We are a professional manufacturer of fiber laser processing heads, with over 10 years of industry experience. Our production facility covers more than 1,600 m² and is equipped with 20+ machines, supporting a complete production line with an annual output of over 10,000 units. Our laser cutting and welding heads serve 20+ industries worldwide. Around 20% of our annual revenue is invested in R&D to drive continuous innovation for automation applications. All production staff undergo professional training, practice, and certification by our R&D department before starting work, ensuring both high-quality products and reliable cooperation.

Yes, we can apply your logo as required. For other specific customization requests, please consult our technical team.

Standard delivery is usually within 5-7 days after order confirmation. For in-stock products, shipping can be arranged within 1-2 days. Lead time for customized products depends on the order specifications.

We support EXW, FOB, CIF, and other common international trade terms.

We work with FedEx, DHL, and SF International Express for global delivery.

There is no strict MOQ. Orders can be placed starting from a single laser head.

We support both OEM and ODM orders. Materials, colors, and designs can be customized, with MOQs to be discussed based on project requirements.

Our laser cutting heads are mainly used for cutting metals, including stainless steel, carbon steel, aluminum, and brass.

They are compatible with fiber lasers from 1 kW up to 30 kW, suitable for a wide range of industrial applications.

Our laser processing components are primarily designed for fiber lasers. Some models may also be compatible with CO₂ and diode lasers. Please contact our technical team for further technical details.

Our welding heads are suitable for carbon steel, stainless steel, aluminum alloys, copper, and other common industrial metals, meeting diverse welding requirements.

They support multiple welding patterns, including linear, circular, and elliptical paths, which can be adjusted according to process requirements.

Yes, we provide laser heads equipped with an auto-focus function to enhance precision and efficiency in both cutting and welding.

Yes, we offer specialized cutting heads designed for highly reflective materials. For detailed specifications, please refer to models such as LDC40 and LDC80.

Yes, we supply laser heads designed for robotic and automated applications, supporting intelligent manufacturing environments.

Our laser cutting heads are designed for a wavelength range of 1080 nm ±10 nm.

Our cutting heads support up to 30 kW, depending on the model and application requirements.

We offer multiple focal lengths such as 100 mm, 150 mm, and 200 mm to suit different processing needs.

They operate reliably within a temperature range of 0°C to 45°C.

Yes. All our laser heads undergo rigorous testing to ensure stable output and consistent processing quality.

Our laser heads are compatible with most laser systems available on the market. For specific model matching and parameter details, please contact our sales team.

Each product includes a detailed installation manual. If additional guidance is required, our technical team can provide support. (Please also visit the Download Center for manuals and videos.)

No, installation usually requires only standard tools such as wrenches and screwdrivers. Specialized tools are not necessary.

Yes, we recommend regular inspection and replacement of protection windows to maintain processing quality and extend equipment service life.

Use only dedicated cleaning tools and procedures to avoid scratching the lens surface, ensuring the light path remains clear and stable.

Yes, lens cleaning tutorials are available. Please visit the protection glass maintenance on our website to view them.

Check the optical path, laser protection window, and nozzle condition to ensure they are clean and functioning correctly.

Yes, customization for our laser heads is available. Share your specific requirements with us, and we will coordinate with our R&D team to provide tailored solutions.

The overseas version of the 5G-LINK function is under development. We will update our customers as soon as it becomes available.

Please refer to the official OSPRI Warranty Agreement for detailed information on our warranty terms.

Laser cutting heads are suitable for a wide range of metals, including carbon steel, stainless steel, aluminum, copper, and galvanized sheet.

A laser cutting head is built from several critical parts that work together to ensure stable and precise performance:

• Optical system: collimation and focusing lenses that shape and direct the laser beam.
• Protective lenses: collimation, focusing, and cutting protection windows that shield the optics from vapor, dust, and spatter.
• Cooling system: maintains the proper temperature of the lenses, nozzles, and housing to prevent thermal damage.
• Assist gas system: uses high-pressure gases (oxygen, nitrogen, or air) to remove molten material and improve edge quality.

Yes. OSPRI laser cutting heads support QBH, QD, Q+, and LOE interfaces, and can be integrated with most major laser sources, including IPG, TRUMPF, RAYCUS, and MAXPHOTONICS. They also support pulse, analog, and EtherCAT communication, making them compatible with various CNC systems.

Each new laser cutting head is supplied with the essential consumables required for the initial setup. Additional consumables can be selected based on the user’s processing requirements and applications.

Orders for standard products in stock can be shipped within 1–2 working days. Non-stock items typically require 3–5 working days. Lead times for customized products may vary depending on specifications.

We recommend using original accessories only. Third-party components may not meet the required tolerances, which can cause gas leakage, unstable cutting performance, or even damage to the head. Non-original protective lenses, seals, and ceramic rings can also affect optical alignment, increase thermal drift, and reduce overall reliability.

They’re intended for thin-sheet work across a broad range of jobs: signage and display parts, small metal fittings and brackets, electrical enclosures and cabinet panels, elevator panels, and thin components in aerospace and automotive (for example, trim pieces and small formed parts). They also suit short, custom runs that need clean edges and stable dimensions.

The main assemblies use an integrated housing that improves sealing and durability, protecting the optics and extending service life. On the control side, the heads connect to plant CNC/smart control for remote status monitoring with real-time alerts and diagnostics. When readings drift, the system warns operators early to prevent faults, cut unplanned downtime, and avoid extra costs for parts or on-site service. Remote diagnostics speed up root-cause identification, reduce back-and-forth in after-sales support, and improve service efficiency.

Low-power heads target thin-gauge metals such as carbon steel, stainless steel, and aluminum. As a rule of thumb, thickness is up to about 10 mm for low-power setups; the exact limit depends on the material grade and surface, assist gas, optics, and the overall cutting machine configuration.

Automatic laser cutting heads are designed to handle reflective-metal jobs and improve productivity at the same power level. Some of the advantages of these laser scanner cutting heads, include:

• Stable on reflective metals: Handles brass, copper, silver, polished stainless, and other high-reflectivity alloys by improving energy coupling and controlling back-reflection.
• Higher precision: Beam scanning enables micron-level accuracy (with proper setup), ideal for fine features.
• Much faster motion: The galvo scanner moves the beam, not the head, so the spot travels much faster than on a gantry machine. Using the same wattage, you often see multiple times the cutting speed and throughput.
• Greater thickness capacity at the same wattage: Compared with a standard head of the same power, supports thicker material on reflective cutting processes.
• Flexible path control: Easily executes complex contours, curves, micro-holes, fine pattern cutting, and engraving by steering the beam rather than the whole head.

Follow these steps to mount, align, and verify before production:

• Mount securely. Place the head at the designated location and fasten it with the correct hardware. Make sure the interface is rigid and free of play to prevent vibration or shift during operation.
• Align and connect. Use alignment tools (or an alignment laser) to set the optical axis and standoff. Check all connections: fiber, assist-gas, air, sensor/IO cables, and water-cooling. Confirm there are no leaks or loose fittings.
• Power-up and calibrate. Start the cutting machine and run the initial tests and calibration (focus, height-follower, scan field if applicable). Make any fine adjustments needed so the head cuts accurately and repeatably before loading production parts.

Our high-power laser cutting head is designed for high-performance in thick plate processing. It integrates gas pressure monitoring, leakage detection, piercing detection, and nozzle temperature monitoring. These functions simplify thick plate cutting, improve stability, and allow efficient operation with easier maintenance.

The specialized tube and profile laser cutting heads are capable of processing round tubes, square tubes, and H-beams. Suitable materials include carbon steel, stainless steel, and other industrial-grade metals.

• Before use, wrap the head with protective tape to prevent dust accumulation in gaps during maintenance.
• Do not attempt to clean or disassemble internal lenses if they become dirty or damaged, as this may cause further contamination. It is recommended to replace them directly.
• Replacement of protective lenses, collimation lenses, and focusing lenses must be performed in a cleanroom environment (class 1000 or above).
• When inspecting lenses, first use white paper to check for black spots on the red laser beam. Then, at low power, use black photosensitive paper to examine the beam spot. Finally, remove the lens and inspect it under a microscope for accuracy.

Laser welding can be used across a wide range of metals, including carbon steel, stainless steel, aluminum alloys, and copper alloys. It also supports dissimilar metal welding, such as copper to aluminum or stainless steel to aluminum, making it highly versatile for different industrial needs.

The thickness that can be welded depends directly on the laser power. Higher power enables deeper penetration and thicker plate welding. When selecting a welding system, factors such as laser power, material type, and joint requirements should all be considered to ensure stable weld quality and efficiency.

A typical laser welding head consists of several key units:

• Optical system: Lenses and collimators that shape and focus the beam
• Swing mechanism: Dual-axis swing in some heads improves seam quality for different materials and thicknesses
• Cooling system: Usually water or air cooling to manage heat during welding
• Gas shielding system: Protects the weld area with gases like argon or nitrogen to prevent oxidation
• Control system: Allows adjustment of focus, height, and swing modes for different applications
• Connection interfaces: Link the welding head with the laser source, robots, or automated systems

Spot diameters usually range from 0.1 mm to 3 mm, depending on the laser source, optics, and application. Precision welds for electronics or medical devices often use ~0.1 mm spots, while thicker plates and large structures require >1 mm spots for faster speed and deeper penetration. Swing welding heads can dynamically adjust spot size during welding to optimize quality.

Yes. Thanks to its highly focused and non-contact nature, the laser beam can reach narrow gaps, deep recesses, and complex geometries where traditional torches cannot. Some models are also compact or include swing optics, making them especially useful for automotive manufacturing, mold repair, and precision component welding.

Compatibility depends on parameters rather than brand. The key factors are:

• Laser interface/connector type (e.g., QBH, QD): Must match the laser source
• Power rating: The head must support the intended laser power
• Laser wavelength: Most fiber laser heads are designed for 1064 nm
• Control protocol: IO, RS232, or Ethernet must align with the system
• Cooling and gas connections: Fittings should match the overall setup

Tip: If you’re unsure whether your system matches, simply share your laser model, connector type, and control details with our technical support team, and we’ll confirm compatibility for you.