U. S. Dixit: Modeling of Metal Forming and Machining Processes, Kartoniert / Broschiert

Beschreibung

The physics of metal forming and metal removing is normally expressed using non-linear partial differential equations which can be solved using the finite element method (FEM). However, when the process parameters are uncertain and / or the physics of the process is not well understood, soft computing techniques can be used with FEM or alone to model the process.
Using FEM, fuzzy set theory and neural networks as modeling tools; Modeling of Metal Forming and Machining Processes provides a complete treatment of metal forming and machining, and includes: an explanation of FEM and its application to the modeling of manufacturing processes; a discussion of the numerical difficulties of FEM; chapters on the application of soft computing techniques in this modeling process.
The algorithms and solved examples included make Modeling of Metal Forming and Machining Processes of value to postgraduates, senior undergraduates, lecturers and researchers in these fields. R&D engineers and consultants for the manufacturing industry will also find it of use.

Inhaltsangabe

Metal Forming and Machining Processes Review of Stress, Linear Strain and Elastic Stress-Strain Relations Classical Theory of Plasticity Plasticity of Finite Deformation and Anisotropic Materials and Modeling of Fracture and Friction Finite Element Modeling of Metal Forming Processes Using Eulerian Formulation Finite Element Modeling of Metal Forming Processes Using Updated Lagrangian Formulation Finite Element Modeling of Orthogonal Machining Process Background on Soft Computing Predictive Modeling of Metal Forming and Machining Processes Using Soft Computing Optimization of Metal Forming and Machining Processes Epilogue

Klappentext

The use of computational techniques is increasing day by day in the manufacturing sector. Process modeling and optimization with the help of computers can reduce expensive and time consuming experiments for manufacturing good quality products. Metal forming and machining are two prominent manufacturing processes. Both of these processes involve large deformation of elasto-plastic materials due to applied loads. In metal forming, the material is plastically deformed without causing fracture. On the other hand, in machining, the material is deformed till fracture, in order to remove material in the form of chips. To understand the physics of metal forming and machining processes, one needs to understand the kinematics of large deformation (dependence of deformation and its rate on displacement) as well as the constitutive behavior of elasto-plastic materials (dependence of internal forces on deformation and its rate). Once the physics is understood, these phenomena have to be converted to mathematical relations in the form of differential equations. The interaction of the work-piece with the tools / dies and other surroundings also needs to be expressed in a mathematical form (known as the boundary and initial conditions). In this book, the first four chapters essentially discuss the physics of metal forming and machining processes. The physical behavior of the work-piece during the processes is modeled in the form of differential equations and boundary and initial conditions.