Metal Joining 3 PDF

Summary

This document details various metal joining techniques, including oxyacetylene welding, pressure gas welding, and their associated metallurgical principles. It explains the roles of fluxes, the compatibility of different materials with various welding processes, and the impact of thermal stresses on the weld. It also explores various types of cracks and how to prevent them.

Full Transcript

METAL JOINING 3
CONTENTS
Oxyacetylene welding with filler rods
Flux? What is its role
Compatibility of oxyacetylene welding with different materials
Pressure gas welding
Welding metallurgy-grain structure and residual stress
Weldability/ joinability
Oxy acetylene welding with consumable electrode

Welding rods come in standard sizes, with diameters from 1.5 to 9.5mm ( 1/16 to
3/8 in.) and lengths from 0.6 to 0.9m(24 to 36 in.).

https://www.youtube.com/watch?v=PbJ6KnV3oFc
Filler rod/ wire. They may be bare/ coated with flux and its role
Functions of a flux
To promote the formation of a better bond, fluxes may be used to clean the surfaces
and remove contaminating oxide.
In addition, the gaseous shield produced by vaporizing flux can prevent further oxidation during the
welding process,
and the slag produced by solidifying flux can protect the weld pool as it cools.
Flux can be added as a powder, the welding rod can be dipped in a flux paste, or the rods can be
precoated.
The flux ingredients are usually: calcium, calcium carbonate, calcium fluoride, magnesium, potassium and
manganese oxides, sodium, silica, and aluminium oxide. The flux ingredients come together to help stabilize the
arc and have more control over the mechanical properties.

Advantages oxy fuel welding process

Oxyfuel equipment is quite portable, relatively inexpensive, and
extremely versatile.
A single set of equipment can be used for welding, brazing, and
soldering, and as a heat source for bending, forming, straightening, and
hardening.
With the modifications to be discussed shortly, it can also perform flame
cutting.
Pressure gas welding
Heating effects: welding metallurgy
Welding metallurgy helps determine the structure and properties across the joint and the need for additional
thermal treatments.

The molten pool is actually a complex alloy of all four materials.

a small metal casting in a large metal mold

a metal casting in a metal mold,
coupled with an abnormal and widely varying heat treatment
Adequate mechanical properties, therefore, can only be
achieved by selecting filler rods or electrodes
filler rod compositions tend to produce fine, equiaxed grains.

Weld pool suffers from defects such as
gas porosity, inclusions, blowholes,
cracks, and shrinkage.
Heat affected zone experiences sufficient heat to bring about structure and property changes,
Phase transformations, recrystallization, grain growth, precipitation or
precipitate coarsening, embrittlement, or even cracking.
Weakest area in the as-welded joint.

The size of the heat-affected zone will also increase with
increased starting temperature, decreased welding speed,
low rates of heat input, slow cooling rate, large area of HAZ increased thermal conductivity of the base metal, and a
decrease in base metal thickness. Weld geometry is also
High heat input, faster cooling rate, small area of HAZ
important, with fillet welds producing smaller heat-affected
zones than butt welds.
THERMAL-INDUCED RESIDUAL STRESSES

If the welded plates in Figure 30-15a are restrained from horizontal
movement, additional stresses will be induced. These residual stresses are
known as reaction stresses, and they can cause cracking of the hot weld
or heat-affected material or can contribute to failure during subsequent use.
EFFECTS OF THERMAL STRESSES -Total heat input to the weld should be minimized
- Shot peening/Surface rolling
When a multipass weld is being made, cracking tends to occur in the early beads where there is
insufficient weld metal to withstand the shrinkage stresses.

Crack-prevention efforts can also include maintaining the proper
size and shape of the weld bead.

cooling more uniform or relaxing the stresses by promoting plasticity in the metals
being welded.

Hydrogen dissolved in the molten weld metal can also induce cracking
 WELDABILITY OR JOINABILITY
Within a given process, the quality of results may vary greatly with variations in the process parameters,
such as electrode material, shielding gas, welding speed, and cooling rate.
References:
1. Kalpakjian S and Schmid S R, Manufacturing Processes for Engineering Materials, 6th Edition, Pearson Education,
2018.
2. J.T Black and Ronald A. Kohser, Degarmo’s Materials and Processes in Manufacturing,11th Edition, John Wiley
and Sons,2012