Applications

In aerospace,  MONO LASER’S femtosecond lasers technology enables high-precision cutting, drilling, and surface structuring for components like titanium bleed air ducts, wing fasteners, and Hastelloy-based fixtures, ensuring structural integrity under extreme conditions.

· Throttle Square Hole Machining for Servo Valve Sleeves: As a core component of electro-hydraulic servo systems, the machining precision of throttle square holes in valve sleeves directly impacts the response speed and stability of hydraulic control. With submicron-level positioning accuracy, femtosecond lasers ensure burr-free, crack-free hole edges, enabling servo valves to precisely regulate aircraft hydraulic systems and guarantee flight safety.

· Key Engine Component Machining: For high-temperature alloy fuel nozzles, femtosecond lasers can machine tapered spray holes with gradient diameters (accuracy up to ±1μm), enabling precise control of fuel injection angle and flow rate, improving combustion efficiency, and reducing emissions.

For automotive innovation, the technology drives advancements in micro-manufacturing, producing ultra-precise micro-sensors, connectors, and injection molds for switches or harnesses, while laser welding enhances durability in miniaturized assemblies.

· High-Pressure Fuel Injector Precision Machining: Relying on multi-dimensional precise control technology, it achieves high-precision machining of the fuel injector’s aperture and taper. This process optimizes fuel atomization, enhances combustion efficiency, boosts torque output performance, and reduces fuel consumption, providing robust support for engine performance upgrades.

· Lightweight Structure Machining: For lightweight automotive materials such as aluminum alloys and carbon fiber composites, femtosecond lasers efficiently cut complex contours and form burr-free edges, assisting new-energy vehicles in achieving body weight reduction and structural optimization.

Advantages

MONO LASER’s femtosecond laser technology reshapes precision machining with three core capabilities:

1. Ultra-Precision Machining: Submicron positioning (±1μm) and nanometer-level surface quality meet the extreme precision requirements of critical components like aerospace servo valves and automotive fuel injectors.

2. Universal Material Compatibility: Effortlessly handles hard-to-machine materials such as titanium alloys, high-temperature ceramics, and polymer composites, breaking through the material limitations of traditional processes.

3. Complex Structure Processing: Supports 3D curved surface drilling, gradient aperture forming, and micro-hole array machining, providing unlimited possibilities for innovative designs.