The working principle of a laser marking machine essentially involves the focusing and application of high-precision laser energy to create fine patterns or text on the surface of a workpiece. The process starts with a laser, which acts as an energy source and emits a high-power, monochromatic laser beam. The laser then passes through a carefully designed lens and reflector system, a process similar to the focusing mechanism of an optical telescope, which converges the originally scattered laser beam into an extremely small, highly energy-concentrated light spot.
When this high-energy light spot falls accurately on the surface of the workpiece, the huge energy it carries is instantly converted into a local high-temperature and high-pressure environment. Under such extreme conditions, the material on the surface of the workpiece undergoes physical or chemical changes, including direct evaporation (i.e. sublimation) of the material or more complex oxidation reactions, leaving a clear and lasting mark on the workpiece.
The laser marking machine is exquisitely constructed, and its key components perform their respective duties: the laser is responsible for generating laser light; the lens and reflector combination serve as "optical path engineers" to ensure that the laser beam can be accurately focused; the scanning mirror is like the pen tip of a plotter, which draws a preset pattern or text on the workpiece by accurately controlling the movement trajectory of the light spot; and the control system is the commander of all this, which is responsible for coordinating the work of each component to ensure that the entire marking process is both efficient and accurate.
In summary, the laser marking machine achieves the goal of leaving personalized marks on the surface of the workpiece quickly and accurately through a highly focused laser beam and a precisely controlled scanning system.