Applications of Finite Element Modeling for Mechanical and Mechatronic Systems

doi:10.3390/books978-3-0365-1556-4

Reprint

Download Flyer

Applications of Finite Element Modeling for Mechanical and Mechatronic Systems

Edited by

August 2021

392 pages

ISBN978-3-0365-1555-7 (Hardback)
ISBN978-3-0365-1556-4 (PDF)

https://doi.org/10.3390/books978-3-0365-1556-4

Free download (PDF)

This book is a reprint of the Special Issue Applications of Finite Element Modeling for Mechanical and Mechatronic Systems that was published in

Biology & Life Sciences

Chemistry & Materials Science

Computer Science & Mathematics

Engineering

Environmental & Earth Sciences

Physical Sciences

Summary

Modern engineering practice requires advanced numerical modeling because, among other things, it reduces the costs associated with prototyping or predicting the occurrence of potentially dangerous situations during operation in certain defined conditions. Thus far, different methods have been used to implement the real structure into the numerical version. The most popular uses have been variations of the finite element method (FEM). The aim of this Special Issue has been to familiarize the reader with the latest applications of the FEM for the modeling and analysis of diverse mechanical problems. Authors are encouraged to provide a concise description of the specific application or a potential application of the Special Issue.

Format

Hardback

License

Keywords

numerical modeling; finite volumne method; underground coal mine; endogenous fires; spontaneous combustion; longwall; ventilation system; shot peening; quantitative description of peening coverage; high peening coverage; Almen intensity; residual compressive stress; hybrid composite; damage; aramid fiber; carbon fiber; finite element method; delamination; cut bar method; thermal conductivity; finite element method; steady-state; heat lakes; finite element modeling; aluminum conductor steel-reinforced cable; bend deformation; stress; friction coefficient; wind loads; fatigue fracture; FEM; SFEM; active periodic structures; smart materials; PCHE; FEM; misalignment; stress; channel; utilization factor; torsion springs; FEA; NURBS; applied load; local behaviors; drill pipe joint; design; sealing properties; experiment; bias tire; textile cord; shrinkage; rubber; inflation analysis; finite element modeling; nondestructive inspection; crack detection; low loading; surface profile; turbine blade; finite element analysis; swingarm; single-sided; Finite Elements Analysis (FEA); three-wheel motorcycle; topology optimization; collision modeling; mechanical parameters; contact detection; web deformation; strain deviation; design of experiment; roll-to-roll process; solid mechanics; finite elements; hp-adaptivity; numerical locking; detection; assessment; resolution; equilibrated residual method; sensitivity analysis; p-enrichment; bell crank; topology optimization; natural frequency; reverse engineering; vibrometer; design; Abaqus; finite element method; numerical simulation; biomechanics; head injury; safety; injury criteria; disability; driver; HALE UAV; generative modelling; thin-layer composite structure; electro-mechanical systems; piezoelectrics; hierarchical models; first-order models; transition models; hpq/hp-approximations; adaptivity; stress gradients; convergence; finite element method; numerical modeling; mechanical parameters; damage detection