A blended powder of tungsten carbide and Metal Alloy Powder can be used for laser cladding, a process used to deposit a layer of material onto a substrate using a laser beam. This blended powder is typically used as a feedstock material for laser cladding applications where high wear resistance and hardness are required. WC Blend,Blended Powder,High Hardness Powder,Blended Coating Powder Luoyang Golden Egret Geotools Co., Ltd , https://www.xtcthermalspray.com
Recently, China Changhang Jiangdong Shipyard combined with the current precision shipbuilding mode, according to the actual needs of the production, proposed a segmented no-capacity closing precision control process plan for the 11,000-ton cargo shipyard of the plant.
According to the introduction, the scheme can achieve the requirement of no-capacity and large-close precision by constructing the double-bottom section of the cargo hold and the precise control, measurement and dressing after turning over, reducing production cost, speeding up technological transformation and improving shipbuilding precision management. Levels improve work efficiency.
The industry believes that this program is of great significance for promoting the upgrading of ship types and models, promoting the transformation of shipbuilding technology, improving the utilization of ship platforms and shortening the shipbuilding cycle.
Tungsten carbide is a hard and wear-resistant material that is commonly used in cutting tools, mining equipment, and other high-wear applications. It has excellent thermal conductivity and high melting point, making it suitable for laser cladding processes.
Metal alloy powders, on the other hand, are often added to the Tungsten Carbide Powder to enhance certain properties or tailor the characteristics of the final cladding layer. These metal alloys can include nickel, cobalt, chromium, or other elements, depending on the specific requirements of the application.
The blended powder is typically prepared by mixing the tungsten carbide and metal alloy powders in the desired ratio. This mixture is then fed into a laser cladding system, where it is melted using a high-power laser beam. The molten powder is rapidly solidified onto the substrate, forming a dense and wear-resistant cladding layer.
The resulting cladding layer can have excellent hardness, wear resistance, and thermal conductivity, making it suitable for various applications such as tooling, wear parts, and surface protection. The specific properties of the cladding layer can be adjusted by varying the composition and ratio of the tungsten carbide and metal alloy powders in the blend.
Overall, the blended powder of tungsten carbide and metal alloy powder offers a versatile and customizable solution for laser cladding applications, providing enhanced wear resistance, hardness, and other desired properties to the final cladding layer.