Damping Alloys
Damping alloys are a class of materials which have excellent damping properties. These alloys are typically composed of a base metal, such as iron or steel, and other alloying elements, such as aluminum, nickel, chrome, and titanium. These materials can absorb up to 98% of vibrational energy, making them highly effective in noise and energy damping applications.
Damping alloys are typically used in the following applications: automotive and heavy equipment components, sound reduction products, electronic device housings, and tools and machinery. These alloys are also used in synthetic rubber, rubber products, and even jewellery.
Alloys of iron and aluminum are commonly used due to their strong yet lightweight properties. These alloys can generally handle high temperatures without sacrificing levels of damping or strength.
Alloys composed of iron, aluminum, and silicon are also used in damping. These alloys are able to absorb high levels of energy and are often used in high heat and humidity conditions. They are also ideal for applications which require light-weight components while providing high levels of damping.
Titanium alloys are also used in some damping applications due to their ability to hold up under extreme temperatures. Titanium alloys are also highly corrosion resistant and require minimal maintenance. These alloys are often used in applications where strength and corrosion resistance are important factors.
Nickel-chrome alloys are commonly used in damping applications because of their good balance of strength, ductility and machinability. Their high heat resistance and excellent corrosion resistance make them a good choice for many different applications.
Damping alloys are very beneficial in any application which requires vibration or noise damping. The material’s ability to absorb up to 98% of vibrational energy makes them essential for a wide range of applications. The types of damping alloys vary based upon the application and environment but the benefits and performance remain consistent across the board.
