Subject : Electrical Machines II (AC Machines)
Cascade speed control of induction motor
Cascade speed control of induction motor:
- The power drawn from the rotor terminals could be spent more usefully. Apart from using the heat generated in meaning full ways, the slip ring output could be connected to another induction machine. The stator of the second machine would carry slip frequency currents of the first machine which would generate some useful mechanical power. A still better option would be to mechanically couple the shafts of the two machines together. This sort of a connection is called cascade connection and it gives some measure of speed control as shown below.
- Let the frequency of supply given to the first machine be f_{1} , its number poles be p_{1}, and its slip of operation be s_{1} . Let f_{2}, p_{2} and s_{2} be the corresponding quantities for the second machine. The frequency of currents flowing in the rotor of the first machine and hence in the stator of the second machine is s_{1}f_{1}. Therefore f_{2} = s_{1}f_{1}. Since the machines are coupled at the shaft, the speed of the rotor is common for both. Hence, if n is the speed of the rotor in radians,
- Note that while giving the rotor output of the first machine to the stator of the second, the resultant stator mmf of the second machine may set up an air-gap flux which rotates in the same direction as that of the rotor, or opposes it which results in values for speed as
- The latter expression is for the case where the second machine is connected in opposite phase sequence to the first. The cascade connected system can therefore run at two possible speeds.
Fig: Generalized rotor control
- Speed control through rotor terminals can be considered in a much more general way. Consider the induction machine equivalent circuit of fig., where the rotor circuit has been terminated with a voltage source E_{r}. If the rotor terminals are shorted, it behaves like a normal induction machine. This is equivalent to saying that across the rotor terminals a voltage source of zero magnitude is connected. Different situations could then be considered if this voltage source E_{r} had a non-zero magnitude. Let the power consumed by that source be P_{r}. Then considering the rotor side circuit power dissipation per phase
- Clearly now, the value of s can be changed by the value of P_{r}. For P_{r} = 0, the machine is like a normal machine with a short circuited rotor. As P_{r} becomes positive, for all other circuit conditions remaining constant, s increases or in the other words, speed reduces. As P_{r} becomes negative, the right hand side of the equation and hence the slip decreases.
- The physical interpretation is that we now have an active source connected on the rotor side which is able to supply part of the rotor copper losses. When P_{r} = −I′_{2}^{2} R_{2} the entire copper loss is supplied by the external source. The RHS and hence the slip is zero. This corresponds to operation at synchronous speed.
- In general the circuitry connected to the rotor may not be a simple resistor or a machine but a power electronic circuit which can process this power requirement. This circuit may drive a machine or recover power back to the mains. Such circuits are called static Kramer drives.