Transformers: Videos & Practice Problems

Transformers are essential devices that utilize the principle of electromagnetic induction to adjust voltage levels for efficient power delivery from generators to homes. In North America, the standard voltage delivered to households is 120 volts, which can be too high for sensitive electronics. Therefore, transformers are used to step down this voltage to safer levels.

The operation of a transformer is based on Faraday's law of electromagnetic induction, which states that a changing magnetic field can induce an electromotive force (emf) in a nearby coil. A typical transformer consists of two solenoids (coils) placed close to each other, each with a different number of turns. The relationship between the input voltage (V₁) and output voltage (V₂) is governed by the equation:

\[ \frac{V_2}{V_1} = \frac{N_2}{N_1} \]

where N₁ is the number of turns in the input solenoid and N₂ is the number of turns in the output solenoid. This equation allows us to determine how the voltages relate to the number of turns in each solenoid.

For example, if we want to design a transformer that reduces 120 volts to 15 volts, we can set up the equation:

\[ \frac{15}{120} = \frac{N_2}{50} \]

Solving this gives us a ratio of 1/8. We can rearrange the equation to find N₂ in two ways: either as N₂ = 8 × N₁ or N₁ = N₂ / 8. Plugging in N₁ = 50 turns, we find:

1. If N₁ is the output solenoid, then N₂ = 6.25 turns.

2. If N₁ is the input solenoid, then N₂ = 400 turns.

Clearly, the configuration that requires the least number of turns for the second solenoid is when it has 6.25 turns, making it the input solenoid. This demonstrates how transformers can be designed to efficiently convert high voltages to lower, safer levels for household use.

In this problem, we are tasked with designing a transformer that reduces the voltage from a standard North American outlet of 120 volts to a safer 15 volts. To achieve this, we need to determine the number of turns in a second solenoid, given that we already have a first solenoid with 50 turns.

The relationship between the voltages and the number of turns in a transformer is defined by the equation:

\[ \frac{V_2}{V_1} = \frac{N_2}{N_1} \]

Here, \(V_1\) is the input voltage (120 volts), \(V_2\) is the output voltage (15 volts), \(N_1\) is the number of turns in the first solenoid, and \(N_2\) is the number of turns in the second solenoid. Substituting the known values into the equation gives us:

\[ \frac{15}{120} = \frac{N_2}{50} \]

This simplifies to:

\[ \frac{1}{8} = \frac{N_2}{50} \]

From this, we can derive that:

\[ N_2 = \frac{50}{8} = 6.25 \text{ turns} \]

However, we also need to consider the alternative scenario where \(N_2\) is 50 turns. In this case, we can rearrange the equation to find \(N_1\):

\[ \frac{1}{8} = \frac{50}{N_1} \]

This leads to:

\[ N_1 = 50 \times 8 = 400 \text{ turns} \]

Comparing the two outcomes, we find that 6.25 turns is significantly fewer than 400 turns. Therefore, the optimal solution is to have the first solenoid with 50 turns, resulting in the second solenoid needing only 6.25 turns to achieve the desired voltage transformation.

This analysis highlights the importance of understanding the transformer equations and the relationship between voltage and the number of turns in solenoids, which is crucial for designing efficient electrical systems.