The Welding Engineer's Guide to Fracture and Fatigue by Moore, Philippa L; Booth, Geoff;

Sorozatcím: Woodhead Publishing Series in Metals and Surface Engineering;

10% KEDVEZMÉNY?
A kedvezmény csak az 'Értesítés a kedvenc témákról' hírlevelünk címzettjeinek rendeléseire érvényes.

Kiadói listaár EUR 149.00
Az ár azért becsült, mert a rendelés pillanatában nem lehet pontosan tudni, hogy a beérkezéskor milyen lesz a forint árfolyama az adott termék eredeti devizájához képest. Ha a forint romlana, kissé többet, ha javulna, kissé kevesebbet kell majd fizetnie.

61 797 Ft (58 855 Ft + 5% áfa)
Kedvezmény(ek) 10% (cc. 6 180 Ft off)
Kedvezményes ár 55 618 Ft (52 970 Ft + 5% áfa)

61 797 Ft

Beszerezhetőség

Megjelenése törölve vagy kivonva a forgalomból. Sajnos nem rendelhető.

A termék adatai:

Kiadó Elsevier Science
Megjelenés dátuma 2018. október 30.

ISBN 9780081013106
Kötéstípus Puhakötés
Terjedelem224 oldal
Méret 228x152 mm
Nyelv angol

Kategóriák

Gépészmérnöki tudományok Üzemmérnöki tudományok Élelmiszer- és dohányipar, élelmiszertudomány Fémipar, fémfeldolgozó ipar További műszaki könyvek

Hosszú leírás:

The Welding Engineer's Guide to Fracture and Fatigue provides an essential introduction to fracture and fatigue and the assessment of these failure modes, through to the level of knowledge that would be expected of a qualified welding engineer. Part one covers the basic principles of weld fracture and fatigue. It begins with a review of the design of engineered structures, provides descriptions of typical welding defects and how these defects behave in structures undergoing static and cyclical loading, and explains the range of failure modes. Part two then explains how to detect and assess defects using fitness for service assessment procedures. Throughout, the book assumes no prior knowledge and explains concepts from first principles.

Több

Tartalomjegyzék:

Dedication
Woodhead Publishing Series in Welding and Other Joining Technologies
Preface
Part One: Principles of weld fracture and fatigue
- 1: Designing engineered structures
  - 1.1 Introduction
  - 1.2 The first engineered structures
  - 1.3 Successful structures
  - 1.4 Materials and fabrication methods
  - 1.5 Industrialisation: benefits and consequences
  - 1.6 Conclusions
- 2: Structures under load
  - 2.1 Introduction
  - 2.2 Sources of loading
  - 2.3 Types of loading
  - 2.4 Loads experienced during construction
  - 2.5 Design approach
  - 2.6 Axial and bending stresses
  - 2.7 Conclusions
- 3: Welding problems and defects
  - 3.1 Introduction
  - 3.2 'Workmanship' defects
  - 3.3 Weldability
  - 3.4 Fabrication cracking in welds
  - 3.5 Other types of weld defect
  - 3.6 Welding residual stresses
  - 3.7 Distortion
  - 3.8 Conclusions
- 4: Design for static loading
  - 4.1 Introduction
  - 4.2 Load-extension curves
  - 4.3 Stress-strain curves
  - 4.4 Static limit state design
  - 4.5 Conclusions
- 5: Brittle fracture and the behaviour of cracks in structures
  - 5.1 Introduction
  - 5.2 Nature of brittle fracture
  - 5.3 The three factors for brittle fracture
  - 5.4 Ductile-to-brittle transition
  - 5.5 Welding and fabrication codes
  - 5.6 Principles of fracture mechanics
  - 5.7 Fracture toughness parameters
  - 5.8 Conclusions
- 6: Structures under cyclic load
  - 6.1 Introduction
  - 6.2 Engineering perspective of fatigue
  - 6.3 Metallurgical perspective of fatigue
  - 6.4 Practical implications for a growing fatigue crack
  - 6.5 Conclusions
- 7: Fatigue of welded joints
  - 7.1 Introduction
  - 7.2 Fatigue performance of welded joints
  - 7.3 Special features of welded joints
  - 7.4 Fatigue design of welded joints
  - 7.5 Stress histories of real structures: variable amplitude loading
  - 7.6 Fatigue of welded aluminium
  - 7.7 Conclusions
- 8: Failure modes and analysis in metals
  - 8.1 Introduction
  - 8.2 Ductile failure
  - 8.3 Brittle fracture
  - 8.4 Fatigue failure
  - 8.5 Scanning electron microscopy (SEM) of fracture surfaces
  - 8.6 Interpreting fracture faces
  - 8.7 Corrosion
  - 8.8 Engineering failure investigations
  - 8.9 Conclusions
Part Two: Testing, analysis and assessment of weld fracture and fatigue
- 9: Mechanical testing of welds
  - 9.1 Introduction
  - 9.2 Weld procedure qualification
  - 9.3 Bend testing
  - 9.4 Tensile testing
  - 9.5 Charpy testing
  - 9.6 Fracture toughness testing
  - 9.7 Fatigue testing
  - 9.8 Creep testing
  - 9.9 Corrosion testing
  - 9.10 Macrographic sections
  - 9.11 Hardness testing
  - 9.12 Conclusions
- 10: Detecting weld defects
  - 10.1 Introduction
  - 10.2 'Perfect' welds and detection of weld defects
  - 10.3 Visual inspection
  - 10.4 Dye penetrant inspection
  - 10.5 Magnetic particle inspection (MPI)
  - 10.6 Eddy-current testing
  - 10.7 Radiography
  - 10.8 Ultrasonic testing (UT)
  - 10.9 Probability of detection
  - 10.10 Flaw-sizing error
  - 10.11 Choosing suitable non-destructive testing (NDT) methods
  - 10.12 Conclusions
- 11: Weld defect assessment
  - 11.1 Introduction
  - 11.2 Fitness-for-service assessment
  - 11.3 When to carry out an engineering critical assessment (ECA)
  - 11.4 Standards for assessment methods
  - 11.5 Input data for ECA
  - 11.6 Failure assessment diagrams (FAD)
  - 11.7 Proximity to failure and safety factors
  - 11.8 Refining the assessment
  - 11.9 Conclusions
- 12: Weld fatigue assessment
  - 12.1 Introduction
  - 12.2 Using fracture mechanics to describe fatigue crack growth
  - 12.3 The power law (Paris equation)
  - 12.4 Assessing weld flaws under fatigue loading
  - 12.5 Advanced fatigue crack growth assessment
  - 12.6 Conclusions
- 13: Improving the fracture performance and fatigue life of welded joints
  - 13.1 Introduction
  - 13.2 Fatigue improvement measures to be taken before welding
  - 13.3 Fatigue improvement techniques for welds
  - 13.4 Other fatigue considerations
  - 13.5 Improving fracture performance
  - 13.6 Using this book: repair of fatigue cracks
  - 13.7 Conclusions
Index