KROHNE IFC 210 E-EEx EN User Manual
Page 88
Sect. 11 Part D Technical Data, Measuring Principle and Block Diagram
IFC 210 E
05/2002
88
11
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The flowmeter is designed for electrically conductive fluids.
Measurement is based on Faraday’s law of induction, according to which a voltage is induced in
an electrically conductive body which passes through a magnetic field. The following expression is
applicable to the voltage:
U = K
×
B
×
v
×
D
K an instrument constant
B magnetic field strength
v mean
velocity
D pipe
diameter
Inside the electromagnetic flowmeter, the fluid passes
through a magnetic field applied perpendicular to the
direction of flow. An electric voltage is induced by the
movement of the fluid (which must have a minimum
electrical conductivity). This is proportional to the mean
flow velocity and thus to the volume of flow. The
induced voltage signal is picked up by two electrodes
which are in conductive contact with the fluid and is
transmitted to a signal converter for a standardized
output signal.
This method of measurement offers the following advantages:
1) No pressure loss through pipe constriction or protruding parts.
2) Since the magnetic field passes through the entire flow area, the signal represents a mean
value over the pipe cross-section; therefore, only relatively short straight inlet pipes 5 x DN
from the electrode axis are required upstream of the primary head.
3) Only the pipe liner and the electrodes are in contact with the fluid.
4) Already the original signal produced is an electrical voltage which is an exact linear function
of the mean flow velocity.
5) Measurement is independent of the flow profile and other properties of the fluid.
The magnetic field of the primary head is generated by a square wave current fed from signal
converter to the field coils. This field current alternates between positive and negative values.
Alternate positive and negative flowrate-proportional signal voltages are generated at the same
frequency by the effect of the magnetic field, which is proportional to the current. The positive and
negative voltages at the primary head electrodes are subtracted from one another in the signal
converter. Subtraction always takes place when the field current has reached its stationary value,
so that constant interference voltages or external or fault voltages changing slowly in relation to
the measuring cycle are suppressed. Power line interference voltages coupled in the primary
head or in the connecting cables are similarly suppressed.