DE2815664A1 - Float flowmeter with tapered tube - has calculator delivering nonlinear intermediate signal converted into linear rate of flow output signal - Google Patents

Abstract

An equilibrium is achieved between the weight of a float in a tapering tube and the upward driving force and resistance. The float height is measured and converted into a signal linearly varying with the rate of flow. The flowmeter has an evaluation device (15) through which the fluid density (phi) and viscosity (eta) are applied to a calculator (14) which calculates from them and the float (11) height (h) an intermediate signal corresponding to the rate of flow (Q). A function convertor (17) converts the nonlinear intermediate signal into a linear output signal which is displayed.

Description

Variable area flow meter

The invention relates to a variable area flow meter in which in an upwardly widening, essentially vertically arranged measuring tube a float movable along the Neßrohrachse of one of the measuring tube of can be raised to a height at which the fluid flowing through the bottom upwards between the downward gravity on the one hand and the upward acting Resulting from the buoyancy force and the drag force in the flowing measuring tube on the other hand, an equilibrium is established, the height of the float being detected and is converted into a signal that changes linearly with the flow rate.

Such a variable area flow meter is disclosed in DE-PS 2,236 588 known. In this known device, linearization is basically used achieved the display, but with the disadvantage that on the one hand the required technical equipment is relatively complicated and on the other hand this known linearization device in each case according to the device properties of the respective variable area flow meter just resulting non-linearity must be adjusted and adjusted.

It is also from the magazine "Regelstechnik", 1959, issue 10, pages 355 to 360 basically known because; 'di) yqn a variable area flow meter determined the pressure to a large extent also from the density and viscosity of the substance to be measured depends. Therefore not only the displayed measured value had to be taken into account afterwards the respective density and / or viscosity must be corrected, but it also had to be corrected the linearization device can be re-adjusted. From the magazine mentioned above "Control engineering" are calibration factor tables to simplify such corrections known, however, the necessary corrective action can only be taken by qualified personnel trained in measurement technology. as well Requires readjustment of the linearization device in addition to detailed Knowledge of the Bach language requires great skill and a considerable investment of time. Like the practical Experience has shown, therefore, is usually both the consideration of density and viscosity as well as the necessary readjustment of the linearization device depending on the respective density and viscosity. But this means that in many cases the measurement results were unsatisfactory.

The invention is based on the A u f g a b e, a variable area flow meter to create the type mentioned at the beginning, in which with one constant good linear display characteristic of the flow rate reading for a practical arbitrarily predeterminable measuring substance also with changing density and / or viscosity particularly high accuracy is displayed directly.

To solve this problem, the invention provides that a measured value detection device is provided, via which a computing device the density and viscosity of the wet substance can be supplied, so that the computing device from the device properties on the one hand and the bonded material detected by the measured value detection device on the other hand, according to the method known per se for the respective Height of the float, an intermediate signal corresponding to the flow rate is calculated and that a function converter is present which compensates for the intermediate signal the variable area flow meter's own non-linear dependence of the height of the float from the flow into the jit the flow changing linearly signal converts which can be displayed as an output signal on a display device.

Advantageous developments and preferred embodiments of the Subject of the invention result from the subclaims.

According to the invention, the main advantage can be achieved that the Measurement accuracy can be increased considerably by the fact that the interference is caused by fluctuating density and / or viscosity can be eliminated. At the same time is through the variable area flow meter according to the invention the application of a individual device considerably enlarged because of the improved measurement accuracy a variable area flow meter according to the invention, for example, also in one Control loop can be used in which there is a need that a The measured flow value is further processed directly, provided that that placed extremely high demands on the accuracy of the measured value will.

Furthermore, the invention makes use of the knowledge that considerable Allow advantages to be achieved by first generating an intermediate signal, which is proportional to the height of the float and which is only then one Linearization in a function converter is subjected to appropriate corrections have already been carried out to take account of density and viscosity.

With this method of operation there is the advantage that the linearized Signal does not have to be corrected again afterwards, which means after the previous one Working method, the effort for a linearization is at least partially in question again was asked.

In many cases this is the density and / or the viscosity of the medium to be measured known with sufficient accuracy so that a satisfactory accuracy can be achieved can, if the known values are set manually on the measured value acquisition device will.

However, if the density and viscosity with greater fluctuations and various measuring materials not with the necessary accuracy and safety are known, provides a particularly preferred embodiment of the subject matter of the invention before that these influencing variables via a corresponding measuring device on the material to be measured determined itself and fed to the variable area flow meter according to the invention will. In this preferred embodiment, the variable area flow meter according to the invention is suitable particularly good for a largely automated measuring operation and also for use in control loops.

Furthermore, the variable area flow meter according to the invention has proven itself therefore particularly advantageous, depending on the application, a pneumatic, electrical or, in principle, another measuring signal can be supplied, in order to take into account the respective requirements of further processing.

The invention is explained below, for example, with reference to the drawing described; these show: FIG. 1 a schematic representation of the principle of a preferred embodiment of the subject matter of the invention and FIG. 2 a corresponding one Representation as in FIG. 1, but with an alternative embodiment of the Subject of the invention is illustrated.

In Fig. 1, the float 11 is in the measuring tube 10 on a Height h shown against a reference level hg.

The float 11, which is concentric to the measuring tube axis 12 is arranged in the measuring tube 10, is of the (not shown) medium in the line 20 shown schematically raised to such a height h that between gravity on the one hand and buoyancy and drag on the other hand, an equilibrium is established in the flowing medium. The rate of descent of the float and the flow rate of the medium are only up a certain height h equal to each other, at a certain flow rate Q. The height h is related to the upper edge of the float, which is used as the reading edge can be designated.

The computing device 14 works according to that from the above Journal "control engineering" well-known method to the dependence of the flow Q of the height h, the density 9 and the viscosity% must be taken into account. The concentration 3 and the viscosity fl are determined in a measured value acquisition device 15, which has corresponding known measuring devices for these sizes, which at the line 20 are connected. The measured value acquisition device 15 delivers its Output signals for further consideration according to the method known per se to the computing device 14. At the output of the computing device 14 there is an intermediate signal available, which is directly proportional to the height h. This intermediate signal is fed to the function converter 17, which contains the variable area flow meter basically compensates for its own non-linear characteristic.

Since it is useful in most cases to include this compensation in the Way to carry out that at the output of the function converter 17 a linearized Signal is available, could possibly also be a quadratic dependency or any other desired characteristic is provided will, if this should be appropriate for further processing.

The overview is greatly increased, especially for a direct display, when the output signal of the function converter 17, which the desired flow measurement value represents, are brought to display on an analog display device 18 can, which has a linearly divided scale.

According to Fig. 2 is in an alternative embodiment of the subject matter of the invention provided that, in contrast to the arrangement according to FIG. 1, the density Z and the viscosity X is set by hand on a measured value acquisition device 16 can be. For many applications, such an embodiment of the invention Variable area flow meter meet the requirements, and this embodiment is characterized by the fact that it is particularly simple and inexpensive. Furthermore also takes place in the embodiment according to FIG. 2, the formation of an intermediate signal, in which to increase the measurement accuracy, the influences of density and viscosity are taken into account. This intermediate signal is then used in a function converter 17 subjected to a linearization or transformed in such a way that a predetermined dependency of the measured flow value is given by the height h.

In the alternative embodiment according to FIG. 2, the function converter is connected 17 a digital display device 19 is connected. Of course the output signal could of the function converter 17 can also be further processed directly instead of in the display device 19 to be shown.

In principle, of course, both a visual display and also at the same time further processing of the output signal from function converter 17 be performed.

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Claims (12)

P a t e n t a n s r p ü c h e 1. Variable area flow meter, at that in an upwardly expanding, essentially vertically arranged measuring tube a float movable along the measuring tube axis of one of the measuring tube of measuring material flowing through the bottom upwards is attached to a height at which between the downward-directed gravity on the one hand and the upward-reaching force They result from the buoyancy force and the resistance force in the flowing medium on the other hand, an equilibrium is set, whereby the height of the float is detected and is converted into a signal that changes linearly with the flow rate, thereby G e -k e n n n z e i c h n e t that a measured value acquisition device (15, 16) is provided is, via which a computing device (14) the density (#) and the viscosity (#) of the measuring substance can be supplied, so that the computing device (14) from the device properties on the one hand and the pulp properties detected by the measured value detection device on the other hand, according to the method known per se for the respective height (h) of the floating body (11) an intermediate signal corresponding to the flow rate (Q) calculated and that a function converter (17) is present, which the intermediate signal compensating for the non-linear dependency inherent in the variable area flow meter the height (h) of the float (11) from the flow into that with the flow itself linearly changing signal converts which as an output signal on a display device can be represented. 2. Variable area flow meter according to claim 1, characterized in that that the measured value acquisition device (15) is a measuring device for the density (#) and the viscosity (V) which are connected to the line (20), in which the measuring tube (10) is installed, and that at the output of the measured value acquisition device (15) one representative each for density (#) and one for viscosity (#) Signal can be tapped. 3. variable area flow meter according to claim 2, characterized in that that the output of the measured value acquisition device (15) to the computing device (14) is connected. 4. variable area flow meter according to claim 1, characterized in that that in the measured value acquisition device (16) the density (#) and the viscosity (X) of the medium flowing through the line (20) can be entered by hand. 5. variable area flow meter according to claim 4, characterized in that that the measured value acquisition device (16) is connected to the computing device 614) is. 6. variable area flow meter according to one of the preceding claims, characterized in that the display device is an analog display device (18) with a linear scale division. 7. variable area flow meter according to one of claims 1 to 5, acharacterized in that the display device is a digital display device (19) is formed. 8. variable area flow meter according to one of the preceding claims, characterized in that a pneumatic computing device is provided. 9. variable area flow meter according to one of claims 1 to 7, characterized in that the computing device is an electrical analog computer is. 10. Variable area flow meter according to claim 9, characterized in that that the output signal proportional to the flow rate corresponds to the standardized standard signal equals from zero to twenty milliamperes. 11. variable area flow meter according to one of claims 1 to 7, characterized in that the computing device is an electrical digital computer is. 12. Variable area flow meter according to claim 11, characterized in that that between the measured value acquisition device (15) and the computing device (14) an analog-to-digital converter is arranged.