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electric_motors [2019/01/10 21:40] paul [Brushed DC Motors] |
electric_motors [2019/03/31 14:49] (current) |
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| ====== Electric Motors ====== | ====== Electric Motors ====== | ||
| - | A an electric motor converts mechanical energy into rotational mechanical movement. | + | A an electric motor converts mechanical energy into rotational mechanical movement. |
| ===== Brushed DC Motors ===== | ===== Brushed DC Motors ===== | ||
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| Conventional brushed motors used a coil wound around an iron core rotor with leads going to a commutator. External permanent magnets are magnetized in opposite directions and provide a fixed magnetic field. | Conventional brushed motors used a coil wound around an iron core rotor with leads going to a commutator. External permanent magnets are magnetized in opposite directions and provide a fixed magnetic field. | ||
| - | Maxon makes fancy core-less brushed DC motors that have a thin cylindrical winding that sleeves over a permanent magnet. | + | Maxon makes fancy core-less brushed DC motors that have a thin cylindrical winding that sleeves over a permanent magnet. |
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| + | ==== Lorentz Force ==== | ||
| {{ :: | {{ :: | ||
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| The basics of electric motor operation relies on the **Lorentz force** which states that a current conductor in an external magnetic field experiences a force. | The basics of electric motor operation relies on the **Lorentz force** which states that a current conductor in an external magnetic field experiences a force. | ||
| - | Formally, a particle of charge $q$ with a velocity $v$ in an electric field $\textbf{E}$ and a magnetic field $\textbf{B}$ experiences a force $\textbf{F}$: | + | Formally, a particle of charge $q$ with a velocity $\textbf{v}$ in an electric field $\textbf{E}$ and a magnetic field $\textbf{B}$ experiences a force $\textbf{F}$: |
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| + | $\textbf{F} = q\textbf{E}+q\textbf{v}\times\textbf{B}$ | ||
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| + | ==== Permanent Magnet | ||
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| + | Permanent magnet power density has been improved over the years. Current fancy magnet is the Neodymium iron boron. | ||
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| + | {{ : | ||
| + | ==== Brushed Commutation ==== | ||
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| + | A DC motor has multiple winding that need to be commutated (switched) mechanically. Two types of brushing options, graphite and precious metals. There' | ||
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| + | ===== Brushless DC Motors ====== | ||
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| + | Brushless motors are electrically commutated motors. They have a winding on the inside with a permanent magnetic core. | ||
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| + | {{ : | ||
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| - | $\textbf{F} = q\textbf{E}+q\textbf{v}\mult\textbf{B}$ | ||