Silicon control

Silicon control technology can help with post-weld cleanup

welding silicon
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weld seam
This weld was made with 0.052-in. FabCor Edge XP metal-cored wire on blasted material, resulting in large, easy-to-remove silicon islands.

Even though gas metal arc welding (GMAW) is generally considered to be a slag-free process, silicon islands present on the weld surface after welding are a normal (and largely unavoidable) byproduct of solid and metal-cored wires. Unfortunately, they can be troublesome when it comes to post-weld cleanup. These islands are often small and hard to see, which can make it difficult to remove them completely.

Metal-cored wires designed with silicon control technology can help, saving time and improving productivity. These products can also save money – not just for labor, but also for the cost of wire wheel brushes and other tools used for cleaning up welds and removing silicon islands.

Silicon is used in the steelmaking process as a deoxidizer and an alloy to improve strength. For this reason, it is often present in both the base metal and the steel used to produce conventional solid and metal-cored welding wires. Metal-cored wires often have a slightly higher silicon content that helps make them more tolerant to welding through dirty surface conditions without creating porosity.

Silicon islands are caused by a chemical reaction similar to the reaction that occurs with fluxing agents. During this reaction, silicon in the weld bonds with impurities such as oxygen. This changes the density of the silicon, causing the silicate to float to the top of the weld pool and congregate into glassy island-like formations.

There are numerous factors that affect the quantity and size of silicon islands, including:

silicon island
This weld shows silicon islands from the FabCor Edge XP metal-cored wire when used to weld through material featuring mill scale.

• Wire silicon content

• Base metal silicon content

• Presence of mill scale and other contaminants

• Welding parameters

Exerting control

Welders can exert some control over silicon levels by adjusting welding parameters. Using higher heat input – through a higher voltage and amperage – melts more of the base metal, resulting in more silicon pickup and more silicon reaction in the weld pool. Using lower heat input typically results in lower silicon levels. Also, removing mill scale from the base metal before welding helps reduce silicon island formation significantly.

silicon island welds
This weld illustrates the use of a metal-cored wire without silicon control technology on blasted material using a pulsed GMAW process. The silicon islands are small and reach into the toes of the weld.

There are many applications where the presence of silicon islands can cause problems that cost time and money.

Post-weld painting: When finished components must be painted, silicon islands can be an issue. The islands can fall off after painting, exposing the bare metal underneath. This necessitates their complete removal.

Multi-pass welds: Silicon islands can migrate into the weld toes during multi-pass welding. Depending on the parameters and technique of subsequent passes, they may not be liquefied by the arc or heat of the weld pool, leading to inclusions. These inclusions can form a stress riser that leads to cracking or early weld failure.

Also, silicon can accumulate when it isn’t removed between passes. The islands will continue to grow in size and can eventually impede the welding arc or flow of the molten weld pool. If the welder welds over an especially large island, the arc can become erratic because the silicon island is nonconductive. This could result in lack of fusion, poor penetration or inclusions.

Control technology

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This weld was created by a metal-cored wire without silicon control technology. It shows the influence of melting more base material due to higher parameters.

Some metal-cored wires, such as the FabCor Edge XP wire from Hobart, feature silicon control technology. This technology uses small and carefully controlled element additions to influence silicon island size and distribution through changes to the surface tension and flow of the weld pool. As a result, the wire minimizes the positioning of islands into the weld toes and minimizes overall distribution of islands. This produces larger islands that float to the center of the weld so they are easier to see and remove.

Be aware that some of the elements most commonly used to influence the weld pool characteristic and silicon islands have relatively low melting points. In applications where joint restraint and solidification stresses are especially high, these elements may have a detrimental effect on solidification crack resistance. This can most often be mitigated by adhering to best practices regarding welding parameters and joint design and managing thermally induced stresses. Most users, however, can convert to products containing silicon control technology with virtually no process changes.

Silicon control technology is a premium feature that is not included in all metal-cored wires, so it does impact the cost of the wire. Still, the benefits of reducing or eliminating silicon islands can help operations cut down on labor and rework, both of which are significantly higher drivers of overall weld cost.

Because FabCor Edge XP wire produces larger silicon islands that are easier to see and remove, the wire boosts a welder’s confidence and productivity. They can be assured that they have completely removed the islands – and reduced instances of rework.

Also, because the silicon islands form toward the welding center line rather than sitting toward the weld toes, welders can complete post-weld cleaning with a variety of lighter duty tools. A power wire wheel brush or a hand brush works well, and there will be less wear and tear on them. Islands that are more entrenched at the toes require the use of more aggressive tools and techniques.

Reducing removal time and extending the life of grinding equipment results in cost savings for the operation.

Silicon control technology also tends to work best when the welder is producing good welds to start with. If the weld bead is very convex and not smooth, silicon problems can be amplified. FabCor Edge XP wire helps the welder produce very good weld bead appearance and contour, which then helps the technology do its job. Potential users should be aware that flat and smooth welds generally require less post-weld cleanup and rework.

Best uses

Silicon control technology should be employed when production efficiency is a concern. The technology helps the welder spend more time welding and less time cleaning welds.

However, silicon control technology is not 100 percent effective in all applications. Some silicon may still form in small islands or into the weld toes, but most users will notice an improvement in overall silicon distribution and average weld cleaning time.

While wires with silicon control technology can provide optimal performance when welding over blasted/ground base metal or light unremoved mill scale and contaminants, they may lose some effectiveness when the mill scale is very heavy (a common occurrence on very thick base metals). Once mill scale gets to a certain thickness, it becomes harder for the silicon control technology to work as intended. In these cases, spending time on pre-weld cleanup can sometimes save time overall by improving the performance of the wire from the perspective of both silicon control and ease of making high-quality welds.

While there are different metal-cored wires designed for different jobs, options such as FabCor Edge XP wire with silicon control technology provide smoother arc characteristics. These features can help operations save time and money in post-weld cleaning and rework. Before implementing a new wire, always check welding procedures and conditions to ensure the change won’t affect other weld characteristics in the application.

Hobart

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