When it comes to finite element analysis software, Abaqus is a widely used tool in the industry. While it may seem daunting to learn, there are numerous online courses available that can help individuals develop a solid understanding of Abaqus. These courses cover various topics such as modeling techniques, material properties, and simulation processes. In this article, we will explore some of the best options available for those looking to learn Abaqus online.
Here’s a look at the Best Abaqus Courses and Certifications Online and what they have to offer for you!
Online Abaqus Certification Course
- Online Abaqus Certification Course
- 1. Abaqus CAE : Learn Static and Dynamic Analysis by Veer Tutorial (Udemy) (Our Best Pick)
- 2. Structural Engineering Abaqus Tutorials by Armin Yousefi Kanani (Udemy)
- 3. ABAQUS FEM : All you need ( A to Z ) by Aria Djavid (Udemy)
- 4. Adhesive Joints and Composite Material Abaqus Tutorial by Armin Yousefi Kanani (Udemy)
- 5. Explosion Simulation Abaqus Tutorial by Armin Yousefi Kanani (Udemy)
- 6. Become CAE Analyst with Abaqus Implicit Solver & Hypermesh by Orville Academy (Udemy)
- 7. Abaqus Fundamentals Course by Laureano Boira Radiu (Udemy)
- 8. ABAQUS FEA: PYTHON SCRIPTING & GUI by CAE Geek (Udemy)
- 9. Practical Tutorial of ABAQUS (Static and Dynamic Case Study) by Learnitist Group (Udemy)
- 10. Modelling Laser Welding with Abaqus by Ali Nasser (Udemy)
1. Abaqus CAE : Learn Static and Dynamic Analysis by Veer Tutorial (Udemy) (Our Best Pick)
The Abaqus CAE course is designed to provide learners with a comprehensive understanding of the software from basic to advanced levels. Abaqus is a widely used Finite Element Analysis (FEA) software that was developed by Dassault SYSTEMS. The course covers topics such as linear and non-linear analysis, heat transfer problems, dynamic analysis, and more. The main content of the course includes 1-D beam analysis, linear static analysis, non-linear analysis, geometric non-linearity, material non-linearity, contact non-linearity, buckling analysis, and more. Learners will be able to access all the files used in the course along with the lectures, and the instructor also offers support for any queries. The course is conducted in English and requires the Abaqus software. Basic knowledge of mechanics of material, machine design, and finite element analysis would be advantageous, but basic concepts will also be explained during the course.This course is suitable for anyone who wants to learn Abaqus, including mechanical engineers, design engineers, master and PhD students, and simulation engineers. The course provides learners with the skills to perform real-life problems and simulations, learn finite element analysis, and confidently specify Abaqus on their resume. The course is divided into sections, including an introduction, basics of FEA, 1-dimensional analysis, linear static analysis, mid surfacing analysis, additional options, analysis of truss members, buckling analysis, heat transfer analysis, transient heat transfer analysis, non-linear analysis, pressure vessel analysis, 3-point bending analysis, dynamic simulation, frequency response analysis, impact analysis, impact analysis of automotive crash box, deflection due to self-weight, and time-dependent load. The course starts with simple analysis and gradually progresses to more complex problems.
The Structural Engineering Abaqus Tutorials course is designed for mechanical and civil engineering students who want to expand their finite element knowledge. The course covers 13.5 hours of real-life structural examples under various loading conditions, providing students with a practical understanding of the software, theory, and analysis that is not available anywhere else on the internet.
The course is divided into 12 sections, with section 1 providing an overview of the tutorial. Section 2 teaches students how to analyze various concrete beams under the 3-point bending condition, with a focus on reinforcing the beams with different methods such as steel bars and strips, CFRP, and metal foam. Section 3 covers the analysis of concrete columns under compressive loading, and section 4 consists of simulations for applying load to the column without any reinforcement, then using CFRP layers to increase its strength before applying the load again.
Section 5 teaches students how to model the combination of the concrete beam and column under cyclic loading, while section 6 covers how to apply tensile loading to various engineering applications. Section 7 focuses on applying impact loading on the concrete plate using rigid and non-rigid projectiles, while section 8 covers thermal behavior and its effects on material under impact loading.
Section 9 covers the simulation of a low-velocity impact with a fun example of simulating a phone drop from a height of 5 meters. Section 10 teaches how to perform repetitive impact loading on a metal beam using the Johnson-cook damage model, and section 11 introduces the XFEM method for studying crack growth in a concrete beam under 3-point and 4-point bending conditions. Finally, section 12 provides background information on all the damage models used in the course.
Students are advised to follow the course in order, as basic terms are explained in the initial sections. The course examples are not intended to apply to any particular situation, and students are cautioned to satisfy themselves as to the accuracy and results of their analyses.
The ABAQUS FEM course is designed to help beginners and mediocres build their knowledge and become professionals in ABAQUS. The course covers multiple examples that encompass all topics, providing a complete understanding of the software.
The course is divided into several sections that include an introduction to ABAQUS, CAD in ABAQUS, tension analysis of a simple supported beam, truss load analysis under concentrated loading, planar stress analysis on a perforated plate, steady state heat transfer analysis in a metal plate, fracture mechanics, tension around a crack, and modeling of composite materials in ABAQUS.
Students will learn how to use ABAQUS from scratch and gain comprehensive knowledge of the software. The course instructors are experienced professionals who will guide students through the learning process. By the end of the course, students will have the necessary skills to apply ABAQUS FEM to real-life problems.
The Adhesive Joints and Composite Material Abaqus Tutorial Course is designed for mechanical and civil engineering students or engineers who want to expand their knowledge of finite element modelling. The course is divided into eight sections, each covering various modelling techniques for adhesively bonded joints and composite materials using Abaqus software. The course begins with two-dimensional double cantilever beam modelling using cohesive element methods in Section 1, followed by surface-based cohesive zone modelling of a two-dimensional single-lap joint in Section 2. Section 3 covers three-dimensional double cantilever beam modelling with cohesive element methods, while Section 4 delves into the use of extended finite element methods for two-dimensional double cantilever beam modelling. Sections 5 and 6 cover the use of extended finite element and cohesive element methods for two-dimensional end notched flexure beam modelling, respectively. Section 7 is a new addition to the course, covering flexible adhesive modelling using various techniques such as hyper-elastic properties and trapezoidal traction separation law. Finally, Section 8 covers composite plate modelling and analysis of buckling and post-buckling conditions.
Future updates to the course include modelling techniques for a composite tube under crushing compression loading, composite plate under 3 point bending, composite panel under impact loading, and 3D composite single lap joint. The author regularly updates the course and welcomes feedback from students.
It is important to note that the course is intended for serious students only, and while the examples provided offer practical understanding of the software, theory, and analysis, they are not intended to apply to any particular situation. Students are advised to verify the accuracy of their analyses and the author is not responsible for any errors or mistakes that may appear in the course. Finally, all rights are reserved and any unauthorised broadcasting, public performance, copying, or re-recording of the course will constitute copyright infringement.
The Explosion Simulation Abaqus Tutorial is a comprehensive course designed for mechanical, civil engineering students, and engineers seeking to expand their finite element knowledge. The course covers the theory behind input parameters, modeling, and analyzing the results of various explosion conditions on different applications. The course is divided into four sections, which include Air-blast, Smoothed particle hydrodynamics (SPH), Coupled Eulerian-Lagrangian (CEL), and Underwater explosion (UNDEX).
Section 1 covers the use of the CONWEP model for air-blast loading on solid and structural elements without the need to model the fluid medium. Four real-life examples and four theory videos are used to teach how to model explosions on concrete structures using concrete damaged plasticity (CDP) and Johnson-Holmquist model. Additionally, the section includes Hasin and Johnson-cook damage model examples in the explosion on the car door and composite beam.
Section 2 teaches the use of the Smoothed particle hydrodynamics (SPH) on the concrete beam and water-tank, including bird-strike examples on the fuselage and jet engine. The section concludes with a bullet example showing how to model gunpowder explosion in the bullet shell.
Section 3 covers the Coupled Eulerian-Lagrangian (CEL) method that combines two mesh approaches-Lagrangian and Eulerian-in the same analysis. Four examples illustrate how to simulate various explosion conditions on different structures, including under-ground pipelines, soil, and bird strike on an airplane wing.
Section 4 teaches how to simulate underwater explosions using waves produced by an explosion or sound source. The section covers the UNDEX charge method and how to use ductile and shear damage models in Abaqus.
The course is intended for serious students seeking practical understanding of the software, theory, and analysis not available anywhere else on the internet. The course examples are not intended to apply to any particular situation.
Course Title: Become CAE Analyst with Abaqus Implicit Solver & Hypermesh
Course Instructors: Orville Academy
Course Short Description: A professional guide to non-linear analysis
Course Long Description:
This course is designed for individuals who are already working in the field of CAE or have knowledge of pre-processing tools such as Hypermesh or ANSA. It is important to note that this course is not intended for beginners in CAE. If you are a beginner, it is recommended to first complete the Complete Altair Hypermesh & Optistruct Course to gain foundational knowledge. Orville Academy offers this course at a discount, and it can be obtained by contacting them directly.
The main theme of the course is non-linear analysis. Through a step-by-step approach, participants will gain a deeper understanding of how professionals use Abaqus to solve physical problems. The course covers the implementation of various options, along with their theory and the repercussions of changing parameters on results, in depth.
As learning solvers can be challenging, the course instructor will be available for live sessions with enrolled students to help solve doubts related to non-linear analysis. These sessions will be scheduled based on a suitable time for both the instructor and student.
To enroll in the course, it is recommended to contact the course instructor beforehand.
Course Content and Sections:
1. Abaqus & Hypermesh Overview
2. File Structure in ABAQUS
3. Streamlining our Workflow
The Abaqus Fundamentals Course is designed to teach students, engineers, and researchers how to simulate engineering problems in Abaqus using the Finite Elements Method. The course offers a step-by-step approach that covers basic to advanced concepts.
The course is ideal for those with no experience in Finite Elements or Abaqus, as it provides a complete basic guide to the software. Students will gain the ability to simulate physical problems in a simple and practical way. Upon completion of the course, students will possess deep knowledge of the subject.
The course instructor, Laureano Boira Radiu, emphasizes the importance of mastering Finite Elements to solve physical problems in engineering. He notes that the demand for this skill is high and increasing. Abaqus is a comprehensive software that offers a multitude of physical modules for simulation, making it a popular choice among engineers.
Abaqus is a complex software, and learning it can be challenging. The course aims to simplify the learning process by providing a step-by-step and detailed explanation of complete mechanical, structural, non-linear, and heat transfer problems. Students can simulate and understand their own physical problems in a short time, and the course content is designed to help students master essential Abaqus tools in an advanced way.
The course instructor aims to provide students with the help and guidance he wished he had when he was starting out. He will be available to answer any questions students may have in the shortest possible time. This course makes learning Abaqus easier than ever before, and students are encouraged to enroll. The course content includes an introduction, first steps in software, non-linear problems, and final problems.
The ABAQUS FEA: PYTHON SCRIPTING & GUI course is designed to teach individuals how to perform engineering analysis using the ABAQUS/CAE software. The course is instructed by CAE Geek and primarily focuses on the utilization of both Python scripting and the Graphical User Interface (GUI) in engineering simulations.
Participants will learn how to code in Python and optimize the software’s capabilities by running Python scripts. Additionally, individuals will gain an understanding of how CAE software computes and executes operations performed in the GUI by replicating the same procedures with Python.
The course is divided into six sections, beginning with an introduction to the material. The following sections include 1D bar analysis using the GUI, linear static analysis on a 3D solid geometry, Python basics, linear static analysis on a cantilever beam utilizing both Python and the GUI, and linear static analysis of a 2D truss structure using Python and the GUI.
The Practical Tutorial of ABAQUS is a course offered by the Learnitist Group that teaches finite element analysis for Static and Dynamic phenomena using the Abaqus software. The course covers several concepts such as providing simulation basic materials, loading knowledge, and boundary conditions, and the nature of the analysis. The course also focuses on dynamic-impact problems, crash tests, plastic deformations, Johnson-Cook, mass scaling, implicit and explicit Abaqus solvers, contact algorithms, geometry and material, and simulation in Abaqus. The course is designed for engineers and students who want to learn about ABAQUS with practical examples, the concepts related to plastic and irreversible deformations, model a dynamic-impact phenomenon, use the mass scaling technique to speed up a simulation, and learn about contact algorithms in Abaqus. A simple example-based tutorial is also available for those who are not familiar with ABAQUS. The course is divided into 12 sections, including an introduction, getting started with ABAQUS, crash test, plasticity, mass scaling, impact, explicit and implicit solvers, contact, geometry and material, simulation in ABAQUS, and the results of analysis. The section on simulation in ABAQUS includes a step-by-step explanation of how to simulate a crash test with the software environment.
The course titled Modelling Laser Welding with Abaqus is instructed by Ali Nasser. The aim of this course is to provide an understanding of laser welding process simulation using Abaqus, study the mechanical and thermal distribution on laser joining by developing a finite element model, learn how to write subroutine Dflux code, and determine the effect of process parameter on laser joining.
The process of laser welding is a non-contact process that requires access to the weld zone from one side of the parts being welded. The weld is formed as the intense laser light rapidly heats the material, typically calculated in milli-seconds. Laser welding process can be divided into two modes, keyhole, and conduction, depending on the intensity of the heat. Partial and completely penetrated welds can be done in keyhole welding mode.
The study will illustrate all that is needed regarding laser welding using Abaqus software. This study follows literature review date and is very informative for researchers.
In this course, residual stress, temperature distribution field will be observed, and students will be able to use their own models according to their needs, specify their needs and assumptions, and use defined functions to have a better understanding of what they are going to do.
The course is divided into an introduction section.