· Power range: 2–6 kW for thin sheets, 8–30 kW for thick plates.
If you want to learn more, please visit our website.
· Cutting speed: fiber lasers are the fastest and most efficient.
· Material type: do you cut sheets, tubes, or both?
· Cost efficiency: weigh the initial investment against long-term savings.
· The LFLNor LFEPRO are excellent for thin stainless steel sheets.
· For heavy-duty plates, the LFGH or GA Series deliver the power you need.
· If you want a dual-use system, the LFCR combines sheet and tube cutting in one machine.
In most cases, a fiber laser for cutting stainless steel offers the best balance of performance, cost, and flexibility.
Many stainless steel grades can be laser-cut efficiently and with high accuracy, provided the correct equipment and process parameters are used. Laser cutting offers various advantages over more traditional approaches — it reduces the risk of work hardening, introduces minimal heat-affected zones (HAZ), and often eliminates the need for post-processing. However, cutting stainless steel requires proper understanding of the material's properties, adherence to best practices, and the use of high-performance laser systems.
This article serves as a primer on best practices for laser cutting stainless steel and highlights how to avoid common errors.
Stainless steel is a broad term for austenitic, ferritic, precipitation, martensitic, and duplex (those with both austenitic and martensitic components) alloys. These alloys contain iron, carbon, chromium, and a range of other metallic alloying agents such as nickel, molybdenum, copper, niobium, titanium, and aluminum. Intentional additions can also be non-metallic, such as silicon, carbon, and sulfur.
The result is a spectrum of properties. Some alloys are strongly magnetic, while others are only weakly so or entirely non-magnetic. Some such steels are easy to work-harden, while others barely change. And though “stainless steel” is rhetorically synonymous with corrosion resistance, some versions do not fare well on that front.
All stainless steel alloys can be laser-cut given the proper machine settings, sufficient power, and the right controlled atmosphere. In general, the types of cuttable stainless steel are:
With competitive price and timely delivery, FOSHAN WINTON STAINLESS CO.,LTD. sincerely hope to be your supplier and partner.
These three primary families of stainless steel differ in key properties, such as work hardening behavior, magnetic permeability, corrosion resistance, hardness, and crystal structure, all of which influence their performance during and after laser cutting.
Laser processing offers distinct advantages over conventional 2D fabrication methods when working with stainless steel. The non-contact nature of the laser cutting process means there is no mechanical force applied, which eliminates distortion and prevents work hardening in the material. When performed under optimized conditions, laser cutting can produce fused, clean-cut edges with minimal burrs, typically requiring little or no post-processing. Laser systems can cut stainless steel up to approximately 100 mm thick in a single pass. However, this capability depends on the laser type, power output (typically multi-kilowatt), cutting gas, and material grade. For most industrial applications, cuts are usually performed on material up to 25 mm thick using high-power fiber lasers.
Laser marking of stainless steel is achieved using two primary techniques:
Because the heat input is highly localized, both methods produce minimal distortion or discoloration outside the immediate marking zone. In contrast, mechanical methods such as rotary machining or abrasive cutting often result in a larger heat-affected zone (HAZ), with potential for structural changes, discoloration, and loss of corrosion resistance.
Laser engraving of stainless steel is possible as well, but it often results in discoloration. The engraving process destroys some of the surface oxide layers. Laser engraving is functionally identical to laser cutting. The difference is that the cut depth must be very tightly controlled to achieve good surface quality.
Laser etching is a more controlled process for stainless steel. The subsurface of unoxidized metal is annealed or melted without removing the protective oxide surface layer, which is essentially transparent to most cutting lasers. This method allows limited diffusion of oxygen through the oxide layer, staining the metal below in shades of yellow or brown, depending on the intensity.
In many contexts, laser etching and laser annealing are used interchangeably, as both involve oxidation-based marking rather than material removal. This method is preferred for decorative, functional, or traceability marking when preserving the corrosion resistance of the stainless surface, which is critical.
The lasers that can effectively cut stainless steel are fiber and CO2 lasers. Fiber lasers can produce much narrower beams, typically half the diameter of the cutter ‘dot’ of a CO2 laser. This results in about quadruple the effective power for the same laser output energy. Fiber lasers can process faster and with greater precision because of this. Operating costs for fiber lasers are lower because of their electrical efficiency (4 to 6 times better than for CO2 devices) and solid-state construction. They do require more nitrogen shielding gas in the cutting process, though.
CO2 laser cutting typically delivers a 600-µm cutter beam width. These lasers are capable of much higher device power than fiber lasers, though modern fiber lasers are gaining ground in that regard. CO2 lasers are better suited to lower-precision cuts on thicker parts. The CAPEX cost of equipment is considerably lower than that of fiber laser machines, but OPEX costs are higher per length of cut. For more information, see our guide on Types of Laser Cutters.
When properly configured, laser cutting of stainless steel produces precise cuts with clean, burr-free edges and minimal heat-affected zones (HAZ). However, the process is susceptible to machine parameters, gas settings, and alignment. A gas-assist system is essential for clearing molten material from the kerf and ensuring consistent quality. Even so, the process is sensitive to setup, and several common faults can appear.
If large, irregular drips form along the lower face on both sides of the cut, the laser is introducing too much heat into the material. This can usually be corrected by increasing the feed rate, raising assist gas pressure to clear molten metal more effectively, or shifting the focal point slightly higher above the surface. When the same type of dripping appears only on one side of the cut, it often indicates a misaligned or off-center assist gas nozzle, though excess heat can also contribute.
Small drips at the lower edge of the cut are usually caused by the focal point being set too low, sometimes combined with a feed rate that is too fast. If molten metal splashes upward out of the kerf, the feed rate is almost certainly too high, and in some cases, the assist gas is also too aggressive.
Finally, yellow or brown discoloration along the cut edge points to insufficient nitrogen shielding or contamination of the nitrogen supply with oxygen. This type of oxidation is a sign that the cut is not being appropriately protected, and it can be corrected by increasing nitrogen flow or checking gas purity.
Want more information on Laser stainless steel sheet? Feel free to contact us.