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Fracture mechanics / C.T. Sun, Z.-H. Jin.

By: Contributor(s): Material type: TextTextPublication details: Waltham, MA : Academic Press, c2012.Description: xvii, 311 p. : ill. ; 25 cmISBN:
  • 9780123850010
  • 0123850010
Subject(s): DDC classification:
  • 620.1126
LOC classification:
  • .S78 2012
Online resources:
Contents:
Introduction -- Griffith Theory of Fracture -- Elastic Stress Field Around a Crack Tip -- Energy Release Rate -- Mixed Mode Fracture -- Crack Tip Plasticity -- Elastic-Plastic Fracture Criteria -- Interfacial Cracks Between Two Dissimilar Solids -- Cohesive Zone Model -- Appendix: Stress Intensity Factors.
Summary: Most design engineers are tasked to design against failure, and one of the biggest causes of product failure is failure of the material due to fatigue/fracture. From leading experts in fracture mechanics, this new text provides new approaches and new applications to advance the understanding of crack initiation and propagation. With applications in composite materials, layered structures, and microelectronic packaging, among others, this timely coverage is an important resource for anyone studying or applying concepts of fracture mechanics. Concise and easily understood mathematical treatment of crack tip fields (chapter 3) provides the basis for applying fracture mechanics in solving practical problems. Unique coverage of bi-material interfacial cracks (chapter 8), with applications to commercially important areas of composite materials, layered structures, and microelectronic packaging. A full chapter (chapter 9) on the cohesive zone model approach, which has been extensively used in recent years to simulate crack propagation. A unified discussion of fracture criteria involving nonlinear/plastic deformations.
Holdings
Item type Current library Call number Copy number Status Date due Barcode
General Lending Carlow Campus Library General Lending 620.1126 (Browse shelf(Opens below)) 1 Available 69757

Includes bibliographical references and index.

Introduction -- Griffith Theory of Fracture -- Elastic Stress Field Around a Crack Tip -- Energy Release Rate -- Mixed Mode Fracture -- Crack Tip Plasticity -- Elastic-Plastic Fracture Criteria -- Interfacial Cracks Between Two Dissimilar Solids -- Cohesive Zone Model -- Appendix: Stress Intensity Factors.

Most design engineers are tasked to design against failure, and one of the biggest causes of product failure is failure of the material due to fatigue/fracture. From leading experts in fracture mechanics, this new text provides new approaches and new applications to advance the understanding of crack initiation and propagation. With applications in composite materials, layered structures, and microelectronic packaging, among others, this timely coverage is an important resource for anyone studying or applying concepts of fracture mechanics. Concise and easily understood mathematical treatment of crack tip fields (chapter 3) provides the basis for applying fracture mechanics in solving practical problems. Unique coverage of bi-material interfacial cracks (chapter 8), with applications to commercially important areas of composite materials, layered structures, and microelectronic packaging. A full chapter (chapter 9) on the cohesive zone model approach, which has been extensively used in recent years to simulate crack propagation. A unified discussion of fracture criteria involving nonlinear/plastic deformations.

68.61

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