A Closer Look at Metal Stampings

Author: wenzhang1

Aug. 12, 2024

Construction & Real Estate

A Closer Look at Metal Stampings

What is Metal Stamping

Metal stamping is an essential process in the manufacturing industry as it enables the production of high-quality, precision parts with minimal waste. The process is used to create a wide range of products, including automotive parts, electronic components, medical devices, and household appliances. The ability to produce complex parts with high accuracy and the consistency makes metal stamping a crucial part of modern manufacturing.

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The history of metal stamping can be traced back to the early s when the first machine press was invented. This machine used a flywheel to apply force to a punch, which cut and shaped metal sheets into specific shapes. Over time, the process evolved to include more advanced machinery, such as the hydraulic and mechanical press.

Today, metal stamping has become an integral part of the manufacturing industry, with advanced machinery and techniques allowing for the production of complex parts with high precision and efficiency. The process continues to evolve, with new materials, tools, and technologies constantly being developed to improve the quality and speed of production.

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Process & Techniques

The metal stamping process involves specialized machinery, including dies and punches, to cut and shape metal sheets into specific shapes and sizes. The process is typically performed on flat sheets of metal fed into a stamping press, where they are cut, bent, or shaped using a series of dies and punches.

Metal stamping is a versatile process that can be performed using various techniques depending on the complexity of the part being produced. Here are some of the most common metal stamping techniques:

Progressive Die Stamping

This technique is commonly used for the high-volume production of parts that require multiple operations to be performed on them. It involves feeding a metal strip through a series of dies that progressively cut, bend, and shape the metal into a finished part. Each die performs a specific operation, which can be automated for high efficiency.

Four-Slide Stamping

This technique uses a four-slide machine to bend and shape metal into complex parts. The machine has four moving slides that work together to create intricate shapes. Four-slide stamping is ideal for producing parts with multiple bends and shapes.

Multi-Slide Tooling

This technique is similar to four-slide stamping but uses a machine with more than four slides. The process is used to create complex parts with multiple bends and shapes. Multi-slide tooling is ideal for the high-volume production of small parts.

Deep Drawing Stamping

This technique uses a punch and dies to draw a flat metal sheet into a three-dimensional shape. The process creates parts with deep recesses or shapes that cannot be achieved through other stamping techniques. Deep drawing stamping is ideal for producing parts with a high depth-to-diameter ratio.

Transfer Die Stamping

This technique involves using a series of dies to transfer the metal sheet from one station to another, each station performing a specific operation. The process is used to create complex parts with tight tolerances. Transfer die stamping is ideal for producing large, complex parts.

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Materials Used In Metal Stamping

Metal stamping can be performed on various materials, including metals, alloys, and composites. The choice of material will depend on the specific requirements of the finished part, including the desired properties, strength, and durability.

Tempered vs. Pre-Tempered Metals

Tempered and pre-tempered metals are two different types of metal alloys used in metal stamping. Tempered metals are heated to a high temperature and then cooled rapidly to create a hardened surface. This process is called quenching, making the metal much stronger and more resistant to wear and tear.

On the other hand, pre-tempered metals have been tempered before they are used in stamping. This means the metal has already undergone quenching and has a hardened surface. As a result, pre-tempered metals are more uniform in their hardness and have more consistent mechanical properties, making them easier to work with during the stamping process.

The choice between tempered and pre-tempered metals depends on the specific requirements of the part or component being produced. For example, pre-tempered metals are often preferred for applications where high precision and uniformity are required. On the other hand, tempered metals are often used in applications where the metal needs to be harder and more wear-resistant.

Tempered Metals:

  • Spring Steel (SAE-, SAE--75, SAE-) Annealed and Pre-Tempered
    • Spring steel is a low-alloy, high-carbon steel known for its strength and durability. It is commonly used in metal stamping to produce springs and other parts that require high strength and flexibility. Spring steel can be annealed or pre-tempered to achieve the desired properties for the finished part.
  • Cold-Rolled (CRS-, CRS ) Steel
    • Cold-rolled steel is a low-carbon steel commonly used in metal stamping to produce parts with tight tolerances and a good surface finish. It is easy to form and weld and is ideal for producing parts that require strength and durability.
  • Brass Metal
    • Brass is an alloy of copper and zinc commonly used in metal stamping to produce parts that require corrosion resistance and good conductivity. It is easy to form and flexible, making it ideal for producing complex shapes and parts.
  • Beryllium Copper
    • Beryllium copper is an alloy of copper and beryllium commonly used in metal stamping to produce parts that require high strength and conductivity. It is ideal for producing parts requiring excellent fatigue and corrosion resistance.
  • Stainless Steel 301
    • Stainless steel 301 is a high-strength, low-carbon steel commonly used in metal stamping to produce parts that require excellent strength, corrosion resistance, and flexibility. It is ideal for producing parts that require good formability and weldability.
  • Stainless Steel 304
    • Stainless steel 304 is a low-carbon steel commonly used in metal stamping to produce parts that require good strength, corrosion resistance, and formability. It is ideal for producing parts that require good weldability and high durability.
  • Aluminum:
    • Aluminum is a lightweight, low-density metal commonly used in metal stamping to produce parts that require good strength, durability, and corrosion resistance. It is ideal for producing parts that require good formability and weldability.

Pre-Tempered Metals:

  • Martensite is steel quenched and tempered to achieve the high hardness and strength. It is commonly used in metal stamping to produce parts that require excellent wear resistance and durability.
  • Stainless steel, when pre-tempered, is an alloy of steel that has been heat-treated to achieve a specific level of hardness and strength. It is commonly used in metal stamping to produce parts that require strength, corrosion resistance, and durability.
  • Brass, when pre-tempered, is an alloy of copper and zinc that has been heat-treated to achieve a specific level of hardness and strength. It is commonly used in metal stamping to produce parts that require good conductivity, corrosion resistance, and durability.

Metal stamping is a versatile and efficient manufacturing process that involves shaping and forming metals into various parts and components. Several types of metal stamping techniques include progressive die stamping, four-slide stamping, multi-slide tooling, deep drawing stamping, and transfer die stamping. Each technique offers its advantages and is suitable for specific applications. The choice of material is also important in metal stamping, with a wide range of metals and alloys available, including pre-tempered metals such as martensite, stainless steel, and brass. Metal stamping is a cost-effective and reliable process widely used in various industries to produce high-quality parts and components.

Need help determining the right stamping process for your application? Contact us to start a conversation with one of our experienced team members or request a quote today.

Advantages of Metal Stamping

Metal stamping offers numerous advantages over other manufacturing processes. The following are some of the most significant advantages of metal stamping:

  • Cost-Effectiveness
    • Metal stamping is a cost-effective process that allows manufacturers to produce high volumes of parts and components at a low cost per unit. The process involves a high level of automation, reducing labor costs and increasing production efficiency.
  • Precision
    • Metal stamping is a highly precise manufacturing process that allows manufacturers to produce complex and detailed parts with high accuracy and consistency. The process allows tight tolerances and ensures that each part meets the required specifications.
  • Quick Production Turnaround Time
    • Metal stamping is a fast and efficient manufacturing process that allows manufacturers to produce large volumes of parts and components in a short amount of time. The high level of automation in the process allows for quick production turnaround times, reducing lead times and increasing production efficiency.
  • Versatility
    • Metal stamping is a versatile manufacturing process that can produce many parts and components, including simple and complex shapes, thick and thin materials, and various sizes and dimensions. The process can also work with various materials, including steel, aluminum, brass, and copper.

Metal stamping is a highly efficient, cost-effective manufacturing process that offers precise and consistent results. Its quick production turnaround time and versatility make it an essential process for many industries, allowing manufacturers to produce high volumes of parts and components at a low cost per unit.

Challenges with Metal Stamping

Although metal stamping offers many advantages, there are also several challenges that manufacturers face. The following are some of the most common challenges in metal stamping:

  • Design Complexity
    • Metal stamping can be challenging when producing parts and components with complex shapes and designs. Complex designs can make maintaining the required tolerances difficult and result in production errors.
  • Material Selection
    • The right material for a specific part or component is critical in metal stamping. Manufacturers must select materials that are compatible with the stamping process as well as the final application of the part. Choosing the wrong material can result in product failure, production errors, and increased costs.
  • Maintenance of Machinery
    • Metal stamping machinery requires regular maintenance to ensure optimal performance and prevent downtime. Failure to maintain machinery can result in production errors, delays, and increased costs.
  • Quality Control
    • Quality control is critical in metal stamping to ensure that each part meets the required specifications. Quality control processes must be implemented throughout manufacturing to detect and correct errors or defects.

Overall, metal stamping can be a challenging process that requires careful planning and execution to overcome the challenges that manufacturers face. Design complexity, material selection, maintenance of machinery, and quality control are critical areas that manufacturers must focus on to ensure that the final product meets the required specifications and is delivered on time and within budget.

Why Partner With Apex Spring and Stamping

Apex Spring and Stamping is committed to being a leading manufacturer of metals stampings. By adopting a no-compromise policy on quality and engineering, we ensure customers the most cost effective product for their application. Cost-effective in house methods are used in manufacturing stampings, blanking, bending, drawing, swedging, and chamfering.

Metal stamping is the best cost-effective option for large quantities that require extreme precision and quality. It&#;s is our goal to provide products with:

  • Consistent Quality
  • Long-Lasting Capability
  • Best Value

Apex has equipment with the following production capacities:

  • (20) 45 &#; 250-ton gap frame presses
  • Press bed sizes range from 16.0&#; x 31.5&#; (45 ton) to 34.0&#; x 106.0&#; (250 ton)
  • In die sensing (standard on all tools)
  • Inline (die) tapping (reduced processes/handling)
  • In die staking (reduced processes/handling)
  • Customer-specific designs
  • Low to high volume run capabilities
  • Material Thickness: .010&#; &#; .250&#;
  • Material Width: .079&#; &#; 18.0&#;

Apex Currently Manufactures These Products:

  • Brackets
  • Hinge Plates
  • Stop Tabs
  • Compression Limiters
  • Fasteners
  • Speed Nuts
  • Tinner type clips
  • Automotive Center Console Parts
  • Horn Brackets
  • Wall System Brackets
  • Motion Control Brackets
  • Components for lighting and lamps
  • Products for decorative stamping
  • Components of bearings
  • Automobile components
  • Controls and components for appliances

As a leader in the production of high-quality stamping products, you can be confident in the products, solutions, services, and value we provide to our customers.  It is always our goal to meet and exceed the needs of our customers.

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The History of Stamping Steel for Mass Production Firearms

This modest stamping press can be used for relatively small shop tasks. 

By Will Dabbs, MD

There is a timeless allegory concerning a boiled frog. I know you&#;ve heard it. Though I&#;ve certainly never tried this myself, legend has it that dropping a live frog into hot water results in some frenetic efforts on the part of the amphibian to extricate himself. Purportedly the best way to boil a frog, should you ever wish to do so, is to put him in a pot of cool water and then increase the heat slowly. He will therefore supposedly bask about in the warmth right up until it is too late to react to his dire circumstances.

The classic application of this odd truism is in tolerating deleterious social change. Shocking, radical, transformational cultural changes often result in revolution and violence. However, the same stuff gradually massaged over time can metamorphose a society without anyone&#;s being the wiser. Sometimes the most momentous events can be lost in the background clutter as a result.

This enormous press is as big as a travel trailer and will stamp out stuff as big as washing machine panels and car hoods. 

I cannot fathom ever having need of boiling frogs myself. However, as it applies to our discussion today, I would posit that the world has been radically changing around us and we honestly haven&#;t much noticed it. With familiarity inevitably comes complacency. As regards modern technology, the curve has of late become asymptotic. This simply means that technological advancement is building in an exponential fashion. It is not simply that science is advancing linearly, such stuff is veritably exploding. While consumer electronics represent the most obvious example, you can see this in weapons design as well. The current rarefied state of the art really began with the Industrial Revolution.

The Chinese Type 56 SKS is a great stamped-steel rifle. Learn more about the SKS here

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Origin Story

Historians place the onset of the Industrial Evolution around . Prior to that time if you wanted a product some poor slob had to squat down in the dirt and make it by hand. Thanks to the innovations surrounding automated textile manufacture, steam power, advanced iron making techniques, and the development of machine tools, smaller numbers of workers could produce larger numbers of higher quality products. In short, at the beginning of the Industrial Revolution mankind began using more brains and less hands.

In the world of gun making, this eventually meant standardized parts. We take that for granted these days. If you get a milspec AR parts kit you can rightfully expect all the holes to line up and the sundry components to work without too much fuss. Such was certainly not always the case. The British Land Pattern Musket was first designed in . 4.3 million copies saw service. The Brits affectionately referred to the thing as the Brown Bess. The etymology of the term likely arose as a veiled reference to the prostitutes of the day. Brown meant drab, while Bess was a generic moniker used to address a lowly woman.

Despite such a massive production run (by comparison, we only made 1.5 million Thompson submachine guns in total during WW2), the internal parts of these muskets were all made slightly oversized. Final production involved hand fitting the lock work to ensure smooth, reliable operation. However, in , a contract was let to Eli Whitney, the inventor of the cotton gin, for 12,000 muskets for use by the Continental Army under President George Washington. Whitney&#;s 12,000 &#;smoke poles&#; were supposed to utilize interchangeable parts. One hammer, trigger, or sear should be a drop-in fit on any of the other 12,000 weapons. With that the whole world moved just a little bit.

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These are male and female stamping dies (top) used to produce oven doors. This same basic concept can be used to make all kinds of stuff. This is a typical modern CNC mill (bottom right). It is an enormously capable machine. Progressive stamping dies (bottom left) can press out large numbers of complex parts quickly. (Shutterstock, DRN Studio) 

Now fast forward to World War 1 and you have the planet&#;s first global conflict on a truly industrial scale. Massive factories produced war materiel in volumes previously unimagined. This fact combined with the widespread use of smokeless powder, high explosives, internal combustion engines, and such diabolical stuff as poison gas transformed the way men killed each other. However, throughout it all, most small arms were still cut from big pieces of forged steel one component at a time.

A cursory study of the major weapons of the day makes this obvious. Guns like the P08 Parabellum Luger, the M pistol, and the Browning Automatic Rifle all started as big billets of forged steel. Like Michelangelo&#;s David, the machine operator then simply removed everything that wasn&#;t a gun receiver. What&#;s left is a sort of mechanical objet d&#;art. This technique makes superb reliable weapons, but it is time consuming and tedious. Nowadays, we use computer-controlled milling machines that are breathtakingly capable. Back then you would just have a lot of machines and a lot of operators. One guy might perform the same milling process on a zillion pieces of stock sequentially passing them on to the next guy who did the next function. Do that enough times and you&#;ve built a bunch of guns.

In the interwar years, gun designers began experimenting with different kinds of production techniques. The electrolytic extraction of elemental aluminum from bauxite ore introduced this material into the manufacturing milieu, particularly for aircraft applications. However, one of the most transformational additions to the industrial landscape was the perfection of mechanical stamping techniques.

Sheet Steel Stamping: The Keys to the Kingdom

It takes a fair amount of experience to learn how to run these big machines efficiently and well. The end result can be pretty satisfying, however. This M3A1 Grease Gun is the product of extensive industrial stamping processes. 

Imagine you take a standard green Army man from your childhood and press him face first into a generous block of Silly Putty. Once you remove the Army man you have a detailed impression left in the Silly Putty medium. Industrial metal stamping similarly uses male and female dies to form complex shapes in sheet stock.

As it applies to firearms, a stamping die is carefully cut from steel that is made tough and hard enough to withstand many thousands of mechanical cycles under extreme pressure. These dies are typically made male and female. There are dozens of considerations to include when making such stuff. A skilled die maker will take into account such things as mechanical springback and burr management as well as ensuring that the deformation is not so extreme as to render the final parts brittle. There is an art to this process. A successful die maker combines a baseline mastery of metallurgy and materials science with the knowledge of how these materials will behave practically that is borne of experience. Creating the dies required for industrial stamping operations is both tedious and expensive. However, the end result is the capacity to create vast quantities of identical stamped parts quickly and at very reasonable cost.

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Industrial stamping can incorporate a variety of specific processes into a single die stroke. These can include punching, bending, embossing, flanging, coining, and blanking, to name but a few. Maintaining the required clearances, tolerances, and respect for the mechanical capabilities of the underlying material comes from experience and training. The design process leading up to a large-scale industrial stamping endeavor is time-intensive and complex.

There are three major types of stamping processes. Progressive die stamping incorporates a series of stations, each of which performs a separate function. In this way a piece of blank stock, frequently maintained on a roll, can be progressively manipulated to form complex shapes. Fourslide or multi-slide stamping involves the use of four different slides or tools that work a part simultaneously. This process allows for intricate cuts and complicated shapes along with greater flexibility for subsequent design changes. This equates out to versatility at the expense of speed. Deep draw stamping involves forming material into a part using a punch that defines the ultimate shape. The term &#;Deep Draw&#; applies when the depth of a part exceeds its diameter. Many automotive and aviation components are made this way, as are cartridge cases.

The MP40, MP43, and MG42 shown here are all produced predominantly via steel stamping. The German MP40 was one of the first mass-produced stamped steel weapons. The MP43 assault rifle was the archetypal WW2-era stamped steel infantry weapon. It changed the way the world looked at military firearms. 

In the manufacture of cartridge cases, a single brass slug called a cup is drawn through a variety of sequential steps to form a complex ammunition case. When necessary the case is annealed at certain points in the process to soften the metal sufficiently to allow further deformation. Annealing is a type of heat treatment wherein a piece of metal is heated sufficiently to relieve internal stresses brought upon by mechanical deformation. By annealing these components stepwise, a relatively bulky starting substrate can be deformed into something truly extraordinary. By way of example, the cup that eventually becomes a .50-caliber BMG round starts out as a little chunk of brass about the size of my thumb.

Making Dies

The primary tools used to create forming dies are CNC milling machines and EDM cutters. CNC stands for Computer Numerically-Controlled, and these machines are simply amazing. Multi-axis machines can craft complex three-dimensional parts out of such stuff as steel and aluminum in a manner akin to sculpting. Various cutter bits approach the work from various directions, removing material until the desired part is all that remains.

Prior to beginning the machining process, design engineers use software like Solidworks to digitally craft a component electronically. In this way, dimensions and manufacturing efficiencies can be optimized prior to actually cutting any metal. These advanced software suites can even combine parts in the digital realm to ensure that tolerances are adequate and nothing interferes with anything else while in motion.

EDM stands for Electrical Discharge Machining. This process is also known as spark machining, spark eroding, die sinking, wire burning, and wire erosion. In this case a series of rapidly recurring electrical discharges run through a thin brass wire is used to make incredibly precise cuts even in thick, heavy material. The process must be undertaken between two electrodes separated by a dielectric liquid.

This process was pioneered during World War 2 by a pair of Soviet scientists investigating a cost-effective method for cutting tungsten, and exceptionally hard element. At the same time but independent from their Soviet counterparts, a group of American scientists was perfecting the same process for use in removal of broken drills and taps from aluminum castings. Nowadays EDM machines are common in most well-equipped tool and die shops. A proper machine shop is a veritable playground for me. Amidst a myriad of cool mechanical toys to be found therein, the EDM machines are my hands-down favorite of them all.

Applications

The HK MP5SD shown disassembled here is an extremely high-quality firearm built using extremely frugal manufacturing techniques. The stamped steel receiver aids in mass production. 

That&#;s a lot of tedious technical stuff for a gun magazine, even one as highbrow as Firearms News. However, the ultimate impact these techniques have had on the modern gun world would be tough to overestimate. Evidence of such stuff surrounds you every time you visit the local gun emporium. The most stark delineation between the processes of machining and stamping can likely be found in the wartime German MP38 and MP40 submachine guns. These two weapons are externally very similar. You could be forgiven should you have difficulty telling the two guns apart in dim light. However, their manufacturing techniques were altogether different as driven by the exigencies of total war.

The MP38 was likely the first mass-produced military weapon to eschew wood of any sort. The receiver for this open-bolt, blowback-operated submachine gun was machined out of a piece of drawn steel tubing. This means that the Germans took a piece of steel pipe and then cut away everything that wasn&#;t an MP38 receiver using machine tools. The end result included longitudinal flutes machined in to minimize weight and maximize stiffness. The pistol grip/fire control unit of the MP38 was machined out of an aluminum casting as well.

The subsequent MP40 looked about the same, but its receiver began life as a sheet of steel stamped out and folded over a mandrel. The MP40 fire control unit was also stamped out of sheet steel as well. Additionally, the barrel was slipped in place and secured through an industrial stamping operation that mashed the receiver wall into grooves cut in the trunnion. The end result, once all the dies and such were perfected, allowed semiskilled workers to churn out vast numbers of components at very reasonable cost in a short period of time.

The MP43 assault rifle was the next step in this mechanical evolution. Everything that could be stamped on the MP43 was stamped. This included the receiver, the rear sight base, the ejection port cover, the fire control unit, the magazine, the front handguard, and the stock mount. These pieces were then welded together as needed. These streamlined techniques allowed the Germans to produce 425,977 copies in less than two years despite aggressive strategic bombing and an omnipresent shortage of raw materials.

Meanwhile on our side of the pond, the Guide Lamp division of General Motors was churning out M3 Grease Guns. These stubby utilitarian pressed steel submachine guns were designed from the outset to be cheap and easy to make. The Grease Gun receiver was stamped as two mating halves that were subsequently welded into a functional whole. The front aspect was threaded to accept the barrel nut. While the end result was undeniably ugly, the weapon was compact, reliable, and effective. I shoot markedly better with the old Greaser than I do with the much more expensive Thompson SMG.

Ruminations

The rear sight base of the MP43 was a pressed steel component welded in place. The fire control unit and selector lever were both formed from stamped steel components. The forward handguard on the MP43 gets hot quickly, but it was easy to press out in quantity. 

Mechanical evolution marches on. Nowadays aluminum casting techniques combine with high speed mills to facilitate such stuff as low cost AR-15 receivers. Mass-production mills churn out components like pistols slides multiple copies per cycle. Such stuff is precise, strong, and lightweight. However, industrial stamping still shapes the gun landscape even today.

All of the roller-locked HK guns and their clones are built around low-cost stamped steel receivers. The same can be said for the CETME-L from Marcolmar. Additionally, if you have ever driven a car, used a clothes drier, or cooked on a stovetop you have likely benefitted from some sort of stamped steel components. Likewise, the chassis of every desktop computer on the planet began life as a flat piece of sheet steel punched, bent, and formed into shape. All of these commercial products are built using the same industrial stamping techniques perfected in the manufacture of war materiel during World War 2.

About the Author

Will is a mechanical engineer who flew UH1H, OH58A/C, CH47D and AH1S aircraft as an Army Aviator. He is airborne and scuba qualified and summited Mount McKinley, Alaska, six times&#;at the controls of an Army helicopter. After eight years in the Regular Army, Major Dabbs attended medical school. He works in his urgent care clinic, shares a business building precision rifles and sound suppressors, and has written for the gun press since .

If you have any thoughts or comments on this article, we&#;d love to hear them. us at .

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