Fundamentals of Welding and Welding Processes PDF

Summary

This document provides an overview of welding and welding processes, covering various types and applications. Topics discussed include fusion welding, solid-state welding, and the advantages and disadvantages of using welding.

Full Transcript

**Fundamentals of welding and welding processes**

The term joining is generally used for welding, brazing, soldering, and
adhesive bonding, which form a permanent joint between the parts -- a
joint that cannot easily be separated. The term assembly usually refers
to mechanical methods of fastening parts together, some of which allow
for disassembly, while others do not.

Welding is a materials-joining process in which two or more parts are
coalesced at their contacting surfaces by a suitable application of heat
and/ or pressure. Many welding processes are accomplished by heat alone,
with no pressure applied; others by a combination of heat and pressure;
and still others by pressure alone, with no external heat supplied. In
some welding processes, a filler material is added to facilitate
coalescence. The assemblage of parts that are joined by welding is
called a weldment.

Welding is most commonly associated with metal parts, but the process is
also used for joining plastics.

- Welding provides a permanent joint. The welded parts become a single
entity.

- The welded joint can be stronger than the parent materials if a
filler metal is used that has strength properties superior to those
of the parents, and if proper welding techniques are used.

- Welding is usually the most economical way to join components in
terms of material usage and fabrication costs. Alternative
mechanical methods of assembly require more complex shape
alterations (e.g., drilling of holes) and the addition of fasteners
(e.g., rivets or bolts). The resulting mechanical assembly is
usually heavier than a corresponding weldment.

- Welding is not restricted to the factory environment. It can be
accomplished "in the field."

Although welding has the advantages indicated above, it also has certain
limitations and drawbacks (or potential drawbacks):

- Many welding operations are performed manually and are expensive in
terms of labor cost. Most welding operations are considered "skilled
trades," and the labor to perform these operations many be scarce.

- Most welding processes are inherently dangerous because they involve
the use of high energy

- Because welding accomplishes a permanent bond between the
components, it does not allow for convenient disassembly. If the
product must occasionally be disassembled (e.g., for repair or
maintenance), then welding should not be used as the assembly
method.

- The welded joint can suffer from certain quality defects that are
difficult to detect. The defects can reduce the strength of the
joint.

Welding processes divide into two major categories: (1) fusion welding,
in which coalescence is accomplished by melting the two part surfaces to
be joined, in some cases adding filler metal to the joint; and (2)
solid-state welding, in which heat and/ or pressure are used to achieve
coalescence, but no melting of the base metals occurs and no filler
metal is added.

Fusion welding is by far the more important category. It includes (1)
arc welding, (2) resistance welding, (3) oxyfuel gas welding, and (4)
other fusion-welding processes -- those that cannot be classified as any
of the first three types.

**Overview of welding technology**

Welding involves localized coalescence or joining together of two
metallic parts at their faying surfaces. The faying surfaces are the
part surfaces in contact or close proximity that to be joined. Welding
is usually performed on parts made of the same metal, but some welding
operations can be used to join dissimilar metals.

**Types of welding processes**

Some 50 different types of welding operations have been catalogued by
the American welding society. They use various types or combinations of
energy to provide the required power. The welding processes can be
divided into major groups: (1) fusion welding and (2) solid-state
welding.

**Fusion welding**

These processes use heat to melt the base metals. In many fusion welding
operations, a filler metal is added to the molten pool to facilitate the
process and provide bulk and strength to the welded joint. A
fusion-welding operation in which no filler metal is added is referred
to as an autogenous weld. The fusion category includes the most widely
used welding processes, which can be organized into the following
general groups.

- Arc welding (AW). Arc welding refers to a group of welding processes
in which heating of the metals is accomplished by an electric arc,
as shown in figure 29.1. Some arc-welding operations also apply
pressure during the process and most utilize a filler metal.

Diagram of a welding process Description automatically generated

- Resistance welding (RW). Resistance welding achieves coalescence
using heat from electrical resistance to the flow of current passing
between the faying surfaces of two parts held together under
pressure.

- Oxyfuel gas welding (OFW). These joining processes use an oxyfuel
gas, such as a mixture of oxygen and acetylene, to produce a hot
flame for melting the base metal and filler metal, if one is used.

- Other fusion-welding processes. Other welding processes that produce
fusion of the metals joined include electron-beam welding and
laser-beam welding.

Certain arc and oxyfuel processes are also used to cut metals

**Solid-state Welding**

Solid-state welding refers to joining processes in which coalescence
results from the application of pressure alone or a combination of heat
and pressure. If heat is used, the temperature in the process is below
the melting point of the metals being welded. No filler metal is
utilized. Representative welding processes in this group include:

- Diffusion welding (DFW). Two surfaces are held together under
pressure at an elevated temperature and the parts coalesce by
solid-state diffusion.

- Friction welding (FRW). Coalescence is achieved by the heat of
friction between two surfaces.

- Ultrasonic welding (USW). Moderate pressure is applied between the
two parts and an oscillating motion at ultrasonic frequencies is
used in a direction parallel to the contacting surfaces. The
combination of normal and vibratory forces results in shear stresses
that remove surface films and achieve atomic bonding of the
surfaces.

**Welding as a commercial operation**

The principal applications of welding are (1) construction, such as
buildings and bridges; (2) piping, pressure vessels, boilers, and
storage tanks; (3) shipbuilding; (4) aircraft and aerospace; and (5)
automotive and railroad. Welding is performed in a variety of locations
and in a variety of industries. Owing to its versatility as an assembly
technique for commercial products, many welding operations are performed
in factories. However, several of the traditional processes, such as arc
welding and oxyfuel gas welding, use equipment that can be readily
moved, so these operations are not limited to the factory. They can be
performed at construction sites, in shipyards, at customers' plants, and
in automotive repair shops.

Most welding operations are labor-intensive. For example, arc welding is
usually performed by a skilled worker, called a welder, who manually
controls the path or placement of the weld to join individual parts into
a larger unit. In factory operations in which arc welding is manually
performed, the welder often works with a second worker, called a fitter.
The fitter's job is to arrange the individual components for the welder
prior to making the weld. Welding fixtures and positioners are used for
this purpose. A welding fixture is a device for clamping and holding the
components in fixed position for welding. It is custom-fabricated for
the particular geometry of the weldment and therefore must be
economically justified on the basis of the quantities of assemblies to
be produced. A welding positioner is a device that holds parts and also
moves the assemblage to the desired position for welding. This differs
from a welding fixture and only holds the parts in a single fixed
position. The desired position is usually one which the weld path is
flat and horizontal.