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- Herausgeber: Wiley-VCH
- Kategorie: Wissenschaft und neue Technologien
- Sprache: Englisch
This volume addresses the specific subject of fatigue, a subject not familiar to many engineers, but still relevant for proper and good design of numerous steel structures. It explains all issues related to the subject: Basis of fatigue design, reliability and various verification formats, determination of stresses and stress ranges, fatigue strength, application range and limitations. It contains detailed examples of applications of the concepts, computation methods and verifications.
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Seitenzahl: 345
Veröffentlichungsjahr: 2012
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Table of contents
FOREWORD
PREFACE
ACKNOLWLEDGMENTS
SYMBOLOGY
TERMINOLOGY
Chapter 1 INTRODUCTION
1.1 BASIS OF FATIGUE DESIGN IN STEEL STRUCTURES
1.2 DAMAGE EQUIVALENT FACTOR CONCEPT
1.3 CODES OF PRACTICE
1.4 DESCRIPTION OF THE STRUCTURES USED IN THE WORKED EXAMPLES
Chapter 2 APPLICATION RANGE AND LIMITATIONS
2.1 INTRODUCTION
2.2 MATERIALS
2.3 CORROSION
2.4 TEMPERATURE
2.5 LOADING RATE
2.6 LIMITING STRESS RANGES
Chapter 3 DETERMINATION OF STRESSES AND STRESS RANGES
3.1 FATIGUE LOADS
3.2 DAMAGE EQUIVALENT FACTORS
3.3 CALCULATION OF STRESSES
3.4 MODIFIED NOMINAL STRESSES AND CONCENTRATION FACTORS
3.5 GEOMETRIC STRESSES (STRUCTURAL STRESS AT THE HOT SPOT)
3.6 STRESSES IN ORTHOTROPIC DECKS
3.7 CALCULATION OF STRESS RANGES
3.8 MODIFIED NOMINAL STRESS RANGES
3.9 GEOMETRIC STRESS RANGES
Chapter 4 FATIGUE STRENGTH
4.1 INTRODUCTION
4.2 FATIGUE DETAIL TABLES
4.3 DETERMINATION OF FATIGUE STRENGTH OR LIFE BY TESTING
Chapter 5 RELIABILITY AND VERIFICATION
5.1 GENERALITIES
5.2 STRATEGIES
5.3 PARTIAL FACTORS
5.4 VERIFICATION
Chapter 6 :BRITTLE FRACTURE
6.1 INTRODUCTION
6.2 STEEL QUALITY
6.3 RELATIONSHIP BETWEEN DIFFERENT FRACTURE TOUGHNESS TEST RESULTS
6.4 FRACTURE CONCEPT IN EN 1993-1-10
6.5 STANDARDISATION OF CHOICE OF MATERIAL: MAXIMUM ALLOWABLE THICKNESSES
REFERENCES
Annex A STANDARDS FOR STEEL CONSTRUCTION
Annex B FATIGUE DETAIL TABLES WITH COMMENTARY
INTRODUCTION
Annex C MAXIMUM PERMISSIBLE THICKNESS TABLES
INTRODUCTION
Fatigue Design of Steel and Composite Structures
1st Edition, 2011
Published by:
ECCS – European Convention for Constructional Steelwork
www.steelconstruct.com
Sales:
Wilhelm Ernst & Sohn Verlag für Architektur und technische Wissenschaften
GmbH & Co. KG, Berlin
All rights reserved. No parts of this publication may be reproduced, stored in a retrieval system, or transmitted in any form or by any means, electronic, mechanical, photocopying, recording or otherwise, without the prior permission of the copyright owner.
ECCS assumes no liability with respect to the use for any application of the material and information contained in this publication.
Copyright © 2011 ECCS – European Convention for Constructional Steelwork
ISBN (ECCS): 978-92-9147-101-0
ISBN (Ernst & Sohn): 978-3-433-02981-7
Legal dep.: - Printed in Multicomp Lda, Mem Martins, Portugal
Photo cover credits: Alain Nussbaumer
FOREWORD
Steel structures have been built worldwide for more than 120 years. For the majority of this time, fatigue and fracture used to be unknown or neglected limit states, with the exception in some particular and “obvious” cases. Nevertheless, originally unexpected but still encountered fatigue and fracture problems and resulting growing awareness about such have that attitude reappraised. The consequent appearance of the first ECCS recommendations on fatigue design in 1985 changed radically the spirit. The document served as a basis for the fatigue parts in the first edition of Eurocodes 3 and 4. Subsequent use of the latter and new findings led to improvements resulting in the actual edition of the standards, the first to be part of a true all-European set of construction design standards.
As with any other prescriptive use of technical knowledge, the preparation of the fatigue parts of Eurocodes 3 and 4 was long and based on the then available information. Naturally, since the publication of the standards, have evolved not only structural materials but also joint techniques, structural analysis procedures and their precision, measurement techniques, etc., each of these revealing new, previsouly unknown hazardous situation that might lead to fatigue failure. The result is that even the most actual standards remain somewhat unclear (but not necessarily unsafe!) in certain areas and cover some others not sufficiently well or not at all. Similar reasoning can be applied for the fracture parts of Eurocode 3, too.
Having all the above-mentioned in mind, the preparation of this manual was intended with the aim of filling in some of the previously revealed gaps by clarifying certain topics and extending or adding some others. For the accomplishment of that task, the manual benefited from a years-long experience of its authors and its proofreaders in the fields treated in it; it is a complete document with detailed explanations about how to deal with fatigue and fracture when using Eurocodes… but also offering much, much more. This is probably the most exhaustive present-day fatigue manual on the use of Eurocodes 3 and 4, checked and approved by members of ECCS TC6 “Fatigue and Fracture”.
This document outlines all the secrets of fatigue and fracture verifications in a logical, readable and extended (in comparison to the standards) way, backed by three thoroughly analysed worked examples. I am convinced that a manual as such cannot only help an inexperienced user in the need of some clarifications but can also be hailed even by the most demanding fatigue experts.
Mladen Lukić
CTICM, Research Manager
ECCS TC6 Chairman
PREFACE
This book addresses the specific subject of fatigue, a subject not familiar to many engineers, but relevant for achieving a satisfactory design of numerous steel and composite steel-concrete structures. Since fatigue and fracture cannot be separated, they are indeed two aspects of the same behaviour, this book also addresses the problem of brittle fracture and its avoidance following the rules in EN 1993-1-10.
According to the objectives of the ECCS Eurocode Design Manuals, this book aims at providing design guidance on the use of the Eurocodes for practicing engineers. It provides a mix of “light” theoretical background, explanation of the code prescriptions and detailed design examples. It contains all the necessary information for the fatigue design of steel structures according to the general rules given in Eurocode 3, part 1-9 and the parts on fatigue linked with specific structure types.
Fatigue design is a relatively recent code requirement. The effects of repetitive loading on steel structures such as bridges or towers have been extensively studied since the 1960s. This work, as well as lessons learned from the poor performance of some structures, has led to a better understanding of fatigue behaviour. This knowledge has been implemented in international recommendations, national and international specifications and codes since the 1970s. At European level, the ECCS recommendations (ECCS publication N° 43 from 1985) contained the first unified fatigue rules, followed then by the development of the structural Eurocodes. Today, fatigue design rules are present in many different Eurocode parts : EN 1991-2, EN 1993-1-9, EN 1993-1-11, EN 1993-2, EN 1993-3, etc. as will be seen throughout this book.
Chapter 1 introduces general aspects of fatigue, the main parameters influencing fatigue life, damage and the structures used in the worked examples. The design examples are chosen from typical structures that need to be designed against fatigue: i) a steel and concrete composite bridge which is also used in the ECCS design manual on EN 1993-1-5 (plate buckling), ii) a steel chimney and iii) a crane supporting structure. Chapter 2 summarizes the application range of the Eurocode and its limitations in fatigue design. Chapters 3 to 5 are the core of this book, explaining the determination of the parts involved in a fatigue verification namely: applied stress range, fatigue strength of details, fatigue design strategies and partial factors, damage equivalent factors. For each of the parts a theoretical background is given, followed by explanation of the code prescriptions and then by application to the different design examples. Finally, chapter 6 deals with steel selection, which in fact is the first step in the design process but is separated from fatigue design in the Eurocodes. In this chapter, the theory and application of EN 1993-1-10 regarding the selection of steel for fracture toughness are discussed. Note that the selection of material regarding through-thickness properties is not within the scope of this book. The books also includes annexes containing the fatigue tables from EN 1993-1-9, as well as detail categories given in other Eurocode parts (cables). The tables include the corrections and modifications from the corrigendum issued by CEN on April 1st, 2009 (changes are highlighted with a grey background). These tables also contain an additional column with supplementary explanations and help for the engineer to classify properly fatigue details and compute correctly the stress range needed for the verification. The last annex contains the tables from EN 1993-1-10 and EN 1993-12 giving the maximum permissible values of elements thickness to avoid brittle fracture.
Luis Borges
Laurence Davaine
Alain Nussbaumer
ACKNOWLEDGMENTS
This document was written under the supervision of the ECCS Editorial Committee. It was reviewed by the members of this committee, whom the authors would like to thank:
Luís Simões da Silva (Chairman - ECCS),
António Lamas (Portugal)
Jean-Pierre Jaspart (Belgium)
Reidar Bjorhovde (USA)
Ulrike Kuhlmann (Germany)
The document was also reviewed by the ECCS Technical Committee 6, working group C. Their comments and suggestions were of great help to improve the quality of the document. Many thanks to all contributive former and current members:
Ömer Bucak, Matthias Euler, Hans-Peter Günther (Chairman WG-C), Senta Haldimann-Sturm, Rosi Helmerich, Stefan Herion, Henk Kolstein, Bertram Kühn, Mladen Lukic (Chairman TC6), Johan Maljaars and Joël Raoul.
Many thanks are also due to all the other persons, too numerous to mention here, who offered their continuous encouragement and suggestions. A large part of the figures were made or adapted by ICOM’s talented draftsman and more, Claudio Leonardi.
Finally, thanks are due to Ms. Joana Albuquerque for formatting the text before publication.
Luis Borges
Laurence Davaine
Alain Nussbaumer
SYMBOLOGY
This list of symbols follows the Eurocodes, in particular EN 1993-1-9, and only the fatigue relevant symbols are given below.
Latin letters
AAreaaCrack depthbeffRelevant thickness in Wallin toughness correlationcHalf crack lengthCConstant representing the influence of the construction detail in fatigue strength expressionmFatigue curve slope coefficientD, dDamage sum, damageGPermanent actions effectskfStress concentration factor (i.e. geometric stress concentration factor, thus in this publication there is no difference with kt)KmatFracture toughnessIinertiaI2inertia of the cracked composite cross sectionMBending momentN, nNumber of cycles, numberNtotTotal number of cycles in a spectrumn0short term modular ratio, Ea / EcmninspTotal number of inspections during services lifenstudnumber of shear studs per unit lengthPfFailure probabilityQLoadQEDamage equivalent fatigue loadQE,2Damage equivalent fatigue load related to 2 million cyclesQk,1Characteristic value of dominant variable load,QK,iCharacteristic value of accompanying variable loads,Qi,QfatCharacteristic fatigue loadRStress ratio, σmin /σmaxSStandard deviation, characteristic value of the effects of the concrete shrinkagetTime, thicknesst0Reference thickness, equal to 1 mmTTemperatureTkCharacteristic value of the effects of the thermal gradientTkv27Temperature at which the minimum energy is not less than 27 J in a CVN impact testTk100Temperature at which the fracture toughness is not less than 100 MPa.m1/2Tmin,dLowest air temperature with a specified return period, see EN 1991-1-5ΔTrTemperature shift from radiation losses of the structural memberΔTσTemperature shift for the influence of shape and dimensions of the member, imperfection from crack, and stress σEdΔTRTemperature shift corresponding to additive safety elementΔTεTemperature shift for the influence of strain rateΔTεplTemperature shift from from cold formingGreek Symbols
γFfPartial factor for fatigue action effectsγMfPartial factor for fatigue strengthλDamage equivalent factorλ1Factor accounting for the span length (in relation with the length of the influence line)λ2Factor accounting for a different traffic volume than givenλ3Factor accounting for a different design working life of the structure than givenλ4Factor accounting for the influence of more than one load on the structural member,λmaxMaximum damage equivalent factor value, taking into account the fatigue limit.λvDamage equivalent factor for the connectionψ1Combination factor for frequent loadsψ2,iCombination factor for quasi-permanent loadsσminMinimum direct or normal stress value (with sign), expressed in N/mm2σmaxMaximum direct or normal stress value (with sign), expressed in N/mm2σresResidual stress value, expressed in N/mm2v2distance from the neutral axis to the relevant fibre in a steel concrete beamΔσCFatigue strength under direct stress range at 2 million cycles, expressed in N/mm2ΔτCFatigue strength under shear stress range at 2 million cycles,expressed in N/mm2ΔσDConstant amplitude fatigue limit (CAFL) under direct stress range,at 5 million cycles in the set of fatigue strength curves, expressed in N/mm2ΔσE,2Equivalent direct stress range, computed at 2 million cycles, expressed in N/mm2ΔσLCut-off limit under direct stress range, at 100 million cycles in the set of fatigue strength curves, expressed in N/mm2ΔτLCut-off limit under shear stress range, at 100 million cycles in the set of fatigue strength curves, expressed in N/mm2ΔvLlongitudinal shear force per unit length at the steel-concrete interfaceTERMINOLOGY
Figure 0.1 - Orientation of the attachment with respect to the main force
