An edition of High-strength steels (2018)

High-strength steels

new trends in production and applications

High-strength steels
Branco, Ricardo (Mechanical en ...
Not in Library

My Reading Lists:

Create a new list

Check-In

×Close
Add an optional check-in date. Check-in dates are used to track yearly reading goals.
Today


Buy this book

Last edited by MARC Bot
December 18, 2022 | History
An edition of High-strength steels (2018)

High-strength steels

new trends in production and applications

High strength steels cover a broad spectrum of applications and are being increasingly used in different areas due to their distinguished features, namely excellent strength-to-weight ratio, good corrosion resistance, deep hardenability, high ductility, high toughness and high strength. These features make them ideal for critical structural applications undergoing severe service conditions and aggressive environments. Long-term durability requires a systematic identification of failure risks and the development of accurate design methodologies. This book covers leading-edge research in these areas. The topics addressed include temperature and stress triaxiality effects on deformation and fracture, analysis of hydrogenation via local electrochemical techniques, second-order direct design methods of columns, hydrogen-steel interactions in automotive transmissions subjected to low-cycle fatigue histories, strain-based design methods for crossing fault rupture in pipelines, metallurgical and technological weldability of quenched and tempered steels, and local-overall interaction buckling phenomena in welded thin-walled columns and beam-columns.

Publish Date
Language
English

Buy this book

Edition Availability
Cover of: High-strength steels
High-strength steels: new trends in production and applications
2018, Nova Science Publishers, Incorporated
in English

Add another edition?

Book Details


Table of Contents

Intro; Contents; Preface; Chapter 1; Effects of Temperature and Stress Triaxiality on Deformation and Fracture Behaviour of High-Strength Rail Steels; Abstract; Introduction; Theoretical Background; Extended Strain Energy Density Model; Equivalent Plastic Fracture Strain of Pre-Cracked SENB Specimen; Experiments; Materials and Test Specimens; Tensile Test of Smooth Specimens; Tensile Test of Short-Gauged Specimens; Three-Point Bending Test; Finite Element Modelling; Temperature Effect on Mechanical Properties; Smooth and Short-Gauged Tensile Specimens; Fracture Toughness.
KSc Prediction Based on an Extended SED ModelConstitutive Equation; Average Stress Triaxiality; Fracture Locus; KSc Prediction; Conclusion; Acknowledgments; References; Chapter 2; Hydrogen Entry and Distribution in Steel: Assessments by Different Local Electrochemical Techniques; Abstract; Introduction; Results and Discussion; Scanning Electrochemical Microscopy (SECM); Scanning Vibrating Electrode (SVET) and Local Electrochemical Impedance (LEIS) Techniques; Scanning Kelvin Probe (SKP) Technique; SKP Application for Determination of Localized Stress.
SKP Technique for Determination of the Hydrogen in SteelsConclusion; References; Chapter 3; New Design Theory of Second-Order Direct Analysis for High-Strength Steel Columns; Abstract; Introduction; Background and Literature Review; High-Strength Steel Materials; Residual Stress; High-Strength Steel Columns; Second-Order Direct Analysis Method; Design by Second-Order Direct Analysis Method for High-Strength Steel Columns; Beam-Column Element Formulations; Plastic Fibre Hinge Model; Cross Section Analysis Technique; Analysis Examples.
Verification of Sectional Analysis Technique with Residual Stress(a) Box-Section with Residual Stress; (b) H-Section with Residual Stress; Direct Analysis of High-Strength Steel Columns; (a) Welded Box-Column with Q460 High-Strength Steel; (b) Welded H-Column with Q460 High-Strength Steel; Conclusion; Acknowledgments; References; Chapter 4; Interactions and Effects of Hydrogen on High Strength Steels; Abstract; Introduction; Experimetal Methods; Hydrogen in Fatigue; Fatigue Behavior; Fractography; Thermal Analysis; Silver Decoration Technique; Conclusion; References; Chapter 5.
Strain-Based Design Method for High-Strength Steel Pipelines in Active Fault Crossing AreasAbstract; Introduction; Material Model for High Strength Pipe Steel; Ramberg-Osgood Model; Novel Material Stress-Strain Characterization Model Proposed by UOA; Strain Demand Analysis Method for Buried Pipe Subjected to Fault Displacements; Fault Displacement Magnitudes; Numerical Model for Strain Demand Calculation; Modeling Soil Constraints on Pipe; Modeling Pipe; Load and Boundary Conditions; Strain Capacity Models for High-Strength Pipe; Tensile Strain Capacity Model.

Edition Notes

Compressive Strain Capacity Model.

Includes bibliographical references and index.

Published in
New York
Series
Mechanical engineering theory and applications, Mechanical engineering theory and applications

Classifications

Dewey Decimal Class
620.1/7
Library of Congress
TA478

The Physical Object

Pagination
1 online resource

ID Numbers

Open Library
OL44422286M
ISBN 10
1536139076
ISBN 13
9781536139075
OCLC/WorldCat
1044949297

Source records

marc_columbia MARC record

Community Reviews (0)

Feedback?
No community reviews have been submitted for this work.

Lists

This work does not appear on any lists.

History

Download catalog record: RDF / JSON / OPDS | Wikipedia citation
December 18, 2022 Created by MARC Bot Imported from marc_columbia MARC record