Working of Asynchronous Motor / induction Motor Fully Explained with 3D Animation..
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#asynchronousmotor #asynchronousmotors
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#3danimation #3delectronics #3delectrical #diyelectrical
#electrical #electrician #electricians #electricalwork #electricalworks #electricalstudent #electricalstudents #electricalengineering #electricalengineer #electricaltips #electricalwiring
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LearningTranscript
00:00An asynchronous motor, also known as an induction motor,
00:03operates based on electromagnetic induction. Today I will explain you.
00:08The principle of electric motors, which I never understood until I graduated,
00:13turned out to be so simple. This is a metal bar that can be rotated.
00:17If a magnet is placed close to the bar, the bar will rotate in the direction of the magnet,
00:22and when the magnet moves, the bar will move with it.
00:26Now we replace the metal rod with an iron disc and replace the bar magnet with a U-shaped magnet.
00:33When we move the magnet, the disc will follow. If we keep the magnet circling the disc,
00:38the disc will follow, and the disc will also rotate.
00:42You might think that it's the magnet's attraction that causes the disc to follow,
00:46but the truth is much more complicated than that.
00:49Let's replace the ferrous disc with an aluminum disc, which is non-ferromagnetic,
00:54and when we move the magnet, the disc rotates just the same.
00:59So why is that?
01:01The magnetic field of the U-shaped magnet flows from the N pole to the S pole,
01:06and when the magnet moves due to the cutting of the magnetic inductance,
01:10according to the principle of electromagnetic induction,
01:13eddy currents will be generated on the iron disc.
01:16Through the right-hand rule can easily know that the direction of the induced current points to
01:21the center of the disc. In which direction does the disc rotate?
01:25It is necessary to use the left-hand rule. The index finger points to the direction of
01:30the magnetic field, the middle finger points to the direction of the current.
01:34The direction of the thumb will produce a force, it is this force to make the disc rotate.
01:40It should be noted that the speed of the magnet is not the same as the speed of the disc.
01:45If the same electromagnetic induction will not occur, the disc will not rotate itself.
01:50Next, we continue to improve the device by replacing the disc with an iron cylinder
01:55and the U-shaped magnet with two bar magnets.
01:58When we rotate the magnets, the cylinder will rotate with them.
02:01And let's look at the force on the cylinder.
02:04The magnetic field flows from the N pole to the S pole,
02:07and since the magnet is moving downward, the relative cylinder is moving upward.
02:12By the right-hand rule, it follows that the current flows in this direction.
02:17Again, by the left-hand rule, you can tell that the force on the cylinder is facing down.
02:22The same principle applies to the other side, yielding that the force is directed upwards,
02:28and eventually the cylinder will be able to rotate along with the magnet.
02:33So, can you make a cylinder turn without turning the magnet?
02:37Let's start with an interesting little experiment.
02:40In this experiment, when the direction of the current is constantly changing,
02:44the direction of the magnetic field is also constantly changing.
02:48According to this principle, we can put several coils around the cylinder,
02:52and when we keep changing the direction of the current,
02:55the magnetic field of the coils will keep changing, which forms a rotating magnetic field.
03:02As before, the force generated by the rotating magnetic field
03:06will be able to push the cylinder to rotate,
03:09which is actually the underlying principle of the asynchronous motor.
03:13Let's take a look at how a three-phase asynchronous motor works in reality.
03:18First of all, let's understand what three-phase alternating current is.
03:22When rotating the magnet around the coil,
03:24the change of the magnetic field will make the coil produce alternating current.
03:29The waveform of the current is like this, which is unidirectional alternating current.
03:34Three coils will be placed at an interval of 120 degrees and then rotate the magnet.
03:41The waveform of the current is like this, which is three-phase alternating current.
03:46The three-phase asynchronous motor is connected to three-phase alternating current.
03:51The motor is mainly divided into rotor and stator,
03:54and the rotor is mainly composed of winding coils.
03:57First, the coil enters from the A port,
04:01then comes out in the opposite direction from the A port directly opposite,
04:05then enters from the B port at 120 degree intervals,
04:09then comes out in the opposite direction from the B port,
04:12and then the same operation is done to connect the coil into the C port at 120 degrees.
04:19And finally, the wires coming back in the opposite direction are connected together.
04:23The other three wires are connected to a three-way alternating current,
04:27and according to Ampere's law, when the current passes through the A coil,
04:31it produces a magnetic field, the direction of which is clockwise.
04:35The coil opposite the other end of the A coil also generates a magnetic field,
04:40which is counterclockwise.
04:42B and C do the same, and you can visualize this change better with this diagram.
04:47When the green coil is energized with alternating current,
04:51the direction of the magnetic field in the green coil changes in the opposite direction
04:56as the current continues to change, regardless of whether the coil is red or blue.
05:01When all three coils are energized, this creates two separate magnetic fields.
05:08As the alternating current continues to change,
05:11the magnetic field changes with it, creating a rotating magnetic field.
05:16With a rotating magnetic field, we can build an electric motor.
05:20This is a simplified squirrel cage motor rotor.
05:23By placing the rotor directly into the stator,
05:25the rotor is able to turn quickly under the action of the rotating magnetic field.
05:30This is just a simple motor made up of windings.
05:33There are more complex windings, but ultimately,
05:35they are all designed to create a rotating magnetic field.
05:39Asynchronous motors are used in a large number of applications
05:43in various industrial and agricultural production
05:46due to their simplicity, reliability, and ease of installation.
05:51Hope you understand now how asynchronous motor works.
05:54Thanks for watching like comment share and subscribe