Fatigue of materials and structures: application to design and damage
Gespeichert in:
| Format: | Elektronisch E-Book |
|---|---|
| Sprache: | English |
| Veröffentlicht: |
London
ISTE
2011
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| Schlagworte: | |
| Beschreibung: | xiii, 344 p. |
| ISBN: | 1848212917 9781848212916 9781118616512 |
Internformat
MARC
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| 020 | |a 9781848212916 |9 978-1-84821-291-6 | ||
| 020 | |a 9781118616512 |c Online |9 978-1-118-61651-2 | ||
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| 041 | 0 | |a eng | |
| 082 | 0 | |a 620.1126 |2 22 | |
| 245 | 1 | 0 | |a Fatigue of materials and structures |b application to design and damage |c edited by Claude Bathias, Andre Pineau |
| 264 | 1 | |a London |b ISTE |c 2011 | |
| 300 | |a xiii, 344 p. | ||
| 336 | |b txt |2 rdacontent | ||
| 337 | |b c |2 rdamedia | ||
| 338 | |b cr |2 rdacarrier | ||
| 505 | 8 | |a Includes bibliographical references and index | |
| 505 | 8 | |a Machine generated contents note: ch. 1 Multiaxial Fatigue / Marc Bletry and Georges Cailletaud -- 1.1.Introduction -- 1.1.1.Variables in a plane -- 1.1.2.Invariants -- 1.1.3.Classification of the cracking modes -- 1.2.Experimental aspects -- 1.2.1.Multiaxial fatigue experiments -- 1.2.2.Main results -- 1.2.3.Notations -- 1.3.Criteria specific to the unlimited endurance domain -- 1.3.1.Background -- 1.3.2.Global criteria -- 1.3.3.Critical plane criteria -- 1.3.4.Relationship between energetic and mesoscopic criteria -- 1.4.Low cycle fatigue criteria -- 1.4.1.Brown-Miller -- 1.4.2.SWT criteria -- 1.4.3.Jacquelin criterion -- 1.4.4.Additive criteria under sliding and stress amplitude -- 1.4.5.Onera model -- 1.5.Calculating methods of the lifetime under multiaxial conditions -- 1.5.1.Lifetime at N cycles for a periodic loading -- 1.5.2.Damage cumulation -- 1.5.3.Calculation methods -- 1.6.Conclusion -- 1.7.Bibliography -- ch. 2 Cumulative Damage / Jean-Louis Chaboche -- | |
| 505 | 8 | |a 2.1.Introduction -- 2.2.Nonlinear fatigue cumulative damage -- 2.2.1.Main observations -- 2.2.2.Various types of nonlinear cumulative damage models -- 2.2.3.Possible definitions of the damage variable -- 2.3.A nonlinear cumulative fatigue damage model -- 2.3.1.General form -- 2.3.2.Special forms of functions F and G -- 2.3.3.Application under complex loadings -- 2.4.Damage law of incremental type -- 2.4.1.Damage accumulation in strain or energy -- 2.4.2.Lemaitre's formulation -- 2.4.3.Other incremental models -- 2.5.Cumulative damage under fatigue-creep conditions -- 2.5.1.Rabotnov-Kachanov creep damage law -- 2.5.2.Fatigue damage -- 2.5.3.Creep-fatigue interaction -- 2.5.4.Practical application -- 2.5.5.Fatigue-oxidation-creep interaction -- 2.6.Conclusion -- 2.7.Bibliography -- ch. 3 Damage Tolerance Design / Raphael Cazes -- 3.1.Background -- 3.2.Evolution of the design concept of "fatigue" phenomenon -- 3.2.1.First approach to fatigue resistance -- | |
| 505 | 8 | |a 3.2.2.The "damage tolerance" concept -- 3.2.3.Consideration of "damage tolerance" -- 3.3.Impact of damage tolerance on design -- 3.3.1."Structural" impact -- 3.3.2."Material" impact -- 3.4.Calculation of a "stress intensity factor" -- 3.4.1.Use of the "handbook" (simple cases) -- 3.4.2.Use of the finite element method: simple and complex cases -- 3.4.3.A simple method to get new configurations -- 3.4.4."Superposition" method -- 3.4.5.Superposition method: applicable examples -- 3.4.6.Numerical application exercise -- 3.5.Performing some "damage tolerance" calculations -- 3.5.1.Complementarity of fatigue and damage tolerance -- 3.5.2.Safety coefficients to understand curve a = f(N) -- 3.5.3.Acquisition of the material parameters -- 3.5.4.Negative parameter: corrosion -- "corrosion fatigue" -- 3.6.Application to the residual strength of thin sheets -- 3.6.1.Planar panels: Feddersen diagram -- 3.6.2.Case of stiffened panels -- | |
| 505 | 8 | |a 3.7.Propagation of cracks subjected to random loading in the aeronautic industry -- 3.7.1.Modeling of the interactions of loading cycles -- 3.7.2.Comparison of predictions with experimental results -- 3.7.3.Rainflow treatment of random loadings -- 3.8.Conclusion -- 3.8.1.Organization of the evolution of "damage tolerance" -- 3.8.2.Structural maintenance program -- 3.8.3.Inspection of structures being used -- 3.9.Damage tolerance within the gigacyclic domain -- 3.9.1.Observations on crack propagation -- 3.9.2.Propagation of a fish-eye with regards to damage tolerance -- 3.9.3.Example of a turbine disk subjected to vibration -- 3.10.Bibliography -- ch. 4 Defect Influence on the Fatigue Behavior of Metallic Materials / Gilles Baudry -- 4.1.Introduction -- 4.2.Some facts -- 4.2.1.Failure observation -- 4.2.2.Endurance limit level -- 4.2.3.Influence of the rolling reduction ratio and the effect of rolling direction -- 4.2.4.Low cycle fatigue: SN curves -- | |
| 505 | 8 | |a 4.2.5.Wohler curve: existence of an endurance limit -- 4.2.6.Summary -- 4.3.Approaches -- 4.3.1.First models -- 4.3.2.Kitagawa diagram -- 4.3.3.Murakami model -- 4.4.A few examples -- 4.4.1.Medium-loaded components: example of as-forged parts: connecting rods -- effect of the forging skin -- 4.4.2.High-loaded components: relative importance of cleanliness and surface state -- example of the valve spring -- 4.4.3.High-loaded components: Bearings-Endurance cleanliness relationship -- 4.5.Prospects -- 4.5.1.Estimation of lifetimes and their dispersions -- 4.5.2.Fiber orientation -- 4.5.3.Prestressing -- 4.5.4.Corrosion -- 4.5.5.Complex loadings: spectra/over-loadings/multiaxial loadings -- 4.5.6.Gigacycle fatigue -- 4.6.Conclusion -- 4.7.Bibliography -- ch. 5 Fretting Fatigue: Modeling and Applications / Trevor Lindley -- 5.1.Introduction -- 5.2.Experimental methods -- 5.2.1.Fatigue specimens and contact pads -- 5.2.2.Fatigue S-N data with and without fretting -- | |
| 505 | 8 | |a 5.2.3.Frictional force measurement -- 5.2.4.Metallography and fractography -- 5.2.5.Mechanisms in fretting fatigue -- 5.3.Fretting fatigue analysis -- 5.3.1.The S-N approach -- 5.3.2.Fretting modeling -- 5.3.3.Two-body contact -- 5.3.4.Fatigue crack initiation -- 5.3.5.Analysis of cracks: the fracture mechanics approach -- 5.3.6.Propagation -- 5.4.Applications under fretting conditions -- 5.4.1.Metallic material: partial slip regime -- 5.4.2.Epoxy polymers: development of cracks under a total slip regime -- 5.5.Palliatives to combat fretting fatigue -- 5.6.Conclusions -- 5.7.Bibliography -- ch. 6 Contact Fatigue / Ky Dang Van -- 6.1.Introduction -- 6.2.Classification of the main types of contact damage -- 6.2.1.Background -- 6.2.2.Damage induced by rolling contacts with or without sliding effect -- 6.2.3.Fretting -- 6.3.A few results on contact mechanics -- 6.3.1.Hertz solution -- 6.3.2.Case of contact with friction under total sliding conditions -- | |
| 505 | 8 | |a 6.3.3.Case of contact with partial sliding -- 6.3.4.Elastic contact between two solids of different elastic modules -- 6.3.5.3D elastic contact -- 6.4.Elastic limit -- 6.5.Elastoplastic contact -- 6.5.1.Stationary methods -- 6.5.2.Direct cyclic method -- 6.6.Application to modeling of a few contact fatigue issues -- 6.6.1.General methodology -- 6.6.2.Initiation of fatigue cracks in rails -- 6.6.3.Propagation of initiated cracks -- 6.6.4.Application to fretting fatigue -- 6.7.Conclusion -- 6.8.Bibliography -- ch. 7 Thermal Fatigue / Luc Remy -- 7.1.Introduction -- 7.2.Characterization tests -- 7.2.1.Cyclic mechanical behavior -- 7.2.2.Damage -- 7.3.Constitutive and damage models at variable temperatures -- 7.3.1.Constitutive laws -- 7.3.2.Damage process modeling based on fatigue conditions -- 7.3.3.Modeling the damage process in complex cases: towards considering interactions with creep and oxidation phenomena -- 7.4.Applications -- 7.4.1.Exhaust manifolds in automotive industry -- | |
| 505 | 8 | |a 7.4.2.Cylinder heads made from aluminum alloys in the automotive industry -- 7.4.3.Brake disks in the rail and automotive industries -- 7.4.4.Nuclear industry pipes -- 7.4.5.Simple structures simulating turbine blades -- 7.5.Conclusion -- 7.6.Bibliography | |
| 650 | 4 | |a Materials |x Fatigue | |
| 650 | 4 | |a Materials |x Mechanical properties | |
| 650 | 4 | |a Microstructure | |
| 700 | 1 | |a Bathias, Claude |e Sonstige |4 oth | |
| 700 | 1 | |a Pineau, A. |e Sonstige |4 oth | |
| 912 | |a ZDB-38-ESG | ||
| 999 | |a oai:aleph.bib-bvb.de:BVB01-030245623 | ||
Datensatz im Suchindex
| _version_ | 1804178366831525888 |
|---|---|
| any_adam_object | |
| building | Verbundindex |
| bvnumber | BV044850764 |
| collection | ZDB-38-ESG |
| contents | Includes bibliographical references and index Machine generated contents note: ch. 1 Multiaxial Fatigue / Marc Bletry and Georges Cailletaud -- 1.1.Introduction -- 1.1.1.Variables in a plane -- 1.1.2.Invariants -- 1.1.3.Classification of the cracking modes -- 1.2.Experimental aspects -- 1.2.1.Multiaxial fatigue experiments -- 1.2.2.Main results -- 1.2.3.Notations -- 1.3.Criteria specific to the unlimited endurance domain -- 1.3.1.Background -- 1.3.2.Global criteria -- 1.3.3.Critical plane criteria -- 1.3.4.Relationship between energetic and mesoscopic criteria -- 1.4.Low cycle fatigue criteria -- 1.4.1.Brown-Miller -- 1.4.2.SWT criteria -- 1.4.3.Jacquelin criterion -- 1.4.4.Additive criteria under sliding and stress amplitude -- 1.4.5.Onera model -- 1.5.Calculating methods of the lifetime under multiaxial conditions -- 1.5.1.Lifetime at N cycles for a periodic loading -- 1.5.2.Damage cumulation -- 1.5.3.Calculation methods -- 1.6.Conclusion -- 1.7.Bibliography -- ch. 2 Cumulative Damage / Jean-Louis Chaboche -- 2.1.Introduction -- 2.2.Nonlinear fatigue cumulative damage -- 2.2.1.Main observations -- 2.2.2.Various types of nonlinear cumulative damage models -- 2.2.3.Possible definitions of the damage variable -- 2.3.A nonlinear cumulative fatigue damage model -- 2.3.1.General form -- 2.3.2.Special forms of functions F and G -- 2.3.3.Application under complex loadings -- 2.4.Damage law of incremental type -- 2.4.1.Damage accumulation in strain or energy -- 2.4.2.Lemaitre's formulation -- 2.4.3.Other incremental models -- 2.5.Cumulative damage under fatigue-creep conditions -- 2.5.1.Rabotnov-Kachanov creep damage law -- 2.5.2.Fatigue damage -- 2.5.3.Creep-fatigue interaction -- 2.5.4.Practical application -- 2.5.5.Fatigue-oxidation-creep interaction -- 2.6.Conclusion -- 2.7.Bibliography -- ch. 3 Damage Tolerance Design / Raphael Cazes -- 3.1.Background -- 3.2.Evolution of the design concept of "fatigue" phenomenon -- 3.2.1.First approach to fatigue resistance -- 3.2.2.The "damage tolerance" concept -- 3.2.3.Consideration of "damage tolerance" -- 3.3.Impact of damage tolerance on design -- 3.3.1."Structural" impact -- 3.3.2."Material" impact -- 3.4.Calculation of a "stress intensity factor" -- 3.4.1.Use of the "handbook" (simple cases) -- 3.4.2.Use of the finite element method: simple and complex cases -- 3.4.3.A simple method to get new configurations -- 3.4.4."Superposition" method -- 3.4.5.Superposition method: applicable examples -- 3.4.6.Numerical application exercise -- 3.5.Performing some "damage tolerance" calculations -- 3.5.1.Complementarity of fatigue and damage tolerance -- 3.5.2.Safety coefficients to understand curve a = f(N) -- 3.5.3.Acquisition of the material parameters -- 3.5.4.Negative parameter: corrosion -- "corrosion fatigue" -- 3.6.Application to the residual strength of thin sheets -- 3.6.1.Planar panels: Feddersen diagram -- 3.6.2.Case of stiffened panels -- 3.7.Propagation of cracks subjected to random loading in the aeronautic industry -- 3.7.1.Modeling of the interactions of loading cycles -- 3.7.2.Comparison of predictions with experimental results -- 3.7.3.Rainflow treatment of random loadings -- 3.8.Conclusion -- 3.8.1.Organization of the evolution of "damage tolerance" -- 3.8.2.Structural maintenance program -- 3.8.3.Inspection of structures being used -- 3.9.Damage tolerance within the gigacyclic domain -- 3.9.1.Observations on crack propagation -- 3.9.2.Propagation of a fish-eye with regards to damage tolerance -- 3.9.3.Example of a turbine disk subjected to vibration -- 3.10.Bibliography -- ch. 4 Defect Influence on the Fatigue Behavior of Metallic Materials / Gilles Baudry -- 4.1.Introduction -- 4.2.Some facts -- 4.2.1.Failure observation -- 4.2.2.Endurance limit level -- 4.2.3.Influence of the rolling reduction ratio and the effect of rolling direction -- 4.2.4.Low cycle fatigue: SN curves -- 4.2.5.Wohler curve: existence of an endurance limit -- 4.2.6.Summary -- 4.3.Approaches -- 4.3.1.First models -- 4.3.2.Kitagawa diagram -- 4.3.3.Murakami model -- 4.4.A few examples -- 4.4.1.Medium-loaded components: example of as-forged parts: connecting rods -- effect of the forging skin -- 4.4.2.High-loaded components: relative importance of cleanliness and surface state -- example of the valve spring -- 4.4.3.High-loaded components: Bearings-Endurance cleanliness relationship -- 4.5.Prospects -- 4.5.1.Estimation of lifetimes and their dispersions -- 4.5.2.Fiber orientation -- 4.5.3.Prestressing -- 4.5.4.Corrosion -- 4.5.5.Complex loadings: spectra/over-loadings/multiaxial loadings -- 4.5.6.Gigacycle fatigue -- 4.6.Conclusion -- 4.7.Bibliography -- ch. 5 Fretting Fatigue: Modeling and Applications / Trevor Lindley -- 5.1.Introduction -- 5.2.Experimental methods -- 5.2.1.Fatigue specimens and contact pads -- 5.2.2.Fatigue S-N data with and without fretting -- 5.2.3.Frictional force measurement -- 5.2.4.Metallography and fractography -- 5.2.5.Mechanisms in fretting fatigue -- 5.3.Fretting fatigue analysis -- 5.3.1.The S-N approach -- 5.3.2.Fretting modeling -- 5.3.3.Two-body contact -- 5.3.4.Fatigue crack initiation -- 5.3.5.Analysis of cracks: the fracture mechanics approach -- 5.3.6.Propagation -- 5.4.Applications under fretting conditions -- 5.4.1.Metallic material: partial slip regime -- 5.4.2.Epoxy polymers: development of cracks under a total slip regime -- 5.5.Palliatives to combat fretting fatigue -- 5.6.Conclusions -- 5.7.Bibliography -- ch. 6 Contact Fatigue / Ky Dang Van -- 6.1.Introduction -- 6.2.Classification of the main types of contact damage -- 6.2.1.Background -- 6.2.2.Damage induced by rolling contacts with or without sliding effect -- 6.2.3.Fretting -- 6.3.A few results on contact mechanics -- 6.3.1.Hertz solution -- 6.3.2.Case of contact with friction under total sliding conditions -- 6.3.3.Case of contact with partial sliding -- 6.3.4.Elastic contact between two solids of different elastic modules -- 6.3.5.3D elastic contact -- 6.4.Elastic limit -- 6.5.Elastoplastic contact -- 6.5.1.Stationary methods -- 6.5.2.Direct cyclic method -- 6.6.Application to modeling of a few contact fatigue issues -- 6.6.1.General methodology -- 6.6.2.Initiation of fatigue cracks in rails -- 6.6.3.Propagation of initiated cracks -- 6.6.4.Application to fretting fatigue -- 6.7.Conclusion -- 6.8.Bibliography -- ch. 7 Thermal Fatigue / Luc Remy -- 7.1.Introduction -- 7.2.Characterization tests -- 7.2.1.Cyclic mechanical behavior -- 7.2.2.Damage -- 7.3.Constitutive and damage models at variable temperatures -- 7.3.1.Constitutive laws -- 7.3.2.Damage process modeling based on fatigue conditions -- 7.3.3.Modeling the damage process in complex cases: towards considering interactions with creep and oxidation phenomena -- 7.4.Applications -- 7.4.1.Exhaust manifolds in automotive industry -- 7.4.2.Cylinder heads made from aluminum alloys in the automotive industry -- 7.4.3.Brake disks in the rail and automotive industries -- 7.4.4.Nuclear industry pipes -- 7.4.5.Simple structures simulating turbine blades -- 7.5.Conclusion -- 7.6.Bibliography |
| ctrlnum | (ZDB-38-ESG)ebr10671489 (OCoLC)842854737 (DE-599)BVBBV044850764 |
| dewey-full | 620.1126 |
| dewey-hundreds | 600 - Technology (Applied sciences) |
| dewey-ones | 620 - Engineering and allied operations |
| dewey-raw | 620.1126 |
| dewey-search | 620.1126 |
| dewey-sort | 3620.1126 |
| dewey-tens | 620 - Engineering and allied operations |
| format | Electronic eBook |
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ind1=" " ind2=" "><subfield code="a">(OCoLC)842854737</subfield></datafield><datafield tag="035" ind1=" " ind2=" "><subfield code="a">(DE-599)BVBBV044850764</subfield></datafield><datafield tag="040" ind1=" " ind2=" "><subfield code="a">DE-604</subfield><subfield code="b">ger</subfield><subfield code="e">aacr</subfield></datafield><datafield tag="041" ind1="0" ind2=" "><subfield code="a">eng</subfield></datafield><datafield tag="082" ind1="0" ind2=" "><subfield code="a">620.1126</subfield><subfield code="2">22</subfield></datafield><datafield tag="245" ind1="1" ind2="0"><subfield code="a">Fatigue of materials and structures</subfield><subfield code="b">application to design and damage</subfield><subfield code="c">edited by Claude Bathias, Andre Pineau</subfield></datafield><datafield tag="264" ind1=" " ind2="1"><subfield code="a">London</subfield><subfield code="b">ISTE</subfield><subfield code="c">2011</subfield></datafield><datafield tag="300" ind1=" " ind2=" "><subfield code="a">xiii, 344 p.</subfield></datafield><datafield tag="336" ind1=" " ind2=" "><subfield code="b">txt</subfield><subfield code="2">rdacontent</subfield></datafield><datafield tag="337" ind1=" " ind2=" "><subfield code="b">c</subfield><subfield code="2">rdamedia</subfield></datafield><datafield tag="338" ind1=" " ind2=" "><subfield code="b">cr</subfield><subfield code="2">rdacarrier</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">Includes bibliographical references and index</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">Machine generated contents note: ch. 1 Multiaxial Fatigue / Marc Bletry and Georges Cailletaud -- 1.1.Introduction -- 1.1.1.Variables in a plane -- 1.1.2.Invariants -- 1.1.3.Classification of the cracking modes -- 1.2.Experimental aspects -- 1.2.1.Multiaxial fatigue experiments -- 1.2.2.Main results -- 1.2.3.Notations -- 1.3.Criteria specific to the unlimited endurance domain -- 1.3.1.Background -- 1.3.2.Global criteria -- 1.3.3.Critical plane criteria -- 1.3.4.Relationship between energetic and mesoscopic criteria -- 1.4.Low cycle fatigue criteria -- 1.4.1.Brown-Miller -- 1.4.2.SWT criteria -- 1.4.3.Jacquelin criterion -- 1.4.4.Additive criteria under sliding and stress amplitude -- 1.4.5.Onera model -- 1.5.Calculating methods of the lifetime under multiaxial conditions -- 1.5.1.Lifetime at N cycles for a periodic loading -- 1.5.2.Damage cumulation -- 1.5.3.Calculation methods -- 1.6.Conclusion -- 1.7.Bibliography -- ch. 2 Cumulative Damage / Jean-Louis Chaboche -- </subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">2.1.Introduction -- 2.2.Nonlinear fatigue cumulative damage -- 2.2.1.Main observations -- 2.2.2.Various types of nonlinear cumulative damage models -- 2.2.3.Possible definitions of the damage variable -- 2.3.A nonlinear cumulative fatigue damage model -- 2.3.1.General form -- 2.3.2.Special forms of functions F and G -- 2.3.3.Application under complex loadings -- 2.4.Damage law of incremental type -- 2.4.1.Damage accumulation in strain or energy -- 2.4.2.Lemaitre's formulation -- 2.4.3.Other incremental models -- 2.5.Cumulative damage under fatigue-creep conditions -- 2.5.1.Rabotnov-Kachanov creep damage law -- 2.5.2.Fatigue damage -- 2.5.3.Creep-fatigue interaction -- 2.5.4.Practical application -- 2.5.5.Fatigue-oxidation-creep interaction -- 2.6.Conclusion -- 2.7.Bibliography -- ch. 3 Damage Tolerance Design / Raphael Cazes -- 3.1.Background -- 3.2.Evolution of the design concept of "fatigue" phenomenon -- 3.2.1.First approach to fatigue resistance -- </subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">3.2.2.The "damage tolerance" concept -- 3.2.3.Consideration of "damage tolerance" -- 3.3.Impact of damage tolerance on design -- 3.3.1."Structural" impact -- 3.3.2."Material" impact -- 3.4.Calculation of a "stress intensity factor" -- 3.4.1.Use of the "handbook" (simple cases) -- 3.4.2.Use of the finite element method: simple and complex cases -- 3.4.3.A simple method to get new configurations -- 3.4.4."Superposition" method -- 3.4.5.Superposition method: applicable examples -- 3.4.6.Numerical application exercise -- 3.5.Performing some "damage tolerance" calculations -- 3.5.1.Complementarity of fatigue and damage tolerance -- 3.5.2.Safety coefficients to understand curve a = f(N) -- 3.5.3.Acquisition of the material parameters -- 3.5.4.Negative parameter: corrosion -- "corrosion fatigue" -- 3.6.Application to the residual strength of thin sheets -- 3.6.1.Planar panels: Feddersen diagram -- 3.6.2.Case of stiffened panels -- </subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">3.7.Propagation of cracks subjected to random loading in the aeronautic industry -- 3.7.1.Modeling of the interactions of loading cycles -- 3.7.2.Comparison of predictions with experimental results -- 3.7.3.Rainflow treatment of random loadings -- 3.8.Conclusion -- 3.8.1.Organization of the evolution of "damage tolerance" -- 3.8.2.Structural maintenance program -- 3.8.3.Inspection of structures being used -- 3.9.Damage tolerance within the gigacyclic domain -- 3.9.1.Observations on crack propagation -- 3.9.2.Propagation of a fish-eye with regards to damage tolerance -- 3.9.3.Example of a turbine disk subjected to vibration -- 3.10.Bibliography -- ch. 4 Defect Influence on the Fatigue Behavior of Metallic Materials / Gilles Baudry -- 4.1.Introduction -- 4.2.Some facts -- 4.2.1.Failure observation -- 4.2.2.Endurance limit level -- 4.2.3.Influence of the rolling reduction ratio and the effect of rolling direction -- 4.2.4.Low cycle fatigue: SN curves -- </subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">4.2.5.Wohler curve: existence of an endurance limit -- 4.2.6.Summary -- 4.3.Approaches -- 4.3.1.First models -- 4.3.2.Kitagawa diagram -- 4.3.3.Murakami model -- 4.4.A few examples -- 4.4.1.Medium-loaded components: example of as-forged parts: connecting rods -- effect of the forging skin -- 4.4.2.High-loaded components: relative importance of cleanliness and surface state -- example of the valve spring -- 4.4.3.High-loaded components: Bearings-Endurance cleanliness relationship -- 4.5.Prospects -- 4.5.1.Estimation of lifetimes and their dispersions -- 4.5.2.Fiber orientation -- 4.5.3.Prestressing -- 4.5.4.Corrosion -- 4.5.5.Complex loadings: spectra/over-loadings/multiaxial loadings -- 4.5.6.Gigacycle fatigue -- 4.6.Conclusion -- 4.7.Bibliography -- ch. 5 Fretting Fatigue: Modeling and Applications / Trevor Lindley -- 5.1.Introduction -- 5.2.Experimental methods -- 5.2.1.Fatigue specimens and contact pads -- 5.2.2.Fatigue S-N data with and without fretting -- </subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">5.2.3.Frictional force measurement -- 5.2.4.Metallography and fractography -- 5.2.5.Mechanisms in fretting fatigue -- 5.3.Fretting fatigue analysis -- 5.3.1.The S-N approach -- 5.3.2.Fretting modeling -- 5.3.3.Two-body contact -- 5.3.4.Fatigue crack initiation -- 5.3.5.Analysis of cracks: the fracture mechanics approach -- 5.3.6.Propagation -- 5.4.Applications under fretting conditions -- 5.4.1.Metallic material: partial slip regime -- 5.4.2.Epoxy polymers: development of cracks under a total slip regime -- 5.5.Palliatives to combat fretting fatigue -- 5.6.Conclusions -- 5.7.Bibliography -- ch. 6 Contact Fatigue / Ky Dang Van -- 6.1.Introduction -- 6.2.Classification of the main types of contact damage -- 6.2.1.Background -- 6.2.2.Damage induced by rolling contacts with or without sliding effect -- 6.2.3.Fretting -- 6.3.A few results on contact mechanics -- 6.3.1.Hertz solution -- 6.3.2.Case of contact with friction under total sliding conditions -- </subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">6.3.3.Case of contact with partial sliding -- 6.3.4.Elastic contact between two solids of different elastic modules -- 6.3.5.3D elastic contact -- 6.4.Elastic limit -- 6.5.Elastoplastic contact -- 6.5.1.Stationary methods -- 6.5.2.Direct cyclic method -- 6.6.Application to modeling of a few contact fatigue issues -- 6.6.1.General methodology -- 6.6.2.Initiation of fatigue cracks in rails -- 6.6.3.Propagation of initiated cracks -- 6.6.4.Application to fretting fatigue -- 6.7.Conclusion -- 6.8.Bibliography -- ch. 7 Thermal Fatigue / Luc Remy -- 7.1.Introduction -- 7.2.Characterization tests -- 7.2.1.Cyclic mechanical behavior -- 7.2.2.Damage -- 7.3.Constitutive and damage models at variable temperatures -- 7.3.1.Constitutive laws -- 7.3.2.Damage process modeling based on fatigue conditions -- 7.3.3.Modeling the damage process in complex cases: towards considering interactions with creep and oxidation phenomena -- 7.4.Applications -- 7.4.1.Exhaust manifolds in automotive industry -- </subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">7.4.2.Cylinder heads made from aluminum alloys in the automotive industry -- 7.4.3.Brake disks in the rail and automotive industries -- 7.4.4.Nuclear industry pipes -- 7.4.5.Simple structures simulating turbine blades -- 7.5.Conclusion -- 7.6.Bibliography</subfield></datafield><datafield tag="650" ind1=" " ind2="4"><subfield code="a">Materials</subfield><subfield code="x">Fatigue</subfield></datafield><datafield tag="650" ind1=" " ind2="4"><subfield code="a">Materials</subfield><subfield code="x">Mechanical properties</subfield></datafield><datafield tag="650" ind1=" " ind2="4"><subfield code="a">Microstructure</subfield></datafield><datafield tag="700" ind1="1" ind2=" "><subfield code="a">Bathias, Claude</subfield><subfield code="e">Sonstige</subfield><subfield code="4">oth</subfield></datafield><datafield tag="700" ind1="1" ind2=" "><subfield code="a">Pineau, A.</subfield><subfield code="e">Sonstige</subfield><subfield code="4">oth</subfield></datafield><datafield tag="912" ind1=" " ind2=" "><subfield code="a">ZDB-38-ESG</subfield></datafield><datafield tag="999" ind1=" " ind2=" "><subfield code="a">oai:aleph.bib-bvb.de:BVB01-030245623</subfield></datafield></record></collection> |
| id | DE-604.BV044850764 |
| illustrated | Not Illustrated |
| indexdate | 2024-07-10T08:02:50Z |
| institution | BVB |
| isbn | 1848212917 9781848212916 9781118616512 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-030245623 |
| oclc_num | 842854737 |
| open_access_boolean | |
| physical | xiii, 344 p. |
| psigel | ZDB-38-ESG |
| publishDate | 2011 |
| publishDateSearch | 2011 |
| publishDateSort | 2011 |
| publisher | ISTE |
| record_format | marc |
| spelling | Fatigue of materials and structures application to design and damage edited by Claude Bathias, Andre Pineau London ISTE 2011 xiii, 344 p. txt rdacontent c rdamedia cr rdacarrier Includes bibliographical references and index Machine generated contents note: ch. 1 Multiaxial Fatigue / Marc Bletry and Georges Cailletaud -- 1.1.Introduction -- 1.1.1.Variables in a plane -- 1.1.2.Invariants -- 1.1.3.Classification of the cracking modes -- 1.2.Experimental aspects -- 1.2.1.Multiaxial fatigue experiments -- 1.2.2.Main results -- 1.2.3.Notations -- 1.3.Criteria specific to the unlimited endurance domain -- 1.3.1.Background -- 1.3.2.Global criteria -- 1.3.3.Critical plane criteria -- 1.3.4.Relationship between energetic and mesoscopic criteria -- 1.4.Low cycle fatigue criteria -- 1.4.1.Brown-Miller -- 1.4.2.SWT criteria -- 1.4.3.Jacquelin criterion -- 1.4.4.Additive criteria under sliding and stress amplitude -- 1.4.5.Onera model -- 1.5.Calculating methods of the lifetime under multiaxial conditions -- 1.5.1.Lifetime at N cycles for a periodic loading -- 1.5.2.Damage cumulation -- 1.5.3.Calculation methods -- 1.6.Conclusion -- 1.7.Bibliography -- ch. 2 Cumulative Damage / Jean-Louis Chaboche -- 2.1.Introduction -- 2.2.Nonlinear fatigue cumulative damage -- 2.2.1.Main observations -- 2.2.2.Various types of nonlinear cumulative damage models -- 2.2.3.Possible definitions of the damage variable -- 2.3.A nonlinear cumulative fatigue damage model -- 2.3.1.General form -- 2.3.2.Special forms of functions F and G -- 2.3.3.Application under complex loadings -- 2.4.Damage law of incremental type -- 2.4.1.Damage accumulation in strain or energy -- 2.4.2.Lemaitre's formulation -- 2.4.3.Other incremental models -- 2.5.Cumulative damage under fatigue-creep conditions -- 2.5.1.Rabotnov-Kachanov creep damage law -- 2.5.2.Fatigue damage -- 2.5.3.Creep-fatigue interaction -- 2.5.4.Practical application -- 2.5.5.Fatigue-oxidation-creep interaction -- 2.6.Conclusion -- 2.7.Bibliography -- ch. 3 Damage Tolerance Design / Raphael Cazes -- 3.1.Background -- 3.2.Evolution of the design concept of "fatigue" phenomenon -- 3.2.1.First approach to fatigue resistance -- 3.2.2.The "damage tolerance" concept -- 3.2.3.Consideration of "damage tolerance" -- 3.3.Impact of damage tolerance on design -- 3.3.1."Structural" impact -- 3.3.2."Material" impact -- 3.4.Calculation of a "stress intensity factor" -- 3.4.1.Use of the "handbook" (simple cases) -- 3.4.2.Use of the finite element method: simple and complex cases -- 3.4.3.A simple method to get new configurations -- 3.4.4."Superposition" method -- 3.4.5.Superposition method: applicable examples -- 3.4.6.Numerical application exercise -- 3.5.Performing some "damage tolerance" calculations -- 3.5.1.Complementarity of fatigue and damage tolerance -- 3.5.2.Safety coefficients to understand curve a = f(N) -- 3.5.3.Acquisition of the material parameters -- 3.5.4.Negative parameter: corrosion -- "corrosion fatigue" -- 3.6.Application to the residual strength of thin sheets -- 3.6.1.Planar panels: Feddersen diagram -- 3.6.2.Case of stiffened panels -- 3.7.Propagation of cracks subjected to random loading in the aeronautic industry -- 3.7.1.Modeling of the interactions of loading cycles -- 3.7.2.Comparison of predictions with experimental results -- 3.7.3.Rainflow treatment of random loadings -- 3.8.Conclusion -- 3.8.1.Organization of the evolution of "damage tolerance" -- 3.8.2.Structural maintenance program -- 3.8.3.Inspection of structures being used -- 3.9.Damage tolerance within the gigacyclic domain -- 3.9.1.Observations on crack propagation -- 3.9.2.Propagation of a fish-eye with regards to damage tolerance -- 3.9.3.Example of a turbine disk subjected to vibration -- 3.10.Bibliography -- ch. 4 Defect Influence on the Fatigue Behavior of Metallic Materials / Gilles Baudry -- 4.1.Introduction -- 4.2.Some facts -- 4.2.1.Failure observation -- 4.2.2.Endurance limit level -- 4.2.3.Influence of the rolling reduction ratio and the effect of rolling direction -- 4.2.4.Low cycle fatigue: SN curves -- 4.2.5.Wohler curve: existence of an endurance limit -- 4.2.6.Summary -- 4.3.Approaches -- 4.3.1.First models -- 4.3.2.Kitagawa diagram -- 4.3.3.Murakami model -- 4.4.A few examples -- 4.4.1.Medium-loaded components: example of as-forged parts: connecting rods -- effect of the forging skin -- 4.4.2.High-loaded components: relative importance of cleanliness and surface state -- example of the valve spring -- 4.4.3.High-loaded components: Bearings-Endurance cleanliness relationship -- 4.5.Prospects -- 4.5.1.Estimation of lifetimes and their dispersions -- 4.5.2.Fiber orientation -- 4.5.3.Prestressing -- 4.5.4.Corrosion -- 4.5.5.Complex loadings: spectra/over-loadings/multiaxial loadings -- 4.5.6.Gigacycle fatigue -- 4.6.Conclusion -- 4.7.Bibliography -- ch. 5 Fretting Fatigue: Modeling and Applications / Trevor Lindley -- 5.1.Introduction -- 5.2.Experimental methods -- 5.2.1.Fatigue specimens and contact pads -- 5.2.2.Fatigue S-N data with and without fretting -- 5.2.3.Frictional force measurement -- 5.2.4.Metallography and fractography -- 5.2.5.Mechanisms in fretting fatigue -- 5.3.Fretting fatigue analysis -- 5.3.1.The S-N approach -- 5.3.2.Fretting modeling -- 5.3.3.Two-body contact -- 5.3.4.Fatigue crack initiation -- 5.3.5.Analysis of cracks: the fracture mechanics approach -- 5.3.6.Propagation -- 5.4.Applications under fretting conditions -- 5.4.1.Metallic material: partial slip regime -- 5.4.2.Epoxy polymers: development of cracks under a total slip regime -- 5.5.Palliatives to combat fretting fatigue -- 5.6.Conclusions -- 5.7.Bibliography -- ch. 6 Contact Fatigue / Ky Dang Van -- 6.1.Introduction -- 6.2.Classification of the main types of contact damage -- 6.2.1.Background -- 6.2.2.Damage induced by rolling contacts with or without sliding effect -- 6.2.3.Fretting -- 6.3.A few results on contact mechanics -- 6.3.1.Hertz solution -- 6.3.2.Case of contact with friction under total sliding conditions -- 6.3.3.Case of contact with partial sliding -- 6.3.4.Elastic contact between two solids of different elastic modules -- 6.3.5.3D elastic contact -- 6.4.Elastic limit -- 6.5.Elastoplastic contact -- 6.5.1.Stationary methods -- 6.5.2.Direct cyclic method -- 6.6.Application to modeling of a few contact fatigue issues -- 6.6.1.General methodology -- 6.6.2.Initiation of fatigue cracks in rails -- 6.6.3.Propagation of initiated cracks -- 6.6.4.Application to fretting fatigue -- 6.7.Conclusion -- 6.8.Bibliography -- ch. 7 Thermal Fatigue / Luc Remy -- 7.1.Introduction -- 7.2.Characterization tests -- 7.2.1.Cyclic mechanical behavior -- 7.2.2.Damage -- 7.3.Constitutive and damage models at variable temperatures -- 7.3.1.Constitutive laws -- 7.3.2.Damage process modeling based on fatigue conditions -- 7.3.3.Modeling the damage process in complex cases: towards considering interactions with creep and oxidation phenomena -- 7.4.Applications -- 7.4.1.Exhaust manifolds in automotive industry -- 7.4.2.Cylinder heads made from aluminum alloys in the automotive industry -- 7.4.3.Brake disks in the rail and automotive industries -- 7.4.4.Nuclear industry pipes -- 7.4.5.Simple structures simulating turbine blades -- 7.5.Conclusion -- 7.6.Bibliography Materials Fatigue Materials Mechanical properties Microstructure Bathias, Claude Sonstige oth Pineau, A. Sonstige oth |
| spellingShingle | Fatigue of materials and structures application to design and damage Includes bibliographical references and index Machine generated contents note: ch. 1 Multiaxial Fatigue / Marc Bletry and Georges Cailletaud -- 1.1.Introduction -- 1.1.1.Variables in a plane -- 1.1.2.Invariants -- 1.1.3.Classification of the cracking modes -- 1.2.Experimental aspects -- 1.2.1.Multiaxial fatigue experiments -- 1.2.2.Main results -- 1.2.3.Notations -- 1.3.Criteria specific to the unlimited endurance domain -- 1.3.1.Background -- 1.3.2.Global criteria -- 1.3.3.Critical plane criteria -- 1.3.4.Relationship between energetic and mesoscopic criteria -- 1.4.Low cycle fatigue criteria -- 1.4.1.Brown-Miller -- 1.4.2.SWT criteria -- 1.4.3.Jacquelin criterion -- 1.4.4.Additive criteria under sliding and stress amplitude -- 1.4.5.Onera model -- 1.5.Calculating methods of the lifetime under multiaxial conditions -- 1.5.1.Lifetime at N cycles for a periodic loading -- 1.5.2.Damage cumulation -- 1.5.3.Calculation methods -- 1.6.Conclusion -- 1.7.Bibliography -- ch. 2 Cumulative Damage / Jean-Louis Chaboche -- 2.1.Introduction -- 2.2.Nonlinear fatigue cumulative damage -- 2.2.1.Main observations -- 2.2.2.Various types of nonlinear cumulative damage models -- 2.2.3.Possible definitions of the damage variable -- 2.3.A nonlinear cumulative fatigue damage model -- 2.3.1.General form -- 2.3.2.Special forms of functions F and G -- 2.3.3.Application under complex loadings -- 2.4.Damage law of incremental type -- 2.4.1.Damage accumulation in strain or energy -- 2.4.2.Lemaitre's formulation -- 2.4.3.Other incremental models -- 2.5.Cumulative damage under fatigue-creep conditions -- 2.5.1.Rabotnov-Kachanov creep damage law -- 2.5.2.Fatigue damage -- 2.5.3.Creep-fatigue interaction -- 2.5.4.Practical application -- 2.5.5.Fatigue-oxidation-creep interaction -- 2.6.Conclusion -- 2.7.Bibliography -- ch. 3 Damage Tolerance Design / Raphael Cazes -- 3.1.Background -- 3.2.Evolution of the design concept of "fatigue" phenomenon -- 3.2.1.First approach to fatigue resistance -- 3.2.2.The "damage tolerance" concept -- 3.2.3.Consideration of "damage tolerance" -- 3.3.Impact of damage tolerance on design -- 3.3.1."Structural" impact -- 3.3.2."Material" impact -- 3.4.Calculation of a "stress intensity factor" -- 3.4.1.Use of the "handbook" (simple cases) -- 3.4.2.Use of the finite element method: simple and complex cases -- 3.4.3.A simple method to get new configurations -- 3.4.4."Superposition" method -- 3.4.5.Superposition method: applicable examples -- 3.4.6.Numerical application exercise -- 3.5.Performing some "damage tolerance" calculations -- 3.5.1.Complementarity of fatigue and damage tolerance -- 3.5.2.Safety coefficients to understand curve a = f(N) -- 3.5.3.Acquisition of the material parameters -- 3.5.4.Negative parameter: corrosion -- "corrosion fatigue" -- 3.6.Application to the residual strength of thin sheets -- 3.6.1.Planar panels: Feddersen diagram -- 3.6.2.Case of stiffened panels -- 3.7.Propagation of cracks subjected to random loading in the aeronautic industry -- 3.7.1.Modeling of the interactions of loading cycles -- 3.7.2.Comparison of predictions with experimental results -- 3.7.3.Rainflow treatment of random loadings -- 3.8.Conclusion -- 3.8.1.Organization of the evolution of "damage tolerance" -- 3.8.2.Structural maintenance program -- 3.8.3.Inspection of structures being used -- 3.9.Damage tolerance within the gigacyclic domain -- 3.9.1.Observations on crack propagation -- 3.9.2.Propagation of a fish-eye with regards to damage tolerance -- 3.9.3.Example of a turbine disk subjected to vibration -- 3.10.Bibliography -- ch. 4 Defect Influence on the Fatigue Behavior of Metallic Materials / Gilles Baudry -- 4.1.Introduction -- 4.2.Some facts -- 4.2.1.Failure observation -- 4.2.2.Endurance limit level -- 4.2.3.Influence of the rolling reduction ratio and the effect of rolling direction -- 4.2.4.Low cycle fatigue: SN curves -- 4.2.5.Wohler curve: existence of an endurance limit -- 4.2.6.Summary -- 4.3.Approaches -- 4.3.1.First models -- 4.3.2.Kitagawa diagram -- 4.3.3.Murakami model -- 4.4.A few examples -- 4.4.1.Medium-loaded components: example of as-forged parts: connecting rods -- effect of the forging skin -- 4.4.2.High-loaded components: relative importance of cleanliness and surface state -- example of the valve spring -- 4.4.3.High-loaded components: Bearings-Endurance cleanliness relationship -- 4.5.Prospects -- 4.5.1.Estimation of lifetimes and their dispersions -- 4.5.2.Fiber orientation -- 4.5.3.Prestressing -- 4.5.4.Corrosion -- 4.5.5.Complex loadings: spectra/over-loadings/multiaxial loadings -- 4.5.6.Gigacycle fatigue -- 4.6.Conclusion -- 4.7.Bibliography -- ch. 5 Fretting Fatigue: Modeling and Applications / Trevor Lindley -- 5.1.Introduction -- 5.2.Experimental methods -- 5.2.1.Fatigue specimens and contact pads -- 5.2.2.Fatigue S-N data with and without fretting -- 5.2.3.Frictional force measurement -- 5.2.4.Metallography and fractography -- 5.2.5.Mechanisms in fretting fatigue -- 5.3.Fretting fatigue analysis -- 5.3.1.The S-N approach -- 5.3.2.Fretting modeling -- 5.3.3.Two-body contact -- 5.3.4.Fatigue crack initiation -- 5.3.5.Analysis of cracks: the fracture mechanics approach -- 5.3.6.Propagation -- 5.4.Applications under fretting conditions -- 5.4.1.Metallic material: partial slip regime -- 5.4.2.Epoxy polymers: development of cracks under a total slip regime -- 5.5.Palliatives to combat fretting fatigue -- 5.6.Conclusions -- 5.7.Bibliography -- ch. 6 Contact Fatigue / Ky Dang Van -- 6.1.Introduction -- 6.2.Classification of the main types of contact damage -- 6.2.1.Background -- 6.2.2.Damage induced by rolling contacts with or without sliding effect -- 6.2.3.Fretting -- 6.3.A few results on contact mechanics -- 6.3.1.Hertz solution -- 6.3.2.Case of contact with friction under total sliding conditions -- 6.3.3.Case of contact with partial sliding -- 6.3.4.Elastic contact between two solids of different elastic modules -- 6.3.5.3D elastic contact -- 6.4.Elastic limit -- 6.5.Elastoplastic contact -- 6.5.1.Stationary methods -- 6.5.2.Direct cyclic method -- 6.6.Application to modeling of a few contact fatigue issues -- 6.6.1.General methodology -- 6.6.2.Initiation of fatigue cracks in rails -- 6.6.3.Propagation of initiated cracks -- 6.6.4.Application to fretting fatigue -- 6.7.Conclusion -- 6.8.Bibliography -- ch. 7 Thermal Fatigue / Luc Remy -- 7.1.Introduction -- 7.2.Characterization tests -- 7.2.1.Cyclic mechanical behavior -- 7.2.2.Damage -- 7.3.Constitutive and damage models at variable temperatures -- 7.3.1.Constitutive laws -- 7.3.2.Damage process modeling based on fatigue conditions -- 7.3.3.Modeling the damage process in complex cases: towards considering interactions with creep and oxidation phenomena -- 7.4.Applications -- 7.4.1.Exhaust manifolds in automotive industry -- 7.4.2.Cylinder heads made from aluminum alloys in the automotive industry -- 7.4.3.Brake disks in the rail and automotive industries -- 7.4.4.Nuclear industry pipes -- 7.4.5.Simple structures simulating turbine blades -- 7.5.Conclusion -- 7.6.Bibliography Materials Fatigue Materials Mechanical properties Microstructure |
| title | Fatigue of materials and structures application to design and damage |
| title_auth | Fatigue of materials and structures application to design and damage |
| title_exact_search | Fatigue of materials and structures application to design and damage |
| title_full | Fatigue of materials and structures application to design and damage edited by Claude Bathias, Andre Pineau |
| title_fullStr | Fatigue of materials and structures application to design and damage edited by Claude Bathias, Andre Pineau |
| title_full_unstemmed | Fatigue of materials and structures application to design and damage edited by Claude Bathias, Andre Pineau |
| title_short | Fatigue of materials and structures |
| title_sort | fatigue of materials and structures application to design and damage |
| title_sub | application to design and damage |
| topic | Materials Fatigue Materials Mechanical properties Microstructure |
| topic_facet | Materials Fatigue Materials Mechanical properties Microstructure |
| work_keys_str_mv | AT bathiasclaude fatigueofmaterialsandstructuresapplicationtodesignanddamage AT pineaua fatigueofmaterialsandstructuresapplicationtodesignanddamage |