Capacitance Analogy: Thinking About Resistors Like Pipes

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Resistors can be effectively visualized as sections of pipe that restrict water flow, representing the slowing of electric current. While similar analogies can be drawn for capacitors, such as modeling them as reservoirs where the water level indicates voltage, these comparisons have limitations. Inductors present a more complex challenge due to their inherent inertia and induction effects, making straightforward analogies less applicable. The discussion emphasizes that while analogies can aid understanding, mastering the fundamental concepts of electricity is ultimately more beneficial. Overall, the use of water flow analogies can provide a basic grasp of electrical components but should be approached with caution.
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My Physics TA said that a good way to think about resistors is to also think about pipes:
the circuit is a pipe with water flowing thru it (water being charge) and a resistor acts like a section of pipe that is smaller than the rest... it slows down the current of charge and water.
using a similar situation, is there a similar way to think about capacitors?
just wondering :)
 
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Probably not. When dealing with capacitors and inductors you have fields involved, namely the electric and magnetic and energy is being stored. Then you have frequency responses. The analogy with the water and pipes is VERY rough. Once you "kind of" understand what is going on there. Move on and develop a stronger analog.
 
allergic said:
My Physics TA said that a good way to think about resistors is to also think about pipes:
the circuit is a pipe with water flowing thru it (water being charge) and a resistor acts like a section of pipe that is smaller than the rest... it slows down the current of charge and water.
using a similar situation, is there a similar way to think about capacitors?
just wondering :)

There is some way to see analogies (but as with all analogies, they are limited).
Voltage can be modeled by the height of the water level (pressure), and current can be modeled by the flow of water. A resistor can indeed be modeled with a pipe (except that the pressure difference over a pipe usually goes as square of the flux (current) and not proportional to it...). A capacitor can be modeled as a reservoir. A big capacitor is a reservoir with big cross section, and a small capacitor as a reservoir with small cross section. The charge is the amount of water in the capacitor (the higher the water column, the higher the voltage and the charge for a given cross section).

Inductors are more difficult. There is an intrinsic "induction effect" due to the inertia of the motion of the water. But it is hard to see how to "increase" the self induction, except with a pump and a flywheel. Transformers could be modeled by pumps connected together mechanically. I even had a professor who had modeled a "water transistor" :-)

The problem is that this becomes so involved that it is in fact easier to master the original concepts in electricity :smile:

cheers,
Patrick.
 

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