This MCQ module is based on: Electromagnetic Induction, Generator and Domestic Electric Circuits
TOPIC 46 OF 50
Electromagnetic Induction, Generator and Domestic Electric Circuits
🎓 Class 10
Science
CBSE
Theory
Ch 12 — Magnetic Effects of Electric Current
⏱ ~22 min
🌐 Language: [gtranslate]
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12.8 Electromagnetic Induction
In 1831 Michael Faraday asked a natural question: if a current produces a magnetic field, can a magnetic field produce a current? After years of careful experiments he showed that the answer is yes — but only when the magnetic field changes with time.
Electromagnetic induction: The phenomenon in which a changing magnetic field inside a closed coil induces an electric current in the coil. The induced current lasts only as long as the field is changing.
Faraday's careful observations from this simple setup:
- Induced current flows only while the magnet is in motion.
- Faster motion → larger induced current.
- Reversing the direction of motion reverses the direction of the induced current.
- The effect is the same whether the magnet moves and coil is fixed, or the coil moves and magnet is fixed. What matters is the relative motion.
Induced current also appears in a coil (secondary) kept near another coil (primary) at the instant the primary current is switched on or off — because switching the current on or off changes the magnetic field through the secondary coil.
12.8.1 Fleming's Right-Hand Rule (for generators)
The direction of the induced current in a straight conductor moving in a magnetic field is given by another three-finger rule.
Fleming's Right-Hand Rule
Stretch the thumb, forefinger and middle finger of the right hand mutually perpendicular. If the:
Stretch the thumb, forefinger and middle finger of the right hand mutually perpendicular. If the:
- Forefinger points along the magnetic Field (B),
- Thumb points along the direction of Motion of the conductor (v),
Activity 12.3 — Make a Current Without a BatteryL3 Apply
Materials: two coils of insulated copper wire (a "primary" coil A and a "secondary" coil B), a battery with a plug-key, a galvanometer.
- Connect coil A to the battery through the key. Connect coil B across the galvanometer. Place the two coils close to each other, side by side, but not electrically connected.
- Quickly press the key — the galvanometer needle gives a momentary deflection. Hold the key pressed — no deflection. Release the key — another momentary deflection, this time in the opposite direction.
Predict: What produces the current in coil B even though it is not connected to any battery?
While the key is pressed or released, the current in coil A is changing, so the magnetic field produced by coil A is also changing. This changing field through coil B induces a current in it — pure electromagnetic induction. While the current in A is steady, the field is steady, so no EMF is induced in B.
12.9 Electric Generator
An electric generator works on the reverse principle of a motor. Mechanical rotation of a coil inside a magnetic field induces an EMF in the coil; this EMF drives a current through an external circuit. Generators are the backbone of every power station in the world.
12.9.1 AC Generator (Alternator)
Working. The coil ABCD is rotated (by a turbine) in the magnetic field. In the first half rotation arm AB moves up and CD moves down; applying Fleming's right-hand rule, the induced current flows A → B → C → D — say, from left brush to the external circuit back to the right brush. In the second half rotation AB moves down and CD moves up; the induced current reverses its direction in the coil (now flows D → C → B → A). Because slip rings are continuous, this reversal reaches the external circuit as well — the current in the external circuit also reverses every half cycle. Thus the generator produces alternating current (AC).
In India, household AC has frequency \(50\,\text{Hz}\) — the direction of the current reverses 100 times a second.
12.9.2 DC Generator
A DC generator is identical to an AC generator except for one change — the slip rings are replaced by a split-ring commutator, just like the one in a motor. The commutator acts as a brush-swapping device: every time the coil rotates through half a turn, the brush that had been positive now touches what was the negative half-ring and vice versa. The current in the external circuit therefore always flows in the same direction, even though inside the coil it reverses each half cycle.
AC generator vs DC generator — at a glance
| Feature | AC generator | DC generator |
|---|---|---|
| End contacts of coil | Two continuous slip rings | A single split-ring commutator |
| Direction of external current | Reverses every half rotation | Always the same |
| Output waveform | Alternating sinusoidal | Unidirectional (pulsating DC) |
| Uses | Power stations, household mains | Charging batteries, DC motors in industry |
AC vs DC — Why AC won the grid war. AC voltage can be stepped up or stepped down by a transformer with very little loss, so it can be transmitted at very high voltage (hence low current, hence low \(I^2R\) loss) over hundreds of kilometres. DC cannot be transformed so easily, which is why AC is used for everyday supply while DC is kept for batteries and electronics.
12.10 Domestic Electric Circuits
The electricity that enters your home arrives through three wires:
- Live (phase) wire — insulated with red (or brown) plastic. It is at a high potential of about +220 V.
- Neutral wire — insulated with black (or blue) plastic. It is at (nearly) zero potential.
- Earth wire — insulated with green (or green-yellow striped) plastic. It is connected to a thick metal plate buried deep in the ground near the house.
The potential difference between live and neutral is 220 V at 50 Hz.
Each room is connected in parallel so that every appliance receives the full 220 V and can be switched on independently. There are usually two separate circuits in a home:
- Lighting circuit — with a 5 A fuse — for bulbs and fans (low current).
- Power circuit — with a 15 A fuse — for high-current sockets that feed geysers, ACs, microwaves.
12.10.1 Earthing — The Safety Wire
Earthing is a life-saver. If the insulation of an appliance fails and the live wire accidentally touches the metal case of (say) a geyser, the case would go to 220 V — any person who touches it could be killed. The earth wire provides a low-resistance path from the case to the ground. As soon as the live wire touches the case, a huge current rushes to earth, the fuse melts (or the MCB trips) and the supply is cut.
12.10.2 Fuse and MCB
Fuse: A short piece of wire (an alloy of tin and lead, low melting point) connected in series with the live wire. If the current exceeds the rated value, the fuse wire heats up and melts, breaking the circuit and saving the appliance.
MCB (Miniature Circuit Breaker): An automatic electromagnetic switch that trips (opens) instantly when the current exceeds its rated value. Unlike a fuse, an MCB can be reset — no need to replace a wire. Modern homes use MCBs (and ELCBs) in place of fuses.
12.10.3 Short Circuit and Overloading
- Short circuit: The live and neutral wires come in direct contact (damaged insulation, wet walls). The resistance of the path becomes nearly zero, so a very large current flows — sparks fly, wires burn and fire can start.
- Overloading: Too many high-power appliances are plugged into the same socket (or the voltage rises above 220 V). The wires carry more current than they are designed for, heat up, and may ignite.
In both cases, a correctly rated fuse or MCB protects the circuit by breaking it before damage is done.
12.10.4 Safety precautions
- Always use good-quality, well-insulated wires.
- Check that the earth wire is connected to every three-pin socket and appliance with a metal body.
- Never use more appliances than the circuit is rated for (avoid multi-plug boards on one socket).
- Never touch a switch or socket with wet hands.
- Always switch off the mains before replacing a bulb, a fuse or repairing any appliance.
- Use MCBs / ELCBs rather than rewirable fuses where possible.
Competency-Based Questions
Scenario: After a thunderstorm, Mr Sharma finds that the MCB in his house has tripped and power is off to the whole kitchen circuit. On checking, he notices that a rat has chewed through the insulation of the fridge cable and the bare copper strands are touching the metal back of the fridge.
Q1. (MCQ) The bare wire touching the metal body of the fridge would have been most dangerous to a person L3 Apply
(b) — If the earth wire is intact, the stray current flows instantly to earth and the MCB trips. Without earthing, the metal body stays at 220 V and can give a fatal shock.
Q2. (MCQ) The colour of the earth wire in standard domestic wiring is L1 Remember
(c) green (or green with yellow stripe).
Q3. (Short answer) Give two reasons why an MCB is preferred to a rewirable fuse in modern homes. L2 Understand
(i) An MCB trips automatically and almost instantly; it does not rely on a wire melting. (ii) It is resettable by a simple flip of the switch, so no replacement wire is needed. An MCB is also more reliable and offers clearer indication of which circuit has faulted.
Q4. (Short answer) Distinguish between a short circuit and overloading. L2 Understand
Short circuit — the live and neutral wires touch directly (damaged insulation), dropping the resistance to near zero and pulling a huge current in an instant. Overloading — too many appliances draw current from one circuit so the total current exceeds its safe rating over time. Both cause heating; both are stopped by the fuse / MCB.
Q5. (HOT) Household appliances are always connected in parallel across the mains and never in series. Give two scientific reasons. L4 Analyse
(i) In a parallel connection each appliance gets the same 220 V, so each can be designed for 220 V operation. In series the supply voltage would be shared, and every appliance would glow at less than its rated voltage. (ii) In a parallel network each appliance has its own independent branch, so it can be switched on or off without affecting others; if one fails, the rest keep working. In series, one failed device breaks the whole circuit.
Assertion–Reason Questions
Options: (A) Both A & R true, R correctly explains A. (B) Both A & R true, R does NOT explain A. (C) A true, R false. (D) A false, R true.
Assertion (A): A current is induced in a closed coil only when the magnetic flux through it changes.
Reason (R): A steady magnetic field through a stationary coil produces a steady current in the coil.
(C) — A is true, but R is false. A steady magnetic field does not induce any current; only a changing field does.
Assertion (A): In an AC generator, slip rings are used instead of a split-ring commutator.
Reason (R): Slip rings keep the external circuit connections fixed so that the current in the external circuit alternates in direction with the current in the coil.
(A) — Both true; R correctly explains A.
Assertion (A): The earth wire in a domestic circuit is coloured green.
Reason (R): The earth wire carries current from the neutral wire to the ground.
(C) — A is true, R is false. The earth wire does not normally carry current; it carries current only in the event of a fault, when the leaking current from the live wire has to be safely taken to earth.
Frequently Asked Questions — Induction, Generator & Domestic Circuits
What is induction, generator & domestic circuits in Class 10 Science (CBSE board)?
Induction, Generator & Domestic Circuits is a key topic in NCERT Class 10 Science Chapter 12 — Magnetic Effects of Electric Current. It explains electromagnetic induction, ac/dc generators and the domestic electric circuit with safety features. Core ideas covered include electromagnetic induction, Fleming's right-hand rule, electric generator, AC generator. Mastering this subtopic is essential for scoring well in the CBSE Class 10 Science board exam because board papers repeatedly test these concepts through MCQs, short answers and long-answer questions. This part gives a complete, exam-ready explanation with activities, diagrams and competency-based practice aligned to NCERT.
Why is electromagnetic induction important in NCERT Class 10 Science?
Electromagnetic induction is important in NCERT Class 10 Science because it forms the foundation for understanding induction, generator & domestic circuits in Chapter 12 — Magnetic Effects of Electric Current. Without a clear idea of electromagnetic induction, students cannot answer higher-order CBSE board questions involving Fleming's right-hand rule, electric generator, AC generator. Board papers regularly include 2-mark and 3-mark questions on this concept, and competency-based questions often link electromagnetic induction to real-life situations. Building clarity here pays off directly in board marks.
How is induction, generator & domestic circuits tested in the Class 10 Science CBSE board exam?
The CBSE Class 10 Science board exam tests induction, generator & domestic circuits through a mix of 1-mark MCQs, 2-mark short answers, 3-mark explanations with examples, 5-mark descriptive questions (often with diagrams or balanced equations) and 4-mark competency-based questions. Expect direct questions on electromagnetic induction, Fleming's right-hand rule, electric generator and application-based questions drawn from NCERT activities. Students who follow NCERT thoroughly and practice this chapter's questions consistently score in the 90%+ range.
What are the key terms to remember for induction, generator & domestic circuits in Class 10 Science?
The key terms to remember for induction, generator & domestic circuits in NCERT Class 10 Science Chapter 12 are: electromagnetic induction, Fleming's right-hand rule, electric generator, AC generator, DC generator, alternating current. Each of these concepts carries exam weightage and regularly appears in the CBSE board paper. Write clear one-line definitions of every term in your revision notes and revisit them before the exam. Linking these terms visually through a flowchart or concept map makes recall easier during the Class 10 Science board exam.
Is Induction, Generator & Domestic Circuits included in the Class 10 Science syllabus for 2025–26 CBSE board exam?
Yes, Induction, Generator & Domestic Circuits is a part of the NCERT Class 10 Science syllabus (2025–26) prescribed by CBSE. It falls under Chapter 12 — Magnetic Effects of Electric Current — and is examined in the annual board paper. The current syllabus retains the full treatment of electromagnetic induction, Fleming's right-hand rule, electric generator as per the NCERT textbook. Because CBSE bases every board question on NCERT, studying this part thoroughly ensures complete syllabus coverage and guarantees marks from this chapter.
How should I prepare induction, generator & domestic circuits for the CBSE Class 10 Science board exam?
Prepare induction, generator & domestic circuits for the CBSE Class 10 Science board exam in three steps. First, read this NCERT part carefully, highlighting definitions and diagrams of electromagnetic induction, Fleming's right-hand rule, electric generator. Second, solve every in-text question and end-of-chapter exercise — CBSE questions often come directly from NCERT. Third, practice competency-based and assertion-reason questions to sharpen reasoning. Write answers in the exam-style format (point-wise with diagrams) and time yourself. This method delivers confidence and full marks in the board exam.
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