Voltage and current
in a practical circuit
Because it takes energy to force electrons
to flow against the opposition of a resistance, there will
be voltage manifested (or "dropped") between any points in a
circuit with resistance between them. It is important to
note that although the amount of current (the quantity of
electrons moving past a given point every second) is uniform
in a simple circuit, the amount of voltage (potential energy
per unit charge) between different sets of points in a
single circuit may vary considerably:
Take this circuit as an example. If we label
four points in this circuit with the numbers 1, 2, 3, and 4,
we will find that the amount of current conducted through
the wire between points 1 and 2 is exactly the same as the
amount of current conducted through the lamp (between points
2 and 3). This same quantity of current passes through the
wire between points 3 and 4, and through the battery
(between points 1 and 4).
However, we will find the voltage appearing
between any two of these points to be directly proportional
to the resistance within the conductive path between those
two points, given that the amount of current along any part
of the circuit's path is the same (which, for this simple
circuit, it is). In a normal lamp circuit, the resistance of
a lamp will be much greater than the resistance of the
connecting wires, so we should expect to see a substantial
amount of voltage between points 2 and 3, with very little
between points 1 and 2, or between 3 and 4. The voltage
between points 1 and 4, of course, will be the full amount
of "force" offered by the battery, which will be only
slightly greater than the voltage across the lamp (between
points 2 and 3).
This, again, is analogous to the water
reservoir system:
Between points 2 and 3, where the falling
water is releasing energy at the water-wheel, there is a
difference of pressure between the two points, reflecting
the opposition to the flow of water through the water-wheel.
From point 1 to point 2, or from point 3 to point 4, where
water is flowing freely through reservoirs with little
opposition, there is little or no difference of pressure (no
potential energy). However, the rate of water flow in this
continuous system is the same everywhere (assuming the water
levels in both pond and reservoir are unchanging): through
the pump, through the water-wheel, and through all the
pipes. So it is with simple electric circuits: the rate of
electron flow is the same at every point in the circuit,
although voltages may differ between different sets of
points.
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