Ammeter impact on
measured circuit
Just like voltmeters, ammeters tend to
influence the amount of current in the circuits they're
connected to. However, unlike the ideal voltmeter, the ideal
ammeter has zero internal resistance, so as to drop as
little voltage as possible as electrons flow through it.
Note that this ideal resistance value is exactly opposite as
that of a voltmeter. With voltmeters, we want as little
current to be drawn as possible from the circuit under test.
With ammeters, we want as little voltage to be dropped as
possible while conducting current.
Here is an extreme example of an ammeter's
effect upon a circuit:
With the ammeter disconnected from this
circuit, the current through the 3 Ω resistor would be 666.7
mA, and the current through the 1.5 Ω resistor would be 1.33
amps. If the ammeter had an internal resistance of 1/2 Ω,
and it were inserted into one of the branches of this
circuit, though, its resistance would seriously affect the
measured branch current:
Having effectively increased the left branch
resistance from 3 Ω to 3.5 Ω, the ammeter will read 571.43
mA instead of 666.7 mA. Placing the same ammeter in the
right branch would affect the current to an even greater
extent:
Now the right branch current is 1 amp
instead of 1.333 amps, due to the increase in resistance
created by the addition of the ammeter into the current
path.
When using standard ammeters that connect in
series with the circuit being measured, it might not be
practical or possible to redesign the meter for a lower
input (lead-to-lead) resistance. However, if we were
selecting a value of shunt resistor to place in the circuit
for a current measurement based on voltage drop, and we had
our choice of a wide range of resistances, it would be best
to choose the lowest practical resistance for the
application. Any more resistance than necessary and the
shunt may impact the circuit adversely by adding excessive
resistance in the current path.
One ingenious way to reduce the impact that
a current-measuring device has on a circuit is to use the
circuit wire as part of the ammeter movement itself. All
current-carrying wires produce a magnetic field, the
strength of which is in direct proportion to the strength of
the current. By building an instrument that measures the
strength of that magnetic field, a no-contact ammeter can be
produced. Such a meter is able to measure the current
through a conductor without even having to make physical
contact with the circuit, much less break continuity or
insert additional resistance.
Ammeters of this design are made, and are
called "clamp-on" meters because they have "jaws"
which can be opened and then secured around a circuit wire.
Clamp-on ammeters make for quick and safe current
measurements, especially on high-power industrial circuits.
Because the circuit under test has had no additional
resistance inserted into it by a clamp-on meter, there is no
error induced in taking a current measurement.
The actual movement mechanism of a clamp-on
ammeter is much the same as for an iron-vane instrument,
except that there is no internal wire coil to generate the
magnetic field. More modern designs of clamp-on ammeters
utilize a small magnetic field detector device called a
Hall-effect sensor to accurately determine field
strength. Some clamp-on meters contain electronic amplifier
circuitry to generate a small voltage proportional to the
current in the wire between the jaws, that small voltage
connected to a voltmeter for convenient readout by a
technician. Thus, a clamp-on unit can be an accessory device
to a voltmeter, for current measurement.
A less accurate type of
magnetic-field-sensing ammeter than the clamp-on style is
shown in the following photograph:
The operating principle for this ammeter is
identical to the clamp-on style of meter: the circular
magnetic field surrounding a current-carrying conductor
deflects the meter's needle, producing an indication on the
scale. Note how there are two current scales on this
particular meter: +/- 75 amps and +/- 400 amps. These two
measurement scales correspond to the two sets of notches on
the back of the meter. Depending on which set of notches the
current-carrying conductor is laid in, a given strength of
magnetic field will have a different amount of effect on the
needle. In effect, the two different positions of the
conductor relative to the movement act as two different
range resistors in a direct-connection style of ammeter.
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REVIEW:
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An ideal ammeter has zero resistance.
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A "clamp-on" ammeter measures current
through a wire by measuring the strength of the magnetic
field around it rather than by becoming part of the
circuit, making it an ideal ammeter.
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Clamp-on meters make for quick and safe
current measurements, because there is no conductive
contact between the meter and the circuit.
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