# 23.10: Transformers

- Page ID
- 2713

**Transformers** do what their name implies—they transform voltages from one value to another (The term voltage is used rather than emf, because transformers have internal resistance). For example, many cell phones, laptops, video games, and power tools and small appliances have a transformer built into their plug-in unit (like that in Figure \(\PageIndex{1}\)) that changes 120 V or 240 V AC into whatever voltage the device uses.

Transformers are also used at several points in the power distribution systems, such as illustrated in Figure \(\PageIndex{2}\). Power is sent long distances at high voltages, because less current is required for a given amount of power, and this means less line loss, as was discussed previously. But high voltages pose greater hazards, so that transformers are employed to produce lower voltage at the user’s location.

The type of transformer considered in this text (Figure \(\PageIndex{3}\)) is based on Faraday’s law of induction and is very similar in construction to the apparatus Faraday used to demonstrate magnetic fields could cause currents. The two coils are called the *primary* and *secondary coils*. In normal use, the input voltage is placed on the primary, and the secondary produces the transformed output voltage. Not only does the iron core trap the magnetic field created by the primary coil, its magnetization increases the field strength. Since the input voltage is AC, a time-varying magnetic flux is sent to the secondary, inducing its AC output voltage.

For the simple transformer shown in Figure \(\PageIndex{3}\), the output voltage \(V_{s}\) depends almost entirely on the input voltage \(V_{p}\) and the ratio of the number of loops in the primary and secondary coils. Faraday’s law of induction for the secondary coil gives its induced output voltage \(V_{s}\) to be

\[V_{s} = -N\dfrac{\Delta \Phi}{\Delta t},\label{23.8.1}\]

where \(N_{s}\) is the number of loops in the secondary coil and \(\Delta \Phi / \Delta t\) is the rate of change of magnetic flux. Note that the output voltage equals the induced emf (\(V_{s} = emf_{s}\)), provided coil resistance is small (a reasonable assumption for transformers). The cross-sectional area of the coils is the same on either side, as is the magnetic field strength, and so \(\Delta \Phi / \Delta t\) is the same on either side. The input primary voltage \(V_{p}\) is also related to changing flux by

\[V_{p} = -N_{p}\dfrac{\Delta \Phi}{\Delta t}.\label{23.8.2}\]

The reason for this is a little more subtle. Lenz’s law tells us that the primary coil opposes the change in flux caused by the input voltage \(V_{p}\), hence the minus sign (This is an example of *self-inductance*, a topic to be explored in some detail in later sections). Assuming negligible coil resistance, Kirchhoff’s loop rule tells us that the induced emf exactly equals the input voltage. Taking the ratio of these last two equations yields a useful relationship:

\[\dfrac{V_{s}}{V_{p}} = \dfrac{N_{s}}{N_{p}}.\label{23.8.3}\]

This is known as the **transformer equation**, and it simply states that the ratio of the secondary to primary voltages in a transformer equals the ratio of the number of loops in their coils.

The output voltage of a transformer can be less than, greater than, or equal to the input voltage, depending on the ratio of the number of loops in their coils. Some transformers even provide a variable output by allowing connection to be made at different points on the secondary coil. A **step-up transformer** is one that increases voltage, whereas a **step-down transformer** decreases voltage. Assuming, as we have, that resistance is negligible, the electrical power output of a transformer equals its input. This is nearly true in practice—transformer efficiency often exceeds 99%. Equating the power input and output,

\[P_{p} = I_{p}V_{p} = I_{s}V_{s} = P_{s}.\label{23.8.4}\]

Rearranging terms gives

\[\dfrac{V_{s}}{V_{p}} = \dfrac{I_{p}}{I_{s}}.\label{23.8.6}\]

Combining this with Equation \ref{23.8.3} , we find that

\[\dfrac{I_{s}}{I_{p}} = \dfrac{N_{p}}{N_{s}}.\label{23.8.7}\]

is the relationship between the output and input currents of a transformer. So if voltage increases, current decreases. Conversely, if voltage decreases, current increases.

Example \(\PageIndex{1}\): Calculating Characteristics of a Step-Up Transformer

A portable x-ray unit has a step-up transformer, the 120 V input of which is transformed to the 100 kV output needed by the x-ray tube. The primary has 50 loops and draws a current of 10.00 A when in use. (a) What is the number of loops in the secondary? (b) Find the current output of the secondary.

**Strategy and Solution for (a):**

We solve Equation \ref{23.8.3} for \(N_{s}\), the number of loops in the secondary, and enter the known values. This gives

\[\begin{align*} N_{s} &= N_{p}\dfrac{V_{s}}{V_{p}} \\[5pt] &= \left(50\right) \dfrac{100,000 V}{120 V} \\[5pt] &= 4.17 \times 10^{4}. \end{align*}\]

**Discussion for (a):**

A large number of loops in the secondary (compared with the primary) is required to produce such a large voltage. This would be true for neon sign transformers and those supplying high voltage inside TVs and CRTs.

**Strategy and Solution for (b):**

We can similarly find the output current of the secondary by solving Equation \ref{23.8.7} and \(I_{s}\) and entering known values. This gives

\[\begin{align*} I_{s} &= I_{p}\dfrac{N_{p}}{N_{s}} \\[5pt] &= \left(10.00 A \right) \dfrac{50}{4.17 \times 10^{4}} \\[5pt] &= 12.0 mA. \end{align*}\]

**Discussion for (b):**

As expected, the current output is significantly less than the input. In certain spectacular demonstrations, very large voltages are used to produce long arcs, but they are relatively safe because the transformer output does not supply a large current. Note that the power input here is

\[\begin{align*}P_{p} = I_{p}V_{p} &= \left(10.00 A \right) \left(120 V \right) \\[5pt] &= 1.20 kW. \end{align*}\]

This equals the power output

\[\begin{align*} P_{p} = I_{s}V_{s} &= \left(12.0 mA \right) \left(100kV \right) \\[5pt] &= 1.20 kW \end{align*}\]

as we assumed in the derivation of the equations used.

The fact that transformers are based on Faraday’s law of induction makes it clear why we cannot use transformers to change DC voltages. If there is no change in primary voltage, there is no voltage induced in the secondary. One possibility is to connect DC to the primary coil through a switch. As the switch is opened and closed, the secondary produces a voltage like that in Figure \(\PageIndex{4}\). This is not really a practical alternative, and AC is in common use wherever it is necessary to increase or decrease voltages.

Example \(\PageIndex{2}\): Calculating Characteristics of a Step-Down Transformer

A battery charger meant for a series connection of ten nickel-cadmium batteries (total emf of 12.5 V DC) needs to have a 15.0 V output to charge the batteries. It uses a step-down transformer with a 200-loop primary and a 120 V input. (a) How many loops should there be in the secondary coil? (b) If the charging current is 16.0 A, what is the input current?

**Strategy and Solution for (a):**

You would expect the secondary to have a small number of loops. Solving Equation \ref{23.8.3} for \(N_{s}\) and entering known values gives

\[\begin{align*} N_{s} &= N_{p}\dfrac{V_{s}}{V_{p}} \\[5pt] &= \left( 200 \right) \dfrac{15.0 V}{120 V} \\[5pt] &= 25. \end{align*}\]

**Strategy and Solution for (b):**

The current input can be obtained by solving Equation \ref{23.8.7} for \(I_{p}\) and entering known values. This gives

\[\begin{align*} I_{p} = I_{s}\dfrac{N_{s}}{N_{p}} \\[5pt] &= \left( 16.0 A \right) \dfrac{25}{200} \\[5pt] &= 2.00 A. \end{align*}\]

**Discussion:**

The number of loops in the secondary is small, as expected for a step-down transformer. We also see that a small input current produces a larger output current in a step-down transformer. When transformers are used to operate large magnets, they sometimes have a small number of very heavy loops in the secondary. This allows the secondary to have low internal resistance and produce large currents. Note again that this solution is based on the assumption of 100% efficiency—or power out equals power in (\(P_{p} = P_{s}\))-- reasonable for good transformers. In this case the primary and secondary power is 240 W. (Verify this for yourself as a consistency check.) Note that the Ni-Cd batteries need to be charged from a DC power source (as would a 12 V battery). So the AC output of the secondary coil needs to be converted into DC. This is done using something called a rectifier, which uses devices called diodes that allow only a one-way flow of current.

Transformers have many applications in electrical safety systems, which are discussed in 23.9.

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## Summary

- Transformers use induction to transform voltages from one value to another.
- For a transformer, the voltages across the primary and secondary coils are related by \[\dfrac{V_{s}}{V_{p}} = \dfrac{N_{s}}{N_{p}},\] where \(V_{p}\) and \(V_{s}\) are the voltages across primary and secondary coils having \(N_{p}\) and \(N_{s}\) turns.
- The currents \(I_{p}\) and \(I_{s}\) in the primary and secondary coils are related by \(\dfrac{I_{s}}{I_{p}} = \dfrac{N_{p}}{N_{s}}.\)
- A step-up transformer increases voltage and decreases current, whereas a step-down transformer decreases voltage and increases current.

## Glossary

- transformer
- a device that transforms voltages from one value to another using induction

- transformer equation
- the equation showing that the ratio of the secondary to primary voltages in a transformer equals the ratio of the number of loops in their coils; \(\dfrac{V_{s}}{V_{p}} = \dfrac{N_{s}}{N_{p}}\)

- step-up transformer
- a transformer that increases voltage

- step-down transformer
- a transformer that decreases voltage

## Contributors and Attributions

Paul Peter Urone (Professor Emeritus at California State University, Sacramento) and Roger Hinrichs (State University of New York, College at Oswego) with Contributing Authors: Kim Dirks (University of Auckland) and Manjula Sharma (University of Sydney). This work is licensed by OpenStax University Physics under a Creative Commons Attribution License (by 4.0).