Abstrict An electromagnetic flow meter comprising a circuit for generating
signals proportional to the intensity of an A.C. magnetic field
impressed on a fluid running through a pipe; a first switch rendered
conducting for a prescribed period simultaneously with an A.C. voltage
obtained in proportional to the period of the A.C. magnetic field;
a second switch actuated after the conduction of the first switch;
a circuit for integrating outputs corresponding to the flow rate
of a fluid obtained through the first switch and further integrating
said outputs with an opposite polarity; a circuit for rendering
the second switch nonconducting when an output from said integration
circuit reaches a referential level; and a circuit for generating
an output corresponding to the period in which said outputs are
integrated, for each operating cycle of said integration circuit.
Claims What is claimed is:
1. An electromagnetic flow meter comprising a pipe for conducting
a fluid; a magnetic flux generator for applying an A.C. magnetic
flux to a fluid traveling through the pipe; a detection circuit
fitted to the pipe so as to generate a detection signal proportional
to a product arrived at by multiplying together the inner diameter
of the pipe, the density of the A.C. magnetic flux and the running
speed of the fluid; a device for generating an A.C. voltage proportional
to the A.C. magnetic flux; a first switch supplied with the detection
signal; a first switch-controlling circuit for closing the first
switch for at least a positive or negative half period of the generated
A.C. voltage; an A.C.-D.C. converting circuit for converting said
A.C. voltage to a D.C. voltage; a second switch to which an output
from said A.C.-D.C. converting circuit is supplied with an opposite
polarity to the detection signal; an integration circuit for integrating
outputs from the first switch and thereafter integrating outputs
from the second switch; a second switch-controlling circuit for
closing the second switch after said positive or negative half period
and opening the second switch when an output from the integration
circuit reaches a referential level; and an output device for producing
an output indicating the flow rate of the fluid corresponding to
the period in which outputs from the A.C.-D.C. converting circuit
are integrated, for each operating cycle of said integration circuit.
2. An electromagnetic flow meter according to claim 1 wherein the
first switch-controlling circuit comprises a phase shifter for causing
the phase of an output from the A.C. voltage generator to coincide
with the phase of a detection signal; a comparator supplied with
an output from the phase shifter and designed to compare the level
of an output from the phase shifter with the referential level and
produce an output signal in synchronization with the detection signal;
and a first switch-driving circuit for closing the first switch
according to an output from the comparator.
3. An electromagnetic flow meter according to claim 2 wherein the
A.C.-D.C. converting circuit comprises a second switch-driving circuit
actuated by an output from the comparator; a third switch having
its operation controlled by an output from the second switch-driving
circuit and connected at one end to the output terminal of the A.C.
voltage generator; an amplifier for arithmetic operation whose negative
terminal is connected to the other end of the third switch and whose
positive terminal is grounded; an integration capacitor connected
between the input and output terminals of the arithmetic operation
amplifier; and a fourth switch connected parallel to the integration
capacitor and rendered conducting for a prescribed period after
the second switch is opened.
4. An electromagnetic flow meter according to claim 1 wherein the
A.C.-D.C. converting circuit includes a rectifying circuit consisting
of a diode connected at one end to the output terminal of the A.C.
voltage generator; a capacitor connected between the other end of
the diode and the ground; and a resistor connected between the other
end of the diode and the second switch.
5. An electromagnetic flow meter according to claim 1 wherein the
second switch-controlling circuit comprises a comparator whose positive
terminal is supplied with an output from the integration circuit
and whose negative terminal is grounded; a NAND gate, one input
terminal of which is supplied with an output from the comparator
and the other input terminal of which is supplied with an output
from the first switch-controlling circuit through a first inverter;
and a switch driving circuit supplied with an output from the NAND
gate through a second inverter and designed to deliver an output
to the second switch.
6. An electromagnetic flow meter according to claim 1 wherein the
output device consists of a third switch having its operation controlled
by an output from the second switch-controlling circuit; a power
source connected to one end of the third switch so as to supply
a direct current having a referential voltage; and a smoothing circuit
connected to the other end of the third switch, thereby producing
from the output terminal of the flow meter an analogue output corresponding
to the flow rate of a fluid passing through the pipe.
7. An electromagnetic flow meter according to claim 6 wherein the
output device comprises a fourth switch connected at one end between
the power source for supplying a direct current having a referential
voltage and the third switch and operated in synchronization with
the first switch; an operational amplifier whose negative terminal
is connected to the other end of the fourth switch whose positive
terminal is grounded and whose output terminal is connected to the
third switch; an integration capacitor connected between the input
and output terminals of the operational amplifier; and a fifth switch
connected parallel between both ends of the integration capacitor,
and closed for a prescribed period after the second switch is opened.
8. An electromagnetic flow meter according to claim 1 wherein the
output device comprises a clock pulse generator for generating clock
pulses; a NAND gate, one input terminal of which is supplied with
an output from the clock pulse generator and the other input terminal
of which is supplied with an output from the second switch-controlling
circuit; frequency dividing means supplied with an output from the
NAND gate and designed to divide the frequency of said output into
a prescribed number of components; and a counter for counting the
frequencies of outputs from the frequency dividing means.
9. An electromagnetic flow meter comprising a pipe for conducting
a fluid; an A.C. source; a magnetic flux generator connected to
the A.C. source to apply an A.C. magnetic flux to a fluid traveling
through the pipe; a detection circuit fitted to the pipe to generate
a detection signal proportional to a product arrived at by multiplying
together the inner diameter of the pipe, the density of the A.C.
magnetic flux and the running speed of the fluid; a transformer
connected to the A.C. source; a device connected to the secondary
winding of the transformer to generate an A.C. voltage in proportional
to the A.C. magnetic flux; a first switch supplied with the detection
signal; a second switch connected to the secondary winding of the
transformer; a first integration circuit connected to the first
switch; a second integration circuit connected to the second switch;
a third switch supplied with an output signal from the second integration
circuit; means for connecting the output terminal of the third switch
to the input terminal of the first integration circuit; a first
switch-controlling circuit for closing the first switch for half
the period of the A.C. voltage generated; a second switch-controlling
circuit for closing the third switch immediately after said half
period in which the first switch is closed; gate-signal generating
means for giving forth a gate signal for the period in which an
output signal from the first integration circuit reaches a prescribed
level after the closing of the third switch; a second gate circuit
opened upon receipt of the gate signal; a clock pulse generator
for supplying clock pulses to the first gate circuit; means for
impressing a D.C. voltage on the second gate circuit; and an output
device supplied with digital and analogue output signals denoting
the flow rate of a liquid from the output terminals of the first
and second gate circuits.
10. An electromagnetic flow meter according to claim 9 wherein
the output device comprises a NAND gate supplied with output signals
from the first inverter and delay circuit; a second inverter supplied
with an output signal from the NAND gate; a driver supplied with
an output signal from the second inverter; and means for holding
the sampled value of an output signal from the multiplier/divider
when supplied with an output signal from the driver.
11. An electromagnetic flow meter comprising a pipe for conducting
a fluid; a magnetic flux generator for applying an A.C. magnetic
flux to a fluid traveling through a pipe; a detection circuit fitted
to the pipe so as to generate a detection signal proportional to
a product arrived at by multiplying together the inner diameter
of the pipe, the density of the A.C. magnetic flux and the velocity
of the fluid running through the pipe; an A.C. voltage generator
for generating an A.C. voltage in synchronization with the A.C.
magnetic flux; a first switch supplied with the detection signal;
a second switch supplied with the A.C. voltage; a first switch-controlling
circuit for closing the first and second switches for at least a
positive or negative half period of the generated A.C. voltage;
first and second integration circuits for integrating outputs from
the first and second switches respectively; an inverter connected
to the output terminal of the first switch-controlling circuit;
a delay circuit connected to the output terminal of the inverter;
an integration-controlling circuit for zeroing integrated outputs
from the first and second integration circuits; a multiplier-divider
supplied with outputs x and y from the first and second integration
circuits and an output z from a power source for generating an output
having a referential voltage and designed to carry out the arithmetic
operation of said three outputs by the formula of x.sup.. z/y; and
an output device for producing an output indicating the flow rate
of the fluid passing through the pipe from an output from the multiplier-divider.
12. An electromagnetic flow meter according to claim 11 wherein
the sampled value-holding means comprises a switch whose operation
is controlled by an output signal from the driver and one terminal
of which is supplied with an output signal from the multiplier-divider;
an operational amplifier connected to the other terminal of said
switch and a capacitor connected between said other terminal of
the switch and the ground.
13. An electromagnetic flow meter comprising a pipe for conducting
a fluid; an A.C. source; a magnetic flux generator connected to
the A.C. source to apply an A.C. magnetic flux to a fluid traveling
through the pipe; a detection circuit fitted to the pipe to generate
a detection signal proportional to a product arrived at by multiplying
together the inner diameter of the pipe, the density of the A.C.
magnetic flux and the running speed of the fluid; a transformer
connected to the A.C. source; a device connected to the secondary
winding of the transformer to generate an A.C. voltage synchronous
with the A.C. magnetic flux; a first switch supplied with the detection
signal; a second switch connected to the secondary winding of the
transformer; a first integration circuit connected to the first
switch; a second integration circuit connected to the second switch;
a referential voltage source; a multiplier-divider supplied with
output signals X, Y from the first and second integration circuits
and an output signal Z from the referential voltage source to carry
out an arithmetic operation of (X/Y).sup.. Z; and a sampled value
holder for holding the sampled value of an output signal from the
multiplier-divider for at least half the period of the A.C. voltage.
Description This invention relates to an electromagnetic flow meter and more
particularly to improvements on an A.C. electromagnetic flow meter.
An A.C. electromagnetic flow meter is so designed as to apply an
A.C. magnetic flux to a fluid passing through a pipe and detecting
signals corresponding to the amount of said fluid running through
the pipe per unit time. In this case, however, an A.C. magnetic
flux applied to a fluid varies with the voltage of a power source,
giving rise to errors in measuring the flow rate of a fluid. To
eliminate such errors, it may be contemplated to connect, for example,
a transformer in series to a device for applying an A.C. magnetic
flux to a fluid to draw out an A.C. voltage proportional to said
A.C. magnetic flux and dividing a signal representing the flow rate
of the fluid by said A.C. voltage. This process can indeed save
a signal denoting said flow rate from the effect of fluctuation
in the voltage of a power source. However, additional provision
of such a division circuit for a flow meter unavoidably renders
the entire arrangement complicated and results in the high cost
of a flow meter device. Moreover, a noise signal of a phase shifted
90.degree. from that of a power source voltage caused by electromagnetic
coupling in the flow meter is included in the detecting signal in
addition to the signal proportional to flow rate. This 90.degree.-shifted
noise has an amplitude comparable with that of the source voltage
and constitutes a significant factor in generating errors of detection.
To avoid said 90.degree.-shifted noise, it may be contemplated to
rectify a detection signal using, for example, a synchronous rectifier.
However, this also leads to the complicated arrangement and high
cost of a flow meter as a whole. In addition, the circuit elements
included in the prior art A.C. electromagnetic flow meter whose
characteristics vary with ambient temperature also exert a very
disadvantageous effect on the precision with which the flow rate
of a fluid passing through a pipe should be determined.
It is accordingly the object of this invention to provide a high
precision electromagnetic flow meter capable of effectively eliminating
errors resulting from fluctuations in the voltage of a power source,
90.degree.-shifted noises and changes in ambient temperature by
means of a simple arrangement.
According to an aspect of this invention, there is provided an
electromagnetic flow meter which comprises a pipe for conducting
a fluid; a magnetic flux-generating device for applying an A.C.
magnetic flux to the fluid running through the pipe; a detection
circuit for detecting a signal denoting a product arrived at by
multiplying together the inner diameter of the pipe, the density
of said magnetic flux and the velocity of the fluid; a device for
generating an A.C. voltage in proportional to said A.C. magnetic
flux; a first switch supplied with said detection signal; a first
switch-controlling circuit for closing said switch for at least
a positive or negative half period of the A.C. voltage thus generated;
an A.C.-D.C. converting circuit for changing the A.C. voltage to
a D.C. voltage; a second switch supplied with an output from said
A.C.-D.C. converting circuit; means for reversing the polarity of
an output from the second switch from that of the detection signal;
an integration circuit for integrating outputs from the first switch
and then integrating outputs from the second switch; a second switch-controlling
circuit for closing the second switch after the positive or negative
half period and opening said second switch when the integrated outputs
reach a referential level; and an output device for producing an
output indicating the flow rate of a fluid corresponding to the
period in which outputs from the A.C.-D.C. converting circuit are
integrated, for each operating cycle of the integration circuit.
This invention can be more fully understood from the following
detailed description when taken in conjunction with the accompanying
drawings, in which:
FIG. 1 is a block circuit diagram of an A.C. flow meter according
to an embodiment of this invention;
FIG. 2 presents the wave forms of signals by way of illustrating
the operation of the flow meter of FIG. 1;
FIG. 3 is a block circuit diagram of a flow meter digitally indicating
an output denoting the flow rate of a fluid obtained by the invention;
FIG. 4 is a block circuit diagram of a flow meter according to
another embodiment of the invention;
FIG. 5 shows the wave forms of signals by way of illustrating the
operation of the flow meter of FIG. 4;
FIG. 6 is a block circuit diagram of a flow meter according to
still another embodiment of the invention;
FIG. 7 indicates the wave forms of signals by way of illustrating
the operation of the flow meter of FIG. 6;
FIG. 8 is a block circuit diagram of a further embodiment of the
invention;
FIG. 9 presents the wave forms of signals by way of illustrating
the operation of the flow meter of FIG. 8;
FIG. 10 is a block circuit diagram of still further embodiment
of the invention; and
FIG. 11 indicates the wave forms of signals by way of illustrating
the operation of the flow meter of FIG. 10.
Referring to FIG. 1 a pair of exciting coils 3a, 3b are provided
outside of a pipe 2 through which a conductive fluid 1 flows. The
exciting coils 3a, 3b are connected in series to an A.C. source
4. An A.C. magnetic flux generated by each of said exciting coils
3a, 3b is applied at right angles to the flow line of a fluid 1
traveling through the pipe 2. An electromotive force is produced
in the directions perpendicular to both the flow line of the fluid
1 and the A.C. magnetic flux applied to said fluid 1. A pair of
signal-detecting electrodes 5a, 5b are provided on the inner walls
of the pipe 2 to detect said electromotive force. A voltage detected
across said electrodes 5a, 5b has a magnitude proportional to the
flow rate of the fluid 1 passing through the pipe 2.
A detection signal appearing between the electrodes 5a, 5b is amplified
by an A.C. type differential amplifier 6 an output from which is
impressed through a resistor 7 on one of the electrodes of a first
switch 8 consisting of, for example, a field effect transistor (hereinafter
referred to as "an FET"). A signal supplied to the first
switch 8 is further conducted upon its closure to an arithmetic
operation amplifier 9 and also to the input terminal of an integration
circuit 11 consisting of a capacitor 10 connected between the input
and output terminals of said arithmetic operation amplifier 9.
The primary winding of a transformer 12 is connected in series
to the exciting coils 3a, 3b, and both ends of the secondary winding
of said transformer 12 are connected to a resistor 13. This arrangement
causes both ends of the resistor 13 to be impressed with an A.C.
voltage proportional to the magnitude of a magnetic flux applied
to the fluid 1 from the exciting coils 3a, 3b. One end of the resistor
13 is grounded and the other end thereof is connected to one end
of a phase shifter 16 consisting of a resistor 14 and capacitor
15 and also to one end of an A.C.-D.C. converting circuit 19 consisting
of a diode 17 and capacitor 18. An output from the phase shifter
16 is supplied to one positive input terminal of a comparator 21
included in a first switch-controlling circuit 20. Since the other
negative input terminal of the comparator 21 is grounded, an output
from the phase shifter 16 is conducted to a switch-driving circuit
22 and also to an inverter 24 of a second switch-controlling circuit
23 each time said output is brought to a negative level. The phase
shifter 16 is used to attain a coincidence between an output from
the A.C. type differential amplifier 6 namely, the phase of a signal
detecting the flow rate of a fluid and the phase of a signal supplied
to said one positive input terminal of the comparator 21. Accordingly,
an output from the switch-driving circuit 22 is supplied to the
first switch 8 namely, the gate electrode of the FET 8 as a switch-controlling
signal, each time the polarity of a detection signal is turned negative,
so as to close first switch 8. Therefore, the integration circuit
11 is supplied with a signal representing the negative half period
of the detection signal.
An output from the integration circuit 11 is delivered to one positive
input terminal of a comparator 25 the other negative input terminal
of which is grounded. Thus, the comparator generates an output,
when an output from the integration circuit 11 has a higher level
than zero. The output terminal of the comparator 25 is connected
to one input terminal of the NAND gate 26 of the second switch-controlling
circuit 23 the other input terminal of said NAND gate 26 being
supplied with an output from the inverter 24. An output from the
NAND gate 26 is delivered through an inverter 27 to the input terminal
of a switch-driving circuit 28. An output from the switch-driving
circuit 28 is supplied as a switch-controlling signal to the gate
electrode of an FET constituting a second switch 29 and also to
the gate electrode of an FET used as a third switch 30.
The second switch 29 is supplied through a resistor 31 with an
output from the A.C.-D.C. converting circuit 19. A D.C. signal of
negative polarity from said converting circuit 19 is further conducted
through the second switch 29 to the input terminal of the integration
circuit 11. Since the diode 17 has the indicated polarity, a detection
signal from the first switch 8 and a signal from the second switch
29 have opposite polarities. Therefore, the integration circuit
11 integrates outputs from the first switch 8 and those from the
second switch 29 in opposite directions by turns.
One electrode of the third switch 30 is connected to a terminal
33 impressed with a referential voltage E.sub.s and the other electrode
of said third switch 30 is connected to the input terminal of a
smoothing circuit 36. Referential numeral 37 denotes the output
terminal of the subject flow meter.
There will now be described by reference to FIG. 2 the operation
of an A.C. electromagnetic flow meter of FIG. 1. A detection signal
appearing between the signal-detecting electrodes 5a, 5b and supplied
to the first switch 8 through the amplifier 6 and resistor 7 has
a sine wave form shown in, for example, FIG. 2 (a). This detection
signal contains a noise component shifted 90.degree. in phase from
the detection signal as illustrated in FIG. 2 (b). Thus, a composite
signal consisting of said detection signal and noise presents a
wave form indicated in FIG. 2 (c). Namely, an input e to the A.C.
type differential amplifier 6 may be expressed by the following
formula: ##EQU1## where: B = density of a magnetic flux applied
to a fluid 1
D = inner diameter of a pipe 2
v = velocity of a fluid passing through the pipe 2
E.sub.n = amplitude of a noise shifted 90.degree. in phase
An output E.sub.1 amplified by the differential amplifier 6 is
the one where only portions represented by the constant terms D
and E.sub.n are amplified. With said constant terms D and E.sub.n
denoted by k.sub.1 and k.sub.2 respectively, the output E.sub.1
may be expressed as follows: ##EQU2##
Since an output M from the phase shifter 16 has the same phase
as the wave form of a detection signal shown in FIG. 2 (a), an output
from the comparator 21 also has the same phase as indicated in FIG.
2 (f), causing the first switch 8 to be rendered conducting and
nonconducting by turns as illustrated in FIG. 2 (d). Namely, the
FET 8 is turned on only when the signal E.sub.1 has a negative level
and turned off only when said signal E.sub.1 has a positive level.
Thus a detection signal continues to be supplied to the integration
circuit 11 through the first switch 8 while the phase of FIG. 2
(a) is shifted, for example, from 0 to .pi.. As apparent from FIG.
2 (a), the detection signals have a negative level for a period
from 0 to .pi. and are effectively integrated by the integration
circuit 11. Since, however, the 90.degree.-shifted noise has a negative
level for a period from 0 to .pi./2 and a positive level for a period
from .pi./2 to .pi., the result of integration carried out for a
period from 0 to .pi. has a value of zero. This means that the 90.degree.-shifted
noise is effectively suppressed by the integration circuit 11. An
output E.sub.2 from the integration circuit 11 may therefore be
expressed by the following equation: ##EQU3## where: CR = time constant
of integration undertaken by the integration circuit 11
T = a period from 0 to .pi.
Thus, the integration circuit 11 continues to integrate outputs
from the first switch 8 in the positive direction as shown in FIG.
2 (g). Since, at this time, a signal supplied to one input terminal
of the comparator 25 has a zero level, an output from the comparator
25 is brought to a state indicated by a logical code 1 when an
output from the integration circuit 11 turns positive. This output
of 1 has a wave form indicated in FIG. 2 (e). Where, under this
condition, an output M from the phase shifter 16 has its level reduced
to zero, the first switch 8 is rendered nonconducting and an output
from the comparator 21 is brought to the state of a logical code
0. Said output of 0 is inverted to a signal of 1 (FIG. 2 (f)) by
the inverter 24. This inverted output of 1 from the inverter 24
is supplied to the NAND gate 26 together with an output of 1 from
the comparator 25. The NAND gate 26 delivers an output of 0 to the
inverter 27 which in turn supplies an output of 1 to the switch-driving
circuit 28. Upon receipt of an input of 1 the switch-driving circuit
28 sends a switch-driving signal to the second and third switches
29 30 so as to close them. At the point of time .pi., an output
E.sub. 3 from the A.C.-D.C. converting circuit 19 bearing the wave
form of FIG. 2 (h) is supplied to the integration circuit 11 through
the second switch 29 and inverter 32. An output from the integration
circuit 11 is linearly attenuated, as shown in FIG. 2 (g), in the
negative direction down to a zero level during a period of T1. Where
an output from the integration circuit 11 has its level reduced
to zero, then an output from the comparator is brought to the state
of 0 as indicated in FIG. 2 (e). On the other hand, an output from
the inverter 24 maintains the state of 1 as shown in FIG. 2 (f).
Consequently, an output from the NAND gate 26 is changed to 1 indicated
in FIG. 2 (h), causing the switch-driving circuit 28 to be reset
by a 0 output from the inverter 27 and the second and third switches
to be turned off. FIG. 2 (i) presents the wave form of a signal
obtained on the output side of the third switch 30.
To explain the above-mentioned operation by means of equations,
an output E.sub.3 from the A.C.-D.C. converting circuit 19 bears
a proportion only to exciting current or the density B of a magnetic
flux. With k.sub.3 taken to be a constant, therefore, said output
E.sub.3 may be expressed as follows:
now let T.sub.1 of FIG. 2 (g) represent the period required for
an output E.sub.2 from the integration circuit 11 to have its level
reduced to zero after the second switch 29 is closed at the point
of time .pi.. Then the following equation results: ##EQU4## Therefore,
the following equation is derived from the equations (3), (4) and
(5):
where k.sub.4 is a constant. As apparent from the above equation
(6), T.sub.1 is unrelated to the density B of a magnetic flux. Since
T is constant, T.sub.1 denotes a value only proportional to the
velocity v of the fluid 1 running through the pipe 2. Therefore,
the ratio of T.sub.1 to T always maintains a value only proportional
to the velocity v of the fluid 1.
Since the third switch 30 is rendered conducting for the same period
of T.sub.1 (FIG. 2 (i)) as the second switch 29 a D.C. voltage
obtained from the output terminal 37 of the flow meter by smoothing
the referential voltage E.sub.s in the smoothing circiut 36 also
bears proportion only to the velocity v of the fluid 1 thereby
providing an analogue signal representing the accurate flow rate
of the fluid 1 free from the 90.degree. shifted noise and variations
in the density B of a magnetic flux. Since the aforesaid equation
(6) does not include the constants C and R associated with the elements
of the integration circuit 11 it is possible to avoid errors in
measuring the flow rate of a fluid 1 which might otherwise arise
from a characteristic variations of the contents C and R and of
amplifiers, etc. caused by the variations of the ambient temperature
and secular change.
Since, as mentioned above, the flow meter of this invention indicates
its output essentially in the form of time T or time ratio T.sub.1
/T, said flow meter can show the flow rate of a fluid 1 not only
in the form of an analogue output using a smoothing circuit 36 as
in the embodiment of FIG. 1 but also in the form of a digital output.
FIG. 3 is a block circuit diagram of the flow meter of this invention
which can indicate the flow rate of a fluid in the form of a digital
output. According to this arrangement, an output, for example, from
the switch-driving circuit 28 of FIG. 1 is supplied to a NAND gate
41 together with a clock pulse generated by a clock pulse generator
40. Namely, an output from the switch-driving circuit 28 is used
as a gate signal and clock pulses having a number corresponding
to a period of T.sub.1 are divided in frequency by a frequency divider
42. Thereafter, the frequency divided clock pulses are supplied
to a proper counter 43. Thus, the flow rate of a fluid 1 can be
easily indicated by digital signals. The accumulated value of the
output pulses is proportional to the accumulated amount of fluid
flowing in the flow meter.
Further, if the switch-driving circuit 28 and switch 30 of FIG.
1 are connected, though not shown, by a known photocoupler consisting
of, for example, a light emitting diode and phototransistor, then
electric insulation can be effected between the flow meter and an
output indicator. This arrangement offers the advantage of preventing
errors in measuring the flow rate of a fluid, particularly in case
the flow meter and output indicator are remotely separated from
each other.
Since the time-constant of the A.C.-D.C. converting circuit 19
of FIG. 1 is very large, one cannot obtain the output voltage of
the circuit 19 in proportion to the voltage of the power supply
in case of a rapid variation of the power supply voltage. This causes
an error in measuring the flow rate of the fluid.
FIG. 4 shows a circuit arrangement of a flow meter according to
another embodiment of this invention which has been improved from
the flow meter of FIG. 1 to elevate the precision of measurement
in view of the above drawbacks of Embodiment of FIG. 1. The parts
of FIG. 4 which are the same as those of FIG. 1 are denoted by the
same numerals and description thereof is omitted. Now let it be
assumed that an output from the differential amplifier 6 is a sine
wave signal bearing the phase of FIG. 5 (a). Then, an output from
the comparator 21 is a positive pulse having, as shown in FIG. 5
(b), a width corresponding to the negative period of an output from
the differential amplifier 6. This positive pulse is supplied from
the comparator 21 to the switch-driving circuits 22a, 22b, inverter
50 and a switch-driving circuit 51 at the same time. An output from
the inverter 50 takes the form of a pulse signal shown in FIG. 5
(c) which is of the opposite polarity to an output from the comparator
21.
Where a switch-driving signal is supplied from the comparator 21
to the switch-driving circuit 22a, then the first switch 8 is closed.
As the result, outputs from the differential amplifier 6 are supplied
to the integrator 11 for integration for a period, for example,
from 0 to .pi.. Thus an output from the integrator 11 increases
as shown in FIG. 5 (d) for a period from 0 to .pi..
On the other hand, the output terminal of the phase shifter 16
is connected through a resistor 52 and FET switch 53 to the negative
side terminal of an operational amplifier 54 constituting the A.C.-D.C.
converting circuit 19 causing the switch-driving circuit 22b to
be operated by an output from the comparator 21 for a period from
0 to .pi.. As the result, the FET switch 53 is closed and an output
from the phase shifter 16 is conducted to the operational amplifier
54. Accordingly, the comparator 54 generates an output progressively
increasing from the point of time 0 to the point of time .pi. as
shown in FIG. 5 (e). This increased output is delivered to the second
switch 29 through the resistor 31. A capacitor 55 and FET switch
56 are connected parallel between the input and output terminals
of the operational amplifier 54. The FET 56 has its operation controlled
by a signal from the switch-driving circuit 57.
An output from the integration circuit 11 is supplied to the comparator
25 which in turn produces an output having a fixed amplitude as
shown in FIG. 5 (f) which increases according to an output from
the integration circuit 11 bearing the wave form indicated in FIG.
5 (d). Said output from the comparator 25 is conducted to the NAND
gate 26 together with an output from the inverter 50 having the
wave form of FIG. 5 (c). The NAND gate 26 is supplied with two input
signals indicated by logical codes of 1 and 0 for a period from
0 to .pi.. Accordingly, an output from the NAND gate 26 takes the
form of 1 and an output from the inverter 27 maintains the form
of 0 as shown in FIG. 5 (g) for a period from 0 to .pi.. An output
from the NAND gate 26 is delivered to the NAND gate 58 together
with a signal supplied to one input terminal of said NAND gate 26.
Since input signals to the NAND gate 58 maintain the forms of 0
and 1 respectively for a period from 0 to .pi., an output from the
NAND gate 58 is brought to the state of 1. Therefore, an output
from the inverter 59 presents the state of 0 as shown in FIG. 5
(h). Since said output from the inverter 59 is delivered to the
switch-driving circuit 57 the FET switch 56 remains open for a
period from 0 to .pi., causing an output from the operational amplifier
54 to be charged in the capacitor 55.
Further, the switch-driving circuit 51 is operated by an output
from the comparator 21 for a period from 0 to .pi.. Accordingly,
an FET switch 60 is closed and the referential voltage E.sub.s is
impressed on the negative side input terminal of an integration
circuit 61.
Since a driving signal is not supplied from the inverter 59 to
a switch-driving circuit 62 an FET switch 63 is opened and the
integration circuit 61 integrates E.sub. s signals supplied from
the FET switch 60 and produces an output progressively increasing
from the point of time 0 to the point of time .pi. as shown in FIG.
5 (i). An output from the integration circuit 61 is delivered to
the FET switch 30 but the switch-driving circuit 28b is not supplied
with a driving signal. Therefore, the output terminal 37 of the
flow meter does not generate an output. Since a signal supplied
to one input terminal of the NAND gate 41 remains in the state of
0 said gate 41 is not opened, nor a digital output terminal 64
is supplied with a clock pulse from the clock pulse generator 40.
During a period from 0 to .pi., a 90.degree.-shifted noise contained
in an output from the differential amplifier 6 is of course effectively
suppressed in the integration circuit 11 as in the case of FIG.
1.
When an output from the differential amplifier 6 has its phase
shifted to .pi., an output from the comparator 21 has its level
brought to zero in synchronization with said output from the differential
amplifier 6. As the result, the FET switches 8 53 60 are opened
through the switch-driving circuits 22a, 22b, 51 causing an output
from the inverter 50 to take the form of 1 as shown in FIG. 5 (c)
for a period from .pi. to 2.pi.. A 1 output from the inverter 50
is conducted to the NAND gate 26. Since, at this time, an output
from the comparator 25 maintains the form of 1 as indicated in FIG.
5 (f), an output from the NAND gate 26 is brought to the state of
0 causing the switch-driving circuit 28a to be actuated by a 1
output from the inverter 27. The FET switch 29 is closed by an output
from the switch-driving circuit 28a and the integration circuit
54 delivers an output bearing the wave form of FIG. 5 (e) to the
integration circuit 11. An output from the integration circuit 19
has an opposite polarity to an output from the differential amplifier
6. Therefore, the integration circuit 11 carries out integration
in the opposite direction starting from the point of time .pi..
An output from said integration circuit 11 is linearly attenuated
from the point of time .pi. as shown in FIG. 5 (d) and falls to
a zero level after a period of T.sub.1.
Since, during the period of T.sub.1 an output from the inverter
27 takes the form of 1 as shown in FIG. 5 (g), and an output from
the inverter 59 is brought to the state of 0 as indicated in FIG.
5 (h), an output from the integrator 61 still maintains a value
attained at the point of time .pi. through the opening of the switch
63 namely, presents the wave form of FIG. 5 (i). the switch-driving
circuit 28b is actuated to close the switch 30 and an output bearing
the wave form of FIG. 5 (j) appears on the output side of said switch
30. At this time, a 1 output from the inverter 27 opens the NAND
gate 41 causing clock pulses from the clock pulse generator 40
as shown in FIG. 5 (k) to appear at the digital output terminal
64 of the flow meter. When, therefore, clock pulses appearing at
said digital output terminal 64 are counted as in the case of FIG.
3 then the flow rate of a fluid can be digitally indicated.
Where an output from the integration circuit 11 falls to zero in
a period of T.sub.1 after the point of time .pi., then an output
from the comparator 25 is brought to the state of 0 and an output
from the NAND gate 26 takes the form of 1. As the result, an output
from the NAND gate 58 presents the state of 0 and an output from
the inverter 59 which is supplied to the switch-driving circuit
57 is turned to the state of 1 causing the FET switch 56 to be
closed. Accordingly, short circuiting takes place across the input
and output terminals of the integration circuit 54 an output from
which rapidly falls to zero as shown in FIG. 5 (e).
An output from the inverter 27 is brought to the state of 0 as
shown in FIG. 5 (g), and the switches 29 30 are opened, causing
outputs from the digital output terminal 64 and the analogue output
terminal 37 to fall to zero.
Where an output from the differential amplifier 6 has its phase
shifted to 2.pi., then an output from the comparator 21 appears
again. At this time an output from the inverter 50 takes the form
of 0 and an output from the inverter 59 is brought back to the state
of 0. Operation during a period from 2.pi. to 4.pi. is the same
as during a period from 0 to 2.pi.. The larger the amount of a fluid
1 running through the pipe 2 the more increased an output from
the diferential amplifier 6. As the result, the voltage integrated
by the integration circuit 11 during a period from 0 to .pi. or
from 2.pi. to 3.pi. grows higher. Since an output from the integration
circuit 54 has a constant voltage, the period of T.sub.1 in which
an amount of outputs is integrated in the opposite direction is
lengthened to the same extent as that to which an amount of outputs
integrated in the normal direction increases. Thus the flow rate
of a fluid 1 passing through the pipe 2 bears a proportional relationship
with the period T.sub.1 of reverse integration. Consequently an
analogue output from the output terminal 37 of the flow meter or
a digital output from its output terminal 64 indicates a magnitude
proportional to the flow rate of a fluid 1 traveling through the
pipe 2.
FIG. 6 is a circuit diagram of a flow meter according to still
another embodiment of this invention. There will now be described
the operation of this embodiment by reference to FIG. 7 showing
the wave forms of signals appearing in said embodiment. An output
signal from the differential amplifier 6 which has detected the
flow rate of a fluid 1 conducted through the pipe 2 has a sine wave
as shown in FIG. 7 (a). During a period from 0 to .pi. in which
there appears a signal detecting the flow rate, an output from the
comparator 21 takes the form of 0 as shown in FIG. 7 (b) and consequently
an output from the inverter 50 is brought to the state of 1 as shown
in FIG. 7 (c). An output from the inverter 50 is supplied to one
input terminal of the NAND gate 26 and also to a delay circuit 70.
This delay circuit 70 produces an output in a time t after the delay
circuit 70 is supplied with an output from the inverter 50. An output
from said delay circuit 70 is conducted to the switch-driving circuits
57 71 and inverter 72. The FET switches 56 73 are rendered conducting
by the switch-driving circuits 57 71 for a period from 0 to .pi..
Therefore, outputs x and y from the integration circuits 11 54
are reduced to zero as shown in FIGS. 7 (e) and (f).
When an output from the differential amplifier 6 has its phase
shifted to .pi., then an output from the comparator 21 takes the
form of 1 as indicated in FIG. 7 (b), and in consequence outputs
from the inverter 50 and delay circuit 70 are brought to the state
of 0 as shown in FIGS. 7 (c) and (d). As the result, the switch-driving
circuits 57 71 are deenergized to open the switches 56 73 and
the integration circuits 11 54 commence integration. Since an output
from the comparator 21 maintains the form of 1 as indicated in FIG.
7 (b) for a period from .pi. to 2.pi., the switches 8 53 are closed
by the switch-driving circuits 22a, 22b. Outputs from the differential
amplifier 6 and phase shifter 16 are integrated, as shown in FIGS.
7 (e) and 7 (f) by the integration circuits 11 54 respectively.
These integrated outputs x, y are supplied to a multiplier-divider
74 together with a referential voltage E.sub.s (referred to as z
throughout the embodiment of FIG. 6). The multiplier-divider 74
carries out the arithmetical operation of said three inputs x, y
and z by the formula of x.sup.. z/y.
Where an output from the differential amplifier 6 which has detected
the flow rate of a fluid 1 has its phase shifted to 2.pi., then
an output from the comparator 21 takes the form of 0 and an output
from the inverter 50 is brought to the state of 1. Under this condition,
the switches 8 53 remain open and the switches 56 73 are also
left open. Accordingly, an output from the integration circuit 11
maintains a value attained when the phase is shifted to 2.pi. as
shown in FIGS. 7 (e) and (f). On the other hand, an output from
the delay circuit 70 maintains the state of 0 and an output from
the inverter 50 is kept in the state of 1 until a delay time T.sub.1
passes from the point of time 2.pi.. Therefore, an input to the
NAND gate 26 takes the form of "11" and an output therefrom
presents the state of 0. As the result, a driving signal bearing
the wave form of FIG. 7 (g) is supplied to the switch-driving circuit
28b to open the switch 30. An output from the multiplier-divider
74 bearing the wave form of FIG. 7 (b) appears on the output side
of the switch 30. This output passes through the smoothing circuit
34 and appears at the output terminal 37 of the flow meter as an
analogue signal indicating the flow rate of a fluid 1 traveling
through the pipe 2.
Throughout the foregoing embodiments, integration in the integration
circuit 11 was carried out once for each period of an output voltage
from the amplifier 6. However, this invention is not limited to
such arrangement, but may be so designed as to effect integration
in said integration circuit 11 once, for example, for every two
periods of an output voltage from the amplifier 6. FIG. 8 exemplifies
the latter case. The parts of FIG. 8 the same as those of FIG. 4
are denoted by the same numerals. Referring to FIG. 8 the output
terminal of the comparator 21 is connected to the terminal T of
a binary flip-flop circuit 81 one of the input terminals of an
AND gate 82 and the input terminal of an inverter 83. The output
terminal Q of the flip-flop circuit 81 and the output terminal of
the inverter 83 are connected to both input terminals respectively
of an AND gate 84 whose output terminal is connected to the input
terminal of the driver 28. The output terminals of the inverter
83 and comparator 25 are connected to both input terminals respectively
of an AND gate 85 whose output terminal is connected to one of
the input terminals of an AND gate 86 and the input terminal of
a driver 28b. The other input terminal of the AND gate 86 is connected
to the output terminal of the clock generator 40. The output terminal
of the AND gate 86 is connected to the output terminal of the digital
signal output terminal 64.
One end of the secondary winding of the transformer 12 is directly
connected to the minus input terminal of a comparator 87 whose
plus input terminal is grounded. The output terminal of the comparator
87 is connected to the terminal T of a binary flip-flop circuit
and one of the input terminals of an AND gate 90. The other input
terminal of the AND gate is connected to the output terminal Q of
a flip-flop circuit 88. The output terminal of the AND gate 90 is
connected to the input terminals of the drivers 22b, 51. The output
terminal of an inverter 89 is connected to one of the input terminals
of an AND gate 91. The output terminal Q of the flip-flop circuit
88 is connected to the other input terminal of the AND gate 91
whose output terminal is connected to the input terminals of the
drivers 57 62.
There will now be described by reference to FIG. 9 the operation
of a flow meter according to the embodiment of FIG. 8. Now, let
it be assumed that an output signal es from the amplifier 6 has
a substantially sine wave form as shown in FIG. 9 (a). In this case,
it is assumed that the 90.degree.-shifted noise component is not
contained in the signal es. Therefore, a signal er induced on the
secondary side of the transformer 12 has a substantially sine wave
form as indicated in FIG. 9 (b). Both signals have, as illustrated,
different phases, because the phase of the exiting current in the
exiting coils 3a, 3b is differed from that of the magnetic flux
generated by the coils 3a, 3b because of the electromagnetic loss
therein. The signal er is transmitted to the phase shifter 16 to
have its phase equalized with that of the signal es, and then conducted
to the plus terminal of the comparator 21. Accordingly, an output
signal TS.sub.1 from the comparator 21 has, as shown in FIG. 9 (c),
a positive level synchronizing with the positive level period of
the signal es. When set by a signal TS.sub.1 the flip-flop circuit
81 generates an output signal TS.sub.2 from the output terminal
Q. This terminal Q output signal TS.sub.2 is produced, as shown
in FIG. 9 (d), at the rise of the signal TS.sub.1 and extinguished
at the succeeding rise of said signal TS.sub.1. An output signal
TS.sub.3 from the AND gate 82 whose input terminal is supplied with
the signals TS.sub.1 TS.sub.2 is given forth once, as shown in
FIG. 9 (e), for every two periods of the signal es. The output signal
TS.sub.3 is delivered to the driver 22a to render the FET 8 conducting.
Operation of the FET 8 causes the signal es to be supplied to the
integration circuit 11 for example, for a period extending from
0 to .pi. so as to be integrated. An output signal eIO generated
from the integration circuit 11 for said 0 to .pi. period has a
wave form shown in FIG. 9 (i).
Voltage er induced on the secondary side of the transformer 12
is further directly delivered to the minus terminal of the comparator
87. An output signal Tr.sub.1 from the comparator 87 therefore,
takes, as shown in FIG. 9 (f), the form of a positive pulse in correspondence
to the negative half period of the signal er. The output terminal
Tr.sub.1 is supplied to the terminal T of the flip-flop circuit
88. The output terminals Q, Q thereof give forth signals Tr.sub.2
Tr.sub.2 of opposite polarity respectively. The output signal Tr.sub.2
from the terminal Q of the flip-flop circuit 88 is produced, as
shown in FIG. 9 (g), at the rise of one pulse of the signal Tr.sub.1
and extinguished at the rise of the succeeding pulse of said signal
Tr.sub.1. The two signals Tr.sub.1 Tr.sub.2 are conducted to the
AND gate 90 whose output terminal gives forth, as shown in FIG.
9 (h), a signal Tr.sub.3 for every two periods of the signal er.
The signal Tr.sub.3 is supplied to the drivers 22b, 51 to put them
into operation. As the result, the FET's 53 60 are rendered conducting,
the signal er is supplied to the integration circuit 19 through
the resistor 52 and FET 53 and D.C. voltage E.sub.s is impressed
on the integration circuit 61 through the FET 60.
While the signal Tr.sub.3 is being produced, the signal Tr.sub.1
is supplied to the inverter 89 and the output terminal Q of the
flip-flop circuit 88 generates a signal Tr.sub.2. At this time,
the drivers 57 62 are not supplied with any signal from the AND
gate 91 and the FET's 56 63 remain inoperative. As the result,
the integration circuits 19 61 are actuated to carry out integration
in the positive direction, as shown in FIGS. 9 (j) and (m), for
a period corresponding to the signal Tr.sub.3 giving forth integrated
signals ero, eQ. Where the signal Tr.sub.1 is extinguished during
the 0 to .pi. period, the inverter 89 produces a signal of 1. The
AND gate 91 supplies a drive signal to the drivers 57 62 to render
the FET's 56 63 conducting. Output signals ero, eQ from the integration
circuits 19 61 are held at the levels obtained at that time, as
shown in FIGS. 9 (j) and (m).
Where the comparator 21 gives forth an output signal TS.sub.1 of
0 when an output signal es from the amplifier 6 has a phase of .pi.,
then the inverter 83 produces an output signal TS.sub.1 of 1. Since,
at this time, an output signal TS.sub.2 from the output terminal
Q of the flip-flop circuit 81 has a level of 1 the AND gate 84
is opened, and the driver 28 is driven by an output signal from
the AND gate 84. As the result, the FET 29 is operated and an integrated
output signal ero held by the integration circuit 19 is delivered
to the integration circuit 11 through the resistor 31 and FET 29.
When the integration circuit 11 which produces a negative integratd
output signal eIO during the 0 to .pi. period is supplied with a
positive signal ero, said integrated output signal eIO rises in
the positive direction as shown in FIG. 9 (i) and is returned to
zero level in a time T.sub.1 after the point of time .pi..
Where the comparator 21 gives forth an output signal TS.sub.1 of
0 at the point of time .pi., then an output signal of 1 from the
inverter 83 is also delivered to the AND gate 85. Since, at this
time, an output signal CO from the comparator 25 has a level of
1 as shown in FIG. 9 (k), the AND gate 85 gives forth an output
signal TO of 1 as shown in FIG. 9 (l). The output signal TO opens
the AND gate 86 and actuates the driver 28b. A clock pulse signal
from the clock pulse generator 40 is conducted from the AND gate
86 to the digital output terminal 64. Operation of the driver 28
renders the FET 30 conducting, causing the signal eQ of FIG. 9 (m)
to be supplied to the smoothing circuit 34 through the FET 30. At
this time, a signal eO is generated from the analogue output terminal
37 via the smoothing circuit 34.
When an output signal eIO from the integration circuit 11 is brought
to zero level in a time T.sub.1 which is proportional to the flow
rate, after the point of time .pi., then the comparator 25 gives
forth a signal CO of 0 to close the AND gate 85. As the result,
an output signal T.sub.0 from the AND gate 85 is set at a level
of 0 to put the FET 30 out of operation, thereby extinguishing the
output signals from the digital output terminal 64 and analogue
output terminal 37 which correspond to the period T.sub.1. When
the signal Tr.sub.1 is brought to a level of 0 during the period
of 2.pi. to 3.pi., the AND gate 90 is closed to render the FET's
53 60 inoperative, with the result that the signals er, E.sub.s
cease to be supplied to the integration circuits 19 61 and that
the output signals ero, eQ are brought to zero level, as shown in
FIGS. 9 (j) and (m).
In the succeeding period of 3.pi. to 4.pi., the signals Tr.sub.3
ero, eQ rise all alike, and an integrated output signal eIO is again
obtained at the point of time 4.pi.. The foregoing operation is
repeated thereafter.
FIG. 10 shows the block circuit diagram of a flow meter according
to a further embodiment of the invention where integration in the
integration circuit 11 is carried out once for every two periods
of output voltage from the A.C. source 4. The parts of FIG. 10 the
same as those of FIG. 8 are denoted by the same numerals. Referring
to FIG. 10 the output terminal of the AND gate 82 is connected
to the input terminals of the driver 22a and inverter 95. The output
terminal of the inverter 95 is connected to one of the input terminals
of the AND gate 96 the other input terminal of which is connected
to the Q output terminal of the binary flip-flop circuit 81. The
output terminal of the AND gate 96 is connected to the input terminal
of the driver 28b. The Q output terminal of the flip-flop circuit
81 is connected to one of the input terminals of the AND gate 84
the other input terminal of which is connected to the output terminal
of the comparator 21 through the inverter 83. The output terminal
of the driver 28b is connected to the gate electrode of the sampling
FET 30 included in a sampled value holder 38. One of the electrode
terminals of the sampling FET 30 is connected to the plus terminal
of an operational amplifier 39 the output terminal of which is
connected to the analogue signal output terminal 37.
There will now be described by reference to FIG. 11 the operation
of the embodiment of FIG. 10. The signals es, er, TS.sub.1 TS.sub.2
TS.sub.3 Tr.sub.1Tr.sub.2 Tr.sub.3 are the same as those of FIG.
8 as seen from FIGS. 11 (a) to 11 (h). Where the AND gate 90 generates
a signal Tr.sub.3 for a length of time extending between the point
of time at which, for example, the signal es has a phase angle of
-.pi. and that at which said signal es has a phase angle of 0 then
the FET 53 is rendered conducting and the integration circuit 19
generates a signal ero as shown in FIG. 11 (j). This signal ero
is supplied to the multiplier-divider 74 as a Y signal. Since at
this time, the output signal eIO from the integration circuit 11
which is supplied as an X signal to said multiplier-divider 74 has
a level of zero, an output signal eQ from said multiplier-divider
74 continues to have a zero level as shown in FIG. 11 (k). When
the voltage signal es has a phase angle of 0 then the AND gate
82 gives forth a signal TS.sub.3 to actuate the driver 22a, and
the voltage signal es is conducted to the integration circuit 11
so as to be integrated, and an output signal eIO from the integration
circuit 11 increases in the negative direction as shown in FIG.
11 (i). While a signal Tr.sub.3 maintains a level of 0 for the period
in which the phase angle of said signal Tr.sub.3 changes from 0
to .pi., then the FET 53 is rendered inoperative, and the output
signal ero from the integration circuit 19 thereafter maintains
the level obtained at that time. The multiplier-divider 74 which
is supplied with three input signals X, Y, Z during the above-mentioned
period extending between the phase angles 0 and .pi. generates a
progressively increasing signal eQ as shown in FIG. 11 (k).
When the voltage signal es has a phase angle of .pi., the comparator
21 produces a signal TS.sub.1 of 0 and the inverter 83 gives forth
a signal of 1. Since, at this time, a Q output signal from the flip-flop
circuit 81 has a level of 1 the AND gate 84 is opened, causing
a driving signal to be supplied therefrom to the FET 73 through
the driver 28. As the result, the FET 73 is actuated and the output
signal eIO from the integration circuit thereafter maintains the
level obtained at that time as shown in FIG. 11 (i). When said output
signal eIO is thus held at a certain level, then the three input
signals X, Y, Z supplied to the multiplier-divider 74 and in consequence
an output signal eQ therefrom also have a fixed level as shown in
FIG. 11 (k). When the output signal eQ has a fixed level and the
signal TS.sub.3 has its level shifted to 0 then the AND gate 96
is opened. Accordingly, the FET 30 is operated by the driver 28b,
causing the output signal eQ from the multiplier-divider 74 to be
supplied to the sampled value holder 38. Accordingly, the output
terminal 37 of the operational amplifier 39 gives fort a signal
eo whose sampled level value has been held as shown in FIG. 11 (l).
This signal eo continues to be produced until the AND gate 96 is
closed upon the shifting of the level of the signal TS.sub.2 to
0. Namely, said signal eo appears for a length of time corresponding
to half the period of the output voltage signal es from the amplifier
6 which denotes a measured flow rate. When the output signal Tr.sub.1
from the comparator 87 has its level brought to 0 during a period
extending between the phase angles 2.pi. and 3.pi. and in consequence
the AND gate 90 is closed, then the signal ero also has its level
set at 0. The multiplier-divider 74 now supplied with a Y signal
(ero) of 0 generates an output signal eQ also of 0. When the signal
TS.sub.1 has its level brought to 0 at the point of time at which
said signal TS.sub.1 has a phase angle of 3.pi., then the FET 8
is rendered inoperative and the integration circuit 11 generates
a signal eIO of 0. The integration circuit 11 thereafter repeats
the above-mentioned cycle of operation with a length of time extending
between the phase angle points -.pi. and 3.pi. taken as one period.
Further, if the sample-hold time is properly set shorter than that
of one shown in FIG. 11 (l), the output of this flow meter will
be obtained within one cycle of the signal er. |