Advances in Understanding the Fatigue Behavior of Materials
Special topic volume with invited papers only.
Published on 29. September 2008
Book
Paperback/Softback
420 pages
978-0-87849-394-4 (ISBN)
Description
This special-topic book consists of a collection of technical papers assembled under the rubric of "Advances in Understanding the Fatigue Behavior of Materials". The focus of "Fatigue Behavior of Materials" centers on the changes in properties that occur upon applying cyclic loads. Following its recognition and increasing importance during the latter half of the nineteenth century, this branch of study has focused upon the study and rationalization of the engineering approaches that are commonly used to design against the initiation and/or propagation of the fatigue damage which would otherwise culminate in catastrophic failure.
More details
Other editions
Additional editions
Tirumalai S. Srivatsan
Advances in Understanding the Fatigue Behavior of Materials
Software
09/2008
Trans Tech Publications Ltd
€324.09
Shipment within 10-20 days
Tirumalai S. Srivatsan
Advances in Understanding the Fatigue Behavior of Materials
E-Book
03/2008
Trans Tech Publications Ltd
€211.86
Available for download
Content
<ul><li>Preface</li><li>Section 1: FERROUS ALLOYS</li><li>The Fatigue Behavior of Steel Structures under Random Loading </li><li>Low Cycle Fatigue Behavior and Microcracks Nucleation on Duplex Stainless Steels </li><li>High Cycle Fatigue Behavior of Normalized 0.15% C Steel under Tension-Compression and Torsion Loading </li><li>On the Cyclic Stability and Fatigue Performance of Ultrafine-Grained Interstitial-Free Steel under Mean Stress</li><li>Fatigue Crack Growth Resistance of Special Nodular Cast Irons</li><li>Internal Fatigue Failure Mechanism of High Strength Steels in Gigacycle Regime</li><li>Advances in Cyclic Behavior and Lifetime Modeling of Tempered Martensitic Steels Based on Microstructural Considerations</li><li>The Fatigue Properties of Duplex Stainless Steels: Role of Microstructure</li><li>Section 2: NON-FERROUS ALLOYS</li><li>Comparison of the Fatigue Crack Propagation Resistance of ?+? and ? Titanium Alloys</li><li>High Cycle Fatigue Behavior of Magnesium Alloys under Corrosive Environment</li><li>The Fretting Fatigue Behavior of Ti-6Al-4V</li><li>Cyclic Depth-Sensing Indentation of Gold Wire</li><li>The High Cycle Fatigue and Fracture Behavior of Friction Stir Welded Aluminum Alloy 2024</li><li>An Investigation of the High Cycle Fatigue and Final Fracture Behavior of Aluminum Alloy 2219</li><li>Low Cycle Fatigue in Model Al-Si Alloys. A Contribution to the Understanding of Cyclic Damage in Two Phase Materials</li><li>High Temperature Low-Cycle Fatigue, Deformation Microstructure and Final Fracture Behavior of a Nickel-Base Superalloy</li><li>An Investigation of the Cyclic Fatigue and Final Fracture Behavior of a Titanium Alloy</li><li>Section 3: EMERGING MATERIALS</li><li>Understanding the Fatigue Behaviour of NiTiCu Shape Memory Alloy Wire Thermal Actuators</li><li>Mechanisms and Mechanics of Fatigue Crack Propagation in Zr-Based Bulk Metallic Glass</li><li>Direct Comparisons of the Fatigue Behavior of Bulk-Metallic Glasses and Crystalline Alloys</li><li>Section 4: ALTERNATIVE NOVEL APPROACHES TO STUDYING FATIGUE</li><li>Surface Cracks in Round Bars under Cyclic Tension or Bending</li><li>Some Applications of Fractal Fracture Mechanics to Describe the Fatigue Behaviour of Materials</li><li>A Study of Fatigue (Cyclic Deformation) Behavior in FCC Metals Using Strain Rate Change Tests</li><li>A Dissipated Energy Approach to Fatigue Crack Growth in Ductile Solids and Layered Materials</li></ul>