Best Computer-Aided Engineering (CAE) Software in Australia - Page 3

Simio is a software solution focused on simulation, production scheduling, and planning, specifically tailored to leverage the object modeling approach. Its primary goal is to provide organizations, regardless of their size or sector, with tools for swift risk assessment and cost-saving opportunities. To cater to varying business requirements, Simio is offered in five distinct versions: Personal, Design, Team, Enterprise, and Portal. Additionally, there is an Academic Edition designed for the use of both students and educators. This diverse range of editions ensures that all users can find a version that aligns with their specific needs and objectives.

Elevate your product design and development process by utilizing Creo, the advanced 3D CAD/CAM/CAE software that enables you to imagine, design, create, and innovate with ease. In today's competitive landscape, product design and manufacturing teams face increasing demands to enhance efficiency and reduce costs while maintaining high standards of creativity and quality. Thankfully, Creo offers a diverse and scalable suite of 3D CAD tools that stand out in the market. The latest version, Creo 7.0, introduces groundbreaking advancements in generative design, real-time simulation, multibody design, additive manufacturing, and more. Transitioning your ideas from initial concept to digital prototype has never been simpler, more accurate, or more intuitive than with Creo, which has been at the forefront of CAD technology for over three decades. With the release of Creo 7.0, PTC showcases its expertise in enriching an already powerful toolset, leveraging strategic partnerships to further enhance its functionalities and meet evolving industry needs. This evolution points to a future where your design capabilities can grow alongside your business aspirations.

Twinn Witness, created by Royal HaskoningDHV, is an advanced predictive simulation tool that allows organizations to build dynamic virtual representations of their current and future facilities and operations. Through the exploration of various hypothetical scenarios, users can gain valuable business insights and test their decisions without any associated risk. The software delivers both two-dimensional and immersive three-dimensional simulation models, which enhance communication and foster a better understanding of processes and the connections between data. It is designed to be user-friendly, adaptable, and highly effective, providing comprehensive insights into capital expenditures, ongoing improvements, and operational enhancements prior to any financial commitments. This ultimately leads to enhanced performance, lowered costs, and the establishment of strong business cases that promote sustainable growth and maximize return on investment. Additionally, Twinn Witness empowers organizations to make informed decisions that align with their long-term strategic objectives.

In January 2015, we introduced a cloud-based solution for computer-aided engineering known as SimForDesign (Simulation Streamlined For Design), which was specifically tailored for designers, enabling users to perform strength engineering analysis without needing specialized knowledge. This innovative service offers a quick and economical method for conducting verification calculations. At present, the capabilities of SimForDesign are confined to static analysis of individual parts and basic assemblies. We are actively enhancing the platform to include a wider variety of assembly types for analysis. Accessible from anywhere globally with an Internet connection, this cloud service eliminates the need for installation, making it user-friendly and convenient. Our ongoing improvements aim to broaden the application range and enhance the overall utility of SimForDesign for designers.

HyperWorks offers easy-to-learn and effective workflows that leverage domain expertise and increase team productivity. This allows for efficient development of today's complex and connected products. Engineers can now move seamlessly from one domain to another with the new HyperWorks experience. They can even create reports without ever leaving the model. HyperWorks allows you to create, explore, and optimize designs. These designs can accurately model structures, mechanisms and fluids as well as electrical, embedded software, systems designs, and manufacturing processes. The solution-specific workflows improve a variety of engineering processes, including fatigue analysis, CFD modeling, concept design optimization, design exploration, and CFD modeling. Each interface is intuitive and well-designed, and differentiated for each user. It's also consistent and easy to use.

Design Force is a revolutionary innovation in electrical design. It allows you to break down the boundaries of your electrical design process. The process of designing a product is becoming more complex. This often involves technologies that are difficult or impossible to use ECAD tools to address. Design Force allows design teams to access system-level design information as early as the planning and conceptual phases. This allows them to layout each product board while simultaneously considering the entire system view. Design Force uses the most current industry hardware and software. Users can design in a native 3D environment. This allows them to achieve optimal performance by using native 64-bit, multithreading, multicore processors. Design Force is compatible with multiple client-server implementations. You can also work from your corporate cloud.

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.

Adams assists engineers in analyzing the behavior of moving components and the distribution of loads and forces in mechanical systems. Often, product manufacturers find it challenging to grasp the actual performance of their systems until late in the design phase. While individual mechanical, electrical, and other subsystems are checked against their designated requirements during the systems engineering process, comprehensive testing and validation of the entire system occur much later, which can result in costly rework and riskier design modifications compared to adjustments made earlier. As the leading and most widely recognized Multibody Dynamics (MBD) software globally, Adams enhances engineering productivity and lowers product development expenses by facilitating early validation of system-level designs. This tool enables engineers to assess and manage the intricate interactions across various disciplines such as motion, structures, actuation, and controls, ultimately leading to optimized product designs that prioritize performance, safety, and user comfort. Additionally, the early insights provided by Adams can significantly streamline the overall design process, paving the way for more innovative solutions.

MASTA serves as a comprehensive collection of CAE tools designed for the creation, simulation, and analysis of driveline systems, spanning from initial concepts to final production. It allows for the precise and swift development of transmission systems, whether starting from scratch or utilizing existing designs. Users gain an in-depth understanding of how mechanical components will perform throughout their lifecycle, particularly under various customer duty cycles. This software enables the early identification of potential failure modes during the product development phase, facilitating quicker adjustments to design. Key performance metrics can be predicted efficiently during the design process, allowing for extensive evaluation of modifications to transmission configurations, component choices, materials, and manufacturing techniques within a simulated environment. Full system simulations are feasible for any transmission or driveline setup, and integrating manufacturing simulations during design helps to minimize both development time and costs. The unique and modern framework of MASTA, developed entirely in C#, enhances its stability and compatibility with current and future operating systems. Overall, MASTA stands out as a robust solution that addresses the evolving needs of driveline design and analysis.

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.

The gear calculation encompasses all prevalent gear types, including cylindrical, bevel, worm, crossed helical, hypoid, and face gears. Alongside calculations adhering to standards such as ISO, DIN, AGMA, and VDI, a variety of sizing and optimization tools are available, along with methodologies that extend beyond the established standards. The integration of shaft and bearing calculations is fully realized within KISSsoft®, allowing for the optional assessment of shaft strengths and bearing rating life while factoring in internal geometry in accordance with ISO TS 16281. The calculation process can consider multiple coaxial shafts and their associated bearings, with the determination of torsion and bending-critical eigenfrequencies for these shafts. During the evaluation of shaft-hub connections, the system verifies the validity of each connection and ensures that the resulting pressures do not exceed the allowable material characteristic values. Furthermore, all calculation modules provide sizing capabilities for strength-relevant geometric dimensions alongside the maximum torque that can be transmitted, enhancing the overall precision of the analysis. This comprehensive approach not only streamlines the design process but also improves reliability in mechanical applications.

Simufact Additive is an advanced and adaptable software tool designed for simulating metal-based additive manufacturing techniques. Learn how to effectively utilize Simufact Additive to enhance your metal 3D printing and rapid prototyping efforts. By employing this software, you can greatly minimize the need for numerous test prints. Our objective is to furnish you with a solution that enables the production of additive manufacturing components with consistent dimensional accuracy on the first attempt. The multi-scale approach of Simufact Additive integrates the most effective methods into a singular software solution, ranging from a rapid mechanical technique to an intricate thermal-mechanical coupled transient analysis that offers exceptional precision in simulation results. Users can select the most suitable simulation method according to their specific requirements. Simufact Additive stands out as a specialized software solution focused solely on the simulation of additive manufacturing processes, which is evident in its streamlined operating framework. This focused approach not only enhances usability but also improves overall efficiency in the design and production workflow.

Additive Works delivers innovative software solutions designed to achieve a "first-time-right" additive manufacturing experience by incorporating advanced analysis and simulation tools into the Laser Beam Melting (LBM, SLM, DMLS, Metal 3D Printing) workflow. Responding to the current demands and challenges faced in industrial additive manufacturing, their software suite, Amphyon, seeks to significantly lower pre-processing expenses and elevate metal additive manufacturing towards higher levels of automation. The ASAP-Principle outlines four essential stages for achieving a stable, efficient, and dependable process chain: Assessment, Simulation, Adaption, and the Process itself. During the Assessment phase, all possible build orientations are evaluated concerning both economic and physical factors, allowing for the identification of design limitations as well as the determination of optimal build orientations. This comprehensive approach not only enhances manufacturing efficiency but also ensures higher quality outcomes in the production process.

Digimat-AM is a software solution offered by Digimat that provides simulation capabilities for the additive manufacturing process, enabling both printer manufacturers and end-users to detect potential manufacturing challenges. Additionally, it fine-tunes printing parameters to enhance productivity and optimize the performance of the final product before the initial print is made. By leveraging numerical simulation, users can significantly reduce the number of trials needed, transforming complex testing into just a few clicks. This powerful tool equips engineers with the ability to simulate various processes, including FFF, FDM, SLS, and CFF, for both unfilled and reinforced materials. It also forecasts potential issues such as warpage, residual stresses, and the microstructure that may arise during printing. Furthermore, Digimat-AM facilitates the analysis of the intertwined thermal and structural responses in both types of polymers, ensuring that the correct manufacturing settings are established for precise printing. Ultimately, this innovative solution serves to connect the intricacies of the printing process with material properties and the performance of the final parts produced.

Ansys Sherlock stands out as the sole electronics design tool based on reliability physics, delivering swift and precise lifespan forecasts for electronic components, boards, and systems during the initial design phases. This automated analysis tool not only accelerates the design process but also effectively circumvents the traditional "test-fail-fix-repeat" methodology by allowing designers to meticulously simulate the interactions between silicon, metal layers, semiconductor packages, printed circuit boards (PCBs), and assemblies to identify potential failure risks stemming from thermal, mechanical, and manufacturing stresses prior to creating a prototype. With its extensive library of over 500,000 components, Sherlock efficiently transforms electronic computer-aided design (ECAD) files into detailed computational fluid dynamics (CFD) and finite element analysis (FEA) models. Each generated model is crafted with precise geometries and material characteristics, offering a comprehensive translation of stress data. This innovative approach not only enhances the design process but also significantly reduces time-to-market for electronic products.

Ansys Discovery introduces a groundbreaking simulation-driven design tool that integrates instantaneous physics simulation, high-fidelity analysis, and interactive geometry modeling into a single, user-friendly platform. This innovative product merges interactive modeling with diverse simulation functionalities, enabling designers to address essential design inquiries earlier in the development stage. By adopting this proactive approach to simulation, teams can significantly reduce the time and resources spent on prototyping while evaluating various design ideas in real-time, eliminating the delays typically associated with waiting for simulation outcomes. The speed and precision with which Ansys Discovery responds to critical design questions enhances productivity and performance, allowing engineers to concentrate on creativity and optimizing product efficacy. Consequently, Ansys Discovery not only minimizes labor and costs associated with physical prototyping but also leads to a notable return on investment for organizations, fostering an environment of continuous improvement and innovation. Ultimately, by streamlining the design process, Ansys Discovery empowers teams to achieve their objectives more efficiently than ever before.

Ansys MotorCAD is a dedicated tool for electric machine design. It allows you to quickly simulate multiphysics across the entire torque-speed operating range. Motor-CAD allows engineers to evaluate motor topologies across the entire operating range. This allows them to create designs that are optimized for size, efficiency, and performance. Motor-CAD software's four modules, Emag, Therm Lab, Mech, allow multiphysics calculations to be performed quickly, iteratively, and users can move from concept to final design in a shorter time. Motor-CAD users can explore more motor topologies and fully evaluate the impact of advanced loss effects during the initial stages of an electrical mechanical design with Motor-CAD's streamlined data input process. This release features powerful new features for design optimization and multi-physics analysis, as well as system modeling for electric motors. Multiphysics simulations are fast across the entire torque-speed range.

PDS® is an all-encompassing and advanced computer-aided design and engineering tool. Focused on production efficiency, PDS ensures optimal design outcomes while minimizing the overall installed costs associated with projects. This application not only boosts value and mitigates risk but also maintains the integrity of data throughout the process. Since the mid-1980s, it has been the preferred choice among owner operators and engineering, procurement, and construction firms worldwide for various design initiatives. It features dynamic walkthroughs, enabling operations and maintenance teams to engage with the virtual plant before actual construction begins. Moreover, PDS offers a specification-driven design approach, performing both "hard" and "soft" interference checks, and it generates precise material take-offs. Additionally, it comes equipped with a wealth of customizable reference data that adheres to industry standards, further enhancing its utility in diverse engineering projects.

HEEDS is an advanced software suite designed for design space exploration and optimization that seamlessly connects with various commercial computer-aided design (CAD) and computer-aided engineering (CAE) tools to foster product innovation. By automating analysis workflows, HEEDS significantly speeds up the product development cycle (Process Automation), optimizes the use of computational resources (Distributed Execution), and conducts thorough explorations of the design landscape for creative solutions (Efficient Search), while also ensuring that new designs meet performance standards through rigorous assessment (Insight & Discovery). The software facilitates automated workflows, streamlining the product development process for users. HEEDS boasts a comprehensive array of pre-built interfaces for numerous CAD and CAE applications, allowing for rapid and effortless integration of different technologies without requiring custom scripts. Moreover, data can be shared automatically among various modeling and simulation tools to assess and compare performance trade-offs effectively, enhancing decision-making in the design process. This interconnectedness not only saves time but also leads to more innovative and effective product solutions.

AVEVA E3D Design stands out as the premier 3D design solution in the world, specifically tailored for the process plant, marine, and power sectors. It provides exceptional visualization capabilities and ensures that multi-discipline 3D designs are clash-free, all while swiftly generating precise drawings and reports that help to minimize costs, timelines, and commercial risks associated with both new and existing capital projects. This advanced tool is recognized for its superior productivity and functionality, seamlessly integrating with other AVEVA Engineering and Design solutions, including AVEVA Unified Engineering. Accessible through the secure cloud platform AVEVA™ Connect, it allows for rapid deployment in a matter of days or weeks, rather than the usual months, enabling users to compile data and develop their engineering digital twin in the cloud concurrently with their work. Furthermore, AVEVA E3D Design can be easily tailored and set up to meet the unique requirements of various companies or projects, making it an invaluable asset across all industries, whether in the industrial plant sector or marine applications. This flexibility ensures that clients can maximize efficiency and innovation in their design processes.

Simcenter Femap is a sophisticated simulation tool designed for the creation, modification, and analysis of finite element models pertaining to intricate products or systems. This software allows users to implement advanced workflows for modeling individual components, assemblies, or entire systems, enabling them to assess how these models react under realistic conditions. Moreover, Simcenter Femap offers robust data-driven capabilities and graphical visualizations for results interpretation, which, when paired with the top-tier Simcenter Nastran, provides a holistic CAE solution aimed at enhancing product performance. As manufacturers strive to develop lighter yet more robust products, there is a growing emphasis on the utilization of composite materials. Simcenter stands at the forefront of composite analysis, continually advancing its material models and element types to meet industry demands. Furthermore, Simcenter accelerates the simulation process for laminate composite materials by providing an integrated connection to composite design, streamlining workflows for engineers in the field. This integration ultimately fosters innovation and efficiency in product development, paving the way for more sustainable manufacturing practices.

When utilized at the outset of the product development process, Inspire enhances the speed and effectiveness of creating, refining, and analyzing innovative and structurally sound components and assemblies through teamwork. Its award-winning interface for designing and altering geometries can be mastered in just a few hours, while providing trustworthy computational power from Altair solvers. With the rapid and precise structural analysis capabilities of Altair® SimSolid®, independently verified by NAFEMS, users can evaluate extensive assemblies and intricate components. Additionally, dynamic motion simulations, which include load extraction, leverage the robust multi-body system analysis offered by Altair® MotionSolve®. The leading standard for achieving structural efficiency, topology optimization via Altair® OptiStruct®, facilitates the generative design of functional, feasible, and manufacturable geometries. Inspire empowers both simulation analysts and designers to conduct what-if scenarios more swiftly, conveniently, and notably at earlier stages, fostering collaboration across teams. This early integration of Inspire in the design process not only streamlines workflows but also promotes innovation in product development.

A robust and adaptable preprocessor designed for generating high-quality finite element meshes at an appealing cost that is significantly lower than international alternatives. It offers strength assessments for both static and dynamic loads, as well as the ability to determine natural frequencies and vibration modes. Users can also analyze critical loads and buckling modes effectively. The software supports both 2D and 3D computations for various structures, including volumetric, thin-walled, and bar configurations. It incorporates elastoplastic deformation analysis based on the Mises and Drucker-Prager models, alongside strength evaluations for large displacements. Additionally, it calculates thermal conditions, heat loss, and temperature-induced deformations in parts and structures, while also providing strength assessments for materials with high elasticity. This comprehensive approach ensures that engineers can conduct thorough analyses across a wide range of applications.

Ansys Gateway powered with AWS is the solution to developers, designers, engineers, and others who want to manage their Ansys Simulation & CAD/CAE development in the cloud. You can access cloud computing resources anywhere, on any device, via your web browser. Cloud applications can be created, customized, and connected with minimal technical knowledge. You can simply install third-party applications alongside Ansys apps. AWS cloud can help you accelerate innovation by removing the hardware barrier on-premises for High Performance Computing (HPC). Ansys' expertise in the configuration and deployment of Virtual Desktop Interfaces (VDI), and High Performance Computing (HPC) is your advantage Your AWS subscription allows you to manage and control your cloud CAD/CAE consumption and costs.

samadii/em oftware that analyzes and calculates the electromagnetic field in 3d space using the Maxwell equation using vector FEM ad GPU computing. it provides electrostatics, magnetostatics as well and induction electronics, including the low-frequency and high-frequency ranges. samadii/em provides a multi-physics approach and high-performance electromagnetics simulation, with Samadii you can quickly address problems from semiconductors and displays to wireless communications, etc.