AC Motors
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Basic Parts and Principles
Electric motors convert electrical energy into mechanical motion by using magnetic forces to accelerate objects. Electricity comes in two flavors: AC and DC. Therefore, electric motors need to be able to utilize at least one of these in order to operate. As a general rule, AC and DC motors are constructed using slightly different parts because of the different behavior of the types of electricity. Lets first look at the parts in a generic AC motor and then discuss the role they play in making motion.
AC motors consist mainly of a stator and a rotor. The stator is fixed inside the motor. Stators are almost always made using tightly wound wire in order to yield a high magnetic flux density. The second part is the rotor, which rotates to provide movement to whatever application is desired. The rotor also uses wound wire, through which current flows. In order to get this current to the rotor without tangling wires around the rotor, metal slip rings are used to complete the circuit.
Magnetic flux is created when current passes through the wires. Since the motor uses alternating current, the magnetic field will alternate polarity. Both the stator and rotor produce magnetic fields. The interaction between magnetic fields says that opposite poles attract while like poles repel. Electric motors use this behavior to produce rotation. When the poles of the stator and rotor are the same, the force will push the two apart. Similarly, the stator and rotor will be pulled together. Motors use both of these simultaneously to impart motion to the rotor, to which the output shaft is attached.
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Synchronous AC Motors
Synchronous motors are termed synchronous because they inherently run at a constant velocity which is synchronized with the frequency of the AC power supply. These motors contain two basic components: A rotor - the components that rotate, and a stator - the outside shell of the motor. The rotor can be made from either a permanent magnet or winding powered by a DC power source. When powered, this winding operates as a permanent magnet. The stator holds the armature winding which creates a rotating magnetic field inside the motor. The armature winding can be either either single or multi-phase. Similarly, the rotor has 2 poles in the simplest case, but can have many more depending on the application. The rotational velocity of a synchronous motor is a function of the number of pairs of poles and is always a <ref>http://www.electricmotors.machinedesign.com/guiEdits/Content/bdeee2/bdeee2_1-4.aspx</ref> <ref>http://www.allaboutcircuits.com/vol_2/chpt_13/2.html</ref> <ref>http://www.acsynchronousmotors.com/</ref>
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