Empowering Design Engineers with Simulation Democratisation

Empowering Design Engineers with Simulation Democratisation

Table of Contents

1. Introduction
2. What is ANSYS AIM?
3. The Need for Democratization of Simulation
4. Simulation-Driven Product Development
5. The Power of ANSYS AIM
6. Customization and Automation with ANSYS AIM
7. Examples of Custom Process Templates
8. Integrating ANSYS AIM with CAD Systems
9. Extensions and Apps in ANSYS AIM
10. Conclusion

Introduction

In this article, we will explore ANSYS AIM, a powerful tool for simulation in engineering. We will discuss how ANSYS AIM enables the democratization of simulation, making it accessible to design engineers and users without specialized knowledge in simulation software. We will also Delve into the customization and automation capabilities of ANSYS AIM, showcasing examples of custom process templates and extensions. Additionally, we will explore how ANSYS AIM can be integrated with various CAD systems. By the end of this article, You will have a comprehensive understanding of ANSYS AIM and its applications in the field of simulation-driven product development.

What is ANSYS AIM?

ANSYS AIM is an integrated solution for 3D engineering simulation that combines the breadth of ANSYS physics in an easy-to-use environment. Built on the ANSYS Workbench platform, ANSYS AIM is designed to enable simulation democratization, allowing design engineers and casual users to perform simulations without extensive expertise in simulation software. With ANSYS AIM, users can import geometry from their CAD systems, Apply meshing, define physics, run simulations, and analyze results, all within one software tool.

The Need for Democratization of Simulation

Simulation-driven product development has become increasingly popular in recent years. Rather than relying solely on physical prototypes, companies are using simulation to couple design and analysis in the early stages of product development. This trend is driven by the growing complexity of products, which often require multiphysics simulations to meet various requirements. ANSYS AIM addresses this need by providing a user-friendly interface that allows design engineers to perform simulations and analyze results without extensive knowledge of simulation software.

Simulation-Driven Product Development

Simulation-driven product development involves the use of simulation tools throughout the design process to optimize product performance and meet design requirements. This approach eliminates the need for extensive physical testing and prototyping, saving time and resources. For example, in automotive design, simulations are used to test structural dynamics, crashworthiness, fluid flow, and electromagnetic effects. By simulating these different physics, engineers can optimize the design and ensure the various subsystems work together effectively. ANSYS AIM is specifically tailored to facilitate simulation-driven product development, providing a platform for performing multiphysics simulations and analyzing the results.

The Power of ANSYS AIM

ANSYS AIM offers a wide range of capabilities that make it a powerful tool for simulation. It allows users to import geometry from various CAD systems, customize material properties, apply loads and constraints, and analyze results. The user-friendly interface and predefined process templates make it easy for design engineers to navigate the software and perform simulations. Additionally, ANSYS AIM supports customization and automation, allowing users to Create their own custom process templates or use extensions developed by experts. With ANSYS AIM, users can optimize their designs, make informed decisions, and achieve accurate results.

Customization and Automation with ANSYS AIM

One of the key features of ANSYS AIM is its ability to be customized and automated. Users can create their own custom process templates to streamline their simulation workflows and deploy best practices throughout their organizations. Additionally, ANSYS AIM supports scripting in XML and Python languages, allowing advanced users to further automate the software and add custom functionality. This customization and automation capability enables companies to tailor ANSYS AIM to their specific simulation needs and accelerate The Simulation process.

Examples of Custom Process Templates

ANSYS AIM offers a variety of predefined process templates for different physics simulations, such as structural, fluid flow, thermal, and electromagnetic analyses. However, users can also create their own custom process templates to automate specific simulation tasks and capture their expertise. These custom templates can be shared and deployed within an organization, allowing design engineers to consistently perform simulations using established best practices. Examples of custom process templates include hip implant analysis, internal flow analysis, and wind tunnel design. These templates enhance the simulation capabilities of ANSYS AIM and enable companies to perform specialized simulations specific to their industry or product.

Integrating ANSYS AIM with CAD Systems

ANSYS AIM provides seamless integration with various CAD systems, allowing users to import geometry and directly launch ANSYS AIM from within their CAD software. This integration simplifies the workflow and ensures that the simulation analysis is performed on the most up-to-date design. Users can edit geometry, define physics, run simulations, and analyze results within ANSYS AIM, without the need to switch between different software tools. CAD interfaces are available for popular CAD systems such as Creo and SolidWorks, making it convenient for users to import their designs into ANSYS AIM.

Extensions and Apps in ANSYS AIM

ANSYS AIM offers a range of extensions and apps that further enhance its capabilities. These extensions, available in the ANSYS App Store, allow users to perform specialized simulations or access additional features within ANSYS AIM. Examples of extensions include the hip implant analysis extension, internal flow extension, and wind tunnel design extension. These extensions are developed by ANSYS experts and provide users with ready-to-use solutions for specific simulation tasks. By leveraging these extensions, users can extend the functionality of ANSYS AIM and perform advanced simulations with ease.

Conclusion

ANSYS AIM is a powerful tool for simulation in engineering, enabling simulation democratization and enhancing the efficiency of product development. By providing an easy-to-use and customizable interface, ANSYS AIM allows design engineers to perform simulations without extensive expertise in simulation software. With its broad range of features, ANSYS AIM supports simulation-driven product development and empowers design engineers to optimize their designs and make informed decisions. By leveraging the customization and automation capabilities of ANSYS AIM, companies can deploy best practices and accelerate their simulation workflows. With seamless integration with CAD systems and the availability of extensions and apps, ANSYS AIM offers a comprehensive solution for engineering simulation.