Where Does Lenz's Law Apply in an Automotive Setting?

AI Thread Summary
Lenz's Law explains the direction of induced current when a magnet moves through a coil, stating that the induced current will oppose the change in magnetic flux. In the discussed scenario, as a bar magnet falls through a coil, the induced current flows anti-clockwise towards the datalogger, indicating a reaction to the magnet's approach. This principle can be applied in automotive settings, such as in regenerative braking systems where the motion of the vehicle generates electricity to recharge the battery. Understanding Lenz's Law is crucial for optimizing energy recovery and efficiency in electric and hybrid vehicles. The discussion emphasizes the practical applications of this law in real-world automotive technology.
Masafi
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A bar magnet is dropped from rest through the centre of a coil of wire which is connected to a resistor and datalogger.

The resistor and datalogger are to the left in the diagram, and the coil on the right side.

Add an arrow to the wire to show the direction of the induced current as the magnet falls towards the coil.

The arrow is drawn going towards the datalogger side (left side) i.e. anti clockwise.

How is this worked out?
 
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First and foremost, the key is in what Lenz's Law states.
Ponder over what Lenz's law says - and try to apply it to the situation here.
 
Fightfish said:
First and foremost, the key is in what Lenz's Law states.
Ponder over what Lenz's law says - and try to apply it to the situation here.

So a current is induced upwards, and that goes anti clockwise?
 
Is anyone able to tell me were lenz's law would occur in an automotive situation
 
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