The Benefits of Using Steel Coil

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Steel coils are more than just a convenient form of metal—they're the engine behind manufacturing efficiency, precision engineering, and high-performance product design. Rolled, slit, and finished to exacting standards, coil makes modern production lines possible and helps transform raw alloy into life-saving medical devices, automotive components, architectural materials, and much more.

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But what is a steel coil, exactly? Where does it fit in the industrial ecosystem? And how are coils shaping the future of high-stakes manufacturing?

What is Steel Coil?

A steel coil is a continuous strip of metal, typically produced in long lengths and wound into a roll. Think of it as the form that bridges the gap between molten metal and functional part. Depending on the grade, dimensions, and mechanical properties required, coil may be produced via hot rolling or cold rolling processes.

Hot-rolled coils are created at elevated temperatures, where the steel is more malleable. This process is ideal for applications or components that don’t require tight tolerances or a refined surface finish.

Cold-rolled coils, by contrast, are processed at ambient temperatures through a series of rollers that reduce thickness, refine grain structure, and produce a smooth surface. These coils are best suited for applications requiring tight dimensional tolerances, excellent surface characteristics, and enhanced strength.

Unlike sheet or plate—which are typically delivered as flat, cut lengths—coils offer uninterrupted form. That continuity matters. Coils can be unwound, fed directly into stamping lines, roll formers, or laser cutters, and tailored to specific widths and gauges. The result: less scrap, faster production, and greater consistency.

Industrial Applications of Steel Coils

Across industries, coils deliver the consistency and volume that modern manufacturing demands. The format supports automation, reduces downtime, and ensures that critical properties are maintained across thousands—sometimes millions—of parts.

Automotive & Mobility

In the automotive sector, coil-fed stamping presses produce everything from structural brackets to fine-featured safety components. While some parts rely on commodity-grade steel, precision coil is essential for applications like:

• Airbag burst discs, where consistent burst pressure is a function of controlled temper and surface finish

• Heat exchanger components in electric vehicles and high-efficiency combustion systems

• EV battery housing and shielding systems requiring strength, conductivity, and dimensional stability

HVAC, Heat Transfer & Energy

Stainless and specialty coils are foundational to high-efficiency HVAC systems, commercial refrigeration units, and heat exchangers. Coils allow the tight control of thickness and hardness needed to produce finely drawn fins, brazed plates, and durable connectors. In clean energy systems, coils also serve as the basis for fuel cell bipolar plates and electrolyzer internals, where conductivity, corrosion resistance, and uniformity are critical.

Architecture & Construction

Whether forming decorative paneling or structural flashing, coils allow for continuous roll forming of façade systems, gutters, handrails, or elevator interiors. Specialty stainless grades with enhanced polishability or oxidation resistance offer both performance and aesthetic benefits.

Medical & Robotics

In medical device manufacturing, coil is used to produce formed surgical instruments, robotic flexures, catheter components, and implant housings. Material must be precisely controlled not only in thickness and temper, but also surface cleanliness and grain orientation.

Everyday Products Made Possible by Steel Coils

Though Ulbrich’s materials often operate in high-stakes environments, the applications they enable can be found everywhere—quietly delivering safety, reliability, and precision.

You might not notice the seam where two components are joined in your vehicle’s seatbelt retractor, but it’s there—stamped from ultra-flat, precision slit coil engineered to respond consistently in a crash. That smart-looking metal credit card in your wallet? Its core material was likely rerolled to exact width and hardness, ensuring both printability and tactile feedback.

Steel coils power the pressure regulation systems behind commercial fire suppression. They form the structural seals in aircraft doors. They’re cut into connectors and tabs for charging stations. They run through servo-driven feeders at stamping facilities producing parts that can’t afford to fail.

That’s the difference: these are not decorative or disposable components. These are parts that make systems work—and keep working—in heat, pressure, vibration, and time.

Future Trends and Innovations in Steel Coil Applications

As industries evolve, so does the role of coil in next-generation manufacturing.

Lightweighting with Precision

Transportation manufacturers continue to demand thinner, lighter components—without compromising on strength. Through advanced rolling and annealing processes, coils can now be produced at sub-millimeter gauges with enhanced mechanicals, supporting fuel efficiency and sustainability targets.

Sustainable and Recyclable Metals

Sustainability is also influencing how coils are sourced and produced. Stainless steel, already one of the most recycled materials on earth, is seeing renewed interest as manufacturers seek closed-loop supply chains. Ulbrich’s rerolling capabilities help customers specify just the material needed—nothing more, nothing wasted.

Smart Alloys for Harsh Environments

From seawater exposure to cryogenic temperatures, engineers are looking for materials that perform under duress. New developments in alloy design, as well as surface treatments and nanostructure refinement, are extending the use of coil into hydrogen systems, space applications, and beyond.

Precision Coil vs. Commodity Coil: What's the Difference?

Not all steel coil is created equal. While commodity coil may be sufficient for basic forming or structural support, precision rerolled stainless steel coil serves an entirely different purpose. The contrast between the two is clearest when you follow the coil into its final application.

Commodity coil is produced at volume for high-flexibility use cases. It’s often deployed in applications where the stakes are low, tolerances are generous, and variation from one batch to the next won’t cause functional issues. In these environments—basic bracketing, fencing, light framing, enclosure panels—the coil's dimensional irregularities, variable mechanicals, or surface inconsistencies are acceptable tradeoffs for lower cost and faster mill output.

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But when a product needs to survive extreme temperatures, form without fracturing, hold shape under pressure, or fit within a multi-part system where every component is interdependent, commodity coil fails to measure up. That’s where precision rerolled coil enters.

Precision stainless steel coil, like that produced by Ulbrich, is engineered for the specific needs of its end use and application. Tolerances on width and thickness aren’t just tighter—they’re held across the entire length of the coil. Mechanical properties like yield strength, tensile, and elongation are dialed in to support specific operations like deep draw, progressive stamping, or fatigue-resistant flexure. Even the temper and grain structure are customized to support repeatability in forming, welding, and assembly.

What this means is that precision coil goes where standard coil can’t. It’s found in:

• Burst discs in airbag systems, where a few psi of inconsistency could trigger failure

• Fuel cell and electrolyzer plates, where conductivity, corrosion resistance, and formability must all align

• Implantable devices and medical robotics, where material uniformity is a prerequisite for both safety and FDA validation

• Supersonic aircraft heat exchangers, where fluctuating pressure, oxidation, and vibration put material properties to the test

Each of these critical applications comes with engineering and material reliability challenges. And no application demanding that level of reliability should rely on a material that varies from one end of the coil to the next.

In short: commodity coil may shape a sheet metal panel. But precision rerolled coil shapes the world we trust to work—in our critical systems, our life-saving devices, and our emerging technologies. That’s why it’s worth knowing the difference.

Why Coil Matters

The form may be simple—a strip of metal wound into a roll—but the impact is profound. Steel coil is a platform for innovation, a vehicle for scale, and a conduit for quality.

Oftentimes, using stainless steel components seems like a simple solution to corrosion on coils. You may see fins or tubes or other parts of the system show signs of corrosion, and it seems that the best option is to change the coil to stainless steel, solving the corrosion problem permanently. While this seems like a simple solution to a significant problem in the HVAC, industrial, and commercial systems where coils are found, the answer to the question “should I make an all-stainless coil?” is far more complex.

While it’s true that stainless steel has excellent corrosion resistance properties, when used in a heat exchanger it can have poor heat transfer characteristics. So, it's possible that by solving the corrosion problem using stainless, other system issues could result. Performance reduction, exceeding fan or motor capacities, and exceeding space or structural limitations of the existing unit are all possibilities when changing a system’s materials to stainless. Finally, there are the economics – is the stainless steel solution a viable commercial option for the installation?

As the system engineer, you are faced with a dilemma: meet the overall system constraints, solve the corrosion problem, and maintain a budget so the project moves forward. These priorities often conflict with each other, but the evaluation and balancing of these objectives are where Super Radiator can lend a hand.

To better understand the potential impact of using an all stainless steel heat exchanger, let’s evaluate an example 400,000 BTU/HR (33 tons or 119 kW) cooling coil. For the example, we’ll use 45° F water and a 36” x 45” coil with standard copper tubes and aluminum fins. The coil for this installation will be 12” deep, weigh 320 pounds and have a cost factor of 1.0. This is our base unit and is the component currently installed in the system.

The question is what is the impact of changing the heat exchanger to all stainless steel? There are two ways to evaluate the case: keep the same unit capacity or fit the space of the current unit.

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Here are the results of using all stainless steel:

• Maintaining capacity: Air pressure drop = increased 2.3x; Weight increase= 6x; Depth increase= 2.2x ; Cost Factor = 6.8x.

• Air pressure drop = no change; weight increase 1.5x; Capacity Decrease = 40%; Cost Factor = 4.

To summarize, changing the coil from the copper and aluminum to all stainless steel will be a cost increase between 4 and 7 times the original coil. Moreover, it will either not fit in the existing unit, or short the system capacity by 40%.

If the system being designed is new, the larger size or different capacity could be reconciled with adjustments to other system components, such as changing the fan to accommodate the higher levels of air friction or altering the unit design to create more space for the larger coil. However, for an existing system, this may not be possible.

Stainless steel or other high corrosion-resistant material may be the only option in some systems: high temperatures, abrasive environments, extreme caustic chemical solution. For many cases, a basic coil with a high-quality coil coating can solve most coil corrosion issues. Let’s evaluate the impact of this option.

Based on Super Radiator research, using a coil coating has little impact to the thermal performance of the coil. However, coating does incur additional cost compared to an uncoated coil. Electro-deposition (E-coat) and baked phenolic (such as Heresite P413) are the most common, quality coil coatings. The example coil, with the coating will have cost factor of 1.3. The price is higher than the bare coil, but coating is a great option to solve the corrosion issue, meet the performance needs of the system, and fit the space.

Copper fin and tube are often considered for corrosive, abrasive, or harsh environments. For select installations, an all-copper construction is a good option. Adding to our example from earlier in the document, a copper coil will have a cost factor of 1.5. However, the copper construction does have the benefit of 3.5% increased capacity. Using copper fins keeps the air friction the same as with aluminum fins. The coil weight does increase by 1.8x.

Is all stainless steel construction the best option to solve the corrosion issue on your finned tube coil? It may be. But there may be better options. Give Super Radiator a call today. We're here to help.