-
Looking for HSC notes and resources? Check out our Notes & Resources page
2018 HSC Q20 (1 Viewer)
- Thread starter askit
- Start date
liamkk112
Well-Known Member
- Joined
- Mar 26, 2022
- Messages
- 948
- Gender
- Female
- HSC
- 2023
firstly, a galvanometer measures current, so the pointer will deflect in the direction of current.
now, when X rotates, there is relative motion between the magnet inside the galvanometer and the conductive wire, so by faraday's law there will be some induced current in the circuit. according to the diagram and by lenz's law, the anticlockwise rotation of galvanometer X means that we would like to push the galvanometer back in the other direction, using induced currents. using right hand rule, we can thus see that the current induced would need to be from the positive terminal of X to the negative of Y. hence, the current will flow from negative to positive in Y; this would mean that the pointer is deflected towards the left. so, C and D are the only remaining options.
now a motor is just something that converts electrical energy to mechanical energy. in essence this is what's happening; the current through Y is being converted to kinetic energy to oppose the motion of X. this is kind of confusing on purpose, because it seems like Y is acting like a generator, converting the kinetic energy of X into some current; however, it is X that is the generator, as the kinetic energy of the rotation is turned into the current through induction, and then Y converts this current back into kinetic energy through opposing the motion of X.
now, when X rotates, there is relative motion between the magnet inside the galvanometer and the conductive wire, so by faraday's law there will be some induced current in the circuit. according to the diagram and by lenz's law, the anticlockwise rotation of galvanometer X means that we would like to push the galvanometer back in the other direction, using induced currents. using right hand rule, we can thus see that the current induced would need to be from the positive terminal of X to the negative of Y. hence, the current will flow from negative to positive in Y; this would mean that the pointer is deflected towards the left. so, C and D are the only remaining options.
now a motor is just something that converts electrical energy to mechanical energy. in essence this is what's happening; the current through Y is being converted to kinetic energy to oppose the motion of X. this is kind of confusing on purpose, because it seems like Y is acting like a generator, converting the kinetic energy of X into some current; however, it is X that is the generator, as the kinetic energy of the rotation is turned into the current through induction, and then Y converts this current back into kinetic energy through opposing the motion of X.
heya sorry if I'm being really stupid rn but I'm not seeing this: using induced currents. using right hand rule, we can thus see that the current induced would need to be from the positive terminal of X to the negative of Y. hence, the current will flow from negative to positive in Y; this would mean that the pointer is deflected towards the left. so, C and D are the only remaining options.
Are we talking about the coiled wire inside the galvanometer?
liamkk112
Well-Known Member
- Joined
- Mar 26, 2022
- Messages
- 948
- Gender
- Female
- HSC
- 2023
yeah, if you like the wire connecting the two meters continues inside of the meters. fyi, galvanometers are out of syllabus, so you probably won't be asked something like this anymore (or at least, they probably won't assume that you know how a galvanometer works / what it is)
wizzkids
Active Member
- Joined
- Jul 13, 2016
- Messages
- 308
- Gender
- Undisclosed
- HSC
- 1998
The correct answer is (C).
Galvanometer 'X' is normally stationary. In normal operation if a positive potential is applied to the + terminal of a galvanometer the armature/needle deflects clockwise to the right (an application of the motor effect).
Now if instead the body of galvanometer 'X' is rotated anticlockwise, the armature, which is free to rotate but is suspended by clock-spring wires, is now behaving as a generator. When the magnet assembly (stator) rotates anticlockwise the armature rotates clockwise relative to the stator and a positive potential will appear at the + terminal of galvanometer 'X'. Hence the negative terminal of galvanometer 'Y' receives this positive potential and a current flows from right to left. Its armature/needle deflects anticlockwise to the left (an application of the motor effect).
So the needle of 'Y' rotates to the left, because a current has flowed from from right to left, which agrees with option (C).
I hope you can follow the logic.
Galvanometer 'X' is normally stationary. In normal operation if a positive potential is applied to the + terminal of a galvanometer the armature/needle deflects clockwise to the right (an application of the motor effect).
Now if instead the body of galvanometer 'X' is rotated anticlockwise, the armature, which is free to rotate but is suspended by clock-spring wires, is now behaving as a generator. When the magnet assembly (stator) rotates anticlockwise the armature rotates clockwise relative to the stator and a positive potential will appear at the + terminal of galvanometer 'X'. Hence the negative terminal of galvanometer 'Y' receives this positive potential and a current flows from right to left. Its armature/needle deflects anticlockwise to the left (an application of the motor effect).
So the needle of 'Y' rotates to the left, because a current has flowed from from right to left, which agrees with option (C).
I hope you can follow the logic.
Last edited: