Gulf States Saw & Machinery Co., Inc. has the capability to produce tube lasers that can be used to replace manual processes or optimize the cutting process.
For XXL tube production, the machine was designed to maximize productivity. The machine's solid-state laser can be used to process tubes and profiles in many ways. It is compatible with many types of material and wall thicknesses.
Large diameter tubes and profiles can be cut with CO2. Tubes up O 14"/24" (355mm /610mm)3D Cutting modeCO2 laser
Fiber lasers don't require as much maintenance. It does not require the same attention as a CO2 laser-cutting machine in terms of mirror cleaning and bellows inspections. It doesn't require any maintenance, as long it has clean chiller water to cool off and its air filters are regularly changed.
Our system solutions allow for flexible production of small or large series with diameters from 10 to 324 millimeters, and pipe and profile lengths as high as 12.5 meters.
A laser cutting machine can make a sheet of sheet metal in seconds. However, a laser tube cutting machine can achieve the same results. It is quite different from how it works.
Even for XXL tubing, it is built for maximum productivity. This machine has a solid-state laser that can be used in a variety of ways to produce tubes and profiles from varying materials and wall thicknesses.
A few machinery manufacturers now use cameras to verify tubes. The cameras reduce the quality inspection to less than a second, as well as the number of required rotations. This allows the machine both to remain productive and accurate.
No need for multiple vendors and orders to be coordinated. Gulf States Saw & Machinery Co., Inc. has the ability to manage everything, including material procurement and past delivery.
The wavelength of fiber lasers is 1.06 microns. This is 10% less than the wavelength of a CO2 laser beam. The fiber laser emits a beam with a shorter wavelength that is more easily absorbed and reflected by reflective materials than a CO2 laser. Fiber laser cutting machines are able to cut brass, copper and other reflective materials. Be aware that the CO2 laser beam can damage not only the machine's lens but also the entire beam path. This risk is eliminated by using a fiber-optic cables for the beam path.
A tube is very flexible and does not require a high-powered laser. Laser generators with a power output of 12 kW are now possible for flat sheet cutting machines. Tube laser cutters require a power consumption of only 5 kW. To cut a tube you must always look at the opposite end of the tube. A stronger laser would simply blow through your tube while cutting. (Officially, if the laser is processing a beam and a channel on the tube's laser, there are no need to worry about any other side.
The most important criteria for the construction of fitness equipment are design, durability, usability, and compactness.
Keep in mind that the traditional method for checking for twists or bows within the tube can take between five and seven seconds before cutting begins. Traditional touch sensing methods can be slow and inaccurate. While this may seem like a long time in the ageof fiber laser cutter, it is actually not that simple when working with tubes.
Secondary operations are eliminated: A tube Laser can cut a length of piece, add holes and cutout other designs in one operation. It also eliminates the need for additional actions like manual material removal. For more complex fabrications, you can maintain tight tolerances. Parts can easily be manufactured from one continuous raw material. Tube laser aluminum, stainless-steel and carbon can be made.
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.