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Stainless steel alloys usually have a chromium
content of a least 10%. Stainless steel base metals are
grouped primarily into three classes depending on their
crystal structure; austenitic (such as 302, 304,
308, 316, etc.), martensitic (such as 410, and 416),
and ferritic (such as 409, and 430.). Austenitic
grades are also available with a lowered carbon content
(designated with an "L", such as 304L or 316L.)
Below is a basic step by step guide to follow
when welding Stainless Steel:
#1. Safety First
Warning: Protect yourself & others. Read & understand
this information.
Fumes & Gases can be hazardous to your health.
Electric Shock can kill.
- Before use, read & understand the manufacturer's
instructions, Material Safety Data Sheets (MSDS) & your
employer's safety practices.
- Keep your head out of the fumes.
- Use enough ventilation; exhaust at the
arc, or both, to keep fumes & gases from your breathing
zone & the general area.
- Wear correct eye, ear, & body protection.
- Do not touch live electrical parts.
- See American National Standard Z49.1, Safety
in Welding, Cutting, & Allied Processes, published by
the American Welding Society, 550 N.W. LeJeune Road, Miami,
FL 33126; OSHA Safety & Health Standards, available from
the U.S. Government Printing Office, Washington, DC 20402
#2. Select Joint Design & Fit up
Start by determining the best manner in which to join your
base metals. Correct joint design & fit up are critical
steps to insuring a strong bond upon weld completion. Be
sure to consider strength required, welding position, metal
thickness & joint accessibility.
The five basic types of joints are butt, corner,
edge, lap & t. These five joints can be arranged in
many combinations to create a large variety of welds. Fixtures
& jigs are helpful in securing the work pieces in place
during the joining procedure. Sheet metal & most fillet
& lap joints should be clamped tightly over the entire length
of the work.
#3. Choose The Welding Process
The three most common stainless welding processes are:
- SMAW - Shielded
Metal Arc Welding or Stick Electrode
SMAW is an electric arc welding process
in which heat for welding is generated by an electric
arc between a covered metal electrode & the base metal.
The electrode coating provides shielding. The welding
equipment for this process is currently the most inexpensive
of the methods described here. However, electrodes do
create some inefficiency, such as stub loss & a slag
coating, which must be removed.
- GTAW - Gas Tungsten
Arc Welding-Tig Welding
Tig Welding is easily performed on a variety
of metals. It generally requires little or no post weld
finishing. It is an electric welding process in which
heat for welding is generated by an electric arc between
the end of a non-consumable tungsten electrode & the
base metal. Filler metal may be added, if necessary.
An inert shielding gas supplies shielding for the arc.
(Inert gas creates a protective atmosphere around the
welding in process).
- FCAW - Flux Cored
Arc Welding-Mig Welding
Flux is contained within the electrode.
It provides shielding, deoxidization & arc stabilization.
Additional shielding may be added. A smoke suction nozzle
around the gun or fume hood aids in reduction of smoke
& fumes. Aufhauser flux cored stainless steel wire is
formulated to provide all position welding & smooth,
stable arc action.
- GMAW - Gas Metal
Arc Welding-Mig Welding
Gas metal arc welding is quick & easy
on thin-gauge metal as well as heavy plate. It generally
calls for little post weld cleanup. GMAW is an electric
arc welding process where heat is produced by an arc
between a continuously fed filler metal electrode &
the base metal. Shielding is obtained from an externally
supplied gas or gas mixture. The two most common types
of GMAW are:
Short Circuit Transfer - The
arc is broken or short circuited with each drop of metal
& restarted. It is used on smaller, thinner gauges & produces
a shallow weld.
Spray Transfer - Metal is transferred
across the arc creating a continuous spray of fine droplets
of metal. These droplets are projected down to the base
metal.
#4. Determine appropriate inert Shielding
Gas
SMAW - none required
GTAW - Argon is suggested for thicknesses up to approximately
1/2". For thicker sections, argon-helium mixtures or pure
helium may be used. Pure helium may also be employed for
deeper penetration. The most common tungsten utilized is
2% thoriated.
FCAW - 100% CO2 or Argon/CO2
The voltage may be somewhat lower if argon with 20 to 25
percent CO2 mixtures is selected. Generally,
a gas flow rate of 40 cfh is suggested. Adjustments can
be made, depending upon the specifics of the application.
GMAW - Spray Transfer Ð Use Argon & 1% to 2% - Oxygen
99% argon, 1% oxygen is predominantly used - 98% argon,
2% oxygen when welding thinner material.
Short Circuiting Transfer - 90% helium,
7.5% argon, 2.5% CO2
#5. Select The Applicable Filler Metal
For applications where both pieces are the same alloy, select
filler metal with a composition similar to that of the base
metals. This will ensure the weld has similar properties.
Dissimilar base metal applications require selection based
on mechanical properties, freedom from cracking, and compatibility.
#6. Set The Parameters
SMAW - uses a direct current (DC) or an alternating
current (AC).
DC uses either straight polarity, which
is electrode negative or reverse polarity, which is electrode
positive. Direct current flows in one direction continuously
through the welding circuit. There are several advantages
of DC. It works well at low current settings & with small
diameters. In addition, igniting the arc & maintaining a
short arc is easier.
Stainless electrodes designated Ð15, (ex:
308-15) use direct current, reverse polarity. Their key
characteristic is fast freezing slag, which make them suitable
for out of position welding. Bead appearance is convex.
AC uses a combination of both straight
& reverse polarities, which alternate in regular cycles.
The advantages of this current include: less
chance of arc blow, which is an unbalance of the magnetic
field around the arc causing a bend in the arc. It also
works well on thick metal with a large diameter electrode.
Stainless electrodes designated Ð16 (ex. 308-16)
use AC or DC. They produce a smooth weld bead, with a flat
to slightly convex bead appearance.
AMPS - The most common settings are:
| Diameter |
1/16
x 12" |
5/64
x 12" |
3/32
x 12" |
1/8
x 14" |
5/32
x 14" |
3/16
x 14" |
1/4
x 14" |
| Amps: |
15
– 40 |
30
– 60 |
50
– 80 |
70
– 110 |
100
– 140 |
130
– 180 |
175
– 220 |
GTAW - For gas
tungsten arc welding use DC current with straight polarity
(electrode negative). The parameters for Tig welding are
dependent upon plate thickness & welding position.
FCAW - Flux cored
stainless steel welding wire generally uses direct current,
reverse polarity (electrode positive). This current type
provides better base metal penetration. Flux cored welding
requires a longer wire extension or "stick out." Stick out
is the distance between the end of the wire and the end
of the contact tip. Stick out for stainless steel flux cored
wire is typically 5/8" to 3/4".
GMAW - Below
are suggested settings for GMAW welding;
Short Circuiting
Transfer:
| Electrode
Diameter, inches |
Welding
Current,
Amperage |
Arc
Voltage |
Wire
Feed
Speed, ipm |
0.030
0.035
0.045 |
60
- 125
75 - 160
100 - 200 |
17
- 22
17 - 22
17 - 22 |
150
- 430
120 - 400
100 - 240 |
Settings based
on 90He 71/2 Ar, 21/2 CO2 shielding gas. Flow
rate 20cfh.
| Electrode
Diameter, inches |
Welding
Current,
Amperage |
Arc
Voltage |
Wire
Feed
Speed, ipm |
0.030
0.035
0.045 |
60
- 125
75 - 160
100 - 200 |
17
- 22
17 - 22
17 - 22 |
150
- 430
120 - 400
100 - 240 |
Settings based
on 90He 71/2 Ar, 21/2 CO2 shielding gas. Flow
rate 20cfh.
Spray Transfer:
| Electrode
Diameter, inches |
Welding
Current,
Amperage |
Arc
Voltage |
Wire
Feed
Speed, ipm |
0.030
0.035
0.045
1/16
3/32 |
160
- 225
180 - 300
200 - 450
220 - 500
250 - 600 |
24
- 28
24 - 29
24 - 30
24 - 32
24 - 32 |
440
- 650
430 - 500
220 - 400
110 - 210
50 - 80 |
Settings based
on Ar, 1 to 5 O2 shielding gas.
#7. Clean The Base
Metal
Cleaning should be done just prior to welding to prevent
the formation of oxides. The base metal surface must be
free of grease, oil, paint, dirt, etc. A clean surface will
provide a smoother, stronger joint. Brush the plate surface
& edges with a stainless steel wire brush to remove burrs
& oxides. Gloves should be worn to prevent hand oil or dirt
from getting on the joining surface.
#8. Preheat If Applicable
Preheat is not required for most 300 austenitic grade stainless
steels. The base metal should be brought to room temperature,
60 to 75 degrees. Preheat is necessary when welding ferritic
or martensitic grades. It is also needed when joining metals
that are thick or contain a high percentage of carbon.
#9. Welding Technique
A good welding technique is developed as a welder gains
experience. The following are basic welding tips:
- Use fixtures &/or
jigs to help keep work in place.
- Butting edges should
be squared. A square butt joint is prevalently used for
stainless sheets 18 gauge or thinner. Heavier gauge sheets
& plates may require an edge bevel to assure full penetration.
- Insure adequate shielding
by centering the filler metal in the gas & weld puddle
area.
- Filler metal should
be dipped into the weld puddle, but should not drip into
it.
- Move the torch/gun
along the joint at a steady, constant speed to maintain
uniformity.
- Hold the torch/gun
over the weld until gas stops, to keep work protected.
#10. Cooling/Post
Weld Cleaning
Postheat may be required to relieve internal stresses caused
by the concentration of heat in the weld area. Postheating
aids in slow down of the cooling process to minimize cracking.
This is a good procedure to use when joining thick metals.
Shielded metal arc and flux cored welding leaves a slag
residue on the weld. Remove slag with a chipping hammer
or by grinding.
#11. Troubleshooting
Look in our Technical Support Index for troubleshooting.
#12. Aufhauser Stainless
Steel Filler Metals
Aufhauser manufactures a complete line of filler metals
for stainless steel welding.
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