FR2607249A1 - Electromagnetic flow meter for conducting or dielectric fluids, and application in particular to fluids of the petrochemicals sector - Google Patents

Abstract

System allowing the non-invasive measurement of the flow rate of a conducting or insulating fluid which flows in a pipe, resulting from the combination of an electromagnetic flow meter operating for the conducting fluids, and a flow meter using cross-correlation with triboelectric noise, operating for the insulating fluids. The system includes a device for non-invasive measurement of the conductivity of the fluid. This conductivity is used by the electronic device processing the signals in order to decide which of the two sensors is supplying a signal actually representing the flow rate of the fluid. The electromagnetic flow meter may be of the type with electrodes of small cross-section in contact with the fluid or, more advantageously, of the capacitive type, with electrodes of large cross-section which are insulated from the fluid.

Description

DBBITHETRP ELECTROMAGNETIC FOR
CONDUCTIVE OR DIELECTRIC FLUIDS
AND APPLICATIONS IN PARTICULAR TO PLUIDS IN THE PETROLIEP SECTOR.

The present invention relates to a system
electromagnetic flow measurement, non-intrusive,
operating with conductive fluids or
dielectric.

Sensors capable of accurately measuring flow
any fluid possibly subjected to a very
high pressure (100 MPa) and non-intrusively
are rare or even non-existent. The service sector
tankers face this type of problem often
aggravated by the fact that the fluid can be extremely
corrosive or erosive. A particularly example
striking concerns the so-called fracturing operations
acid from an oil-bearing rock formation where acid
hydrochloric is pumped under pressure sometimes
greater than 100 MPa in special steel pipes of
5 to 10 centimeters in diameter, at flow rates such as
linear flow velocity covers a range from O to 25
m / s.

For other fracturing operations fluids
pumped can also be diesel-based gels,
relatively viscous, carrying strong sand
proportion.

In these conditions it is essential that the sensor
does not present any obstacle to the passage of the fluid. From
systems of the prior art, practically only the
Electromagnetic flowmeters can claim to answer a significant part of the problem posed by flow measurement under the conditions given.

Unfortunately, these flowmeters only work for conductive fluids, while almost half of the applications concern dielectric fluids.

The system which is the subject of the present invention combines the advantages of electromagnetic flowmeters with those of a device called intercorrelation on triboelectric noise. The invention resides in the method of combining the two systems in a configuration allowing their use in the field, in difficult conditions.

When a dielectric fluid is pumped through an electromagnetic flowmeter with electrodes in contact with the fluid, a signal is generally received because the electrodes then constitute antennas sensitive to electromagnetic noise which are no longer stopped by the conductivity of the fluid. In this case, the two sensors present in the system which is the subject of the present invention each provide a signal. In order to select the right signal - in this case that delivered by the intercorrelation device - the system object of the present invention also includes an electronic device for measuring the conductivity of the fluid. This selection of the signal is also one of the essential aspects of the invention.

Figure 1 is an overall diagram of the system, showing the arrangement of the sensors and a block diagram of the electronic device.

Figure 2 details the content of the electronic device for measuring the conductance of the fluid.

Figure 3 is a sectional view of the conduit in an exemplary embodiment of the invention.

Figure 4 is a sectional view of the conduit in another embodiment of the invention.

The same reference numerals designate the same members in the different figures.

In FIG. 1, the electromagnetic flowmeter is represented by its two coils (1) (2) for generating a magnetic field B perpendicular to the direction of the average speed of flow of the fluid in the conduit (3), and by its electrodes (4) (5) transversing the conduit so as to be in contact with the fluid. This device corresponds to the electromagnetic flowmeter with small section electrodes (also called point electrodes), in contact with the fluid.

We could also have represented here an electromagnetic flowmeter with large section electrodes (called "capacitive"), the general principle of which is known and will not be repeated here.

The flow meter shown in the figure includes an electronic device (6) ensuring the control as a function of time of the current in the coils (1) (2), and the measurement of the voltage between the electrodes (4) and (5).

In this same figure, the device for intercorrelation on triboelectric noise consists of two signal detection antennas (7) (8), distant by a distance (a) in the direction of flow of the fluid, each being connected to a charge amplifier electronic device (9) (10).

These devices provide "active guard" of the detection antennas so as to cancel the signal losses between the antennas and their surroundings and also ensure an amplification of a gain approximately equal to 1. Such an intercorrelation device is described in the application. fran patent
çais No 86 16529 filed on November 25, 1986 filed by the plaintiff, the content of which is incorporated here by reference. The outputs of the two devices (9) (10) are connected to an electronic device (11) calculating from the two signals the time taken by the fluid for
travel the distance between the two antennas. An electronic device (12) makes it possible to measure a quantity directly linked to the conductivity of the fluid, and for this is connected to an antenna (8) and to the output of the amplifier (10) of the other antenna.

Finally an electronic device (13) receives information from the two sensors: the signal (15) provided by the electromagnetic flow meter, the signal (17) provided by the triboelectric noise cross-correlation flow meter and the conductance between the two antennas (16) . The device (13) performs a test on the value of the conductance and, as a function of this test, selects the correct value of the flow rate (15) or (17).

The electrodes of the electromagnetic flowmeter as well as the antennas of the intercorrelation device will preferably be produced by a well-known technique of flexible multilayer printed circuit, in particular by photoerosion.

Figure 2 gives the detail of the operating principle of the device (12) for measuring the conductance between the antennas (7) and (8).

This device comprises on the one hand a sinusoidal oscillator generating a current of frequency F well known, injected on the antenna (8) through a resistor R of very high value.

On the other hand, a device for measuring the amplitude of the signal at the same frequency F, measured at the output of the amplifier (10) connected to the second antenna (7).

The choice of the value of F is made in such a way that the measurement of the conductance can be done simultaneously with the calculation of the intercorrelation function in the device (11) without the result of this calculation being significantly disturbed. In practice, F is between 5 and 20 KHz, the maximum value being a practical limit for the detection of the component at frequency F on the output of the amplifier (10).

Figure 3 is a sectional view of the conduit (3) in which the fluid flows in the case where the system results from the combination of an electromagnetic flowmeter with electrodes (4) (5) of small section in contact with the fluid and a device for intercorrelation on triboelectric noise whose antennas (7) (8) are placed inside the duct (3).

The interior of the conduit (3) is covered with a layer (18) of uniform thickness of a dielectric material, such as
polyurethane, isolating the antennas (7) (8) from the fluid flowing in the conduit, while leaving the electrodes (4) and (5) flush. This embodiment is used in particular when the fluid pressure can reach very high values. In this case it is convenient to use a metal to make the conduit (3). This must be non-magnetic, so that the magnetic field B can act on the fluid. This metal can be aluminum or its alloys, or stainless steel or titanium, in particular if the pressure of the fluid can be higher than 100 MPa. In the case of high pressures of the fluid, the crossing of the electrodes and antenna connections uses special devices capable of withstanding the pressure, which are not described in this figure but are described in French patent application No 86 16529 filed on 25
November 1986 by the plaintiff. It will be advantageous, in certain cases, for the duct (3) to be made of a "composite" material based in particular on glass fibers, carbon or aramid, or else on a ceramic material, more particularly alumina.

Finally, FIG. 4 illustrates an embodiment of the invention in which the conduit (3) is made of a dielectric material outside of which the electrodes (4) (5) of large cross section of the electromagnetic flowmeter operating by "capacitive" mode and the antennas (7) (8) of the triboelectric noise intercorrelation device. Finally, a grounded conductive jacket (19) protects the entire system against external electromagnetic interference.

This achievement has the advantage of being completely non-intrusive. Furthermore, when the fluid can be subjected to very high pressures, it suffices to choose as the constituent material of the conduit (3) a ceramic such as alumina or a composite material with glass fibers, carbon or aramid.

Claims (9)

Claims 1. System for measuring the flow of a conductive or insulating fluid flowing in a conduit, characterized in that the system results from the combination of an electromagnetic device for measuring the flow of conductive fluids and an intercorrelation device on triboelectric noise for measuring the flow rates of dielectric fluids, the two antennas of which, isolated from the fluid, are on the one hand each connected to an electronic charge amplifier device, on the other hand connected to an electronic device measuring the conductance between said antennas, and in that the system comprises an electronic device selecting from the signals supplied by the two sensors, as a function of the value of said conductance, the signal representative of the measurement of the flow rate of the fluid. 2. flow measurement system according to claim 1, characterized in that the electronic device for measuring the conductance between the two antennas of the triboelectric noise cross-correlation flowmeter consists on the one hand of a sinusoidal oscillator of frequency F included between 5 and 20 KHz, injecting a sinusoidal current of the same frequency on one of the two antennas through a resistor of very high value, and on the other hand a device for detecting the amplitude of the current at frequency F measured at the output of the charge amplifier device connected to the second antenna, the latter current amplitude providing a direct measurement of the conductance between the two antennas. 3. Flow measurement system according to claim 1 and or 2 characterized in that the electromagnetic flow meter is of the type with electrodes of small section in contact with the fluid. 4. Flow measurement system according to any one of claims 1, 2 and 3, characterized in that the conduit conveying the fluid is a non-magnetic metal cylinder and more particularly of one of the following types: stainless steel, titanium , aluminum and their alloys, and in that the antennas of the triboelectric noise intercorrelation device are plated on the internal wall of said cylinder and are isolated from the fluid by a layer of dielectric material covering the interior of said uniform thickness led, while allowing the electrodes of the electromagnetic sensor to be exposed. 5. A flow measurement system according to claim 1 or 2, characterized in that the electromagnetic flow meter is of the capacitive type, with large section electrodes and isolated from the fluid. 6. Flow measurement system according to any one of claims 1, 2 and 5, characterized in that the capacitive electrodes of the electromagnetic flow meter as well as the detection antennas of the device for intercorrelation on triboelectric noise are plated outside the conduit carrying the fluid, said conduit being made of dielectric material. 7. A flow measurement system according to claim 6, characterized in that the conduit carrying the fluid is made of composite material whose fibers are of one of the following types: glass, carbon or aramid. 8. Flow measurement system according to claim 6, characterized in that the conduit conveying the fluid is made of ceramic and more particularly of alumina. 9. Flow measurement system according to any one of claims 5 to 8, characterized in that the capacitive electrodes of the electromagnetic flowmeter as well as the antennas of the device for intercorrelation on triboelectric noise are produced on the same flexible multilayer printed circuit.