcenter

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