DE19713751A1 - Magnetic inductive flow meter for flowing media - Google Patents

Abstract

A magneto-inductive flowmeter for flow media has a measurement pipe (1), an electromagnet (2) for generating a magnetic field at least substantially perpendicular to the measurement pipe axis, at least two measurement electrodes (3, 4) arranged along a connection line which extends at least substantially perpendicular to the measurement pipe axis and to the magnetic field orientation, a current source (5) for supplying direct current to the electromagnet (2) and an evaluation circuit (6) for evaluating the measurement voltages from the measurement electrodes (3, 4) and generating a flow signal. According to the invention, a magneto-inductive flow meter for flow media is characterised in that at least one magnetic field sensor (7, 8) is arranged in the magnetic field of the electromagnet (2) and in that the evaluation circuit (6) has a processing circuit (9) connected to the magnetic field sensor (7, 8).

Description

The invention relates to a magnetic-inductive flow meter for flowing Media, with a measuring tube, one generating at least essentially Electromagnetic serving perpendicular to the measuring tube axis of the magnetic field ten, at least two along one at least substantially perpendicular to the measurement arranged tube axis and connecting line extending to the magnetic field direction Measuring electrodes, one of the supply of the electromagnet with a switched Direct current power source and a measuring voltage of the measuring electrodes evaluating, generating a flow signal evaluation circuit.

The basic principle of the electromagnetic flowmeter for strö media already goes back to Faraday, who proposed in 1832 the principle of electrodynamic induction for flow velocity measurement application. According to Faraday's law of induction, one arises flowing medium, which carries charge carriers and through a magnetic field flows, an electric field strength perpendicular to the direction of flow and to the magnet field. This law becomes in a magnetic-inductive flow meter used that a magnet, usually consisting of two solenoids, a magnet Field generated perpendicular to the direction of flow in the measuring tube. Within this Ma gnetfeldes delivers each volume element of the moving through the magnetic field flowing medium with the field strength arising in this volume element a contribution to the measuring voltage tapped via the measuring electrodes. The Measuring electrodes are used in the known electromagnetic flowmeters advise so that they are either galvanic or capacitive with the flowing Medium are coupled. A special feature of the magnetic-inductive through flow measuring devices is the proportionality between the measuring voltage and the over the Cross-section of the pipe averaged flow velocity of the medium, d. H. between measuring voltage and volume flow.

Magnetic-inductive flowmeters were initially used in the industrial sector operated with an alternating magnetic field. For cost reasons, the Electromagnet for generating the magnetic field on the existing alternating chip voltage network connected so that the magnetic field is essentially sinusoidal Strength changes. With these operated with alternating voltage magnetic-inductive Flowmeters are the fluctuations in the AC network immediately  were passed on to the electromagnet and thus went fully into the Meßge accuracy of the magnetic-inductive flow meter. To get one anyway To ensure acceptable measurement accuracy, it is for magnetic inductive through flowmeters, which are operated with an alternating magnetic field, are known, to arrange on the electromagnet reference windings and those in this reference induced voltages to correct the measuring voltages on the windings Use measuring electrodes.

The well-known magnetic-inductive flow meters with a magneti working alternating field, are problematic in that the to the measuring electro the applied measuring voltage inevitably the frequency of the AC voltage network. In practice, however, there are also mains frequency interference voltages the measuring electrodes, z. B. by axial electrical currents in the stream medium - caused, for example, by grounding pumps the adjacent pipelines - which follow the Faraday induction ge the resulting measuring voltages are superimposed. This problem leads to that with magnetic-inductive flowmeters, which with a magnetic Alternating field work, high measuring accuracies can hardly be guaranteed, so that these can only be used to a limited extent in the industrial sector.

Magnetic-inductive flow has been increasing steadily since the mid-1970s measuring devices that work with a switched magnetic direct field. This Devices avoid a multitude of magnetic-inductive flow measurements problems that work with an alternating field and thus enable very high measuring accuracy in the range of up to one per thousand.

In the known magnetic-inductive flow meters with a ge switched magnetic direct field work (see, for example, EP-B-0 521 169) instead, as with the magnetic-inductive flowmeters, which with a change known field work of the magnetic field measured via reference windings the current through the coil of the electromagnet to correct the to the measuring elec measuring voltages applied. Starting point for this before is the assumption that in the steady state the strength of the magnetic field which is directly proportional to the coil current.  

The starting point chosen in the prior art is problematic in that that to ensure proportionality between the strength of the current through the electromagnet and the strength of the magnetic field regardless of temperature, Pressure, installation conditions, field frequency and service life are a lot of work must be driven. For example, the magnetic change with temperature Properties of the iron core that the magnetic field outside the flowing medi should lead and within the flowing medium for the highest possible measure gnetfeld should worry. It is therefore necessary to choose an iron core whose properties as little as possible change with temperature. As a result, the Material costs and the required material cross section for the iron core. Continue is also the distance between the pole pieces of the iron core due to a changing temp variable, which in turn changes the proportionality between the strength of the Stro mes touched by the electromagnet and the strength of the magnetic field. The Ab standing between the pole pieces can also be caused by pressure changes in the measuring tube. This can only be done by a special stable, expensive mechanical construction of the magnetic-inductive through avoid flow meter. Also the installation conditions of the magnetic-inductive Flow meter, such as. B. the magnetic properties of the user used screws and flanges have an influence on the course of the ma magnetic field lines between the pole pieces. This influence can be re induce that the electromagnetic flow meter opposite the pipe diameter is particularly long. This in turn creates higher ones Costs. It also has the field frequency with which the polarity of the magnet field is switched, an influence on the strength of the magnetic field, as a result inductors and eddy currents are not always assumed can that the magnetic field is constant during the actual measurement time. In particular the influence of the eddy currents becomes when assuming a linear combination depends on the strength of the magnetic field and the strength of the electric magnet flowing current is not taken into account. Finally, the together relationship between the strength of the magnetic field and the strength of the current the electromagnet due to aging and deposits of material with ma change the magnetic properties within the measuring tube.  

The invention is therefore based on the object of a magnetic inductive through flow meter for flowing media, which works with a switched DC field, to provide, which a higher measuring accuracy with significantly reduced guaranteed in the mechanical structure.

According to the invention, the previously derived and shown problem is solved by that at least one magnetic field sensor is arranged in the magnetic field of the electromagnet net and the evaluation circuit is a Ver connected to the magnetic field sensor has working circuit. The fact that now also with a magnetic-in ductive flow meter for flowing media, with a switched DC field works, the magnetic field is actually measured and not as before of a proportionality between the strength of the current through the electromagnet ten and the strength of the magnetic field is assumed, either a ma Magnetic-inductive flow meter with comparable accuracy at clearly reduced effort or a magnetic-inductive flow meter with deut Realize increased accuracy with comparable or less effort. For example, the teaching of the invention enables the use of simple Structural steel for the magnetically stressed components without compromising on measurement accuracy.

The magnetic field sensor delivers a particularly easy to evaluate signal when it is designed as a Hall sensor. The output signal of a Hall sensor is directly pro proportional to the average strength of the magnetic field, d. H. the mean magnetic In production, over the area of the Hall sensor.

A magnet that penetrates the entire surface of the flowing medium field-averaged measurement of the strength of the magnetic field is ensured in that the magnetic field sensor is designed as a reference coil, the reference coil covers the entire cross-section mentioned. Such a training of the reference In contrast to the design, the coil is only small areas of the magnet field-sensing Hall sensor possible without any problems.

Another advantageous embodiment of the magnetic inductor according to the invention ven flow meter is ensured that the magnetic field sensor in  the immediate vicinity of the measuring tube between the pole pieces of the electromagnet is arranged. This type of arrangement of the magnetic field sensor ensures Continues that this does not flow as far as possible regardless of the scattering influences of the medium penetrating magnetic field works.

Since Hall sensors in particular also, though to a much lesser extent, Refe limit coils have a temperature dependency, it is advantageous to close the Magnetic field sensor to arrange a temperature sensor, so that with the help of the Tempe ratursignals this temperature sensor, the output signal of the magnetic field sensor can be corrected.

In the event that the shape of the magnetic field changes over time, it is advantageous holds that for the location-dependent measurement of the magnetic field a plurality of magnets field sensors are provided. The output signal of this different magnet Field sensors are then used for further processing according to their arrangement weighted. With distortions in the magnetic field, the valence distribution plays in the measurement volume of the flowing medium plays an important role and is in the correction of the Measurement signal to be taken into account. The mentioned distortions of the magnetic field tre especially when ferromagnetic particles in the flowing medium are present or if the magnetic-inductive flow meter related its diameter is relatively short, so that the surrounding piping system or the flanges connected to it influence the shape of the magnetic field men.

According to a first particularly advantageous embodiment, this is the invention Magnetic-inductive flow meter characterized in that the Auswer teschaltung has a correction circuit correcting the flow signal and an output of the processing circuit with an input of the correction circuit connected is. By the measure mentioned is a correction of the Durchflußsi gnals easily possible based on the signals of the magnetic field sensor. So at for example, if the magnetic field is too strong compared to the desired magnetic field Magnetic field weighted the measuring voltage between the measuring electrodes less than with a relatively weak magnetic field.  

The correction just described is particularly advantageous in that the Cor rectification circuit on the flow signal converting analog / digital converter points and the output signal of the processing circuit at the reference input of the. Analog / digital converter is present. This configuration makes it possible to correct the Flow signal still guaranteed in the analog part of the evaluation circuit. This Correction is carried out with very little effort and without delay.

According to a second particularly advantageous embodiment, this is according to the invention ße magnetic-inductive flow meter characterized in that the current source a current regulating the direct current supplied to the electromagnet controller and an output of the processing circuit with the setpoint gear of the current controller is connected. The aim of this configuration is the magnetic field monitored by the magnetic field sensor at a constant value regardless of to keep external influences. For the optimal case in which this constant maintenance is full continuously successful, there are no further corrective measures with regard to the through flow signal necessary. However, since magnetic field fluctuations actually occur external - even short-term - influences cannot be completely ruled out, it is special advantageous, the second particularly advantageous measure just explained with the already explained first particularly advantageous embodiment of the invention to combine appropriate magnetic-inductive flow meter.

Since a coil arranged in a magnetic field, such as the reference coil, delivers a coil current that changes the magnetic flux across its surface che is proportional, it is advantageous to the processing circuit for evaluating the To provide reference coil signal with an integrator circuit. This integrator circuit delivers as the output signal a signal which, apart from an unknown con constant and known proportionality factors to the magnetic flux and thus the mean ren strength of the magnetic field corresponds. Thus the output signal is the integrator circuit suitable for correcting the flow signal.

Assigns the processing circuit in addition to the evaluation of the reference coil gnals a high-pass filter, it is ensured that in the output signal of the Ver working circuit only the time-varying portions of the measurement signal of the magnet field sensor are taken into account. After an integration, this is suitable through a  High-pass filter filtered measurement signal of the magnetic field sensor especially for correction the flow signal of the magnetic inductive flow meter according to the invention device.

In particular, there are various options for the magne according to the invention To design and further develop a table-inductive flow meter. This will referred on the one hand to the claims subordinate to claim 1, on the other hand to the description of preferred embodiments in Ver binding with the drawing. In the drawing shows

Fig. 1 shows schematically an embodiment of a magnetic flow meter according to the invention diagrammatically inductive,

Fig. 2 shows a circuit of an embodiment of the supply to the electromagnet of a flow meter according to the invention the nenden current source,

Fig. 3a, b time-dependent diagrams for the course of the current flowing through the electromagnet currents, the strength of the magnetic field generated by the electromagnet and the integrated measuring signal a magnetic field sensor at a relatively low field frequency of the switched DC field and

Fig. 4a-d time-dependent diagrams of the course of the currents flowing through the electromagnet and the strength of the magnetic field generated by the electromagnet, the measurement signal of the magnetic field sensor, the filtered measurement signal of the magnetic field sensor and the filtered, integrated measurement signal of the magnetic field sensor at a relatively high field frequency for the switched constant field.

In Fig. 1 of the drawing, an embodiment of a magnetic table inductive flowmeter for flowing media is shown. From this exemplary embodiment has a measuring tube 1 , one of the generation of a perpendicular to the measuring tube axis magnetic field serving electromagnet 2 , two ent long a perpendicular to the measuring tube axis and the magnetic field direction connecting line arranged measuring electrodes 3 , 4 , one of the supply of the electromagnet 2 with a switched Direct current source 5 and a flow signal that evaluates the measuring voltage of the measuring electrodes 3 , 4 generate the evaluation circuit 6 . According to the illustrated electromagnetic flow meter is characterized in that two magnetic field sensors 7 , 8 are arranged in the magnetic field of the electroma 2 and the evaluation circuit 6 has a processing circuit 9 connected to the magnetic field sensors 7 , 8 .

The embodiment shown in Fig. 1 of a magnetic-inductive flow meter has two magnetic field sensors 7 , 8 , which are guided as reference coils and are arranged between the pole pieces 10 , 11 of the electromagnet 2 . As an alternative to designing the magnetic field sensors 7 , 8 as reference coils, they can, as already mentioned, also be designed as Hall sensors. The reference coils are presently preferably designed so that their diameter corresponds to the diameter of the coils 12 , 13 of the electromagnet 2 , so that the proportion of the magnetic field that penetrates the flowing medium also passes through the reference coils.

The evaluation circuit 6 of the embodiment shown in Fig. 1 for a he inventive magnetic-inductive flow meter has a measuring voltage between the measuring electrodes correcting, a flow signal emitting correction circuit 14 , which is connected to an input with an output of the processing circuit 9 Ver. Thus, the correction circuit 14 is available as an input signal, a signal proportional to the strength of the magnetic field, based on which the correction circuit 14 corrects the flow signal according to the following equation:

This correction is carried out particularly simply in that the correction circuit 14 has an analog / digital converter 16 which converts the measuring voltage between the measuring electrodes 3 , 4 which is amplified by a differential amplifier 15 and to which an output signal of the processing circuit 9 is present via a reference input. The correction according to Eq. 1 already in the analog part of the evaluation circuit 6 .

Cumulative of the already mentioned embodiment of the evaluation circuit 6 , the current source 5 of the embodiment of a magnetic inductive flow measuring device according to the invention shown in FIG. 1 has a current regulator 17 which supplies the direct current to the electromagne 2 , an output of the processing circuit 9 having the setpoint input of the Current regulator 17 is connected, so that the current through the coils 12 , 13 of the electromagnet 2 is controlled so that the strength of the magnetic field generated by the electromagnet 2 remains constant regardless of external influences. The actual supply of the spools 12 , 13 of the electromagnet 2 takes place via a reversible H circuit 18 within the current source 5 .

In the event that the magnetic field sensors 7 , 8 are designed as reference coils, the processing circuit 9 has at least one integrator circuit 19 and preferably a high-pass filter 20 for evaluating the reference coil signal. The exact function of the integrator circuit 19 and the high-pass filter 20 will be explained in more detail later with reference to FIGS . 3 and 4.

The current source 5 shown only schematically in FIG. 1 is shown in detail in FIG. 2 as a circuit. As already mentioned, the current source 5 has a current regulator 17 and an H circuit 18 . The H circuit 18 is controlled to generate the switched DC field from a clock generator 21 and has four electronic switches 22 for controlling the solenoid Darge 12 presented here for the sake of simplicity. A controllable constant current source 23 serves as the current source in the actual sense of the current source 5 shown in FIG. 2. This controllable constant current source 23 is controlled by the current controller 17 , which is connected to an erasable via an electronic switch 24 , preferably arranged in the processing circuit 9 integrator 25 via a resistor 26 and an electronic switch 27 . The input of the integrator 25 is connected in the simple representation, via an electronic switch 28, to the output of a magnetic field sensor 7 designed as a reference coil.

In Fig. 3 is now the course of the preferably across the magnetic field cross-section strength of the magnetic field, that is, the course of the magnetic induction B, the. The course of the coil current I _sp through the coils in Fig. 3a and the course of the inte grated output voltage of a reference coil located in the magnetic field in Fig. 3b shown for the case that the field frequency of the switching of the magnetic field is relatively low. The relatively low field frequency when switching the magnetic field entails that the magnetic induction in the hatched measurement intervals shown in FIG. 3, during which the measurement voltage is recorded, no longer changes. In this case, it is sufficient to correct the measuring voltage applied to the measuring electrode if the stroke of the magnetic induction B is used for the correction. The stroke of the magnetic induction B results in a simple way as follows:

With
U _ref = reference voltage of the reference coil.

In Fig. 4, on the other hand, the case is shown that the field frequency for switching the DC field is so high that the magnetic induction B has not yet reached saturation at the end of a measuring interval. This is shown in Fig. 4a. In this case, as shown in FIG. 4b, the integrated reference voltage of the reference coil also changes within the measurement intervals shown hatched in FIG. 4. In this case, it is advantageous if only the AC voltage component of the reference voltage of the reference coil shown in FIG. 4c is now integrated, which is obtained after filtering the reference voltage of the reference coil by a high-pass filter. In the integration of this in Fig. 4c Darge signal obtained, as shown in Fig. 4d, again a signal for the magnetic induction B, which is then also suitable for the correction of the measuring voltage applied to the measuring electrode, if this while the measuring interval is still changing.

It should finally be mentioned that when switching through the coils of the electromagnet flowing current occurring surge, which in turn by Remanence leads to an increase in magnetic induction, not an error conditional in the flow signal, since this automatically comes over the integral formation is pensated.

Claims (11)

1. Magnetic-inductive flow meter for flowing media, with a measuring tube ( 1 ), one of the generation of an at least substantially perpendicular to the measuring tube axis magnetic field serving electromagnet ( 2 ), at least two along an at least substantially perpendicular to the measuring tube axis and the magnetic field direction extending connecting line arranged Messelektro the ( 3 , 4 ), one of the supply of the electromagnet ( 2 ) with a switched DC current source ( 5 ) and the measuring voltage of the Messelektro the ( 3 , 4 ) evaluating, a flow signal generating evaluation circuit ( 6 ), characterized in that at least one magnetic field sensor ( 7 , 8 ) is arranged in the magnetic field of the electromagnet ( 2 ) and the evaluation circuit ( 6 ) has a processing circuit ( 9 ) connected to the magnetic field sensor ( 7 , 8 ). 2. Magnetic-inductive flow meter according to claim 1, characterized in that the magnetic field sensor ( 7 , 8 ) is designed as a Hall sensor. 3. Magnetic-inductive flow meter according to claim 1, characterized in that the magnetic field sensor ( 7 , 8 ) is designed as a reference coil. 4. Magnetic-inductive flow meter according to one of claims 1 to 3, characterized in that the magnetic field sensor ( 7 , 8 ) in the immediate vicinity of the measuring tube ( 1 ) between the pole pieces ( 10 , 11 ) of the electromagnet ( 2 ) is arranged. 5. Magnetic-inductive flow meter according to one of claims 1 to 4, characterized in that a temperature sensor is arranged in the vicinity of the magnetic field sensor ( 7 , 8 ). 6. Magnetic-inductive flow meter according to one of claims 1 to 5, characterized in that a plurality of magnetic field sensors ( 7 , 8 ) is provided for location-dependent measurement of the magnetic field. 7. Magnetic-inductive flowmeter according to one of claims 1 to 6, characterized in that the evaluation circuit ( 6 ) has a correcting the flow signal correction circuit ( 14 ) and an output of the processing circuit ( 9 ) with an input of the correction circuit ( 14th ) connected is. 8. Magnetic-inductive flow meter according to claim 7, characterized in that the correction circuit ( 14 ) has a flow signal converting analog / digital converter ( 16 ) and the output signal of the processing circuit ( 9 ) at the reference input of the analog / digital converter ( 16 ) is present. 9. Magnetic-inductive flow meter according to one of claims 1 to 8, characterized in that the current source ( 5 ) has a the current regulator ( 17 ) supplied to the electromagnet ( 2 ) direct current regulator ( 17 ) and an output of the processing circuit ( 9 ) with the setpoint input the current controller ( 17 ) is the verbun. 10. Magnetic-inductive flow meter according to one of claims 3 to 9, characterized in that the processing circuit ( 9 ) for evaluating the reference coil signal has an integrator circuit ( 19 ). 11. Magnetic-inductive flow meter according to claim 10, characterized in that the processing circuit ( 9 ) for evaluating the reference coil signal has a high-pass filter ( 20 ).