Enhance Product Design with ANSYS AIM Simulation and Templates

Table of Contents:

1. Introduction
2. Importance of Simulation in Product Development
3. An Introduction to ANSYS AIM
4. Using Process Templates in ANSYS AIM 4.1. Starting with a Template 4.2. Importing Geometry and Meshing 4.3. Defining Physics and Boundary Conditions 4.4. Solving and Viewing Results
5. Customizing Process Templates in ANSYS AIM 5.1. Scripting and Extension Creation 5.2. Creating Application-Specific Templates 5.3. Creating Custom Help Files
6. Examples of Custom Process Templates 6.1. Hip Implant Analysis 6.2. Electrostatic Field Analysis 6.3. Internal Flow Analysis 6.4. Virtual Wind Tunnel Application
7. FAQ 7.1. Can ANSYS AIM handle combustion simulation with thermal stress analysis?
8. Conclusion

Article:

Introduction

Welcome to the Tristar webinar on the use of ANSYS AIM and its process templates. In today's webinar, we will discuss the importance of simulation in product development and how ANSYS AIM provides an easy-to-use solution for engineers. We will also explore the customization options available in ANSYS AIM, including the creation of custom templates. So let's dive right in!

Importance of Simulation in Product Development

Simulation plays a crucial role in the early stages of product development. Whether it's analyzing the structural dynamics of a car's b-Pillar or designing the body Shape for optimal aerodynamics, simulation allows engineers to evaluate different design options and make informed decisions before costly physical prototypes are built. Furthermore, simulation is essential for developing and verifying advanced systems such as active safety features and autonomous driving capabilities. By simulating various scenarios, engineers can ensure that these systems work together seamlessly and meet performance, reliability, and safety requirements.

In today's complex products, multiple physics need to be analyzed. ANSYS AIM provides a comprehensive solution by offering predefined process templates for single physics simulations, as well as the ability to combine multiple physics in a single environment. This eliminates the need for engineers to learn and use multiple specialized tools, simplifying The Simulation process and saving time. Additionally, ANSYS AIM leverages the power of the ANSYS solver and physics to deliver accurate results and enable engineers to optimize their designs effectively.

An Introduction to ANSYS AIM

ANSYS AIM is an integrated solution for engineering simulation that combines the breadth and depth of ANSYS physics with an intuitive and immersive user interface. It allows engineers to perform 3D engineering simulations using the CAD data they are already familiar with. With ANSYS AIM, every engineer can leverage the power of the ANSYS solver and access a wide range of physics, including structural analysis, fluid flow analysis, thermal analysis, and electromagnetic analysis.

The user interface of ANSYS AIM is designed to guide engineers through the simulation process, starting from importing geometry and creating meshes to defining physics and boundary conditions. Process templates in ANSYS AIM provide predefined workflows for different physics types, allowing engineers to quickly set up simulations without the need for extensive training. Engineers can also customize these templates or Create their own, tailored to their specific analysis needs.

Using Process Templates in ANSYS AIM

When using ANSYS AIM, engineers can start their simulations with process templates. These templates provide step-by-step guidance for the entire simulation workflow, ensuring that engineers follow the best practices and predefined methodologies. The templates are categorized Based on physics types and include options for single physics simulations, as well as multiphysics simulations.

To begin, engineers can import their geometry into ANSYS AIM or create new geometry using the built-in SpaceClaim design engine. Once the geometry is in place, engineers can create meshes, Apply boundary conditions, define physics properties, and solve the simulation. ANSYS AIM provides a user-friendly interface to view and analyze the simulation results. The entire simulation process is streamlined, allowing engineers to focus on their designs rather than complex simulation setup.

Customizing Process Templates in ANSYS AIM

One of the key advantages of ANSYS AIM is the ability to customize process templates. Engineers can create their own templates or modify existing ones to suit their specific analysis needs. This customization can be done using scripting and extension creation tools provided by ANSYS AIM.

By customizing process templates, engineers can automate repetitive tasks, define specific mesh controls and physics properties, and create application-specific solutions. For example, a design team can create a template for hip implant analysis, allowing them to quickly simulate different implant designs and analyze their performance. Custom templates can also include additional instructions and help files to guide users through the analysis process.

Examples of Custom Process Templates

There are various examples of custom process templates that can be created in ANSYS AIM. For instance, a template for electrostatic field analysis can include predefined mesh controls based On Target solution accuracy. This ensures that engineers get accurate results while saving time on pre-processing work. Another example is an internal flow analysis template, where advanced users can define specific flow setups, boundary conditions, and analysis goals to investigate flow behavior inside a component.

Additionally, ANSYS AIM allows the creation of application-specific templates, such as a virtual wind tunnel application or a wing aerodynamics analysis template. These templates enable engineers to analyze fluid flow and aerodynamic performance without the need for specialized tools or extensive training. The customization options in ANSYS AIM empower engineers to tailor the simulation process to their specific needs and efficiently evaluate their designs.

FAQ

Q: Can ANSYS AIM handle combustion simulation with thermal stress analysis?

A: ANSYS AIM provides the flexibility to handle complex simulations involving combustion and thermal stress analysis. While there may not be an out-of-the-box template specifically for this Scenario, engineers can create custom templates or modify existing ones to incorporate combustion simulations and analyze the thermal stress effects on a component.

Conclusion

Simulation-driven product development is essential for optimizing designs, reducing costs, and improving performance. ANSYS AIM provides a powerful yet easy-to-use solution for engineers to perform engineering simulations using process templates. These templates streamline the simulation process, guide engineers through the workflows, and enable customization to meet specific analysis needs. With ANSYS AIM, every engineer can leverage the power of simulation and make informed design decisions. So start exploring ANSYS AIM and unleash the true potential of simulation in your product development process.