GB2349954A - Suspended body flowmeter - Google Patents

Abstract

The flowmeter for flowing media, has a measuring tube (1), having a suspended body (2) which is disposed in the measuring tube (1) and which can move in the direction of flow, with two magnetic field sensors (10, 11) with identical measuring axes extending parallel to the tube axis outside the measuring tube (1), and an evaluation circuit for forming the difference of the output signals of the sensors as a measure of flow. An annular follower magnet, magnetised laterally with the north pole and the south pole on its coupling part which is nearer to the measuring tube (1) form an angle, preferably about 90{, may also be provided.

Description

2349954 SUSPENDED BODY FLOWMETER This invention relates to a suspended

body flowmeter for flowing media, having a measuring tube, having a suspended body which is disposed in the measuring tube and which can move in the direction of flow, having at least one permanent magnet attached to the suspended body, having at least one rotatably mounted follower magnet which is disposed outside the measuring tube and which follows the movements of the permanent magnet attached to the suspended body, and having an indicator device which converts the movements of the follower magnet, wherein the follower magnet is constructed as an annular permanent magnet.

Suspended body flowmeters have been used since the middle of the last century for determining volume and mass flows in closed pipelines. Even today, they are still to be found in about one in five flow measuring devices in the chemical and process technology industry.

In its simplest form, a suspended body flowmeter consists of a tapered measuring tube and the'suspended body. The measuring tube is a tapered tube which widens towards the top and through which the liquid or gas flow passes which is to be measured, and in which the suspended body, which is a suitably fashioned measuring body which is freely movable vertically, is situated and together with the measuring tube forms a throttle location. The density of the suspended body is higher than that of the fluid. Depending on the flow rate, the suspended body transiently takes up a defined height location in the measuring tube, which results from the equilibrium between the hydrodynamic force due to the flow, which is transmitted to the suspended body, and the difference between the weight and the buoyancy forces acting on the 2 suspended body. This height setting is either read off directly by the observer via a scale on a glass measuring tube, or is transmitted via a magnetic coupling on to an external scale and/or on to an electrical measurement recorder. The suspended body flownieter to which the preselat invention relates is one in which the height setting of the suspended body can be transmitted, by a magnetic coupling and via an external follower magnet, on to a scale and/or on to an electrical measurement recorder.

In addition to designs comprising a tapered measuring tube and spherical or sharp-edged suspended bodies, straight measuring tubes comprising a metering orifice and a tapered suspended body inside the orifice aperture can also be used. It is even possible for the measuring tube not to be disposed vertically, wherein in this situation it is necessary for the weight of the suspended body to be replaced by the spring force of a spring which acts on the suspended body. However, the present invention is independent of the possible variations in design of a suspended body flowmeter which have been described.

A suspended body flowmeter is known from the prior art (see US - A - 4, 944,190) which comprises at least one follower magnet. The follower magnet is disposed outside the measuring tube and follows the movements of the permanent magnet, which directly forms the suspended body here. This prior art follower magnet is of annular construction, and this annular follower magnet is magnetised diametrically and therefore has a north pole and a south pole which are displaced by 180'.

One problem in the prior art is that at a constant height of the suspended body the annular

3 follower magnet executes different angles of rotation depending on the nominal diameter of the measuring tube. With regard to the manufacture of suspended body flowmeters this means that, depending on the nominal diameter of the measuring tube used, either scales of different expansos have to be used for indicating the movements of the follower magnet, or other correction options have to be put into effect. Correction options such as these, which enable scales with the same spread to be used, consist of using counter-weights or auxiliary rod assemblies for example.

In principle, the problem outlined above can in fact be avoided by determining the movements of the follower magnet electronically, using magnetic field sensors, and by the subsequent correction of the different angles of rotation with the aid of an amplification factor which depends on the nominal diameter. However, this is undesirable in many cases, since it is often quite a definite advantage of a suspended body flowmeter that - in contrast to a magnetic inductance flowmeter, for example - it provides a reading even without auxiliary energy. For this reason, many suspended body flowmeters do in fact comprise an electronic measuring signal output, but at the same time do not dispense with the purely mechanical indicator.

A basic object of the present invention is therefore to fashion and further develop the known suspended body flowmeters for flowing media so that scales of the same spread can be used for the mechanical indicator without auxiliary means or means of correction.

According to the present invention there is provided a suspended body flowmeter for flowing media, having a measuring tube, having a suspended body which is disposed in the measuring tube and which can move in the direction of flow, and having at least one permanent 4 magnet attached to the suspended body, wherein two magnetic field sensors are provided, which sense the magnetic field of the permanent magent and which have identical measuring axes which extend parallel to the axis of the measuring tube, and an evaluation circuit is provided for formiN the difference of the output signals of the magnetic field sensors as a measure of the flow.

In the known suspended body flowmeter from which the present invention stems (see US A-4,944,190), the follower magnet is magnetised diametrically, as stated above. in contrast, in the suspended body flowmeter according to this invention the follower magnet is magnetised laterally. With regard to the types of magnetisation which are customary for permanent magnets, and therefore with regard to diametral magnetisation and lateral magnetisation also, reference is made to page 5 of the catalogue issued in 1991 by the company by the name of MAGNETFABRIK SCHRAMBERG GMBH & CO, of Schramberg-Sulgen.

A suspended body flowmeter for which it is unimportant whether it provides an indication without auxiliary energy can provide an electrical output signal even without a follower magent if it is designed so that two magnetic field sensors are provided, which sense the magnetic field of the permanent magnet attached to the suspended body. The aforementioned independence of external, interfering magnetic fields is again achieved according to the invention in that the magnetic field sensors have identical measuring axes which extend parallel to the axis of the measuring tube, and an evaluation circuit is provided for forming the difference of the output signals of the magnetic field sensors as a measure of the flow. The magnetic field sensors are preferably provided with magnetic field concentrators which are aligned towards the measuring tube or towards the permanent magnet attached to the suspended body. The magnetic field concentrators permit a relatively large distance to be employed between the magnetic field sensors and the measuring tube or the permanent magnet attached to the suspended body, so that the effect on the magnetic field sensors of the temperature of the medium flowing through the measuring tube is relatively slight.

In addition, it is recommended that magneto-resistive magnetic field sensors be provided for the embodiments of suspended body flowmeters described above.

In detail, numerous possibilities exist for fashioning and further developing the suspended body flowmeter according to the invention. In this respect, reference is made firstly to the claims which are subsidiary to claim 1 and secondly to the description of preferred embodiments in association with the drawings, which are as follows:

Figure 1 is a schematic vertical section. through a first embodiment of a suspended body flowmeter according to the invention; Figure 2 is a plan view of a diametrally magnetised, annular follower magnet which is 15 constructed with two poles and which is known in the art; Figure 3 illustrates a first embodiment of an annular, laterally magnetised follower magnet according to the invention; Figure 4 illustrates a second embodiment of an annular, laterally magnetised follower magnet according to the invention; 20 Figure 5 illustrates a third embodiment of an annular, laterally magnetised follower magnet 6 according to the invention; Figure 6 is a schematic illustration of two suspended body flowmeters in combination with follower magnets which are known from the prior art;

Figure 7 is a horizontal section through a first embodiment of the suspended body flowmeter according to the invention; Figure 8 illustrates a second embodiment of the suspended body flowmeter according to the invention, in which measuring tubes of different nominal diameters are indicated; Figure 9 is a side view, shown partly in section, of a third embodiment of a suspended body flowmeter according to the invention, in combination with an indicator device which provides an electrical measuring signal; and Figure 10 is a side view, shown partly in section, of a fourth embodiment of a suspended body flowmeter according to the invention, in which a follower magnet is dispensed with.

The basic construction of a suspended body flowmeter according to the invention is clearly shown by the illustration of a first embodiment in Figure 1. This suspended body flowmeter comprises a measuring tube 1, a suspended body 2 which is disposed in the measuring tube 1 and which can move in the direction of flow, a permanent magnet 3 disposed in the suspended body 2, a rotatably mounted follower magnet 4 which is disposed outside the measuring tube 1 and 7 which follows the movements of the permanent magnet 3 disposed in the suspended body 2, and an indicator device, which is constructed as a pointer 5 here, and which converts the movements of the follower magnet 4. Figure 1 also shows that the follower magnet 4 is constructed as an annular permanent magnet.

In the suspended body flowmeter which is known in the art, the annular follower magnet is magnetised diametrally; the north pole and the south pole form an angle a of 18T. This is shown in Figure 2.

Figures 3, 4 and 5 show follower magnets 4 which can be used in the suspended body flowmeters which are illustrated in Figures 1 and 7 to 9. It is essential that the annular follower magnet 4 is magnetised laterally and the north pole and the south pole on its coupling part which is nearer to the measuring tube 1 form an angle a which is preferably about 90'. In the embodiments illustrated in Figures 3, 4, and 5 the north pole and the south pole form an angle of exactly 9C.

As has already been explained at the outset, the design according to the invention ensures that the movement, and therefore the angle of rotation, of the follower magnet 4 is the same at the same height of the suspended body 2 over a wide range of different nominal diameters of the measuring tube 1. This result is substantially independent of the construction of the follower magnet 4 on the part of the follower magnet 4 which is remote from the coupling part.

Figure 6 illustrates an embodiment of a suspended body flowmeter which is known in the art and which again clearly illustrates the problems of this known suspended body flowmeter. In Figure 6a), the position of the follower magnet 4 in relation to the measuring tube 1 is illustrated for two quite different nominal diameters. This results in the problem illustrated in Figure 6b), namely that with the conventional design which is known from the prior art the follower magnot

4, when mounted at the same distance from the measuring tube 1 each time, executes different angles of rotation depending on the nominal diameter of the measuring tube 1 at the same height of the suspended body 2 and of the permanent magnet 3 provided therein. Figure 6b) clearly shows that in association with a measuring tube 1 of small nominal diameter the follower magnet 4 executes, at the same height of the suspended body 2 and of the permanent magnet 3 attached thereto, a significantly larger angle of rotation than is the case when the same follower magnet 4 is mounted on a measuring tube 1 with a considerably larger nominal diameter. Scales of different expanses are therefore necessary in the prior art for different nominal diameters of the measuring tube 1.

In the embodiment of a suspended body flowmeter known from the prior art which is illustrated in Figure 6, the follower magnet 4 is disposed so that the mid-plane of the follower magnet 4 intersects the axis of the measuring tube 1. In contrast to this, it can be seen from Figure 7 that in the embodiment of a suspended body flowmeter according to the invention which is illustrated here the mid-plane of the follower magnet 4 neither intersects nor contacts the measuring tube 1. In order to ensure a movement of the follower magnet 4 which depends on the movement of the suspended body 2 in an arrangement of this type, it is necessary for the distance X of the axis of the follower magnet 4 from the axis of the measuring tube 1 to be greater than 9 zero. The given distance X between the axis of the follower magnet 4 and the axis of the measuring tube 1, and the diameter of the follower magnet 4, are determined by each other; the distance X must be greater than half the diameter of the follower magnet 4. Moreover, the height-dependent angle of rotation of the follower magnet can be predetermined via the distance X; a given scale therefore requires a given distance X.

Figure 8 illustrates a housing 8 which accommodates the follower magnet 4, a metal bushing 6 and an electronics unit 7. A pointer 5 in turn is fixed to the follower magnet 4 as an indicator device, and provides a reading of the flow through the suspended body flowmeter via its position in relation to a scale 9. Various measuring tubes 1 of different nominal diameters are indicated above the housing 8. According to the invention, the follower magnet 4 executes the same angle of rotation for the same movement of a suspended body, which is not illustrated here, at different nominal diameters of the measuring tube 1. This advantage of the invention is ensured at a constant distance X of the axis of the follower magnet 4 from the axis of the measuring tube 1. The desired angle of rotation can be set by varying the distance X, irrespective of the nominal diameter of the measuring tube 1.

The metal bushing 6 illustrated in Figure 8 forms the column of an eddy current brake formed by the follower magnet 4 and the metal bushing 6, wherein the metal bushing 6 consists of an electrically conducting, non-ferromagnetic material, e.g. of aluminium or of copper. The braking effect is increased by making the air gap between the follower magnet 4 and the metal bushing 6 as small as possible and by manufacturing the follower magnet 4 from a rare earth metal. A further increase in the braking effect is ensured by the construction of the follower magnet 4 illustrated in Figure 5. The multiple north-south polarisation, as shown in Figure 5, of the follower magnet 4 on its braking part which is fizlher from the measuring tube 1 increases the magnetic field strength, which determines the braking effect, between the braking part of the follower magnet 4 and the metal bushing 6.

Figure 9 illustrates a further embodiment of a suspended body flowmeter according to the invention, in which an electrical measuring signal is also available in addition to the analogue pointer signal. Figure 9a) illustrates this embodiment of the suspended body flowmeter according to the invention in the absence of flow, and Figure 9b) illustrates the same embodiment under conditions of full flow. It can be seen from Figure 9 that the length of the suspended body 2 approximately corresponds to half the maximum height of the suspended body 2, so that a permanent coupling between the permanent magnet 3 and the follower magnet 4 is ensured.

In the embodiment shown in Figure 9, two magnetic field sensors 10, 11 are provided, which sense the magnetic field of the follower magnet 4 and which have identical measuring axes

12, 13 which extend parallel to the axis of the measuring tube 1. The output signals from the magnetic field sensors 10, 11 are fed to an evaluation circuit, which is not illustrated, for forming the difference of the output signals of the magnetic field sensors 10, 11 as a measure of the flow.

This ensures a high level of insensitivity to interference effects from external magnetic fields.

Moreover, a rotational movement of the permanent magnet 3 attached to the suspended body 2 has no effect on the measured result.

Finally, Figure 10 shows a further embodiment of a suspended body flowmeter according to the invention, in which a follower magnet is not present. In this embodiment, the magnetic field of the permanent magnet 3 attached to the suspended body 2 is sensed. In order to increase the magnetic field at the location of the magnetic field sensors 10, 11, magnetic field concentrators

14, 15 are provided, which are aligned towards the measuring tube 1 or towards the permanent magnet 3 attached to the suspended body 2 and which guide the magnetic field to the location of the magnetic field sensors 10, 11 and focus it there. The relatively large distance between the magnetic field sensors 10, 11 and the measuring tube I or the permanent magnet 3 attached to the measuring tube I which can thereby be achieved provides the advantage that the thermal resistance between the measuring tube I and the magnetic field sensors 10, 11 is relatively high, so that the temperature of the medium flowing in the measuring tube I has practically no effect on the measuring signal.

Finally, it should also be mentioned that magneto-resistive magnetic field sensors 10, 11 are used in the embodiments shown in Figures 9 and 10.

12

Claims (5)

1. A suspended body flowmeter for flowing media, having a measuring tube, having a suspended body which is disposed in the measuring tube and which can move in the directiop of flow, and having at least one permanent magnet attached to the suspended body, wherein two magnetic field sensors are provided, which sense the magnetic field of the permanent magnet and which have identical measuring axes which extend parallel to the axis of the measuring tube, and an evaluation circuit is provided for forming the difference of the output signals of the magnetic field sensors as a measure of the flow.

   2. A suspended body flowmeter according to Claim 1, wherein the magnetic field sensors are provided with magnetic field concentrators which are aliged towards the measuring tube or towards the permanent magnet attached to the suspended body.

   3. A suspended body flowmeter according to Claim 2, wherein magnetoresistive magnetic field sensors are provided.

   4. A suspended body flowmeter substantially as herein before described with reference to the accompanying drawings.

   Anicndments to the clairns have been filed as fDIIDNs CLAIMS A suspended body flowmeter for flowing media, having a measuring tube, having a suspended body which is disposed in the measuring tube and which can move in the directiPn of flow, and having at least one permanent magnet attached to the suspended body, wherein two magnetic field sensors are provided, which sense the magnetic field of the permanent magnet and which have identical measuring axes which extend parallel to the axis of the measuring tube, and an evaluation circuit is provided for forming the difference of the output signals of the magnetic field sensors as a measure of the flow.

   . C. '.
2. 2. A suspended body flowmeter according to Claim 1, wherein the magnetic field sensors are provided with magnetic field concentrators which are aliged towards the measuring tube or towards the permanent magnet attached to the suspended body.
3. 3. A suspended body flowmeter according to Claim 2, wherein magnetoresistive magnetic field sensors are provided.
4. 4. A suspended body flowmeter as claimed in Claim 1, and substantially as herein before described with reference to Figures la and lb of the accompanying drawings.
5. 5. A suspended body flowmeter as claimed in Claim 1, and substantially as herein before described with reference to Figures 10, of the accompanying drawings.