Crack Problems in the Classical Theory of Elasticity
Title | Crack Problems in the Classical Theory of Elasticity PDF eBook |
Author | Ian Naismith Sneddon |
Publisher | John Wiley & Sons |
Pages | 248 |
Release | 1969 |
Genre | Mathematics |
ISBN |
Contact Problems in the Classical Theory of Elasticity
Title | Contact Problems in the Classical Theory of Elasticity PDF eBook |
Author | G.M.L. Gladwell |
Publisher | Springer Science & Business Media |
Pages | 740 |
Release | 1980-06-30 |
Genre | Science |
ISBN | 9789028607606 |
Crack Problems in the Classical Theory of Elasticity
Title | Crack Problems in the Classical Theory of Elasticity PDF eBook |
Author | Ian Naismith Sneddon |
Publisher | John Wiley & Sons |
Pages | 248 |
Release | 1969 |
Genre | Mathematics |
ISBN |
Elasticity
Title | Elasticity PDF eBook |
Author | Martin H. Sadd |
Publisher | Elsevier |
Pages | 474 |
Release | 2010-08-04 |
Genre | Technology & Engineering |
ISBN | 008047747X |
Although there are several books in print dealing with elasticity, many focus on specialized topics such as mathematical foundations, anisotropic materials, two-dimensional problems, thermoelasticity, non-linear theory, etc. As such they are not appropriate candidates for a general textbook. This book provides a concise and organized presentation and development of general theory of elasticity. This text is an excellent book teaching guide. - Contains exercises for student engagement as well as the integration and use of MATLAB Software - Provides development of common solution methodologies and a systematic review of analytical solutions useful in applications of
Methods of Analysis and Solutions of Crack Problems
Title | Methods of Analysis and Solutions of Crack Problems PDF eBook |
Author | George C. Sih |
Publisher | Springer Science & Business Media |
Pages | 562 |
Release | 2013-11-11 |
Genre | Science |
ISBN | 9401722609 |
It is weH known that the traditional failure criteria cannot adequately explain failures which occur at a nominal stress level considerably lower than the ultimate strength of the material. The current procedure for predicting the safe loads or safe useful life of a structural member has been evolved around the discipline oflinear fracture mechanics. This approach introduces the concept of a crack extension force which can be used to rank materials in some order of fracture resistance. The idea is to determine the largest crack that a material will tolerate without failure. Laboratory methods for characterizing the fracture toughness of many engineering materials are now available. While these test data are useful for providing some rough guidance in the choice of materials, it is not clear how they could be used in the design of a structure. The understanding of the relationship between laboratory tests and fracture design of structures is, to say the least, deficient. Fracture mechanics is presently at astandstill until the basic problems of scaling from laboratory models to fuH size structures and mixed mode crack propagation are resolved. The answers to these questions require some basic understanding ofthe theory and will not be found by testing more specimens. The current theory of fracture is inadequate for many reasons. First of aH it can only treat idealized problems where the applied load must be directed normal to the crack plane.
Methods of Analysis and Solutions of Crack Problems
Title | Methods of Analysis and Solutions of Crack Problems PDF eBook |
Author | George C. Sih |
Publisher | Springer Science & Business Media |
Pages | 578 |
Release | 1973-01-31 |
Genre | Science |
ISBN | 9789001798604 |
It is weH known that the traditional failure criteria cannot adequately explain failures which occur at a nominal stress level considerably lower than the ultimate strength of the material. The current procedure for predicting the safe loads or safe useful life of a structural member has been evolved around the discipline oflinear fracture mechanics. This approach introduces the concept of a crack extension force which can be used to rank materials in some order of fracture resistance. The idea is to determine the largest crack that a material will tolerate without failure. Laboratory methods for characterizing the fracture toughness of many engineering materials are now available. While these test data are useful for providing some rough guidance in the choice of materials, it is not clear how they could be used in the design of a structure. The understanding of the relationship between laboratory tests and fracture design of structures is, to say the least, deficient. Fracture mechanics is presently at astandstill until the basic problems of scaling from laboratory models to fuH size structures and mixed mode crack propagation are resolved. The answers to these questions require some basic understanding ofthe theory and will not be found by testing more specimens. The current theory of fracture is inadequate for many reasons. First of aH it can only treat idealized problems where the applied load must be directed normal to the crack plane.
Mathematical and Computational Analyses of Cracking Formation
Title | Mathematical and Computational Analyses of Cracking Formation PDF eBook |
Author | Yoichi Sumi |
Publisher | Springer |
Pages | 285 |
Release | 2014-06-11 |
Genre | Science |
ISBN | 4431549358 |
This book is about the pattern formation and the evolution of crack propagation in engineering materials and structures, bridging mathematical analyses of cracks based on singular integral equations, to computational simulation of engineering design. The first two parts of this book focus on elasticity and fracture and provide the basis for discussions on fracture morphology and its numerical simulation, which may lead to a simulation-based fracture control in engineering structures. Several design concepts are discussed for the prevention of fatigue and fracture in engineering structures, including safe-life design, fail-safe design, damage tolerant design. After starting with basic elasticity and fracture theories in parts one and two, this book focuses on the fracture morphology that develops due to the propagation of brittle cracks or fatigue cracks. In part three, the mathematical analysis of a curved crack is precisely described, based on the perturbation method. The stability theory of interactive cracks propagating in brittle solids may help readers to understand the formation of a fractal-like cracking patterns in brittle solids, while the stability theory of crack paths helps to identify the straight versus sharply curved or sometimes wavy crack paths observed in brittle solids. In part four, the numerical simulation method of a system of multiple cracks is introduced by means of the finite element method, which may be used for the better implementation of fracture control in engineering structures. This book is part of a series on “Mathematics for Industry” and will appeal to structural engineers seeking to understand the basic backgrounds of analyses, but also to mathematicians with an interest in how such mathematical solutions are evaluated in industrial applications.