Tube Laser Cutting Systems Design

Trumpf Laser

Every need has its own cutting technology. The materials to be processed, as well as the desired level of productivity and cutting quality, allow users to choose between CO2 and fiber laser cutting systems.

Discover laser systems for electronics manufacturing that perform fast, high-precision cutting, welding, marking, and ablation of metals and plastics.

Tube Lasers Cutting Systems York Pa —

Due to the power required to make a CO2 laser it is much less efficient than a fiber laser and has a lower wall plug efficiency. The large chillers needed to create CO2 lasers require more power overall. The fiber laser resonator has a wall plug efficiency of over 40 percent so you not only use less power but also take up less of your high-demand floor space.

No downtime or extended lead time: Because we combine a tube machine and a laser, each stage of your project can be completed in one location. We can offer full-service support for all your needs.

Tube Lasers Cutting Systems Jacksonville Fl

The wavelength of fiber lasers is 0.06 microns. This difference is 10 times smaller than the wavelength of CO2 lasers. A fiber laser beam produces a wavelength of 1.06 microns, which is 10 percent smaller than that of a CO2 light source. However, a CO2 light source is much more likely be absorbed by reflective materials. Fiber laser cutting machines have the ability to cut brass, copper, or other reflective materials. Note that CO2 laser light that reflects off the material could not only damage the machine's optical system, but also the entire beam pathway. This risk is eliminated when the beam path is made of fiber-optic cable.

Fiber lasers are nearly maintenance-free and demonstrate superior wall plug efficiency compared to traditional CO2 Laser cutting machines. They can also be used for precise cutting of reflective materials. They are faster than CO2 when cutting certain thicknesses of steel. The speed of cutting tube is relative. Real time savings can be achieved by speeding up processing times for the tube and creating finished parts.

Tube Lasers Cutting Systems Jacksonville Fl
Affiliated Websites

Affiliated Websites

For large diameter tubes or profiles, CO2 is the best choice. Tubes up O 14/24" (355 mm/ 610mm) 3D cutting modeCO2 laser

Cambus Medical uses Coherent StarCut Tube, a laser-powered tube cutter machine powered by lasers, and Select Laser Welders for business success.

Tube Laser Cutting Systems Design Pdf

Monaco high-power femtosecond lasers provide superior edge quality in micromachining as well as improvements in scientific applications, such as three-photon microscopescopy.

StarCut Tube SL combines an fs-laser to create complex metal shapes.

Why is my laser not cutting
Why is my laser not cutting

Get a peek into our StarCut Tube manufacturing area and lab to learn about the multi-axis CNC machines that can be used for flat and tube production, as well as medical devices such stent shafts, hypotubes and PTCA devices.

The shape laser technology allows you to customize and cut-to length in one step. From raw material, finished or semi-finished parts can be produced.

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For loading tube stock up 80" or 6'8", we offer a tube extension. Please note that the maximum part size for this extension is 52".

This is the simplest way to get into tube laser cutting. Tubes up to O 4,72 inches (120 mm).2D cutFiber laser

Frequently Asked Questions

The laser beam is the most important component of the laser cutter; it determines wavelength and power, and thus the material that it can cut or engrave. Solid-state lasers, fiber lasers, and CO2 lasers are the three main types of lasers used in laser cutting.

CO2 laser cutters are the most commonly used types of laser cutters because they are low power, relatively inexpensive, efficient, and can cut through and raster a wide range of materials.

Modern CO2 machines typically generate the laser beam in a sealed glass tube filled with gas, typically carbon dioxide. A high voltage flows through the tube, interacting with the gas particles and increasing their energy, resulting in the production of light.