CO2 Laser Marker
A CO2 laser marker is ideal for marking organic materials such as paper, plastic, and leather. It can also mark metals. Its line quality is clear and durable.
Choosing the right laser marking machine is important. Consider the material type you will be using as well as the marking speed.
Precision Engraving
CO2 laser markers are highly versatile and work with a variety of organic materials. This makes them a popular choice for businesses that need to mark complex designs, logos, and barcodes on items like cardboard boxes, wood products, and leather bags. They also work well on synthetic rubber and glass. Glass has a high heat resistance, so standard Fiber wavelength systems are unable to interact with it, but a CO2 marker can easily etch or mark it.
CO2 machines are also highly accurate and able to produce precise marks with little effort. This is especially beneficial when engraving or marking intricate or delicate designs. They can also be used to score or crease plastic surfaces, making them ideal for adding branding and serial numbers to plastic products or components. This level of customization is an attractive feature for businesses that want to offer their customers a personalized experience.
While these laser machines are excellent for working with a variety of materials, there are some things to keep in mind. For example, some materials may generate toxic gases if they are exposed to a laser beam, and the high-energy of the CO2 machine’s beam can cause permanent damage to eyes if not properly protected. This is why it’s important to have a comprehensive laser safety plan for your business.
High Speed Marking
Laser markers can mark a variety of patterns on non-metallic parts such as plastic, leather and paper. This RF CO2 laser marker is equipped with a high speed galvanometer scanner that helps you mark faster and more precisely. This machine also has an integrated control system that lets you operate it easily. The HS-CL30 is an ideal option for any production line that handles non-metal products.
Using a CO2 laser to mark your products helps you increase productivity. The laser can mark at a higher speed than traditional marking methods, and it can also print more complex codes. This flexibility allows you to adapt your printing needs as production requirements change.
As your line speeds increase, you need a coding solution that can keep up. Videojet high-performance CO2 systems deliver superior code quality across a wide range of substrates, including paperboard, PET, glass and coated metals. They can also accommodate a mix of code formats and fonts, making them the perfect choice for a variety of applications.
Depending on your application, you may need a CO2 laser with co2 laser marker a specific wavelength. Longer wavelengths are best for cutting materials, while shorter wavelengths work better for marking transparent material like glass and PET. There are two different types of CO2 lasers: DC and radio frequency (RF). RF lasers offer several advantages over DC lasers, including greater power stability and a longer operating lifetime.
Easy to Operate
CO2 laser machines operate in the invisible infrared wavelength range and use an aiming beam to indicate where the treatment beam will impact tissue. A focusing lens on the handpiece can be used to collimate this beam into a fine spot, concentrating its photon energy in one location to produce a very high power density (also known as an extremely high irradiance) at this point.
This is sufficient for instant vaporization of the targeted tissue, giving the CO2 laser its reputation as the “laser scalpel”. Because it co2 laser marking system produces an explosive reaction that disperses a laser plume of steam and particulate matter, the clinician should always use a dedicated smoke evacuator during treatment.
The CO2 laser can be operated in a number of temporal beam modes, which can be mechanically or electronically gated to control the delivery of energy over time. The simplest mode is continuous wave (CW), where the beam is turned on for a fixed period of time and then off again. More recent CO2 systems often utilize a train of very short low peak power pulses with a long interpulse interval, also known as quasi-CW (Figure 4a).
This provides a much faster ablation and allows for more efficient bulk vaporization of the target tissue with less thermal build-up in the surrounding area. The CO2 laser can be used to safely mark glass and transparent/translucent plastics such as PET without breaking them, producing a white marking that appears to float on the surface of the material.
Low Maintenance
CO2 laser markers typically have lower initial costs and operating costs than Fiber or UV systems, making them a good choice for budget-conscious buyers. Additionally, these machines are more effective at marking non-metallic materials and can produce crisp codes that ensure product traceability and tamper-proofing.
The laser marker works by using carbon dioxide gas to amplify a beam of light energy, which is then converted into heat energy and transmitted onto the target material. This causes the surface to become melted or gasified, leaving a mark on the material. This process is not only very fast, but it can also be applied to a wide range of materials and surfaces, including plastics, paper, and leather.
This makes the laser marker a great option for manufacturing and production processes, as it can be easily integrated into existing lines without sacrificing speed or precision. It can also be used to mark a variety of 1D and 2D codes, which can help manufacturers improve efficiency.
In addition to its industrial applications, the laser marker can also be used in medical procedures. For example, it can be used to treat certain nail diseases, such as onychodystrophy and ingrown toenails. By irradiating the affected area, the laser can effectively destroy the diseased cells and prevent them from spreading to other parts of the body.