Oct. 07, 2024
Fiber laser cutting has been the go-to manufacturing process for companies worldwide. Others rarely match its precision, accuracy, cost, and efficiency. However, the coil-fed laser cutting machine has proven superior in several industrial applications with its continuous material feed.
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Continue reading to learn about the several benefits of coil-fed fiber laser cutting.
Coil-fed laser cutting machines have an open-style cutting bed that allows continuous metal sheets to pass through. A Decompiler slowly unwinds the metal sheet off the coil while a straightener feeds it to the cutter uniformly.
The continuous sheet metal supply keeps the laser cutting machine fed until the coil runs out. Hence, a coil-fed laser cutting machine is preferred for large-volume productions. Coil-fed machines support sheet metal thicknesses up to 6mm. After 6mm, the material is officially categorized as a plate.
A laser is a high-intensity light beam focused through an optical fiber. The spot diameter of the laser beam starts around 10,000 μm (10mm or 0.39 in) and goes all the way down to an impressive 15μm (0. in.). As a result, fiber laser cutting systems are incredibly powerful and can outperform almost all other means of fabrication. The coil width of the coil-fed laser cutting depends on the particular laser cutting machine and its functions.
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Laser cutting machines cater to various manufacturing processes. However, coil-fed units are uniquely designed and can adapt to all applications. The following advantages show the versatility and practicality of the coil-fed laser cutting system.
Sheet metal cutting operations are a delicate balance between desired shape and area availability. After processing the sheet metal, you are left with leftover waste that is very difficult to manage. A coil-fed fiber laser cutting machine massively helps with waste material reduction.
Higher-end models use an intelligent vision system that can accurately identify the edges of the metal sheet and keep the designs within range. In addition, a laser vision system can detect potential cutting errors early in production.
A significant amount of time is wasted between production cycles. Workpiece (sheet metal) loading and unloading times can often take longer than the actual cutting process. A continuous coil system keeps the laser cutter fed and the production line moving.
Laser cutting technology is incredibly fast and precise. The bottleneck in production lines comes from manual material loading and machine maintenance. Coil-fed laser cutting is ideal for swift manufacturing and is often used in the automotive industry.
Most fiber laser cutting machines can be easily automated to deal with large-volume manufacturing. However, the limiting factor of manual material loading remains. On the other hand, coil-fed laser machines are fully automated, from material feed to waste management.
A typically coil-fed laser system involves five distinct parts working in harmony.
Metal coils come with a paper spacer lined between the layers. As the metal coil unrolls, the paper spacer comes with it and needs to be rolled (coiled) onto another spool.
In a fully automated system, the operator only needs to load the coil onto the decoiler. Afterward, the production cycle will continue independently of the operator until the job is finished or the system runs out of raw material. Additionally, a coil-fed machine frees the operator to continue working on other projects ensuring maximum efficiency on the production line.
Coil-fed cutting is also considerably more cost-effective than other methods of processing sheet metal. Fiber laser systems are very efficient from a power consumption perspective. So you&#;re already saving a significant amount in annual operating costs.
Additionally, coil-fed cutters provide an increase in time efficiency for material processing. Faster loading times, quicker cutting speeds, and optimized production cycle times reduce the general cost of manufacturing.
Fiber lasers have a reasonable level of material compatibility. You can cut various raw materials like metals, non-metals, and composites. However, coil-fed lasers are designed to handle sheet metal rolls.
Here is a brief list of the most popular metal options.
Additionally, you can process treated metals with a fiber laser if needed. Several treated materials, including anodized, coated, painted, galvanized, and metal-plated sheets, are compatible with this technique.
As discussed above, coil-fed laser systems are broken into five distinct modules. And the entire system can still work even at the loss of two modules. The paper recoiler and the waste (processed) sheet recoiler help smooth the process but are not strictly necessary.
This modular design ensures that the laser cutting operations can continue with a limited capacity if a supporting part breaks down. Maintenance and repair costs are also reduced with the modular approach.
Fiber lasers have an overall lower maintenance requirement than their CO2 counterparts. Therefore, with a modular design, you are not bound by the maintenance requirements of other assembly parts.
The fiber laser at the core of a coil-fed machine is incredibly precise. It makes clean cuts in the metal at high speed. Among the many advantages of this process, speed and accuracy are undoubtedly the most impressive. The supporting equipment of a coil-fed system is designed to further enhance the main advantages of fiber laser technology.
Unlike traditionally machined metals, laser cut parts don&#;t generate swarf (metal chips) during manufacturing. Thus, there is no need for deburring parts after the finished parts leave the laser cutter.
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Coil-fed laser cutting systems can handle all manner of sheet metal processing. Therefore, any task that can be accomplished with a fiber laser system can be more effectively executed with a coil-fed laser process.
The following is a brief list of the most popular applications of coil-fed laser cutting.
Blanks are simple geometric shapes cut out of a sheet of metal. A coil-fed laser blanking line utilizes continuous feed to quickly produce several hundred blanks out of a single metal coil. These blanks are sent to partners who manufacture the end product.
Almost every large-scale factory buys blanks from an external supplier instead of starting its laser blanking line. A majority of coil processing takes place at some laser blanking line. Most businesses cannot justify the investment cost of a fiber laser cutting machine. The other applications on this list mainly utilize laser cut blanks in their production systems.
The automotive industry is full of several interconnected production systems that work together to create a single vehicle. One such system is the coil-fed laser blanking system, which makes the aluminum veneer, electrical cabinets, and small engine parts.
Electronic enclosures are one of the biggest markets for laser cut parts. Whether we are discussing ventilators for the medical industry or computer cases for servers and desktops, the odds are they were made using a laser cutting machine.
Coil-fed laser blanking produces flat planes in the correct size, which are bent, cut, and riveted into an enclosure.
Aside from metal enclosures, coil laser systems make several miscellaneous medical equipment such as metal table tops, scalpels, etc.
The aerospace industry uses coil laser cutting machines for various custom projects, like electric shielding, aircraft body parts, or small engine components.
Coil Fed Laser compared to traditional methods is excellent at producing high-performance precision brackets and hinges.
Some kitchen equipment like knives starts as laser cut blanks which are later shaped, sharpened, and polished into a blade.
Here we have compiled some tips to help you get better coil-fed laser cutting results.
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Coil-fed laser cutting machines are excellent for a wide range of applications. The addition of an automated coil feed boosts overall productivity and reduces production times. Fiber lasers are compatible with several different materials. But coil feed systems limit them to sheet metals, producing more efficient production.
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Modern fiber lasers are the result of a collective effort of a hundred years worth of research and development. In just a few short years, these laser systems have gone from industrial-grade tools to widespread everyday machines used by hobbyists and small business owners.
This article provides an in-depth look into fiber laser technology, its inner workings, applications, and benefits.
Let&#;s dive into it.
Fiber laser technology uses an optical fiber cable made of silica glass as the gain medium to boost the strength of the laser.
The optical fiber is exposed to a high-intensity light source, and as light rays pass through the cable, they refract internally and get amplified.
Additional reflectors at the end of the fiber cable further reflect and amplify the laser beam.
The wattage of the light source determines the strength of a fiber laser. High-wattage lamps pump light into the gain medium, which leads to greater laser penetration.
Due to the flexibility of fiber laser systems, it has seen widespread adoption in the manufacturing industry. You will see fiber laser machines commonly used for cutting, welding, making, cleaning, and drilling metals, as well as non-metals.
The invention of the modern fiber laser is a complex and fascinating story that spans nearly a hundred years and with the collaboration of over a dozen scientific minds. Albert Einstein&#;s research into simulated light emissions became the basis for modern lasers. Einstein proposed the theory that photos of light can trigger atoms to release other photons.
Four decades after Einstein () published his paper, Gordon Gould presented the basic structure of visible light amplification.
Gould was the first person to use the acronym for the technology in his work notebook, calling it a LASER: Light Amplification by Stimulated Emission of Radiation.
While Gould formed the basis of the laser, Ted Maiman went on to construct the first functional laser.
Just a few years after Maiman&#;s achievement, Elias Snitzer, who was then working on fiber optics, created a system to combine the two technologies, creating the first fiber laser system in .
Optical fibers were still very difficult to fabricate in the 60s, and without high-quality fiber cables, the fiber laser would not be competitive to gas power lasers.
Over the next 30 years, several scientists, including Snitzer, would improve the design and introduce high-purity optical fibers, double-clad fiber, and rare earth metal doped fiber cables.
In the late s, Italian company Salvagnini would finally bring a fully functional fiber laser cutting machine to the market. Ever since then, fiber lasers have been rapidly and steadily improving to the point of overtaking CO2 lasers.
Following the sale of the first fiber laser cutter, improvements in manufacturing technology, CNC performance, and fiber optics have further enhanced the capabilities of fiber lasers.
Modern laser beams are a commutation of years of research and decades of improvements in the manufacturing process.
Many see fiber laser systems as a complex and daunting technology. But the basic operating principles are very easy to understand.
Here we break down the basic steps involved in fiber laser operation.
The first element of a fiber laser is the light source. Modern fiber lasers use a semiconductor diode for illumination. Higher wattage will result in a high-power fiber laser but at the cost of excess heat generation at the light source.
A robust cooling system is necessary when dealing with high-output power concentrated in such a small space.
Lasers used for manufacturing in industrial environments are incredibly powerful, and a standard light source is often insufficient for such systems.
Some fiber lasers bypass the overheating issues by using multiple smaller pump laser diodes to fill the optical fiber cable with light.
Once your light source is initialized, it must be directed toward the optical fiber cable. As light exits the diode source, it scatters in all directions.
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Hence opaque thicker materials surround the diode to prevent the light from escaping in unwanted directions. Then the only exit point for the light would be in the direction of the optical fiber.
The process of directing more and more light into a single optical fiber is called pumping.
However, the optical fibers are prone to light leakage as well. If you pump light into a naked fiber, most of the energy will dissipate to the surrounding. So the fibers must be clad in a thin and flexible material, preventing light leakage and improving the fiber&#;s refractive index. The fibers combine with cladding material to form a cable, and the cable&#;s core is the optical fiber.
When light enters the fiber cable, it is still too weak and unfocused. But as the light packets (photons) pass through the fiber, they are refracted internally and concentrated. Light continuously bounces inside the fiber until a laser beam is formed.
Even after forming the laser light into a cohesive beam, the power output is still relatively low. So the laser must now be amplified until the beam quality improves significantly. Amplification occurs in three ways.
An optional step for optimizing fiber laser output is to control the wavelength (frequency) of the final beam. The stimulated emission from molecules is at varying wavelengths and can affect the quality of the laser output. To control the beam output, fiber Bragg gratings are needed.
Fiber Bragg gratings are a series of deflectors constructed inside the optical fiber that block unwanted wavelengths of light and only allow the desired ones to pass through.
After the laser diodes pump light into the core of the fiber-optic cable and a laser beam is formed, it is strong enough to melt or even cut materials. But at this point, the light is too unfocused, and the spot diameter of the laser is too large.
A series of high-quality lenses shape the laser beam into a smaller point (spot) and help manage other laser parameters like the focal length. Higher-quality lenses result in better beam quality.
After passing through the gain medium and the lenses, the laser beam is ready for any application. But controlling the position and direction of the laser beam is still a challenge.
The solution is a set of electronically controlled deflectors (mirrors) at the end of the laser beam. As light hits these deflectors, a computer-controlled system changes the angle of the deflector to control the fiber laser&#;s direction.
The sensitive parts inside the fiber laser cavity aren&#;t designed to be moved around. Using this method, the fiber laser can stay stationary while moving only the laser beam.
Here is a brief list of the most important benefits that fiber laser machines bring to the table.
One of fiber lasers&#; most significant improvements over the older CO2 lasers is the incredible laser precision. This higher precision is achieved by the combination of smaller spot diameters and advancements in CNC (computer numerical control).
Fiber lasers can now accurately and precisely move to a th of an inch. (0.001 in. or ~25 microns).
Laser electrical efficiency is measured based on the difference between power drawn from the wall socket and the power output of the laser beams.
Fiber lasers are incredibly energy efficient and can convert up to 35% of the input electricity into laser energy. This is slightly higher than neodymium lasers and nearly twice the efficiency of CO2.
A significant contributor to size reduction for fiber lasers is the lack of a laser tube. Older CO2 lasers use a bulky glass tube that houses a gas mixture used as the gain medium.
Additionally, using energy-efficient diode lasers to pump light into the laser medium leads to smaller cooling systems inside the fiber laser cavity.
Finally, the ability to coil the fiber cable inside the machine has led to higher-power fiber lasers in the same smaller package.
Fiber lasers are versatile tools that can be deployed in different manufacturing systems. For example, a fiber laser cutting machine can also laser engrave and mark.
By reducing the focus of the laser beam or using pulsed fiber lasers, you can decrease the energy output and use the laser for non-cutting applications.
Outside the manufacturing sector, fiber lasers are used in medical equipment, engineering measuring tools, and many more.
Another excellent selling point for fiber lasers is their long life and durability. A standard fiber laser is designed for over 30,000 hours of operation.
This is nearly 15 times longer than a traditional gas-powered laser machine. Due to their high durability, fiber lasers also require less frequent maintenance.
Fiber lasers are primarily recommended for metalwork. You can cut, mark, clean, engrave, and drill through sheet metal and even thicker plates using fiber lasers.
However, fiber lasers provide limited compatibility with non-metals. Limited compatibility means the laser can engrave and mark but will struggle to cut the material.
You can use lower-power fiber lasers for marking and cutting textiles, leather, wood, etc.
Fiber laser machines offer significant savings through higher energy efficiency, lower power consumption, and maintenance-free operation.
Your annual cost per part will be considerably lower in the long term than traditional gas-powered laser solutions.
Non-manufacturing laser applications are best suited to low-powered diode lasers. Although fiber lasers are used in medical fields, Nd: YAG lasers dominate that field.
Because the high power output by fiber lasers can reach upwards of tens of kilowatts, they are favored for their manufacturing capabilities. Here are five of the most common fiber laser applications.
Metal cutters are one of the most widespread applications for fiber laser systems. Most modern metal manufacturing involves the manipulation of sheet metal, metal tubes, or thin metal plates.
Moreover, fiber laser cutting excels at dealing with those exact types of materials. Laser-cutting machines vary based on the laser beams&#; power output, the machine&#;s size, and automation capabilities.
Higher beam quality is necessary for precision cutting. Hence high, quality lenses should be used and cleaned regularly.
Fiber lasers can quickly and accurately carve letters and complex designs into products that will last as long as the product is in use.
A major use case of laser engraving comes from combining CNC laser systems with design software to allow users to create detailed and complex patterns on any number of surfaces.
Low-power fiber lasers are excellent options for marking components and products. They can quickly impart product details and safety instructions onto a component with high precision and clarity.
Laser marking is often used to draw company logos and brandings onto the final product.
Large-scale factories use fiber laser markers to impart serial numbers and batch numbers into small components such as memory chips, PCBs, and car chassis.
Fiber laser welding is a high-precision welding technique used to join two thinner sheets of material with minimal weld marks. Additionally, it is possible to weld plastics using low-power or pulsed lasers.
Laser welding is more expensive than traditional TIGor MIG welding and is typically reserved for specialized applications like microscopic welds, precious metal welding, etc.
Laser welding is an excellent alternative to other sheet metal joining methods like rivets as it produces a more flush finish. Similarly, laser welding is preferred for joining non-metals when air-tight joints are required, and glue (or adhesives) is not a viable option.
Fiber lasers are also used for cleaning up the edges and surfaces of metals. Rusted iron pieces can be cleaned using a fiber laser in a few seconds compared to sanding. Laser cleaning also yields a better surface finish.
Lasers can also clean up weld marks and metal burrs from other manufacturing processes. Laser cleaning is less common in general manufacturing due to its higher initial cost.
Cleaning is primarily concerned with laser power and consistency. Beam quality and focus are secondary factors for this process.
So far, in this article, we have only focused on fiber lasers. However, there are two more laser systems available right now that are popular and, in some cases, better than the fiber option.
CO2 predates fiber lasers by half a century and is a tested and trusted option. Nd: YAG is similar to fiber lasers and a somewhat newer technology that is still being researched. This section compares the three technologies and highlights their respective advantages.
Laser costs range from a few hundred dollars (USD) all the way up to a million. Gas lasers are the cheapest at $2,000 for a beginner unit, while entry-level fiber and YAG models start around the $15,000 mark.
The initial investment into gas lasers is considerably low, but the maintenance cost can start to add up.
CO2 lasers are best suited for low-volume production runs. In such situations, a lower life span and poor energy efficiency can be justified by the significant reduction in upfront costs.
CO2 lasers are bulkier because of the large and heavy gas mixture tube used for photon generation. As you directly pump light into a fiber and YAG lasers, there is no need for the photon-generating glass tube.
Fiber laser machines occupy less space and maintain a higher beam quality.
The biggest power draw of a laser system is the light source, as it is necessary for amplification.
Since both fiber and YAG lasers use energy-efficient lamps to pump light into the laser medium, they have a higher overall efficiency leading to lower operating costs.
Semiconductor lasers that use diodes have the highest efficiency, upwards of 60% but only at 5-10W of power.
At this range, semiconductor lasers are only helpful for marking and cutting plywood or fabrics.
The lifespan of CO2 lasers is the lowest among all laser technologies as the gas mixture tube degrades over time and needs to be replaced after 2,000 hours of operation.
Contrarily, Fiber lasers can operate at their high (peak) power all day and still maintain their long lifespan. Neodymium lasers share a similar lifespan to single-mode fiber lasers.
Modern optimizations have led to increased reliability of all laser systems. Generally speaking, a solid-state laser and a gas laser will have the same level of reliability in optimal operating conditions.
However, in hazardous situations like factory floors or chemical processing plants, gas lasers will have lower reliability due to the fragile nature of the glass laser tube.
CO2 lasers have the most diverse material compatibility as they can be used on metals, plastics, polymers, wood, and more. They are only limited by highly reflective metal surfaces like bronze or copper, as most of the laser energy is reflected off the surface.
YAG lasers have reasonably high metal material compatibility but are only compatible with some ceramic non-metals.
Fiber lasers are the best of both worlds as they have a near-universal compatibility with metals, including highly reflective surface ones and decent non-metal compatibility.
Fiber laser machines are a versatile, flexible, and cost-effective solution for small to medium-sized businesses. However, it is crucial to buy a machine that is best suited to your needs.
Especially since fiber laser machines have a higher initial investment cost, choosing a suitable machine for your business can significantly reduce your ROI (return on investment) period.
Here are the major factors you must consider before buying a fiber laser.
Outline your primary use case for a fiber laser. If you primarily work on sheet metal fabrication, getting a fiber laser cutter would be a smart business decision. You benefit from the diverse metal compatibility.
Laser cleaning, marking, and welding machines are uni-task tools that are designed for only one purpose. If you cannot fully utilize these machines on a regular basis, then it&#;s best to avoid them.
Although fiber laser machines are small and compact, they still need ample breathing room.
You should have enough clearance around the machine for good airflow so the laser doesn&#;t overheat.
Additionally, you should have enough roaming space so someone doesn&#;t accidentally bump into the machine while it&#;s operational.
You must also consider decent ventilation when cutting plastics or certain hazardous materials that can generate dangerous fumes.
High-power fiber lasers are mostly reserved for cutting thick blocks of metal. Most industries won&#;t benefit from a 10kW solid-state laser.
Laser marking requires the least amount of power, while engraving, cleaning, and cutting will require varying levels of power based on operating conditions.
Avoid high-power lasers if they don&#;t provide significant benefits to your business.
A solid-state laser, like a fiber one, will generally cost more at the initial purchase than a CO2 one.
However, fiber lasers have lower operating costs due to their excellent efficiency, even when hitting high-power targets.
Fiber lasers are also considered maintenance-free because of their exceptionally long lifespan.
Lasers can operate in two modes depending on the application.
Most lasers utilize a stationary work bed. The size of the bed limits the production capacity of fiber laser machines.
A larger bed size would be necessary for larger businesses that need quick turnaround times, but it won&#;t be viable for mass production.
Aside from bed size, some fiber laser cutters utilize a coil feed system.
Here, the main fiber laser body is attached to a sheet metal decoiler that continuously feeds metal to the machine.
Coil-fed laser systems are typically reserved for high-volume and low-complexity production runs.
Fiber laser systems started as an unverifiable theory in the mind of Einstein and slowly grew into one of the most innovative modern tools today. These lasers are versatile tools that are a crucial part of several industries, including metalwork, robotics, surgery, and more. Highly regarded for their small footprint and efficiency, fiber laser machines are now more affordable than ever before.
Furthermore, the broad material compatibility of fiber laser systems has given them an edge over other metal fabrication processes.
Baison is a long-term manufacturer of precision laser cutting machines. Our best-in-class fiber laser systems are shipped globally to over 100 countries across the globe.
We offer value-added services like pre-purchase application evaluation and a thorough operator training program.
Our catalog includes powerful and robust Fiber and CO2 laser machines.
A successful business needs quality tools. Get the Best Fiber Laser Machine Today!
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