Laser cladding is a type of laser additive manufacturing process, where a selected cladding material is applied to the surface of a base component, forming a metallurgical bond with the substrate. This surface coating significantly enhances the base material’s resistance to corrosion, wear, high temperatures, oxidation, and certain electrical properties. It is used to modify or repair the surface of workpieces in a way that meets the specific performance requirements of materials, while also saving valuable resources by avoiding unnecessary consumption of precious elements.

În prezent, placare cu laser is primarily applied in several key areas: surface modification of materials such as rollers, gas turbine blades, gears, etc., to increase their performance; surface repair of products like rotors and drill bits, where the repair cost is only about 20% of the cost of re-manufacturing, shortening repair time and addressing the urgent need for fast repairs of key components for continuous and reliable operations in large-scale enterprises. Additionally, placare cu laser technology is used to apply a super-wear-resistant, corrosion-resistant alloy to the surface of molds, significantly increasing the lifespan of these components.

Commonly Used Laser Cladding Materials

The most commonly used materials in placare cu laser include nickel-based, cobalt-based, iron-based alloys, and tungsten carbide composites. Among these, nickel-based materials are the most frequently used due to their cost-effectiveness when compared to cobalt-based materials. Compared to traditional methods such as welding, electroplating, spraying, and chemical vapor deposition, placare cu laser technology offers the following advantages:

Fast Cooling Rate: The rapid solidification process allows the workpiece to achieve fine-grained structures or produce new phases such as non-equilibrium or amorphous states, which cannot be obtained through equilibrium processes.

Low Cladding Dilution: The cladding material forms a strong metallurgical bond or interface diffusion bond with the substrate. By adjusting parameters like laser power, spot size, and focal length, a high-quality coating with controlled composition and dilution can be obtained.

Minimal Thermal Distortion: Using high-power density for rapid cladding, deformation can be controlled and reduced to within the assembly tolerance of the part. If the part undergoes a post-cladding laser surface enhancement process, internal stresses are removed, and brittleness is reduced, yielding the best results.

Flexible Powder Selection: There are almost no restrictions on the powders that can be used, and any type of powder material can be selected according to process requirements, especially in cases where high-melting-point alloys are cladded onto low-melting-point metals.

Selective Cladding: Placare cu laser allows for selective cladding, reducing material consumption while improving performance, making it an economically efficient solution.

Reaching Hard-to-Access Areas: Placare cu laser can be applied to areas that are difficult to reach, as long as the laser spot and powder can reach the required regions.

Wide Range of Cladding Thickness: The thickness of the cladding layer can be varied, and the same area can undergo multiple passes of cladding for enhanced coating quality.

Laser Cladding in Component Repair and Maintenance

Component damage, especially in drive shafts, often involves irregular wear in various locations such as bearing seats and exposed areas. Even parts that are frequently worn or corroded may only show damage in specific areas. Many surfaces may also have non-circular and non-linear characteristics, requiring a cladding process that can adapt to multiple orientations within a single operation. This is particularly challenging for traditional straight-line machines, but robots with mechanical arms can simulate human-like motions to handle such tasks, making placare cu laser ideal for parts with non-circular and non-linear features. Traditional machine tools, particularly CNC lathes, are still commonly used as the motion carriers during cladding operations.

Aplicații industriale ale placării cu laser

În prezent, placare cu laser is widely used in industries such as shipbuilding and mining machinery, especially for manufacturing or repairing key large moving parts. The ability to quickly repair and enhance these critical components is a significant advantage in these industries, as it minimizes downtime and extends the lifespan of expensive machinery.