From short arc-on times for tacking parts to completing long continuous welds on thick plate, the MIG gun needs to offer the appropriate welding capacity for the job. For example, welding operators may not need a MIG gun that is the same amperage as the power source. That is because often they weld only 30 to 50 percent of the time, making the use of a lower amperage gun an appropriate option. Conversely, when welding operators overwork a light-duty MIG gun, it could lead to premature failure. Or, in some cases, the welding operation may have multiple applications, making it necessary to have a MIG gun that can address the needs of several applications.
On the Lighter Side
For welding applications that require short arc-on times, such as tacking parts or completing welds on small parts, a light-duty MIG gun may be the best choice. A light-duty MIG gun is typically considered one that provides from 100 to 300 amps of welding capacity. Like all MIG guns, light-duty ones are rated according to their duty cycle, or the number of minutes in a 10-minute period that the gun can be operated at its full capacity without overheating. Generally, MIG gun manufacturers rate their products at 60 to 100-percent duty cycle. In the case of light-duty applications, including welding thinner materials, a light-duty MIG gun would work well.
Because light-duty MIG guns typically offer low amperage capacity, they also tend to be smaller and weigh less than higher duty ones, making them easy to maneuver even in tight areas. Most have small, compact handles as well, so they are comfortable for the welding operator to use.
Light-duty MIG guns often use light or standard duty consumables — nozzles, contact tips, and retaining heads (or gas diffusers). These consumables generally have less mass and are less expensive than their heavy-duty counterparts. Similarly, because they are designed for short arc times, the necks (or goosenecks) on light-duty MIG guns are made of lightweight materials, including polymer, rubber or light aluminum armor.
The strain relief and connections on light-duty guns also need to be considered. The strain relief is usually composed of a flexible rubber component, and in some cases may be absent all together. These features help maintain the gun's light weight, but they can allow for kinking that may lead to poor wire feeding and gas flow.
Finally, some unicables on light-duty MIG guns have crimped connections and may not be able to be repaired. If a crimped cable becomes damaged, the cable or possibly the entire gun may need to be replaced.
As a rule, light-duty MIG guns offer standard features at a lower price and typically need to be replaced more frequently.
For tougher jobs
On the opposite end of the spectrum from the light-duty applications and MIG guns previously described are jobs that require long arc-on times and/or multiple-passes on thick sections of material. These applications include ones found in heavy equipment manufacturing for the agriculture, construction and mining industries, over-the-road trailers and trucks, and other similarly demanding welding jobs. For these applications, heavy-duty MIG guns are the best choice, as they can be used for continuous welding on one inch or thicker material and in harsh environments typical to such industries.
Heavy-duty MIG guns generally range from 400 to 600 amps and are available in both air- and water-cooled models. Choosing between a water- or air-cooled heavy-duty MIG gun largely depends on welding application, operator preference and cost considerations. Water-cooled systems are more expensive and often require more maintenance. Specially treated coolant solution, rather than tap water, is necessary for a radiator cooling system because tap water can cause algae growth or scale (mineral buildup) on the internal gun surfaces and cable assembly. In addition, over time water can leak from hoses, the gun neck or heads, requiring immediate repair to prevent weld discontinuities and gun failure. However, despite the additional cost, when welding on very thick plate that requires high deposition and good weld penetration, a water-cooled heavy-duty MIG gun may be required.
Heavy-duty MIG guns — both air- and water-cooled models — often have larger handles than their light-duty counterparts in order to accommodate the guns' larger cables (due to the higher amperage being provided). Heavy-duty MIG guns often use heavy-duty front-end consumables that are capable of withstanding high amperages and longer arc-on times. The goosenecks on these guns are often longer as well, which puts more distance between the welding operator and the high heat output from the arc. Most goosenecks for heavy-duty guns are generally comprised of aluminum armor that protects it from damage from the high temperatures, plus day-to-day wear and tear. The addition of a heat shield is an option to protect the welding operator from the heat output of a high amperage MIG gun and longer arc-on time. This heat shield provides a barrier between the arc and the welding operator's hand. Adding a unicable cover can help protect the power cable from a harsh environment, too.
Heavy-duty MIG guns often feature locking triggers, as welding operators use these guns for multiple weld passes and/or long continuous welds and these types of triggers help prevent fatigue. Other heavy-duty MIG guns feature dual- or multi-schedule triggers that can be mounted on the top or the bottom of the MIG gun according to the position that the welding operator finds most comfortable.
Heavy-duty MIG guns can also, in many cases, be customized to meet the needs of the application at hand. Some MIG gun manufacturers allow operators to configure a heavy-duty MIG gun according to their preferred handle style, gooseneck length and angle, and unicable length.
Parting Thoughts
Remember, just like any part of the welding process, MIG guns play an important part in obtaining the quality and performance desired for a given application. Overusing a light-duty MIG gun can easily result in poor performance, while using a heavy-duty MIG gun without cause can increase the cost of the welding operation unnecessarily. If a company has multiple power sources guns can be standardized to fit them through the addition of a feeder adapter. Doing so allows for one common MIG gun to be used throughout the operation, lessening the need to inventory multiple styles of guns and consumables.
Ultimately the goal is to accommodate both the amperage and duty cycle of the application in the best way possible. And even more so, the selection can also conserve the resources of the welding operation and aid in achieving high productivity.