TruLaser Tube 5000 fiber is an affordable laser tube cutting machine. It's easy to use and reliable, making it ideal for new users as well as those who need a second machine.
Save time and reduce the number of components.Make tubular frames and metal structures that are more precise and faster to assemble.Complete your part in one programming step, in one machining step, and on one system.
Another thing to remember is that traditional methods of checking for twists and bows in the tube may take as long as five to seven seconds before cutting begins. You have to compromise accuracy for productivity with traditional touch sensing. This can be frustrating, especially in this age of fiber laser cutting. However, working with tube is much more difficult than working with sheet metal.
StarCut Tube L 600 can be ordered with either a fiber laser, USP laser, or both. StarCut Tube SL compact model has the smallest footprint on the market.
Motion Dynamics is a top manufacturer of neurological subassemblies. These include steerable catheters and "pullwire" assemblies. Motion Dynamics makes use of StarCut Tube machines for precise cutting of key components.
Cambus Medical uses Coherent StarCut Tube, a laser-powered tube cutter machine powered by lasers, and Select Laser Welders for business success.
The worthwhile laser tube cutting machine: the TruLaser Tube 3000 fiber is economical even when it is not being fully utilized. Thanks to its reliability and easy of operation, it is perfect for first-time users or as a supplementary machine.
Built for maximum productivity, even for XXL tubes. With its robust solid-state laser, this machine can be used in numerous ways for the processing of tubes and profiles with a wide range of types of material and wall thicknesses.
Traditional tube features can take a lot of time. FabLight makes it simple to have exactly what you want, and how you design it in just minutes.
Use Coherent laser systems to cut, weld, drill, texturize, and mark medical devices for precision manufacturing.
The fiber laser requires less maintenance than a CO2 laser. The fiber laser does not need the mirror cleaning or bellows checking that a CO2 cutting machine requires. The fiber laser doesn't need any preventive maintenance, provided it receives clean chiller and cooling water.
Some things aren’t quite as evident until you take a closer look at a fiber laser in operation. Because its beam diameter is often one-third the size of a CO2 beam, a fiber laser has a greater power density than a CO2 laser beam. Not only does this allow the fiber to cut faster, but it also allows it to pierce faster. This smaller beam size also gives the fiber the ability to cut intricate shapes and leave sharp edges. Imagine cutting a company logo out of a tube when the spacing between the logo’s letters is 0.035 inch; a fiber can make that cut, while a CO2 laser can’t.
PowerLine C is a CO2 laser-based system for precision drilling, cutting and scribing of many non-metals including glass and organic materials.
Many believed fiber lasers could only work with thin materials. Because CO2 has a longer wavelength, it created enough material kerf to permit material removal. Fiber lasers can't produce the same level of kerf and results with thicker materials. This has been corrected by collimating tech, which can produce a wide fiber laser-generated beam that allows for materials separation. It also makes it possible to allow for material removal in thicker materials. You can also switch the beam width so that the machine can process thin materials with the narrower beam. This allows you to process more materials in a shorter time.
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.