DE19922311A1 - Method and device for determining spatial distribution of velocity in liquids capable of conducting electricity consists of a magnetic field sensor to measure a magnetic field induced by the reciprocal effect of liquid movement. - Google Patents

Abstract

Multiple magnetic field sensors (1) are fitted outside a liquid. Multiple electric collectors (2) are fitted on the contact surface of a conductive liquid and on a non-conductive outer area. A first signal processor (3) picks up measurement values for the magnetic field sensors. A second signal processor (4) picks up measurement values for the electric collectors. There is also a control, evaluation and memory unit and an output device.

Description

The invention relates to a method and an arrangement for determining the spatial Ge speed distribution in electrically conductive liquids.

A preferred area of application of the device is to determine the speed in hot and / or chemically aggressive liquid metals and semiconductor melts.

The fact that in a conductive moving liquid under the influence of an external Magnetic field (primary field) electrical currents are induced, u. a. also outside of generate an additional magnetic field in the liquid under consideration, was described by Baumgartl, J., Hu bert, A., and Müller, G. in "The use of magnetohydrodynamic effects to investigate fluid flow in electrically conducting melts ", Phys. Fluids AS (12), December 1993, pp. 3280-3289 wrote. In this work the problem of spatial speed reconstruction was also discussed structure from the induced magnetic fields measured in the external area. The However, the specified method is not able to add all speed components determine. So z. B. in the case of an external magnetic field applied in the z direction Rotation of the liquid around this axis cannot be determined. Also for every other one Not all speed components can be determined in the primary field.

DE 43 16 344 A1 describes a flow measuring device in which Ge Velocity components from time delays of magnetic signals between magnet field-generating and magnetic field-measuring components can be determined. It was provided that the direction of action of the primary field and magnetic field measuring components are perpendicular to the speed component to be measured, which requires that for the determination of all speed components created three different magnetic fields should be. There are also speed components in this technical solution, that cannot be determined.

The invention has for its object a method and an arrangement for loading tuning of spatial speed distributions in electrically conductive liquids to propose results that are reproducible for all speed components rant.

According to the invention, the object is achieved with the features stated in the patent claims solved.  

The invention for determining velocity fields in electrically conductive liquids with the conductivity σ is based on the fact that a current = σ × _{0 is} induced by applying an external magnetic field ₀ (primary field). This current in turn creates an additional magnetic field, which can also be measured outside the liquid. For the present method according to the invention, however, there is the problem that, in addition to the current = σ × ₀ , the so-called secondary currents at the interface of the liquid contribute to the induced magnetic field measured externally Potentials at the interfaces by using the known equation from Ge selowitz (Geselowitz, DB, "On the magnetic field generated outside an inhomogeneous vo lume conductor by internal current sources", IEEE Transactions on magnetics, Vol. Mag-6, No. 2, June 1970, pp. 346-347). Furthermore, the electrical potential measured at the interfaces is used as a further source of information to solve the inverse problem of determining the speed distribution.

The electrical potential ϕ _i is determined at a plurality 1 ≦ i ≦ NP of points with the coordinates _i = (x _i , y _i , z _i ) at the interface between the conductive liquid and the external boundary (e.g. a glass or ceramic wall). It must be assumed that the electrical conductivity of the wall is significantly lower than that of the liquid. The points should be distributed as evenly as possible over the interface.

Furthermore, at a plurality 1 ≦ k ≦ NB of points with the coordinates _k = (x _k , y _k , z _k ) in the outer region there is a magnetic field component B _k = ( _{0, k} + _k ). _k measured. The direction of the unit vector _k at the measuring point k should be as perpendicular as possible to the nearest point on the wall. In order to obtain the magnetic field component b _k caused by the liquid movement, the component of the externally applied magnetic field B _{0, k must be} subtracted from the actual measurement result B _k . The number NB and the number NP should be approximately the same size. It should be noted that the number of actual information is determined by NB and NP. This also gives an upper limit for the number of points at which the speed inside the liquid can be determined. For a suitable discretization of the speed field, the number of points in the layer closest to the wall should be less than or equal to the minimum of NB and NP.

From the measured data of the electrical potential at the interface and the magnet field in the external area is used using the Biot-Savart law and the formulas of Ge selowitz, who describe the influence of secondary currents at the interface solved speed determination problem. This is done using the method of least squares, with the mean square Ab deviations of the magnetic fields induced by the assumed speed and elec trical potentials of the measured values are used. As further informat on serves the fact that the velocity field is assumed to be free of divergence, which  is implemented in the process by installing an appropriate functional. To avoid of unphysically large amounts of speed in solving the inverse problem is a regularization of the speed field by using an additional Functionals made.

A major advantage of the invention is that it can also be used for speed is suitable in hot and / or chemically aggressive liquids, since the di direct contact of parts of the device with the liquid on electrical potential probes limited, which is very resistant to high temperatures due to a suitable choice of materials and against chemical decomposition.

The invention is based on an exemplary embodiment of the method and the Arrangement described in more detail.

The accompanying drawing shows a schematic diagram of the arrangement according to the invention.

It will be a concrete embodiment of the spatial velocity method mood described.

This can be broken down into three steps.

In the first step, the potentials ϕ _i measured at the interface and the induced magnetic fields b _k measured in the outside area are converted to modified potentials _j and modified magnetic fields _k by subtracting the surface terms resulting from secondary currents at the liquid boundary. The _{k are located} at the same coordinates _k as the fields b _k . The coordinates = ( _j , _j , _j ) of the modified electrical potentials _j are, however, also modified and must lie in the outer region of the liquid. The points of these modified coordinates should enclose the liquid area as evenly as possible. For the distance between both the coordinates _k , at which the magnetic field is measured, and the coordinates to the interface of the liquid, it should be approximately in the order of magnitude of the linear extent of the surface elements with which the surface integrals are approximated via the potential . The transition from the original to the modified sizes takes place according to Geselowitz's formulas, which are in a discretized form

respectively.

can be noted. Δ _i is to be understood as an outward vectorial surface element at point i of the interface.

The modified magnetic fields are linear with the one sought by the Biot-Savart law Velocity field linked in the liquid. The modified electrical potentials are also linearly related to speed through a similar relationship. By Discretization of the liquid volume, a matrix equation can be set up in which as the modified magnetic fields and the modified electric fields Product of a matrix with the column vector of all searched speed components being represented. This is a linear system of equations for determining the speed components that are solved by the least squares method that can.

Specifically, this is implemented as follows: The discretized velocity field _m should be reconstructed as best as possible with 1 ≦ m ≦ NV at the support points _m = (x _m , y _m , z _m ) in the volume of the liquid. In many applications it must be ensured that the relative speed between fluid and solid walls disappears (no-slip boundary condition). This requirement can be taken into account in a natural way if one moves from the speeds _m located at the NV support points to a set of NVV ≧ NV speeds which are based on a point set offset with respect to the system of the original support points with the coordinates = ( _l , _l , _l ) are localized. These speeds at the offset points can be suitably according to

are interpolated from the speeds _m to be determined at the original support points, the no-slip condition at the limits being guaranteed by corresponding entries in the matrix M. Furthermore, a corresponding volume element ΔV _{l is} assigned to the speeds at the offset support points.

The essence of the speed reconstruction is now to find such a speed distribution _m , through which both the discretized form of the Biot-Savart law

as well as the discretized form of the corresponding law for the connection between speed and modified potential in the outer area

is fulfilled as well as possible. These equations can be compact in form

are noted, the matrix elements of A and C being uniquely determined by equations (4) and (5), respectively. The determination of the speeds now results from the principle of the least squares by minimizing the functional of the speeds

where s _B and s _P stand for the a priori assumed measurement errors of the magnetic fields or electrical potentials. The minimization of the functional in equation (8) is carried out according to the least squares method (described, for example, in IN Bronstein, KA Semendjajew, "Pocket Book of Mathematics", joint edition by Nauka Publishing House, Moscow, BSB BG Teubner Verlagsgesellschaft, Leipzig , 1981, p. 825, this quote takes over the content of this publication into the present description) on the system of normal equations for determining the speeds, which can be solved with a standard method for solving systems of linear equations.

However, this system of equations generally turns out to be poorly conditioned for a larger number of speeds to be determined and must therefore be regularized in a second method step. The mathematical method of regularizing poorly conditioned inverse problems is comprehensively dealt with in Engl, HW, Hanke, M. and Neubauer, A., "Regularization of Inverse Problems", Kluwer Aca demic Publishers, Dordrecht, Boston, London, 1996. In the case of The present invention offers itself as an embodiment of the regularization method, the so-called Tichonov regularization, in which a functional is added to the functional of the mean square residual deviations, which ensures that a suitable norm of the speed sought is minimized. The method of Tichonov regularization and the method of the L curve to be discussed in the following have been described e.g. B. described in Hansen, PC, "Analysis of discrete ill-posed problems by means of the L-curve", SIAM Review, Vol. 34, No. 4, pp. 561-580, December 1992; this quotation transfers the content of this publication to the present description. For the purpose of the method according to the invention, the functional of the mean quadratic speed amount and the functional of the mean quadratic curvature of the speed prove to be suitable as the regularization function. The second variant is preferable from a physical point of view, since the velocity field can be assumed to be relatively smooth in many hydrodynamic applications. This functional is weighted with an initially still free regularization parameter. In addition, a function of the mean squared speed divergence is added to ensure freedom from divergence of the speed field sought. The staggered coordinates = ( _l , _l , _l ) given above are expediently used as support points for the regularization functional and the divergence functional. Analogous to equation (3), the demand for ver disappearing velocities at interfaces can be built in in a natural way if the curvature term and the divergence term at the support point l are represented by

Specifically, this results in the entire functional to be minimized

F _B [] + F _P [] + F _R [] + F _D [] = Min (13),

where F _B [] and F _P [] are given by equations (9) and (10) and the regularization function F _R [] and the function to ensure freedom from divergence F _D [] are discretized by

The parameter s _{R is} to be interpreted as the mean permitted curvature of the speed field and s _D as the mean permitted divergence of the speed field. While s _D should always be chosen very small to ensure freedom from divergence, s _{R is} initially still a free parameter.

In a third and final step, the system of normal equations is solved for a set of regularization parameters s _R , which is to scale the relative weight of the regularization function in relation to the function of the mean residual squared deviation over a wide range. For each of the regularization parameters, the forward task for determining the modified magnetic fields and potentials resulting from the respective solution is then solved according to ( 4 ) and ( 5 ). The mean square residual deviations from the actually present values _k and _j and the mean square curvature of the speed field are then determined. The logarithm of the mean square curvature (ie log (F _R [] s ² _R )) is then plotted against the logarithm of the weighted mean residual square deviation (ie log (F _B [] + F _B [])). The resulting curve is typically L-shaped (Tichonov L curve). Experience has shown that a physically realistic solution to the inverse problem can be assumed at the point where the L-curve is most curved. At this point a reasonable compromise is reached between minimizing the mean square residual deviation and minimizing the mean square curvature.

The foregoing describes the preferred embodiment of the present invention method according to the assumption that the essence of this method ver is illustrated. Since the expert recognizes numerous possibilities for modification is, in particular those of the specific embodiment of the discretization of the Surface and volume integrals as well as the specific regularization radio to be selected tionals, it is not desirable to tailor the invention to the precise construction and the precise Limit applications as described and shown.

The arrangement according to the invention for speed reconstruction in conductive fluids consists of a plurality of magnetic field sensors 1 outside the liquid, a plurality of electrical potential probes 2 at the interface of conductive liquid and non-conductive outside area, a signal processor 3 for recording the measured values of the magnetic field sensors, and a signal processor 4 for recording the measured values of the electrical potential sensors, from a control, evaluation and storage unit 5 and an output device 6 .

For the sake of clarity of presentation, only the verb in the drawing 2 sensors for the respective signal processors are explicitly shown and the remaining connections are indicated by broken lines.

The externally generated magnetic field can e.g. B. generated by a pair of Helmholtz coils, which with an appropriate polarity within the liquid has an almost constant axial Magnetic field generated. However, this is not necessary as it is a special feature of the The method is that none of the spatial structure of the externally generated magnetic field whose requirements are made in terms of homogeneity or isotropy.

Align the strength B _{0 of} the externally applied magnetic field ₀ with the given problem. If the velocity distribution undisturbed by influences from magnetic fields is to be determined, the strength of the magnetic field should be selected so that the interaction parameter N = σ B ² ₀ L / (ρU) is much smaller than 1 (where σ is the electrical conductivity of the Liquid, ρ the density of the liquid, L a typical linear expansion and U a typical speed of the liquid). It is u. It may also be possible to use the earth's magnetic field for ₀ , which can be exposed as spatially constant before in the measuring volume. In this case, it must be clarified for each measurement task whether the induced magnetic fields and electrical potentials can still be measured with sufficient accuracy. For special applications for the investigation of magnetohydrodynamic effects in magnetic fields, the magnetic field which is already present per se can be used for the measurement technology application according to the invention. With regard to the determinable speed amounts, it must be noted that the magnetic Reynolds number R _m = σµ ₀ LU (where µ _{0 is} the permeability of the vacuum) must be less than 1, which, however, is also guaranteed for almost all possible technical and industrial applications . Otherwise, the magnetic fields induced by the speed movement will be of the same order of magnitude as the external magnetic field applied, and the approximations implicitly used for the method according to the invention will fail.

Claims (6)

1. A method for determining the spatial velocity distribution in electrically conductive liquids, wherein the magnetic fields induced by the interaction of the liquid movement with a static magnetic field are measured at a plurality of detection points outside the liquid, characterized in that also at a plurality of detection points the interface of the liquid-induced electrical potentials are measured and are included as necessary information in the determination of the speed. 2. The method according to claim 1, characterized in that the determination of the Ge speed using the least squares principle, where as Functionalities to be minimized are the mean square deviations of those caused by the assumed speed induced magnetic fields and electrical potentials of the values measured in each case. 3. The method according to claim 1, characterized in that the freedom from divergence of the Velocity field by minimizing the functional of the middle quadrati speed field divergence is used as additional information becomes. 4. The method according to claim 1, characterized in that to avoid unphysical tichonov regularization is used. 5. The method according to claim 4, characterized in that for the Tichonov regulari the mean square speed or the mean square elbow Speed field is used as a regularization functional. 6. Arrangement for determining spatial velocity distributions in electrically conductive liquids, consisting of a magnetic field sensor for measuring the magnetic field induced by the interaction of the liquid movement with an adjacent primary field and a downstream signal processor, characterized in that a plurality of magnetic field sensors ( 1 ) outside the liquid speed and a plurality of electrical potential probes ( 2 ) are arranged at the interface of conductive liquid and non-conductive outer area, that a signal processor ( 3 ) for receiving the measured values of the magnetic field sensors and another signal processor ( 4 ) for receiving the measured values of the electrical Potential probes such as a control, evaluation and storage unit ( 5 ) and an output device ( 6 ) are provided.