EN 
-
Products
- Application
- Company
-
Services
- Resources
- News
-
Contact Us
Introducing our Multilayer Inductors - HK100510NJ-T, MPL2012S2R2MHT, MPL2012S4R7MHT, SCDS8D43T-100M-N, and VHF100505H2N0ST. These advanced inductors are designed to provide high performance in a compact size. With excellent Q factors, high self-resonance frequencies, and a wide range of inductance values, our multilayer inductors are ideal for a variety of applications, including power supplies, filters, and RF circuits.
Multilayer inductors are typically made using ceramic materials, such as barium titanate, lead zirconate, and calcium titanate. Other materials, such as polypropylene and polystyrene, may be used in certain applications. The specific material used depends on factors such as the desired inductance value, performance requirements, and cost.
Multilayer inductors are commonly used in power supply circuits to filter out high-frequency noise and stabilize the output voltage. In power supply circuits, multilayer inductors act as smoothing filters, which help prevent unwanted fluctuations and ensure a stable output.
A multilayer inductor is a type of inductor that consists of multiple layers of a conductive material wound around a central core. When current passes through the inductor, a magnetic field is generated in the core, which results in energy storage. The inductance value and performance are affected by the number of layers and the geometrical arrangement of the conductive material.
The temperature range for multilayer inductors can vary depending on the specific material used, as well as the design of the inductor. Most multilayer inductors can operate within a temperature range of -55°C to +125°C.
The maximum current rating for multilayer inductors can vary depending on the specific inductor design and the application. Most multilayer inductors have a current rating ranging from a few milliamps to several amps.
Multilayer inductors are manufactured by placing multiple layers of conductive material, such as ceramic, onto a substrate. The layers are then patterned and connected by a conductor to form a spiral coil. A magnetic core may be added, and the inductor is then sealed and packaged for use.
