Solid-State Welding Processes
Chapter 31 Solid-State Welding Processes
Roll Bonding Figure 31.1 Schematic illustration of the roll bonding or cladding process.
Ultrasonic Welding Figure 31.2 (a) Components of an ultrasonic welding machine for making lap welds. The lateral vibrations of the tool tip cause plastic deformation and bonding at the interface of the workpieces. (b) Ultrasonic seam welding using a roller as the sonotrode.
Friction Welding Figure 31.3 (a) Sequence of operations in the friction welding process: (1) Left-hand component is rotated at high speed. (2) Righthand component is brought into contact under an axial force. (3) Axial force is increased; flash begins to form. (4) Left-hand component stops rotating; weld is completed. The flash can subsequently be removed by machining or grinding. Figure 31.4 Shape of the fusion zones in friction welding, as a function of the axial force applied and the rotational speed.
Friction Stir Welding Figure 31.4 The principle of the friction stir welding process. Alluminum-alloy plates up to 75 mm (3 in.) thick have been welded by this process.
Spot Welding Figure 31.6 (a) Sequence of events in resistance spot welding. (b) Cross-section of a spot weld, showing the weld nugget and the indentation of the electrode on the sheet surfaces. This is one of the most commonly used processes in sheet-metal fabrication and in automotive-body assembly.
Spot Welding Configurations Figure 31.7 (a) Schematic illustration of an airoperated, rocker-arm, spot welding machine. (b) and (c) Two electrode designs for easy access into components to be welded. Figure 31.8 Two electrode designs for easy access to the components to be welded.
Spot Welding Figure 31.9 (a) and (b) Spot-welded cookware and muffler. (c) An automated spotwelding machine with a programmable robot; the welding tip can move in three principal directions. Sheets as large as 2.2 m 0.55 m (88 in. 22 in.) can be accommodated in this machine. Source: Courtesy of Taylor–Winfield Corporation.
Spot Weld Testing Figure 31.10 Test methods for spot welds: (a) tension-shear test, (b) cross-tension test, (c) twist test, (d) peel test. (see also Fig. 32.9).
Seam Welding Figure 31.11 (a) Seam-welding process in which rotating rolls act as electrodes; (b) overlapping spots in a seam weld; (c) roll spot welds; (d) mash-seam welding.
High-Frequency Butt Welding Figure 31.12 Two methods of high-frequency continuous butt welding of tubes.
Resistance Projection Welding Figure 31.13 (a) Schematic illustration of resistance projection welding. (b) A welded bracket. (c) and (d) Projection welding of nuts or threaded bosses and studs. (e) Resistance-projection-welded grills.
Flash Welding Figure 31.14 (a) Flash-welding process for end-to-end welding of solid rods or tubular parts. (b) and (c) Typical parts made by flash welding. (d) Some design guidelines for flash welding.
Stud Welding Figure 31.15 The sequence of operations in stud welding, commonly used for welding bars, threaded rods, and various fasteners onto metal plates.
Weld Sizes Figure 31.16 The relative sizes of the weld beads obtained by tungsten-arc and by electron-beam or laser-beam welding.
Explosion Welding Figure 31.17 Schematic illustration of the explosion welding process: (a) constant interface clearance gap and (b) angular interface clearance gap; (c) cross-section of explosion-welded joint; titanium (top) and low-carbon steel (bottom); (d) ironnickel alloy (top) and low-carbon steel.
Aerospace Diffusion Bonding Applications Figure 31.18 Aeropspace diffusion bonding applications.
Diffusion Bonding and Superplastic Forming Figure 31.19 The sequence of operations in the fabrication of a structure by diffusion bonding and superplastic forming of three, originally flat sheets. Sources: (a) After D. Stephen and S.J. Swadling. (b) and (c) Rockwell International Corp.
Roll Bonding Figure 31.1 Schematic illustration of the roll bonding or cladding process.
Ultrasonic Welding Figure 31.2 (a) Components of an ultrasonic welding machine for making lap welds. The lateral vibrations of the tool tip cause plastic deformation . Typical parts made by flash welding. (d) Some design guidelines for flash welding. Stud Welding Figure 31.15 The sequence of operations in stud welding, commonly used for .
6.3 Mechanised/automatic welding 114 6.4 TIG spot and plug welding 115 7 MIG welding 116 7.1 Introduction 116 7.2 Process principles 116 7.3 Welding consumables 130 7.4 Welding procedures and techniques 135 7.5 Mechanised and robotic welding 141 7.6 Mechanised electro-gas welding 143 7.7 MIG spot welding 144 8 Other welding processes 147 8.1 .
affected zone. Welding processes that are commonly used with the corrosion-resistant alloys are shown in Table 1. In addition to these common arc welding processes, other welding processes such as plasma arc welding, resistance spot welding, laser beam welding, electron beam welding, and submerged arc welding can be used. Because of
the welding processes most often used in today's industry including plasma arc cutting, oxyfuel gas cutting and welding, Gas Metal Arc Welding (GMAW), Flux-Cored Arc Welding (FCAW), Shielded Metal Arc Welding (SMAW), and Gas Tungsten Arc Welding (GTAW). Flat welding positions and basic joints will be practiced. Pipe and tube welding
Welding Processes Fusion welding - coalescence is accomplished by melting the two parts to be joined, in some cases adding filler metal to the joint Examples: arc welding, resistance spot welding, oxyfuel gas welding Solid state welding - heat and/or pressure
10.6 Braze-welding 460 Exercises 466 11 Joining processes (welding) 467 11.1 Fusion welding 468 11.2 Oxy-acetylene welding 468 11.3 Manual metal-arc welding 490 11.4 Workshop testing of welds 504 11.5 Miscellaneous fusion welding processes 506 11.6 Workholding devices for fusion welding 509 11.7 Resistance welding 515
welding. Since my M.Tech. thesis work is on Friction stir welding (FSW), a solid state welding process so now onwards, FSW will only be explained in detail. Friction Stir Welding: Friction stir welding (FSW) is an emerging, energy efficient, attractive and eco-friendly solid state welding process invented in 1991 in England [4].
seam butt welding resistance butt welding flash butt welding resistance butt welding shielded unshielded other process plasma laser resistance butt welding inert gas welding submerged arc welding atomic hydrogen shielded metal arc welding (coated electrode) esepl w w w . e u r e k a e l e c t r o d e s .
3. Classification of Underwater Welding Underwater welding may be divided into two main types: a) Wet welding b) Dry welding Fig. 3.1 Classification of underwater welding 3.1 Wet welding 3.1.1. Wet welding with coated electrode Wet welding is performed at ambient pressure with the welder-diver in the water and no physical barrier
