Discover the PCIM Europe

ELECTRONIC COMPONENTS Understanding the role of inductors in power electronics

Updated on 21.04.2023 From Luke James |

Related Vendors

One of the most obscure of power electronics components is the inductor: the coil-like structures that you find in most circuits. It’s down to these and their properties that transformers and other power electronics circuits work.

What are inductors, how are they constructed, and what are the different types?
What are inductors, how are they constructed, and what are the different types?
(Source: gemeinfrei / Pixabay)

Inductors are typically used as energy storage devices in switched-mode power devices to produce DC current. The inductor, which stores energy, supplies energy to the circuit to maintain current flow during “off” switching periods, thus enabling topographies where output voltage exceeds input voltage.

Due to the way they work — by not only altering electric field but the magnetic field around it — many people struggle to understand them.

What is an inductor?

An inductor — also known as choke or coil — is arguably the simplest of all electronic components. It’s a passive two-terminal electrical component that stores energy in a magnetic field when electric current flows through it. Typically, an inductor will consist of an insulated wire that’s wound into a coil, much like a resistor. This design was settled on following extensive trial and error methods that considered methods like Hanna curves and area-product.

When the current flowing through the coil changes, the time-varying magnetic field induces voltage in the conductor with a polarity which opposes the change in current that created it. As such, inductors oppose any changes in current that pass through them.

The induced magnetic field also induces an electrical property known as inductance — the ratio of voltage to the rate of change of current. Inductance quantifies how much energy an inductor is capable of storing.

Inductor design and key components

The design of an inductor is governed by electrical, mechanical, and thermal requirements of a given application. In general, it involves:

  • Selecting the core material
  • Deciding a core shape and size
  • Selecting a winding wire

The core material is an enamel-coated magnetic wire typically made of copper which is then coated in layers of insulating polymer material. The winding can form many shapes, including circular, rectangular foil, and square cross-section. A magnetic wire is chosen to confine and guide the magnetic fields, and this is insulated to prevent problems like short circuits and breakdowns.

The inductor symbol

When designing an electronic circuit diagram, it is very important to use the proper electronic symbols, which indicate the exact location of the respective electronic component and explain how the circuit is interconnected. The standard schematic symbol of an inductor is shown in figure 1. In addition to the representation by electronic circuit symbols, there is also the possibility of clearly identifying electronic components by means of reference designators. An inductor is referred to with the letter "L".

Figure 1. Schematic symbol of an inductor.
Figure 1. Schematic symbol of an inductor.
(Source: Akilaa - Wikimedia Commons)

The different types of inductor

Different applications require different types of inductor. In almost all cases, you’ll find that an inductor in a system is formed around a core material — generally iron or iron compounds — to support the creation of a strong magnetic field.

Iron core inductors

Figure 2. An iron core inductor manufactured by Jantzen Audio for audio applications.
Figure 2. An iron core inductor manufactured by Jantzen Audio for audio applications.
(Source: Hifi Collective)

Iron is the classic and most recognizable magnetic material, making it the perfect choice for use in inductors. As above, iron in inductors takes the form of an iron core. They are typically used for low frequency line filtering due to their relatively large inductances. They are also used a lot in audio equipment. Inductors don’t always need to have an iron core, though.

Air core inductors

Figure 3. An air core inductor manufactured by Wurth Elektronik.
Figure 3. An air core inductor manufactured by Wurth Elektronik.
(Source: Farnell)

As the name suggests, air core inductors have no core — the core is open air. Since air has a low permeability, the inductance of air core inductors is very low. This means that the rate of current rise is relatively fast for an applied voltage, making them capable of handling high frequencies found in applications like RF circuits.

Ferrite core inductors

Figure 4. A ferrite core inductor manufactured by Wurth Elektronik.
Figure 4. A ferrite core inductor manufactured by Wurth Elektronik.
(Source: RS Components)

A ferrite is a ceramic material made by mixing and firing iron(III) oxide blended with small amounts of one or more additional metallic elements, such as nickel and zinc. When used in inductors, ferrite powder is mixed with an epoxy resin and molded to form a core around which a magnetic wire can be wound. Ferrite inductors are the most widely used type as it’s possible to finely control their permeability by tuning the ratio of ferrite to epoxy.

Practical applications of inductors

Inductors, due to the copper and iron materials needed to make them, tend to be expensive. This relegates the majority of their use cases to applications in areas where such an expense can be justified, such as telecoms equipment, radios, and power supplies. In power supplies, an inductor’s role is to prevent sudden changes in current used. Working alongside a capacitor, an inductor prevents sudden changes in the power supply’s output voltage and current. Overall, they’re very simple components that play a critical role in power electronics.

Subscribe to the newsletter now

Don't Miss out on Our Best Content

By clicking on „Subscribe to Newsletter“ I agree to the processing and use of my data according to the consent form (please expand for details) and accept the Terms of Use. For more information, please see our Privacy Policy.

Unfold for details of your consent