When metal parts need to be precise, clean, and fast to produce, traditional cutting tools may not be enough. Many companies face delays and rising costs from slow processing times or messy finishes. Fiber laser cutting helps solve these problems. It uses focused light to cut metal quickly, cleanly, and accurately.
This article breaks down fiber laser cutting. You’ll see how it works, why it’s popular, and where it fits best.
What Is Fiber Laser Cutting?
Beim Faserlaserschneiden wird ein leistungsstarker Laserstrahl zum Schneiden von Metall verwendet. Der Strahl kommt von einem Glasfaserkabel, das gebündeltes Licht auf einen kleinen Punkt auf der Oberfläche sendet. Dieses Licht erhitzt das Material, bis es schmilzt oder verdampft. Ein Gas, wie Stickstoff oder Sauerstoff, bläst das geschmolzene Material weg. So bleibt ein sauberer und schmaler Schnitt zurück.
A computer controls the laser. The laptop follows a design file to guide the beam across the metal. This gives high precision and repeatability. Fiber lasers are efficient. They use less power than older laser types. They also last longer and need less maintenance.
How Fiber Laser Cutting Works?
A fiber laser generates light by exciting atoms in a fiber optic cable with a diode. This light builds up and is amplified inside the fiber. The result is a very focused and powerful laser beam. The wavelength of this beam is ideal for cutting metal, especially reflective types like aluminum or brass.
This beam delivers high energy to a small spot. It heats the metal until it melts, burns, or vaporizes. A stream of gas then clears away the molten metal.
Components of a Fiber Laser Cutter
A fiber laser cutting system has several key parts that work together.
Laserquelle
This is where the laser beam is created. It uses laser diodes to produce light, which is then boosted in a fiber optic cable. The light becomes stronger and more focused as it travels through the fiber.
Strahlführungssystem
The beam travels through fiber optics to the cutting head. This system is sealed and requires little maintenance. It offers stable, high-power delivery without mirrors or moving parts.
Cutting Head and Nozzle
The cutting head focuses the beam into a tiny spot. A lens or a group of lenses does this. The nozzle below the lens directs gas onto the cut zone. This gas clears out molten material and keeps the cut clean.
CNC Controller and Software
The CNC system controls the motion of the machine. It follows digital drawings to guide the laser. The software tells the machine where and how to cut. It controls speed, power, and gas flow.
Fiber Optic Transmission Explained
The laser beam travels through a flexible fiber optic cable. This replaces traditional mirrors and lenses. Fiber optics are durable and don’t go out of alignment. They allow high power transmission with low energy loss. This makes the whole system compact and efficient.
Role of Assist Gases in the Cutting Process
Assist gases help remove molten material. They also influence cut speed and edge quality. The choice of gas depends on the material and the finish needed.
Stickstoff
Nitrogen is used when a clean, oxide-free edge is needed. It doesn’t react with the metal. It’s ideal for stainless steel or aluminum parts that need painting or Schweißen later.
Sauerstoff
Oxygen supports faster cutting by reacting with the metal. This reaction gives extra heat, which boosts cutting speed. It’s commonly used with mild steel. The downside is that it leaves an oxidized edge.
Luft
Air is a low-cost option. It contains both nitrogen and oxygen. It’s suitable for basic cuts where edge quality is not critical. Air cutting reduces gas costs, especially in high-volume work.
What Materials Can You Cut with Fiber Lasers?
Fiber lasers handle many materials, but some work better than others. Let’s look at what you can cut—and what you can’t.
Metals Commonly Processed
Fiber lasers excel at cutting metals. They deliver clean edges with minimal waste.
Rostfreier Stahl
Fiber lasers cut stainless steel smoothly. They work well for medical devices, kitchen equipment, and industrial parts. The heat-affected zone is small, reducing warping.
Kohlenstoffstahl
This is the easiest metal for fiber lasers. They slice through thin or thick carbon steel fast. It’s perfect for automotive frames, machinery, and construction parts.
Aluminium
Aluminum reflects light, making it trickier. But fiber lasers handle it better than CO₂ lasers. They’re used for aerospace parts, electronics, and automotive components.
Messing und Kupfer
These metals are highly reflective, so cutting them requires higher power. Fiber lasers still work, but slower speeds help avoid excess heat buildup.
Limitations on Non-Metal Materials
Fiber lasers struggle with wood, acrylic, and glass. These materials burn or melt unevenly. CO₂ lasers work better for them.
Material Thickness Capabilities
Thinner materials cut faster and cleaner. Fiber lasers handle:
- bis zu 20 mm for carbon steel
- Bis zu 12 mm for stainless steel
- bis zu 10 mm for aluminum
What Settings Affect Fiber Laser Cutting Results?
To get clean, precise cuts, you must adjust key machine settings. Here’s what matters most:
Laser Power (Watts)
Higher power cuts through thicker materials faster. But too much power can burn thin sheets. Typical ranges:
- 500W–1kW for thin metals (<3mm)
- 2kW–6kW for medium thickness (3–10mm)
- 8kW+ for heavy plates (>12mm)
Schneidgeschwindigkeit
Faster speeds work for thin materials. Thicker metals need slower movement to ensure complete penetration. Example speeds:
- 10m/min for 1mm stainless steel
- 2m/min for 8mm carbon steel
Focal Point Position
The laser’s focus must match the material thickness:
- Above the surface for thin sheets
- On the surface, for medium cuts
- Below the surface for thick plates
Assist Gas Type and Pressure
Gas blows away molten metal for cleaner edges:
- Nitrogen (N₂) – Prevents oxidation (best for stainless steel, aluminum)
- Oxygen (O₂) – Adds heat through combustion (faster cuts on carbon steel)
- Compressed air – Low-cost option for non-critical cuts
Nozzle Size and Distance
Smaller nozzles (1–1.5mm) give precise cuts on thin materials. Larger nozzles (2–3mm) handle thicker plates. Keep a 0.5–1.5mm distance from the material.
Pulse Frequency (for Pulsed Lasers)
Higher frequency (500–5,000Hz) works for thin metals. Lower frequency (50–500Hz) helps pierce thick materials.
Key Advantages of Fiber Laser Cutting
Fiber laser cutting brings many benefits to shops that want speed, precision, and lower costs. It improves efficiency across the whole cutting process.
Higher Cutting Speeds
Fiber lasers cut faster than CO2 or plasma systems, especially on thin to medium-thick metals. Their focused beam delivers more energy into a small area.
Greater Energy Efficiency
Fiber lasers convert electrical energy into laser light with high efficiency. Most of the power goes into the beam, not into heat. This lowers electricity bills and reduces cooling needs.
Lower Maintenance Requirements
Fiber lasers have fewer moving parts. They don’t need mirrors or gas-filled tubes. The beam travels through fiber optics, which stay sealed and clean.
Superior Edge Quality and Precision
The beam is very narrow and stable. It creates sharp, clean edges with minimal burr. Holes and contours are cut with high accuracy. Parts often need little or no post-processing.
Compact Machine Design
Fiber laser systems are smaller than older laser machines. The fiber optics take up less space than mirror-based beam paths. This compact design saves floor space.
Eco-Friendly Cutting
Fiber laser cutting uses less energy and creates less waste. It doesn’t burn material like plasma or oxy-fuel. The cleaner process means fewer fumes and fewer emissions.
Beschränkungen und Überlegungen
Fiber laser cutting has many benefits, but it’s not perfect. Some challenges can affect setup, cost, and part quality.
Reflective Material Challenges
Highly reflective metals, like brass or copper, can reflect the laser beam. This may cause unstable cuts or damage the machine. Modern fiber lasers handle reflection better than CO2 lasers, but risk still exists.
Initial Equipment Investment
Buying a fiber laser cutter costs more upfront than other cutting tools. High-power systems, automation, and software add to the price.
Safety Requirements
Fiber lasers can be dangerous without the proper safety measures. The beam is invisible and powerful. It can burn skin or damage eyes. Machines must have adequate shielding.
Strahlqualität
The beam from a fiber laser is very focused. This is good for precision, but can be tricky for thicker materials. If the setup isn’t correct, the cut may show taper or rough edges.
Applications of Fiber Laser Cutting
Fiber laser cutting is used in many industries. It helps create precise, repeatable parts with fast turnaround times.
Autoindustrie
Fiber lasers are used to cut body Platten, Klammern, and structural parts. High speed and clean edges help meet production demands in automotive assembly lines.
Luft- und Raumfahrt und Verteidigung
Aerospace parts require high precision and clean finishes. They are used for cutting engine parts, airframe elements, and structural supports.
Herstellung medizinischer Geräte
The medical industry uses fiber lasers to cut small, detailed parts. These include surgical tools, implant components, and housings. The clean edges and tight tolerances meet strict regulatory standards.
Elektronik und Gehäuse
Fiber lasers cut thin metals used in electronic parts and device housings. They handle intricate designs for brackets, shields, and Gehege.
How to Choose a Fiber Laser Cutter?
Choosing the right fiber laser cutter depends on what parts you make, what materials you cut, and how fast you need to work.
Materialart und Dicke
Start with what you plan to cut. Thinner materials need less power. A thick plate may need 6kW or more. If you work with reflective metals, check that the machine handles them safely and efficiently.
Power and Speed
Higher power cuts faster and handles thicker metal. For general sheet metal work, 3kW to 6kW covers most needs. Higher wattage means higher cost, but also faster production.
Bed Size
Pick a bed size that matches your most significant parts. Standard sizes are 4’×8′ or 5’×10′. Larger beds let you cut more parts in one run. That improves efficiency and reduces material waste.
What is the Difference Between Fiber Laser Technology and CO2 Laser?
The most significant difference is how the laser beam is generated and delivered.
Laserquelle
Fiber lasers use a solid-state source with fiber optics. CO2-Laser use a gas mixture and mirrors to guide the beam.
Wellenlänge
Fiber lasers operate at around 1.06 microns. CO2 lasers work at 10.6 microns. Metals absorb fiber laser light better, which makes fiber lasers more effective for cutting metal.
Cutting Speed and Power Efficiency
Fiber lasers cut metal faster and use less power. They are more energy-efficient and cheaper to run.
Wartung
Fiber lasers have fewer moving parts and need less upkeep. CO2 lasers need regular alignment and have more parts to service.
Material Flexibility
CO2 lasers are better for non-metals like wood, plastic, and glass. Fiber lasers are best for metals, especially reflective ones like copper and aluminum.
Schlussfolgerung
Fiber laser cutting is a fast, precise, and cost-effective way to process metal. It uses a high-powered laser beam sent through fiber optics to cut through various metals with speed and accuracy. This method offers clean edges, high efficiency, and low maintenance. It’s ideal for industries that need reliable results and consistent part quality.
Looking for a trusted partner to handle your laser cutting needs? Kontaktieren Sie uns heute, um Ihr Projekt zu besprechen und ein kostenloses Angebot zu erhalten!
Hey, ich bin Kevin Lee
In den letzten 10 Jahren bin ich in verschiedene Formen der Blechbearbeitung eingetaucht und teile hier coole Erkenntnisse aus meinen Erfahrungen in verschiedenen Werkstätten.
Kontakt aufnehmen
Kevin Lee
Ich verfüge über mehr als zehn Jahre Berufserfahrung in der Blechverarbeitung und bin auf Laserschneiden, Biegen, Schweißen und Oberflächenbehandlungstechniken spezialisiert. Als Technischer Direktor bei Shengen bin ich bestrebt, komplexe Fertigungsherausforderungen zu lösen und Innovation und Qualität in jedem Projekt voranzutreiben.
