Advertisements
Advertisements
प्रश्न
Define self-inductance of a coil. Show that magnetic energy required to build up the current I in a coil of self inductance L is given by `1/2 LI^2`
उत्तर
Self inductance is the inherent inductance of a circuit, given by the ratio of the electromotive force produced in the circuit by self-induction to the rate of change of current producing it. It is also called coefficient of self-induction.
Self-inductance is also called the inertia of electricity.
Suppose I = Current flowing in the coil at any time
Φ = Amount of magnetic flux linked
It is found that Φ ∝ I
`phi = LI`
Where,
L is the constant of proportionality and is called coefficient of self induction
SI unit of self-inductance is Henry.
Let at t = 0 the current in the inductor is zero. So at any instant t later, the current in the inductor is I and rate of growth of I is dI/dt.
Then, the induced emf is e = L×dI / dt
If the source is sending a constant current I through the inductor for a small time dt, then small amount of work done by the source is given by
dW = eI dt =(LdI/dt)I dt = LIdI
The total amount of work done by the source of e.m.f., till the current increases from its initial value I = 0 to its final value I is given by
`W =int_0^1LIdI = Lint_0^1IdI =L|I^2/2|_0^1 `
This work done by the source of emf is used in building up current from zero to I0 is stored in the inductor in energy form. Therefore, energy stored in the inductor is
`U = 1/2 LI^2`
APPEARS IN
संबंधित प्रश्न
A toroidal solenoid with air core has an average radius of 15 cm, area of cross-section 12 cm2 and has 1200 turns. Calculate the self-inductance of the toroid. Assume the field to be uniform across the cross-section of the toroid.
Derive the expression for the self-inductance of a long solenoid of cross sectional area A and length l, having n turns per unit length.
A long wire carries a current of 4.00 A. Find the energy stored in the magnetic field inside a volume of 1.00 mm3 at a distance of 10.0 cm from the wire.
Explain why the inductance of two coils connected in parallel is less than the inductance of either coil.
Consider a solenoid carrying supplied by a source with a constant emf containing iron core inside it. When the core is pulled out of the solenoid, the change in current will ______.
A graph of magnetic flux `phi` versus current (I) is shown for four inductors A, B, C, D. Smaller value of self inductance is for inductor ____________.
A resistance of 100 `Omega`, inductor of self-inductance`(4/pi^2)` H and a capacitor of unknown capacitance are connected in series to an a.c. source of 200 V and 50 Hz. When the current and voltage are in phase, the capacitance and power dissipated is respectively ____________.
A graph of magnetic flux `(phi)` versus current (I) is shown for four inductors A, B, C and D. Larger value of self-inductance is for inductor ____________.
Calculate the self-inductance of a coil using the following data obtained when an AC source of frequency `(200/pi)` Hz and a DC source are applied across the coil.
| AC Source | ||
| S.No. | V (volts) | I (A) |
| 1 | 3.0 | 0.5 |
| 2 | 6.0 | 1.0 |
| 3 | 9.0 | 1.5 |
| DC Source | ||
| S.No. | V (volts) | I (A) |
| 1 | 4.0 | 1.0 |
| 2 | 6.0 | 1.5 |
| 3 | 8.0 | 2.0 |
What is meant by magnetic coupling coefficient?
