Mechanical and electro-chemical interactions under tribocorrosion : from measurements to modelling for building a relevant monitoring approach / edited by Pierre Ponthiaux, Jean-Pierre Celis.

Format:

Book

Contributor:

Ponthiaux, P. (Pierre), editor.

Celis, Jean-Pierre, editor.

Series:

Publications (European Federation of Corrosion)

European Federation of Corrosion publications

Language:

English

Subjects (All):

Tribo-corrosion.

Physical Description:

1 online resource (280 pages)

Edition:

1st ed.

Place of Publication:

Duxford, England ; Cambridge, Massachusetts : Woodhead Publishing, [2021]

Summary:

Mechanical and Electro-chemical Interactions under Tribocorrosion: From Measurements to Modelling for Building a Relevant Monitoring Approach looks at progress in the field of tribocorrosion.

Contents:

Intro

Mechanical and Electro-chemical Interactions under Tribocorrosion: From Measurements to Modeling for Building a Relevant M ...

Copyright

Contents

European Federation of Corrosion publications: Series introduction

Volumes in the EFC series

Contributors

Chapter 1: Preamble

Chapter 2: Stress/strain effects on electrochemical activity: Metallurgical/mechanical/interactions and surface reactivity

2.1. Introduction

2.2. Definition of a relevant approach

2.3. Influence of compressive stresses

2.4. Influence of tensile stresses in the elastic domain

2.5. Influence of plastic deformation

2.5.1. Geometrical effects due to the presence of slip bands

2.5.2. Crevice effect due to the presence of cracks

2.5.3. Modifications of the passive film

2.5.4. Presence of dislocations

2.5.5. Influence of grain refinement generated by severe plastic deformation

2.6. Conclusions

2.7. Notations

References

Chapter 3: Mechanical and chemical coupling in tribocorrosion: In situ and ex situ characterization techniques

3.1. Introduction

3.2. Local electrochemical techniques

3.2.1. Scanning reference electrode technique (SRET) and scanning vibrating electrode technique (SVET)

3.2.1.1. General description

3.2.1.2. Scanning vibrating electrode technique. Experimental results for surface abrasion

3.2.2. Electrochemical microcell (EMC)

3.2.3. Scanning Kelvin probe

3.2.3.1. Principles of the technique

3.2.3.2. SKP application to tribocorrosion and experimental results

3.2.4. Local electrochemical impedance spectroscopy (LEIS)

3.2.5. Scanning electrochemical microscopy (SECM)

3.2.6. Atomic force microscopy (AFM) and scanning Kelvin probe force microscopy (SKPFM)

3.3. Application of in situ vibrational spectroscopy for studies of tribochemical and tribocorrosion processes.

3.4. Conclusions

3.5. List of symbols

3.6. List of abbreviations

Chapter 4: Managing tribocorrosion investigations by stress mapping: Dual mobility concept, hip implant, as required step

4.1. Introduction

4.2. Testing of human gait in vitro as an example

4.2.1. Materials, size of contacting parts and set-up

4.2.2. Some results on the maximum pressure recoded by the pressure-sensitive film

4.3. Applications in tribocorrosion

4.3.1. Cup positioning/samples positioning influence

4.3.2. Liquid influence/contact pressure influence

4.3.3. The clearance impact of any contact

4.3.4. Tribocorrosion and pressure-mapping film

4.4. Conclusions

4.5. Notations

Acknowledgments

Further reading

Chapter 5: Parallel wear tests: The need for statistical analysis in tribology

5.1. Introduction: Lab testing approach to industrial issues of tribocorrosion

5.2. Need for statistics to analyze wear

5.3. State-of-the-art on current wear generators

5.4. Industrial examples on statistical wear analysis

5.4.1. Biomedical field

5.4.2. Construction industry

5.4.3. Printing industry

5.4.4. Aeronautical field

5.4.5. Offshore installations

5.4.6. Industrial coatings

5.5. Summary

5.6. Notations

Chapter 6: The use of the Pearson's correlation coefficients to identify mechanical-physical-chemical parameters controlli ...

6.1. Introduction

6.2. The Pearson correlation method

6.2.1. Assumptions

6.2.2. Basic principles of the PCM

6.2.3. Significance test

6.2.4. Output of the PCM

6.3. Methodology

6.4. Application of the PCM in corrosion science and engineering

6.5. Application of the PCM to stress corrosion cracking and fatigue corrosion

6.6. Application of the PCM to tribocorrosion

6.7. Conclusions

6.8. Notations.

References

Chapter 7: Fretting wear analysis through a mechanical friction energy approach: Impact of contact loadings and ambient c ...

7.1. Introduction

7.2. Fretting test experiments

7.2.1. Fretting sliding condition

7.2.2. Fretting regime concept

7.3. Fretting mapping approach

7.4. Wear rate description

7.4.1. Archard and friction energy wear approach

7.4.2. Third-body theory

7.4.3. Contact oxygenation concept

7.5. Influence of contact loadings regarding wear rate fluctuations

7.5.1. Influence of the sliding amplitude

7.5.2. Influence of the normal load

7.5.3. Influence of the sliding frequency

7.5.4. Influence of the contact size

7.5.5. Extended wear coefficient approach: A power law formulation

7.6. Influence of the ambient conditions

7.6.1. Influence of temperature

7.6.2. Influence of the lubricated (grease) interface

7.6.3. Influence of the aqueous (corrosion) processes

7.7. Surface wear modeling: Prediction of the maximum wear depth

7.7.1. Modeling of worn profiles

7.7.2. Prediction of the coating durability using the friction energy density parameter

7.8. Conclusion

7.9. Notations

Chapter 8: Harmonic analysis of tribocorrosion: Identification of repassivation kinetics and separation of reactive (corro ...

8.1. Introduction

8.2. General concept, experimental approach, and techniques

8.3. Analysis of repassivation kinetics by ac modulation of the angular velocity of the counter-body

8.3.1. General formalism of the response to a time-dependent velocity of wear

8.3.2. Experimental validation and application

8.4. From steady-state to electrochemical impedance ac modulation of the applied potential

8.4.1. General formalism of the current response to a time-dependent potential

8.4.2. Reaction model of dissolution-repassivation.

8.4.3. Application to the tribocorrosion of stainless steel in an acidic solution

8.4.4. Application to the separation of contributions to the total wear: Reactive and mechanical

8.5. Conclusions and perspectives

8.6. Notations

Chapter 9: Modeling erosion-corrosion in metals: The effects of elastic rebound and impact angle on erosion-corrosion maps

9.1. Introduction

9.2. Energy balance during a solid particle erosion event

9.3. Derivation of an expression for the coefficient of restitution

9.4. Derivation of erosion models based on the rebound analysis

9.4.1. The effect of particle rebound on the erosion models

9.4.2. Dimensionless erosion based on erodent rebound effect

9.4.3. Derivation of pure erosion rate from the dimensionless erosion

9.5. Corrosion rate and boundary conditions

9.5.1. Corrosion rates at active and passive conditions

9.5.2. Boundary conditions for the erosion-corrosion maps

9.6. Elastic rebound effects on the transition boundaries of the aqueous erosion-corrosion map

9.6.1. Velocity-Potential maps for a range of pure metals

9.6.2. Velocity-Impact angle map for a range of pure metals

9.7. Discussion

9.8. Conclusions

9.9. Notations

Chapter 10: A monitoring management strategy in tribocorrosion: Application to erosion-corrosion in oil and gas exploratio ...

10.1. Introduction

10.2. Erosion-corrosion in oil and gas production

10.2.1. Erosion-corrosion concerns

10.2.2. Erosive agents

10.2.3. Corrosive materials, CO2 corrosion

10.2.4. System and subsystem components sensitive to abrasion and erosion-corrosion

10.3. Erosion and corrosion management strategy

10.3.1. Tolerable erosion and corrosion

10.3.2. Risk assessment

10.3.2.1. Class of erosive service

10.3.2.2. Risk assessment.

10.3.3. Basis of the sand production strategy

10.3.3.1. Sand control

10.3.3.2. Selection criteria and methodology

10.3.3.3. Sand production mitigation measures

10.3.3.4. Material selection and corrosion inhibitors

10.3.4. Experimental methods for investigating erosion-corrosion

10.3.4.1. Erosion-corrosion laboratory and loop tests

10.3.4.2. Erosion and corrosion models

10.3.5. On site erosion-corrosion monitoring

10.4. Conclusions

10.5. Notations

Index.

Notes:

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Description based on print version record.

Description based on publisher supplied metadata and other sources.

ISBN:

9780128237663

012823766X

OCLC:

1265465066