Laser
cleaning, on the other hand, is non-contact and non-abrasive, and so
will only irradiate the material that you want to get rid of. This makes
the process in particular, ideal for cleaning intricate and textured
materials. You also have a great deal of control over the beam, meaning
you can achieve the desired depth that you want to. Further to this, you
can irradiate the whole surface layer of a material, or a much thinner
layer, say the topcoat of paint, but not the primer below. Or, should
you wish, you can just clean a very small section. If using another
process which simply blasts the material, it is hard to enjoy such a
high level of control. One of the key benefits in the way that laser
cleaning works is that not much waste is left over due to the
irradiation process; the substrate is simply vaporised rather than left
as waste. The majority of the waste that is left over comes as dust
particles and can be easily collected and removed by the user.
It is mostly dust particles that are left behind from the laser cleaning process As if all the above isn’t
enough, the laser cleaning process is also much faster, leaving staff more able to complete other work and
not spend all of their time cleaning!
Application industry and purpose of Laser Cleaning Machine
Cleaning
machine application industry microelectronics: semiconductor
components, microelectronics, memory templates, etc.; cultural relic
protection: stone carving, bronze, glass, oil painting and murals, etc.;
abrasive cleaning: rubber molds, composite molds, metal molds, etc.;
surface Treatment: Hydrophilic treatment, treatment of welds before and
after welding, etc.; Paint removal and rust removal: aircraft, ships,
weaponry, bridges, metal pressure vessels, metal pipes, etc.; aircraft
parts, electrical product parts, etc.; Others: urban graffiti, printing
rollers, building exterior walls, nuclear industry, Shipbuilding
industry, auto parts, rubber molds, high-end machine tools, tire molds
Track Environmental protection industry Weapon equipment industry
Nuclear power industry and others etc,.
Machine model | LS1LW |
Max laser power | 1000 watt/2000w/3000w |
Laser source | Relfar |
Laser wavelength | 1070nm |
MAX Pulse width | 100mm |
Laser Style | continuous |
Instability of energy | <2% |
Beam Divergence | ≤8mrad |
minimal beam diameter | 0.1mm |
Adjustable scope of laser spot | 0.1~1mm |
Welding depth | 3~8mm |
Continue working time | 16hours |
Noise | ≤30db |
Transmission system | Fiber optical transmission system (FOTS) |
Fiber optical length | 10m standard |
Power Consumption | ≤7.2KW |
Cooling system dimensions | Water cooling |
Power required | 220V±10%/50Hz |
Consumable | Xenon lamp、Filter element、Protective lens、Argon |
Working temperature | 55°F(13°C)-82°F(28°C) |
Working Humidity | 5%-75% |
Oil mist | ≤15mg/m³ |