Number of Turns vs. Wire Gauge (BLDC Motor)

AI Thread Summary
In designing a brushless DC motor, the strength of the magnetic field generated by coils depends significantly on the number of turns and the thickness of the wire used. Thinner wire allows for more turns, which increases the magnetic field intensity, while thicker wire has lower resistance and can handle higher currents. However, using thicker wire results in fewer turns, which may reduce the magnetic field strength. The key factor is that for the same current, more turns with thinner wire yield a more powerful magnetic field. Thermal management is crucial, as the heat generated from I^2R losses limits the wire's performance. The choice of wire thickness must also consider the current capacity of the BLDC controller. Overall, the design involves trade-offs between wire thickness, number of turns, and thermal dissipation capabilities.
George-M
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For the same mass of copper wire, would more turns or greater thickness create a stronger magnetic field from a coil?
Summary: For the same mass of copper wire, would more turns or greater thickness create a stronger magnetic field from a coil?

So I am attempting to make a brush less DC motor, and I am wondering whether the coils would create a greater magnetic force if there are more turns or if the wire is thicker. If the copper wire is thicker, there will have to be fewer turns. If the copper wire is thinner, there will be more turns. I do believe that wire of a greater thickness has less resistance. Imagine I have two coils of copper wire with the same mass of identical copper wire; one of greater thickness but fewer turns, and the other of less thickness but more turns. My question is: which would create the strongest magnetic force? (Extended distance/ range of magnetic field is not necessary, because the rotor will be extremely close to the coils anyway). Please pardon my lack of technical terminology.
 
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the magnetic field has nothing to do with the size of the wire but everything to do with the number of turns. More turns, greater field intensity.
 
Thicker wire permits higher currents. So for the same current thinner wire and more turns allows a more powerful field.

The limit is thermal; how much heat can you dissipate from the coils at a reasonable temperature. The thermal load is produced by ##I^2R## losses. Thinner wires have higher R per foot and more feet if you increase the number of turns.

A BLDC motor is designed to mate with a BLDC controller. You have to consider how much current the controller can provide.

As in most designs, everything interacts with everything else and there are many tradeoffs.

Reading this may help you;
https://www.edn.com/design/sensors/4406682/Brushless-DC-Motors---Part-I--Construction-and-Operating-Principles
 
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Thank you both ever so much. I am going to use thinner wire because, I have a design that should keep temperatures low as is.
 

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