Metal Forming of Brackets in Bulk Requires Progressive Power Presses

Metal brackets are the unsung heroes of countless structures and devices we rely on daily. Whether holding together pieces of furniture, supporting electrical enclosures, or stabilizing building frameworks, these seemingly simple components play a crucial role in our everyday lives. The importance of efficient and precise manufacturing processes for metal brackets cannot be overstated, particularly when it comes to high-volume production.

Diverse Uses of Metal Brackets

Metal brackets serve a multitude of functions across various industries. Here are ten examples showcasing their versatility:

  1. Furniture Assembly: Brackets are used to connect and support furniture components, such as shelving units and cabinet fittings.

  2. Electromechanical Equipment: Brackets hold and position electronic components within devices like computers and appliances.

  3. Building Materials: They are integral to constructing frameworks for walls, ceilings, and other structural elements.

  4. Automotive Parts: Brackets secure components within vehicles, such as engine mounts and suspension systems.

  5. HVAC Systems: They support and stabilize heating, ventilation, and air conditioning equipment.

  6. Signage: Brackets are used to mount and display signs in various commercial and public spaces.

  7. Plumbing: They hold pipes and fittings in place, ensuring a secure and stable installation.

  8. Electrical Installations: Brackets support electrical panels, conduit, and other wiring infrastructure.

  9. Shelving Units: They are critical for creating stable and functional shelving systems in both commercial and residential settings.

  10. Structural Reinforcement: Brackets add strength and stability to structural elements, such as beams and columns.

The Importance of Good Bracket Design

Designing metal brackets involves more than just creating a functional piece; it requires a deep understanding of the forces and stresses the bracket will encounter. Engineers and product designers are responsible for ensuring that brackets meet specific strength, durability, and aesthetic requirements. Good bracket design considers factors such as material selection, load-bearing capacity, and compatibility with other components.

The Role of Metal Stamping Power Presses

Metal stamping power presses are essential in transforming flat sheets of metal into fully formed metal brackets. These presses use high pressure to shape metal into desired forms through various stamping operations. The process allows for the creation of brackets with precise dimensions and often complex geometries, catering to different applications and specifications.

Manual Fed vs. Progressive Sheet Metal Stamping Presses

There are significant differences between manual-fed metal stamping presses and progressive sheet metal stamping presses.

  • Manual Fed Metal Stamping Press: This type of metal forming press requires the operator to manually feed individual cut sheets of metal into the press for each stamping operation. While suitable for small production runs or prototyping, this method is less efficient and scalable for large volumes due to its slower pace and higher labor costs.

  • Progressive Sheet Metal Stamping Press: In contrast, a progressive stamping press automates the entire process. A length of sheet metal is fed continuously through a series of die stations, with each die station performing a different stamping operation as the strip of sheet metal progresses through the press. This method allows for high-speed, high-volume production and ensures consistency and precision across all steps.

The Manufacturing of Metal Stamping Dies

Metal stamping dies are critical tools in the stamping process. A die is essentially a custom-made mold that shapes the metal into the desired bracket form. The die-making process involves designing and machining the die to achieve the precise shape and dimensions needed. Die makers for metal stamping presses use various machined metal parts to create dies that can handle multiple forming operations, including punching, bending, and embossing.

Why Progressive Stamping Is Ideal for Bracket Production

Stamping metal brackets often requires multiple forming operations, including cutting, bending, and embossing. Using a single die to complete all these operations in one go can be highly efficient and cost-effective. Companies that perform progressive metal stamping in PA are particularly well-suited for stamping tasks because it streamlines the production process by combining several operations into one continuous sequence and their proximity to major thoroughfares, rail lines and port facilities. Progressive stamping processes speeds up production but also reduces material waste and ensures high precision across all parts.

The Benefits of High-Volume Production

For manufacturers, producing metal brackets in higher volumes can significantly lower the per-part costs. By leveraging the capabilities of metal stamping shops and partnering with experienced metal fabrication companies near me, businesses can achieve greater efficiency, consistency, and cost-effectiveness in their bracket production. Investing in a metal stamping shop with advanced equipment and skilled die makers for metal stamping presses ensures that you get the best results for your high-volume needs.

In summary, whether you’re looking for progressive metal stamping in PA or seeking a reliable metal stamping shop, focusing on bulk production can help you reduce costs and improve your product’s overall quality.

Cutting & Fabricating Sheet Metal Is Faster With Lasers

In today’s evolving world of metal fabrication, companies are investing heavily in technologically advanced equipment to remain competitive. This shift is driven by the need for speed, precision, and cost-effectiveness. Fabricators are increasingly turning to laser cutting equipment, which are designed to optimize both speed and performance in cutting through sheet metal. As demand for high-quality products continues to rise, many businesses are realizing that traditional methods simply can’t keep up with the efficiency that laser technology provides.

The Adoption of Laser Cutting in Metal Fabrication

Laser cutting technology has revolutionized sheet metal fabrication. Unlike traditional cutting methods that rely on mechanical tools to cut through metal, laser cutting machines use concentrated beams of light to perform the same task with greater precision and at faster speeds. This process allows for intricate cuts, smoother edges, and a higher level of accuracy, which is crucial for fabricators offering laser cutting services for metal.

For many companies, adopting laser cutting is now essential to meet the demands of various industries, such as automotive, aerospace, and industrial manufacturing. A metal parts manufacturer in PA can utilize laser cutting to handle a wide range of metals, including stainless steel, aluminum, and other alloys. The ability to cut intricate designs quickly and consistently makes laser technology an invaluable asset for custom metal projects.

Merging and Partnering with Larger Entities

In response to the growing need for advanced technology, many mom-and-pop metal fabricating businesses have merged or partnered with larger entities. These partnerships allow smaller businesses to access the capital and resources necessary to invest in cutting-edge technologies like fiber laser cutting machines, automation equipment, and robotics. In today’s competitive metal fabricating landscape, staying relevant requires more than just skilled labor—it requires embracing technological advancements.

Larger entities have the financial capability to invest in these technologically advanced machines, which provide the speed, precision, and efficiency needed for complex custom metal work. This consolidation within the industry is helping fabricators stay competitive by streamlining processes, reducing lead times, and expanding their service offerings. For example, many stainless steel fabricators are now turning to fiber laser cutting to handle high-volume production runs without compromising on quality.

The Benefits of Fiber Laser Cutting Machines

Fiber laser cutting machines have gained popularity among metal fabricators due to their ability to deliver high performance and superior results. These machines are specifically designed to offer faster cutting speeds, which is crucial when working with thin to medium-thickness materials. Fiber lasers can cut through stainless steel, aluminum, and other metals more quickly and efficiently than traditional CO2 laser cutting machines, making them a preferred choice for many fabricators.

For companies providing laser cutting services for metal, fiber lasers offer numerous advantages, including:

  1. Faster Cutting Speeds: Fiber lasers are much faster when cutting thinner materials compared to CO2 lasers, significantly reducing production times and improving overall efficiency.

  2. Higher Precision: Fiber lasers have a smaller beam size, which allows for tighter tolerances and more detailed cuts, making them ideal for industries that require precision, such as electronics and medical device manufacturing.

  3. Energy Efficiency: Fiber lasers are more energy-efficient than CO2 lasers, which helps reduce operating costs while maintaining high productivity. This makes them not only cost-effective but also environmentally friendly.

  4. Versatility: Fiber lasers can cut through a wide variety of materials, including reflective metals like brass and copper, which are difficult to process with traditional laser machines. This versatility makes them a top choice for custom metal work and complex designs.

Automation and Robotics in Metal Fabrication

Beyond just laser cutting machines, the integration of robotics and automation has also played a key role in transforming the metal fabrication industry. Automation allows for continuous production with minimal downtime, enabling businesses to take on more projects without compromising quality. As demand for stainless steel fabricators continues to grow, the ability to deliver high-quality products at a faster pace is becoming increasingly important.

Many larger fabricators are now incorporating robotics into their production lines, ensuring consistent output and reduced labor costs. For smaller businesses that have merged with larger companies, this shift towards automation provides the opportunity to expand their capabilities and offer a broader range of services, such as custom metal work.

Why Fiber Laser Cutting Is Superior to CO2 Lasers

When it comes to selecting the best cutting technology for sheet metal fabrication, fiber laser cutting machines are considered superior to CO2 laser cutting machines for several reasons:

  1. Speed: Fiber lasers can cut through materials much faster than CO2 lasers, particularly when working with thin and medium-gauge metals. This increased speed translates into shorter lead times and higher productivity, making fiber lasers an ideal solution for high-volume production.

  2. Lower Operating Costs: Fiber lasers are more energy-efficient and require less maintenance compared to CO2 lasers. This not only reduces overall operating costs but also contributes to a more sustainable production process.

  3. Improved Precision: Fiber lasers offer a smaller focal point, allowing for tighter tolerances and finer detail in cuts. This level of precision is critical for industries that require intricate designs, such as automotive and aerospace.

  4. Versatility: Fiber lasers can cut a wider range of materials than CO2 lasers, including highly reflective metals such as brass and copper. This versatility is essential for fabricators providing laser cutting services for metal, as it allows them to take on more diverse projects.

As companies continue to invest in advanced technologies, fiber laser cutting machines are becoming an indispensable tool for sheet metal fabrication. Their speed, precision, and energy efficiency make them superior to traditional CO2 laser cutting machines. Whether it’s a metal parts manufacturer in PA or stainless steel fabricators working on custom projects, fiber lasers offer the performance and versatility needed to stay competitive in today’s fast-paced industry. With the adoption of automation and robotics, fabricators are now better equipped to deliver high-quality custom metal work faster than ever before, meeting the growing demands of their clients across various sectors.

Metal Brackets Are Used Everywhere But Are Not Easy to Make

The production of metal brackets through sheet metal stamping is a critical process in manufacturing, involving meticulous design and powerful machinery. The journey begins with the mechanical design process, often carried out by mechanical engineers or industrial designers. These professionals use computer-aided design (CAD) software to create detailed blueprints of the bracket, specifying dimensions, material type, and any special features such as holes, bends, or slots. The design must ensure that the bracket can withstand the mechanical stresses it will encounter in its final application while being cost-effective to produce.

Metal brackets are ubiquitous in various industries due to their versatility and strength. Here are five industries that extensively use metal brackets in their equipment:

  1. Automotive Industry: Metal brackets in automobiles secure various components such as engines, transmissions, exhaust systems, and interior fittings. These brackets must be robust to handle the vibrations and stresses of vehicle operation.

  2. Construction Industry: Metal brackets are essential in building frameworks, supporting structures like beams, and securing pipes and electrical conduits. They ensure structural integrity and safety in both residential and commercial buildings.

  3. Electronics Industry: In electronics, metal brackets hold circuit boards, components, and assemblies in place within devices like computers, televisions, and mobile phones. They need to be precisely manufactured to fit intricate designs.

  4. Aerospace Industry: The aerospace sector uses metal brackets to secure and align critical components within aircraft. These brackets must be lightweight yet strong enough to endure extreme conditions during flight.

  5. Medical Equipment Industry: Metal brackets in medical devices and equipment secure parts, supports, and assemblies, ensuring reliability and safety in demanding medical environments.

The production process begins with sheet metal stamping, a method favored for its efficiency and precision. Metal stamping presses mold and form metal brackets by applying high pressure to a sheet metal blank between a die set. This process is preferred due to its ability to produce complex shapes with tight tolerances at high volumes, reducing the need for additional machining or finishing.

A metal stamping power press differs significantly from a typical press brake. A press brake is used for bending and folding operations, manually or with CNC control, to form parts from sheet metal. In contrast, a metal stamping power press can perform a variety of operations such as punching, blanking, embossing, bending, and flanging, all in a single stroke or series of strokes. This versatility makes it ideal for producing intricate and high-volume parts like metal brackets.

Within metal stamping, there are two primary types of presses: manual sheet-fed stamping presses and progressive sheet-fed stamping presses. A manual sheet-fed stamping press requires an operator to manually feed the sheet metal into the press for each cycle. This method is suitable for low-volume production or simple parts but is labor-intensive and less consistent.

On the other hand, a progressive sheet-fed stamping press uses a continuous roll of sheet metal that feeds through the press automatically. The strip of sheet metal passes through multiple stations, each performing a different operation, resulting in a completed part by the end of the line. This method, known as progressive metal stamping, is highly efficient for high-volume production and complex parts, as it reduces labor costs and ensures consistent quality.

Most metal stamping companies in PA and beyond often leverage these advanced techniques to offer their custom sheet metal fabrication services. They can take over sheet metal stamping projects from design to production, ensuring seamless execution and high-quality results. Companies like FBF Inc specialize in this area, providing reliable and efficient production of metal brackets and other stamped parts.

In conclusion, the sheet metal stamping process is vital for manufacturing durable and precise metal brackets used across various industries. Whether it’s the automotive, construction, electronics, aerospace, or medical equipment industry, the need for high-quality brackets remains constant. FBF Inc stands out in this competitive field, known for their fast turnarounds and competitive pricing, making them a go-to choice for businesses needing custom sheet metal fabrication. If you’re looking for expert metal stamping services, consider FBF Inc for your next project.

Punch Press or Laser? Choices for Cutting Metal

Metal workers are tasked with manufacturing high quality, marketable products for their clients. Metal fabrication often starts with sheet metal materials that need to be cut and formed into usable metal parts that get moved along the supply chain to a point of final assembly. In metal working, there are different options for cutting, forming, coining, piercing, punching and bending the metal into the finished product your company needs. Several methods involve what is called a punch press, and another one entails the use of a high-powered industrial laser. Each uses a different process, achieves different end results and holds distinct advantages.

The Punch Press

Punch presses operate by first developing cutting dies, forming dies or progressive die sets. The die is the tool within the press used to cut and or form the metal, and a progressive die set is used in machines where coils of sheet metal material pass through several stations within a die set in one pass. Punching is a form of metal stamping, which is when a die is used to cut metal blanks with the aid of a die and a power press. The punch press is about speed and high-scale production, and is characterized by a number of features:

  • Force or power used to cut the metal

  • The tooling die and complexity of the die

  • Size of working area on the metal blank

  • Frame type

Progressive long run stamping, another fast and cost-effective method, uses a power punch press. The material (in coil form rather than pre-cut sheets) involves multiple cutting and forming stages through a single machine before the desired result is achieved. Precision metal stamping is a bit different; this process converts flat sheet metal into different commissioned shapes maintaining very tight tolerances.

Laser Cutting

A slightly more modern technique, industrial laser cutting services is about precision. A beam of heat energy sears into the metal and melts the excess away. This energy is often operated by CNC (computer numerical control). There are some particular projects for which laser cutting is best to use:

  • Tight intricate cuts

  • Multiple metal blanks all cut from the same plate of metal

  • Short run projects where tooling costs need to be avoided

There are many benefits to sheet metal laser cutting. For instance, laser cutting pre-painted metal without scarring the paint is possible with certain fiber lasers. There is also less chance of contaminating the material than with the cutting edge used in mechanical cutting.

Strengths and Weaknesses

Overall, both punch press cutting and laser cutting have certain advantages and disadvantages in the industry. Each are an asset to the task of metalworkers and their field, but in different ways. For more information, seek out a professional quote today.

Progressive Die Stamping Has Not Changed Much in 20 Years

You can see the impact of metal stamping using progressive dies in the building trades, consumer products, automobiles and the equipment we use to manufacture “things”. From everyday appliances in our homes to heavy machinery for large-scale industry, die stamped parts are in most every metal part in use today. While innovations continue to lead the metal forming industry forward, the foundation of progressive metal stamping remains the same, set in place in the early and mid-20th century. In the decades since, little has change because progressive die stamping methods of metal forming are basic; even cutting-edge manufacturers still follow the guidelines set in the 50s, and they still serve well today.

Early History of Progressive Die Stamping

The 1896 treatise titled The Press Working of Metals by Oberlin Smith, together with J.L. Lewis’s Dies and Die Making a year later, discussed “follow-on” tooling and the use of “successive gang cutting” techniques.These were the early beginnings of progressive dies. At its onset in the early 20th century, progressive dies saw fairly limited usage among companies in need of in-house manufacturing. Contract tool and die makers still relied on single-operation presses and workers loading and unloading materials by hand to transfer them between dies - a slow and often dangerous task, as hand-feeding strips and parts meant exposing unprotected hands to moving parts. The post-WWII metal manufacturing industry pushed production demands too increase outputs, and worker injuries on these single function hand transfer presses were becoming increasingly commonplace.

The Start of Modern Metal-Stamping Tradition

In 1953, design engineer Ed Stouten started a die design business called the Capitol Engineering Company in Grand Rapids, MI. He proposed an alternative: a multi-station progressive die where parts remained on the strip between operations and scrap material was reused. Sheet metal bending, cutting, punching and forming became a continuous process with little manual input between stages. Impressed, tool and die makers spread the word, and everyone wanted to try this new progressive die stamping process. Stouten developed an official manual and training course, Progressive Dies for Designers, Engineers and Manufacturers, and spent the next 50 years traveling the world along with leading die designer Arnold Miedema, giving seminars to share these new ideas.

The Legacy of Progressive Die Stamping

The fundamentals of progressive metal stamping remain the same not because of stagnation, but because of how significant the development was, and is, to the sheet metal bending industry. Stouten and Miedema’s seminars and designs remain vital for most tool and die makers in Pennsylvania and those outside our region. Manufacturers and customers everywhere owe it to Stouten’s work for the production of high-quality, reliable and safe die-stamped metal parts.

Cut Complex Geometries With Speed and Precision Using Fiber Laser Cutting

Precision is essential when cutting thin metal used in medical instruments, industrial equipment and parts for the electronics industry.The quality of the cut can have a significant impact on the effectiveness of the part, and negative consequences if tolerances are not adhered too. As a result, metal fabrication companies place quality and precision as a top priority, but also need to consider other factors to ensure their business thrives. A fiber laser cutting machine can produce high precision of metal cutting for some very complex shapes while contributing to business goals of cost reduction and improved lead times.

3 Dimensional Cutting

One of the most significant ways laser technology stands out among metal fabrication methods is its ability to work in three dimensions if necessary.A custom laser cutting machine using solid state processing can can cut intricate shapes in one pass with amazing precision, which is often an impossible feat for wire electric discharge machining(EMD), the next leading method. To create a three-dimensional shape using wire EMD requires additional equipment and software, which means higher costs and longer processing times. A CNC turning mill utilizes a 3-5-axis motion package, allowing it to cut in two or three dimensions with specialized cutting tools. A solid state fiber laser cutting service uses a beam of light, no investment in specialty cutting tools.

Speed

When it comes to speed, nothing compares to a fiber laser cutting service cranked up for speed.We have done over 7 different metal parts from one sheet of 108 inch metal. The computer onboard arranges the shapes to make the most economical use of the metal sheet, minimizing waste.  Other fabrication methods require several passes to achieve the same level of precision and take much longer to complete the 7 different parts.

Laser technology also includes the option to utilize fusion cutting, which introduces gas to the cutting zone during the process. When oxygen is added, the speed can increase up to 50% without detrimental effects on the quality.

Accuracy and Quality

Metal fabrication with lasers can provide the cleanest edges of any method. The intense focus of the laser also allows for incredible precision. Laser technology can create products that have:

  • Exit sides with minimal dross/burr
  • ±0.001 in. dimensional accuracy
  • Less than 0.002 in. cut width
  • Less than 0.3 µm “as cut” roughness

Fusion cutting can also be used to increase the quality by using nitrogen instead of oxygen. Although this is a slower process, the mobility and power of a laser ensures that fusion cutting with nitrogen is still a quicker process than a turret punch press for example.

A laser cutting service proficient operating their equipment can produce high quality metal blanks while ensuring a quick turnaround. Metal fabrication with lasers is transforming the way metal fabrication companies in Philadelphia and meeting the demands of their clients. Custom laser cutting of metal is slowly replacing the way complex metal parts are made today. The additional option of fusion cutting with oxygen, nitrogen or argon as an assist gas can speed up production times but should be allowed specialized jobs due to controlling gas emissions.

Cutting Complex Metal Blanks Just Got Easier, Faster and More Affordable

There are thousands of products that are manufactured using metal parts cut the old fashion way. This article is focused on laser cutting technologies that are faster and a more affordable way of cutting metal parts. Almost all kinds of metals such as the mild steel, aluminum, and nickle alloys can be cut using the advanced laser technologies that are available.

Laser cutting achieves high precision cuts as well as improved production speed compared to punch presses and shears. Lasers are highly programmable and don’t require any tooling.

The laser cutting helps get more complex parts done with less waste.There are two primary types of laser technologies that are available for cutting complex parts, One is CO2 lasers and the other is solid state fiber laser cutting machines. One of the major benefits of fiber lasers is the minimized energy consumption compared to CO2 laser machines currently on the market.

Fiber Lasers

Fiber lasers tend to do a better job with thinner metal sheets. TruDisk solid-state lasers enable you to work quickly, particularly in thin sheet metal. This is possible because they emit abeam with a wavelength of approximately 1.03 µm, which is absorbed significantly more intensely than the wavelength of CO2 lasers: these lasers transfer more energy to the sheet metal, enabling cutting to be carried out more quickly.

CO2 Lasers

CO2 lasers are particularly effective for any applications that require especially smooth and high-quality cut edges. They are the right choice for cutting edges that will be visible and where smooth edges matter for the further processing of your part. CO2 lasers are an older type of laser technology, which means that in general, the price to acquire them has come down over time.  Yet, it’s a technology that has continued to evolve beautifully, even as prices fall. CO2 lasers, while not as fast as their fiber cousins, are extremely flexible and adaptable for use on the most common types of materials, such as aluminum and steel, and on a range of material thicknesses.

When investigating a laser cutting service for your next fabricated metal part, it would be wise to quote out a few companies that do metal fabrication with lasers and ask them about the quality of the cutting surface for the metal parts you are making. If you are just doing a laser cut for metal blanks that don’t require any forming, you may not be concerned with the type of machine. But if you are doing some custom laser cutting of more complex parts that need additional forming, then we recommend that a fiber laser cutting service get involved in the project. Not every metal fabrication shop in Philadelphia is created equal.

Challenges and Considerations of AHSS Metal Stamping

Designing and producing lighter-weight vehicles is a primary goal of some automobile manufacturers. Less weight allows for improved performance, safety and fuel economy while also reducing material costs. Advanced high-strength steel (AHSS) alloys represent a strong candidate for use in structural components of automobiles. They also present new difficulties in alloy composition; OEMs should pay attention to ongoing research in their formation, properties and effective stamping of these metal parts.

Observed Advantages of AHSS

Conventional mild steels have low carbon content and minimal blending elements which result in simple microstructures. AHSS alloys use carefully controlled additions of alloying elements to produce complex multi-phase structures with unique mechanical properties. There are a variety of AHS steel compositions and their properties provides considerable versatility. Dual-phase (DP) steels and transformation-induced plasticity (TRIP) for example, already see considerable use in vehicles. DP steels are highly resistant to fractures and necking. TRIP steels demonstrate a capacity for high energy absorption under sudden strain, excellent for the “crumple zones” of vehicles.

Formability Concerns of AHSS

Formability - the ability of a piece of metal to undergo plastic deformation without sustaining damage - is a critical trait for automotive alloys to ensure that parts do not fracture within metal forming presses. AHSS alloys, however, exhibit issues with formability as it relates to springback during some more complex precision metal stamping processes. Assessing the related mechanical properties of AHSS, in turn, is difficult with usual testing because the multi-phase structure leads to non-constant strain hardening. The viscous pressure bulge (VPB) test has shown promise, though, in constructing flow stress curves for AHSS samples.

Effective Modeling of Fracture States

The forming limit curve (FLC) is a standard in predicting the forming behavior of sheet metal to illustrate stress states that result in fracture. Traditionally, this involves a series of tests at varying ratios of shear and strain to determine when fracture occurs, but the variability of AHSS responses to strain make this especially costly in time and materials. The Center for Precision Forming at Ohio State University, however, has demonstrated a “three-point technique” for approximating the FLC with just three tests: pure shear, pure strain and biaxial tension. This can provide a more time- and cost-effective method for OEMs and their progressive metal stamping companies they work with.

The advances made in newer metal forming presses allow sheet metal stampers in PA to make fine adjustments to speed and force when forming critical shapes. There is great promise for precision metal stamping in the automobile industry. Further research in controlling the properties and performing effective testing and working will help manufacturers realize goals of more efficient automotive design.

Deciding Between Die Stamping and Laser Cutting? Consider This

As a metal fabrication buyer, you may have questions about the differences between die stamping and laser cutting from a quality and economy’s standpoint. There are advantages to each process and knowing what those are can ensure that you choose the right option. We’ll go over how the processes work and why one or the other might be better for your specific purposes.

Metal Stamping Process

Die stamping is a process where a metal die is made according to the final drawing of your part and is installed into a power press that is used to fabricate metal. The die is pressed into the metal to pinch it into the shape that is needed. This type of process requires the right metal substrate and the correct force to stamp, mold and shape that metal. Progressive dies can perform multiple tasks in one pass through the equipment.

Laser Cutting Process

Sheet metal laser cutting involves the use of a CO2 laser machine or a fiber laser cutting service which cuts the metal into a specific shape that remains flat. There is no die required because the drawing is input into the computer of the laser machine. However, this also means that the metal part can only be made into a flat shape. Die stamping allows the shape to be molded and turned into a specific piece that you need.So there will be additional passes through a press brake that may be required to shape the metal part. If your part is nothing more than a flat shape, this may be a wonderful option.

Differences Between Die Stamping and Laser Cutting Service

When you are using the stamping method, one of the disadvantages is the need for a physical die tool to me made by a craftsman. The creation of the die can be time-consuming, requires hardened tool material and can be costly to produce depending upon its complexity.As for sheet metal laser cutting, a technician programs the computer based upon the drawing provided so there are some labor costs and required skills involved but the time and material costs are significantly reduced.

Not all fabricators have opted for laser cutting equipment. The machines are a big investment and the payoff may be years.If your part requires metal forming, bending and other processes, a progressive die stamping company might be better equipped to handle your metal part. If your part requires only blanking, cutting and coining, perhaps a company that has a newer fiber laser cutting machine is a good partner.

The Right Choice for You

The metal part drawing and the sheet metal thickness and quality will be required for you to make the right decision. Not all steel fabrication companies are considered equal and encourage you to do your due diligence. Get a quote, a few testimonials and have the conversations with your partner. Ask if they are an ISO Certified metal stamping company and ask to see their certificate.

Progressive Metal Stamping Dies Get Complex

Mass production of metal parts using progressive die stamping helps manufacturers complete multiple forming operations in a single pass through the press. The stamping dies that are crafted for the bending, piercing and forming of these parts can get very intricate. In order to create the least amount of waste for the strongest result, sheet metal forming companies often have to make several intermediary steps or stages in the metal forming process that minimizes stress on the parts they are making.

Orientation and Rotation

Long run stamping is done on a sheet of metal that is fed through the machine via a roll or coil of metal. There is a need to synchronize the metal pull length with the die stages. Running perpendicular to the metals grain direction is usually the best option, but some amount of rotation may be performed to reduce material waste. Performing a variety of tests and creating multiple samples are useful to determining where the tradeoff in strength and waste lies. No matter how much you save on material costs, you lose out in the long run if your parts durability is minimized.

Keeping It All Together

As parts pass through a progressive die, some scrap between each stage helps carry the entire strip through. This method of "carrying the part," where some scrap is left between each piece, is the most common and produces minimal scrap. Each of the metal stamping companies in Philadelphia we have interviewed for this post manufacturer their dies differently in an effort to get the end result cost effectively.

A different carrying method is to is to use a guide edge to pull the strip through the press and stamp the part die on the other side of the metal strip. This method can create problems in lift since the strip can only be held on one side and a balanced strip progresses more easily than an unbalanced one. This method was far less common with the die stamping companies we interviewed.

Ladder style is the third type of carrying method and it consists of adding material on both sides. This is a balanced version of the second method but can produce much more waste. As with any long run stamping project, a balance must be struck between ease of manufacturing, material strength and material waste.

Exiting the Die

During the design process, it's important not to overlook the act of exiting the die. Some exit strategies involve the part falling naturally off the metal strip, but the balance must be right for this to happen. Any flanges or tabs added can affect the need for any finishing tasks like deburring. It is best to have your tool die makers in house when working with long run stamping dies because the wear and tear on the dies is greater and therefore maintenance is required to extend the life of the dies. Most sheet metal forming companies have a variety of tools and techniques to make the parts a client needs.

What Are the Advantages of Fiber Lasers?

It took CO2 lasers nearly twenty years to reach the 4kW cutting threshold. Fiber lasers have achieved this level of performance and much more in only five years. Laser cutting services and custom metal fabricators now use even more powerful fiber lasers for cutting sheet metal. Fiber lasers outperform CO2 lasers when it comes to making precise cuts on thin sheets of metal. Keep reading to find out about the many advantages of fiber lasers.

Compact and Powerful Configurations

Fiber lasers feature compact solid state design configurations with fiber-to-fiber capabilities, making these machines much more efficient and powerful than CO2 lasers. This type of laser really shines when it comes to cutting thin sheets of metal. The focal point of a fiber laser can achieve a power density that greatly exceeds that of the strongest industrial CO2 lasers. The shorter wavelength of fiber lasers allows for greater absorption, particularly when the sheets of metal being cut are quite thin, ideally no more than .160″ in thinkness for the best performance and results.

Cutting Thin Sheets

The higher absorption of the fiber laser wavelength and the power density of the focused beam can increase the functionality, precision, and speed of sheet metal laser cutting. This is particularly the case when the sheets being cut are thinner than 1/8″. As the majority of cutting applications involve thinner materials, fiber laser machines can make a substantial difference in the effectiveness and efficiency of cutting metal blanks for most manufacturers.

Low Cost of Operation and Maintenance

CO2 lasers remain more common than fiber lasers, but these machines are neither as economical nor efficient. The major benefits of fiber lasers include the fact that they are cheaper to operate and easier to maintain than CO2 lasers. Fiber lasers require less in maintenance costs, require less power to operate and produce cleaner cuts faster. Metal fabricators should check the optics as well as the steel belt and the straightness and verticality of the track. Regardless of which type of laser is used, it is a good idea to regularly clear dust and dirt and clean and lubricate the guide rails and motors of a cutting machine.

Custom metal fabricators interested in improving the effectiveness of their laser cutting services may be interested in sheet metal laser cutting with fiber lasers, especially on metal sheets that are thin. Ask metal fabrication vendors about their machines and methods and make sure you end up with the best cut.

5 Steps to Improve Press Brake Productivity

Let’s face it. When it comes to your metal fabrication shop needs, your main focus is on producing high quality results cost effectively. Equipment productivity is key to reducing internal costs and raising the margins of profitability on each job. If there are areas within your production process that slow down productivity, let’s identify them and find a few solutions that tend to bog down a fabrication flow. There are five steps you can follow to improve the productivity when it comes to the press brake operations.

Step 1: Organize the Workstation

Organization is important in any metal forming company with welding capabilities. If your operators must stop to find tools, this takes him or her away from focusing on operating the press brake. A cluttered workstation is also a safety hazard. There needs to be a place for everything within easy access. Operators should be trained to put tools back to specifically assigned spots so that they and others can access them anytime.

Step 2: Handling Tools Effectively

There are ways to do things that can have a huge impact. Most fabrication companies have a solid inventory of press brake tooling, each tool is relevant to a specific type of bend. Cutting corners on tool selection or not putting the time into choosing the right tool can add extra steps into the forming process. Stage-bending, for example, helps reduce the need to adjust or change die heights. Sometimes the decision to do stage bending instead of swopping out for the right tool can add more time than originally allocated in the estimate. Reducing overall set up time for each bending stage and lead to dollars in the bank. This all also leads to easier change outs and helps increase productivity.

Step 3: Take Advantage of Precision Tooling

Getting operators into better productivity habits is important. Have them work smarter and training them on the right tooling for each task is part of that. Segmented tooling allows the operator work with precut pieces to reduce waste and save time. That may require the blanks to be cut on a turret press or fiber laser cuttingmachine before it arrives at the press brake first. Furthermore, such operations reduce press brake tool wear, improves quality and lets you put less experienced operators on the job while reserving your more experienced operators for much more complex work.

Step 4: Use Power Clamping

A great way to reduce setup time is with power clamping. Operators can load and unload in front of the press, which goes faster than loading at the ends of the brake. It also saves space since front loading requires less space around the press brake. Up time for the machine is increased because it allows for clamp and seat tooling in one step.

Step 5: Use Control Technology Innovation

Finally, you should make use of any CNC programming installed on the press brake. If your operator is not fully trained on the full capabilities of the machine’s computer, let’s get them trained ASAP. Many of the CNC machines today can do so much more that they are currently being tasked with. Most machine manufacturers offer the training but require your operators to fly to a remote location. Our metal fabrication shop in Philadelphia brings the trainers to us and operators are trained on our machines. Don’t become one of those sheet metal fabricators that accepts the status quo as good enough. Continuous improvement should be part of the company culture.

Press Maintenance and Safety is Important

Stamping metal components uses very large equipment that has often been around for a few years. To fill orders and reach new customers, managers must work to reinforce a safe metal stamping environment. Everyone who works on or around the press at the metal stamping company must be committed to press maintenance and safety.

Training the Individual

Before anyone can work on a large power press, he or she must receive and understand stamping equipment training. The type of training delivered should include information about wearing personal protective equipment like goggles, steel tipped shoes and learn how to operate the press safely. It should also outline procedures for identifying hazards and reporting risks. Progressive metal stamping requires everyone to commit to both initial training and retraining. With a comprehensive training program, supervisors are confident employees know the safety rules.

Having a Zero-Tolerance Policy

Metal stamping power presses are incredibly powerful machines. They are also very dangerous if someone operates them in a way they were not intended to be used. Metal stamping company supervisors realize they must have a zero-tolerance policy for press misuse or unsafe behavior. Workers also must conduct press maintenance evaluations truthfully, pledging never to overload presses or misuse equipment.

Using Die Blocks and Cable Covers

When trying to stay on track to complete an order, workers may be tempted to use die blocks for other purposes outside of their intended purpose. Simply put, the original die blocks for a project are company assets just as the equipment itself. Die blocks should not be used to stand on, raise bins off the floor or turned in a press to hold it open. When not in use, they should be returned to the tool and die inventory room. Likewise, no safety cable should be exposed. Instead, supervisors must be certain all necessary covers and other protective pieces are securely in place.

Identifying Hazards

To avoid accidents, the press must be free from all hazards, scrap, foreign debris or anything not part of the safe operation of a power press. Everybody on the floor must be responsible for identifying all risks without exception. Tripping hazards, sharp objects, and other dangerous items should be removed as soon as possible. If the hazards are fixtures, they should be clearly marked and included in safety briefings and with yellow or orange markings.

Making Repairs

Keeping the press in good shape is not only good for business, it is essential for keeping employees safe. Machines that have missing safety guards or tendencies to malfunction are ticking time bombs. Managers, shift leaders and supervisory personnel must take safety as a number one priority including all employees who work around the press. If equipment is not functioning properly, it is everyone’s responsibility to submit a work order for repairs. Progressive metal stamping company supervisors should also have the authority to stop work until the completion of a repair. No timeline or due date for a custom metal stamping project is more important that the safety of an employee. If you work for a metal stamping company in Pennsylvania, you probably have an independent 3rd party that helps oversee the safety environment of your metal fabrication shop.

Press safety and maintenance are inextricably intertwined. For stamping companies that are committed to reducing injury, there is no substitute for a safety and maintenance plan.

Advantages of Working With a Progressive Metal Stamping Partner

Now that your design is ready for fabrication, choosing the right metal stamping company can become a critical step in the production process. Consider the many ways in which partnering with a large metal stamping company may be advantageous.

Cost Savings

Cost considerations may be important to marketability of the final product. Large metal stamping partners may be able to share cost savings without compromising quality.

  1. Setup Costs. Rather than paying for setup on multiple machines, long run stamping machines may save costs due to one comprehensive setup process. Particularly for smaller runs, reducing setup costs can make a significant impact in the product’s final cost.
  2. Bulk purchases. The larger the partner, the bigger their bulk pricing discounts may be due to the quantities of raw materials they purchase.
  3. Shipping costs. Larger metal stamping companies may be able to manage more sections of the manufacturing process without passing the product onto another vendor, which can save in shipping and handling costs.

Speed to Market

  1. Multiple Forming Stages in One Pass: If your metal part requires multiple metal forming stages to occur, using a progressive stamping die may be the way to go.
  2. Processing efficiencies. Progressive stamping presses feed sheet metal from a coil rather than lifting precut sheets into the press, reducing downtime between processes.
  3. Availability of materials. Companies that regularly handle larger stamping runs may have on hand a broader inventory of materials, reducing wait times for raw material delivery.
  4. Longer runs. The price per part costs are often significantly reduced in the progressive die stamping process. Ultimately you will need to sell what you produce so over production is not wise. Accurate forecasting is the key to managing production sizes.

State-of-the-Art Technology

Larger fabricators are more likely to invest in CNC technology that improves quality and productivity. Quite often progressive metal stamping economies can be found in the form of automation. Material handling and press set up is what takes workers the most time and there are lifts, automated die inserters and other automated solutions that speed up the production process.

Best Value for the Money

So the best value for the money comes when partnering with the larger metal stamping companies in PA who can provide manufacturing services that improve the production speed as well as lower costs. When you have product sales over 10K units in a given year, progressive metal stamping tends to be the better manufacturing process to lower metal part costs. Long run stamping companies are limited with only a few good options is Pennsylvania.