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Produktbild: A Unified Statistical Methodology for Modeling Fatigue Damage

A Unified Statistical Methodology for Modeling Fatigue Damage

93,99 €

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Beschreibung

Produktdetails

Einband

Taschenbuch

Erscheinungsdatum

19.10.2010

Verlag

Springer Netherland

Seitenzahl

232

Maße (L/B/H)

23,5/15,5/1,4 cm

Gewicht

382 g

Auflage

1. Auflage

Sprache

Englisch

ISBN

978-90-481-8086-8

Beschreibung

Rezension

From the reviews:


"This book provides a unified methodology to derive models for fatigue life. … The book gives a new methodology to build-up fatigue models based on a practical knowledge of fatigue problems, combined with common sense, functional equations and statistical methods. … Appendix presents a short description of classical and more recent fatigue models existing in the literature. The proposed models allow simple approaches to be implemented in a practical fatigue design, similar to those employed in current engineering standards." (Razvan Raducanu, Zentralblatt MATH, Vol. 1161, 2009)

Produktdetails

Einband

Taschenbuch

Erscheinungsdatum

19.10.2010

Verlag

Springer Netherland

Seitenzahl

232

Maße (L/B/H)

23,5/15,5/1,4 cm

Gewicht

382 g

Auflage

1. Auflage

Sprache

Englisch

ISBN

978-90-481-8086-8

Herstelleradresse

Springer-Verlag KG
Sachsenplatz 4-6
1201 Wien
AT

Email: ProductSafety@springernature.com

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  • Produktbild: A Unified Statistical Methodology for Modeling Fatigue Damage
  • Introduction and Motivation of the Fatigue Problem An Integrated Overview of Fatigue 1.1 Introduction 1.2 Models with dimensionless variables 1.3 S-N or Wohler curves 1.3.1 Compatibility condition of NlAo and AalN 1.3.2 Statistical considerations 1.4 E-N curves 1.5 Stress-level effect 1.5.1 Compatibility condition of S-N curves for constant o;T, and S-N curves for constant a& 1.6 Crack-growth curves 1.6.1 Crack-growth curves for a constant stress pair T 1.6.2 Crack-growth curves for a varying stress pair T 1.6.3 Compatibility of crack-growth and S-N models 1.7 Crack-growth rate curves 1.8 Size effect 1.9 Normalization 1.9.1 Percentilebased normalizations 1.9.2 Stress range and lifetimebased normalizations 1.9.3 Extended percentile normalization 1.10 Damage measures and damage accumulation 11 Models Used in the Stress-Based Approach 2 S-N or Wohler Field Models 2.1 Introduction 2.2 Dimensional analysis 2.3 Extreme models in fatigue 2.3.1 The Weibull model 2.3.2 The minimal Gumbel model 2.4 Model for constant stress-level and range 2.4.1 Derivation of the model 2.4.2 Parmeter estimation 2.4.3 Alternative methods for dealing with run-outs 2.5 Model for a given stress-level and varying range 2.5.1 Derivation of the model 2.5.2 Some weaknesses of the proposed model 2.5.3 Parameter estimation 2.5.4 Use of the model in practice 2.5.5 Examples of application 2.6 Model for varying stress-level and range 2.7 Dimensional Weibull and Gumbel models 2.8 Properties of the model 2.8.1 Parameter estimation 2.8.2 Use of the model in practice 2.8.3 Example of applications 2.9 Concluding remarks 2.10 Appendix A: Derivation of the general model 2.11 Appendix B: S-N curves for the general model 3 Length Effect 3.1 Introduction 3.2 Modeling the S-N field for different lengths 3.2.1 A previous example 3.2.2 General model for different lengths 3.2.3 Parameter estimation 3.3 Examples of applications 3.3.1 Prestressing wires 3.3.2 Prestressing strands I11 Models Used in the Strain-Based Approach 4 Log-Weibull e-N Model 4.1 Introduction 4.2 Model for a constant strain level and range 4.2.1 Practical example 4.3 Model for a varying strain level and range 4.4 Converting strain into stress-life curves 4.4.1 Practical example 4.5 Concluding remarks IV Models Used in the Fracture-Mechanics Approach 5 Crack-Growth Models 5.1 Introduction and motivation 5.2 Building crack growth models 5.3 Crack-growth curves approach I 5.3.1 Crack-growth curves for constant Aa and a 5.3.2 Crack-growth curves for varying AD and a 5.3.3 Compatibility of crack-growth and S-N models 5.4 crack-growth curves approach I1 5.4.1 crack-growth curves for constant Aa and a; 5.4.2 crack-growth curves for varying Aa and a 5.4.3 Statistical distributions of aI N and Nla 5.4.4 Learning and estimating the mode1 5.4.5 Compatibility of approaches I and I1 5.5 Example of application 5.6 Summary and future work V Damage and Damage Accumulation Models 6 Damage Measures 6.1 Introduction 6.2 Normalization 6.3 Damage measures 6.3.1 Some requirements for a damage measure 6.3.2 Some damage measures 6.4 Concluding remarks 7 Damage-Accumulation 7.1 Damage-accumulation 7.1.1 Accumulated damage after a constant