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Full Guide to Metal Stamping: Process, Techniques ...

Author: Helen

Aug. 19, 2024

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Full Guide to Metal Stamping: Process, Techniques ...

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Through the cold-forming process of metal stamping, sheet metal is transformed into different shapes. The metal-stamping process uses a combination of dies and stamping presses to convert pieces of flat metal into usable shapes for a variety of industries.

From the automotive industry to aerospace projects to medical machinery, many industries throughout the globe heavily rely on metal stamping for their equipment. There is an increasing need worldwide for mass-produced quantities of complex parts, and metal stamping is a cost-efficient way to do so.

Metal stamping is a complicated process that can be completed through a variety of
 metal-forming techniques. Some examples include bending, punching, blanking, spinning, hydroforming, or piercing the metal to alter it to the ideal shape.

In this article, we&#;ve outlined the metal stamping process and some different types of metal stamping techniques to help you get a better understanding of how this process works.

What Is Metal Stamping?

The metal stamping process also referred to as metal pressing, consists of taking flat sheet metal and feeding it into a stamping press. This press then uses pressure and die to transform the metal into the predetermined shape.

Some examples of stamping techniques used include punching, coining, embossing, bending, blanking, and flanging.

To ensure the metal piece turns out the way it is supposed to, stamping professionals need to use the design tool that comes with CAD/CAM engineering technology. These designs must be as accurate as possible for each part to come out looking and operating how it should.

Because the metal stamping process can turn out a high volume of the same part in a short amount of time, it is used in a variety of industries.

Metal stamping can help produce:

  • Hardware such as nuts, bolts, screws, hinges, and washers for shelves, custom switches, doors, lighting, etc.
  • Specialty stamped hardware that includes products such as household tools, locks, power tools, mounting brackets, etc.
  • Electrical components such as cups, covers, fasteners, clips, and sensitive electronic assemblies.
  • Durable, high-quality parts for the construction industry that will stand the test of time.
  • Fastening solutions such as bolts, hooks, or complicated contact elements.
  • Components for appliances such as grills, ice machines, microwaves, cooktops, ranges, fryers, griddles, toaster ovens, disposal systems, and more.

Not only can metal stamping machines stamp, but they can also cut, punch, cast, and shape metal sheets into their desired shape and size. Stamping machines are designed to be as accurate as possible, and they can also be programmed to ensure accuracy.

Types of Metal Stamping Techniques

There are a variety of metal stamping techniques that are utilized for particular applications. We&#;ve outlined some examples below.

Progressive Die Stamping

This metal stamping technique breaks down the process into a series of stations that each serve a different function. The stock strip carries the part from one station to the next until it is finished and removed from the strip.

The original metal strip travels from its coil and makes its way into the die press. From there, the metal moves horizontally across each station. As soon as the desired bend, punch, or cut is made, the part moves onto the next station until it&#;s completed.

The part is still connected to the metal strip while it is being altered, so each movement must be as accurate as possible. This precision and accuracy assure that the end part is accurate and usable.

Progressive die stamping is a beneficial way to produce mass quantities of parts at a low cost, making it an attractive option for many. The die lasts for a long time and it&#;s easy to repeat the process as many times as needed. This type of metal stamping also produces minimal wasted scrap.

However, without a high level of precision and accuracy during progressive die stamping, the parts may not be accurately made.

Transfer Die Stamping

Another type of metal stamping is transfer die stamping. It is similar to progressive die stamping, but a mechanical transport system moves the part from station to station instead of an automated strip. This type of stamping is useful for making parts that need to be free from the metal strip during the stamping process.

This may be a single die on its own or it may require multiple dies or machines in a row to create a makeshift production line.

The lower tooling costs associated with transfer die stamping make it an excellent option for production. They are also versatile and can produce features such as cut-outs, ribs, knurls, threading, and pierced holes. This means that no secondary operations are required, further cutting back on cost.

Transfer die stamping is used in markets such as agriculture, automotive, locomotive, electronics, medical, recreational vehicles, and more. It&#;s beneficial in creating larger, bulkier parts that may require the use of multiple presses.

Fine Blanking

Another type of metal stamping is fine blanking, also referred to as fine-edge blanking. This specialty type of metal stamping is ideal for achieving flatness and a full-sheared edge in a way that other metal stamping techniques cannot.

This technique uses cold extrusion and it is a single-step process, resulting in a lower fabrication cost.

Fine blanking is typically completed using a hydraulic or mechanical press, or a combination of the two. There are three recognizable movements used in the fine blanking process:

  1. Using the workpiece&#;s clamp to hold the workpiece or work material in place
  2. Completing the blanking operation
  3. The finished part is ejected

The product is manufactured and needs to have complete contact with the surface on the part&#;s edge to be effective.

One example of a part that is often made using fine blanking is a gear. Gears require flatness in certain areas and every tooth needs to be fully engaged to be effective, making fine blanking the perfect candidate for this type of production.

The fine blanking press runs at much higher pressures than more conventional stamping techniques, so the machinery must be designed to withstand these higher pressures.

Four-Slide Stamping

Four-slide stamping, also referred to as multi-slide stamping, uses four tools simultaneously to form the piece into the proper shape. As the metal sheet is fed through the four-slide, it is quickly bent by each shaft.

It is ideal for producing products that require intricate cuts or complicated bends. While other metal stamping techniques use a vertical slide during production, four-slide stamping uses four different sliding tools to shape the metal piece.

The tool slides used in four-slide stamping are highly productive and straightforward, meaning this is an ideal method for creating complex or multi-part bends, even bends that are larger than 90 degrees. Multiple bends, punches, folds, or cuts can be completed in just one step.

Another advantage of four-slide stamping is the tooling itself is relatively inexpensive and there is minimal waste produced during the process.

Types of Stamping Presses

Stamping presses play an integral role in the process, and there are three common types: mechanical, hydraulic, and mechanical servo. The distinction between the three types comes from the power source.

In most cases, the stamping press is linked to an automatic feeder that moves the sheet metal through the press. We&#;ll get into detail on each type of stamping press below.

Mechanical

Mechanical stamping presses have a motor that&#;s connected to the mechanical flywheel. The flywheel then stores that energy to help the machine operate. These presses can produce a variety of punch sizes, ranging anywhere from 5mm to 500mm depending on the specific press being used.

The speed of mechanical presses ranges as well. It can operate as slow as 20 strokes per minute or operate as fast as 1,500 strokes per minute. In the case that additional energy is needed when the speed is lower, the operator can add an auxiliary flywheel to the drive. Mechanical presses are typically faster than hydraulic presses, however.

The press stroke length is kept as short as possible because it has such an impact on speed. On average, each stroke is 2 inches.

The operator of the mechanical press will use electronic control, a clutch, and a brake to help engage and disengage the press drive as necessary.

Mechanical stamping presses are most often used to create simple and shallow parts made from coils of sheet metal, most notably for large production runs for transfer and progressive stamping.

Hydraulic

As the name implies, hydraulic stamping presses use the hydraulic fluid as the power source. The technology used in hydraulic presses has significantly improved over time, with each improvement offering an upgrade in electronics and valves.

The hydraulic pistons release fluid that has a proportional amount of force to the piston head&#;s diameter. This allows for a high level of control over how much pressure is applied at any given moment. Despite so much flexibility in its stroke and speed capabilities, hydraulic presses can still deliver full power at any point in the stroke.

The pressure used in hydraulic presses may be preset by the user. The velocity can also be tweaked to adjust how fast the slide travels while the die closes. When the right pressure level is achieved, the valve helps activate pressure reversal to avoid overloading.

Hydraulic presses range anywhere from 20 tons to 10,000 tons. Their stroke sizes are anywhere from 10mm to 800 mm. This type of press is ideal for creating small, intricate parts thanks to its changeable stroke length and consistent pressure.

Mechanical Servo

Mechanical servo stamping presses don&#;t use flywheels as their power source. Instead, they rely on high-capacity motors to ultimately create intricate designs at a faster pace than standard hydraulic presses.

Servo presses are highly programmable, making it easy to have control over the stroke, slide position, motion, and speed of the press. These machines operate on a link-assisted drive system or a direct drive system.

Their high speed and high levels of customization make mechanical servo presses the most expensive option out of the three.

Types of Stamping Dies

Now let&#;s discuss the dies used in metal stamping. There are two types of dyes used: single-station dies or multi-station dies.

A single-station die is made from compound dies and combination dies; a compound die is capable of performing multiple operations in a single press. For example, if a steel washer needs to be made in a single press, it would need multiple cuts, thus requiring compound dies.

Combination dies use cutting and non-cutting operations in one stroke. For example, a combination die may produce both a cut and a flange when shaping a metal blank.

The other type of die used in metal stamping is multi-station dies. Progressive dies and transfer dies are included in this category. Examples of operations resulting from this die-set include cutting, punching, or notching.

Another noteworthy die used in stamping presses is steel rule dies, commonly referred to as knife dies. This type of die was first used on soft non-metal materials such as paper, cardboard, or leather. Over time, knife dies have also been utilized on copper, brass, and aluminum.

Additional reading:
Boost Operational Efficiency with Stamping Press Optimization

Aomate Product Page

Metal Stamping Advantages and Disadvantages

Let&#;s now compare the pros and the cons of metal stamping.

Advantages of metal stamping include:

  • Compared to other stamping processes, the costs of metal stamping are low.
  • High levels of automation compared to other presses.
  • Not as expensive to produce or maintain compared to those used in other processes.
  • More affordable secondary costs such as plating or cleaning.
  • Can use highly technical computer programs to provide increased precision.
  • Overall faster production and turnaround time with metal stamping.
  • Low cost of labor thanks to how automated this process can be.

On the other hand, there are also some downsides to metal stamping. Disadvantages of stamping include:

  • The presses themselves are extremely expensive and heavy to transport.
  • It&#;s not always easy or fast to acquire the dies needed in metal stamping.
  • If custom dies are used, the pre-production process takes longer.
  • If dies need to be changed in the middle of production due to a change in design, it can be difficult to achieve.

Applications of Metal Stamping

Now that we&#;ve covered the basics of metal stamping, let&#;s look at how this process is used and applied. It is used in a variety of ways, especially for the creation of three-dimensional designs. Chances are high that there are appliances or light fixtures in your home that were created through metal stamping.

It is utilized in the automotive industry, the lighting industry, the automotive industry, the medical field, the electronic industry, telecommunications services, and so many more. From simple components to extremely intricate machines and parts, metal stamping has seemingly endless applications.

Conclusion

Metal stamping is a widely used process that has applications relevant to your daily lifestyle. If you&#;re interested in learning more about metal stamping or any of our other metal capabilitiesSchaumburg Specialties is happy to assist you.

We&#;ve been serving the Chicagoland area for decades, and we&#;re looking forward to helping you next. Fill out our contact form, and our team will be in touch with you soon!

Powder Metallurgy Vs. Stamping: Advantages & ...

Stamping has produced pieces from cold sheet metal for hundreds of years. In contrast, the powder metallurgy process is even older and involves temperatures that reach well into the four-digit range.

The advantages of powder metallurgy vs. stamping are largely in powder metallurgy&#;s (PM&#;s) ability to form a complex, net-shape part. But even we admit PM is not a good alternative to stamping 100% of the time.

These are the pros and cons of the stamping and powder metallurgy processes when you stack them up against each other:

The Basics of Powder Metallurgy Vs. Stamping

Powder metal raw material is often blended from various elements to achieve the combination of strength, hardness, corrosion resistance, and even magnetic properties you need. Powder metallurgy entails compacting metal powder in a die into mostly the finished shape. The "green" parts then pass through a sintering furnace where high temperatures create metallurgical bonds between the powder particles. 

In stamping, the manufacturer places a metal sheet, typically less than 0.25" thick, on a die. A punch descends onto the sheet, shearing it around the perimeter and producing a flat, 2D blank.

Even just these basic descriptions of each manufacturing process may have clued you in as to how they each perform. Now let&#;s look deeper.

Disadvantages and Advantages of Powder Metallurgy Vs. Stamping

These processes have two things in common: Both need tooling shaped to the geometry of the final part, and both can put out high volumes. So what of the differences? They lie in:

  1. Dimensional precision
  2. Quality
  3. Design flexibility
  4. Affordability (both per part and tooling)
  5. Strength
  6. Speed
  7. Scrap efficiency



1. Precision

Both processes produce profiles with very little part-to-part variability. However, sintering introduces a degree of dimensional distortion that gives the stamping process a small advantage. It should also be noted that PM can produce more than a 2D profile; its inherent advantage is the ability to make 3D shapes with a single stroke of the compaction press.  

Note that with powder metal components, it&#;s important to keep surfaces that&#;ll be formed by the die and lower pressing as straight as possible. In the stamping process, the sheer must be considered. Many customers don&#;t realize that In the PM process, you gain the possibility of straight, clean angles.

 

2. Quality

Both processes yield highly consistent parts. Stamping can leave marks in the metal surface, especially if slugs carry over on the punch. 

Powder metal parts inherently have porosity. Depending on your application, this can be a good or bad thing. Fortunately, advanced compaction techniques can get you to a denser, less porous part than in years past.

Where things really get interesting is magnetic performance.

*F- is basically a pure iron with less than 0.03% sintered carbon

*FY- 17Y is a pure iron alloyed with 0.45% phosphorus 

AISI is a commonly used steel for stamping. The powder metal materials in the chart above -- F- and FY- 17Y -- show &#;

  • Higher permeability (faster response)
  • Lower coercivity (overall better magnetic performance) 
  • Higher induction 

&#; at a given applied field.  The strength and elongation numbers are solid, too.

3. Design Flexibility

One of the trademark advantages of powder metallurgy is design flexibility. Think of it in three ways:

  • Stamping is restricted to how the metal blank can be deformed and is limited by radii, angles, and dimensions. Powder metal parts can be &#;sculpted&#; with material exactly where it's needed, as long as your manufacturer can successfully release them from the die. Think again of the 3D design flexibility.



  • A disadvantage of stamping is its poor edge quality. Shearing results in a combination of deformation and cracking, leaving an uneven and unattractive edge. You&#;re guaranteed to need a secondary finishing operation -- a hassle powder metallurgy avoids.



  • Also among the disadvantages of the stamping process is the need for a somewhat ductile/low-strength metal. This limits stamping predominantly to low-carbon steels and nonferrous materials like copper and aluminum. In PM, you can blend metal powders to the exact composition needed by the finished part.

One limitation of powder metallurgy is part size. With taller pieces, the powder metal manufacturer may struggle to achieve uniform density all the way through, or may not even be able to fit it in the compaction equipment.

4. Affordability (Both Per-Part and Tooling)

Per-part affordability is one of the greatest advantages of stamping processes. But PM is not as far behind as you think.

A caveat: The cost-efficiency of both processes largely depends on project volume. It&#;s rarely going to be cost-efficient to make 10 powder metal stators for your next electric engine design. You could say the same thing about stamping.

If it&#;s feasible to make your component with the stamping process, then stamping is a very logical, economical choice. However, as a stamped component gets more complex, the price will rise.

If your component is complicated and requires multiple dies or a progressive die, tooling and production costs may dictate that powder metal is more efficient. If multiple stampings are a must, the additional fixture and welding costs make PM even more advantageous. Most powder metal components only require one press operation and one set of tools.

 

5. Strength

The nature of stamping operations typically limits you to relatively low-strength materials such as low-carbon iron or steel. High-strength materials tend to break the tools.

Stamped parts can be stiffened by forming ribs and other radii, but the material must have some ductility. Meanwhile, advanced compaction techniques and unique material alloys can make some sturdy powder metal parts. Unlike stamping, PM employs copper and stainless steel alloys -- not only are these strong, they also resist corrosion exceptionally well..

 

6. Speed of Process

Neither powder metallurgy nor metal stamping is ideal for low-volume work.

Powder metallurgy has always been a high-volume technique. If you order a limited number of components, the per-part lead time may disappoint you. It may take the powder metallurgy company almost a month just to get the necessary powder in-house, and you can tack on a few weeks of production after that.

But when you have a need for speed in addition to the many of the qualities above, stick with powder metallurgy. While it&#;s ill-suited for a 10-part order, it&#;s incredibly efficient for 10,000-part orders.

To make up for some of the many shortcomings of stamping vs. powder metal, there&#;s a special type of stamping called fine blanking (AKA fine-edge blanking). This method improves accuracy, flatness, and edge characteristics. But here&#;s the catch: It suffers from significantly slower production speeds than powder metallurgy. Producing complex parts using the thickness inherent to blanking is much more restrictive than with PM.

 

7. Scrap Efficiency

If you&#;re an environmentalist, you&#;ll want to hide your eyes here.

Stamping processes always leave a web of unused material behind. On top of that, since the raw material comes in uniform width and thickness, it may not conform to the blank&#;s requirements. Your manufacturer even consumes material to clamp the sheet metal in the die!

Yes, you can recycle it, but stamping scrap only recoups a fraction of the original cost.

In contrast, material use in the powder metallurgy process is about 97%. If necessary, "green" compacts can be broken apart and reused. No wonder manufacturers call powder metallurgy a &#;green technology.&#;

Your Winner (Plus More Resources)

For thin metal parts from low carbon steel or nonferrous material, stamping is fast and cost-efficient. When appearance matters or the part needs special strength or magnetic properties, or complex features, powder metallurgy leads the pack.

It all comes down to the needs of your project. Are you OK with throwing away 50% of your material? Do you need a more daring design that improves magnetic performance?

While you&#;re pondering those possibilities, check out our free e-book below.  It assesses the pros and cons of powder metallurgy vs. machining, stamping, casting, forging, MIM, and more. Don&#;t miss the chance to learn a new trick nobody&#;s taught you yet!

Want more information on stamping press cost-effective solutions? Feel free to contact us.

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