Mathematical concepts for mechanical engineering design
PREFACE
In this book a computational and practical method was used for a prediction of mechanical systems failure.
The proposed method allowed for any arbitrary combination of devices in mechanics of a liquid, gas
and plasma. A scale model and a prototype (real) system were used. This book presents the performances
of a computational method for system failure prediction by numerical
analysis and nonlinear dynamic model. In this book various methods were
developed to solve fluid mechanics problems. This range includes the approximate
equations to numerical solutions of the nonlinear Navier–Stokes equations.
The model was presented by method of the Eulerian based expressed in
a method of characteristics (MOC): finite deference, finite volume, and finite element.
It was defined by finite difference form for heterogeneous model with varying
state in the system. This book offers MOC as a computational approach from theory to practice
in numerical analysis modeling. Therefore, it was presented as the mathematical concepts for
mechanical engineering design and as a computationally efficient method for flow irreversibility
prediction in a practical case.
This book includes the research of the authors on the development of optimal mathematical
models. The problem was presented by means of theoretical and experimental research. The authors
also used modern computer technology and mathematical methods for analysis
of nonlinear dynamic processes. This collection develops a new method for the calculation of
mathematical models by computer technology. The process of entering input for the calculation
of mathematical models was simplified for the user through the use of advances in control and
automation of mechanical systems. The authors used parametric modeling technique
and multiple analyzes for mechanical systems. This method has provided a suitable
way for detecting, analyzing, and recording mechanical systems fault. Certainly, it can be
assumed as a method with high-speed response ability for detecting the failure phenomena
during irregular condition. The authors believe that the results of this book have a new idea and
it can help to reduce the risk of system damage or failure at the mechanical systems.
Download
*
PREFACE
In this book a computational and practical method was used for a prediction of mechanical systems failure.
The proposed method allowed for any arbitrary combination of devices in mechanics of a liquid, gas
and plasma. A scale model and a prototype (real) system were used. This book presents the performances
of a computational method for system failure prediction by numerical
analysis and nonlinear dynamic model. In this book various methods were
developed to solve fluid mechanics problems. This range includes the approximate
equations to numerical solutions of the nonlinear Navier–Stokes equations.
The model was presented by method of the Eulerian based expressed in
a method of characteristics (MOC): finite deference, finite volume, and finite element.
It was defined by finite difference form for heterogeneous model with varying
state in the system. This book offers MOC as a computational approach from theory to practice
in numerical analysis modeling. Therefore, it was presented as the mathematical concepts for
mechanical engineering design and as a computationally efficient method for flow irreversibility
prediction in a practical case.
This book includes the research of the authors on the development of optimal mathematical
models. The problem was presented by means of theoretical and experimental research. The authors
also used modern computer technology and mathematical methods for analysis
of nonlinear dynamic processes. This collection develops a new method for the calculation of
mathematical models by computer technology. The process of entering input for the calculation
of mathematical models was simplified for the user through the use of advances in control and
automation of mechanical systems. The authors used parametric modeling technique
and multiple analyzes for mechanical systems. This method has provided a suitable
way for detecting, analyzing, and recording mechanical systems fault. Certainly, it can be
assumed as a method with high-speed response ability for detecting the failure phenomena
during irregular condition. The authors believe that the results of this book have a new idea and
it can help to reduce the risk of system damage or failure at the mechanical systems.
Download
*