Complete Guide to Induction Coil Design

5 Basics of Induction Heating Coil Design

Induction coil design can have a major impact on part quality, process efficiency, and manufacturing costs. How do you know if your coil design is best for your part and process? Here are some induction coil basics and five tips to optimize your design.

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How Induction Heating Coils Work

The induction coil determines how effectively and efficiently a workpiece is heated. Induction coils are water-cooled conductors made of copper tubing that is readily formed into the shape of the coil for the induction heating process. Induction heating coils do not themselves get hot as water flows through them.

Work coils range in complexity from a simple helical- or solenoid-wound coil (consisting of a number of turns of copper tube wound around a mandrel) to a coil that is precision machined from solid copper and brazed.

Coils transfer energy from the power supply to the workpiece by generating an alternating electromagnetic field due to the alternating current flowing in them. The coil’s alternating electromagnetic field (EMF) generates an induced current (eddy current) in the workpiece, which generates heat due to I Squared R losses (core losses).

The current in the workpiece is proportional to the coil’s EMF strength. This transfer of energy is known as the transformer effect or eddy current effect.

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Designs & Frequency Selections

Induction coil design has a major impact on process efficiency and final part quality, and the best coil design for your product largely depends on your application. Certain coil designs tend to work best with specific applications, and a less than optimal coil-application pairing can result in slow or irregular heating, higher defect rates, and lower quality products.

Designing an induction coil for your application

Start with understanding where the heat needs to be generated in the part to perform the process, and then design the coil to achieve the heating effect. Similarly, frequency selection will depend on the induction heating application you’ll be using for your part.

Before designing your induction coil, consider these three factors along with your induction application:

1. Part motion relative to coil - Several applications rely on part movement with the help of conveyors, turntables, or robots. A properly designed induction coil incorporates these individual handling requirements without the loss of heating efficiency.

2. Frequency- Higher frequencies are used for applications like brazing, soldering, annealing or heat treating, where surface heating is desired. Lower frequencies are preferred for applications requiring through-heating of the parts to the core like forging and die heating.

3. Power-density requirements- Higher power densities are required for short cycle heating applications requiring high temperatures. Higher power densities may also be required to keep the hot zone confined to a small area, reducing the heat affected area.

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Calculate Coupling Distance

Coupling is the transfer of energy that occurs in the space between the heating portion of the coil and the workpiece. So, coupling distance is how big that space needs to be to balance efficiency and manufacturing requirements.

Generally, distance increases with the diameter of the part, typical values being 0.75, 1.25, and 1.75 inches (19, 32 and 44 mm) or billet-stock diameters of approximately 1.5, 4 and 6 inches (38, 102, and 152 mm), respectively.

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Improve Heating Uniformity via Coil Design

Magnetic flux tends to concentrate toward the center of the length of a solenoid work coil. This means the heating rate produced in this area is generally greater than that produced toward the ends. Further, if the part being heated is long, conduction and radiation remove heat from
the ends at a greater rate. The coil can be modified to provide better heating uniformity along the part length. The technique of adjusting the coil turns, spacing, or coupling with the workpiece to achieve a uniform heating pattern is sometimes known as “characterizing” the coil.

1. Coil characterization
2. Six other common ways to improve heating uniformity
3. Heating two separate areas on a part
4. Heating tapered parts
5. Heating a part with secondary fabrications
6. Heating a variety of different parts with one coil

6 ways to improve uniformity of heating...

Solenoid Coil Designs & Calculations

The type and design of the induction coil determines how effectively and efficiently a workpiece is heated. Work coils range in complexity from a simple helical- or solenoid-wound coil (consisting of a number of turns of copper tube wound around a mandrel) to a coil that is precision-machined from solid copper and brazed.

The helical solenoid coil is the most ubiquitous induction coil design. It provides a wide range of heating behaviors since the part or heating area is located within the coil, in the area of greatest magnetic flux. Flux lines in a solenoid coil are concentrated inside the coil, providing the maximum heating rate at that location.

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sankafola said:

the LG motor have 36 coil and 48 poles

Check the counts. 36 coils will probably make three phases, each of 12 coils in series. The magnetic rotor will need to have 12 N-S magnets that repeat every three coils. That makes 24 magnetic poles, not 48. The 24 pole rotor could be a ring of 12 flat magnets stuck on a magnetic backing plate. Hold a magnetic wire near the rotor to feel and identify the magnetic poles.

Each coil is wound on a stator pole. Follow and visualise the magnetic field lines from a N pole on the PM rotor, across the gap into the stator core, then through the laminated core surrounded by a winding, probably splitting in two before returning back across the gap into the adjacent S poles on the PM rotor.

Each time the rotor moves by one magnetic pole, the field reverses through each coil.
Each time the rotor moves by one N and then one S pole, it produces one cycle of AC voltage.

I expect every third coil on the LG motor is wound in series to produce one phase. All those poles in series produce the output voltage in phase. Three phase requires the number of coils be a multiple of three. Every third coil should be opposite a N pole at the same time.

7 coils will not work efficiently with 24, 36 or 48 poles because 7 is not a factor of 12 and the poles need to line up. Notice that as the PM rotor moves through each magnetic cycle, it sequentially passes three evenly spaced windings, to generate the three phase voltages separated by 120°.

The LG direct drive motor looks like the F&P smartdrive motor developed in NZ.Check the counts. 36 coils will probably make three phases, each of 12 coils in series. The magnetic rotor will need to have 12 N-S magnets that repeat every three coils. That makes 24 magnetic poles, not 48. The 24 pole rotor could be a ring of 12 flat magnets stuck on a magnetic backing plate. Hold a magnetic wire near the rotor to feel and identify the magnetic poles.Each coil is wound on a stator pole. Follow and visualise the magnetic field lines from a N pole on the PM rotor, across the gap into the stator core, then through the laminated core surrounded by a winding, probably splitting in two before returning back across the gap into the adjacent S poles on the PM rotor.Each time the rotor moves by one magnetic pole, the field reverses through each coil.Each time the rotor moves by one N and then one S pole, it produces one cycle of AC voltage.I expect every third coil on the LG motor is wound in series to produce one phase. All those poles in series produce the output voltage in phase. Three phase requires the number of coils be a multiple of three. Every third coil should be opposite a N pole at the same time.7 coils will not work efficiently with 24, 36 or 48 poles because 7 is not a factor of 12 and the poles need to line up. Notice that as the PM rotor moves through each magnetic cycle, it sequentially passes three evenly spaced windings, to generate the three phase voltages separated by 120°.

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