Fretting Fatigue: Current Technology and PracticesThis volume includes 36 of the 40 papers presented at the symposium, and a collection of six keynote papers providing background on the subject. Topics covered include parameter effects, environmental effects, crack nucleation, material and microstructural effects, damage analysis, fracture mechanic |
Contents
Plastic Deformation in Fretting Processes a Review | 3 |
A New Approach to the Prediction of the Fretting Fatigue Life that Considers the Shifting of the Contact Edge by Wear | 19 |
On the Standardization of Fretting Fatigue Test MethodModeling Issues Related to the Thermal Constriction Phenomenon and Prediction of Contact ... | 31 |
Relation Through a Mapping Concept | 49 |
High Temperature Fretting Fatigue Behavior in an XDTM γbase TiAl | 65 |
Applications of Fracture Mechanics in Fretting Fatigue Life Assessment | 80 |
Spectrum Load Effects on the Fretting Behavior of Ti6AI4V | 100 |
The Effects of Contact Stress and Slip Distance on Fretting Fatigue Damage in Ti 6AI4V174PH Contacts | 117 |
Influence of Microstructure on Fretting Fatigue Behavior of a Nearalpha Titanium Alloy | 294 |
Fretting Fatigue Behavior of Ti6Al4V against Ti6AI4V under FlatonFlat Contact with Blending Radii | 308 |
Fretting Fatigue Strengths of Forged and Cast AlSi Aluminum Alloys | 322 |
Analysis of Fretting Damage Using Confocal Microscope | 335 |
Analysis of Fretting Damage in Polymers by Means of Fretting Maps | 352 |
Methodologies for Linking Nucleation and Propagation Approaches for Predicting Life Under Fretting Fatigue | 369 |
Fretting Fatigue Testing Methodology Incorporating Independent Slip and Fatigue Stress Control | 390 |
An Analysis of Rotating Bending Fretting Fatigue Tests Using Bridge Specimens | 404 |
Length Scale Considerations in Fretting Fatigue | 141 |
An Investigation of Friction Force in Fretting Fatigue | 154 |
A Multiaxial Fatigue Analysis of Fretting Contact Taking Into Account the Size Effect | 167 |
Interaction of HighCycle and LowCycle Fatigue on Fretting Behavior of Ti64 | 183 |
Effects of Contact Load and Contact Curvature Radius of Cylinder Pad on Fretting Fatigue in High Strength Steel | 199 |
An Experimental Investigation of Fretting Fatigue with Spherical Contact in 7075T6 Aluminum Alloy | 213 |
Fretting Fatigue of Some NickelBased Alloys in Steam Environment at 265 C | 229 |
Fretting Fatigue of 8090T7 and 7075T651 Aluminum Alloys in Vacuum and Air Environments | 247 |
Influence of Ambient Air on Nucleation in Fretting Fatigue | 257 |
Experimental Study of Fretting Crack Nucleation in Aerospace Alloys with Emphasis on Life Prediction | 267 |
Crack Behavior in the Early Stage of Fretting Fatigue Fracture | 282 |
Evaluation of Fretting Stresses Through FullField Temperature Measurements | 423 |
A New Approach in Accordance with Experimental Observations | 436 |
Development of a HighTemperatureSteam Fretting Wear Test Apparatus | 451 |
Fretting Fatigue Behavior of TiNCoated Steel | 463 |
The Effect of the Contact Conditions and Surface Treatments on the Fretting Fatigue Strength of Medium Carbon Steel | 477 |
Influence of Surface Treatments on Fretting Fatigue of Ti6242 at Elevated Temperatures | 491 |
Fracture Mechanics Approach to the Fretting Fatigue Strength of Axle Assemblies | 507 |
Fretting in Aerospace Structures and Materials | 523 |
On a New Methodology for Quantitative Modeling of Fretting Fatigue | 538 |
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Common terms and phrases
aluminum alloy analysis applied ASTM International ASTM STP axial axial stress behavior coefficient of friction components contact area contact edge contact load contact pressure contact stress contact surface crack initiation crack length crack nucleation crack propagation displacement effect elastic experimental fatigue crack growth fatigue limit fatigue specimen Figure finite element fracture mechanics fret pin fretting contact fretting crack fretting damage fretting fatigue crack fretting fatigue limit fretting fatigue strength fretting fatigue tests fretting map fretting pads fretting scar fretting wear frictional force gross slip interface investigation lap joint maximum mean stress Mechanical Engineering microstructure multiaxial fatigue normal force normal load number of cycles observed parameter partial slip plain fatigue predict residual stress rivet S-N curves shear stress shot peening shown in Fig sliding slip regime stress amplitude stress intensity factor tangential force temperature tensile Testing and Materials titanium alloy Tribology Waterhouse West Conshohocken zone
References to this book
Fretting Fatigue: Advances in Basic Understanding and Applications Steven E. Kinyon Limited preview - 2003 |