AC Induction Motors and Generators
In 1888, Nikola Tesla used two AC currents 90° out of phase to create a rotating magnetic field — the key innovation of his AC induction motor. An aluminium squirrel-cage rotor follows the rotating field via eddy current induction, with no physical electrical connection. Modern induction motors achieve 85–95% efficiency (compared with ~70% for DC motors) and today 80% of all industrial motors worldwide are induction motors. Australia has approximately 50 million in operation.
Practise this lesson
Four printable worksheets that build from the foundations up to exam-style questions — start at whatever level suits you.
An AC induction motor has a rotor made of metal bars shorted at both ends (a squirrel cage). There are no wires connecting the rotor to a power supply.
- How can the rotor turn if there is no electrical connection to it?
- Why does the rotor always turn slightly slower than the rotating magnetic field of the stator?
- What would happen if the rotor somehow spun at exactly the same speed as the stator field?
Warm-up — in an induction motor, the currents in the rotor bars are produced by:
Know — Induction Motor Structure
- Stator: three-phase windings create a rotating magnetic field
- Rotor: squirrel cage of conducting bars, no electrical connection
- Slip: the rotor always turns slower than the stator field speed
Understand — How Induction Works
- The rotating stator field induces currents in the rotor bars
- These induced currents create a rotor magnetic field
- The interaction between stator and rotor fields produces torque
Can Do — Analyse and Compare
- Explain why slip is necessary for torque production
- Compare induction motors and power station generators
- Calculate synchronous speed and percentage slip
Core Content
No brushes, no commutator — just induction
Suspend an aluminium cylinder freely on a bearing inside a ring of electromagnets. Connect the electromagnets to a three-phase AC supply — and the cylinder starts to rotate, seemingly by itself. Nothing is mechanically connected to it; no current is supplied directly to it. What you are watching is electromagnetic induction: the rotating magnetic field from the stator continuously changes the flux through the aluminium rotor, inducing eddy currents; those currents interact with the rotating field to produce torque, chasing the field around. This is the AC induction motor in its simplest form.
Stator: Stationary electromagnets arranged in three phases. When three-phase AC passes through these windings, it creates a rotating magnetic field that spins around the inside of the motor at synchronous speed.
Rotor (squirrel cage): A cylinder of conducting bars (usually aluminium or copper) connected at both ends by conducting rings. There are no brushes and no wires connecting the rotor to anything external.
How it works — four steps
- The rotating stator field sweeps past the rotor bars.
- By Faraday's Law, this changing flux induces currents in the rotor bars.
- By Lenz's Law, these induced currents create a magnetic field that opposes the relative motion between the rotor and the stator field.
- The rotor is pushed along in the same direction as the rotating field, producing torque.
When explaining induction motor operation: (1) rotating stator field, (2) induced currents in rotor (Faraday's Law), (3) torque production via interaction of fields. Then explain why slip is necessary.
Why slip is essential
If the rotor spun at exactly the same speed as the stator field (synchronous speed), there would be no relative motion, no changing flux, no induced currents, and therefore no torque. The rotor must turn slightly slower — this difference is called slip. Typical slip is 2–5% of synchronous speed.
$n_s = \dfrac{120f}{p}$
where $f$ = frequency (Hz), $p$ = number of poles, $n_s$ = synchronous speed (RPM)
$\% \text{ slip} = \dfrac{n_s - n_r}{n_s} \times 100$
where $n_r$ = actual rotor speed (RPM)
AC induction motor: stator (3-phase AC → rotating field) + squirrel-cage rotor (no brushes, no direct connection). Induction sequence: rotating field → changing flux → induced current (Faraday) → torque via Lenz's Law. Slip essential: $n_s = 120f/p$ (RPM); % slip $= (n_s-n_r)/n_s \times 100$.
Pause — copy the highlighted induction motor sequence and slip formulas into your book before moving on.
The rotor of an induction motor must turn slower than the stator's rotating field to maintain torque.
The squirrel cage rotor needs slip rings to receive electrical current from the stator.
From mechanical rotation to grid electricity
We just saw how an induction motor converts electrical energy to mechanical rotation using slip. That raises a question: what about the reverse — how does a power station convert mechanical rotation into electricity at grid scale? This card answers it → a synchronous alternator (no slip) driven by a turbine, output stepped up by transformers.
Power stations use large AC generators (alternators) driven by turbines. Unlike induction motors, power station generators run at exactly synchronous speed — slip would reduce their output frequency.
Generation process
- Energy source: Coal, gas, nuclear, or hydro provides thermal or kinetic energy.
- Turbine: Steam, water, or gas spins a turbine at high speed (50 Hz in Australia = 3000 RPM for a 2-pole generator).
- Generator: The turbine spins a rotor (electromagnet) inside a stationary stator. As the rotor turns, the magnetic flux through the stator windings changes, inducing a large alternating emf.
- Transformer: The generated voltage (typically 10–25 kV) is stepped up to 330 kV or higher for efficient long-distance transmission.
Induction motor vs power station generator
| Feature | Induction Motor | Power Station Generator |
|---|---|---|
| Energy conversion | Electrical to mechanical | Mechanical to electrical |
| Rotating part | Rotor (squirrel cage) | Rotor (electromagnet) |
| Field creation | Stator windings (AC) | Rotor windings (DC excitation) |
| Slip | 2–5% (necessary) | None (synchronous) |
| Brushes needed | No | Yes (for rotor excitation) |
Power station generator (alternator): turbine spins DC-excited rotor inside stator → changing flux → AC emf. Runs at synchronous speed (no slip). 2-pole, 50 Hz → 3000 RPM; 4-pole → 1500 RPM. Output stepped up by transformer for long-distance transmission.
Add the highlighted power station generator summary to your notes before the check below.
A 2-pole power station generator operates at 50 Hz. Its rotational speed is:
Use the interactive tool. An electric motor converts energy from…
Calculate motor and generator speeds
An AC induction motor operates on 50 Hz mains power and has 4 poles.
- (a) Calculate the synchronous speed of the stator field.
- (b) If the rotor turns at 1425 RPM, calculate the slip speed and percentage slip.
- (c) A 2-pole generator must produce 50 Hz. At what speed must it rotate?
$n_s = \dfrac{120f}{p} = \dfrac{120 \times 50}{4} = 1500 \text{ RPM}$
Slip speed = 1500 − 1425 = 75 RPM
$\% \text{ slip} = \dfrac{1500 - 1425}{1500} \times 100 = 5.0\%$
$n_s = \dfrac{120f}{p} = \dfrac{120 \times 50}{2} = 3000 \text{ RPM}$
Use the table and your notes to answer these questions
- Explain why an induction motor cannot reach synchronous speed. What would happen if it did?
- List three advantages of an induction motor over a DC motor for industrial use.
- A power station generator produces electricity at 50 Hz. If it has 2 poles, what is its rotational speed in RPM?
- Why do power station generators use electromagnets for the rotor rather than permanent magnets?
Three of these statements about an AC induction motor are correct. Pick the odd one out.
Swap your working with a partner and check each other's calculations
Swap with a partner. Check that they: (1) used the correct formula $n_s = 120f/p$, (2) calculated slip correctly as a percentage of synchronous speed (not rotor speed), and (3) clearly distinguished between motor slip and generator synchronous operation. Give one piece of positive feedback and one suggestion.
- AC induction motors use a rotating stator field to induce currents in a squirrel cage rotor.
- Slip (2–5%) is necessary — without it, no flux change, no induction, no torque.
- Power station generators use turbines to spin rotors, inducing AC in stator windings.
- Both devices rely on Faraday's Law and electromagnetic induction, but convert energy in opposite directions.
A fresh five-question set drawn from this lesson's bank — feedback shown immediately. +5 XP per correct · +25 XP all correct
Pick your answer, then rate your confidence — that tells the system what to drill next.
ApplyBand 4(4 marks) 1. A 4-pole AC induction motor operates on 50 Hz mains power.
- Calculate the synchronous speed. (1 mark)
- The rotor turns at 1440 RPM. Calculate the percentage slip. (2 marks)
- Explain what would happen to the torque if the rotor somehow reached synchronous speed. (1 mark)
1 mark: correct $n_s = 1500$ RPM · 1 mark: correct slip speed (60 RPM) · 1 mark: correct % slip (4.0%) · 1 mark: torque falls to zero (no relative motion, no induced current)
AnalyseBand 5(3 marks) 2. A three-phase induction motor is running at full load with 4% slip. If the load suddenly increases, explain what happens to the slip and the current drawn by the motor. Justify your answer using the principles of electromagnetic induction.
1 mark: slip increases (rotor slows further) · 1 mark: greater relative motion → greater rate of flux change → larger induced current · 1 mark: larger current → greater magnetic force → greater torque to match increased load
Show all answers
Multiple choice
MC answers and full explanations are shown inline as you complete each question. Use the retry button to attempt a fresh set drawn from the lesson bank.
Short Answer — Model Answers
Q1 (4 marks): (a) $n_s = 120f/p = 120 \times 50 / 4 = 1500$ RPM (1 mark). (b) Slip speed $= 1500 - 1440 = 60$ RPM; $\% \text{ slip} = 60/1500 \times 100 = 4.0\%$ (2 marks: method + answer). (c) At synchronous speed, there is no relative motion between the rotor and the rotating field. No flux change means no induced EMF, no current, and therefore no torque — the motor would stall (1 mark).
Q2 (3 marks): When load increases, the rotor decelerates slightly, increasing the slip (1 mark). The greater relative motion between rotor and stator field increases the rate of flux change through the rotor bars, inducing a larger EMF and larger current by Faraday's Law (1 mark). The larger rotor current interacts with the stator field to produce a greater magnetic torque, restoring the rotor speed and matching the increased load demand (1 mark).
Five timed questions on induction motors and generators. Beat the boss to bank a tier — gold (perfect + fast), silver (80%+), or bronze (cleared).
⚔ Enter the arenaAt the start you were asked about Tesla's 1888 induction motor — what physical principle allows the squirrel-cage rotor to spin without any direct electrical connection?
The answer: electromagnetic induction (Faraday's Law). The rotating stator field changes flux through the rotor bars, inducing eddy currents. Those currents interact with the stator field (Lenz's Law) to produce torque. Slip is not a flaw — without it there is no relative motion, no flux change, and no torque. The rotor must always chase the rotating field but never quite catch it.
Extend: How does a power station operator control the output frequency if the turbine speed changes slightly due to grid demand fluctuations?