DE2950084C2 - Magnetic-inductive flow meter - Google Patents

Description

Influence can exert more, and that also the flow of liquids can be measured with sufficient accuracy is whose conductivity in the direction of flow and transversely thereto under the influence of temperature and Flow is subject to different changes

The solution to this problem is seen in the features of the claims.

Characterized in that, according to the features of claim 1, the two opposite measuring electrodes are connected to the high-resistance input each of an impedance converter with a high-resistance input and a low-resistance output and the electrodes provided in the flow direction upstream and downstream of the measuring electrode pair are electrically connected to the low-resistance output of the impedance converter stand, the measured high-resistance signal is converted into a low-resistance signal. The decoupled signal is then supplied to a display device the same time, the decoupled via the impedance transducer signal but is also supplied to the auxiliary electrode This has the consequence that at the resistors Rl exactly the same voltage drops as at the measuring electrodes, namely, the voltage UE Thus there but the Additional electrodes have the same voltage as on the measuring electrodes. As a result, there is no longer any voltage at the resistors R _v , so that the current / i flowing through these resistors becomes zero, ie the resistors R _L and R _x are no longer included in the measurement voltage. If the input of the impedance converter has a sufficiently high resistance, no current flows in the measuring branch, so that the voltage Ue applied to the measuring electrodes is equal to the measuring voltage U _M

Since the liquid can no longer flow current through the resistors R _v , the measuring voltage source is no longer additionally loaded by these resistors. The measuring voltage can therefore be measured more sensitively and more accurately. Since the size of the resistances Rl or R _{v is} no longer included in the measurement result, the length of the magnetic field no longer plays a role. With the flow of liquids, the conductivity of which changes differently with the temperature and with the flow, ie in which the resistance values Rv and Rl are not proportional to each other with the same sign, calibration errors no longer occur, since the values of these resistances no longer occur are included in the measurement result.

It is advantageous if the additional electrodes are arranged mirror-symmetrically to the measuring plane. It is also advantageous if in the planes parallel to the measuring plane in which the additional electrodes are located several such additional electrode pairs are arranged because of the different arrangement of these Additional electrodes, the voltage distribution in the cross section of the additional electrodes can be influenced can. For example, it is also expedient to design the additional electrodes as flat bodies, their The contour of the inner wall of the pipe section is adapted, the additional electrodes as symmetrical flat bodies can be formed with changing width along the contour of the inner wall of the pipe section. In addition to the advantage of being able to influence the voltage distribution, this configuration also brings the The advantage that the additional electrodes which can be introduced from the outside through the pipe section are only sealed at one point need to be because the sheet itself can be made stable enough. It is also possible and expedient to use the additional electrodes as semicircular or circular bands to train uniform or variable width. These band-shaped additional electrodes can also be made from several individual sections attached to one another can be built up.

The invention is explained using exemplary embodiments in the following description of the drawing, which represents various possible designs It shows

F i g. 1 a schematic representation of the electrical conditions (equivalent circuit diagram) of the various Resistances on a magnetic flow meter, the field of which has a certain length, 2 shows the schematic arrangement according to an exemplary embodiment of the invention,

F i g. 3 a first embodiment of the arrangement of the additional electrodes according to the invention, F i g. 4 another embodiment of the arrangement of the additional electrodes,

F i g. 5 and 6 each exemplary embodiment for training options the additional electrodes,

F i g. 7 is a side view of the additional electrodes of FIG. 5 or 6 and

Finally, FIGS. 8a and 8b show two further possibilities the arrangement of additional electrodes in a plane perpendicular to the direction of flow.

In FIG. 1 shows schematically a pipe section ί of a magnetic flow meter through which an electrically conductive liquid flows in the direction of arrow 2 at speed ν. The pipe section 1 should have a circular cross-section and it is equipped in the measuring cross-section 3 with two diametrically opposite measuring electrodes 4, on which the measuring voltage Um generated by the flowing liquid is to be detected. Not shown is a magnet coil arrangement placed around the pipe section 1 on the outside, with which a magnetic field is generated in a manner known per se, the longitudinal extent of which is intended to be limited by the two curved border lines 5. It is clear that in practice the transition between the magnetic field, which is intended to correspond to the area A within these boundary lines 5, and the two areas B outside of this magnetic field is fluid. For a better understanding, however, be of the FIG. 1 assumed arrangement.

The size of the measuring voltage U _M detected at the measuring electrodes 4, which is shown in the equivalent circuit diagram, is determined by the size of the flow velocity ν and the field strength of the magnetic field A, the field distribution over the pipe cross-section and the expansion of the magnetic field A in the direction of flow. Since the magnetic field A is spatially limited, the liquid flowing outside the magnetic field A - i.e. the liquid flowing in area B - acts as a load resistance Rl on the measurement voltage Um with the internal resistance / ?, (across the direction of flow). The resistances Λ, are the resistances of the liquid that occur in the direction of flow. From the equivalent circuit of Fi g. 1 shows that the measurement of the voltage Um is falsified by the load resistances Rl outside the magnetic field. If the ratio of these resistances shown in FIG. 1 remains constant for all flows, the error that occurs can be eliminated by calibration. However, if the ratio of the resistances changes with the flow, as is the case, for example, with the previously mentioned eeför-

If the other soap is the case, the measurement itself is made falsified and a wrong throughput indicated, since all resistances change depending on the flow, partly also with different signs.

F i g. 2 shows a possible solution by which the influence of the limited magnetic field length can be excluded, which on the one hand leads to a loss of measuring voltage and on the other hand - in the case of measuring materials whose conductivity changes depending on the flow - can lead to incorrect measurements due to the resulting calibration error . In addition to the two measuring electrodes 4 in the measuring cross-section 3, additional electrodes 6 and 7 are provided in the embodiment according to the invention in two planes upstream and downstream of the measuring plane 3 at the same distance and perpendicular to the flow direction 2 9 are each connected to the measuring electrodes 4. As a result of this configuration, the potential applied to the measuring electrodes 4 is also applied to the additional electrodes 6 and 7, so that a current from the area of the plane in which, for example, the additional electrodes 6 are arranged, and approximately the area of the position of the load resistor Rl the Fi g. 1 could not flow back to the measuring electrodes. The measurement voltage Um is therefore not influenced in this embodiment by the load resistances Rl formed by the liquid in the areas B. The measurement is therefore more accurate.

Like in the. F i g. 3 to 8b is shown, the Additional electrodes 6 or 7 can be designed in various ways or by several in each case in one or individual electrodes lying on several levels must be replaced. Thus, Fig. 3 an embodiment in which, for example the additional electrodes 6 by two symmetrically opposite one another on the pipe cross section 1 Individual electrodes 10 and 11 are formed, each for are introduced into the pipe section 1 from the outside. There is also the option of both sides a third electrode 12 to be assigned. This can reduce the value of the stress distribution in the cross-sections and can be influenced in the arrangement of the additional electrodes, which is known to be advantageous

F i g. 4 shows an embodiment in which only one additional electrode 13 is diametrically opposed to one of the same formed electrode is inserted into the pipe section 1. These electrodes 13 can be the ones shown in FIGS. 5 and 6 The sheet of FIG. 5 looks roughly barrel-shaped in plan view but according to Fig. 7 and 4 is bent according to the inner contour of the pipe section 1 according to FIG. 6th however, the cross-section can also be thinner in the middle than at the two ends, depending on the soft stress distribution over the cross-section is desired 3 has the advantage that, viewed over the cross section, a different stress distribution it becomes possible, however, that only one sealing point 14 can be provided for each of the two electrodes 13 must, through which those are introduced into the interior of the pipe section.

F i g. 8a shows a modification insofar as here a circular additional electrode 15 made of semiconducting material is shown which can be constant or variable in its cross-section. This electrode 15 forms a Voltage divider. This band-shaped electrode 15 can also, like the one in FIG. 8b indicated can be constructed from individual sections 15a of additional electrodes. These additional electrodes are either all connected to the impedance converter 9 via the connecting line 8, or they are connected via one Voltage divider at different voltages.

For this purpose 2 sheets of drawings

Claims (7)

1 2nd voltage therefore depends on the flow rate of this liquid, which enables a quantity measurement for a given pipe cross-section. 1. Magnetic-inductive flow meter with the voltage detected at the measuring electrodes depends on a pipe section surrounded by a coil arrangement, but also on the inside 5 on the field strength of the magnet coil arrangement, on the one behind the other in terms of flow, the field distribution over the pipe cross-section and flow direction several electrodes each consist of the expansion of the magnetic field in the pipe axis, diametrically opposite electrodes, ie in the direction of flow. Only with one determining electrode pairs are provided, which have the th field length, an optimum of measuring voltage with electrically conductive flowing through the pipe section is achieved the gegenüberliegen- in the SPU load resistor RL to the measuring voltage Um with their lena order (a) in a plane transverse to the flow direction acting interior Wide gestures, the pair of measuring electrodes and forming the indu- stood R, a. As a result, the electrodes (4) detecting the measuring voltage taken from the electrodes are acted upon. it occurs particularly strongly with large converters (9) with a high-resistance input and low nominal widths. An equalizing output is connected and the flow direction in front of and / or behind the plane so that the measuring voltage receives the usual value, because a larger excitation current is supplied, is provided (3) of the measuring electrode pair (4) especially with large encoders, as they are necessary as additional electrode pairs for large nominal electrodes (6, 7), uneconomical. Irish with the low-resistance output (8) the Im- Is the ratio of the resistances, d. H. so that too Pedanzwandler (9) are in connection. Ratio of the internal resistance of the liquid to the 2. Magnetic-inductive flow meter after other resistances constant and remains constant Claim 1, characterized in that the inlet 25 different flow velocities, the Set electrodes (6, 7, 10, 11) mirror-symmetrical to the effect caused by field length differences in the Measuring plane (3) are arranged. Calibration must be taken into account so that the 3. Magnetic-inductive flowmeter measured by the electrodes is always proportional to the voltage Claim 1 or 2, characterized in that is in flow velocity. But there is electric the planes parallel to the measuring plane (3) of the conductive liquids, for example soap, the hot charge electrodes several additional liquid electrodes are to be fed into heated tubes pairs (10,11,12) are arranged. which once the temperature gradient across the flow 4. Magnetic-inductive flow meter changes according to measurement cross-section and where also the Claim 1 or 2, characterized in that the conductivity is dependent on the temperature. It results in additional electrodes (13,13a; then, as surface bodies, there are defects which cannot be eliminated by calibration The edges of which are the inner wall of the pipe and which vary in size depending on the flow Piece (1) are adapted. are. For example, the resistances of the 5. Magnetic-inductive flow meter for liquid in the direction of flow other than the Wi-claim 4, characterized in that the condition is transverse to the direction of flow, so that thereby Set electrodes (13, 13a,) as symmetrical surface 40 the generated measurement voltage is changed. body with itself along the contour of the inner wall From DE-OS 22 25 356 is a magnetic-inductive of the pipe section (1) changing width formed ver flow meter with a permanent magnet are. for the generation of the magnetic field 6. Magnetic-inductive flow meter according to the one behind the other in the direction of flow Claim 4, characterized in that the supply 45 is made up of several diametrically opposed Set electrodes (15) provided as semicircular or circular electrodes existing electrode pairs shaped ribbons (15) are more uniform, all of which serve as measuring electrodes and their associated or variable width are formed. summarized measuring voltage a measure for the volume 7. Magnetic-inductive flow meter according to flow rate. The individual measuring electrodes are Claim 6, characterized in that the band 50 here via resistors to the common measuring line shaped additional electrodes made up of several connected to one another, so that a current flows from the central measuring set individual sections (15a; built-up electrodes to which are provided outside the magnetic field. henen measuring electrodes via these resistors or over the parallel to it, in the direction of flow 55 direction occurring resistance R _{v of} the liquid flows, which additionally loads the measuring voltage. Here, too, the measuring voltage is determined by the load resistance The invention relates to a magneto-inductive de Rl of the fluid flowing outside the magnetic field Reduced flow meter with a fluid flowing from a coil assembly currents. Especially at Surrounded, internally electrically insulated pipe section, to 60 liquids, whose electrical conductivity is through the diametrically opposite measuring electrodes for a temperature migrating across the flow cross-section Detection of the from an electrically conductive, the pipe temperature gradient or from a changing flow piece of liquid flowing through induced the stress profile in the direction of flow and across this un- are provided. changes differently, step through different ones here With magnetic flow meters, the change in fluid resistance results in measurement errors. Measurement voltage in a known manner in that the object of the invention is to provide a magnetically-inductive To form the measuring fluid through the flow meter, which is ductile by the coil arrangement, so that the length generated magnetic field moves. The magnitude of the induced magnetic field as far as possible does not distort it