Verfügbarkeit: Fatigue life analyses of welded structures

Fatigue life analyses of welded structures: [FLAWS]

Gespeichert in:

Bibliographische Detailangaben
1. Verfasser:	Lassen, Tom (VerfasserIn)
Format:	Buch
Sprache:	English
Veröffentlicht:	London [u.a.] ISTE 2006
Ausgabe:	1. publ.
Schlagworte:	Welded joints > Fatigue Welded steel structures Schweißverbindung Statistik Materialermüdung
Online-Zugang:	Contributor biographical information Publisher description Table of contents only Inhaltsverzeichnis
Beschreibung:	XVI, 407 S., [4] Bl. Ill., graph. Darst.
ISBN:	9781905209545 1905209541

Internformat

MARC


LEADER	00000nam a2200000zc 4500
001	BV022407058
003	DE-604
005	20190508
007	t
008	070430s2006 xxuad\|\| \|\|\|\| 00\|\|\| eng d
010			\|a 2006020963
020			\|a 9781905209545 \|9 978-1-905209-54-5
020			\|a 1905209541 \|9 1-905209-54-1
035			\|a (OCoLC)70219886
035			\|a (DE-599)BVBBV022407058
040			\|a DE-604 \|b ger \|e aacr
041	0		\|a eng
044			\|a xxu \|c US
049			\|a DE-91G \|a DE-634 \|a DE-M347
050		0	\|a TA492.W4
082	0		\|a 671.5/2042
084			\|a UQ 7400 \|0 (DE-625)146577: \|2 rvk
084			\|a ZM 8420 \|0 (DE-625)159845: \|2 rvk
084			\|a FER 525f \|2 stub
100	1		\|a Lassen, Tom \|e Verfasser \|4 aut
245	1	0	\|a Fatigue life analyses of welded structures \|b [FLAWS] \|c Tom Lassen ; Naman Récho
250			\|a 1. publ.
264		1	\|a London [u.a.] \|b ISTE \|c 2006
300			\|a XVI, 407 S., [4] Bl. \|b Ill., graph. Darst.
336			\|b txt \|2 rdacontent
337			\|b n \|2 rdamedia
338			\|b nc \|2 rdacarrier
650		4	\|a Welded joints \|x Fatigue
650		4	\|a Welded steel structures
650	0	7	\|a Schweißverbindung \|0 (DE-588)4053878-3 \|2 gnd \|9 rswk-swf
650	0	7	\|a Statistik \|0 (DE-588)4056995-0 \|2 gnd \|9 rswk-swf
650	0	7	\|a Materialermüdung \|0 (DE-588)4074631-8 \|2 gnd \|9 rswk-swf
689	0	0	\|a Schweißverbindung \|0 (DE-588)4053878-3 \|D s
689	0	1	\|a Materialermüdung \|0 (DE-588)4074631-8 \|D s
689	0	2	\|a Statistik \|0 (DE-588)4056995-0 \|D s
689	0		\|5 DE-604
700	1		\|a Recho, Naman \|e Sonstige \|4 oth
856	4		\|u http://www.loc.gov/catdir/enhancements/fy0668/2006020963-b.html \|3 Contributor biographical information
856	4		\|u http://www.loc.gov/catdir/enhancements/fy0668/2006020963-d.html \|3 Publisher description
856	4		\|u http://www.loc.gov/catdir/toc/ecip0616/2006020963.html \|3 Table of contents only
856	4	2	\|m HBZ Datenaustausch \|q application/pdf \|u http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=015615610&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA \|3 Inhaltsverzeichnis
999			\|a oai:aleph.bib-bvb.de:BVB01-015615610

Datensatz im Suchindex

_version_	1804136470808625152
adam_text	Table of Contents Abbreviations xv PART I. Common Practice 1 Chapter 1. Introduction 3 1.1. The importance of welded joints and their fatigue behavior 3 1.2. Objectives and scope of the book 4 1.3. The content of the various chapters 5 1.4. Other literature in the field 7 1.5. Why should the practicing engineer apply reliability methods? 8 1.6. How to work with this book 9 1.7. About the authors 10 Chapter 2. Basic Characterization of the Fatigue Behavior of Welded Joints 11 2.1. Introduction and objectives 11 2.2. Fatigue failures 11 2.3. Basic mechanisms of metal fatigue 15 2.4. Parameters that are important to the fatigue damage process 17 2.4.1. External loading and stresses in an item 17 2.4.2. Geometry, stress and strain concentrations 19 2.4.3. Material parameters 20 2.4.4. Residual stresses 24 2.4.5. Fabrication quality and surface finish 25 2.4.6. Influence of the environment 25 2.5. Important topics for welded joints 26 2.5.1. General overview 26 viii Fatigue Life Analysis of Welded Structures 2.6. Various types of joints 30 2.6.1. Plated joints 30 2.6.2. Tubular joints 34 2.7. References 35 Chapter 3. Experimental Methods and Data Analysis 37 3.1. Introduction and objectives 37 3.2. Overview of various types of tests 38 3.3. Stress-life testing (S-N testing) of welded joints 38 3.3.1. Test specimens and test setup 38 3.3.2. Preparations and measurements 41 3.3.3. Test results 46 3.4. Testing to determine the parameters in the strain-life equation 49 3.5. Crack growth tests - guidelines for test setup and specimen monitoring 50 3.6. Elementary statistical methods 55 3.6.1. Linear regression analyses 55 3.7. References 60 Chapter 4. Definition and Description of Fatigue Loading 61 4.1. Introduction and objectives 61 4.2. Constant amplitude loading 62 4.3. Variable amplitude loading 63 4.3.1. Overview 63 4.3.2. Rain-flow cycle counting of time series 64 4.3.3. The energy spectrum approach 69 4.4. References 73 Chapter 5. The S-N Approach 75 5.1. Introduction and objectives 75 5.2. Method, assumptions and important factors 76 5.2.1. Statistics for the S-N approach, median and percentile curves . . 76 5.2.2. Discussion of S-N curves-important factors 78 5.2.2.1. The threshold phenomenon 78 5.2.2.2. Mean stress and loading ratio 79 5.2.2.3. Stress relieving 79 5.2.2.4. The thickness effect 80 5.2.2.5. Misalignment 81 5.2.2.6. Post-weld improvement techniques 82 5.2.2.7. Corrosive environment 83 5.3. Mathematics for damage calculations 84 5.3.1. Linear damage accumulation; load spectrum on a histogram format 84 Table of Contents ix 5.3.2. Discussion of the validity of the linear damage accumulation. . . 86 5.3.3. Definition of the equivalent stress range 88 5.3.4. Load spectrum on the format of a Weibull distribution 88 5.4. S-N curves related to various stress definitions 91 5.4.1. Nominal stress, geometrical stress and weld notch stresses .... 92 5.4.2. Geometrical stresses in tubular joints 96 5.4.3. Fatigue life estimate based on the weld notch stress approach . . 98 5.4.4. Conclusions on the various stress approaches 101 5.5. Some comments on finite element analysis 104 5.6. Current rule and regulations 110 5.6.1. General considerations 110 5.6.2. The original fatigue classes and S-N curves from DoE 112 5.6.3. S-N life predictions according to Eurocode 3-Air environment 117 5.6.4. S-N life predictions according to HSE 119 5.6.5. S-N life predictions according to NORSOK and DNV 120 5.6.6. S-N life predictions for ship structures 122 5.7. The industrial case: an offshore loading buoy 130 5.8. References 136 Chapter 6. Applied Fracture Mechanics 139 6.1. Introduction 139 6.2. Objectives of this chapter 142 6.3. Basic concepts of linear elastic fracture mechanics 142 6.3.1. The local stress field ahead of the crack front 142 6.4. Fracture criterion due to extreme load 152 6.4.1. Mixed mode rupture 153 6.4.2. The R6 criterion and critical crack size 154 6.5. Fatigue threshold and fatigue crack growth 156 6.5.1. Crack growth models 156 6.5.2. Parameters C andm 159 6.5.3. Residual stresses 160 6.5.4. Some notes on the size of the initial cracks 161 6.6. Geometry function and growth parameters given in BS7910 161 6.6.1. The geometry function 162 6.6.2. Parameters C and m 163 6.7. Fracture mechanics model for a fillet welded plate joint 165 6.7.1. Basic assumptions and criteria for the model 165 6.7.2. Data for crack growth measurements (database 1) 166 6.7.3. Data for fatigue lives at low stress levels (database 2) 167 6.7.4. Procedure and curve fitting 167 6.7.5. Growth parameters C and m 169 6.7.6. The initial crack depth ao 172 x Fatigue Life Analysis ofWelded Structures 6.7.7. Prediction of crack growth histories and construction of S-N curves 173 6.7.8. Conclusions for fillet joints with cracks at the weld toe 175 6.8. Fatigue crack growth in tubular joints 176 6.8.1. Discussion of current models 179 6.8.2. Conclusion on the empirical fracture mechanics model 183 6.8.3. Proposal for model improvements 183 6.9. A brief overview of stiffened panels 184 6.10. Units and conversion for fracture mechanics parameters 186 6.11. Industrial case: fatigue re-assessment of a welded pipe 186 6.11.1. Introduction 186 6.11.2. Description of the loading buoy with steel pipe 187 6.11.3. Replacement and inspection strategy 189 6.11.4. Re-assessment based on the S-N approach 190 6.11.5. Re-assessment based on fracture mechanics 191 6.12. References 193 PART II. Stochastic Modeling 197 Chapter 7. Stochastic Modeling 199 7.1. Introduction and objectives 199 7.2. Overview of models and methodology 200 7.2.1. Sources of uncertainty 200 7.2.2. Introduction to the random variable model and related methods . 201 7.2.3. Requirements for a stochastic model 203 7.2.4. The concept of the limit state function and the safety margin. . . 204 7.2.5. The first and second order reliability methods (FORM/SORM) . 206 7.3. Elementary reliability models 207 7.3.1. General considerations 207 7.3.2. The Lognormal distribution 208 7.3.3. The Weibull distribution 209 7.4. The random variable model using simulation methods 212 7.4.1. General considerations 212 7.4.2. The realization of a random variable by the Monte Carlo method 213 7.5. Random variable models based on the S-N approach 215 7.5.1. The lognormal format for the S-N fatigue life 215 7.5.1.1. Example: full-penetration butt joint in an offshore structure 217 7.5.2. Monte Carlo Simulation of the S-N fatigue life 219 7.6. Random variable models based on fracture mechanics 220 7.6.1. General considerations 220 7.6.2. Taking account for future inspections and inspection results ... 221 7.6.3. Characterization of the performance of the non-destructive inspection technique 223 Table of Contents xi 7.6.4. Simulation with account for future planned inspections 225 7.6.4.1. A first approximation to the inspection problem 225 7.6.4.2. Full stochastic simulation 226 7.6.5. Simulation of planned inspections for a fillet welded joint 229 7.6.6. Updating based on inspections results 231 7.7. The Markov chain model 235 7.7.1. Basic concepts. 235 7.7.2. Simple illustration on how the model works 235 7.7.3. Elaboration of the model 242 7.7.4. Influence of scheduled inspection and repair 244 7.7.5. Parameter estimation 246 7.7.6. Hybrid model to account for additional scatter 248 7.7.7. Analysis of a fillet welded joint 249 7.7.7.1. Short review and elaboration of database 1 250 7.7.7.2. Determination of parameters in the Markov model 251 7.7.7.3. Reliability results and discussion 253 7.8. A damage tolerance supplement to rules and regulation 255 7.8.1. Introduction . 255 7.8.2. An industrial case study: single anchor loading system 260 7.8.2.1. Example 1: butt weld in upper pipeline 262 7.8.2.2. Example 2: welded brackets on the main plates 263 7.8.3. Conclusions for the damage tolerance supplement 263 7.9. Risk assessments and cost benefit analysis 264 7.10. Reliability and risk assessment for the riser steel pipe 267 7.11. References 268 PART III. Recent Advances 271 Chapter 8. Proposal for a New Type of S-N Curve 273 8.1. Introduction and objectives 273 8.2. General considerations for the conventional S-N approach 275 8.2.1. Basic assumptions 275 8.2.2. The S-N approach based on BS5400 and Eurocode 3 275 8.3. S-N curves based on a random fatigue limit model 277 8.4. Experimental data for model calibration 278 8.4.1. Data for fatigue life at high stress levels (database 1) 278 8.4.2. Data for fatigue lives at low stress levels (database 2) 279 8.5. Comparison between the F-class curve, the RFLM-based curve and the data 279 8.6. Conclusions. 284 8.7. References 284 xii Fatigue Life Analysis of Welded Structures Chapter 9. Physical Modeling of the Entire Fatigue Process 287 9.1. Introduction and objectives 287 9.2. Modeling the fatigue crack initiation period 289 9.2.1. Basic concept and equations for the local stress-strain approach 289 9.2.2. Definition of the initiation phase and determination of parameters 292 9.2.3. Local toe geometry and stress concentration factor 292 9.2.4. Transition depth 294 9.2.5. Cyclic mechanical properties and parameters in Coffin-Manson equation 295 9.3. Constructing the S-N curve from the two-phase model 297 9.4. Damage accumulation using the TPM 301 9.5. The practical consequences of the TPM 302 9.5.1. General considerations 302 9.5.2. Life predictions and dimensions 302 9.5.3. Predicted crack evolution and inspection planning 303 9.6. Conclusions 306 9.7. Suggestions for future work 307 9.8. References 308 Chapter 10. A Notch Stress Field Approach to the Prediction of Fatigue Life 309 10.1. A modified S-N approach 309 10.1.1. General considerations 309 10.1.2. The basic theory for the notch stress intensity factor 311 10.1.3. S-N data analysis for fillet welded joints 313 10.2. A modified crack growth approach 315 10.3. References 317 Chapter 11. Multi-Axial Fatigue of Welded Joints 319 11.1. Introduction and objectives 319 11.2. Overview of theory and crack-extension criteria 321 11.3. The crack box technique 322 11.3.1. General considerations for finite element analysis and element mesh 322 11.3.2. Methodology 322 11.3.3. Examples 324 11.4. Tentative mixed-mode model to crack propagation in welded joints . 325 11.4.1. Modeling the effect of the loading mode on the crack growth rate 327 11.4.2. Modeling the effect of the residual stress due to the weld on the crack growth rate 328 Table of Contents xiii 11.4.3. Measured effect of the loading angle on the crack growth rate . 329 11.4.4. Measured effect of weld on the crack growth rate 331 11.4.5. Measured crack extension angle under mixed mode loading. . . 332 11.5. Validation of the model 333 11.5.1. Verification of the models for non-welded steel specimens under mixed-mode loading 334 11.5.2. Verification of the models for non-welded and welded steel specimens under mode I loading 336 11.5.3. Verification of the models for welded steel specimens under mixed-mode loading 337 11.5.4. Verification of the effect of the welded residual stress on the fatigue life 338 11.5.5. Discussion and conclusions 339 11.6. Extension to full test 340 11.6.1. Modeling methodology 341 11.6.2. Global calculation scheme 341 11.6.3. The crack box technique 343 11.6.4. Crack-propagation rate 344 11.6.5. Description of experiments carried out 345 11.6.6. Results 345 11.6.7. Weld toe geometry 346 11.6.8. Numerical calculations 347 11.6.8.1. Crack initiation 347 11.6.8.2. Crack growth 349 11.7. References 351 Chapter 12. The Effect of Overloads on the Fatigue Life 355 12.1. Introduction and objectives 355 12.2. Residual stress opening approach at the crack tip following an overload during fatigue 359 12.3. Numerical modeling 362 12.3.1. Modeling aspects 362 12.3.2. Finite element modeling choices 363 12.4. Proposed deterministic approach to fatigue crack growth following an overload 366 12.5. Reliability modeling including the effect of an overload 370 12.6. Application of the reliability model to a fillet welded joint 371 12.7. References 375 Appendix A. Short Overview of the Foundations of Fracture Mechanics . 381 Al. Introduction 381 A2. Elementary failure modes and stress situations 383 A3. Foundations of fracture mechanics 383 A4. Parameters characterizing the singular zone 385 xiv Fatigue Life Analysis of Welded Structures A4.1. The stress intensity factor (SIF), K 385 A4.2. The energy release rate, G 387 A4.3. The J-integral 388 A4.4. The crack-opening displacement (COD) 389 A5. Asymptotic stress field in elastic-plastic media 390 A5. References 391 Appendix B. Spreadsheet for Fatigue Life Estimates 393 Appendix C. CG - Crack Growth Based on Fracture Mechanics 395 Appendix D. CI - Crack Initiation Based on Coffin-Manson 399 Index 403
adam_txt	Table of Contents Abbreviations xv PART I. Common Practice 1 Chapter 1. Introduction 3 1.1. The importance of welded joints and their fatigue behavior 3 1.2. Objectives and scope of the book 4 1.3. The content of the various chapters 5 1.4. Other literature in the field 7 1.5. Why should the practicing engineer apply reliability methods? 8 1.6. How to work with this book 9 1.7. About the authors 10 Chapter 2. Basic Characterization of the Fatigue Behavior of Welded Joints 11 2.1. Introduction and objectives 11 2.2. Fatigue failures 11 2.3. Basic mechanisms of metal fatigue 15 2.4. Parameters that are important to the fatigue damage process 17 2.4.1. External loading and stresses in an item 17 2.4.2. Geometry, stress and strain concentrations 19 2.4.3. Material parameters 20 2.4.4. Residual stresses 24 2.4.5. Fabrication quality and surface finish 25 2.4.6. Influence of the environment 25 2.5. Important topics for welded joints 26 2.5.1. General overview 26 viii Fatigue Life Analysis of Welded Structures 2.6. Various types of joints 30 2.6.1. Plated joints 30 2.6.2. Tubular joints 34 2.7. References 35 Chapter 3. Experimental Methods and Data Analysis 37 3.1. Introduction and objectives 37 3.2. Overview of various types of tests 38 3.3. Stress-life testing (S-N testing) of welded joints 38 3.3.1. Test specimens and test setup 38 3.3.2. Preparations and measurements 41 3.3.3. Test results 46 3.4. Testing to determine the parameters in the strain-life equation 49 3.5. Crack growth tests - guidelines for test setup and specimen monitoring 50 3.6. Elementary statistical methods 55 3.6.1. Linear regression analyses 55 3.7. References 60 Chapter 4. Definition and Description of Fatigue Loading 61 4.1. Introduction and objectives 61 4.2. Constant amplitude loading 62 4.3. Variable amplitude loading 63 4.3.1. Overview 63 4.3.2. Rain-flow cycle counting of time series 64 4.3.3. The energy spectrum approach 69 4.4. References 73 Chapter 5. The S-N Approach 75 5.1. Introduction and objectives 75 5.2. Method, assumptions and important factors 76 5.2.1. Statistics for the S-N approach, median and percentile curves . . 76 5.2.2. Discussion of S-N curves-important factors 78 5.2.2.1. The threshold phenomenon 78 5.2.2.2. Mean stress and loading ratio 79 5.2.2.3. Stress relieving 79 5.2.2.4. The thickness effect 80 5.2.2.5. Misalignment 81 5.2.2.6. Post-weld improvement techniques 82 5.2.2.7. Corrosive environment 83 5.3. Mathematics for damage calculations 84 5.3.1. Linear damage accumulation; load spectrum on a histogram format 84 Table of Contents ix 5.3.2. Discussion of the validity of the linear damage accumulation. . . 86 5.3.3. Definition of the equivalent stress range 88 5.3.4. Load spectrum on the format of a Weibull distribution 88 5.4. S-N curves related to various stress definitions 91 5.4.1. Nominal stress, geometrical stress and weld notch stresses . 92 5.4.2. Geometrical stresses in tubular joints 96 5.4.3. Fatigue life estimate based on the weld notch stress approach . . 98 5.4.4. Conclusions on the various stress approaches 101 5.5. Some comments on finite element analysis 104 5.6. Current rule and regulations 110 5.6.1. General considerations 110 5.6.2. The original fatigue classes and S-N curves from DoE 112 5.6.3. S-N life predictions according to Eurocode 3-Air environment 117 5.6.4. S-N life predictions according to HSE 119 5.6.5. S-N life predictions according to NORSOK and DNV 120 5.6.6. S-N life predictions for ship structures 122 5.7. The industrial case: an offshore loading buoy 130 5.8. References 136 Chapter 6. Applied Fracture Mechanics 139 6.1. Introduction 139 6.2. Objectives of this chapter 142 6.3. Basic concepts of linear elastic fracture mechanics 142 6.3.1. The local stress field ahead of the crack front 142 6.4. Fracture criterion due to extreme load 152 6.4.1. Mixed mode rupture 153 6.4.2. The R6 criterion and critical crack size 154 6.5. Fatigue threshold and fatigue crack growth 156 6.5.1. Crack growth models 156 6.5.2. Parameters C andm 159 6.5.3. Residual stresses 160 6.5.4. Some notes on the size of the initial cracks 161 6.6. Geometry function and growth parameters given in BS7910 161 6.6.1. The geometry function 162 6.6.2. Parameters C and m 163 6.7. Fracture mechanics model for a fillet welded plate joint 165 6.7.1. Basic assumptions and criteria for the model 165 6.7.2. Data for crack growth measurements (database 1) 166 6.7.3. Data for fatigue lives at low stress levels (database 2) 167 6.7.4. Procedure and curve fitting 167 6.7.5. Growth parameters C and m 169 6.7.6. The initial crack depth ao 172 x Fatigue Life Analysis ofWelded Structures 6.7.7. Prediction of crack growth histories and construction of S-N curves 173 6.7.8. Conclusions for fillet joints with cracks at the weld toe 175 6.8. Fatigue crack growth in tubular joints 176 6.8.1. Discussion of current models 179 6.8.2. Conclusion on the empirical fracture mechanics model 183 6.8.3. Proposal for model improvements 183 6.9. A brief overview of stiffened panels 184 6.10. Units and conversion for fracture mechanics parameters 186 6.11. Industrial case: fatigue re-assessment of a welded pipe 186 6.11.1. Introduction 186 6.11.2. Description of the loading buoy with steel pipe 187 6.11.3. Replacement and inspection strategy 189 6.11.4. Re-assessment based on the S-N approach 190 6.11.5. Re-assessment based on fracture mechanics 191 6.12. References 193 PART II. Stochastic Modeling 197 Chapter 7. Stochastic Modeling 199 7.1. Introduction and objectives 199 7.2. Overview of models and methodology 200 7.2.1. Sources of uncertainty 200 7.2.2. Introduction to the random variable model and related methods . 201 7.2.3. Requirements for a stochastic model 203 7.2.4. The concept of the limit state function and the safety margin. . . 204 7.2.5. The first and second order reliability methods (FORM/SORM) . 206 7.3. Elementary reliability models 207 7.3.1. General considerations 207 7.3.2. The Lognormal distribution 208 7.3.3. The Weibull distribution 209 7.4. The random variable model using simulation methods 212 7.4.1. General considerations 212 7.4.2. The realization of a random variable by the Monte Carlo method 213 7.5. Random variable models based on the S-N approach 215 7.5.1. The lognormal format for the S-N fatigue life 215 7.5.1.1. Example: full-penetration butt joint in an offshore structure 217 7.5.2. Monte Carlo Simulation of the S-N fatigue life 219 7.6. Random variable models based on fracture mechanics 220 7.6.1. General considerations 220 7.6.2. Taking account for future inspections and inspection results . 221 7.6.3. Characterization of the performance of the non-destructive inspection technique 223 Table of Contents xi 7.6.4. Simulation with account for future planned inspections 225 7.6.4.1. A first approximation to the inspection problem 225 7.6.4.2. Full stochastic simulation 226 7.6.5. Simulation of planned inspections for a fillet welded joint 229 7.6.6. Updating based on inspections results 231 7.7. The Markov chain model 235 7.7.1. Basic concepts. 235 7.7.2. Simple illustration on how the model works 235 7.7.3. Elaboration of the model 242 7.7.4. Influence of scheduled inspection and repair 244 7.7.5. Parameter estimation 246 7.7.6. Hybrid model to account for additional scatter 248 7.7.7. Analysis of a fillet welded joint 249 7.7.7.1. Short review and elaboration of database 1 250 7.7.7.2. Determination of parameters in the Markov model 251 7.7.7.3. Reliability results and discussion 253 7.8. A damage tolerance supplement to rules and regulation 255 7.8.1. Introduction . 255 7.8.2. An industrial case study: single anchor loading system 260 7.8.2.1. Example 1: butt weld in upper pipeline 262 7.8.2.2. Example 2: welded brackets on the main plates 263 7.8.3. Conclusions for the damage tolerance supplement 263 7.9. Risk assessments and cost benefit analysis 264 7.10. Reliability and risk assessment for the riser steel pipe 267 7.11. References 268 PART III. Recent Advances 271 Chapter 8. Proposal for a New Type of S-N Curve 273 8.1. Introduction and objectives 273 8.2. General considerations for the conventional S-N approach 275 8.2.1. Basic assumptions 275 8.2.2. The S-N approach based on BS5400 and Eurocode 3 275 8.3. S-N curves based on a random fatigue limit model 277 8.4. Experimental data for model calibration 278 8.4.1. Data for fatigue life at high stress levels (database 1) 278 8.4.2. Data for fatigue lives at low stress levels (database 2) 279 8.5. Comparison between the F-class curve, the RFLM-based curve and the data 279 8.6. Conclusions. 284 8.7. References 284 xii Fatigue Life Analysis of Welded Structures Chapter 9. Physical Modeling of the Entire Fatigue Process 287 9.1. Introduction and objectives 287 9.2. Modeling the fatigue crack initiation period 289 9.2.1. Basic concept and equations for the local stress-strain approach 289 9.2.2. Definition of the initiation phase and determination of parameters 292 9.2.3. Local toe geometry and stress concentration factor 292 9.2.4. Transition depth 294 9.2.5. Cyclic mechanical properties and parameters in Coffin-Manson equation 295 9.3. Constructing the S-N curve from the two-phase model 297 9.4. Damage accumulation using the TPM 301 9.5. The practical consequences of the TPM 302 9.5.1. General considerations 302 9.5.2. Life predictions and dimensions 302 9.5.3. Predicted crack evolution and inspection planning 303 9.6. Conclusions 306 9.7. Suggestions for future work 307 9.8. References 308 Chapter 10. A Notch Stress Field Approach to the Prediction of Fatigue Life 309 10.1. A modified S-N approach 309 10.1.1. General considerations 309 10.1.2. The basic theory for the notch stress intensity factor 311 10.1.3. S-N data analysis for fillet welded joints 313 10.2. A modified crack growth approach 315 10.3. References 317 Chapter 11. Multi-Axial Fatigue of Welded Joints 319 11.1. Introduction and objectives 319 11.2. Overview of theory and crack-extension criteria 321 11.3. The crack box technique 322 11.3.1. General considerations for finite element analysis and element mesh 322 11.3.2. Methodology 322 11.3.3. Examples 324 11.4. Tentative mixed-mode model to crack propagation in welded joints . 325 11.4.1. Modeling the effect of the loading mode on the crack growth rate 327 11.4.2. Modeling the effect of the residual stress due to the weld on the crack growth rate 328 Table of Contents xiii 11.4.3. Measured effect of the loading angle on the crack growth rate . 329 11.4.4. Measured effect of weld on the crack growth rate 331 11.4.5. Measured crack extension angle under mixed mode loading. . . 332 11.5. Validation of the model 333 11.5.1. Verification of the models for non-welded steel specimens under mixed-mode loading 334 11.5.2. Verification of the models for non-welded and welded steel specimens under mode I loading 336 11.5.3. Verification of the models for welded steel specimens under mixed-mode loading 337 11.5.4. Verification of the effect of the welded residual stress on the fatigue life 338 11.5.5. Discussion and conclusions 339 11.6. Extension to full test 340 11.6.1. Modeling methodology 341 11.6.2. Global calculation scheme 341 11.6.3. The crack box technique 343 11.6.4. Crack-propagation rate 344 11.6.5. Description of experiments carried out 345 11.6.6. Results 345 11.6.7. Weld toe geometry 346 11.6.8. Numerical calculations 347 11.6.8.1. Crack initiation 347 11.6.8.2. Crack growth 349 11.7. References 351 Chapter 12. The Effect of Overloads on the Fatigue Life 355 12.1. Introduction and objectives 355 12.2. Residual stress opening approach at the crack tip following an overload during fatigue 359 12.3. Numerical modeling 362 12.3.1. Modeling aspects 362 12.3.2. Finite element modeling choices 363 12.4. Proposed deterministic approach to fatigue crack growth following an overload 366 12.5. Reliability modeling including the effect of an overload 370 12.6. Application of the reliability model to a fillet welded joint 371 12.7. References 375 Appendix A. Short Overview of the Foundations of Fracture Mechanics . 381 Al. Introduction 381 A2. Elementary failure modes and stress situations 383 A3. Foundations of fracture mechanics 383 A4. Parameters characterizing the singular zone 385 xiv Fatigue Life Analysis of Welded Structures A4.1. The stress intensity factor (SIF), K 385 A4.2. The energy release rate, G 387 A4.3. The J-integral 388 A4.4. The crack-opening displacement (COD) 389 A5. Asymptotic stress field in elastic-plastic media 390 A5. References 391 Appendix B. Spreadsheet for Fatigue Life Estimates 393 Appendix C. CG - Crack Growth Based on Fracture Mechanics 395 Appendix D. CI - Crack Initiation Based on Coffin-Manson 399 Index 403
any_adam_object	1
any_adam_object_boolean	1
author	Lassen, Tom
author_facet	Lassen, Tom
author_role	aut
author_sort	Lassen, Tom
author_variant	t l tl
building	Verbundindex
bvnumber	BV022407058
callnumber-first	T - Technology
callnumber-label	TA492
callnumber-raw	TA492.W4
callnumber-search	TA492.W4
callnumber-sort	TA 3492 W4
callnumber-subject	TA - General and Civil Engineering
classification_rvk	UQ 7400 ZM 8420
classification_tum	FER 525f
ctrlnum	(OCoLC)70219886 (DE-599)BVBBV022407058
dewey-full	671.5/2042
dewey-hundreds	600 - Technology (Applied sciences)
dewey-ones	671 - Metalworking & primary metal products
dewey-raw	671.5/2042
dewey-search	671.5/2042
dewey-sort	3671.5 42042
dewey-tens	670 - Manufacturing
discipline	Physik Fertigungstechnik Werkstoffwissenschaften / Fertigungstechnik
discipline_str_mv	Physik Fertigungstechnik Werkstoffwissenschaften / Fertigungstechnik
edition	1. publ.
format	Book
fullrecord	<?xml version="1.0" encoding="UTF-8"?><collection xmlns="http://www.loc.gov/MARC21/slim"><record><leader>02120nam a2200529zc 4500</leader><controlfield tag="001">BV022407058</controlfield><controlfield tag="003">DE-604</controlfield><controlfield tag="005">20190508 </controlfield><controlfield tag="007">t</controlfield><controlfield tag="008">070430s2006 xxuad\|\| \|\|\|\| 00\|\|\| eng d</controlfield><datafield tag="010" ind1=" " ind2=" "><subfield code="a">2006020963</subfield></datafield><datafield tag="020" ind1=" " ind2=" "><subfield code="a">9781905209545</subfield><subfield code="9">978-1-905209-54-5</subfield></datafield><datafield tag="020" ind1=" " ind2=" "><subfield code="a">1905209541</subfield><subfield code="9">1-905209-54-1</subfield></datafield><datafield tag="035" ind1=" " ind2=" "><subfield code="a">(OCoLC)70219886</subfield></datafield><datafield tag="035" ind1=" " ind2=" "><subfield code="a">(DE-599)BVBBV022407058</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="044" ind1=" " ind2=" "><subfield code="a">xxu</subfield><subfield code="c">US</subfield></datafield><datafield tag="049" ind1=" " ind2=" "><subfield code="a">DE-91G</subfield><subfield code="a">DE-634</subfield><subfield code="a">DE-M347</subfield></datafield><datafield tag="050" ind1=" " ind2="0"><subfield code="a">TA492.W4</subfield></datafield><datafield tag="082" ind1="0" ind2=" "><subfield code="a">671.5/2042</subfield></datafield><datafield tag="084" ind1=" " ind2=" "><subfield code="a">UQ 7400</subfield><subfield code="0">(DE-625)146577:</subfield><subfield code="2">rvk</subfield></datafield><datafield tag="084" ind1=" " ind2=" "><subfield code="a">ZM 8420</subfield><subfield code="0">(DE-625)159845:</subfield><subfield code="2">rvk</subfield></datafield><datafield tag="084" ind1=" " ind2=" "><subfield code="a">FER 525f</subfield><subfield code="2">stub</subfield></datafield><datafield tag="100" ind1="1" ind2=" "><subfield code="a">Lassen, Tom</subfield><subfield code="e">Verfasser</subfield><subfield code="4">aut</subfield></datafield><datafield tag="245" ind1="1" ind2="0"><subfield code="a">Fatigue life analyses of welded structures</subfield><subfield code="b">[FLAWS]</subfield><subfield code="c">Tom Lassen ; Naman Récho</subfield></datafield><datafield tag="250" ind1=" " ind2=" "><subfield code="a">1. publ.</subfield></datafield><datafield tag="264" ind1=" " ind2="1"><subfield code="a">London [u.a.]</subfield><subfield code="b">ISTE</subfield><subfield code="c">2006</subfield></datafield><datafield tag="300" ind1=" " ind2=" "><subfield code="a">XVI, 407 S., [4] Bl.</subfield><subfield code="b">Ill., graph. Darst.</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">n</subfield><subfield code="2">rdamedia</subfield></datafield><datafield tag="338" ind1=" " ind2=" "><subfield code="b">nc</subfield><subfield code="2">rdacarrier</subfield></datafield><datafield tag="650" ind1=" " ind2="4"><subfield code="a">Welded joints</subfield><subfield code="x">Fatigue</subfield></datafield><datafield tag="650" ind1=" " ind2="4"><subfield code="a">Welded steel structures</subfield></datafield><datafield tag="650" ind1="0" ind2="7"><subfield code="a">Schweißverbindung</subfield><subfield code="0">(DE-588)4053878-3</subfield><subfield code="2">gnd</subfield><subfield code="9">rswk-swf</subfield></datafield><datafield tag="650" ind1="0" ind2="7"><subfield code="a">Statistik</subfield><subfield code="0">(DE-588)4056995-0</subfield><subfield code="2">gnd</subfield><subfield code="9">rswk-swf</subfield></datafield><datafield tag="650" ind1="0" ind2="7"><subfield code="a">Materialermüdung</subfield><subfield code="0">(DE-588)4074631-8</subfield><subfield code="2">gnd</subfield><subfield code="9">rswk-swf</subfield></datafield><datafield tag="689" ind1="0" ind2="0"><subfield code="a">Schweißverbindung</subfield><subfield code="0">(DE-588)4053878-3</subfield><subfield code="D">s</subfield></datafield><datafield tag="689" ind1="0" ind2="1"><subfield code="a">Materialermüdung</subfield><subfield code="0">(DE-588)4074631-8</subfield><subfield code="D">s</subfield></datafield><datafield tag="689" ind1="0" ind2="2"><subfield code="a">Statistik</subfield><subfield code="0">(DE-588)4056995-0</subfield><subfield code="D">s</subfield></datafield><datafield tag="689" ind1="0" ind2=" "><subfield code="5">DE-604</subfield></datafield><datafield tag="700" ind1="1" ind2=" "><subfield code="a">Recho, Naman</subfield><subfield code="e">Sonstige</subfield><subfield code="4">oth</subfield></datafield><datafield tag="856" ind1="4" ind2=" "><subfield code="u">http://www.loc.gov/catdir/enhancements/fy0668/2006020963-b.html</subfield><subfield code="3">Contributor biographical information</subfield></datafield><datafield tag="856" ind1="4" ind2=" "><subfield code="u">http://www.loc.gov/catdir/enhancements/fy0668/2006020963-d.html</subfield><subfield code="3">Publisher description</subfield></datafield><datafield tag="856" ind1="4" ind2=" "><subfield code="u">http://www.loc.gov/catdir/toc/ecip0616/2006020963.html</subfield><subfield code="3">Table of contents only</subfield></datafield><datafield tag="856" ind1="4" ind2="2"><subfield code="m">HBZ Datenaustausch</subfield><subfield code="q">application/pdf</subfield><subfield code="u">http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=015615610&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA</subfield><subfield code="3">Inhaltsverzeichnis</subfield></datafield><datafield tag="999" ind1=" " ind2=" "><subfield code="a">oai:aleph.bib-bvb.de:BVB01-015615610</subfield></datafield></record></collection>
id	DE-604.BV022407058
illustrated	Illustrated
index_date	2024-07-02T17:20:30Z
indexdate	2024-07-09T20:56:55Z
institution	BVB
isbn	9781905209545 1905209541
language	English
lccn	2006020963
oai_aleph_id	oai:aleph.bib-bvb.de:BVB01-015615610
oclc_num	70219886
open_access_boolean
owner	DE-91G DE-BY-TUM DE-634 DE-M347
owner_facet	DE-91G DE-BY-TUM DE-634 DE-M347
physical	XVI, 407 S., [4] Bl. Ill., graph. Darst.
publishDate	2006
publishDateSearch	2006
publishDateSort	2006
publisher	ISTE
record_format	marc
spelling	Lassen, Tom Verfasser aut Fatigue life analyses of welded structures [FLAWS] Tom Lassen ; Naman Récho 1. publ. London [u.a.] ISTE 2006 XVI, 407 S., [4] Bl. Ill., graph. Darst. txt rdacontent n rdamedia nc rdacarrier Welded joints Fatigue Welded steel structures Schweißverbindung (DE-588)4053878-3 gnd rswk-swf Statistik (DE-588)4056995-0 gnd rswk-swf Materialermüdung (DE-588)4074631-8 gnd rswk-swf Schweißverbindung (DE-588)4053878-3 s Materialermüdung (DE-588)4074631-8 s Statistik (DE-588)4056995-0 s DE-604 Recho, Naman Sonstige oth http://www.loc.gov/catdir/enhancements/fy0668/2006020963-b.html Contributor biographical information http://www.loc.gov/catdir/enhancements/fy0668/2006020963-d.html Publisher description http://www.loc.gov/catdir/toc/ecip0616/2006020963.html Table of contents only HBZ Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=015615610&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis
spellingShingle	Lassen, Tom Fatigue life analyses of welded structures [FLAWS] Welded joints Fatigue Welded steel structures Schweißverbindung (DE-588)4053878-3 gnd Statistik (DE-588)4056995-0 gnd Materialermüdung (DE-588)4074631-8 gnd
subject_GND	(DE-588)4053878-3 (DE-588)4056995-0 (DE-588)4074631-8
title	Fatigue life analyses of welded structures [FLAWS]
title_auth	Fatigue life analyses of welded structures [FLAWS]
title_exact_search	Fatigue life analyses of welded structures [FLAWS]
title_exact_search_txtP	Fatigue life analyses of welded structures [FLAWS]
title_full	Fatigue life analyses of welded structures [FLAWS] Tom Lassen ; Naman Récho
title_fullStr	Fatigue life analyses of welded structures [FLAWS] Tom Lassen ; Naman Récho
title_full_unstemmed	Fatigue life analyses of welded structures [FLAWS] Tom Lassen ; Naman Récho
title_short	Fatigue life analyses of welded structures
title_sort	fatigue life analyses of welded structures flaws
title_sub	[FLAWS]
topic	Welded joints Fatigue Welded steel structures Schweißverbindung (DE-588)4053878-3 gnd Statistik (DE-588)4056995-0 gnd Materialermüdung (DE-588)4074631-8 gnd
topic_facet	Welded joints Fatigue Welded steel structures Schweißverbindung Statistik Materialermüdung
url	http://www.loc.gov/catdir/enhancements/fy0668/2006020963-b.html http://www.loc.gov/catdir/enhancements/fy0668/2006020963-d.html http://www.loc.gov/catdir/toc/ecip0616/2006020963.html http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=015615610&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA
work_keys_str_mv	AT lassentom fatiguelifeanalysesofweldedstructuresflaws AT rechonaman fatiguelifeanalysesofweldedstructuresflaws

Verfügbarkeit

Es ist kein Print-Exemplar vorhanden.

Fernleihe Bestellen Achtung: Nicht im THWS-Bestand! Inhaltsverzeichnis

MARC

Datensatz im Suchindex

Es ist kein Print-Exemplar vorhanden.

Ähnliche Einträge