Laser engraving is very different from traditional engraving methods. Its high-efficiency, high-precision, low-cost, and non-contact processing methods are well received and trusted by customers once it is launched. However, when buying a laser engraving machine, users and friends need to consider all aspects, starting from the power, speed, precision, etc., which are usually neglected in our transactions, in order to purchase a truly satisfactory laser equipment.

First of all, we must choose the appropriate laser tube power.

Depending on the material and content of the engraving, the appropriate laser tube wattage should be selected. For example, the engraving of acrylic and two-color panels does not require too much laser tube power, while the engraving of wood and stone and the cutting of any material may require a higher power laser tube to get more results with less effort.

Secondly, we must consider the speed and accuracy of the laser engraving machine.

Only by producing more products at the fastest speed in the shortest time can create higher profits, so the speed is often the key to receiving orders and making money. In addition, the biggest difference between the laser engraving machine and the traditional mechanical engraving method is its high precision. 

Finally, the most important point is the manufacturer's after-sales maintenance service.

The after-sales maintenance service of machinery and equipment is very important. A good after-sales service level is even a decisive factor in attracting users to become regular customers. There are no machinery and equipment that will never break, so the level of after-sales service that makes customers feel at home is very important.

The main difference between fiber lasers and carbon dioxide lasers is that the working materials of the two are different. The working material of fiber lasers is fiber, while the working material of carbon dioxide laser is carbon dioxide, which is a gas laser. In addition, the power of the two is relatively large. the difference.

At present, fiber lasers are widely used from hundreds of watts to thousands of watts, while the common power range of carbon dioxide lasers is 80W to 600W. The photoelectric conversion efficiency of fiber lasers is higher than that of carbon dioxide lasers. In terms of cutting quality and speed, fiber lasers are better than carbon dioxide lasers; in terms of use and maintenance costs, fiber lasers are lower than carbon dioxide lasers; in terms of one-time investment, fiber lasers are slightly better Higher than carbon dioxide lasers; in addition, both fiber lasers and carbon dioxide lasers require chillers to cool them down.

1. It is strictly forbidden for non-laser professionals to operate the laser.

2. Make sure to read the "Laser Operating Instructions" carefully before using the laser.

3. It is forbidden for the eyes to be at the same level as the laser light outlet, and it is absolutely forbidden to expose the body to the laser transmission light path.

4. Be sure to wear laser protective glasses to operate the laser.

5. Make sure that the position of the laser output window is not blocked before the light is emitted.

6. Get in touch with the company's technical support as soon as you encounter problems during use.

7. Ensure that the laser use environment is grounded.

The particles in the water will penetrate into the laser casing, directly attached to the circuit board, or even penetrate the optical module attached to the surface of the sensitive optical fiber. The surface of the optical fiber absorbs the laser light and generates heat, which destroys the coating layer and causes the entire optical part to be destroyed.

Therefore, once the laser or processing head suffers serious water soaking, the end customer must be reminded to notify the equipment manufacturer as soon as possible after-sales, and confirm that the laser and laser output head have no problems through on-site maintenance or return to the factory for cleaning.

If the current after-sales tasks are tight, you can also ask the customer to take a picture and send it to the OUHK engineer to simply judge whether you need to return to the factory. The OUHK is willing to fully assist your service work at this special moment!

Laser cutting is a technique that uses a laser to slice materials. Although commonly used in industrial manufacturing applications, it has also begun to be used by schools, small businesses and hobbyists.

Fiber lasers can cut copper, brass, and aluminum better and safer than CO2 because the beam is more easily absorbed rather than reflected. Due to the low power consumption and high electrical efficiency of fiber lasers, the operating cost of fiber lasers is usually only half of the cost that a CO2 system can provide.

Laser cutting is a technique that uses a laser to slice materials. Although commonly used in industrial manufacturing applications, it has also begun to be used by schools, small businesses and hobbyists.

Fiber lasers can cut copper, brass, and aluminum better and safer than CO2 because the beam is more easily absorbed rather than reflected. Due to the low power consumption and high electrical efficiency of fiber lasers, the operating cost of fiber lasers is usually only half of the cost that a CO2 system can provide.

Laser cutting is a technique that uses a laser to slice materials. Although commonly used in industrial manufacturing applications, it has also begun to be used by schools, small businesses and hobbyists.

Fiber lasers can cut copper, brass, and aluminum better and safer than CO2 because the beam is more easily absorbed rather than reflected. Due to the low power consumption and high electrical efficiency of fiber lasers, the operating cost of fiber lasers is usually only half of the cost that a CO2 system can provide.

Laser cutting is a technique that uses a laser to slice materials. Although commonly used in industrial manufacturing applications, it has also begun to be used by schools, small businesses and hobbyists.

Fiber lasers can cut copper, brass, and aluminum better and safer than CO2 because the beam is more easily absorbed rather than reflected. Due to the low power consumption and high electrical efficiency of fiber lasers, the operating cost of fiber lasers is usually only half of the cost that a CO2 system can provide.