Chapter 09: Choosing the Correct Wire and Winding Method

Everything you need to know about professional magnetic component design.


Beginner → Advanced

15 Chapters

100+ Illustrations

Engineering Design Examples

Interactive Calculators

Free


Engineering illustration comparing round wire, parallel conductors, Litz wire, and foil windings used in magnetic component design.
Different conductor types affect resistance, efficiency, thermal performance, manufacturability, and high-frequency losses in magnetic components.


Introduction

Selecting the proper conductor is just as important as selecting the magnetic core itself.

Even the best magnetic design can fail if the winding method is not chosen correctly.

The wire affects:

  • DC resistance (DCR)
  • Copper losses
  • Temperature rise
  • Efficiency
  • Manufacturability
  • Cost

As switching frequencies increase, conductor selection becomes even more critical because additional AC losses begin to appear.

In this chapter, we will explore the most common conductor types used in inductors and transformers and learn how to select the best winding method for a given application.


The Purpose of the Winding

The winding creates the magnetic field that stores and transfers energy.

When current flows through the wire, a magnetic field is produced.

The magnetic field strength is proportional to:

H=NIlH=\frac{NI}{l}

Where:

  • H = Magnetic Field Strength
  • N = Number of Turns
  • I = Current
  • l = Magnetic Path Length

Increasing either current or turns increases the magnetic field.

Because the winding carries current continuously, conductor selection has a major impact on efficiency and thermal performance.


DC Resistance (DCR)

Every conductor has resistance.

The resistance of a wire is:

R=ρlAR=\rho\frac{l}{A}

Where:

  • R = Resistance
  • ρ = Resistivity
  • l = Length
  • A = Cross-sectional Area

Resistance increases with:

  • Longer wire length
  • Smaller conductor area

Resistance decreases with:

  • Larger wire diameter
  • Parallel conductors

Lower resistance reduces power loss and improves efficiency.


Copper Losses

Current flowing through the winding produces heat.

Copper loss is:

PCu=I2RP_{Cu}=I^2R

Notice that current is squared.

Doubling current results in four times the copper loss.

This is one reason high-current inductors often use very large conductors or multiple parallel strands.


Round Magnet Wire

Round enamel-coated copper wire is the most common conductor used in magnetic components.

Advantages

  • Lowest cost
  • Easy to obtain
  • Easy to wind
  • Available in many sizes

Disadvantages

  • Limited packing efficiency
  • Higher AC losses at high frequency

Typical Applications

  • Power inductors
  • Flyback transformers
  • General-purpose magnetics

For most switching power supplies below a few hundred kilohertz, round wire remains an excellent choice.


Parallel Conductors

Instead of using one large wire, multiple smaller wires can be connected in parallel.

Advantages:

  • Lower resistance
  • Improved winding flexibility
  • Better window utilization

Example:

Three strands of AWG18 wire may fit more easily than a single conductor with equivalent copper area.

Parallel conductors are commonly used in:

  • High-current inductors
  • Power converters
  • Automotive electronics

Litz Wire

Litz wire consists of many individually insulated strands woven together in a specific pattern.

The purpose of Litz wire is to reduce AC resistance caused by:

  • Skin effect
  • Proximity effect

Advantages:

  • Lower high-frequency losses
  • Improved efficiency

Disadvantages:

  • Higher cost
  • More difficult termination
  • Larger overall conductor diameter

Typical Applications:

  • Wireless charging
  • High-frequency transformers
  • RF magnetics
  • Resonant converters

Understanding Skin Effect

As frequency increases, current tends to flow near the outer surface of a conductor.

This phenomenon is called skin effect.

The effective depth of current penetration is known as skin depth.

Skin depth is:

δ=2ρωμ\delta=\sqrt{\frac{2\rho}{\omega\mu}}

Where:

  • δ = Skin Depth
  • ρ = Resistivity
  • ω = Angular Frequency
  • μ = Permeability

As frequency increases:

  • Skin depth decreases
  • Effective conductor area decreases
  • AC resistance increases

This is one of the primary reasons Litz wire is used in high-frequency applications.


Proximity Effect

Proximity effect occurs when magnetic fields from nearby conductors force current to crowd into specific regions of the conductor.

This can significantly increase AC resistance.

Proximity effect becomes important in:

  • Multi-layer windings
  • Transformers
  • High-current inductors

Often proximity effect causes more loss than skin effect.

Good winding layout can significantly reduce these losses.


Foil Windings

Copper foil can be used instead of round wire.

Advantages:

  • Very low resistance
  • Excellent current handling
  • Reduced proximity losses

Disadvantages:

  • More difficult manufacturing
  • Additional insulation requirements

Typical Applications:

  • High-current power inductors
  • High-power transformers
  • Industrial converters

Fill Factor

The winding window can never be filled completely with copper.

Insulation, bobbins, and manufacturing tolerances all consume space.

Fill factor is:

Fill Factor=Copper AreaWindow AreaFill\ Factor=\frac{Copper\ Area}{Window\ Area}

Typical practical fill factors:

Construction TypeTypical Fill Factor
Hand Wound25–35%
Machine Wound35–50%
Optimized Designs50–70%

Attempting to exceed realistic fill factors usually results in manufacturing problems.


Insulation Systems

Wire insulation serves several important purposes:

  • Prevents shorts between turns
  • Meets safety requirements
  • Improves reliability

Common insulation classes include:

ClassMaximum Temperature
A105°C
B130°C
F155°C
H180°C

Higher temperature ratings generally increase cost but improve thermal margin.


Winding Layout Considerations

Good winding layout helps improve:

  • Efficiency
  • EMI performance
  • Thermal behavior

Designers should consider:

Layer Count

More layers increase winding resistance and AC losses.

Turn Spacing

Spacing affects insulation and EMI.

Interleaving

Transformer windings are often interleaved to reduce leakage inductance.

Lead Routing

Proper lead placement improves manufacturability and reduces unwanted coupling.


SolidMag Engineering Note

Bigger Wire Is Not Always Better

Many new designers assume that larger wire is always the best choice.

In reality, wire size must be balanced against:

  • Available window area
  • Number of turns required
  • Fill factor limitations
  • Manufacturing constraints
  • High-frequency effects

An oversized conductor may actually prevent the winding from fitting inside the core window.

The best design is usually the conductor that minimizes total losses while remaining manufacturable.


What You’ve Learned

In this chapter you learned:

  • How wire size affects resistance
  • Why copper losses occur
  • The differences between round wire, parallel conductors, Litz wire, and foil windings
  • How skin effect impacts high-frequency designs
  • Why proximity effect increases losses
  • What fill factor means
  • How insulation systems affect reliability
  • How winding layout influences performance

Continue Reading

Chapter 10: Understanding Core Losses

Now that we understand how winding choices affect copper losses, the next step is learning how magnetic materials themselves dissipate energy and how core losses influence efficiency, temperature rise, and overall magnetic component performance.


Ready to Generate Your Custom Magnetic Design?

Upload your electrical requirements and receive:

  • 3D CAD model
  • Manufacturing drawings
  • BOM
  • Build-ready geometry
Start Design Analysis

Name
Would you like to subscribe to our newsletter?