Why does current decay in an RL circuit?

In summary, the decay of current in an RL circuit can be explained by the interaction between induced voltages and currents, as well as the principles of Ohm's Law, Faraday's Law of Induction, and Lenz's Law. The rate of decay is determined by the resistance and inductance in the circuit, with smaller inductance resulting in a faster decay of current.
  • #1
suhasm
11
0
I fully understand mathematically using differential equations and also using conservation of energy why current should decay in an RL circuit.
However , I cannot comprehend how this phenomenon can be explained purely based on induced voltages and currents. An intuitive understanding basically.
Can anyone help me out?
 
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  • #2
I'll try to provide a conceptual explanation, based on induced voltages.

If there is a nonzero current, then by Ohm's Law there is a nonzero voltage (due to the resistor).

Since there is a nonzero voltage, then by Faraday's law of induction the magnetic flux through the inductor must be changing.

The magnetic flux through the inductor is produced by the current. So a changing flux goes hand-in-hand with a changing current.

To figure out whether the current change causes an increase or decrease, use Lenz's Law and one of the right-hand-rules -- specifically, the one that tells you the direction of B for a given direction of current through the inductor loops.

Hope that helps.
 
  • #3
suhasm said:
I fully understand mathematically using differential equations and also using conservation of energy why current should decay in an RL circuit.
However , I cannot comprehend how this phenomenon can be explained purely based on induced voltages and currents. An intuitive understanding basically.
Can anyone help me out?
Current is merely the net flow of electrons through a material. If the material has resistance then we know that electrons are scattering off of the electrons which make up the conductor and thus loose speed in the process.
 
  • #4
We start with a certain amount of magnetic energy stored in the L. This is associated with a certain current flowing.

So long as there is no resistance in the circuit then the current will flow forever because no energy is discharged. This is a superconductor situation.

Put a low resistance into the circuit and with the given current as a starting value then energy will discharge slowly into the resistance and we will see the current decay as the energy is transferred from the magnetic field of the L to heat in the resistor.

Put a high resistance into the circuit and with the given starting current there will be higher loss rates in the resistor. There is still the same amount of energy in the L to start with so because the higher resistive load consumes it faster the current decays faster.
 
  • #5
an intuitive explanation: There is some initial current. What the system wants to do, is to dissipate all the energy straight away in the resistor (bringing the current swiftly to zero). But the inductor doesn't like a sudden change in the current. So the inductor only let's the current go down gradually (as an exponential).

And the typical timescale for the decay is given by the inductance, divided by resistance. So in the limit of very small inductance, we get what we expect - the current goes to zero very rapidly, so that we would hardly see the curve, it would look almost like a step function. (Well, the exponential tail never really disappears, but you know what I mean, it looks more like a step function, for systems with smaller inductance).

Edit: well, the shape of the decay function is always the same. But the timescale depends on the inductance, so if you had a circuit with inductance much smaller than resistance, then you would need to have a better 'time resolution' to be able to see the curve before it gets very close to zero.
 

1. Why does current decay in an RL circuit?

The current in an RL (resistor-inductor) circuit decays over time because of the presence of inductance. Inductance is the property of a circuit element that resists changes in current. When the circuit is turned on, the inductor initially resists the change in current and causes a back EMF (electromotive force) that counteracts the applied voltage. As the current continues to flow, the back EMF gradually decreases, allowing more current to pass through the circuit. This process continues until the current reaches its steady-state value, causing the current to decay over time.

2. How does the inductor affect current decay in an RL circuit?

The inductor is the key component that causes current decay in an RL circuit. As mentioned before, inductance is the property of a circuit element that resists changes in current. In an RL circuit, the inductor initially resists the change in current and creates a back EMF that opposes the applied voltage. This back EMF gradually decreases, allowing more current to flow through the circuit. The inductor essentially acts as a buffer, slowing down the rise and decay of current in the circuit.

3. What factors affect the rate of current decay in an RL circuit?

The rate of current decay in an RL circuit is affected by several factors, including the inductance of the inductor, the resistance of the circuit, and the applied voltage. The higher the inductance, the slower the rate of decay. The higher the resistance, the faster the rate of decay. And the higher the applied voltage, the faster the rate of decay. Additionally, the type of inductor used and the frequency of the applied voltage can also affect the rate of current decay.

4. How does the time constant of an RL circuit affect current decay?

The time constant of an RL circuit is a measure of how quickly the current in the circuit decays. It is calculated by multiplying the inductance and resistance values of the circuit. A higher time constant means that the current will take longer to reach its steady-state value and will decay slower. Conversely, a lower time constant means that the current will reach its steady-state value faster and will decay faster.

5. Can the current in an RL circuit ever reach zero?

Technically, the current in an RL circuit will never reach zero, but it will approach zero over time. This is because there will always be a small amount of inductance present, which will always cause some resistance to changes in current. However, in practical terms, the current can be considered zero once it reaches a very small value that is negligible for most applications.

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