Troubleshooting Mig Welding of Aluminum
Aluminum offers numerous benefits to OEMs—high strength-to-weight ratio, corrosion resistance and high thermal and electrical conductivity—that make it one of the most specified materials in the welding industry. However, welding with aluminum presents some unique challenges to fabricators, including a tenacious oxide layer, vastly different compositions among alloys, the need to use a less rigid filler metal, and the need for very clean base metal. Selecting the right type of welding filler metal, consumables and equipment, as well as quick troubleshooting, can help mitigate these issues.
To minimize downtime and enhance productivity in the weld shop, this article looks at some of the most common issues welding operators face when gas-metal-arc welding (GMAW, mig) aluminum. We also discuss tips to prevent those problems, or to quickly address them if they occur.
Welding aluminum presents some unique challenges. Take care to select the right type of filler metal, consumables and equipment, and take steps to ensure quick trouble-shooting of any problems that arise.
How to Avoid Hot Cracking
Cracking is one of the most critical issues that can occur in aluminum weldments. Even small cracks can prevent welds from meeting code requirements and can eventually lead to weld failure. Most aluminum alloys, however, can be successfully welded without experiencing cracking-related problems. Using the most appropriate filler metal and completing the weld with the appropriate procedure are important to success.
While there are two types of cracking—hot cracking and stress cracking—hot cracking is the more common of the two experienced when welding aluminum. Hot cracking mainly is a function of weld composition, which impacts how the weld metal solidifies.
Three factors can significantly influence the probability for hot cracking in aluminum welding:
1) The susceptibility of the base-material composition to cracking;
2) The selection of the most appropriate filler metal to help prevent the formation of a crack-sensitive composition; and
3) Selecting the most appropriate weld-joint design to dilute the base metal and help avoid a crack-sensitive weld composition.
Because some aluminum alloys are more susceptible to cracking than others, it’s important to select a filler metal that will result in weldmetal composition with low crack sensitivity. When welding aluminum that has low crack sensitivity, als use a filler metal of similar composition. Conversely, when welding aluminum with high crack sensitivity, select a filler metal with a different composition that will deposit a weld with low crack sensitivity.
Aluminum filler metals are identified by a numerical American Welding Society (AWS) classification that corresponds to the Aluminum Association registration number identifying the particular alloy composition. Not all filler metals are suitable for welding all aluminum base alloys. Reference a reputable filler-metal selection guide to make the best choice for welding different aluminum alloys.
While not as common as hot cracking, stress cracking also can affect aluminum welds. A primary cause of stress cracking: excessive shrinkage rates during weld solidification and cooling. Selecting a filler metal containing silicon, when appropriate, can reduce shrinkage stresses to help avoid stress cracks.
Most cracks in aluminum welds appear in the crater (defined as an undesirable depression in the weld bead), and often go unnoticed. While crater cracks start small, if not addressed they can propagate throughout the weld and cause major failures. As a best practice, welders should take care to completely fill the crater during welding, either by using an automated crater-fill function on the welding power supply or by using some other approved method of filling the crater.
Increasing weld-travel speed can help reduce the probability of stress cracking, because it narrows the heat-affected zone and minimizes base-metal melting. Preheating also may help, by reducing residual stress levels of the base material during and after welding. This in turn will lower the probability of stress cracking.
Avoid welding aluminum that is very cold, and avoid overheating during preheating operation—a 150 F preheat temperature suffices for all aluminum alloys. Overheating some alloys, such as those in the 6xxx series, can unacceptably reduce base-material tensile strength.
While not as critical of an issue as cracking, porosity is perhaps the most common complaint when mig welding aluminum. Porosity refers to the cavity-like discontinuities in the weld formed by gas entrapment during solidification.
Weld porosity results primarily from the absorption of hydrogen during melting and the expulsion of hydrogen during weld-pool solidification. Sources of hydrogen that create porosity:
• Hydrocarbons, in the form of paint, oil, grease and other lubricants and contaminants.
• Hydrated aluminum oxide—aluminum oxide that has absorbed moisture can release hydrogen when subjected to heat during the welding operation.
• Moisture, which can come from the atmosphere (humidity) or from other sources such as compressed air, small leaks in water-cooled torches, contaminated shielding gas or precleaning operations.
The first step in solving this issue: Identify the source of hydrogen responsible for producing the porosity. Weld shops also can purchase low-dew-point shielding gases (argon or argon/helium mixtures) to help reduce weld porosity. And, ensure welders closely follow the recommended shielding-gas flow rates and purge cycles for the welding procedure and weld position being used.
Welding operators must thoroughly clean base metals with a solvent and clean cloth or paper towel, followed by stainless-steel wire brushing prior to assembling the weld joint. Note: Shop rags typically are not clean enough for use on aluminum, as they can contain residual hydrocarbons that contribute to porosity.
Also, ensure that the base metal and filler metal are condensation-free. When bringing aluminum in from a cooler location (such as outdoors), allow it to sit in the welding area for 24 hr. before welding. Likewise, store unpackaged aluminum filler metals in a heated cabinet or room to help prevent them from cycling through dew points and avoid creating hydrated oxide on their surface.
Lastly, diligently purchase high-quality filler metals from reputable manufacturers. Such filler metals typically have been diamond-shaved to eliminate harmful oxides; manufactured following procedures to produce low residual-hydrogen-containing compounds; and weld-tested to stringent AWS standards.
Prevent Erratic Wire Feeding and Unstable Arcs
Welders can follow several guidelines to avoid erratic wire feeding and arc issues, starting with using a welding power supply and consumables designed specifically for aluminum. Use the right kind of contact tips, with the size matched to the wire diameter being used. And, use a contact tip designed for aluminum wire; using a tip designed for steel wire can cause excessive burnback when welding aluminum.
The contact tip should be recessed in the gas cup by 1⁄8 to ¼ in. to ensure proper gas cooling of the tip, and for spatter control. As the contact tip wears, arc flaring can become a problem. To prevent this, replace contact tips as needed.
Selecting the correct type of drive roll will help to prevent wire-feeding issues when delivering aluminum weld wire to the joint. The majority of these problems result from aluminum wire shavings that originate from poor fitting and incorrectly designed drive rolls. The shavings can build up and clog the weld-gun liners, restricting the free flow of the wire. Use a U-groove drive roll in the wire feeder, designed for aluminum; a V-groove drive roll will compress the wire and deform it, causing erratic arc conditions.
Also, carefully align the drive rolls, and als use the lowest drive-roll pressure capable of consistently feeding the wire. Performing regular maintenance and periodically replacing items that wear, including drive rolls, liners and inlet guides, also helps prevent wire-feeding issues. Use a push-pull wire feeder or spool gun to promote optimum wire feedability. Most push-pull guns have two liners: a conduit liner, which typically lasts longer, and a head-tube liner in the gun portion, which can wear out more quickly. Periodic replacement of both liners proves helpful, especially once clogging becomes an issue.
Minimizing Weld Discoloration and Smut
Introduction of oxygen into the shielding-gas envelope via air, moisture and contaminants can increase burning (oxidation) of the filler metal, which produces weld discoloration and smut. The use of certain filler metals also can contribute to this problem.While weld discoloration and smut look bad, they are easy issues to avoid. The 4xxx series of filler metals produce less weld discoloration and smut than do the 5xxx series—magnesium in 5xxx-series alloys vaporizes in the arc and condenses as black soot next to the weld bead. Most 4xxx-series alloys contain little or no magnesium. Also, welders can keep air out of the shielding gas by decreasing welding-gun angle, increasing gas-cup size, holding the gas cup closer to the base metal, removing spatter buildup from the gas cup and carefully shielding the arc from drafts. Welders used to working with steel may be dragging their weld. Use a push angle instead, to put the arc-cleaning action in front of the weld. This angle continually cleans the weld and reduces smut. MF
See also: Hobart Brothers Co.
I converted my 1978 "white face" Miller 200 to push Aluminum wire in /045 with Argon but it just burns back to the tip as soon as I trigger an arc. It has welded to tip to the wire also. Any suggestions? Dspencerpi@aol.com