What will i learn?
- High Cycle Fatigue in FEA Simulation: Introduction to Fatigue,Stress-Life Curves,Mean Stress Effects on S-N Behavior, and Factors effecting S-N Behavior,S-N curve representation and approximations,S-N approach for Notched Members,Example of life estimation using the S-N approach,Workshop1: HCF calculations for Gas turbine components,Workshop2:HCF calculations for automobile components
- Low cycle Fatigue Simulation in FEA Simulation: Introduction to LCF,Strain-Life Curves,Mean Stress Effects on strain-life Behavior, and Factors effecting strain-life Behavior,Strain-Based approach to life estimation,Strain-life approach for Notched Members,Finding stresses in plastic region using Nuber’s rule , Strain energy density or glinka’s rule ,Workshop3: LCF calculations for Gas turbine components
- Fatigue from Variable Amplitude Loading in FEA Simulation,Spectrum loads and cumulative damage,Damage quantification, damage fraction, and accumulation,Load interaction and sequence effects,Cycle counting methods; rain flow, and other cycle counting methods,Life estimation using the stress-life approach,Life estimation using a strain-life approach,Crack growth and life estimation models, Workshop 4: LCF and HCF calculations for Gas turbine components
- Fracture Mechanics:Mechanisms of Fatigue and Creep Fatigue,Fundamentals of LEFM and applications to Fatigue Crack Growth Contribution,FRACTURE TOUGHNESS - Kc , KIc,Crack Tip Plastic Zone,Fatigue crack growth,Mean stress effect,Cyclic Plastic Zone Size,Crack Closure,Small Fatigue Cracks and LEFM Assumption,Plastic Extension of LEFM and Elastic Plastic Fracture Mechanics,Applications of Fracture Mechanics to crack growth at notches,SIF for residual stresses,Crack growth and life estimation for variable amplitude loading,Crack growth and life estimation for multiaxial stresses,Fatigue crack growth of weldments ( Constant amplitude Fatigue)
- Environmental effects: Fatigue crack growth behavior,Corrosion Fatigue,Fretting Fatigue,Low temperature Fatigue,High temperature Fatigue
- Exercises of Fracture Mechanics: Computation of SIF for solid cylinder block through (Elliptical Crack,Pre meshed crack,Arbitrary crack),Crack Propagation simulation for three-point bend specimen (LEFM),Plasticity accountability through LEFM –Spur gear example through perturbation approach,Crack Propagation due to High cycle Fatigue for turbine blade.
- Workshops on Fracture Mechanics :3D Fracture Mechanics Simulation Procedure through ANSYS Workbench (Elliptical Crack- pressure vessel with internal pressure,Pre meshed crack – Rail track from publication,Arbitrary crack- Spur gear root fillet ),Crack Propagation simulation in ANSYS Workbench,LEFM (Linear Elastic Fracture Mechanics)- Spur gear tooth ( ASME publication),LEPM (Linear elastic-plastic Fracture Mechanics)- Gas turbine blade,Thermal Mechanical Fatigue (TMF)- Gas turbine blade,Crack Propagation due to High cycle Fatigue - Gas turbine blade.
Curriculum for this course
0 Lessons
00:00:00 Hours
Requirements
- Engineering Graduates
+ View more
Description
sdaad
+ View more
Other related courses
About the instructor
- 0 Reviews
- 26 Students
- 10 Courses
+ View more
PYTHAGORAS Engineering and Consultancy offers high-quality instruction in the field of finite element analysis with the Ansys software. A significant number of individuals hailing from various regions throughout the globe have derived advantages from the meticulously designed instructional program. A significant majority, over 90%, of our students successfully get positions inside esteemed firms, using the information acquired via my training program.
Dr. Joel Daniel, a highly esteemed individual with a Master of Technology and a Doctorate degree, has been recognized as a prominent Finite Element Analysis (FEA) Trainer for the last two decades. He is a member of the Indian Society for Technical Education (ISTE), as well as the Institution of Engineers (India) (IEI) and the Institution of Production Engineers (IPE). He serves as a consultant in the field of Finite Element Analysis (FEA), conducts research, and has a position as an academic instructor. He earned his Ph.D. in fatigue and fracture mechanics.
As a scholar, he actively engages in several academic endeavours, such as serving as a teaching faculty member at multiple engineering institutions associated with JNTU. He was employed as an adjunct faculty member at ANURAG Engineering College. Delivered several guest lectures pertaining to modern technologies within the field of mechanical engineering. He had a position as a member of the curriculum board at Vignan engineering institutions. The individual in question has conducted reviews of several national and international publications, as well as provided guidance to a significant number of postgraduate and PhD students, both domestically and internationally. The individual organized Finite Element Analysis (FEA) workshops for esteemed educational institutions such as the National Institute of Technology (NIT), Birla Institute of Technology and Science (BITS) Dubai, and Navajo Technical University in the United States.
The individual has over two decades of research expertise in the fields of gas turbine design, vehicle engineering, and the oil and gas industry, having worked with Textron, GE, and Siemens. The individual employed Finite Element Analysis (FEA) tools, specifically ANSYS, to address intricate issues within various domains. These domains encompass linear and nonlinear systems, composites, structural vibrations (including modal, harmonic, random, and shock load analysis), rotor dynamics (both lateral and torsional), fatigue and fracture mechanics, as well as implicit and explicit analysis. He serves as a consultant for several firms, such as APSCO (USA), TATA HITACHI (JAPAN), HYDRO (US), Sundyne, Premier pumps, Ruhrpumpen, WOM, Word pumps, among others.
The course was developed with the intention of catering to the needs of graduate students seeking to further their careers in the field of Finite Element Analysis (FEA), as well as design engineers who need to enhance their understanding of FEA principles and independently make informed judgments based on FEA results.
Based on his extensive teaching and research background, he had a comprehensive understanding of the knowledge acquisition process among students inside his educational institution and a keen awareness of the requisite abilities necessary for successful entry into the sector. This served as a source of motivation for him to develop an appropriate curriculum that would bridge the divide between the industry and the educational institution. The curriculum was constructed to allow students to go from foundational concepts to the point where they can solve intricate problems. Numerous individuals from diverse regions around the world derived significant advantages from his instructional sessions, including the incorporation of their own research findings into their Master's and Doctoral dissertations, as well as securing enhanced employment prospects inside reputable organizations. The training program is highly recommended for anybody seeking to transition their career from design to analytical domains.
Dr. Joel noted that a significant number of design engineers rely on expertise in finite element analysis (FEA) to make engineering assessments. He always maintains the belief that possessing a shared understanding of design principles and finite element analysis (FEA) is essential for engineers in order to cultivate the creation of efficient and impactful products. This course aims to enhance the comprehension of design engineers about fundamental and advanced principles in Finite Element Analysis (FEA), enabling them to effectively use FEA techniques in the component design process.
Student feedback
Reviews
Write a public review