Solid State Welding Processes in Manufacturing Welding process Manufacturing, solid state welding processes in

Phenomenological Modeling of Fusion Welding Processes

MRS Bulletin ◽

10.1557/s0883769400038835 ◽

1994 ◽

Vol 19 (1) ◽

pp. 29-35 ◽

Cited By ~ 44

Author(s):

S.A. David ◽

T. DebRoy ◽

J.M. Vitek

Keyword(s):

Solid State ◽

Heat Source ◽

Base Metal ◽

Weld Pool ◽

Welding Process ◽

Poor Performance ◽

Consumer Products ◽

Phase Changes ◽

Fusion Welding ◽

Welding Processes

Welding is utilized in 50% of the industrial, commercial, and consumer products that make up the U.S. gross national product. In the construction of buildings, bridges, ships, and submarines, and in the aerospace, automotive, and electronic industries, welding is an essential activity. In the last few decades, welding has evolved from an empirical art to a more scientifically based activity requiring synthesis of knowledge from various disciplines. Defects in welds, or poor performance of welds, can lead to catastrophic failures with costly consequences, including loss of property and life.Figure 1 is a schematic diagram of the welding process showing the interaction between the heat source and the base metal. During the interaction of the heat source with the material, several critical events occur: melting, vaporization, solidification, and solid-state transformations. The weldment is divided into three distinct regions: the fusion zone (FZ), which undergoes melting and solidification; the heat-affected zone (HAZ) adjacent to the FZ, that may experience solid-state phase changes but no melting; and the unaffected base metal (BM).Creating the extensive experimental data base required to adequately characterize the highly complex fusion welding process is expensive and time consuming, if not impractical. One recourse is to simulate welding processes either mathematically or physically in order to develop a phenomenological understanding of the process. In mathematical modeling, a set of algebraic or differential equations are solved to obtain detailed insight of the process. In physical modeling, understanding of a component of the welding process is achieved through experiments designed to avoid complexities that are unrelated to the component investigated.In recent years, process modeling has grown to be a powerful tool for understanding the welding process. Using computational modeling, significant progress has been made in evaluating how the physical processes in the weld pool influence the development of the weld pool and the macrostructures and microstructures of the weld.

Solid State Welding Process for Aerospace Components

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.1119.597 ◽

2015 ◽

Vol 1119 ◽

pp. 597-600

Author(s):

Hyun Ho Jung ◽

Ye Rim Lee ◽

Jong Hoon Yoon ◽

Joon Tae Yoo ◽

Kyung Ju Min ◽

...

Keyword(s):

Friction Stir Welding ◽

Solid State ◽

Structural Integrity ◽

Welding Process ◽

Diffusion Welding ◽

Intimate Contact ◽

Friction Stir ◽

Base Materials ◽

Welding Processes ◽

And Diffusion

Since solid state welded joint is formed from an intimate contact between two metals at temperatures below the melting point of the base materials, the structural integrity of welding depends on time, temperature, and pressure. This paper provides some of examples of friction stir welding and diffusion welding process for aerospace components. Friction stir welding process of AA2195 was developed in order to study possible application for a large fuel tank. Massive diffusion welding of multiple titanium sheets was performed and successful results were obtained. Diffusion welding of dissimilar metals of copper and stainless steel was necessary to manufacture a scaled combustion chamber. Diffusion welding of copper and steel was performed and it is shown that the optimum condition of diffusion welding is 7MPa at 890°C, for one hour. It is shown that solid state welding processes can be successfully applied to fabricate lightweight aerospace parts.

Solid-state joining of aluminum to titanium: A review

Proceedings of the Institution of Mechanical Engineers Part L Journal of Materials Design and Applications ◽

10.1177/14644207211010839 ◽

2021 ◽

pp. 146442072110108

Author(s):

Vijay S Gadakh ◽

Vishvesh J Badheka ◽

Amrut S Mulay

Keyword(s):

Mechanical Properties ◽

Solid State ◽

Titanium Alloys ◽

Intermetallic Compounds ◽

Welding Process ◽

High Strength ◽

Weld Interface ◽

Fusion Welding ◽

Cp Ti ◽

Welding Processes

The dissimilar material joining of aluminum and titanium alloys is recognized as a challenge due to the significant differences in the physical, chemical, and metallurgical properties of these alloys, where the increasing demands for high strength and lightweight alloys in aerospace, defense, and automotive industries. Joining these two alloys using the conventional fusion techniques produces commercially unacceptable sound joints due to irregular, complex weld pool shapes, cracking and low strength, high residual stresses, cracks, and microporosity, and the brittle intermetallic compounds formation leads to poor formability or inferior mechanical properties. The formation of intermetallic compounds is inevitable but it is less severe in solid-state than in the fusion welding process. Hence, this article reviews on aluminum–titanium joining using different solid-state and hybrid joining processes with emphasis on the effect of process parameters of the different processes on the weld microstructure, mechanical properties along with the type of intermetallic compounds and defects formed at the weld interface. Among the various solid-state welding processes for aluminum–titanium joining, the following grades of aluminum and titanium alloys were employed such as cp Ti, Ti6Al4V, cp Al, AA1xxx, AA 2xxx, AA5xxx, AA6xxx, AA7xxx, out of which Ti6Al4V and AA6xxx alloys are the most common combination.

Comprehensive Analysis of the Microstructure and Mechanical Properties of Friction-Stir-Welded Low-Carbon High-Strength Steels with Tensile Strengths Ranging from 590 MPa to 1.5 GPa

Applied Sciences ◽

10.3390/app11125728 ◽

2021 ◽

Vol 11 (12) ◽

pp. 5728

Author(s):

HyeonJeong You ◽

Minjung Kang ◽

Sung Yi ◽

Soongkeun Hyun ◽

Cheolhee Kim

Keyword(s):

Mechanical Properties ◽

Tensile Test ◽

Joint Strength ◽

Solid Phase ◽

Welding Process ◽

High Strength Steels ◽

High Strength ◽

Low Carbon ◽

Friction Stir ◽

Welding Processes

High-strength steels are being increasingly employed in the automotive industry, requiring efficient welding processes. This study analyzed the materials and mechanical properties of high-strength automotive steels with strengths ranging from 590 MPa to 1500 MPa, subjected to friction stir welding (FSW), which is a solid-phase welding process. The high-strength steels were hardened by a high fraction of martensite, and the welds were composed of a recrystallized zone (RZ), a partially recrystallized zone (PRZ), a tempered zone (TZ), and an unaffected base metal (BM). The RZ exhibited a higher hardness than the BM and was fully martensitic when the BM strength was 980 MPa or higher. When the BM strength was 780 MPa or higher, the PRZ and TZ softened owing to tempered martensitic formation and were the fracture locations in the tensile test, whereas BM fracture occurred in the tensile test of the 590 MPa steel weld. The joint strength, determined by the hardness and width of the softened zone, increased and then saturated with an increase in the BM strength. From the results, we can conclude that the thermal history and size of the PRZ and TZ should be controlled to enhance the joint strength of automotive steels.

Microstructure and mechanical property improvement of dissimilar metal joints for TC4 Ti alloy to Nitinol NiTi alloy by laser welding

International Journal of Materials Research (formerly Zeitschrift fuer Metallkunde) ◽

10.1515/ijmr-2020-7935 ◽

2021 ◽

Vol 0 (0) ◽

Author(s):

Yan Zhang ◽

DeShui Yu ◽

JianPing Zhou ◽

DaQian Sun ◽

HongMei Li

Keyword(s):

Tensile Strength ◽

Laser Welding ◽

Mechanical Performance ◽

Niti Alloy ◽

Welding Process ◽

Ti Alloy ◽

The One ◽

Fusion Weld ◽

Welding Processes ◽

Cu Interlayer

Abstract To avoid the formation of Ti-Ni intermetallics in a joint, three laser welding processes for Ti alloy–NiTi alloy joints were introduced. Sample A was formed while a laser acted at the Ti alloy–NiTi alloy interface, and the joint fractured along the weld centre line immediately after welding without filler metal. Sample B was formed while the laser acted on a Cu interlayer. The average tensile strength of sample B was 216 MPa. Sample C was formed while the laser acted 1.2 mm on the Ti alloy side. The one-pass welding process involved the creation of a joint with one fusion weld and one diffusion weld separated by the remaining unmelted Ti alloy. The mechanical performance of sample C was determined by the diffusion weld formed at the Ti alloy–NiTi alloy interface with a tensile strength of 256 MPa.

Advanced submerged arc welding processes for Arctic structures and ice-going vessels

Proceedings of the Institution of Mechanical Engineers Part B Journal of Engineering Manufacture ◽

10.1177/0954405416636037 ◽

2016 ◽

Vol 232 (1) ◽

pp. 114-127

Author(s):

Pavel Layus ◽

Paul Kah ◽

Viktor Gezha

Keyword(s):

Case Studies ◽

Arc Welding ◽

Oil And Gas ◽

Welding Process ◽

Submerged Arc Welding ◽

The Arctic ◽

Correct Selection ◽

Advantages And Disadvantages ◽

Welding Processes ◽

Submerged Arc

The Arctic region is expected to play an extremely prominent role in the future of the oil and gas industry as growing demand for natural resources leads to greater exploitation of a region that holds about 25% of the world’s oil and gas reserves. It has become clear that ensuring the necessary reliability of Arctic industrial structures is highly dependent on the welding processes used and the materials employed. The main challenge for welding in Arctic conditions is prevention of the formation of brittle fractures in the weld and base material. One mitigating solution to obtain sufficiently low-transition temperatures of the weld is use of a suitable welding process with properly selected parameters. This work provides a comprehensive review with experimental study of modified submerged arc welding processes used for Arctic applications, such as narrow gap welding, multi-wire welding, and welding with metal powder additions. Case studies covered in this article describe welding of Arctic steels such as X70 12.7-mm plate by multi-wire welding technique. Advanced submerged arc welding processes are compared in terms of deposition rate and welding process operational parameters, and the advantages and disadvantages of each process with respect to low-temperature environment applications are listed. This article contributes to the field by presenting a comprehensive state-of-the-art review and case studies of the most common submerged arc welding high deposition modifications. Each modification is reviewed in detail, facilitating understanding and assisting in correct selection of appropriate welding processes and process parameters.

Numerical Analysis of Residual Stresses and Distortions in Aluminium Alloy Welded Joints

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.809-810.443 ◽

2015 ◽

Vol 809-810 ◽

pp. 443-448 ◽

Cited By ~ 3

Author(s):

Tomasz Kik ◽

Marek Slovacek ◽

Jaromir Moravec ◽

Mojmir Vanek

Keyword(s):

Finite Element Method ◽

Finite Element ◽

Aluminium Alloy ◽

Thermal Cycle ◽

Technology Development ◽

Welding Process ◽

Simulation Software ◽

Structure Knowledge ◽

Welding Processes ◽

Element Method

Simulation software based on a finite element method have significantly changed the possibilities of determining welding strains and stresses at early stages of product design and welding technology development. But the numerical simulation of welding processes is one of the more complicated issues in analyses carried out using the Finite Element Method. A welding process thermal cycle directly affects the thermal and mechanical behaviour of a structure during the process. High temperature and subsequent cooling of welded elements generate undesirable strains and stresses in the structure. Knowledge about the material behaviour subjected to the welding thermal cycle is most important to understand process phenomena and proper steering of the process. The study presented involved the SYSWELD software-based analysis of MIG welded butt joints made of 1.0 mm thickness, 5xxx series aluminium alloy sheets. The analysis of strains and the distribution of stresses were carried out for several different cases of fixing and releasing of welded elements.

Microstructural Effects between AHSS Dissimilar Joints Using MIG and TIG Welding Process

MRS Proceedings ◽

10.1557/opl.2015.409 ◽

2015 ◽

Vol 1766 ◽

pp. 29-35 ◽

Cited By ~ 1

Author(s):

G.Y. Pérez Medina ◽

M. Padovani ◽

M. Merlin ◽

A.F. Miranda Pérez ◽

F.A. Reyes Valdés

Keyword(s):

Arc Welding ◽

Gas Metal Arc Welding ◽

Welding Process ◽

High Hardness ◽

Inert Gas ◽

Mechanical Degradation ◽

Low Alloy Steels ◽

Dissimilar Joints ◽

Lap Shear ◽

Welding Processes

ABSTRACTGas tungsten arc welding-tungsten inert gas (GTAW-TIG) is focused in literature as an alternative choice for joining high strength low alloy steels; this study is performed to compare the differences between gas metal arc welding-metal inert gas (GMAW-MIG) and GTAW welding processes. The aim of this study is to characterize microstructure of dissimilar transformation induced plasticity steels (TRIP) and martensitic welded joints by GMAW and GTAW welding processes. It was found that GMAW process lead to relatively high hardness in the HAZ of TRIP steel, indicating that the resultant microstructure was martensite. In the fusion zone (FZ), a mixture of phases consisting of bainite, ferrite and small areas of martensite were present. Similar phase’s mixtures were found in FZ of GTAW process. The presence of these mixtures of phases did not result in mechanical degradation when the GTAW samples were tested in lap shear tensile testing as the fracture occurred in the heat affected zone. In order to achieve light weight these result are benefits which is applied an autogenous process, where it was shown that without additional weight the out coming welding resulted in a high quality bead with homogeneous mechanical properties and a ductile morphology on the fracture surface. Scanning electron microscopy (SEM) was employed to obtain information about the specimens that provided evidence of ductile morphology.

Part Repairing Using a Hybrid Manufacturing System

ASME 2007 International Manufacturing Science and Engineering Conference ◽

10.1115/msec2007-31003 ◽

2007 ◽

Cited By ~ 3

Author(s):

Lan Ren ◽

Kunnayut Eiamsa-ard ◽

Jianzhong Ruan ◽

Frank Liou

Keyword(s):

Manufacturing System ◽

Energy Savings ◽

Welding Process ◽

Hybrid Manufacturing ◽

Present Part ◽

Cutting Processes ◽

Main Component ◽

Time And Energy ◽

The Military ◽

Welding Processes

At present, part remanufacturing technology is gaining more interest from the military and industries due to the benefits of cost reduction as well as time and energy savings. This paper presents the research on one main component of part remanufacturing technology, which is part repairing. Traditionally, part repairing is done in the repair department using welding processes. However, the limitations of the traditional welding process are becoming more and more noticeable when accuracy and reliability are required. Part repairing strategies have been developed utilizing a hybrid manufacturing system in which the laser-aided deposition and CNC cutting processes are integrated. Part repairing software is developed in order to facilitate the users. The system and the software elevate the repairing process to the next level, in which accuracy, reliability, and efficiency can be achieved. The concept of the repairing process is presented in this paper, and verification and experimental results are also discussed.

Welding Procedure Establishment for Tubular Joints Welded by Single Station, Solid State Welding Machine

ASME 2010 Pressure Vessels and Piping Conference: Volume 6, Parts A and B ◽

10.1115/pvp2010-25626 ◽

2010 ◽

Author(s):

Ganesan S. Marimuthu ◽

Per Thomas Moe ◽

Bjarne Salberg ◽

Junyan Liu ◽

Henry Valberg ◽

...

Keyword(s):

Solid State ◽

Oil And Gas ◽

Welding Process ◽

High Strength ◽

Pipe Material ◽

Tubular Joints ◽

Welding Machine ◽

Single Station ◽

Welding Procedure ◽

Treatment Procedures

Forge welding is an efficient welding method for tubular joints applicable in oil and gas industries due to its simplicity in carrying out the welding, absence of molten metal and filler metals, small heat-affected zone and high process flexibility. Prior to forging, the ends (bevels) of the joining tubes can be heated by torch or electromagnetic (EM) techniques, such as induction or high frequency resistance heating. The hot bevels are subsequently pressed together to establish the weld. The entire welding process can be completed within seconds and consistently produces superior quality joints of very high strength and adequate ductility. Industrial forge welding of tubes in the field is relatively expensive compared to laboratory testing. Moreover, at the initial stages of a new project sufficient quantities of pipe material may not be available for weldability testing. For these and several other reasons we have developed a highly efficient single station, solid state welding machine that carefully replicates the thermomechanical conditions of full-scale Shielded Active Gas Forge Welding Machines (SAG-FWM) for pipeline and casing applications. This representative laboratory machine can be used to weld tubular goods, perform material characterization and/or simulate welding and heat treatment procedures. The bevel shapes at mating ends of the tubes are optimized by ABAQUS® simulations to fine tune temperature distribution. The main aim of this paper is to establish a welding procedure for welding the tubular joints by the representative laboratory machine. The quality of the welded tubular joint was analyzed by macro/micro analyses, as well as hardness and bend tests. The challenges in optimizing the bevel shape and process parameters to weld high quality tubular joints are thoroughly discussed. Finally a welding procedure specification was established to weld the tubular joints in the representative laboratory machine.