🔌 Transformers are the unsung heroes of modern electricity, letting us safely step voltage up or down for everything from phone chargers to power plants.
A simple iron‑cored transformer has two main parts:
Think of the iron core as a magnetic bridge that carries the “magnetic traffic” from the primary to the secondary, much like a road that lets cars move from one side of a city to the other.
The transformer works on two key ideas:
Mathematically, the relationship is:
\$\dfrac{Vp}{Vs} = \dfrac{Np}{Ns}\$
Where:
Because power is (approximately) conserved in an ideal transformer, we also have:
\$Pp \approx Ps \;\;\;\;\text{or}\;\;\;\; Vp Ip \approx Vs Is\$
From this we can deduce the current relationship:
\$\dfrac{Ip}{Is} = \dfrac{Ns}{Np}\$
The iron core keeps the magnetic field lines together, reducing the amount of magnetic flux that leaks into the surroundings. This makes the transformer more efficient and safer.
📝 Remember:
⚡ A transformer has 200 turns on the primary and 800 turns on the secondary. If the primary voltage is 120 V, what is the secondary voltage?
Solution: \$\dfrac{Vp}{Vs} = \dfrac{Np}{Ns} \;\;\Rightarrow\;\; Vs = Vp \dfrac{Ns}{Np} = 120 \times \dfrac{800}{200} = 480\text{ V}\$
📚 The mains supply in most homes is 230 V. To power a 12 V laptop charger, a step‑down transformer reduces the voltage from 230 V to 12 V, making it safe and efficient.
| Parameter | Formula | Key Point |
|---|---|---|
| Voltage Ratio | \$\dfrac{Vp}{Vs} = \dfrac{Np}{Ns}\$ | More turns → higher voltage. |
| Current Ratio | \$\dfrac{Ip}{Is} = \dfrac{Ns}{Np}\$ | More turns → lower current. |
| Power Conservation | \$Vp Ip \approx Vs Is\$ | Ideal transformer has no power loss. |