The application of
amorphous nanocrystalline cores in inductors is mainly based on their excellent magnetic performance and wide applicability. This material is widely used in various types of inductors due to its high permeability, low loss, high saturation magnetic induction strength, and good temperature stability and frequency characteristics.
Amorphous nanocrystalline cores have high permeability and low coercivity, which makes them excellent in
common mode choke. For example, in EMC (Electromagnetic Compatibility) filters and common mode choke, amorphous nanocrystalline cores can effectively suppress common mode noise and improve inductor performance. In addition, amorphous nanocrystalline cores are also suitable for miniaturized designs of boost inductors due to their low loss and high saturation flux density characteristics.
Amorphous nanocrystalline cores also excel in high frequency applications. Their high permeability and wide frequency characteristics make them ideal for use in high-frequency applications, such as photovoltaic inverters, new energy vehicles and smart grids. These application scenarios require high frequency response of inductors, and amorphous nanocrystalline cores are able to meet these demands and offer good cost performance in high current and high power usage scenarios.
In addition, amorphous nanocrystalline cores are used in other types of inductors such as energy storage inductors, reactors, magnetic amplifiers and spike suppressors. The performance requirements for inductors in these applications vary, but amorphous nanocrystalline cores provide a reliable solution due to their excellent magnetic properties and stability.
To summarize, amorphous nanocrystalline cores are widely used in
inductors, and their excellent magnetic properties and stable physical characteristics make them widely used in common mode choke, high frequency inductors, and a variety of other inductive devices. By choosing the right amorphous nanocrystalline core material, the overall performance and reliability of the inductor can be significantly improved.
