Abstract

Automotive and aerospace sectors have a pressing need for structural components that are lighter and stronger, aiming to improve energy efficiencies and reduce anthropogenic environment. Steel has already a wide variety of structural applications in the transportation industry due to its excellent properties. To further reduce CO2 emissions, lightweight magnesium (Mg) and aluminum (Al) alloys have increasingly been used in the vehicle fabrication due to their lower density, higher specific strength and stiffness, excellent size stability and process ability. The structural application of these alloys inevitably involves welding and joining of similar Mg-to-Mg and Al-to-Al, and dissimilar Mg-to-Al, Mg-to-steel and Al-to-steel. Resistance spot welding produces coarse grains, large defects and thick brittle intermetallic compounds (IMCs) in the weld metal. Alternative solid-state welding processes are being considered such as ultrasonic spot welding (USW), which produces coalescence through the simultaneous application of localized high-frequency vibratory energy and moderate clamping forces. In this study, USW was successfully carried out on similar Mg alloy and dissimilar Mg-to-Al, Mg-to-steel and Al-to-steel alloys. The overall objective of this work is to gain a better understanding of the dominant factors determining the joint performance, with particular emphasis on the microstructural evolution, crystallographic texture, micro-hardness, lap shear strength, fatigue resistance, fatigue life prediction model and fracture analysis of similar and dissimilar USWed joints. Overall, USWed Mg-to-Mg is stronger and more consistent in terms of weldability than the dissimilar USWed Mg-to-Al, Mg-to-steel and Al-to-steel. This was attributed to the large volume of thick brittle IMCs and significantly higher welds center hardness in dissimilar metals welding, which is the main cause of joint failure. The IMCs were confirmed by XRD, EDS and micro-hardness measurement tests.. Therefore, another objective of this study is to minimize the presence of brittle IMCs and engineer an acceptable intermetallic layer to produce sound joints between Mg-to-Al, Mg-to-steel and Al-to-steel. A third material (tin foil or zinc coating) was placed in-between the work pieces. With this procedure, the lap shear strength of the welded samples was increased. The detailed microstructural characterization and mechanical properties of welded joints with an interlayer are presented.

Highlights

  • AND MOTIVATIONEnvironmental pollution may be attributed to a large extent to the transportation industry, predominantly CO2 emissions produced by automotive vehicles

  • After converting the maximum applied load into the maximum stress using the nominal welding nugget area in different welding techniques, the USWed joints displayed a longer fatigue life compared with other welding processes

  • In all joint combinations considered in this study, lap shear tensile strength of the joints increased with increasing energy inputs and decreased

Read more

Summary

INTRODUCTION

Environmental pollution may be attributed to a large extent to the transportation industry, predominantly CO2 emissions produced by automotive vehicles. These can have devastating effects on human society and the environment [1-9]. To improve the mechanical properties like lap shear tensile and fatigue, IMCs of dissimilar USWed joints were engineered with the help of a Sn interlayer and Zn coating. The remainder of this Chapter establishes the motivation and framework for welding and particular USW process

Motivation for welding
Motivation for ultrasonic spot welding
Objective and scope of this dissertation
Structure of the dissertation
CHAPTER 2 LITERATURE REVIEW
Principles and fundamentals of USW
History of USW
USW equipment
Wedge-reed USW
Lateral-drive USW
Principles of USW
Applications of USW
Advantages of USW
Prior works in the area of USW
Welding of similar Mg Alloy
Microstructure, grain size and recrystallization
Crystallographic texture of welded Mg alloy
Fatigue behavior of welded Mg alloy
Welding of dissimilar alloys
Welding of dissimilar Mg-to-Al alloys
Welding of dissimilar Mg-to-steel alloys
Welding of dissimilar Al-to-steel alloys
Summary of the literature review
Experimental materials
Processing parameters of USW
Metallography
Quantitative image analysis
X-ray diffraction for phase identification
Temperature profile during USW
Crystallographic texture measurement
Microhardness test
3.10 Lap shear tensile test
3.11 Fatigue Test
CHAPTER 4 ULTRASONIC SPOT WELDING OF MAGNESIUM ALLOY*
Microstructure and grain size measurement
Relationship between Zener-Hollomon parameter and grain size
Shear strain rate calculation
Temperature measurement
Zener-Hollomon parameter analysis and calculation
Microhardness profile
Effects of USW on microhardness
Crystallographic texture of USWed Mg alloy
Crystallographic texture by X-ray diffraction profiles
Crystallographic texture by pole figures profiles
51 Dim ension
26 Color m ap: 2CTOhoDenFttaop:urorsje:ct
51 Contour7s16
76 Pr oje ction
Lap shear tensile strength of joints
Lap shear tensile fractography
Fatigue behavior and failure mode
Fatigue fractography
Fatigue life estimation
Global stress intensity factor solutions for main cracks
Local stress intensity factors solutions for kinked cracks
K II s in sin
A fatigue crack growth model
Applicability of the fatigue model
4.10. Summary
Microstructure
Energy-dispersive X-ray spectroscopy analysis
Microhardness
A AZ31B-H24 B
X-ray diffraction analysis
Summary
Energy-dispersive X-ray spectroscopy (EDS) analysis
C Composite like Eutectic layer of Sn
Energy dispersive spectroscopy analysis
B Galvanized HSLA Steel
Contribution
Findings
Major conclusions
Full Text
Published version (Free)

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call