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This article covers all the information you need to know about Metal Stamping.
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Metal stamping is a coldworking process that transforms sheets or coils of metal into specific, preset shapes. It uses specialized tooling that involves the stroke of a punch to bring conformational change to a metal sheet. With a sufficient amount of force, a metal stamper can cut or form a metal sheet into a pre-engineered desired shape.
The process of stamping begins with designing the tooling for the process using computer aided design (CAD) and computer aided manufacturing (CAM). The tooling is precision engineered to ensure that each punch, bend, or cut has the proper clearance to produce high quality parts. CAD renderings can be complex and intricate in order to create tooling with hundreds of parts and components. Once the tooling is completed, there are any number of options a manufacturer can use to produce the final part.
The many types of metal stamping methods fall into three categories, which are progressive, fourslide, and deep draw. Progressive die stamping involves several stations with each station performing a single step of the stamping process. With fourslide stamping, four tools are used at the same time to reshape and form the workpiece. Deep draw stamping refers to a process where the workpiece is pulled into a punch where it is formed using a punch. Each of the processes is beneficial in creating components for specific industries and applications.
A metal stamper is a versatile machine that is capable of a broad range of cutting and forming operations. It can combine multiple cutting and forming steps in one tooling and may be performed on the workpiece within a single stroke. Multiple parts can be processed simultaneously in the same stroke. Metal stampers are easily automated and controlled, which benefits the metal fabricators by increasing their production rate, reducing labor costs, and improving parts’ quality, repeatability, and precision. Combined with accurate tooling, they can produce parts with complex designs quickly and efficiently.
Metal stampers can create a variety of useful products from a simple washer, springs, hinges, and brackets, to parts with sophisticated designs such as those found in structural components, engines, industrial machinery, and automotive components. Stamped metal products are beneficial to many industries and end customers.
There are several types of metal stamping machines, each designed for specific applications. Here are some common types of metal stamping machines:
Mechanical presses are widely used for metal stamping. They use a mechanical system, typically a crankshaft and flywheel, to generate force and perform stamping operations. They are known for their precision and reliability.
Hydraulic presses use hydraulic cylinders to generate force for metal stamping. They are capable of exerting high levels of force and are often used for deep drawing and forming operations.
Servo presses are a modern variation of mechanical presses. They use servo motors for precise control over the speed and force of the stamping process, which allows for more flexibility and customization in stamping operations.
Progressive die stamping machines are used for high-volume production of metal parts. They have multiple stations, each performing a different operation as the metal strip passes through, making them efficient for continuous production.
Transfer presses are used for complex stamping operations that require multiple steps. They use a transfer system to move the metal between different stations within the machine.
Fine blanking presses are specialized machines used for producing precision parts with extremely tight tolerances. They are often used in industries where part accuracy is critical, such as the automotive and aerospace sectors.
Punch presses are versatile machines used for various metalworking operations, including blanking, piercing, and coining. They come in both mechanical and hydraulic variations.
Turret punch presses are primarily used for sheet metal fabrication and are designed to punch holes, cut shapes, and bend metal sheets.
Hot stamping machines heat a die and use heat and pressure to transfer a foil or pigment to the metal surface. They are commonly used for decorative and labeling purposes.
Coining presses are used for creating coins and other high-precision, flat parts with intricate designs. They are designed to produce highly detailed and precise results.
Metal stamping operations refer to the entire process or set of activities involved in shaping, cutting, or forming metal workpieces using stamping machines. The operations involve a series of steps, including design and tooling, material feeding, stamping, quality control, and sometimes post-processing. The types of metal stamping operations employed in a metal fabrication plant are as follows:
In progressive die stamping, a sheet of metal is unrolled, fed into the press and passes through different stations of tooling each of which performs one or more metalworking processes (e.g., cut, bend, and punch). The sheet stays in the conveyor system of the stamper and the part stays connected in its base strip throughout the process.
The workpiece stops at each station and is shaped by a die before it moves on. After completion of the stamping, the press moves up, and the sheet moves horizontally in the bed. The part is gradually formed as the workpiece progresses through the stations. At the last station, the finished part is ejected from the sheet.
The advantages of a progressive die stamping operation are quick production of parts with complex geometries, tight tolerances, high repeatability, and reduced labor costs. Progressive die stamping combines multiple metalworking steps in a single tooling. Due to the nature of the process of progressive die stamping and its inability to make deep punches, it is not used for parts that require deeper punches.
In transfer die stamping, the workpiece is first separated from the metal sheet and transferred from one stamping station to the other. The separated materials can be transferred to different presses, which enables the fabricator to produce varieties of parts in parallel.
Transfer die stamping is used in forming large parts. Since the part is not connected to its base metal sheet, the punch can go as deep as it can without affecting other operations, hence it is suitable for parts requiring deep drawing. It is also used in processes with intermediate steps in which the separation of the part early in the process would be more efficient.
In fourslide stamping or multi-slide stamping, the rams are aligned horizontally and slide toward the workpiece. It is a unique type of stamping process, different from the traditional stamping process which requires the downward stroke of a press. Each slide has one tool that can simultaneously bend, twist, cut or form in a horizontal stroke. A multi-slide stamping machine can have more than four moving slides.
Fourslide stamping is ideal for creating complex and multiple bends, for bends greater than 900, and for forming cylindrical parts. It has the unique ability to form twists. It can produce parts quickly, has inexpensive tooling, and lower initial cost. It also produces less scrap and reduces material cost because the raw metal piece can be bought to a width closer to the finished part.
In compound stamping, the die can perform multiple operations such as cutting, bending, and punching in one downward stroke. The sheet is continuously fed in the stamper and the finished part is then ejected out from the metal strip. A stroke can create multiple cuts and holes in the workpiece without the use of multiple dies and performing multiple strokes, which reduces production time and augments cost savings.
Compound stamping has good repeatability. However, it is somewhat limited to forming flat metal pieces with simpler geometries, such as washers.
Hot stamping is a process that is commonly used in Europe and Asia where it is known as press hardening and hot press forming. It is a thermoforming process that involves a heat treatment during the stamping process. The process of hot metal stamping developed in the 1970s as a method for hardening steel for the manufacture of agricultural tools. It has evolved since that time as a method for hardening lightweight high strength parts for the auto industry.
The blank for hot stamping is placed in an oven or furnace to heat it to the proper hot stamping temperature. Once the blank reaches 1700°F, it is transferred by press feeding to the hot stamping press that rapidly closes over the blank and holds it firmly for several seconds until it cools. The hardened and formed part is ejected from the press for its final finishing.
The two forms of hot metal stamping are direct and indirect, which differ by how the blank is treated before being subjected to the heating process. In direct hot stamping, the blank is immediately placed in an oven or furnace for heating. With indirect hot stamping, the blank is cold formed prior to the heating process.
Some of the reasons that hot stamping is preferred over cold working are material properties and form and quench tooling. The hardenability of hot metal stamping increases the strength of the workpiece while reducing its weight, which makes the process ideal for producing parts for the auto industry. The quenching and forming of hot metal stamping assists in the workpiece attaining the proper microstructure.
The down side of hot metal stamping is the amount of time it takes to produce each part. A cold stamping machine can make 20 to 1500 strokes in a minute while a hot metal stamping press takes 10 to 30 seconds with each stroke, which can be longer for thicker metals. Delays in the process are further increased by after stamping finishing.
There are numerous machines available to perform metal stamping in the United States and Canada. These machines are essential in today's society as they enable efficient and cost-effective mass production of metal components used in various industries, such as automotive, aerospace, electronics, and appliances, contributing to technological advancements and economic growth. We examine many of these machines and the features that have made them popular below.
The E2W series presses from Komatsu are known for their high precision, reliability, and energy efficiency. They are equipped with advanced servo-driven technology, which allows for precise control of the ram's motion, resulting in consistent and accurate stamping. These machines are designed to reduce energy consumption and lower operating costs, making them a popular choice for various metal stamping applications.
AIDA's NC1 series presses are renowned for their robust construction, high-speed performance, and versatility. They come equipped with advanced controls and automation features, allowing for fast and efficient production. The NC1 series is known for its high precision and ability to handle a wide range of stamping applications, making it a popular choice for metal stamping companies.
The Bliss C1 Straight Side Press is highly regarded for its durability and rigidity, providing stable and accurate stamping operations. Its straight side design allows for easy access to the working area, simplifying die changes and maintenance. These presses are known for their ability to handle heavy-duty stamping applications with ease.
The DSF Series Servo Presses from SEYI are recognized for their precision and high-speed capabilities. They utilize servo motor technology to control the ram's movement accurately, resulting in reduced energy consumption and increased productivity. These presses are often favored for applications requiring complex forming and intricate shapes.
The Heim Maxi Stamper Press is known for its heavy-duty construction and reliability. These presses are capable of handling large and demanding stamping jobs with consistent accuracy. They come equipped with advanced safety features and user-friendly controls, making them a popular choice for various metal stamping operations.
Remember that specific models and their features may have changed over time, so it is recommended that you reach out to manufacturers or industry experts for the most current and comprehensive information on metal stamping machines available in the United States and Canada.
Metal stamping is a collection of several metalworking processes such as blanking, bending, and drawing. A metal stamper is a versatile machine that is capable of many metalworking tasks which transform sheet metal into a useful one. The capabilities of metal stampers are grouped into cutting and forming.
Cutting is the application of a sufficient shearing force to separate material into portions. The shearing force must exceed the material‘s ultimate yield strength for the material to fail and separate at the cut location.
Blanking is a metal fabrication step in which the workpiece is cut from its base metal sheet. The downward stroke of the punch shears the outline of the workpiece. The cut-out is called a blank. It is usually the first step in a metal fabrication process. It makes the workpiece more manageable to handle for the succeeding operations. The excess material is scrapped and may be recycled.
A special type of blanking is fine blanking, in which the base metal sheet is supported by high-pressure pads. One of the pads is equipped with an impingement ring (V-ring) which pierces the perimeter of the piece before contacting the die and prevents the metal from flowing away while pushing it towards the punch. It uses a counterdie to provide a reciprocating pressure at the bottom of the workpiece and maintain its flatness. The tight clamping and balanced pressure prevent plastic deformation from occurring which results in smoother and fully sheared edges. After punching, the tool is opened and an ejector pin at the bottom half pushes the finished part.
In fine blanking, the clearance is minimized to less than 0.0005 inches to achieve a fully-sheared edge when combined with high pressures. The clearance is much smaller compared to traditional punching. Hence, it is prone to accelerated tool wear because of the occasional contact between the die and the punch. Deburring is necessary since the impingement ring consumes a small area that is attached to the finished part after punching.
Fine blanking is ideal for parts that require flatness, geometric accuracy, and must have smooth edges. It can also pierce small holes in the part. However, it is more expensive compared to traditional blanking.
Punching, or sometimes referred to as piercing, works in a similar fashion to blanking. It is the process of boring small shapes (e.g., holes) in the workpiece by application of a shearing force. A portion of the blank is cut from the blank and is discarded after ejection. Punching may be combined with the blanking step in a single downward stroke of the punch.
Trimming is the step in which the width is reduced to its desired profile by cutting out the outer perimeter of the workpiece. The excess material is often discarded or may be recycled.
Lancing is the step in which a portion of the workpiece is partially cut without separating it from its base sheet.
Forming is the re-shaping of a section in a material by applying a combination of compressive and tensile stresses to induce deformation. This process involves using dies and punches to deform the metal, creating bends, curves, or complex shapes
Bending is a metalworking process of forming an angle or a curvature in the workpiece by inducing a plastic deformation to form the bend. It is done by forcing the forming die in the workpiece which is fixed in an opposing bottom die. The downward stroke of the punch gives the bend profile to be enforced in the workpiece. Some of the bending methods that can be performed in a stamping process include the following:
In bottom pressing or bottoming, the punch presses the workpiece and touches the bottom surface of a V or U-shaped die. The die determines the final angle of the bend. This method produces precise bends and has less tendency of a springback in the workpiece as more bending force is applied.
In air bending or partial bending, the punch presses the workpiece partially so that it will not touch the bottom surface of the die. A sharper bend can be achieved by applying more bending force. This method is less accurate than bottom pressing and coining.
Coining is a bending process that compresses the workpiece between the punch and the die. The compressive force is 30 times greater than the other bending process. The punch and the die complement each other and its internal dimensions give the exact angle or curvature to the workpiece. This method produces a more accurate bending and eliminates the tendency of a springback.
In flanging or wipe bending, the workpiece is held between the bottom die and the upper pressure pad, and the protruding material is pushed down by a forming punch. The springback is compensated by modifying the die and punch angle. This method is suitable for making perpendicular bends.
Drawing is a metalworking process of forming the blank into a hollow or concave shape with a seamless edge and parts with several diameters. It is performed by clamping the blank into a die by a blank holder and forced through it using a drawing punch. As the draw punch strokes downward towards the cavity, the workpiece experiences a complex sequence of stresses and deformation to form the finished part.
When the blank is drawn longer than its diameter, it is considered a deep drawing. Otherwise, it is referred to as shallow drawing.
Coining is a metalworking process of modifying the roughness of the surface of the workpiece by applying compressive stress resulting in plastic deformation. This operation results in a reduced surface grain size and a harder surface in the workpiece while maintaining its toughness and ductility.
This operation is different from coining in bending. It is used in manufacturing coins, buttons, and badges.
Embossing is a process where a design or pattern is raised above the surface of the metal. Debossing is the opposite, where the design is pressed into the metal, creating a depressed area. These processes are accomplished by pressing the workpiece against a male and female die. These processes are used to label or decorate a workpiece by adding unique and specific details such as texts, logos, and images.
Dies are the sets of tooling used to cut or shape the material to create specific customized parts. Dies may be classified as a cutting die or forming die, but they have almost the same components:
Die assemblies are classified as follows:
Simple dies are dies that can perform only one task per stroke. It is commonly utilized for fabrication processes with few steps and for processing workpieces of low volumes. It may be less efficient but these specialized dies can perform a cutting or bending operation more precisely.
Compound dies perform more than one cutting operation per stroke, such as simultaneous blanking and piercing that is usually combined. They are used to produce parts with multiple cuts and complex designs, which perform the task faster. However, they are not suitable for forming operations as these processes require more force. A typical application of compound dies is in the production of flat washers.
Combination dies are sophisticated dies that are capable of performing more than one cutting and forming operations by a single stroke. Simultaneous cutting and forming (e.g., trimming and flanging) done in the workpiece speeds up the production time.
Progressive dies are used to gradually cut or form a workpiece by passing through the series of stations arranged within the die according to the sequence of steps involved in the fabrication of the part. The metal sheet is continuously fed in the metal stamper. It moves horizontally on the stamper‘s conveying system when the die is open, then stops at the next station after the other. The distance between each station of the die is equal to each other. The final step is usually the ejection of the stamped part out from its base sheet.
Transfer dies are a series of multiple dies that are arranged on the production floor according to the sequence of steps involved in the fabrication of the part. Its operation begins with the workpiece being separated from its base metal sheet in the first station, and then transferred to the series of dies by a conveying system. Two or more sets of transfer dies may be used to run different products in parallel.
Transfer dies are used in the fabrication of parts that are large and have complex designs which require specialized dies to operate precisely.
The metals commonly processed in a stamping process are the following:
Copper alloys are popular choices for stamping processes because of their excellent electrical conductivity, corrosion resistance, and malleability. Common copper alloys used in stamping include:
Brass is an alloy of copper and zinc. It's known for its attractive gold-like appearance and is often used in decorative and architectural applications. It is also used in electronics, plumbing fittings, and musical instruments.
Bronze is an alloy of copper and other elements such as tin, aluminum, or silicon. It is known for its durability, making it suitable for applications like bearings, bushings, and sculptures.
Steel is a wide class of alloys that mainly consists of iron and carbon. Their mechanical properties primarily depend on the concentration of their alloying elements. Higher carbon content makes steel harder, more brittle, and less ductile. Meanwhile, higher nickel and chromium content make the steel more corrosion-resistant. Generally, steel alloys have high strength and high toughness and can withstand extreme temperatures, but they are quite challenging to be stamped.
The common steel alloys in metal stamping include stainless steel and carbon steel.
Common steel alloys used in stamping processes include:
This is a basic alloy of iron and carbon. It is widely used in automotive parts, machinery, and construction materials due to its strength and affordability.
Stainless steel contains chromium, which provides excellent corrosion resistance. It is used in applications requiring both strength and resistance to rust and staining, such as kitchen appliances, medical equipment, and outdoor architectural elements.
Aluminum is a low-cost, lightweight, and non-ferrous metal. It is also corrosion-resistant, can withstand extreme temperatures, has good thermal and electrical conductivity, and has a high decorative value. Because of its ductility, flexibility, malleability, softness, and high strength-to-weight ratio, it can be stamped smoothly without failing.
Commonly used aluminum alloys include:
This is a commercially pure aluminum alloy with good formability. It's used in applications like food packaging, chemical equipment, and heat exchangers.
This alloy combines good strength with excellent workability, making it suitable for applications like cooking utensils, heat exchangers, and automotive components.
Known for its high strength and heat-treatable properties, it's used in aerospace, automotive, and structural components.
This alloy offers good corrosion resistance and is often used in marine applications, signage, and fuel tanks.
Here are some of the key advantages of using metal stamping:
The speed and efficiency of stamping processes reduce labor costs and minimize material waste, making it an economical choice for mass production. Additionally, the durability of stamping dies means they can produce thousands or even millions of parts before replacement, further lowering overall costs.
Metal stamping offers a high degree of precision and accuracy in producing parts. Computer-aided design (CAD) and computer numerical control (CNC) technology can be used to ensure the exact dimensions and tolerances of the parts.
The automation of many stamping processes, such as progressive and transfer stamping, allows for rapid production, resulting in shorter lead times. This agility is essential for meeting tight production schedules and responding to market demands promptly.
Metal stamping is versatile and adaptable to various metals, including steel, aluminum, brass, and copper. This versatility allows manufacturers to produce a wide range of components for different applications and industries, from tiny intricate parts in electronics to large structural components in construction.
Metal stamping minimizes material waste through precise cutting and forming processes. This not only reduces raw material costs but also contributes to environmental sustainability by reducing scrap and energy consumption during production.
Stamping can produce complex and intricate part geometries with high precision, often in a single operation. This is advantageous in situations where complex shapes and designs are required, as it eliminates the need for multiple manufacturing steps and secondary operations, streamlining the production process.
Stamped metal components tend to be robust and durable due to the cold-working process. The process work-hardens the metal, enhancing its strength and resistance to wear, corrosion, and other environmental factors. This durability is particularly important for applications requiring long-lasting and resilient components.
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