21. (i) With the help of an activity, explain the method of inducing electric current in a coil with a moving magnet.
State the rule used to find the direction of electric current thus generated in the coil. 5
(ii) Two circular coils-1 and coil-2 are kept close to each other as shown in the diagram.Coil-1 is connected to a battery
and key and coil-2with a galvanometer. State your observation in the galvanometer:
(a) When key k closed ; (b) when key k is opened;
Give reason for your observations.
Answers
Take a coil of wire AB having a large number of turns.
image
Connect the ends of the coil to a galvanometer.
Take a strong bar magnet and move its north pole towards the end B of the coil.
There is a momentary deflection in the needle of the galvanometer, say to the right. This indicates the presence of a current in the coil AB. The deflection becomes zero the moment the motion of the magnet stops.
Now withdraw the north pole of the magnet away from the coil. Now the galvanometer is deflected toward the left, showing that the current is now set up in the direction opposite to the first.
Place the magnet stationary at a point near to the coil, keeping its rforth pole towards the end B of the coil. We see that the galvanometer needle deflects toward the right when the coil is moved towards the north pole of the magnet. Similarly, the needle moves toward left when the coil is moved away.
When the coil is kept stationary with respect to the magnet, the deflection of the galvanometer drops to zero.
To find the direction of electric current Fleming’s right hand rule is applied. According to it, if we stretch the forefinger, middle finger and thumb of our right hand mutually perpendicular in such a way that thumb points along the direction of motion of conductor, forefinger along the direction of magnetic field; then the middle finger points along the direction of induced current
(ii) When key is closed galvanometer will show a momentary deflection due to produce of induced current due to change in magnetic field lines.
And when key is opened again a momentary deflection will be seen but at opposite direction due to again a change in magnetic fields..
Answer:
Take a coil of wire AB having a large number of turns.
image
Connect the ends of the coil to a galvanometer.
Take a strong bar magnet and move its north pole towards the end B of the coil.
There is a momentary deflection in the needle of the galvanometer, say to the right. This indicates the presence of a current in the coil AB. The deflection becomes zero the moment the motion of the magnet stops.
Now withdraw the north pole of the magnet away from the coil. Now the galvanometer is deflected toward the left, showing that the current is now set up in the direction opposite to the first.
Place the magnet stationary at a point near to the coil, keeping its rforth pole towards the end B of the coil. We see that the galvanometer needle deflects toward the right when the coil is moved towards the north pole of the magnet. Similarly, the needle moves toward left when the coil is moved away.
When the coil is kept stationary with respect to the magnet, the deflection of the galvanometer drops to zero.
To find the direction of electric current Fleming’s right hand rule is applied. According to it, if we stretch the forefinger, middle finger and thumb of our right hand mutually perpendicular in such a way that thumb points along the direction of motion of conductor, forefinger along the direction of magnetic field; then the middle finger points along the direction of induced current
(ii) When key is closed galvanometer will show a momentary deflection due to produce of induced current due to change in magnetic field lines.
And when key is opened again a momentary deflection will be seen but at opposite direction due to again a change in magnetic fields..
(i) Activity:
(a) Take a coil of wire AB having a large number of turns.
(b) Connect the ends of the coil to a galvanometer
(c) Take a strong bar magnet and move its north pole towards the end B of the coil.
(d) There is a momentary deflection in the needle of the galvanometer, say to the right. This indicates the presence of a current in the coil AB. The deflection becomes zero the moment the motion of the magnet stops.
(e) Now withdraw the north pole of the magnet away from the coil. Now the galvanometer is deflected toward the left, showing that the current is now set up in the direction opposite to the first.
(f) Place the magnet stationary at a point near to the coil, keeping its north pole towards the end B of the coil. We see that the galvanometer needle deflects toward the right when the coil is moved towards the north pole of the magnet. Similarly, the needle moves toward left when the coil is moved away. When the coil is kept stationary with respect to the magnet, the deflection of the galvanometer drops to zero. To find the direction of electric current Fleming's right hand rule is applied. According to it, if we stretch the forefinger, middle finger and thumb of our right hand mutually perpendicular in such a way that thumb points along the direction of motion of conductor, forefinger along the direction of magnetic field; then the middle finger points along the direction of induced current.
(ii) (a) When current in P is changed, the field associated with Q will vary causing an induced current in Q.
(b) If both the coils are moved in the same direction with same speed, there will not be any change in the field associated with Q. Hence no current will be induced in Q.
ty how it was helpful
mark me as the brainlist plz -..-