Description
Laser welding is a high-efficiency, precision welding technique that uses a high-energy laser beam as its heat source. The laser heats the surface of the workpiece, and the heat diffuses inward through conduction, melting the material to form a controlled weld pool.
By adjusting parameters such as pulse width, energy, peak power, and repetition frequency, highly accurate welds can be achieved.
Thanks to its speed, precision, and minimal heat distortion, laser welding is widely used for micro and small component fabrication across various industries.
Key Advantages
- High electro-optic conversion efficiency for superior energy utilization.
- Deep penetration welding on thick plates with minimal spatter.
- Excellent material adaptability and high reaction capability.
- Efficient and precise welding performance on thin plates.
- Customizable output fiber length to meet various application needs.
- Wide modulation frequency range for enhanced process flexibility.
- Maintenance-free operation ensures consistent productivity.
- Stable water-cooling system for reliable long-term performance.
Technical Parameters
| Laser Source | Max Handle – Aluminium hand-held, light and easy to use |
|---|---|
| Laser Power | 1500W / 2000W / 3000W |
| Wavelength | 1080 nm ±5 |
| Laser Incidence | Coaxial |
| Power Stability | ±1.5% |
| Laser Repetition Frequency | 50 – 50,000 Hz |
| Collimated Focal Length | 50 mm |
| Beam Quality (M²) | < 1.3 |
| Focusing Focal Length | 100 mm |
| Red Light Indicator Output Power | 0.1 – 1 mW |
| Operating Voltage | AC 220V, 50 Hz |
| Fiber Core Diameter | 25 µm |
| Cross Power | < 5000 W |
| Output Cable Length | 10 m |
| Gas Source | 0.2 MPa (Nitrogen) |
| Operating Mode | Continuous |
| Cooling Method | Water Cooling |
| Interface Type | QBH |