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Transformer is an electrical device used to 'step up' or ‘step down' the voltage levels between circuits. A transformer is a passive electrical device that uses electromagnetic induction in order to transmit electrical energy from one circuit to another. The transformer raises or reduces AC voltage between circuits while keeping the current's frequency constant. Transformer formula is given by the equation,
\(\frac{V_p}{V_s} = \frac{N_p}{N_s}\)
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Key Terms: Transformer, Transformer Formula, Step up, Step down, current, faraday’s law, circuit, EMF, Current Coil, Electromagnetic Induction.
What is a Transformer?
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Transformers are electrical devices that employ a changing magnetic field to transmit electrical energy between two or more coils of wire.
- A transformer is a simple stationary electromagnetic device that uses Faraday's Law of Induction to convert electrical energy from one value to another.
- The transformer does this conversion by connecting multiple electrical circuits via a common oscillating magnetic circuit that is generated by the transformer.
- In the form of Mutual Induction, a transformer acts on the principles of "electromagnetic induction."
- The transformer formula or transformer equation can be written as Vp × Ip = Vs × Is.
The video below explains this:
Transformer Detailed Video Explanation:
Also Read:
Transformer Formula
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An electric circuit’s power can be calculated by multiplying the current intensity with the voltage.
(Primary coil input voltage) + (Primary coil input current) = (Secondary coil output voltage).(Output current on the secondary coil)
\(\frac{\text{Input Voltage on Primary Coil}}{\text{Output Voltage on Secondary Coil}} = \frac{\text{No. of truns of wire on Primary Coil}}{\text{No. of turns of Wire on Secondary Coil}}\)
The formula for the transformer is as follows:
\(\frac{V_p}{V_s} = \frac{N_p}{N_s}\)
Where,
- Vp denotes main voltage
- Vs denotes secondary voltage.
- Np denotes the number of primary turns.
- Ns denotes the number of secondary turns.
- The ratio Np/Ns is also called the turn ratio as it denotes the difference between the number of turns in a primary coil with that of the secondary coil.
Step Up Transformer Formula
On the primary side, a step-up transformer converts low voltage (LV) and high current to high voltage (HV) and low current on the secondary side. In a step-up transformer, which transforms a low primary voltage to a high secondary voltage, the primary coil turns are smaller than the secondary coil turns. The formula for a step-up transformer is as follows:
VS = NS/NP x VP
Step Down Transformer Formula
A step-down transformer lowers the secondary voltage from a high primary voltage. In a Step Down Transformer, the primary winding of a coil has more turns than the secondary winding. The formula is as follows:
VS = NS/NP x VP
Solved ExamplesExample: Calculate the current in the secondary coil if the voltage in the secondary coil is 50 V. We have a transformer with a current in the primary coil of 10 A and an input voltage in the primary coil of 120 V. Solutions: Because we need to figure out the output current in the secondary coil, we'll use the first equation, i.e. Vp × Ip = Vs × Is Given, Vp = 120 V Vs = 50 V Ip = 10 A Using the values provided in the question: Is = Vp/Vs × Ip Is = 12050 × 10 = 24 A As a result, the secondary coil's output current is 24 A. Example: The number of primary and secondary windings in a transformer is 60 and 100 respectively. The secondary voltage is 250V, find out the primary voltage. Solution: Given: Np = 60 Ns = 100 Vs = 250V The transformer formula is given by, Vp/Vs = Np/Ns Vp = Np/Ns × Vs = 60/100 x 250 Vp = 150 V |
Types of Transformers
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The two main types of transformers are:
- Step-up Transformer: As the number of turns on the secondary is always more than the number of turns on the primary, the step-up transformer aids in the voltage rise on the output side. The secondary side of the transformer generates a high voltage.
- Step-down Transformer: The output voltage is reduced using a step-down voltage transformer. In other words, it transforms high voltage, low current electricity into low voltage, high current electricity. The power supply, for example, has a voltage of 230-110 V, while the doorbell only needs 16 V. As a result, a step-down transformer should be used to lower the voltage from 110 V or 220 V to 16 V.
Parts of Transformer
The different parts of a transformer are as follows.
- The magnetic core, primary winding, and secondary winding are the three main components of a transformer.
- A live supply of AC power is connected to the primary winding.
- An oscillating magnetic field surrounds the coil as a result of this.
- The secondary winding experiences an EMF.
- If the secondary winding circuit is closed, AC current will flow through it.
- The magnetic core, which is commonly formed of laminated steel sheets and offers a low resistance route for the magnetic field, is shared by these windings.
- The ratio of the number of turns between the two windings is the same as the ratio of output and input voltage.
- The secondary winding in a step-down transformer has fewer turns than the primary, whereas the secondary winding in a step-up transformer has more.
Working Principle of a Transformer
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Mutual inductance between two circuits connected by a shared magnetic flux is the primary basis of the functioning of a transformer. A basic transformer is made up of two inductive coils that are electrically distinct yet magnetically coupled by a reluctance channel. The transformer's operating principle may be seen in the diagram below.
Principle of Transformer
- The core laminations are linked in the shape of strips, and you can see some tiny gaps along the length of the cross-section of the core. The mutual inductance of both coils is quite high.
- The alternating flux that is built up in the laminated core, due to the coil that is coupled to an alternating voltage source, induces a mutual electromotive force in the transformer.
- The mutual induced electromotive force is created when the majority of the alternating flux produced by this coil is coupled with the other coil.
- Faraday's equations of electromagnetic induction may be used to describe the electromotive force that has been created.
- A current flows through the second coil circuit while it is closed, and electrical energy is transmitted magnetically from the first to the second coil.
- The first coil receives an alternating current source and hence is referred to as the primary winding.
- The energy is extracted from the second coil, which is referred to as the secondary winding.
Also Read:
Things to Remember
- A transformer transfers AC current from one circuit to another while raising or reducing voltage via electromagnetic induction.
- The primary winding, secondary winding, and magnetic core are the three main components of a transformer.
- A transformer is an electrical device that allows us to sustain power while increasing or decreasing the voltage in an alternating current electrical circuit.
- The formula for the transformer is as follows:
\(\frac{V_p}{V_s} = \frac{N_p}{N_s}\)
Sample Questions
Ques. The primary and secondary windings each have 60 and 100 turns, respectively. Determine the primary voltage by multiplying the secondary voltage by 250 V. (3 marks)
Ans. Given:
Np = 60,
Ns = 100
Vs = 250V
The formula for the transformer is as follows:
Vp / Vs = Np / Ns
Vp = Np / Ns ×Vs
= 60 / 100 x 250
Vp = 150 V
Ques. There are 100 primary and 350 secondary windings, respectively. Determine the secondary voltage based on the primary voltage of 200V. (3 marks)
Ans. Given:
Np = 100,
Ns = 350 and
Vp = 200V
The formula for the transformer is as follows:
Vp / Vs = Np / Ns
Vs = Vp×Ns / Np
Vs = 200 × 350 / 100
Vs = 700V
Ques. There are 90 primary and 120 secondary windings, respectively. The primary voltage is determined by 310V, while the secondary voltage is determined by 310V. (3 marks)
Ans. Given:
Np = 90,
Ns= 120
Vs = 310V
By Transformer Formula,
Vp / Vs = Np / Ns
VP = 90/120 x 310
Vp = 232.5 volt
Ques. There are 110 primary and 240 secondary windings, respectively. The secondary voltage is determined by the primary voltage, which is 300V. (3 marks)
Ans. Given:
Np = 110,
Ns= 240
Vp = 300V
By Transformer Formula,
Vp / Vs = Np / Ns
VS = 240/110 x 300
Vs = 654.5 volts
Ques. A transformer contains a main and secondary coil with 500 and 5000 loops, respectively. 220 V is the input voltage. What is the voltage of the output? (5 marks)
Ans. We Know
500 loops in the primary coil (NP).
5000 loops in the secondary coil (Ns).
220 Volt Primary Voltage (VP)
To find: Secondary voltage (VS)
Solution :
Vs / Ns = Vp / Np
Vs / 5000 = 220 / 500
Vs / 5000 = 0.44
Vs = (0.44)(5000)
Vs = 2200 Volt
Ques. The primary coil of a transformer contains 1200 loops, whereas the secondary coil has 1000 loops. What is the current in the secondary coil if the first coil has a current of 4 Ampere? (5 marks)
Ans. Given:
1200 loops in the primary coil (NP).
1000 loops in the secondary coil (NS).
The principal coil current (IP) is 4 Ampere.
The current in the secondary coil is required (IS) to found
IS/IP = NP/NS
The current in the secondary coil :
IS/4 = 1200/1000
IS/4 = 1.2
IS = 1.2 (4)
IS = 4.8 Ampere
Ques. If the secondary voltage is 220 volts and the main voltage is 110 volts, the secondary coil and primary coil comparison is… (5 marks)
Ans. Given:
220 Volt Secondary Voltage (VS)
110 volts (VP) is the primary voltage.
NS/NP is required.
VS/VP = NS/NP
220/110 = NS/NP
22/11 = NS/NP
2/1 = NS/NP
12/6 = NS/NP
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