ICEMCFD Master Class (Level 2) from Udemy

Meshing is the most important part of any CFD process. Meshing is the process to divide continuous domain in discrete parts known as control volumes. After discretizing, this mesh is provided to numerical (CFD) solver to solve algebraic equations arising from partial differential equations of continuous domain. Therefore meshing is most important part of any CFD process and accuracy & stability of CFD process largely depends on good quality mesh.

It is estimated that around 70% time is spent on meshing in any CFD project. But after taking this course, you will be expert in meshing and you can generate meshes in very less time than rest of CFD community.

In meshing you can either go with full hexa meshing or tetra meshing (with prism layers). Hexa meshing is more of an art and requires great deal of time. But yields most accurate solution. It also requires less number of nodes and hence it require less compactional resources and less solution time. It also avoids numerical errors /numerical diffusivity as you can observe in tetra meshes. It is estimated that tetra meshes requires as much as five times of mesh size as that of hexa meshing.

In this course you will enhance your ICEMCFD hexa meshing skills on more complicated geometries such as circular cylinder, 3D airfoils, stirred tank, wind turbine etc. Here you will each and every trick/tip of business of CFD meshing. After going through this course, you will be able to create perfect grid according to CFD simulation requirements and hence will be able to get most accurate results in less time.

We will cover different topics as well which will increase effectiveness of hexa meshing.

What's inside

Learning objective

Students will learn about creating high quality hexa meshing for cfd analysis

Syllabus

Introduction

Course contents

How to use this course effectively

Workshop 1 : Vertical cylinder with hemisphere

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Read about what's good

what should give you pause

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Focuses on hexa meshing, which is known for yielding accurate solutions and requiring fewer computational resources compared to tetra meshing, making it valuable for complex CFD projects

Enhances skills in ICEMCFD, a tool used for generating meshes on complex geometries, which is essential for accurate CFD simulations and analyses in various engineering applications

Covers techniques to improve mesh quality, such as mesh bunching and edge editing, which are crucial for achieving reliable and accurate results in CFD simulations

Requires familiarity with CFD principles and software, as it delves into advanced meshing techniques for complex geometries, which may pose a challenge for beginners

Emphasizes the importance of meshing in CFD, estimating that around 70% of time is spent on it in any CFD project, highlighting the need for expertise in this area

Reviews summary

Icemcfd master class level 2

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Uses workshops for hands-on learning.

"Workshop 1 : Vertical cylinder with hemisphere"

"Workshop 3 : Re-Using blocking on new geometry with few modifications"

"Workshop 4 : Circular Cylinder with hemisphere and rectangular domain"

"Mixing tank Hexa meshing"

Course targets advanced hexa meshing challenges.

"In this course you will enhance your ICEMCFD hexa meshing skills on more complicated geometries such as circular cylinder, 3D airfoils, stirred tank, wind turbine etc."

"Hexa meshing of full Aircraft model (Wing-body Configuration)"

Covers blocking, association, quality improvement.

"Creating blocking and 3D hexa meshing"

"Hint 2 : Correcting edge and surface association issues"

"Hint 5 : How to improve mesh quality"

"Use of mesh bunching and other techniques to increase mesh quality"

Designed as a 'Master Class (Level 2)'.

"ICEMCFD Master Class (Level 2)"

"After taking this course, you will be expert in meshing..."

"Here you will each and every trick/tip of business of CFD meshing."

Activities

Be better prepared before your course. Deepen your understanding during and after it. Supplement your coursework and achieve mastery of the topics covered in ICEMCFD Master Class (Level 2) with these activities:

Review Fundamentals of CFD

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Refresh your understanding of CFD fundamentals to better grasp the meshing concepts covered in the course.

Browse courses on Computational Fluid Dynamics

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Review governing equations of fluid flow.
Study different numerical methods used in CFD.
Familiarize yourself with common CFD terminology.

Read 'An Introduction to Computational Fluid Dynamics: The Finite Volume Method'

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Gain a solid foundation in CFD principles to better understand the meshing process and its impact on simulation results.

View An Introduction to Computational Fluid Dynamics... on Amazon

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Read the introductory chapters on CFD and the finite volume method.
Study the chapters on mesh generation and quality.
Work through the example problems to reinforce your understanding.

Practice Geometry Preparation in SpaceClaim

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Improve your geometry preparation skills in SpaceClaim to create clean and suitable geometries for meshing in ICEMCFD.

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Import CAD models into SpaceClaim.
Clean up the geometry by removing unnecessary features.
Create surfaces and volumes suitable for meshing.
Export the geometry in a format compatible with ICEMCFD.

Four other activities

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Read 'The Finite Volume Method in Computational Fluid Dynamics'

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Deepen your understanding of the numerical methods used in CFD to improve your meshing skills.

View The Finite Volume Method in Computational Fluid... on Amazon

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Read the chapters on discretization schemes.
Study the sections on boundary conditions.
Take notes on the key concepts and equations.

Follow ICEMCFD Hexa Meshing Tutorials

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Enhance your ICEMCFD skills by following online tutorials that demonstrate various meshing techniques and workflows.

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Search for ICEMCFD hexa meshing tutorials on YouTube or the Ansys Learning Hub.
Follow along with the tutorials, practicing the techniques on your own geometries.
Take notes on the key steps and best practices.

Document Meshing Workflow for a Simple Geometry

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Solidify your understanding of the meshing process by documenting the steps involved in creating a hexahedral mesh for a simple geometry.

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Select a simple geometry, such as a cube or cylinder.
Create a hexahedral mesh for the geometry in ICEMCFD.
Document each step of the meshing process, including blocking, edge association, and mesh quality improvement.
Include screenshots and explanations to illustrate each step.

Mesh a Complex Geometry

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Apply your meshing skills to a complex geometry to gain experience and confidence in creating high-quality hexahedral meshes.

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Select a complex geometry, such as an airfoil or a turbine blade.
Prepare the geometry for meshing in SpaceClaim or ICEMCFD.
Create a hexahedral mesh for the geometry in ICEMCFD.
Optimize the mesh for accuracy and efficiency.
Export the mesh for use in a CFD solver.

Career center

Learners who complete ICEMCFD Master Class (Level 2) will develop knowledge and skills that may be useful to these careers:

CFD Analyst

A Computational Fluid Dynamics Analyst uses simulation software to model and analyze fluid flow, heat transfer, and related physical phenomena. The ability to create high-quality meshes is a fundamental skill for obtaining accurate and reliable results. Because this course is designed to enhance skills in ICEMCFD hexa meshing on complicated geometries, one may find it very practical for a aspiring CFD Analyst. The course emphasizes creating perfect grids according to CFD simulation requirements, enabling the CFD Analyst to obtain the most accurate results in less time. The analyst will be able to focus on the results.

See salaries and explore the career path for CFD Analyst

Simulation Engineer

Simulation Engineers develop and use computer models to simulate physical systems and processes across industries. This often involves Computational Fluid Dynamics, where quality meshing is crucial for accurate results. This course is particularly relevant for a budding Simulation Engineer, offering an opportunity to master ICEMCFD hexa meshing techniques. The course curriculum focuses on creating high-quality meshes for Computational Fluid Dynamics analysis, covering techniques for complicated geometries and optimizing mesh quality. This skill is indispensable for a Simulation Engineer seeking reliable and efficient simulations.

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Thermal Engineer

Thermal Engineers are responsible for managing heat in various systems, from electronics cooling to HVAC systems. Computational Fluid Dynamics is a crucial tool for modeling and optimizing thermal performance, and meshing is a core skill in this process. This course is designed to enhance ICEMCFD hexa meshing skills on complex geometries, making it a great option for Thermal Engineers. Mastering the creation of perfect grids according to Computational Fluid Dynamics simulation requirements, as taught in this course, allows Thermal Engineers to efficiently obtain the most accurate results for their thermal analyses.

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Turbomachinery Design Engineer

Turbomachinery Design Engineers focus on designing and optimizing rotating equipment like turbines and compressors and often rely on Computational Fluid Dynamics simulations for performance analysis. The quality of the mesh directly impacts the accuracy of these simulations. This course is very beneficial for Turbomachinery Design Engineers, as it improves their skills in hexa meshing, which is essential for Computational Fluid Dynamics analysis. The course's emphasis on creating perfect grids for Computational Fluid Dynamics simulations results in more accurate and reliable performance predictions, which is invaluable for design engineers.

See salaries and explore the career path for Turbomachinery Design Engineer

Fluid Dynamics Specialist

Fluid Dynamics Specialists focus on the study of fluid motion and its effects, often using Computational Fluid Dynamics software to model complex flow scenarios. Proficiency in meshing is essential for generating accurate and reliable simulation results. This course's focus on enhancing ICEMCFD hexa meshing skills is directly applicable to the work of a Fluid Dynamics Specialist. The specialist learns to create perfect grids tailored to Computational Fluid Dynamics simulation requirements, and this leads to obtaining the most accurate results efficiently. This mastery will prove invaluable to the specialist.

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Computational Fluid Dynamics Engineer

A Computational Fluid Dynamics Engineer relies heavily on meshing techniques to simulate fluid flow and heat transfer. The role involves creating accurate and efficient mesh designs to solve complex engineering problems. This course helps one become an expert in meshing, allowing for generation of meshes in less time, a crucial skill for a Computational Fluid Dynamics Engineer. The course's focus on hexa meshing and its application to complex geometries, directly translates to improved accuracy and reduced computational resources. It also covers techniques to correct edge and surface association issues, and improving mesh quality. These are essential in producing reliable simulations.

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Biomedical Engineer

Biomedical Engineers use Computational Fluid Dynamics to simulate blood flow, design medical devices, and analyze physiological processes. Accurate meshing is crucial for reliable simulation results. This course can help a Biomedical Engineer enhance their Computational Fluid Dynamics skills, especially in creating high-quality hexahedral meshes. The tips and tricks of Computational Fluid Dynamics meshing taught in this course are directly applicable to biomedical applications, improving simulation accuracy and enabling better designs.

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Automotive Engineer

Automotive Engineers use Computational Fluid Dynamics to analyze airflow around vehicles, optimize engine cooling, and improve aerodynamic performance. High-quality meshing is essential for accurate simulation results. This course may be helpful for an Automotive Engineer who wants to improve their Computational Fluid Dynamics skills, especially in creating high-quality hexahedral meshes. The course's focus on practical skills and efficient mesh generation is directly applicable to the automotive industry. This course gives Automotive Engineers a better understanding of meshing.

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Energy Engineer

Energy Engineers work on improving energy efficiency and developing renewable energy technologies. Computational Fluid Dynamics is often used to simulate and optimize energy systems, requiring proficiency in meshing. This course enhances the ability to create high-quality hexahedral meshes in ICEMCFD, directly benefiting an aspiring Energy Engineer. With its focus on complex geometries, the course provides the skills necessary to accurately model and simulate renewable energy systems, contributing to their efficient design and optimization. These skills are applicable to the energy sector.

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Mechanical Engineer

Many Mechanical Engineers use Computational Fluid Dynamics to analyze fluid flow and heat transfer in mechanical systems. Creating high-quality meshes is important for accurate and efficient simulations. This course may be helpful for aspiring or current Mechanical Engineers because it focuses on creating high-quality hexahedral meshes and optimizing them for Computational Fluid Dynamics analysis. The knowledge of hexa meshing skills on more complicated geometries, and the tips and tricks provided, are directly transferable to the mechanical engineering field. These simulations help mechanical engineers design better products.

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Aerospace Engineer

Aerospace Engineers often use Computational Fluid Dynamics software to design and analyze aircraft and spacecraft. The ability to create high quality meshes is critical for obtaining accurate simulation results. Since this course teaches how to create high quality hexahedral meshes and optimize them for Computational Fluid Dynamics analysis, taking it may prove helpful for an Aerospace Engineer. The skills of the trade that are taught in this course are directly transferable to the aerospace field, especially the section on hexa meshing of a full aircraft model. This course hones skills needed by Aerospace Engineers.

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Research Scientist

Research Scientists in various fields use Computational Fluid Dynamics to model and simulate complex phenomena. Meshing skills are essential for setting up and running these simulations. This course may be useful for a Research Scientist who wants to enhance their abilities to create high quality hexahedral meshes for Computational Fluid Dynamics analysis. The course covers different topics which will increase the effectiveness of hexa meshing, which is useful for research. A Research Scientist benefits from the improved accuracy and efficiency of complex simulations.

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Heat Transfer Engineer

Heat Transfer Engineers analyze and design systems for managing thermal energy. Computational Fluid Dynamics simulations are frequently employed to model heat transfer processes, and high-quality meshing is crucial for obtaining accurate results. This course may be useful for Heat Transfer Engineers as it advances their proficiency in ICEMCFD hexa meshing techniques. The course is focused on creating high-quality meshes for Computational Fluid Dynamics analysis, and this directly enhances the ability to model and optimize heat transfer systems effectively. They can make better simulations from this course.

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Product Development Engineer

Product Development Engineers use simulation tools to optimize product designs. Computational Fluid Dynamics simulations play a key role in understanding fluid behavior within and around products. This course can assist a Product Development Engineer in improving their meshing abilities to ensure accuracy in Computational Fluid Dynamics simulations. The course content, which includes hexa meshing skills for complex geometries like stirred tanks and wind turbines, directly improves the effectiveness of product design and analysis. These simulations allow for better design.

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Research and Development Engineer

Research and Development Engineers use Computational Fluid Dynamics to explore and improve new technologies and products. Quality meshing is essential for accurate and reliable simulations. This course may be useful for a Research and Development Engineer who wants to refine their skills in creating high-quality hexahedral meshes for Computational Fluid Dynamics analysis. The skills learned in this course are directly applicable to a variety of research and development projects, making it an asset for innovative engineers.

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Reading list

We've selected two books that we think will supplement your learning. Use these to develop background knowledge, enrich your coursework, and gain a deeper understanding of the topics covered in ICEMCFD Master Class (Level 2).

An Introduction to Computational Fluid Dynamics e...

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Widely used textbook that provides a clear and concise introduction to the finite volume method. It covers the fundamental concepts and techniques used in CFD, including meshing, discretization, and solution algorithms. This book is particularly helpful in providing background knowledge for those new to CFD. It is commonly used as a textbook at academic institutions.

An Introduction to Computational Fluid Dynamics e...

Paperback

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An Introduction to Computational Fluid Dynamics e...

Kindle Edition

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The Finite Volume Method in Computational Fluid...

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Provides a comprehensive overview of the finite volume method, which is the foundation of many CFD solvers. It explains the discretization process and numerical schemes used in CFD. Understanding these concepts will help you create better meshes and interpret CFD results more accurately. This book is valuable as additional reading to deepen your understanding of the numerical methods behind CFD.

The Finite Volume Method in Computational Fluid...

Paperback

$$$

ICEMCFD Master Class (Level 2)

What's inside

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Syllabus

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Reviews summary

Icemcfd master class level 2

Activities

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