How to Reduce Spatter When MIG Welding: Top 4 Fixes

How to Reduce Spatter When MIG Welding: Top 4 Fixes

As a beginner hobbyist welder, I was getting more spatter around my welds than expected—sometimes a lot more!

My grinding skills improved more quickly than my welding skills—so I needed to learn how to reduce spatter when MIG welding.

I found that the top causes of excessive weld spatter fall into four categories. You’ll find more troubleshooting tips below, but here’s the checklist I’m using to reduce MIG welding spatter.

Checklist: How to Reduce Spatter When MIG Welding

  • Check for contaminated materials: Properly clean and prepare the workpiece. Clean, or replace, dirty, or rusty wire.
  • Check welding technique: Angle the gun no more than 5-15° from vertical. Keep stick out at ⅜-in. for MIG and ½-in. for flux-cored wire.
  • Check welder settings: Use the correct polarityReduce wire feed speed and/or voltage.
  • Check for equipment issues: Erratic wire feed, poor work clamp connection, insufficient shielding gas, worn or over-sized contact tip.

What is MIG Welding Spatter?

MIG welding spatter, sometimes called splatter, comprises molten droplets of welding material. Generated around the welding arc, some droplets are expelled outside the weld puddle. When the molten droplets land and cool, you’re left with spatter.

Here’s a short, 30-second video giving you a close-up view of a rough arc generating excessive spatter. When you can see the violent activity in the weld pool, it’s easier to understand where all that spatter comes from.

When MIG welding—especially in short circuit mode—the question isn’t if you’ll get spatter, but how much.

If your welding arc is stable and smooth, the beads of spatter might be so fine to be only a nuisance. But if the arc is sputtering and popping, the amount of spatter could be substantial. You may find BB-sized drops of the spatter that you must chisel or grind off your workpiece.

The spatter itself won’t affect weld integrity unless you were to weld over it on a multi-pass joint. It’s mainly a cosmetic issue, but the root cause behind the spatter may jeopardize your weld strength.

Machine Settings to Reduce MIG Spatter

It’s easy to forget to change polarity when switching between flux-cored to solid wire. When your arc is rough, and there’s as much filler material outside the weld as made it to weld bead, double-check the polarity. This happens to everyone.


Setting the wire feed speed too fast is a leading cause of excessive spatter. Try dialing it back a bit. Same for the voltage settings.

Fine-tuning your MIG welder for a smooth, stable arc will cut the amount of welding spatter.

This ability comes through experience. Overall welding experience helps, as does time with your particular welder.

You can use your welder settings chart or programs to give you a starting point. But because welding machines, materials, and conditions vary, they usually need adjustments for the best arc.

Here’s how I dial in my welder settings:

  1. Set voltage according to the welder chart, or to where I think it should be from experience. This is a coarse setting that I don’t touch again unless I can’t get the arc right with the following steps.
  2. Set wire speed according to settings chart. This is a fine setting that I adjust up or down in small increments to get a smooth arc. Small adjustments prevent skipping over the sweet spot.
  3. If I’ve run through the entire wire feed speed range and still can’t get a good arc, it’s time to make a coarse voltage change, either up or down. Then, return to Step 2 and repeat until the arc is stable.
  4. With a stable arc, I’ll check the weld bead for penetration. If needed, I can make small adjustments to wire feed speed or gun travel speed to get a good bead profile (an indicator of penetration) while maintaining a smooth arc.
  5. If the arc sputters, while the bead still looks too cold or hot, I know that I’m out of range for the current heat (voltage) setting. I’ll either increase the voltage or turn it down. Then, after fine-tuning the wire feed speed, I should be ready to weld.

Key for me: Making one change at a time and taking notes for future reference.

Welding Technique Affects Spatter

When the amount of spatter varies during a weld, I’ll take a hard look at what I’m doing for operator error. Proper welding techniques can go a long way towards reducing spatter.

Keeping your gun angled only 5-15° from vertical allows the shielding gas to blanket the weld area. It’s easy to exceed that angle when trying to keep the weld puddle in view.

But too much gun angle can push the gas to one side of the weld, leaving the other unprotected. Spatter and weld porosity could result.

If the electrode stick-out is too long, it may jab into the weld pool causing spatter. A short arc helps reduce spatter, but if your electrode is too short, the arc may sputter. This also can disturb the weld puddle causing spatter.

Yes, sputtering causes spattering.

The stick-out recommendation of ⅜-in. for MIG, or ½-in. for flux-cored welding works well for me. Keeping the electrode length uniform helps me make consistent welds.

Maintaining consistent form will help you dial in your weld settings quickly.

Clean Materials Reduce Welding Spatter


Rust, paint, grease, and mill-scale on your work surface will cause the arc to spit and sputter; splashing spatters out of the weld.

Many people don’t like to paint, but I enjoy painting walls, doors, and even trim. What I don’t like is all the preparation needed before painting can begin.

It’s the same for me with welding. But it doesn’t take long to realize that even the most skilled welder (or painter) can’t achieve the best results without a well-prepared surface.

As much as I dislike all the prep work in welding, I enjoy re-dos even less. I waste time grinding off the lousy weld and spatter and end up preparing the piece just as I should have from the start.

Don’t forget to check your wire spool for contamination. Dust can collect, and rust can form on your wire. This can cause erratic feeding and weld contamination, both leading to excess spatter.

Removing the top layers may expose clean wire underneath.

Some use a product to clean the wire as it feeds called Lube-Matic from Weld-Aid. I haven’t tried this yet, but some say it works on the lightly contaminated wire.

If you’re an occasional home welder, a lot of time may pass between welding projects. You can remove the wire from your welder between uses and place it in a ziplock bag. This will keep it dry, clean, and ready to use. Find a warm, dry place for storage.

Equipment Issues That Contribute to Excess MIG Spatter

Many things can go wrong with a welder, resulting in poor welds with excessive spatter. The most common causes are also the easiest to correct.

Check the Work Clamp


A weak connection here can cause the welding arc to fluctuate. Check that the clamp has a good bite into the workpiece or the table.

Hit the contact area with a wire wheel or brush if needed. Check the clamp and the machine for loose cable connections. Try attaching the clamp as close to your weld as possible.

Some welder manufacturers skimp on clamp quality for homeowner MIG machines. If you think your clamp is on the flimsy side, it’s simple to upgrade to this strong copper-cast clamp.

Wire Feed Problems

Erratic wire feeding will mess up your welds with spatter.

Check that your wire feed tension is not so loose to cause the drive roller(s) to slip. While you’re at it, check that you’ve installed the correct drive roller for the wire size.


Do you see a lot of metal dust around the drive rollers or wire guide? This dust can also build up inside your cable liner.

With the wire drive tensioner disengaged, the wire should easily move back and forth through the cable by hand. If not, remove the gun and use compressed air to blow out the liner towards the gun end.

The liner could also be kinked and damaged.

As mentioned earlier, a dirty or rusty spool of wire will feed erratically and cause a lot of spatter.

Lack of Shielding Gas

Besides protecting your weld from atmospheric impurities, the MIG shielding gas helps stabilize the welding arc. So, a lack of shielding gas can cause an unstable arc and extra spatter.


First, verify that gas is reaching the gun. If you disengage the wire feed tensioner and pull the trigger, you should hear the gas flowing from the nozzle.

If not, check, and if needed, adjust the gas regulator and make sure the gas valve is working.

use spring clips over tubing that could become disconnected.

Spatter can build up inside the gun nozzle and restrict gas flow. Clean or replace. If you weld with flux-cored wire without a nozzle or using a MIG nozzle, spatter may reach and cover the gas ports.

Clean or replace the contact tip adapter. Flux-cored nozzles that protect the gas ports from the spatter are available for many guns.

Protect the welding area from breezes that can dissipate your shielding gas. Reposition fans or hang welding blankets or curtains to block airflow.

When added to Argon welding gas, CO2 (2-25%) stabilizes the welding arc and reduces spatter. Although cheaper, using 100% CO2 results in more spatter than the traditional C25 MIG mix of 75% Argon and 25% CO2.

Worn or Oversized Contact Tips

I have never worn out a contact tip, but I get how this can happen. The thin steel wire is harder than copper and acts as a fine saw blade. Ever notice the sawtooth-like impressions left by a knurled flux-core roller?

Higher welding temperatures only enhance the cutting effect. Bernard has more information about the contact tip wear.

Now, this is something I have done. With different sized contact tips all looking the same and hard-to-read markings, it’s easy to install the wrong tip.

With too large an opening, the wire electrode can lose contact with the tip, causing the arc to sputter. Replace if the wire passage looks oval instead of round, or if it’s the wrong size for the wire. An easy fix.

Spatter Management

While these products don’t reduce spatter, a light coating of welding anti-spatter spray or my favorite nozzle gel can keep the spatter from sticking. Makes for an easier cleanup of your gun and base metals.