Induction motor

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Three-phase induction motors
Three-phase induction motors

An induction motor (IM) is a type of AC motor where power is supplied to the rotating device by means of electromagnetic induction. An electric motor converts electrical power to mechanical power in its rotor (rotating part). There are several ways to supply power to the rotor. In a DC motor this power is supplied to the armature directly from a DC source. But in an AC motor this power is induced in the rotating device. An induction motor can be called a rotating transformer because the stator (stationary part) is essentially the primary side of the transformer and the rotor (rotating part) is the secondary side. Induction motors are widely used, especially polyphase induction motors, which are frequently used in industrial drives.

Induction motors are now the preferred choice for industrial motors due to their rugged construction, lack of brushes (see DC Motors) and — thanks to modern power electronics — the ability to control the speed of the motor.

Contents

[edit] History

The induction motor with a wrapped rotor was invented by Nikola Tesla in 1888 in the United States. In his scientific work, Tesla laid the foundations for understanding the way the motor operates. The induction motor with a cage was invented by Mikhail Dolivo-Dobrovolsky about a year later in Europe. Technological development in the field has improved to where a 100 hp (73.6 kW) engine from 1976 takes the same volume as a 7.5 hp (5.5 kW) engine did in 1897. Currently, the most common induction motor, is the cage rotor motor.

[edit] Principle of operation and comparison to synchronous motors

A 3-phase power supply provides a rotating magnetic field in an induction motor
A 3-phase power supply provides a rotating magnetic field in an induction motor

The basic difference between an induction motor and a synchronous AC motor is that in the latter a current is supplied onto the rotor. This then creates a magnetic field which, through magnetic interaction, links to the rotating magnetic field in the stator which in turn causes the rotor to turn. It is called synchronous because at steady state the speed of the rotor is the same as the speed of the rotating magnetic field in the stator.

The induction motor does not have any supply onto the rotor; instead, a secondary current is induced onto the rotor. Conductors in the rotor induce a current as the rotating magnetic field created by the stator windings sweep past them much in the same way as in a transformer. This current in the rotor conductors will therefore induce a magnetic field which will interact with the rotating magnetic field in the stator and the rotor will turn. For this to happen, the speed of the rotor and the speed of the rotating magnetic field in the stator must be different, or else the magnetic field will not be moving relative to the rotor conductors and no current will be induced. If this happens, the rotor slows slightly until a current is re-induced and then the rotor continues as before. This difference between the speed of the rotor and speed of the rotating magnetic field in the stator is called slip. It is unitless and is the ratio between the relative speed of the magnetic field as seen by the rotor to the speed of the rotating field. Due to this an induction motor is sometimes referred to as an asynchronous machine.

TYPES:

  1. Based on type of phase supply
    1. three phase induction motor (self starting in nature)
    2. single phase induction motor (not self starting)
  2. Other
    1. Squirrel cage induction motor
    2. Slip ring induction motor

[edit] Formulas

The relationship between the supply frequency, f, the number of pole pairs, p, and the synchronous speed, n, is given by f = p*n.

From this relationship:

Speed of rotating field (n) = f/P (revs.s-1)

Speed of rotor = n(1-S) (rev.s-1)

where S is the slip.

Slip is calculated using:

% slip = (n - r) / n * 100

where r is the rotor speed

In contrast, a synchronous motor always runs at either a constant speed N=(120f)/P or zero.

N = speed of synchronous motor

P = number of poles

f = frequency

[edit] Construction

The stator consists of wound 'poles' that carry the supply current that induces a magnetic field in the conductor. The number of 'poles' can vary between motor types but the poles are always in pairs (i.e. 2,4,6 etc). There are two types of rotor:

  1. Squirrel-cage rotor
  2. Slip ring rotor

The most common rotor is a squirrel-cage rotor. It is made up of bars of either solid copper (most common) or aluminum that span the length of the rotor, and are connected through a ring at each end. The rotor bars in squirrel-cage induction motors are not straight, but have some skew to reduce noise and harmonics.

The motor's phase type is one of two types:

  1. Single-phase induction motor
  2. 3-phase induction motor

[edit] Speed control

The rotational speed of the rotor is controlled by the number of pole pairs (number of windings in the stator) and by the frequency of the supply voltage. Before the development of cheap power electronics, it was difficult to vary the frequency to the motor and therefore the uses for the induction motor were limited.

There are various techniques to produce a desired speed. The most commonly used technique is PWM (Pulse Width Modulation), in which a DC signal is switched on and off very rapidly, producing a sequence of electrical pulses to the inductor windings. The duty cycle of the pulses, also known as the mark-space ratio, determines the average power input to the motor. For example, a 100 V DC signal that is cut into on- and off- pulses of equal width, has an average voltage of 50 V. If the on- pulses are a third of the duration of the off pulses, the average would be 25 V. The frequency of the pulses determines the motor speed.

The general term for a power electronic device that controls the speed as well as other parameters is called an 'inverter'. A typical unit will take the mains AC supply, rectify and smooth it into a "link" DC voltage, and, by using the method described above, converts it into the desired AC waveform.

Because the induction motor has no brushes and is easy to control, many older DC motors are being replaced with induction motors and accompanying inverters in industrial applications.

[edit] Starting of induction motor

In a three phase induction motor, the induced emf in the rotor circuit depends on the slip of the induction motor and the magnitude of the rotor current depends upon this induced emf (electromotive force). When the motor is started, the slip is equal to 1 as the rotor speed is zero, so the induced emf in the rotor is large. As a result, a very high current flows through the rotor. This is similar to a transformer with the secondary coil short circuited, which causes the primary coil to draw a high current from the mains. Similarly, when an induction motor starts, a very high current is drawn by the stator, on the order of 5 to 9 times the full load current. This high current can damage the motor windings and because it causes heavy line voltage drop, other appliances connected to the same line may be affected by the voltage fluctuation. To avoid such effects, the starting current should be limited. A soft start starter is a device which limits the starting current by providing reduced voltage to the motor. Once the rotor speed increases, the full rated voltage is given to it. arul

[edit] Types of starters

  1. Direct on line starter
  2. Autotransformer starter
  3. Star Delta starter
  4. Stator Resistance starter

[edit] See also

v  d  e
Electric motors
Broad Motor Categories
Conventional Electric Motors
InductionBrushed DCBrushless DCStepperLinearUnipolarReluctance
Novel Electric Motors
Motor Controllers
See also

[edit] External links