Presentation is loading. Please wait.

Presentation is loading. Please wait.

Asperities and surface initiated rolling contact fatigue Bo Alfredsson Solid Mechanics at KTH 2015-10-07 – Tribodays Nynäshamn.

Published byTobias McKenzie Modified over 8 years ago

Similar presentations

Presentation on theme: "Asperities and surface initiated rolling contact fatigue Bo Alfredsson Solid Mechanics at KTH 2015-10-07 – Tribodays Nynäshamn."— Presentation transcript:

1 Asperities and surface initiated rolling contact fatigue Bo Alfredsson Solid Mechanics at KTH 2015-10-07 – Tribodays Nynäshamn

2 Rolling contact fatigue Rolling contact fatigue has been considered the default failure mode of Hertzian rolling contact elements: If all other failure modes could be avoided, then rolling contact fatigue would eventually limit the component life.

3 Rolling Contact Fatigue – gears and bearings

4 Two types of Rolling Contact Fatigue  v ≈  · r Rolling contact Sub-surface initiation 3 mm Tallian 1992 Surface initiation

5 Surface initiated spalling 0.2 mm 0.1 mm   = 20 – 24 º

6 General conditions for fatigue initiation and fatigue crack growth Initiation  Sufficiently large shear stress amplitude  Tensile maximum stress Fatigue crack growth  Sufficiently large  K I ( > K th, which is R dependent)  Open crack tip: K I,max –  K I > K I,cl  Crack with mode II or mode III fatigue load will arrest or kink to mode I  Crack will follow direction of maximum  K I

7 Whole contact: 2D line contact  Always pressure!  Stress free surface (J 2.15) rr r  Line load – 2D P

8 The spall is local, asperity is local – local point contact  Tensile radial stress! z r rr Sphere

9 Asperity mechanism for surface initiated spalling Inside – compression Together Line Cmpressive stresses Stress free Entry – compression and tension Asperity  point contact Tensile surface stress

10 Gear surface roughness profile Asperity size from roughness measurements Radius of curvature at roll circle – R = 13.6 mm Nominal contact pressures: 2.10 – 2.27 Gpa Model asperities  dh /  m 2002 1001 502 Yes, asperities exist! How can they be responsible for spalling?

11 Stress in front of rolling contact entering asperity  d = 200  m h = 2  m  d = 100  m h = 2  m  d = 100  m h = 1  m  d = 50  m h = 2  m

12 Influence of asperity size: asp = h asp /r asp

13 Influence of contact friction: 

14 Influence of residual surface stress:  R / MPa

15 Asperity mechanism for surface RCF: Questions to be answered Can a point contact give fatigue? Do the conditions exist in applications? Asperities? Stress levels? Is the crack behaviour predicted? Crack profile of spalls Spalling life Is the parameter influence predicted? Residual surface stress Surface roughness  Lubrication film thickness and EHD influence o Well, more to follow o On-going research  Mechanism explains why and how Design guidelines

16 Asperities and surface initiated rolling contact fatigue Bo Alfredsson

Download ppt "Asperities and surface initiated rolling contact fatigue Bo Alfredsson Solid Mechanics at KTH 2015-10-07 – Tribodays Nynäshamn."

Similar presentations

Chap.8 Mechanical Behavior of Composite

Chap.8 Mechanical Behavior of Composite
ME 240: Introduction to Engineering Materials Chapter 8. Failure 8.1 CHAPTER 8.

ME 240: Introduction to Engineering Materials Chapter 8. Failure 8.1 CHAPTER 8.
Lecture 25 Bodies With Holes / Stress Perturbations Around Cracks Geol 542 Textbook reading: p.313-318; 354-357.

Lecture 25 Bodies With Holes / Stress Perturbations Around Cracks Geol 542 Textbook reading: p ;
Mechanical Engineering Tribology Laboratory (METL) November 14, 2013 Yi Shen Research Assistant Effect of Retained Austenite and Residual Stress on Rolling.

Mechanical Engineering Tribology Laboratory (METL) November 14, 2013 Yi Shen Research Assistant Effect of Retained Austenite and Residual Stress on Rolling.
Mechanical Engineering Dept.

Mechanical Engineering Dept.
Design of Machine Elements

Design of Machine Elements
November 14, 2013 Mechanical Engineering Tribology Laboratory (METL) Benjamin Leonard Post-Doctoral Research Associate Third Body Modeling Using a Combined.

November 14, 2013 Mechanical Engineering Tribology Laboratory (METL) Benjamin Leonard Post-Doctoral Research Associate Third Body Modeling Using a Combined.
Pavement Analysis and Design

Pavement Analysis and Design
Chapter 3 Biomechanics of Articular Cartilage

Chapter 3 Biomechanics of Articular Cartilage
The Influence of Surface Roughness on Thin Film, Mixed Lubrication

The Influence of Surface Roughness on Thin Film, Mixed Lubrication
Simulation of Pillar Failure Using FRACOD 2D. Objective n To test the capability of FRACOD 2D in predicting failure of a pillar between two rock excavations.

Simulation of Pillar Failure Using FRACOD 2D. Objective n To test the capability of FRACOD 2D in predicting failure of a pillar between two rock excavations.
Simulation of Borehole Breakouts Using FRACOD. Objective n To test the capability of the fracture propagation code FRACOD in predicting borehole breakouts.

Simulation of Borehole Breakouts Using FRACOD. Objective n To test the capability of the fracture propagation code FRACOD in predicting borehole breakouts.
Estimation of Engine Frictional Power P M V Subbarao Professor Mechanical Engineering Department Understand and Analyze All means of Power Draining…

Estimation of Engine Frictional Power P M V Subbarao Professor Mechanical Engineering Department Understand and Analyze All means of Power Draining…
3 Torsion.

3 Torsion.
Case study: starter pinions (1) Established within the GROWTH project GRD1-1999-10748 Improvement of Service Life and Reliability of Cold Forging Tools.

Case study: starter pinions (1) Established within the GROWTH project GRD "Improvement of Service Life and Reliability of Cold Forging Tools.
Products made from rolling

Products made from rolling
Japan-US Workshop held at San Diego on April 6-7, 2002 How can we keep structural integrity of the first wall having micro cracks? R. Kurihara JAERI-Naka.

Japan-US Workshop held at San Diego on April 6-7, 2002 How can we keep structural integrity of the first wall having micro cracks? R. Kurihara JAERI-Naka.
Design of an Aerospace Component

Design of an Aerospace Component
Influence of Overload Induced Residual Stress Field on Fatigue Crack Growth in Aluminum Alloy Jinhee Park (M.S. Candidate) Date of joining Masters’ program.

Influence of Overload Induced Residual Stress Field on Fatigue Crack Growth in Aluminum Alloy Jinhee Park (M.S. Candidate) Date of joining Masters’ program.
Screws, Fasteners, and the Design of Nonpermanent Joints

Screws, Fasteners, and the Design of Nonpermanent Joints

Similar presentations

Ads by Google