How accurate is metal stamping?

Metal stamping is ideal for quick production of both specialized precision components and simple industrial parts and has several advantages.

When you need customized components, you want quality and you want them fast. With advances in metal stamping technology, you can reap the benefits of getting your components just the way you want.

Please visit our website for more information on this topic.

Metal stamping is ideal for quick production of both specialized precision components and simple industrial parts. Applications that benefit from metal stamping encompass various industries, but all stamped components share the same advantages:

Extreme Precision

Metal stamping can produce highly accurate parts within extremely tight tolerances. 

Production Volume

After the die has been created, metal stamping can be used to complete high-volume production runs quickly and efficiently.

Versatility

Metal stamping can be used to create components in a variety of shapes and sizes, from micro-stamped components to engine housings. Round components are inexpensive to manufacture when compared with other fabrication methods.

Process Control

The metal stamping process can be controlled strictly from conceptualization of your component through finishing, so your part is assembly-ready upon completion.

Cost Efficiency

With metal stamping, cost efficiency is one of the biggest reasons why companies are beginning to take advantage of this process. Dies are relatively less expensive to produce and maintain than those used in other common processes. Speeding up the production process requires less machine use, fewer laborers, and reduced labor time, which means your overall expenses will drop.

Longer Runs 

The continuous material feed used in the progressive die stamping process allows for long runs.   Longer runs between material changes and tooling adjustments mean your parts can be produced in a much shorter time.

High Repeatability 

The hard tooling die designs allow for high-volume runs without die degradation.  This means that part quality remains high and there are fewer failed parts.

Quicker Setup 

When compared to traditional fabrication or machining, the setup time may be much less for the progressive stamping process. What is achieved in multiple setups and processes during traditional fabrication and machining, may be performed in one operation if progressive die stamping is utilized. 

Less Scrap Material 

Progressive stamping is a metalworking method that can encompass punching, coining, bending, and several other ways of modifying metal to produce your desired end part shape. The vast majority of the material is used, hence, less scrap is produced. What is left over is recycled.

 

Emphasizing Quality

At AMS, we use the best of the best machines and technology. We know that metal prices are always fluctuating, but we do our best to keep costs low and quality high for our customers. Our in-house integration system makes sure that your product is produced in a timely manner. We specialize in the stamping of tight-tolerance, close-pitch, high-precision, and light-gauge metal components, as well as thicker gauge, larger metal components, and assemblies. 

We can customize a myriad of precision metal stamped solutions tailored to your specific end-application needs, and produce them to your exacting specifications. By placing an emphasis on quality, we maintain robust internal tooling capabilities that ensure all our progressive stamping tools exceed customer requirements. 

By Leslie Radford

What is Precision Metal Stamping?

Precision metal stamping is a high-volume metalworking process that uses stamping tools to create sheet metal components by forcing the material into an impression of the desired shape. This is done according to a pattern, with each part removed from the main sheet after being stamped.

The precision metal stamping method allows manufacturers to make parts that require undercuts, multiple features, or fragile walls for assembly.

It uses high pressure equipment to force sheet metal into dies, so products are shaped with geometric accuracy and excellent surface finish at the same time.

Advantages of Precision Metal Stamping

Precision metal stamping offers a variety of advantages for both manufacturers and end-users. These include:

High Volume Production

Precision metal stamping can make thousands to millions of parts in a single run. That is a higher production rate than other metalworking processes, such as CNC machining, fabrication, or welding.

This process is perfectly suited to high-volume manufacturing, where metal parts are made in large quantities.

Uniformity

Precision metal stamping is versatile, producing a variety of components with the same tooling, and little- to-no additional setup or adjustment between production runs.

Because of this, precision metal stamping has a higher degree of uniformity when compared to other industrial processes. Since all the products are stamped from sheet stock, they have equal wall thicknesses and nearly identical surface finishes, making assembly and quality control inspections easier post production.

Featured content:
Key Questions to Ask When Choosing Stainless Steel Kitchen Appliances
10 Facts You Should Know about Erw Steel Pipe

greatlionparts contains other products and information you need, so please check it out.

Precision metal stamping also supports mass customization of the end product by automating changeable designs, which allow meeting the customer&#;s unique requirements quickly.

Quality

Precision metal stamping is a versatile process capable of producing a range of components with different surface finishes and tolerances.

It also produces parts with thin walls, deep draws, and undercuts, which are otherwise challenging to produce using other processes, such as CNC machining or fabrication.

This makes precision metal stamping an excellent choice for the aerospace, medical implant, automotive, lighting, and consumer electronic product development sectors, where precise shapes and thin walls are desired features.

Precision metal stamping is one of the few technologies that can produce the specific thin-wall geometries required for demanding electronic packaging applications because of its ability to make deep drawing features.

Ease of Use

Engineers and designers find precision metal stamping easy use to because it makes complex shapes with minimal tool changes.

This capability offers greater design flexibility for clients, opening the door for concept exploration in the early stages of product development.

It also helps them reduce costs by minimizing material waste because fewer die changes are needed for each new part design iteration.

Precisely designed components are easier to manufacture using precision metal stamping, as they require less machining time in secondary processes throughout the production run. This results in more efficient workflows, especially where production volumes are high.

Minimizes Material Waste

Precision metal stamping is an economical manufacturing process because it uses the minimum amount of material needed to make the parts.

This feature allows manufacturers to make products with thin walls with no complex secondary operations, such as CNC machining, which can be time-consuming and expensive.

Cost Efficiency

Precision metal stamping has low startup costs compared to the large die-cast machines used for mass production. So, it is beneficial when production needs are not high volume but are still relatively high in quantity.

It also offers high flexibility, with the design options available to manufacturers to work on clients&#; custom projects that cannot be produced any other way. This means higher profits for them without needing too much initial investment to get started.

Minimal Secondary Operations

With precision metal stamping, secondary operations, such as cutting threads after production, are not usually necessary. The process creates accurately shaped features, concurrently, leaving no room for error, like pre-drilling holes, counter-sinking, or cutting threads. Secondary operations often increase cost and time to market, but hand finishing is minimal after stamping, again, saving money and time.

Considerations When Using Precision Metal Stamping Techniques

Surface Quality

The surface quality of stamped parts depends on the metal being used, its hardness, thickness, and whether it is heat-treated after being stamped. Softer materials are prone to scratching during stamping, while thicker metals are less prone because of their increased tolerance for pressure from the tooling. Heat treatment helps to improve the metal&#;s grain structure, making it harder and more resistant to wear and tear without compromising the material&#;s strength.

Undercuts

Undercuts can cause difficulties during the stamping process, as they make it hard for the tool to penetrate the sheet metal completely.

One way of addressing this issue is by using a progressive die instead of using one large die to cut out all the parts&#; shapes in one go. Multiple dies perform minor cuts until all the part&#;s features are achieved. Progressive stamping also reduces the force required to release undercuts but, it also limits production speed and can cause irregular shapes that need secondary operations to clean up.

Tolerances verse Accuracy

Tolerances refer to how much variation is allowed in dimensions within the part&#;s design, while accuracy refers to how close the final measurements are to the intended dimensions.

Precision metal stamping can achieve accurate dimensions with tight tolerances because, unlike other manufacturing processes, it uses a controlled force to produce components,.

Parts produced with this process match specifications more closely than parts made from alternate methods, such as CNC machining or welding.

Material Strength vs. Tool Wear

To keep costs low, manufacturers often use softer, less expensive metals for tool making. However, using less robust tools creates a tradeoff in material strength, adversely affecting design and quality, especially when thin-walled geometries are required for a product. Such tools can put undue compressive stress on components.

Pressure from the tool is the leading cause of material deformation, so it is essential to consider this tradeoff when designing parts for metal stamping.

Product Complexity vs. Costs

The complexity of the part&#;s design determines how many tools are required to make all its features. However, manufacturers may work around this cost by performing secondary operations on specific components in the same production run, rather than making unique tooling for complex shapes or geometries, such as undercuts.

This makes it possible for manufacturers to produce multi-component products with multiple materials in one run without increasing costs.

What To Look for in a Precision Metal Stamping Partner

Experience and Knowledge

Experience plays an important role when using precision metal stamping in an assembly, and
a knowledge of the process itself, in combination with experience in working with different metals and tolerances, is key to ensuring that parts are made within specifications while also maintaining their strength.

Machine Capacity

Part design directly affects machine capacity. capacity can be limited by material thickness and the overall maximum pressure used on the sheet metal during production. It is essential to make sure machines used for this method can handle the component&#;s weight and size, while also considering the part geometry and quantity needed per run.

Tool Quality

Materials used may reduce or increase tool wear and raise or lower costs, so finding a balance between hardness levels and the tool&#;s life is essential. The frequency with which a manufacturer will use precision metal stamping to produce parts determines the wisdom of investing in high-quality tools that last longer and have less downtime between production runs.

Quality Control Measures

Best practices for quality control with this manufacturing method are to check dimensions after the part is released from the press and then performing secondary operations to reduce the number of unique tools required for each part produced.

Customization of Presses

Machines used for precision metal stamping can be modified with different tooling components to create unique shapes and features needed for products.

Manufacturers offering this service can alter equipment controls to reduce cycle times or create fixtures for secondary operations if needed.

Stamping Capabilities

When choosing a manufacturing partner, remember metal stamping capabilities vary widely across machine models, making it is essential to consider what types of parts are being made, which metals are used in production, are they thick or heavy, etc.

It is also wise to ask about the secondary operations the company offers, and whether machines used for this process are customizable. This is because specific customization options may be more expensive depending on the manufacturer.

Precision Metal Stamping Capabilities and the Industries We Serve

MicPro Precision offers comprehensive in-house metal stamping services, drawing on our research and development team&#;s extensive experience in design, prototyping, and production of highly durable parts. Clients have access to our broad spectrum of stamping capabilities, which include accommodating various metal thicknesses, selecting the type of metal, and specifying the dimensions of the metal sheet.

Our facility is outfitted with cutting-edge machinery, including sophisticated press brakes and transfer presses that are adept at manufacturing robust parts as well as precision components from thin gauge metals. Our distinction in the industry lies in our ability to fabricate delicate parts without compromising on quality.

MicPro Precision&#;s proficiency encompasses a wide range of materials, enabling us to fulfill the varied requirements of our clientele. We handle materials from robust metals to versatile plastics, all with exceptional precision and efficiency. Our stamping capabilities are versatile, handling material thicknesses ranging from 1/8&#; to .005&#; (4mm to .1mm), positioning us to undertake projects demanding both sturdy and fine components.

The commitment at MicPro Precision to deliver excellence is mirrored in our investment in state-of-the-art equipment. Our facilities, featuring advanced press brakes and transfer presses, are engineered to process diverse materials and thicknesses with utmost precision. This fusion of our extensive capabilities and unwavering commitment to quality establishes MicPro Precision as the partner of choice for clients in need of durable, high-quality metal stamping solutions.

Summing Up

Precision metal stamping is a highly versatile manufacturing process utilized across various industries. It plays a crucial role in producing metal parts with complex geometries and intricate features that would be impractical or cost-prohibitive to achieve through alternative methods like die casting or machining. When considering the most suitable metal stamping process for a project, manufacturers need to carefully evaluate factors such as budget, machine capacity, and tool quality. However, precision metal stamping has gained a reputation for its exceptional accuracy and reliability, making it a preferred choice for many applications.

The process of precision metal stamping offers numerous benefits. Its ability to create intricate shapes and features with precision ensures that the final parts meet demanding specifications. This level of accuracy is essential for industries where tight tolerances are critical, such as aerospace, automotive, and medical sectors. By utilizing advanced stamping techniques, manufacturers can achieve consistent results and maintain the highest quality standards throughout production.

Moreover, precision metal stamping enables cost-effective manufacturing solutions. The efficiency and speed of the stamping process allow for large production volumes, reducing the overall unit cost of each part. This is particularly advantageous for projects with high-volume requirements, where economies of scale can significantly impact the bottom line. Additionally, the automated nature of precision metal stamping minimizes the need for labor-intensive processes, leading to increased productivity and reduced labor costs.

Furthermore, precision metal stamping offers enhanced material utilization. With careful design and optimization, manufacturers can maximize material usage, minimizing waste and reducing material costs. This is especially beneficial for projects that require expensive or rare materials, as precision metal stamping ensures efficient utilization and reduces material waste.

In conclusion, precision metal stamping is a highly effective and efficient manufacturing process, capable of producing complex geometries and achieving exceptional accuracy. Its advantages in terms of cost-effectiveness, material utilization, and high-volume capabilities make it a reliable choice for a wide range of industries. By leveraging precision metal stamping, manufacturers can meet demanding specifications, achieve economies of scale, and deliver high-quality metal parts for their projects.

FAQ

What are metal stamping blanks?

Metal stamping blanks are pieces of metal sheet or parts that have not yet undergone any kind of fabrication process. Prior to the fabrication, manufacturers adhere to specific standards and guidelines, considering factors such as hole diameter, geometry, and taper. These criteria determine how the metal will be pierced, bent, and fabricated. For instance, a critical consideration is that the minimum diameter of a hole should be at least 1.2 times larger than the thickness of the material. Furthermore, materials with high tensile strength require a hole diameter of at least 2 times the material thickness. By adhering to these specifications, manufacturers ensure that the metal stamping blanks are prepared appropriately for subsequent fabrication processes.

For more custom precision metal stampinginformation, please contact us. We will provide professional answers.