Metal components are meant to be used or operated in different environments. Some of those environments are very harsh in that they have very high temperatures, are very corrosive, or are very reactive among other conditions. Such environments are able to cause very severe effects when they come in contact with metal components, which may lead to a significant reduction in durability, aesthetic value, and functionality among others. To curb the effects of such environments, diffusion coatings were invented.
The process through which a diffusion coating is applied on a metal component is referred to with the same name, diffusion coating. The process takes place in environments with very high temperatures inside a controlled chamber. This process involves activating various metals such as cobalt, nickel, and iron thermally. During the process, the metal component that needs to be coated is cleaned using various methods such as abrasive blasting to remove all kinds of external materials that may affect bond formation with the coating.
Once the substrate has been cleaned properly, it is placed into a contained together with the metal used for coating. The container is then placed inside a furnace or a chamber. The furnace is turned on and the temperature set to the range of 380-425 degrees centigrade.
Diffusion of the metal occurs when temperatures rise high enough within the range specified. An alloy between the substrate and metal is formed in turn. The duration of the whole processes varies relying on the kind of metal and substrate used. However, 2-4 hours is the normal range. Continuous turning of substrates must be done for uniformed thickness to be attained.
The smoothness of the resultant coating is high while the thickness if uniform. Thicknesses can be varied to suit different functions. However, 15-80 micrometers is the normal range of thickness. The coating resembles the metal used in color. Iron, cobalt, chromium, aluminum, and silicon are some among the commonest metals in use. Various metals such as iron, steels, cobalt, and nickel can be coated.
The coating that results is capable of resisting erosion, oxidation, and reaction with substances like air and water. Metal components that are used for critical functions are made stronger, more durable, and more reliable. Gave valves, pump impellers, power generation components, and gas turbines engine constituents including vanes, blades, and cases are among the components that are coated this way.
The process is used mostly in industrial settings and few household equipment have components that are coated this way. The technology was invented several years ago and has been undergoing a lot of modifications aimed at perfecting it. Currently, there are better methods and technology for doing it.
Modern day furnaces have a lot of improvements in the form of features aimed at increasing efficiency and functionality. Today it is possible to achieve very thin coatings that are very strong and effective at eliminating corrosion. The automotive industry is particularly known for using this technology.
The process through which a diffusion coating is applied on a metal component is referred to with the same name, diffusion coating. The process takes place in environments with very high temperatures inside a controlled chamber. This process involves activating various metals such as cobalt, nickel, and iron thermally. During the process, the metal component that needs to be coated is cleaned using various methods such as abrasive blasting to remove all kinds of external materials that may affect bond formation with the coating.
Once the substrate has been cleaned properly, it is placed into a contained together with the metal used for coating. The container is then placed inside a furnace or a chamber. The furnace is turned on and the temperature set to the range of 380-425 degrees centigrade.
Diffusion of the metal occurs when temperatures rise high enough within the range specified. An alloy between the substrate and metal is formed in turn. The duration of the whole processes varies relying on the kind of metal and substrate used. However, 2-4 hours is the normal range. Continuous turning of substrates must be done for uniformed thickness to be attained.
The smoothness of the resultant coating is high while the thickness if uniform. Thicknesses can be varied to suit different functions. However, 15-80 micrometers is the normal range of thickness. The coating resembles the metal used in color. Iron, cobalt, chromium, aluminum, and silicon are some among the commonest metals in use. Various metals such as iron, steels, cobalt, and nickel can be coated.
The coating that results is capable of resisting erosion, oxidation, and reaction with substances like air and water. Metal components that are used for critical functions are made stronger, more durable, and more reliable. Gave valves, pump impellers, power generation components, and gas turbines engine constituents including vanes, blades, and cases are among the components that are coated this way.
The process is used mostly in industrial settings and few household equipment have components that are coated this way. The technology was invented several years ago and has been undergoing a lot of modifications aimed at perfecting it. Currently, there are better methods and technology for doing it.
Modern day furnaces have a lot of improvements in the form of features aimed at increasing efficiency and functionality. Today it is possible to achieve very thin coatings that are very strong and effective at eliminating corrosion. The automotive industry is particularly known for using this technology.
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