The Ultimate CFD Training Course using ANSYS Fluent

Description

In engineering analysis, the CAD model plays an important role. It may have errors like merged faces, duplicate curves, extra edges, split edges, gaps, or even interference errors. Therefore, we need to avoid dirty CAD geometry, which needs to be repaired and converted to error free geometry. To avoid modeling errors, it is important to select the correct physical models. The most important model for fluid dynamics is a set of partial differential equations called the Navier-Stokes equations.

After getting error-free, correct geometry, we need to go for discretization or meshing. To have an accurate result, we need to focus on better meshing quality because the better the mesh, the better the solution. To minimize the discretization error, we need to go on meshing and remeshing again and again till we reach the minimum error. When we get the exact solution, we say that the convergence criteria have been met.

From this theoretical understanding, we can realize that in FEA, CFD, or any kind of Engineering analysis, meshing or discretization play a very important role. Sometimes the geometry or the CAD model may have some intersecting solids or surfaces. It may have errors like merged faces, duplicate curves, extra edges, split edges, gaps, or even interference errors. In these cases, we cannot go for perfect meshing. Therefore, we need to rectify those errors using the ANSYS space-claim repair tool, and even then, we can share topology. So, if we require perfect meshing, and after that, if we want to go for different types of analysis like structural or CFD analysis, we must say that ANSYS is the best software. Here, to have perfect meshing, we can adopt different meshing methods like watertight geometry and fault tolerant meshing, which are new to the ANSYS interface and have been introduced in the ANSYS 2021 version. Therefore, to be familiar with these new techniques, we have developed this course considering different types of engineering applications with advanced techniques like watertight geometry, fault-tolerant meshing as well as conventional approaches.

Accordingly, we have categorized this CFD course into three different units consisting of twenty videos relevant to industrial applications.

The first unit comprises ANSYS Fluent Fault-Tolerant Meshing, consisting of ten videos.

The second unit comprises ANSYS Fluent watertight geometry, consisting of four videos, and the third unit contains four videos with the conventional approach of CFD Fluent flow analysis.

Unit 1: CFD Flow Analysis with ANSYS Fluent Fault Tolerant Meshing:

(i) Introduction to the Course

(ii) CFD Heat Transfer Analysis through a Shell-Tube Heat Exchanger using ANSYS Fluent Fault Tolerant Meshing

(iii) CFD Heat Transfer Analysis through a Counter-Flow Heat Exchanger using ANSYS Fluent Fault Tolerant Meshing

(iv) CFD Heat Transfer Analysis through a Cross-Flow Heat Exchanger using ANSYS Fluent Fault Tolerant Meshing

(v) CFD Heat Transfer Analysis through a Condenser Heat Exchanger using ANSYS Fluent Fault Tolerant Meshing

(vi) CFD Heat Transfer Analysis through a Plate Heat Exchanger using ANSYS Fluent Fault Tolerant Meshing

(vii) CFD Heat Transfer Analysis through a Surface Condenser using ANSYS Fluent Fault Tolerant Meshing

(viii) CFD Fluid Mixing through a Special type Heat Exchanger using ANSYS Fluent Fault Tolerant Meshing

(ix) CFD Heat Transfer Analysis through an Exhaust Manifold using ANSYS Fluent Fault Tolerant Meshing

(x) CFD Heat Transfer Analysis through Catalytic Converter using ANSYS Fluent Fault Tolerant Meshing

(xi) CFD Heat Transfer Analysis through a Wind Tunnel using ANSYS Fluent Fault Tolerant Meshing

(xii) CFD Heat Transfer Analysis through a Venturi-meter using ANSYS Fluent Fault Tolerant Meshing

(xiii) CFD Heat Transfer Analysis through an Expander using ANSYS Fluent Fault Tolerant Meshing

(xiv) CFD Heat Transfer Analysis through Heat Pipe using ANSYS Fluent Fault Tolerant Meshing

(xv) CFD  Conjugate Heat Transfer Analysis using ANSYS Fluent Fault Tolerant Meshing

Unit 2: CFD Flow Analysis with ANSYS Fluent Watertight Geometry:

(i) CFD Watertight Geometry Workflow through a Wind Tunnel

(ii) CFD Heterogeneous Fluid Mixing using ANSYS Fluent Watertight Geometry

Unit 3: CFD Flow Analysis with conventional ANSYS Fluent Flow

(i) CFD Flow Analysis Over a Cylinder Surface using ANSYS Fluent

(ii) CFD Intermixing of Fluids in a Bent-Pipe using ANSYS Fluent

(iii) CFD Flow through a Converging & Diverging Section (2D) using ANSY Fluent

(iv) CFD Flow through a Venturi-meter using ANSYS Fluent

What You Will Learn!

• Understand the importance of clean CAD geometry in engineering analysis and learn how to repair and convert CAD models to error-free geometry.
• Gain knowledge about selecting the appropriate physical models to avoid modeling errors, with a focus on fluid dynamics and the Navier-Stokes equations.
• Master the process of discretization and meshing to achieve accurate results in CFD analysis, recognizing the critical role of high-quality meshing.
• Develop proficiency in minimizing discretization errors through iterative meshing and remeshing techniques until convergence criteria are met.
• Acquire a deep understanding of the significance of meshing and discretization in various engineering analyses, including FEA, CFD, and other applications.
• Learn to rectify CAD model errors, such as intersecting solids, merged faces, duplicate curves, and gaps, using the ANSYS Space Claim repair tool.
• Familiarize yourself with ANSYS Fluent, a powerful software for achieving perfect meshing and conducting structural and CFD analyses.
• Explore advanced meshing methods like watertight geometry and fault-tolerant meshing introduced in ANSYS 2021, enhancing your skills in different applications.
• Gain practical knowledge through hands-on examples and case studies relevant to industrial applications, covering a wide range of heat transfer analysis.
• Develop expertise in CFD flow analysis techniques using ANSYS Fluent, including analyzing heat exchangers, exhaust manifolds, catalytic converters, wind tunnels
• Acquire proficiency in watertight geometry workflows and heterogeneous fluid mixing simulations using ANSYS Fluent.
• Understand the fundamentals of flow analysis over cylinder surfaces, intermixing of fluids in bent pipes, flow through converging and diverging sections, etc.
• Apply the learned concepts to perform conjugate heat transfer analysis and heat transfer analysis through heat pipes using ANSYS Fluent Fault-Tolerant Meshing.
• Enhance your skills in CFD analysis by combining conventional approaches with the powerful features of ANSYS Fluent.

Who Should Attend!

• Under Graduate, Post Graduate Engineering Students and any CFD Learner or Professionals working as an CFD Application Engineer

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