The main purpose of this book is to equip, undergraduate/graduate students and professionals, who are craving to start up or enhance their learning with hands-on experience in solving real-life Finite Element Analysis (FEA) problems. This textbook is specially designed for mechanical, aeronautical, mechatronics, biomedical (i.e. orthopedics and dental studies), geotechnics and civil engineering students who are focusing on stress/strain analysis, heat transfer, and vibration characteristics of the problem of their interest. At the same time, this book may also serve the students from different backgrounds, who have a common or special interest in FEA.

Presents the basic concepts of finite element analysis applied to engineering applications. Coverage includes several modules of elasticity, heat conduction, eigenvalue and fluid flow analysis; finite element formulations have been presented using both global and natural coordinates; heat conduction problems and fluid flows; and factors affecting the formulation.

An introductory textbook for senior/graduate couses in finite element analysis taught in all engineering departments. Covers the basic concepts of the finite element method and their application to the analysis of plane structures and two-dimensional continuum problems in heat transfer, irrotational fluid flow, and elasticity. This revised edition includes a reorganization of topics and an increase in the number of homework problems. The emphasis on numerical illustrations make topis clear without heavy use of sophisticated mathematics.

Becoming a Finite Element Analyst: A Design-Model-Verify Approach helps students become solid finite element analysts through hands-on lessons. Rather than focusing on theory, the book uses an inverted approach. Students are first shown how to build finite element models of real engineering parts through increasingly complex examples and case studies. They are then introduced to the accompanying theory. The book is based on a design-model-verify approach that teaches three key skills. Students will make decisions required to convert a real part into an appropriately simplified model. They will correctly choose the element types and boundary conditions to best represent their model. They will successfully interpret simulation results to determine if the results are realistic and reasonable. The target skills in Becoming a Finite Element Analyst include stress analysis of solids, beams, shells, and assemblies; modal and bucking analysis; and nonlinear and thermal analysis. Each lesson highlights basic concepts to be built on as the book progresses and provides a corresponding homework assignment or mini-project. Becoming a Finite Element Analyst is suitable for senior-level undergraduate or beginning graduate courses in applied finite element methods.

Finite Element Analysis Applications: A Systematic and Practical Approach strikes a solid balance between more traditional FEA textbooks that focus primarily on theory, and the software specific guidebooks that help teach students and professionals how to use particular FEA software packages without providing the theoretical foundation. In this new textbook, Professor Bi condenses the introduction of theories and focuses mainly on essentials that students need to understand FEA models. The book is organized to be application-oriented, covering FEA modeling theory and skills directly associated with activities involved in design processes. Discussion of classic FEA elements (such as truss, beam and frame) is limited. Via the use of several case studies, the book provides easy-to-follow guidance on modeling of different design problems. It uses SolidWorks simulation as the platform so that students do not need to waste time creating geometries for FEA modelling. Provides a systematic approach to dealing with the complexity of various engineering designs Includes sections on the design of machine elements to illustrate FEA applications Contains practical case studies presented as tutorials to facilitate learning of FEA methods Includes ancillary materials, such as a solutions manual for instructors, PPT lecture slides and downloadable CAD models for examples in SolidWorks

Learn Basic Theory and Software Usage from a Single Volume Finite Element Modeling and Simulation with ANSYS Workbench combines finite element theory with real-world practice. Providing an introduction to finite element modeling and analysis for those with no prior experience, and written by authors with a combined experience of 30 years teaching the subject, this text presents FEM formulations integrated with relevant hands-on applications using ANSYS Workbench for finite element analysis (FEA). Incorporating the basic theories of FEA and the use of ANSYS Workbench in the modeling and simulation of engineering problems, the book also establishes the FEM method as a powerful numerical tool in engineering design and analysis. Include FEA in Your Design and Analysis of Structures Using ANSYS Workbench The authors reveal the basic concepts in FEA using simple mechanics problems as examples, and provide a clear understanding of FEA principles, element behaviors, and solution procedures. They emphasize correct usage of FEA software, and techniques in FEA modeling and simulation. The material in the book discusses one-dimensional bar and beam elements, two-dimensional plane stress and plane strain elements, plate and shell elements, and three-dimensional solid elements in the analyses of structural stresses, vibrations and dynamics, thermal responses, fluid flows, optimizations, and failures. Contained in 12 chapters, the text introduces ANSYS Workbench through detailed examples and hands-on case studies, and includes homework problems and projects using ANSYS Workbench software that are provided at the end of each chapter. Covers solid mechanics and thermal/fluid FEA Contains ANSYS Workbench geometry input files for examples and case studies Includes two chapters devoted to modeling and solution techniques, design optimization, fatigue, and buckling failure analysis Provides modeling tips in case studies to provide readers an immediate opportunity to apply the skills they learn in a problem-solving context Finite Element Modeling and Simulation with ANSYS Workbench benefits upper-level undergraduate students in all engineering disciplines, as well as researchers and practicing engineers who use the finite element method to analyze structures.

Emphasizing how one applies FEM to practical engineering problems, this text provides a thorough introduction to the methods of finite analysis and applies these methods to problems of stress analysis, thermal analysis, fluid flow analysis, and lubrication.