Q: I have a small, 120V input power wire feeder / welder in my shop, which I use for MIG welding on mild steel. I have a new fabrication job on 16 gauge 304 grade stainless steel sheet metal and am wondering if I can use this same welder for stainless steel MIG welding? If so, how do you set up the welder?
A: First, note that a 304 grade is an austenitic type of stainless steel. Therefore, this article will only address this type. While austenitic stainless steels are very common, there are also ferritic, martensitic, duplex and precipitation hardening types of stainless steels.
Finally, stainless steel’s main attribute is its corrosion resistance (i.e., it does not rust like carbon steel). This property is achieved with much higher levels of alloys in the base material (namely chromium and nickel). However, these higher levels of alloys also decrease the weldability of stainless steel, in that it has a more sluggish or ropy weld bead characteristic.
Now translate these property differences into the various parameters needed in order to MIG weld stainless steel. First, the machine should be set on DC+ (direct current positive) polarity. Regarding wire feed speed and voltage settings, most of these compact MIG welders have a recommended settings chart on the door. However, the chart may not have settings for stainless steel. If not, or if none are found in the machine’s instruction manual, then as a starting point use the chart’s recommended settings for carbon steel, based on the thickness of the stainless steel sheet metal in which you are welding. Then adjust the settings from there to fine tune the weld. In general, you will likely need to run a little higher wire feed speed rate than used with mild steel, but which will still likely result in a little lower current level. In addition, you will likely need to use higher voltage settings, which will help wet out the puddle more, giving a flatter face and better wash-in at the toes of the weld.
Note that the short circuit mode of metal transfer is a lower arc energy or lower heat input process, compared to other arc welding processes. While it helps reduce the chances of burn-through on sheet metal, it also produces a colder, ropier weld bead. With stainless steel welding, the issue is compounded by the fact that stainless steel has a more sluggish weld bead (as discussed already). Therefore, the recommended shielding gas to use for short circuit stainless steel MIG welding is a tri-mix shielding gas, such as 90%He/7.5%Ar/2.5%CO2. The high thermal conductivity of helium helps provide a flatter weld bead and good fusion into the base plate. While high helium blends can be more expensive than other types of shielding gases, the high percentage of helium in the mix helps counteract the cold, sluggish bead characteristics. Another acceptable shielding gas mix for short circuit stainless steel MIG welding is 98%Ar/2%O2 (or an equivalent 98%Ar/2%CO2). This latter mix produces a colder weld than the helium tri-mix and therefore the molten weld puddle does not wet out as well. However, welding characteristics are still acceptable and generally the cost of the gas mix is less than the helium tri-mix, as well as more readily available.
With both these stainless steel gas mixes the minor gases in the blend are required to provide good arc starting characteristics. Therefore, you do not want to use a completely inert shielding gas, such as 100% helium or 100% argon for stainless steel MIG welding. The arc characterisitcs would be poor. Note: Do not confuse this recommendation with the recommended shielding gases for the Gas Tungsten Arc Welding or TIG process, which is 100% argon or 100% helium (or a mix of the two) for any type of base metal, including stainless steel. The arc dynamics are quite different with the TIG process than with the MIG process. In addition, you do not want to use the same type of shielding gas that you use with carbon steel wire, such as 75%Ar/25%CO2 or 100%CO2. Both carbon and oxygen from the shielding gas react with the stainless steel in the heat of the arc, resulting in some oxidization and reduction in corrosion resistance. The maximum level of oxygen or carbon dioxide that should be used in a shielding gas mix with stainless steel is 3% or 5% respectively.