Lasertube makes it easy to customize parts according to the requirements of your customers.
The CO2 solution to large-diameter tubes and profiles Tubes up O14" / 24", (355 mm, 610 mm).3D cutting modeCO2 laser
Some things are quite noticeable. The laser “generator” on a fiber laser is much smaller when compared to a traditional CO2 resonator. In fact, the fiber laser is created by banks of diodes that are put together in a briefcase-size module that can range in power from 600 to 1,500 watts. Multiple modules are spliced together to create the final powered resonator, which is typically the size of a small filing cabinet. The light generated is channeled and amplified through fiber-optic cable. When the light exits the fiber-optic cable, it is the same that is was upon being generated with no loss of power or quality. It is then adjusted and focused for the type of material to be cut.
How can you compensate for this? Traditionally, you will touch your face with a sensor marking the contact point. The tube is then rotated and the opposite end of the tube touched. The control will then be able to see how bent the tube looks. This allows for precise measurements and ensures that the through-holes will work properly. Keep in mind, however, that every rotation of the tube reduces the ability for very high tolerances.
Cambus Medical uses Coherent StarCut Tube to cut tubes and Select Laser Welders in order to build business success.
There is no perfect tube. They also have bows. The tube's interior can also be exposed by welding seams. It can be challenging to process this material quickly and consistently when inconsistencies exist between products.
Parts are held in place with automatic tabbing, done in FabCreator and a set o jaws on each drive chuck or idler chuck.
Another consideration in tube cutting is the weld seam. This material is roll-formed and welded together. This brings up two points that typically must be addressed:
We offer the best solutions in laser tube cutting. Discover how lasers are able to reduce the time and increase the amount of parts you can create.
Tubes are very simple and do not require a powerful laser. Tube laser cutting machines require only 5 kW power, whereas flat sheet laser cutters can be powered by laser generators up to 12 kW. When cutting a tube, it is important to always think about the other side. A stronger laser would simply blow through the tube on the opposite side during cutting. You don't need to worry about the other side if you're processing a beam of a channel or a channel using the tube laser.
At one time many thought that fiber lasers could be used only for thin materials. The CO2, with its larger wavelength, created enough kerf during the cutting of thick materials that enough space was allowed for material removal; the fiber laser couldn’t produce the same kerf or results with thicker materials. But that has been addressed in recent years with collimating technology that can produce a wider fiber laser-generated beam that creates materials separation and room for material removal in thick materials. And since the beam width is switchable, the machine can use the narrower beam to process thin materials, which allows for faster processing of different-sized materials on the same fiber laser cutting machine.
The most productive solution to tubes of any section. Tubes upto O 6" (152.4mm).2D cutCO2 (or fiber laser).
This is your easiest route to tube laser cutting. Tubes as large as O 4,72" (120mm).2D cutter laser
There is a cutting technology that suits every need. Users have two options: CO2 laser cuttingsystems or fiber laser cutting systems, depending on the material to be cut and the level of productivity desired.
A fiber laser cutting machine generates a laser beam using active optical fibers and transmits it to the machine's cutting head via a transport fiber. This extremely hot laser is condensed into a narrow beam and is used to cut through various metal thicknesses.
What is the operation of a CO2 Laser? 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.
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.