EMWorks | Electromagnetic Simulation Software

Navigating the complexities of electromagnetic design requires a strategic balance between magnetic flux concentration and field uniformity to enhance overall performance. In our upcoming webinar on October 31st, our experts will explore the trade-offs among various Halbach array topologies. We'll also demonstrate how to leverage advanced simulation tools from EMWorks for informed design decisions. Swipe through the post below to deepen your understanding and elevate your design skills. Secure your spot by registering via the link in the first comment. #MagneticFluxOptimization #ElectromagneticApplications #SimulationTechniques

Optimizing Halbach Arrays for Improved Performance: A Webinar on Electromagnetic Simulation Are you struggling with magnetic flux optimization and field uniformity in your designs? In many electromagnetic applications, achieving the right balance between flux concentration and uniformity is key to improving performance. Our upcoming webinar on October 31st will show you how to solve these issues with simulation techniques that drive real results.    In this session, you'll learn how to:  - Analyze magnetic fields in different Halbach array topologies  - Compare performance trade-offs between flux concentration and field distribution  - Apply simulation results to make more informed design decisions    Discover the benefits of improved electromagnetic simulation. Register now to learn how to optimize your designs and enhance your simulation workflows.    (Registration link in the first comment)    #MagneticFluxOptimization #ElectromagneticApplications #SimulationTechniques #EngineeringSolutions   

𝗧𝗵𝗲 𝗜𝗺𝗽𝗼𝗿𝘁𝗮𝗻𝗰𝗲 𝗼𝗳 𝟮𝗗 𝗮𝗻𝗱 𝟯𝗗 𝗠𝗼𝗱𝗲𝗹𝘀 𝗶𝗻 𝗘𝗹𝗲𝗰𝘁𝗿𝗼𝗺𝗮𝗴𝗻𝗲𝘁𝗶𝗰 𝗦𝗶𝗺𝘂𝗹𝗮𝘁𝗶𝗼𝗻 𝗳𝗼𝗿 𝗘𝗻𝗴𝗶𝗻𝗲𝗲𝗿𝘀 For engineers working on complex systems like wireless power transfer (WPT) for electric vehicles, access to both 2D and 3D models is essential. 2D models allow for precision analysis, enabling engineers to focus on specific aspects of the design and quickly detect potential issues. In contrast, 3D models provide a comprehensive view, allowing for full system visualization and a better understanding of component interactions in a real-world environment. With the ability to superimpose 2D models onto 3D models, engineers can visualize both detailed and holistic views of their designs, improving performance, accuracy, and overall system efficiency. This dual approach leads to more informed decision-making and reduces the risk of design flaws further down the line. Here is a webinar about the Design and Analysis of Wireless Power Transfer Charger for Electric Vehicles, where you will see the superimposition of the 2D and 3D model. The link is in the first comment. #EngineeringSimulation #2D3DModeling #ElectricVehicles

Key Challenges in Wireless Power Transfer (WPT) for Electric Vehicles Engineers developing wireless power transfer systems for electric vehicles face significant challenges that can impact efficiency, reliability, and cost-effectiveness. Addressing these challenges is critical for improving the performance of electric vehicle (EV) charging solutions. Low Efficiency Due to Air Gap Distance As the distance between transmitter and receiver coils increases, the magnetic coupling weakens, leading to a significant loss of power transfer efficiency. Accurate electromagnetic field simulations can optimize coil designs to reduce these losses. Misalignment During Vehicle Parking Misalignment between coils during vehicle parking can cause a drop in efficiency. Engineers need simulation tools that allow testing of multiple configurations and alignments to improve system tolerance and performance, even when misalignment occurs. Electromagnetic Interference (EMI) and Shielding EMI can interfere with the vehicle's electronics and other external systems. Electromagnetic loss calculations, including eddy currents and core losses, are essential to design efficient shielding and minimize interference, ensuring the system remains compliant with safety standards. Size and Weight of the Charger The physical dimensions and weight of the charging unit are important for integration into the vehicle. Structural and thermal stress simulations help engineers evaluate various designs to optimize both performance and the overall form factor. Generated Heat Excessive heat generation can compromise system performance and safety. Thermal management simulations provide insights into heat dissipation, helping to design systems that operate efficiently under safe temperature conditions. Cost Considerations Balancing cost and performance is a constant challenge in WPT systems. By running simulations across multiple configurations, engineers can optimize designs to enhance performance while keeping costs within target limits. Circuit system simulations also ensure a seamless integration of the physical model and electrical system, reducing costly design iterations. These challenges can be addressed through the advanced electromagnetic simulation tools offered by EMWORKS, enabling engineers to develop efficient, reliable, and cost-effective wireless power transfer systems for electric vehicles. Learn more by checking out our application notes about wireless power transfer by clicking the link in the first comment of this post. #ElectromagneticSimulation #WirelessCharging #ElectricVehicles

New to EMWORKS-MotorWizard? Watch our 'Getting Started' training video to learn how to design and analyze motors with ease! In this step-by-step guide, we cover everything from project setup to running performance analyses and visualizing results. The full video link is in the comment! #motorwizard #motordesign #simulationsoftware

Induction cooking technology is known for its precise control and energy efficiency. The thermal performance of induction cookware is critical in optimizing heat transfer, energy consumption, and cooking speed. Advanced electromagnetic simulation tools such EMWORKS enable comprehensive thermal analysis of induction cooker pots. With detailed insights into magnetic field distribution and heat transfer, engineers and manufacturers can improve product design, ensuring uniform heat distribution and minimizing energy waste. The key benefits of electromagnetic simulation for induction cookware include: - Accurate thermal modeling to optimize heat distribution - Identification of potential hotspots for greater energy efficiency - Enhanced designs for consistent, high-performance cooking Electromagnetic simulation allows manufacturers to integrate thermal behavior into the design process, leading to more efficient, cost-effective, and high-quality products. The ability to predict heat flow and optimize cookware design is essential for delivering superior induction cooking solutions. For more details on the attached application note on Thermal Analysis of an Induction Cooker Pot for Improved Efficiency to refine product designs, visit link in the first comment. #ElectromagneticSimulation #ThermalAnalysis #InductionCooking

This application note examines advancements in DC contactor design, focusing on a three-part contactor with electronic control and permanent magnets, engineered to enhance energy efficiency and reduce noise in electrical switchgear. The study includes Magnetostatic simulations that analyze the electromagnetic behavior, such as the force across a nonlinear ferromagnetic core. Key findings include a peak flux density of 0.98 T at 2A current excitation, along with insights into the dynamic response of the contactor's moving parts. For a detailed analysis of this innovative design, read the full application note in the link provided in the first comment. #ElectromagneticDesign #ElectricalEngineering #SwitchgearTechnology

Magnetic flux density is a critical quantity that is not visible to the naked eye but can be detected and visualized through simulation software like EMWORKS. In the short video below, a section plot of a solenoid's magnetic flux density is displayed, highlighting areas of low and high flux density with corresponding values on the chart. In this model, the maximum magnetic flux density reaches 2 Teslas. This plot is particularly useful for identifying regions where magnetic saturation of steel might occur, allowing for adjustments to improve the design, such as adding thickness to areas with higher magnetic flux density. For more information on solenoids and how to visualize magnetic flux density, click the link in the first comment below. #ElectromagneticSimulation #MagneticFlux #EngineeringDesign

Designing magnetic levitation systems requires careful management of magnetic fields, control systems, thermal effects, and electromagnetic interference. EMWorks' advanced simulation tools tackle these challenges effectively by optimizing magnetic fields, fine-tuning control strategies, and analyzing thermal impacts. Their solutions also help reduce electromagnetic interference. EMWorks enables engineers to simplify the design process, boost system performance, and transition smoothly from prototypes to full-scale implementations.  To learn more about our solutions, dive into our application note section for maglev systems:  https://lnkd.in/dveWXvgt #Maglev #Simulation #Electromagnetics

Experience the future of magnetic levitation system design with EMWorks’ virtual prototyping tools in this brief preview. Be sure to attend our webinar on August 29th for a comprehensive exploration of how to optimize maglev systems effectively.  Secure your spot now! https://lnkd.in/dybpTDWZ  #Maglev #Electromagnetics #Simulation #AutodeskInventor