Have you wondered, "What is flux core welding?" or "What is a flux core welder?" Flux core welding, also known as flux-cored arc welding (FCAW), is a type of welding that uses a continuous hollow wire electrode to meld metals and other materials together. Flux core welding is suitable for materials contaminated with dirt and rust, making it ideal for outdoor and contaminated environments.
There are two types of flux-cored arc welding: gas-shielded and self-shielded. Gas-shielded FCAW is similar to gas metal arc welding (GMAW), while self-shielded FCAW does not require an external shielding gas.
FCAW is commonly used in the construction industry due to its high welding speed, portability and ability to be used outdoors. Flux core welding has advantages such as increased mobility, high deposition rate and versatility, but also has disadvantages such as fumes, cleanup and higher equipment costs.
Keep reading to learn more about flux core welding basics and processes.
Flux-cored arc welding is a good technique to use on materials that are no thinner than 20 gauge, including carbon steel, low-alloy steels, high-nickel alloys, cast iron and stainless steels. The flux-cored wire is powerful and able to penetrate thick weld joints. For this reason, it can also prove more productive than other types of welding.
FCAW is often used in the construction industry, since this semiautomatic type of welding can be used outdoors, has a high welding speed and is easily portable.
FCAW can be used for projects like:
When a welder needs to work outdoors or on contaminated materials, FCAW can produce high amounts of welds in a short amount of time.
However, FCAW isn’t ideal for everyone or every project. Let’s discuss the advantages and disadvantages of flux core welding.
Wondering how to weld flux core wire and the specific process? We have you covered.
In FCAW, an electric arc unites a continuous filler metal electrode with the base material. As the welding process happens, the shield gas provided by the flux protects the weld pool from oxidation and other atmospheric elements.
After the weld is completed, there is slag that must be removed. Welders need to account for the time to remove slag to make the weld look clean. The welder should remove the slag between each pass.
There are a few different processes a welder can use when performing flux-cored arc welding. As previously mentioned, these variants include self-shielded FCAW and gas-shielded FCAW.
Different fluxing agents provide different benefits to the welder. Self-shielded FCAW is typically used outdoors because FCAW using a separate gas shield would have issues with wind potentially blowing it away.
Flux agents used in gas-shielded processes are designed to help deliver deeper penetration and work with out-of-position welds. Gas-shielded welds are also known as dual shields because flux-cored welds already rely on the electrode for shielding.
There are a variety of welding patterns that can be achieved with flux-cored welds. High and narrow welds, for example, can be achieved by using a backhand flux core welding motion.
There is a stringer bead method that deposits weld beads in a straight line, as well as a weave bead technique that forms a zigzag pattern.
Wires for flux-cored arc welding differ depending on whether the process is self-shielded or gas-shielded. Self-shielded wires, or FCAW-S, don’t need an external gas cylinder. They are often used for portable jobs but do tend to produce more smoke and spatter.
Gas-shielded wires, or FCAW-G, require an external shielding gas. They are easier to control and produce aesthetically pleasing welds. They’re typically used in shop settings since outdoors the gas could blow around.
FCAW-G wires tend to be less expensive than FCAW-S wires. Both wires are typically available in diameters ranging from .035 to 7/64 of an inch.
The polarity for flux-cored arc welding processes depends on whether they are self-shielded or gas-shielded. Most gas-shielded welds work best with a direct-current electrode positive (DCEP) polarity. When using a self-shielded process, direct-current electrode negative (DCEN) polarity is used.
To achieve a flux core weld, you will need:
In addition to these tools, the welder should wear safety equipment, including an auto-darkening helmet, gloves and protective clothing.
Flux core welding is often compared to stick and MIG welding, and while it can be similar to these methods, it’s also unique in a number of ways. Let’s discuss how.
The primary difference between stick welding, also known as shielded metal arc welding (SMAW), and flux core welding is the physical structure of their electrodes.
Stick electrodes are metal rods coated in flux. As you weld, the metal center melds with your metal base while the flux casing melts and releases gas to protect the molten metal from contamination.
Flux core electrodes have a metal exterior that contains flux on the inside. Additionally, FCAW electrodes come in a spool and are fed through a semiautomatic welding gun managed by the welder. On the contrary, stick electrodes are long rods attached to an electrode holder managed by the welder’s hand.
Both welding types are self-shielded, removing the need for a gas agent like carbon dioxide. Because stick welding does not require a gas shield, it is also portable and fit for outdoor use.
SMAW also leaves behind slag that requires cleaning between each pass. However, it has a lower deposition rate than FCAW, making for a slower process. Stick welding is common in construction, pipelines, shipbuilding and underwater welding.
MIG welding, also called gas metal arc welding, uses a welding gun that is fed a solid wire from a spool. FCAW also receives a wire from a spool, except the wire is tubular instead of solid.
The shielding process is another difference between these welding types. As indicated by its name, GMAW requires a gas shield to protect the weld pool. The welding gun contains a nozzle that sends gas through it along with the welding wire to ensure a clean process.
Because MIG welding requires a gas shield, little splatter occurs, minimizing slag and making for an overall cleaner weld. However, it’s not fit for outdoor use as a draft can easily blow away the gas shield. It is also less portable because it requires transporting both the MIG machine and the shielding gas.
MIG welding is more expensive than FCAW and less compatible with various welding positions due to a high heat input. However, the MIG machine eases use, making it simple to learn.
MIG welding is also more versatile, as it can be used on multiple metals and alloys. Industries like manufacturing, automotive maintenance and production, pipe welding, construction, and shipbuilding use this type of welding.
Because flux core wire is tubular and MIG wire is solid, many are inclined to believe MIG wire is the stronger of the two. However, both flux core and MIG welding wires meet the American Welding Society tensile strength standard of 70 KSI. Measuring which weld is stronger would come down to analyzing the welder’s skill.
The stronger weld would depend on the wire used to perform the process. Both flux core and MIG wires come in various tensile strengths. However, the wire you select should correlate with the tensile strength of the metal you’re welding.
Aside from this, determining which type of weld is stronger would depend on the welder’s experience and technique. Both welding techniques can penetrate thick metals. Therefore, the kind you choose boils down to efficiency and comfortability.
The flux core welding motion naturally produces slag. Therefore, it’s best to pull away from what you've welded. Pushing the wire will cause the flux to become trapped in the melted metal.