WO2004111580A1

WO2004111580A1 - Magnetically induced flowmeter

Info

Publication number: WO2004111580A1
Application number: PCT/EP2004/006316
Authority: WO
Inventors: Steen Møllebjerg MATZEN; Per Mondrup
Original assignee: Siemens Aktiengesellschaft
Priority date: 2003-06-12
Filing date: 2004-06-11
Publication date: 2004-12-23
Also published as: DE10326374A1

Abstract

The invention relates to a magnetically induced flowmeter (1) comprising a measuring section (2), a magnetic field generating device (12, 4, 5) for generating a magnetic field (6) perpendicular to the measuring section (2), an electrode array (7, 8) arranged perpendicular to the measuring section (2) and perpendicular to the magnetic field (6) and an evaluation device (9) comprising a booster (10) and a control device (11). The aim of the invention is to improve the accuracy of the flowmeter. This is achieved in that the evaluation device (9) has an amplification for the alternating current components which is different from that of direct current components of a signal from the electrode array (7, 8).

Description

description

Magnetic-inductive flow meter

The invention relates to a magnetic-inductive flow meter with a measuring section, a magnetic field generating device for generating a magnetic field perpendicular to the measuring section, an electrode arrangement which is arranged perpendicular to the measuring section and perpendicular to the magnetic field, and an evaluation device which has an amplifier and a control device.

Such a flow meter is known for example from US 4,704,908. If a fluid flows through the measuring section and a magnetic field is generated, then a voltage arises between the electrodes of the electrode arrangement, which voltage can be evaluated by the evaluation device. The magnetic field generating device is operated in such a way that the magnetic field is directed alternately in opposite directions. Accordingly, the sign of the voltage present between the electrodes of the electrode arrangement is also reversed. Certain errors can then be suppressed by averaging over time (or another evaluation) of the inverted voltages.

Another flow meter is known from EP 1 030 168 Al. The evaluation device brings about a high suppression of a common mode signal and a high suppression of low-frequency components in the difference signal. This is achieved in that the evaluation device is equipped with a preamplifier, which is a differential preamplifier.

In certain areas of application, a flow meter of the type mentioned at the outset is not operated continuously. The magnetic field is therefore only generated from time to time. The evaluation device is also not switched on continuously. A Such an operating mode is selected in particular in the case of battery-operated flow meters in order to save energy. However, flow meters in which a measurement signal can only be taken from time to time due to an unfavorable spatial arrangement can also be operated in this way.

In such an operating mode, the problem arises that the signal that can be picked up at the electrodes of the electrode arrangement contains not only an AC voltage component, which essentially contains the information of the measurement signal, but also an undesired DC voltage component. This DC component can be much larger than the AC component. For example, the DC voltage component can be up to several 100 millivolts, which is a lot compared to the AC voltage component, the amplitude of which is of the order of 10 microvolts. One would now like to have the AC signal amplified by the amplifier. However, the amplifier also amplifies the DC voltage signal. Due to the large DC voltage signal, the amplifier then comes relatively quickly into a saturation range, i. H. the output signal of the amplifier is no longer linearly related to the AC component.

It is theoretically possible to filter out the AC signal with a high pass filter. However, this procedure is complex and is not always associated with success. The time during which the preamplifier is active is short compared to the time constant of a high-pass filter and therefore the desired attenuation of the DC voltage signal is not achieved.

The invention has for its object to provide a flow meter with improved accuracy.

With a flow meter of the type mentioned at the outset, this object is achieved in that the evaluation device has a different gain for AC and DC components of a signal from the electrode arrangement.

The procedure avoids overloading the amplifier. The DC voltage components are amplified with a significantly lower gain factor than the AC voltage components, theoretically with a factor of zero. The AC voltage components are amplified significantly more than the DC voltage components. This prevents the amplifier from reaching a saturation range. The relationship between the input signal and the output signal of the amplifier remains more controllable. This results in improved accuracy.

The evaluation device preferably has a DC voltage removal device. This term is to be understood functionally. Of course, a DC voltage cannot be easily removed. However, the DC voltage removal device ensures that the DC voltage component of the measurement signal, which is picked up between the electrodes of the electrode arrangement, is only supplied to the amplifier to a reduced extent. Accordingly, the amplifier can only amplify the DC voltage component to a reduced extent.

It is also advantageous that the control device does not initiate any action on the magnetic field generating device until after the DC voltage signal has been sampled and that a new scan is carried out before each measurement period.

The DC voltage removal device is preferably arranged in front of the amplifier. The DC voltage removal device is thus connected to the input of the amplifier in such a way that the DC voltage is only present at the input with a fraction of its original value. In theory, the same voltage is at the invert and at the non-inverting input so that the differential voltage to be amplified is zero and is not amplified. Accordingly, the amplification of the direct voltage component, measured on the original direct voltage component, is substantially less than the amplification of the alternating voltage component.

The DC voltage removal device preferably has a switched memory which is connected to a non-inverting input of the amplifier. The memory, for example a capacitor, therefore stores the DC voltage and feeds it to the non-inverting input of the amplifier. If a measuring cycle then takes place, the "complete" signal between the electrodes of the electrode arrangement can be fed to the inverting input of the amplifier, i. H. a signal that contains both the AC component and the DC component. The amplifier amplifies the difference between the inverting and the non-inverting input. Since DC components of approximately the same size are present at the inverting and non-inverting inputs, the DC voltage component is practically not amplified. There remains an amplification of the AC voltage component.

The control device preferably initiates an application of the magnetic field generating device only when a rate of change of the DC voltage at the amplifier falls below a predetermined value. One therefore waits until the memory is charged to such an extent that the stored value corresponds in principle to the DC component of the measurement signal. For example, since a capacitor charges according to an exponential function, it would take a relatively long time for the capacitor's charging voltage to match the DC voltage. So you allow a certain mistake. If the voltage across the capacitor practically no longer changes, it is assumed that the desired conditions have been met, i.e. during the following period the DC component of the measurement signal is supplied to the non-inverting input. In this case it is possible to start a measuring cycle and generate the magnetic field.

The control device preferably controls the magnetic field generating device in such a way that it generates different magnetic field directions at different times. With this technique, which is known per se, certain disturbances can be filtered out.

It is particularly preferred that the control device controls the magnetic field generating device in such a way that in a first measurement period a magnetic field is generated first in a first direction and then in a second direction and in a subsequent measurement period first in the second direction and then in the first direction. and the output signal of the two measurement periods is linked to one another. The first and the second direction of the magnetic field are opposite to each other. If you do not generate the same sequence of magnetic field blocks in each measurement period, but invert this sequence, so to speak, you can also compensate for phenomena that result from a non-linear component of a DC voltage component. This non-linear component can result, for example, from the fact that the voltage at the memory, for example the capacitor mentioned above, does not remain constant, but rather this voltage does not decrease linearly, for example after an e-function.

A voltage boost circuit is preferably provided which raises the output signal of the amplifier into a region around the center of a supply voltage region. This provides favorable evaluation conditions for the output signal of the amplifier. The invention is described below with reference to a preferred embodiment in connection with the drawing. Show here:

Fig. 1 is a schematic representation of a magnetic-inductive flow meter and

Fig. 2 is a schematic representation of an evaluation device.

A magnetic-inductive flow meter 1 has a measuring section 2 which is formed in a tube 3. The tube 3 has an extent perpendicular to the plane of the drawing in FIG. 1. Accordingly, the measuring section 2 is flowed through perpendicularly to the plane of the drawing by a fluid, for example a liquid.

A magnetic field generating device with two coils 4, 5 generates a magnetic field 6 symbolized by a double arrow perpendicular to the direction of flow through the measuring section 2. The coils 4, 5 are controlled in such a way that the magnetic field has a first direction in a certain time period, for example from bottom to top (based on the representation of FIG. 1), and in a second period the opposite direction. The ^• periods can be of the order of several 10 ms. Basically, you create a low-frequency alternating field.

Furthermore, two electrodes 7, 8 are provided which form an electrode arrangement which is arranged perpendicular to the measuring section 2 and perpendicular to the magnetic field 6. If a fluid, for example a liquid, now flows through the measuring section 2 and a magnetic field is present, then a voltage arises between the two electrodes 7, 8. This voltage has the same, relatively low frequency as the magnetic field. This voltage is fed to an evaluation device 9. The evaluation device 9 has a reinforcement device 10. Furthermore, the evaluation device 9 has a control device 11 which controls the amplifier device 10 and a coil driver device 12.

The amplifier device 10 will now be described in connection with FIG. 2.

The electrode arrangement with the two electrodes 7, 8 is shown as a generator V _E , which is formed by a direct voltage generator 13 and an alternating voltage generator 14. The AC voltage generator 14 is intended to generate the AC voltage mentioned above. The output of the voltage generator V _E is fed to an amplifier 15 which has an inverting input 16 and a non-inverting input 17. The amplifier 15 amplifies the voltage difference between the inverting input and the non-inverting input 17, the amplification factor being determined by a ratio between a resistor R1, which is arranged between an output 22 of the amplifier 15 and the inverting input 16, and a resistor R2 between the input 16 of the amplifier 15 and the generator V _E. The ratio R1 / R2 can be 20, for example.

With this configuration, the problem arises that the amplifier 15 is overdriven if the DC voltage component of the DC voltage generator 13 is significantly larger than the AC voltage component of the AC voltage generator 14. Such a situation occurs, for example, when the evaluation device 9 is switched on. This may be due to the fact that an electrical charge layer must first build up on the electrodes 7, 8. The DC voltage component can be up to several 100 millivolts, which is a great deal in comparison to the AC voltage signal from the AC voltage generator 14. The following procedure is therefore used to amplify the AC voltage components and the DC voltage components from the voltage generator V _E , ie the voltage between the electrodes 7, 8, with different amplifications.

The non-inverting input 17 is connected to a capacitor 18 as a memory, which is otherwise connected to ground 19. The capacitor 18 is charged via a switch 20 with a voltage from a voltage divider R3, R4, which receives its voltage from the voltage generator VE. The switch 20 is actuated by the control device 11.

Shortly before the coils 4, 5 are supplied with current in order to generate the magnetic field, the switch 20 is closed by the control device 11. A signal S, i.e. H. the voltage between the electrodes 7, 8 runs through the resistor R3 of the voltage divider R3, R4 and the switch 20 to the capacitor 18 and to the non-inverting input 17. This signal S contains the DC voltage component and the AC voltage component mentioned, but which is considerably smaller than that Is DC component and is essentially formed by a noise signal from the measuring electrode 7, 8. The signal S does not yet contain a measurement signal, because this is only generated later by the magnetic field 6 which is not yet present.

The switch 20 forms, together with the capacitor 18, a kind of sample and hold element. The switch 20 remains closed until the capacitor 18 is charged. The charging time is determined by a time constant which results from the parallel connection of R3 and R4 and the capacitor 18. The switch 20 is kept closed until the voltage across the capacitor 18 no longer changes or does not change noticeably, ie until it has the same amplitude as at the input of the switch 20. The switch 20 then opens. A voltage is present via the capacitor 18 which is the same (or approximately the same) as the DC amplitude at inverting input 16.

The DC voltage component is therefore practically the same at inverting input 16 and at non-inverting input 17, so that there is no difference that can be amplified. An output voltage VO1 of the amplifier 15 is therefore zero. Now the actual flow measurement can begin. The control device 11 puts the coil driver device 12 into operation, which generates a magnetic field with changing directions. For this purpose, it is only necessary to apply current to the coils 4, 5, which current runs in opposite directions.

The signal S, which contains an alternating voltage, which is a function of the flow, can now be taken off at the electrodes 7, 8. This signal is fed to the inverting input 16 of the amplifier 15. The connection to the non-inverting input 17 has been interrupted by opening the switch 20. This creates a differential voltage at the input of the amplifier 15 and this voltage is amplified as desired. The gain factor in the present example is R1 / R2 = 20. The output signal VO1 can then be evaluated, for example with an A / D converter.

The circuit shown in FIG. 2, so to speak, achieves a selective amplifier which only reacts to AC signal components. As described above, the scanning of the DC voltage level is carried out shortly before each magnetic field generation.

A double circuit is shown in the lower half of FIG. 2. Elements that correspond to the upper half are provided with deleted reference numerals. The deleted elements are all the same size as the non-deleted elements. A reference voltage R is used to raise the signal S to a range approximately in the middle of the positive voltage range generated by the voltage supply V28. As a result, an A / D converter with single supply can subsequently be operated. The reference voltage generator R also consists of a DC voltage generator 21 and an AC voltage generator 22. In this case, the AC voltage generator 22 is a symbol for a noise signal. This noise signal can be generated, for example, by electromagnetic radiation. Here only the DC voltage generator 21 is to be used in order to be able to raise the voltage S correspondingly in terms of voltage. The fact that the circuit is mirrored, so to speak, suppresses the noise component of the generator 22.

In a manner known per se, the coils 4, 5 are operated such that a magnetic field is first generated in one direction, for example from top to bottom, and then in the other direction, for example from bottom to top. In order to simplify the explanation, this is referred to below as "positive magnetic field block" and "negative magnetic field block".

A small pause is left between the individual magnetic field blocks, the length of which can correspond, for example, to the length of the magnetic field blocks.

In successive measurement periods, however, the same sequence of magnetic field blocks is not used, but this sequence is inverted. For example, one can have a course in a first measurement period: pause - positive magnetic field block - pause - negative magnetic field block and in a second measurement period the sequence: pause - negative magnetic field block - pause - positive magnetic field block. The output signal VO1 of the amplifier 15 is now averaged on the one hand in each measurement period and on the other hand over two successive de measurement periods. This can take into account the fact that the voltage across the capacitor 18 may drop exponentially under certain circumstances. This would normally lead to a falsification of the measurement result. This problem is largely alleviated by inverting the sequence of the magnetic field blocks.

Claims

claims

1. Magnetic-inductive flow meter with a measuring section, a magnetic field generating device for generating a magnetic field perpendicular to the measuring section, an electrode arrangement that is arranged perpendicular to the measuring section and perpendicular to the magnetic field, and an evaluation device that has an amplifier and a control device, characterized in that the evaluation device (9) has a different gain for AC and DC components of a signal (S) from the electrode arrangement

(7, 8).

2. Flow meter according to claim 1, characterized in that the evaluation device (9) has a DC voltage removal device (18, 20).

3. Flow meter according to claim 2, characterized in that the DC voltage removal device (18, 20) is arranged in front of the amplifier (15).

4. Flow meter according to claim 2 or 3, characterized in that the DC voltage removal device (18, 20) has a switched memory (18) which is connected to a non-inverting input (17) of the amplifier (15).

5. Flow meter according to one of claims 1 to 4, characterized in that the control device (11) only acts upon the magnetic field generating device (4, 5, 12) after a sampling of the DC voltage signal and that a new sampling is carried out before each measurement period.

6. Flow meter according to one of claims 1 to 5, characterized in that the control device (11) is only applied to the magnetic field generating device (12, 4, 5) then initiates when a rate of change of the DC voltage at the amplifier (15) falls below a predetermined value.

7. Flow meter according to one of claims 1 to 6, characterized in that the control device (11) controls the magnetic field generating device (12, 4, 5) so that it generates different magnetic field directions at different times.

8. Flow meter according to claim 7, characterized in that the control device (11) controls the magnetic field generating device (12, 4, 5) so that in a first measuring period a magnetic field first in a first direction and then in a second direction and in a subsequent one Measurement period is first generated in the second direction and then in the first direction, and the output signal of the two measurement periods is linked.

9. Flow meter according to one of claims 1 to 8, characterized in that a voltage boost circuit (R) is provided, which raises the output signal of the amplifier (VOl) in a range around the center of a supply voltage range (V28, V29).