CDH113NP-270LC Datasheet/PDFFixed Inductors: CDH113NP-270LC Application Field and Working Principle
Fixed inductors are a type of electronic component composed of an energy storing coil. The number of turns and size of the coil determines the inductance of the inductor. CDH113NP-270LC is a common type of fixed inductor. This article discusses their application field and working principle.
Applications
CDH113NP-270LC fixed inductors are used in a variety of applications, including power circuits, switching circuits, and signal processing circuits. In power circuits, CDH113NP-270LC fixed inductors can be used to control the voltage and current in the circuit. In switching circuits, they can be used as filters to reduce electromagnetic interference. In signal processing circuits, they can be used to form an inductor-capacitor (LC) filter to block unwanted frequencies.
Working Principle
CDH113NP-270LC fixed inductors work by storing electrical energy within a conductive coil. This process is known as inductance. In CDH113NP-270LC fixed inductors, the number of turns and size of the coil determine the inductance of the inductor. When current flows through the inductor, a magnetic field is generated, which induces a voltage across the coil. This voltage opposes the current and limits the rate of change of the current. This property is known as reactance.
The CDH113NP-270LC fixed inductors also have the ability to store energy in its magnetic field. This energy, which is known as magnetic flux, is released when the current through the inductor is stopped. This property is known as self-inductance and can be described mathematically with the equation L = inductance.
Conclusion
CDH113NP-270LC fixed inductors are versatile components used in various circuits. They work by storing electrical energy within a conductive coil. This process is known as inductance and is found in all types of inductors. The number of turns and size of the coil determine the inductance of the inductor. CDH113NP-270LC fixed inductors can also store energy in its magnetic field, which is known as magnetic flux and is released when the current through the inductor is stopped.