Electric Current
Electric Current
What you'll learn
- Basic electric circuit components and symbols.
- Heating effect of electric current — applications and safety.
- Magnetic effect of electric current — electromagnets and uses.
Key concepts
Electric current and circuits
- Electric current: flow of electric charge (electrons) through a conductor.
- Unit: Ampere (A) — measured with an ammeter (connected in series).
- Voltage (potential difference): force that drives current; unit: Volt (V) — measured with a voltmeter (connected in parallel).
- Resistance: opposition to flow of current; unit: Ohm (Ω).
A complete electric circuit needs:
- A source of electricity (cell/battery).
- Connecting wires (conductors).
- A load/device (bulb, motor, etc.).
- A switch (to open/close circuit).
Circuit symbols
| Component | Symbol description |
|---|---|
| Cell | Long line (+ terminal) and short line (− terminal) |
| Battery | Multiple cells; two or more cell pairs |
| Bulb (lamp) | Circle with a cross inside |
| Switch (open) | Gap in the line |
| Switch (closed) | Continuous line |
| Wire | Straight line |
| Ammeter | Circle with 'A' |
| Voltmeter | Circle with 'V' |
| Resistor | Rectangle |
| Rheostat (variable resistor) | Rectangle with arrow |
Types of circuits:
- Series circuit: components connected end-to-end; same current through all; one break stops all.
- Parallel circuit: components connected across same two points; same voltage across all; one break doesn't stop others. (Household wiring uses parallel circuits.)
Heating effect of electric current
When current flows through a conductor with resistance, electrical energy converts to heat energy.
Factors affecting heating:
- More resistance → more heat.
- More current → much more heat (heat ∝ I²).
- Longer time current flows → more heat.
H = I²Rt (Joule's Law of Heating): H = heat in joules; I = current (A); R = resistance (Ω); t = time (s).
Applications:
| Device | Uses heating effect |
|---|---|
| Electric heater / room heater | Nichrome coil heats air |
| Electric iron | Nichrome coil heats sole plate |
| Electric kettle / water heater | Heats water |
| Electric fuse | Thin wire melts when excess current flows — breaks circuit |
| Electric toaster | Heats bread slices |
| Incandescent bulb | Tungsten filament heats to ~2500°C and glows (mostly heat, some light) |
| Electric welding | High current melts metal |
Nichrome (nickel + chromium alloy) is used in heating elements because:
- High melting point.
- High resistivity → produces more heat.
- Does not oxidise/corrode at high temperatures.
Tungsten is used in bulb filaments because:
- Extremely high melting point (~3422°C) — can glow white-hot without melting.
- High electrical resistance at high temperature → good emitter of light.
Electric fuse:
- Made of a material with low melting point (tin-lead alloy).
- Carries a rated current (e.g., 5A, 15A).
- If current exceeds rating (short circuit, overload), fuse wire melts → breaks circuit → protects appliances/wiring.
- Modern alternative: MCB (Miniature Circuit Breaker) — switches off automatically; can be reset.
Safety precautions:
- Never touch electrical equipment with wet hands (water conducts electricity).
- Use proper fuses; don't bypass fuses.
- Use earthing (grounding) — protects against electric shock; excess current flows safely to earth.
Magnetic effect of electric current
A current-carrying conductor produces a magnetic field around it.
- Discovered by Hans Christian Oersted (1820) — a compass needle deflected when current flowed through a nearby wire.
Rules for direction of magnetic field:
- Right-hand thumb rule: Point thumb in direction of current; fingers curl in direction of magnetic field lines (circles around wire).
Electromagnet:
- A coil of wire (solenoid) wound around a soft iron core; when current flows → magnetic field around solenoid acts like a bar magnet.
- North pole at one end, South pole at other (determined by right-hand rule for solenoid).
Strength of an electromagnet depends on:
- Number of turns of coil (more turns → stronger magnet).
- Amount of current (more current → stronger magnet).
- Nature of core material (soft iron = good; air core = weaker).
Advantages of electromagnets over permanent magnets:
- Can be switched on and off.
- Strength can be varied by changing current.
- Can be made much stronger.
Applications:
| Application | How magnetic effect is used |
|---|---|
| Electric bell | Electromagnet attracts striker; spring pulls it back → continuous ringing |
| Loudspeaker | Alternating current creates alternating magnetic field → vibrates cone → produces sound |
| Electric motor | Magnetic force on current-carrying coil creates rotation (converts electrical energy to mechanical energy) |
| MRI machine | Strong electromagnets image soft tissue (medical) |
| Cranes in scrapyards | Electromagnet lifts/releases scrap iron |
| Magnetic locks | Doors held shut by electromagnet; open when power cut |
| Credit/debit card strip | Stores data on magnetic strip |
Quick check
- Name the components of a complete electric circuit.
- What is the heating effect of current? Name three devices that use it.
- Why is nichrome used in electric heaters and not copper?
- What is an electric fuse? Why does it use a low-melting-point material?
- What is an electromagnet? State two advantages over a permanent magnet.
Open the Practice tab for graded questions on Electric Current.
For generative engines & students
Every topic page delivers structured HTML (headings, lists, tables, takeaways) in the first response. Perfect for citations in AI overviews and fast scanning by students and parents.
