FR2462710A1 - Speed measurement for molten electroconducting fluid - requires detector comprising ferromagnetic cylinder with protruding diametrically opposed conductors - Google Patents

Abstract

The speed and flow of an electrically conducting fluid is measured locally by a detector comprising a ferromagnetic cylinder. This allows fluid at high temperature such as molten metal to be measured. A detector (1) at the end of a rod (2) is plunged into a fluid flow and comprises a small cylindrical rod (3) of ferromagnetic material. This is enclosed by a non-magnetic cover (5). A pair of electrodes (4a,4b) are insulated from the material by a stainless steel sheath (6a,6b) containing compacted magnesia. These are located in diametrically opposite positions to define a transverse axis. The ends of the electrodes are based of insulation to make contact with the fluid. A voltage is generated between these electrodes by the flow and which is proportional to its speed.

Description

The present invention relates to methods and devices for locally measuring instantaneous velocities of an electroconductive fluid, in particular of a molten metal.

 The technical sector of the invention is that of measuring the speeds and flow rates of an electroconductive fluid, and more particularly of a high temperature fluid.

 In the remainder of the description, reference will be made more particularly to the measurement of the speeds and the flow rates of molten metals and metal alloys, which constitute a particularly advantageous field of applications of the speed and flow rate sensors according to the invention. .

 It is specified that this choice does not entail any limitation of the invention and that the sensors according to the invention can be used to measure speeds and flow rates within any electroconductive fluid, in particular within hot fluids, such as plasmas or molten salt hydrates which are used to store heat in the form of latent heat of fusion.

The most used speed and flow sensors to date are either differential pressure sensors of the tube type.
Pitot, or hot wire anemometers.

 Pitot tubes cannot be used within a metal or a molten salt hydrate. Indeed, there is a solidification of the metal or of the hydrate saline inside the tubes which become blocked.

Hot wire anemometers are based on a measurement of variation in electrical resistance due to a variation in temperature of the wires and their sensitivity, at high temperatures, is very reduced.

In many practical problems, it is sought to measure locally, within a molten metal, the modulus and the direction of the speed vector. This is the case, for example, to study convection movements inside a metal smelting or refining furnace. This is also the problem to be solved for measuring, for example, the flow rates of a molten metal and, in particular, for constructing automatic devices, which make it possible to interrupt a casting when a quantity of metal sufficient to fill a mold, has passed.

An objective of the present invention is to provide means which make it possible to locally measure the module and the direction of the instantaneous speeds, within an electroconductive fluid and, in particular, within a fluid at high temperature, for example of a molten metal.

This objective is achieved by means of a process according to which a speed sensor comprising a small cylindrical bar, made of a ferromagnetic material, having a longitudinal geometric axis and at least one pair of insulated electrodes is placed within the moving fluid. whose two ends are arranged at two diametrically opposite points of said bar and define a first transverse axis, a magnetic field is created, substantially parallel to said longitudinal axis, and the potential difference between the two electrodes is measured, which is proportional to the value instant of the speed component along a second transverse axis perpendicular to said longitudinal axis and to the first transverse axis.

When the direction of the speed is unknown, the components of the speed are measured in three trirectangular directions and the modulus and direction of the speed vector are deduced therefrom.

 To measure the components of the speed in three trirectangular directions, a first measurement of the Ux component is carried out, along an ox axis, by placing the sensor so that the ends of the two electrodes are placed along a perpendicular oy axis. to Ox, and that the geometric axis of the sensor is arranged along an axis Oz, perpendicular to the axes Ox and Oy.

 We then rotate the sensor 90 around the geometric axis, and measure the component Uy of the speed along the axis Oy.

 Finally, rotate the sensor and the magnetic field around the Ox axis and measure the Uz component of the speed along the Oz axis.

A device according to the invention comprises a speed sensor which is placed within the moving electroconductive fluid and which comprises - a small cylindrical bar, made of a ferromagnetic material, having an axis
longitudinal geometric, - means for creating, in said rod, a substantially magnetic field
parallel to said geometric axis, --and at least one pair of electrodes placed in an insulating sheath, the
two ends are stripped and are arranged at both ends of a
transverse diameter of said bar where they come into contact with said fluid
in motion, - and said device further comprises means for measuring the difference
potential between the two electrodes of each pair of electrodes, which
is proportional to the component of the speed along the perpendicular axis
the said longitudinal axis and said transverse diameter.

Preferably, the cylindrical bar is a permanent magnet.

According to a preferred embodiment, a sensor according to the invention comprises two pairs of electrodes, the stripped ends of which are disposed respectively at the two ends of two transverse diameters of the bar, perpendicular to each other.

 Preferably, a sensor according to the invention comprises a cylindrical housing, coaxial with said bar, inside which are placed said bar and said electrodes, which pass through said insulating casing at two diametrically opposite points for each pair of electrodes.

 The invention results in the local measurement of instantaneous speeds, within an electroconductive fluid in particular in a high temperature fluid and more particularly within a metal or a molten metal alloy. It also relates to new speed sensors and new devices equipped with these sensors.

 A first advantage of the speed sensors according to the invention is due to the fact that their composition makes it possible to construct them entirely from materials which are resistant to high temperatures. The electrodes can be placed in an insulating sheath in magnesia, or in any other refractory oxide. , and the end of the electrodes which is in contact with the fluid can be constructed of an electroconductive metal, having a high melting temperature; for example platinum.

 the rod, made of ferromagnetic material, can be composed of an alloy or a ferrite which resists the temperature well, without losing its magnetic properties. In the case where velocities have to be measured at a temperature below 7000, the ferromagnetic bar can be composed of ferromagnetic material, commonly used to construct permanent magnets or electromagnet cores, and, generally having a temperature of Curia of the order of B0 to 8000. Thus, the velocities can be measured in molten metals, such as bismuth, cadmium, coesium, gallium, indium, potassium, Pithium, sodium, mercury, lead, rubidium, tin, zinc. For higher temperature applications, special alloys with a higher Curie point can be chosen.

 the speed sensors according to the invention deliver an electric voltage which varies in a very proportional manner as a function of the component of the speed to be measured and, this, in a range of speeds going from very low speeds, of the order of a few millimeters per second, at speeds of several meters per second, that is to say over the entire range of speeds that are encountered in current industrial practice.

Systematic laboratory tests have also shown that the proportionality coefficient is independent of the temperature in the range between ambient temperature and a temperature of the order of 7000.

These same tests have shown that the proportionality coefficient is independent of the physical properties of the molten metal, such as viscosity or electrical conductivity. However, the fluid must be electrically conductive, but in the conductivity range of metals and metal alloys, the proportionality coefficient is independent of the value of the electrical conductivity. it follows that the calibration of a speed sensor according to the invention is valid for all common use cases and that it can be easily carried out in the laboratory, for example in a mercury bath.

Tests in the laboratory have also shown that the dynamic properties of a speed sensor according to the invention are very good and that the electrical signal very faithfully follows the variations in speed for frequencies up to 100 Hz. All these properties mean that the speed sensors according to the invention are very well suited to very many practical cases where problems of speed and flow measurement arise, in a molten metal or in an electroconductive fluid.

The electrical signal delivered by a speed sensor according to the invention reproduces analogically, very faithfully, the variations in speed of the fluid at the point where it is placed, and the devices according to the invention constitute speed or flow rate reducers in a signal electric. In addition, the dimensions of a sensor according to the invention are very small, of the order of 5 mm in diameter and 1 cm in length, so that their presence, within the liquid, does not substantially disturb the flow and that the sensor can be moved to various points in a fluid stream to obtain local velocity measurements and explore a velocity field.

 When the direction of the speed is unknown, it is possible, with a sensor according to the invention, to measure the components of the speed Ux, Uy and Uz according to three trirectangular axes and to deduce therefrom the direction and the modulus of the speed . All these properties make it possible to use the sensors according to the invention to control flows of molten metals, by using the signals delivered by the sensors, either to actuate indicating devices, or alarms, or even automatic devices or slaves. It is also possible to use speed sensors according to the invention to study movements or flows of molten metals, in various practical and industrial applications which are still poorly known. For example, the sensors according to the invention can be used to to study the movements of response in the liquid sodium which circulates in the heat exchangers, used in certain nuclear reactors, or the phenomena of backwash and electromagnetic stirring which occur in arc or induction melting furnaces.

The following description refers to the accompanying drawings which show, without any limitation being examples of embodiment and implementation of devices according to the invention.

 Figure 1 is a geometric figure.

Figures 2 to 4 are axial and transverse sections of a speed sensor according to the invention.

 Figure 5 is an axial section of an alternative embodiment of a speed sensor according to the invention.

Figure 6 is a geometric figure.

 Figures 7, 8 and 9 illustrate three steps of measuring the direction and the modulus of the speed at a point.

Figure 10 is an axial section of an alternative embodiment of a speed sensor according to the invention.

 FIG. 1 is a geometric figure which makes it possible to explain the notations used, the theoretical foundations of the invention and to describe the steps of a method according to the invention.

 The problem to be solved is to locally measure the speed U at a point 0, located within a moving electroconductive fluid. We assume, for the moment, that we know the direction of the speed vector U and that the measurement sought is that of the module | U |, which is a frequent case, in practice, in all cases , where one wishes to know the magnitude of the speed of a flow, along a pipe, the direction of the speed then being parallel to the generatrices of this pipe.

The electroconductive fluid is for example a molten metal having a melting temperature below 700 "C.

 To carry out this measurement, a speed sensor 1 placed at the end of a rod 2 is immersed in the molten metal. This speed sensor comprises a small cylindrical bar 3, which has a geometric axis A and for example a length of 5 mm and a diameter of 2mm. The bar 3 is made of a ferromagnetic material. The sensor 1 comprises at least a pair of electrodes 4a and 4b which are isolated. The ends A - and A 'of the two electrodes are arranged at two points diametrically opposite the bar 3 and they define a first transverse axis Ox which is perpendicular to the axis A.

The ends A and A 'of the electrodes are stripped and in electrical contact with the moving fluid. We create, in the bar 3, a magnetic field
H which is substantially parallel to the axis A of the bar. According to a preferred embodiment, the bar 3 is a permanent magnet having an axis of magnetic polarization coinciding with the geometric axis A. According to another embodiment, the bar 3 is a soft iron core of an electromagnet.

 there appears between the electrodes 4a and 4b a potential difference or voltage V which is proportional to the module | U | of ulve the speed U.

If U is not directed along the transverse axis Oy perpendicular to the axis Ox, the voltage V is proportional to the component uyi of the speed along the axis Oy. The voltage V analogically represents the instantaneous speed at point 0. By moving the sensor within the liquid, one can measure the local velocities at different points of a moving fluid.

The simplified theoretical interpretation of this result is as follows
The speed U being parallel to an axis, for example to the axis Oy, the voltage VAA 'is noted which appears between two points AA' arranged along an axis Ox perpendicular to the axis Oy.

 The voltage AA 'is proportional to the component Ex along the axis Ox of an induced field, deriving from a potential, which is linked by a linear relationship to the component along the axis Ox of the electromotive field U t. The voltage VAA ′ is therefore consequently proportional to the component Ux of the speed along the axis Oy. This result s1 is explained by a magneto-hydrodynamic effect due to the creation of a boundary layer on the external wall of the sensor which behaves like a cylindrical obstacle.

The bar 3 can be electrically conductive, and in this case, part of the induced current passes through the bar. it can also between insulator and, in this case, the current circulates around the rod in the electroconductive fluid.

 FIG. 2 represents a partial axial section of a speed sensor according to the invention. FIG. 3 is a notched cross section along II II of FIG. 1.

The parts homologous to those of FIG. 1, are represented by the same references.

 We find the probe 1 placed at the end of a hollow rod 2, through which the electrodes 4a and 4b pass. We also find the small cylindrical bar 3, of axis A, which is, in this case, a permanent magnet whose magnetic axis is axis A.

 The magnet 3 is enclosed inside a cylindrical case 5, made of a non-magnetic material, which is coaxial with the bar 3.

 For example, the housing 5 is made of stainless steel, or of refractory steel, for sensors intended to be immersed in a molten metal, having a temperature below 7000C.

 Each electrode comprises for example a conductive wire 4a, 4b which is enclosed inside a sheath 6a, 6b, for example a stainless steel sheath, with an insulating lining, in compacted magnesia, 7a 7b, which separates the wire sheath.

The electrodes are placed inside the hollow rod 2 and inside the housing 5 in the intermediate space between the housing and the bar 3.

The lower end of each electrode crosses the housing 5 at two diametrically opposite points, so that the stripped ends A and A 'of the two conductors 4a and 4b are flush with the exterior surface of the housing and are placed in contact with the electroconductive fluid, in which the sensor is immersed The housing 5 has for example an outside length of 6mm and an outside diameter of 2.5mm.

FIG. 4 is a cutaway taken along II II of an alternative embodiment of a sensor according to the invention which comprises two pairs of electrodes, a first pair 4a, 4b, the stripped ends A and
A 'are arranged at the ends of a first transverse diameter D1, and a second pair 8a, 8b, the ends BB' of which are arranged at the two ends of a second transverse diameter D2 perpendicular to the diameter D1.

The presence of a housing 5, which envelops the electrodes and the bar 3, is a preferred embodiment.

 This housing has the advantage of protecting the magnetic bar or the electromagnet from possible corrosion by the electroconductive fluid. The choice of the material making up the housing can be guided in certain specific cases by the chemical nature of the fluid. it is specified that the presence of a box is not essential.

 Figure 5 is an axial section of an alternative embodiment of a speed sensor according to the invention. In this example, the cylindrical bar 3 is a permanent magnet of axis A.

it is crossed over a part of its length by a blind bore 9 and moreover, by a transverse bore 10, which intersects the bore 9.

The bore 9 comprises at its upper end a counter bore 11, into which the hollow rod 2 penetrates. The electrodes 4a and 4b are wrapped in an insulating and refractory lining 7a, 7b, as in the case of FIG. 2, and they are housed inside the holes 9 and 10 The stripped ends A and A 'open at the two opposite ends of the transverse hole 10. Of course, the bar 3 may have two transverse holes 10, perpendicular to one another, and the sensor according to FIG. 5 can then comprise two pairs of electrodes 4a, 4b and 8a, 8b as in the case of FIG. 4.

FIG. 6 is a geometric figure intended to explain how it is possible to measure, at the same time, the modulus and the direction of the speed U, when the direction of the latter is unknown. Let be the velocity vector U at a point 0, and be a system of fixed trirectangular coordinates Ox,
Oy and Oz f is the angle of the velocity vector with the axis Oz.

et les angles f et e, d'après les équations
Ux = U sin f sin e
Uy = U sin f cos e
et Uz = U cos f
Les figures 7, 8 et 9 montrent les étapes successives du procédé qui permet de mesurer successivement les composantes Ux, Uy et Uz, avec un capteur selon l'invention comportant un seul couple d'électrodes AA'.On expliquera ensuite les étapes d'un procédé simplifié, dans le cas où la sonde comporte deux couples d'électrodes AA' et BB'.U is the projection of the vector U on the xoy plane and e is the angle of the vector U ', with the axis Oy. Ux, Uy and Uz are the respective projections of the vector U on the three axes Ox, Oy and Oz. Recall that knowing the values of Ux, Uy and Uz is sufficient to determine both the module | U |, which is equal to

and the angles f and e, from the equations
Ux = U sin f sin e
Uy = U sin f cos e
and Uz = U cos f
FIGS. 7, 8 and 9 show the successive stages of the method which makes it possible to successively measure the components Ux, Uy and Uz, with a sensor according to the invention comprising a single pair of electrodes AA ′. We will then explain the stages of a simplified method, in the case where the probe comprises two pairs of electrodes AA 'and BB'.

 It is therefore assumed, first, that a probe 1 is used, according to Figures 2 or 5, comprising a single pair of electrodes AA '.

 First place the probe at point 0, which is the point where you want to determine the local speed. The axis A of the probe is parallel to the vertical axis Oz and the axis parallel to the line AA ′ c is chosen as the fixed axis Oy. is this position which is represented by FIG. 7.

The voltage V1 is measured between the electrodes A and A '. This voltage V1 is proportional to the component of the speed which is perpendicular both to the axis A, which is parallel to the field H and to the axis AA '.

 V1 is therefore proportional to the component Ux.

Then probe 1 is rotated a quarter turn around the axis A, to bring it into the position of Figure 8, where the line AA 'is parallel to the axis Ox. The voltage V2, which appears between the electrodes AA ′, is measured and V2 is proportional to the component Uy. We do then
rotate probe 1 a quarter of a turn around line AA ', to bring it
in the position of figure 9. The field H is then parallel to the axis Oy
and the voltage V3 between the electrodes A and A 'is proportional to the
Uz component.

If you use a probe 1 with two couples of electro
AA 'and BB', operations are simpler.

Place the probe, first, in the position according to the figure
8 and on the one hand, the voltage between the electrodes AA ′ which is
proportional to Uy and on the other hand, the voltage between the electrodes BB ', which is proportional to Ux. We then rotate the probe a quarter turn around AA 'or BB', for example around AA 'to move to the position of Figure 8 and the voltage measured between A and A' is then proportional to the Ux component.

 In the case of an incompressible liquid, the relation div.U = O makes it possible to know the third component Uz of the speed, by measuring only two components Ux and Uy and therefore with a single position of a probe comprising two couples of electrodes AA 'and BB', hence the particular interest of the probes equipped with two pairs of electrodes, which constitute a preferred embodiment of a sensor according to the invention.

Figure 10 is an axial section of an alternative embodiment of a sensor according to the invention. In this variant, the bar 3 is placed inside a coil 13, which is connected to two conductors 12a and 12b, which make it possible to excite it and create, in the bar 3, a magnetic field H parallel to the geometric axis A of the bar and the coil. One of the conductors 12b crosses, for example, the coil 3 by an axial bore. The core 3 and the coil 13 are arranged inside a housing 5 and the sensor comprises either a pair of electrodes 4a, 4b which pass through the housing and which open at two diametrically opposite points A and A ', or two pairs of electrodes, the ends AA 'and
BB 'are arranged at the ends of two perpendicular diameters, as in the example in Figure 4.

 Of course, without departing from the scope of the invention, the various constituent elements of the sensors which have just been described by way of example, may be replaced by equivalent elements fulfilling the same functions.

Claims (9)

1 - Method for locally measuring the instantaneous velocities of a fluid  electroconductive, in particular of a molten metal, characterized in that a speed sensor is placed within said moving fluid  comprising a small cylindrical bar made of a ferromagnetic material, having a longitudinal geometric axis and at least one pair of electrodes  insulated whose two ends are arranged in two diametric points  trally opposite from said bar and define a first transverse axis  sal; a magnetic field is created which is substantially parallel to said axis  longitudinal and we measure the potential difference between the two.  electrodes, which is proportional to the instantaneous value of the speed component along a second transverse axis per pendulum to said longitudinal axis and to the first transverse axis.  22 - Method according to claim 1 for locally measuring the value ab-  solue and the direction of the instantaneous velocity of flow of a electroconductive fluid, in particular of a molten metal, characterized in  that we make a first measurement of the Ux component of the speed, along a first transverse axis by the process according to the claims  tion 1, then rotate the bar a quarter turn around of its longitudinal axis and we measure the potential difference between the two electrodes which is proportional to the instantaneous value of  the component Uy of the speed, along a second transverse axis,  and then we rotate the bar, as well as the magnetic field, a quarter turn around the transverse axis passing through the extremi tees of the two electrodes, and again measure the difference in poten  tiel between these two electrodes, which is proportional to the compo health Uz of the instantaneous value of speed, according to a third  axis perpendicular to the other two. 3 - Device for locally measuring instantaneous flow velocities ment of an electroconductive fluid, in particular of a molten metal, charac  terized in that it has a speed sensor which is placed within  of said fluid in motion and which comprises - a small cylindrical bar made of a ferromagnetic material having a  longitudinal geometric axis,  - Means for creating in said bar a sensitive magnetic field parallel to said geometric axis, - and at least one pair of electrodes placed in an insulating sheath, the two ends of which are stripped and are arranged at both ends of a transverse diameter of said bar where they come from in contact with said moving fluid,  - And said device further comprises means for measuring the  potential difference between the two electrodes of each pair of electrodes, which is proportional to the component of the  speed, along the axis perpendicular to said longitudinal axis and  audit transverse diameter. 4 - Device according to claim 3, characterized in that said bar water is a permanent magnet. 5 - Device according to any one of claims 3 and 4, characterized in that the ledic sensor comprises two pairs of electrodes whose ends  stripped mites are arranged respectively at the two ends of two  transverse diameters perpendicular to each other. 6 - Device according to any one of claims 3 to 5, characterized in that said sensor further comprises a cylindrical housing, coa  xial with said bar, inside which are placed said bar and said electrodes, which pass through said housing at two points  diametrically opposite for each pair of electrodes. 7 - Device according to claims 3 and 6, characterized in that said  sensor has a coil supplied with electric current which surrounds  said bar. 8 - Device according to any one of claims 3 to 5, characterized  in that said bar comprises an axial bore and at least one bore  transverse which overlap, and said isolated electrodes are available  inside these holes and the stripped ends of each  couple of electrodes lead to the two opposite ends of each  said transverse holes. 9 - Method for locally measuring the absolute value and the direction of the  instantaneous velocity of flow of an electroconductive fluid, in particular molten metal, using a speed sensor according to the income  dication 5, comprising two pairs of electrodes AA 'and BB', character  laughed at by placing said sensor within said fluid  speed and we measure the voltage V1 between the electrodes AA 'which is  proportional to the component Uy of the speed along BB 'and the voltage  V2 between the electrodes BB ', which is proportional to the component Ux speed along axis AA ', then rotate the probe around a transverse axis passing through the ends of a pair of electrodes,  and we measure the voltage that appears between two electrodes, which  is proportional to the component Uz of the speed, according to the third axis parallel to the initial position of the geometric axis of the probe.  10 - Method for locally measuring the three components Ux, Uy and Uz  of the instantaneous velocity of flow of an electroconductive fluid  incompressible, in particular of a molten metal, by means of a vi sensor  packing according to claim 5, comprising two pairs of electrodes  AA 'and BB', characterized in that said sensor is placed within  of said fluid and the voltages V1 and V2 which appear, res are measured pectively, between the electrodes AA 'and BB' and which are proportional  the to the components of the speed Ux and Uy along two axes perpen between them, and we deduce the Uz component, according to a  third axis perpendicular to the other two-, according to the relation  Div. t = O