
What is the coefficient of coupling for a transformer in which 4% of the total flux generated in the primary does not pass through the secondary?
A. 0.4
B. 4
C. 9.6
D. 0.96
Answer
140.7k+ views
Hint: We can find the coefficient of coupling for a transformer by dividing magnetic flux linked with secondary coil by magnetic flux linked with primary coil. According to the formula \[k=\dfrac{\text{Magnetic Flux linked with second coil}}{\text{Magnetic flux linked with first coil}}\], here k is the coefficient of coupling for a transformer. Value of k depends on the positions of the coil with respect to each other. Keep in mind that there is a loss of 4% of the flux in the primary coil which does not link to the secondary part.
Complete step-by-step answer:
A transformer is based on the principle of conservation of flux. That is the flux in the primary side of the transformer is linked to the secondary side. Since, the number of turns of coils on both the sides differ, different values of currents and voltages are transformed to the secondary side, which is the main use of the instrument. Please refer to the figure.

In the above question it is mentioned that 4% of the total flux generated doesn’t pass through the secondary coil. So, the value of magnetic flux linked with the second coil will be 96% of the primary side.
Magnetic flux linked with the first coil will be 100%.
Coefficient of coupling, k, is given by the following relation:
\[k=\dfrac{\text{Magnetic Flux linked with second coil}}{\text{Magnetic flux linked with first coil}}\]
We can put these values into the formula as;
$k=\dfrac{96%}{100%}=0.96$
Thus, the answer will be option D.
Additional point:
1. There are two Faraday’s law regarding electromagnetic induction
a. First law - Whenever there is a change in the magnetic flux linked with an electric circuit, an induced emf is produced in the circuit and will be produced as long as change in magnetic field continues.
b. Second law – The induced emf will be equal to the negative of the change in magnetic flux with time given as;
$emf=-\dfrac{d\phi }{dt}$
Where a negative sign indicates that electric circuits resist change in magnetic flux linked with it.
$\phi $ represents the magnetic flux.
2. Transformer is the device that raises and lowers the AC circuit voltage through mutual induction.
Mutual induction – Transformer is made up of two coils wound on the same core. When AC passes through one coil, it generates changing magnetic flux. This changing magnetic flux passes through the secondary coil and induces AC current there.
Note: When current flows through one coil it produces flux; the whole flux may not link with the other coil coupled, and this is because of leakage flux by a fraction (k) known as coefficient of coupling.
The value of coefficient of coupling (k) depends on the positions of the secondary coil with respect to the primary coil and k’s value varies from 0 to 1.
k = 1, when flux produced by the primary coil completely links with the secondary coil.
k = 0, when flux produced by the primary coil doesn’t link with the secondary coil.
Complete step-by-step answer:
A transformer is based on the principle of conservation of flux. That is the flux in the primary side of the transformer is linked to the secondary side. Since, the number of turns of coils on both the sides differ, different values of currents and voltages are transformed to the secondary side, which is the main use of the instrument. Please refer to the figure.

In the above question it is mentioned that 4% of the total flux generated doesn’t pass through the secondary coil. So, the value of magnetic flux linked with the second coil will be 96% of the primary side.
Magnetic flux linked with the first coil will be 100%.
Coefficient of coupling, k, is given by the following relation:
\[k=\dfrac{\text{Magnetic Flux linked with second coil}}{\text{Magnetic flux linked with first coil}}\]
We can put these values into the formula as;
$k=\dfrac{96%}{100%}=0.96$
Thus, the answer will be option D.
Additional point:
1. There are two Faraday’s law regarding electromagnetic induction
a. First law - Whenever there is a change in the magnetic flux linked with an electric circuit, an induced emf is produced in the circuit and will be produced as long as change in magnetic field continues.
b. Second law – The induced emf will be equal to the negative of the change in magnetic flux with time given as;
$emf=-\dfrac{d\phi }{dt}$
Where a negative sign indicates that electric circuits resist change in magnetic flux linked with it.
$\phi $ represents the magnetic flux.
2. Transformer is the device that raises and lowers the AC circuit voltage through mutual induction.
Mutual induction – Transformer is made up of two coils wound on the same core. When AC passes through one coil, it generates changing magnetic flux. This changing magnetic flux passes through the secondary coil and induces AC current there.
Note: When current flows through one coil it produces flux; the whole flux may not link with the other coil coupled, and this is because of leakage flux by a fraction (k) known as coefficient of coupling.
The value of coefficient of coupling (k) depends on the positions of the secondary coil with respect to the primary coil and k’s value varies from 0 to 1.
k = 1, when flux produced by the primary coil completely links with the secondary coil.
k = 0, when flux produced by the primary coil doesn’t link with the secondary coil.
Recently Updated Pages
JEE Main Participating Colleges 2024 - A Complete List of Top Colleges

JEE Main Maths Paper Pattern 2025 – Marking, Sections & Tips

Sign up for JEE Main 2025 Live Classes - Vedantu

JEE Main 2025 Helpline Numbers - Center Contact, Phone Number, Address

JEE Main Course 2025 - Important Updates and Details

JEE Main 2025 Session 2 Form Correction (Closed) – What Can Be Edited

Trending doubts
JEE Main 2025 Session 2: Application Form (Out), Exam Dates (Released), Eligibility, & More

JEE Main 2025: Derivation of Equation of Trajectory in Physics

JEE Main Exam Marking Scheme: Detailed Breakdown of Marks and Negative Marking

Learn About Angle Of Deviation In Prism: JEE Main Physics 2025

Electric Field Due to Uniformly Charged Ring for JEE Main 2025 - Formula and Derivation

JEE Main 2025: Conversion of Galvanometer Into Ammeter And Voltmeter in Physics

Other Pages
JEE Advanced Marks vs Ranks 2025: Understanding Category-wise Qualifying Marks and Previous Year Cut-offs

Degree of Dissociation and Its Formula With Solved Example for JEE

JEE Advanced Weightage 2025 Chapter-Wise for Physics, Maths and Chemistry

Physics Average Value and RMS Value JEE Main 2025

JEE Main Chemistry Question Paper with Answer Keys and Solutions

Atomic Structure - Electrons, Protons, Neutrons and Atomic Models

Students Also Read