Industry Oriented Program on Structural Analysis Using Ansys
Complete Lecture on Fatigue Analysis, Modal Analysis, Thermal Analysis, Coupled Analysis and Stress Reporting

What you will learn
Finite Element Analysis
Finite Element Method
Structural Analysis
Thermal Analysis
Fatigue Analysis
Modal Analysis
Coupled Analysis
Meshing
Ansys
Engineering Mechanics
Strength of Material
Design Standards
Why take this course?
๐ Industry Oriented Program on Structural Analysis Using ANSYS ๐
Course Headline:
Complete Lecture on Fatigue Analysis, Modal Analysis, Thermal Analysis, Coupled Analysis, and Stress Reporting
Course Description:
This comprehensive course has been meticulously designed to equip you with the knowledge of Finite Element Analysis (FEA) and Finite Element Method (FEM) at an industrial level. Ravi Shankar Reddy Thammaneni, our esteemed instructor, leverages years of experience to ensure that the course content mirrors real-world project execution in the industry.
What You Will Learn:
- Industry Practices: The course is structured to provide a working environment akin to industry standards, ensuring that students are well-prepared to meet the demands of client projects.
- Comprehensive Coverage: From Pre-Prepossessing to Post-Processing, this course covers all necessary topics essential for solving complex structural problems.
- Hands-On Experience: With the material provided, you will gain practical experience and be able to execute operations as per industry needs.
- Real-World Application: The methods followed in this course are identical to those used by professionals in the field, ensuring that upon completion, you are not just theoretically proficient but also practically skilled.
Syllabus Overview:
Pre-Prepossessing:
- Introduction to Ansys and FEM principles
- Navigating the Ansys User Interface
- Mastering Model Creation, including sketching, constraining, modeling, planes creation, defeaturing, idealization, body splitting, slicing, applying fillets/chamfers, incorporating holes/slots, importing/exporting geometries, and combining geometries
- Working with default shapes and applying various materials
Meshing:
- Comprehending the fundamentals of meshes
- Exploring different element shapes (2D & 3D) and mesh types (mapped face, structured, unstructured)
- Understanding the advantages of each mesh type
- Learning mesh layering, size control, quality optimization, and applying loads with appropriate constraints
Solving:
- Running the setup after all preparations are complete
Post-Processing:
- Taking various outputs
- Creating animations for a better understanding of dynamics
- Interpreting results
- Generating automatic reports for clear documentation
- Conducting grid independence studies
- Managing ANSYS projects efficiently
Course Highlights:
- Industry-Specific Focus: Tailored to align with actual industry practices.
- Complete Workflow: From problem setup to result interpretation and report generation.
- Hands-On Learning: Practical exercises that mirror real-world applications.
- Comprehensive Coverage: Ensuring a deep understanding of FEA in structural analysis.
By the end of this course, you will have a solid grasp of how to perform a complete structural analysis using ANSYS, from pre-processing to post-processing, and be fully equipped to produce quality reports that meet industry standards. ๐ ๏ธ๐๐
Join us on this journey to master the art of structural analysis with ANSYS, and take your career to new heights! ๐โจ
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Our review
Overall Course Rating: 3.50
Course Review Synthesis:
Pros:
- The course aims to introduce fundamental concepts early on, which is crucial for learners to understand how software performs the Finite Element Method (FEM).
- Recent feedback indicates that the course's intent to cover the introductory aspects of Ansys and FEM is commendable.
Cons:
- Content Mastery: The instructor appears to lack a firm grasp of the subject matter, leading to confusion and misuse of terms throughout the lectures. Specifically, referring to ANSYS as "Analytical Methods" instead of a numerical method indicates a significant misunderstanding of the topic.
- Technical Accuracy: There are numerous technical and conceptual errors in the explanation of concepts. For instance, the incorrect use of the term "discretization" for "discrimination" shows that the instructor's explanations cannot be relied upon for accurate learning.
- Video Clarity: The quality of the videos is subpar, with instances where text and images on the screen are not visible, which hinders the learning experience. This makes it difficult to understand what the instructor is demonstrating.
- Presentation and Content Quality: The course content and presentation slides reflect a lack of professionalism and preparation. It seems as though the author hastily put together the course materials without thorough review or revision.
- Recording Errors: There are recorded tutorials with mistakes that have been uploaded without correction, which suggests inattention to detail and a less-than-rigorous approach to content validation.
Recommendations for Improvement: To improve the course, we recommend:
- A thorough review and revision of the course content by experts in both the theoretical aspects of FEM and the practical use of Ansys to ensure accuracy and clarity.
- Enhancing the video quality to ensure that all on-screen text, images, and actions are visible and understandable.
- Providing professional presentation slides that effectively convey complex concepts in a clear and engaging manner.
- Re-recording tutorials with attention to detail, ensuring that any mistakes are corrected before publication.
- Considering the inclusion of additional resources or supplementary materials for a more comprehensive learning experience.
- Implementing a peer-review process or adding subject matter expert contributions to validate the content and improve its quality.
By addressing these issues, the course can significantly enhance the educational value it offers to learners interested in FEM and Ansys software applications.