EP3058318A1 - Measuring tube for magnetoinductive flowmeter systems - Google Patents

Abstract

The invention describes and presents a measuring tube (1) for magnetoinductive flowmeter systems, wherein the flowmeter systems have the measuring tube (1) for the flow of an electrically conductive medium and a magnetic field generating device for generating a magnetic field running at least also perpendicular to the longitudinal axis of the measuring tube (1), at least two measuring electrodes (3, 4) which tap off the measurement voltage induced in the electrically conductive medium and preferably an evaluation unit, wherein the measuring electrodes (3, 4) have measuring contacts (5, 6) which are accessible on the outside of the measuring tube (1), wherein the measuring tube (1) forms a first functional unit with the measuring electrodes (3, 4), and mating contacts corresponding to the measuring contacts (5, 6) of the measuring electrodes (3, 4), the magnetic field generating device and the evaluation unit, if such an evaluation unit is present, form a second functional unit, and wherein the mating contacts (5, 6), the magnetic field generating device and the evaluation unit, if such an evaluation unit is present, are provided in a measuring system housing. According to the invention, the measuring contacts (5, 6) of the measuring electrodes (3, 4) are designed and provided on the measuring tube (1) in such a manner that the measuring contacts can be brought into electrically conductive contact with the mating contacts by means of a movement which runs substantially perpendicular to the direction of the magnetic field and is substantially only translational.

Description

 Measuring tube for magnetic-inductive flow measuring systems

The invention relates to a measuring tube for magnetic-inductive flow measuring systems, wherein the flow measuring systems, the measuring tube for the flow of an electrically conductive medium and a magnetic field generating means for generating at least also perpendicular to the longitudinal axis of the measuring tube extending, preferably alternating magnetic field, at least two in the electrically the measuring electrodes have on the outside of the measuring tube accessible measuring contacts, the measuring tube with the measuring electrodes a first functional unit and corresponding to the measuring contacts of the measuring electrodes mating contacts, the magnetic field generating device and the evaluation unit (if one is present) form a second functional unit and wherein the mating contacts, the magnetic field generation device and the evaluation unit ( if such exists) are provided in a measuring system housing.

Magnetic-inductive flow measuring systems have been extensively known in the art for decades. For this purpose, the reference "Technical Flow Measurement" by Prof. Dr.-Ing. K. W. Bonfig, 3rd edition, Vulkan-Verlag Essen, 2002, pages 123 to 167, and also to the reference "Basics Magnetic-Inductive Flow Measurement" by Dipl. Ing. Friedrich Hoffmann, 3rd edition, 2003, document of KROHNE Messtechnik GmbH & Co. KG, referenced.

The principle of a magnetic-inductive flow measuring system for measuring the flow of a flowing medium goes back to Michael Faraday, who proposed in 1832 to apply the principle of electromagnetic induction for measuring the flow velocity of an electrically conductive medium.

According to Faraday's law of induction, an electric field strength perpendicular to the flow direction of the medium and perpendicular arises in a flowing, electrically conductive medium penetrated by a magnetic field

CONFIRMATION COPY to the magnetic field. The Faraday's law of induction is exploited in magnetic-inductive flow measuring systems that by means of a magnetic field generating device, which usually has at least one magnetic field coil, usually during the measurement time-changing magnetic field is generated and the magnetic field at least partially passes through the flowing through a measuring tube electrically conductive medium. In this case, the generated magnetic field has at least one component perpendicular to the longitudinal axis of the measuring tube or perpendicular to the flow direction of the medium.

If it is stated in the introduction that at least one magnetic field generating device belongs to the magnetic-inductive flowmeter "for generating a magnetic field extending at least perpendicular to the longitudinal axis of the measuring tube", then it should be pointed out once again that the magnetic field is preferably perpendicular to the longitudinal axis of the Measuring tube resp. is perpendicular to the flow direction of the medium, but sufficient that a component of the magnetic field is perpendicular to the longitudinal axis of the measuring tube or perpendicular to the flow direction of the medium.

By way of introduction, it is also stated that the magnetic field generating device is intended to generate a preferably alternating magnetic field. This expresses the fact that it is not important for the teaching of the invention - according to its starting point, according to the underlying tasks and the solutions to these problems - that it is an alternating magnetic field, even though predominantly magnetic-inductive flowmeter have magnetic field generating devices that generate a changing magnetic field.

It is also stated at the outset that at least two measuring electrodes, which preferably pick up the medium, belong to the magnetically inductive flow measuring system in question, which measures the measuring voltage induced in the electrically conductive medium. Preferably, the virtual connecting line of the two measuring electrodes extends at least substantially perpendicular to the direction of the magnetic field passing through the measuring tube perpendicular to the longitudinal axis of the measuring tube. In particular, the measuring electrodes be provided so that their virtual connection line actually - more or less - perpendicular to the longitudinal axis of the measuring tube passing magnetic field.

Finally, it is stated at the outset that the measuring electrodes may in particular be those which contact the medium. In fact, of course, the electric field strength generated by induction in the flowing, electrically conductive medium can be tapped off as measuring voltage by measuring electrodes which are in direct contact with the medium, that is, galvanically in contact with the medium. However, there are also magnetic-inductive flow measuring systems in which the measuring voltage is not tapped by measuring electrodes which are not directly in contact with the medium, but rather the capacitance is measured capacitively.

Two different embodiments of magnetically inductive flow measuring systems are conceivable, namely a first embodiment in which the two functional units, ie the measuring tube on the one hand and the magnetic field generating device on the other hand, are separate components which, when brought into operation together, produce a functioning magnetic-inductive flow measuring system, and a second Embodiment in which the two functional units, so the measuring tube and the magnetic field generating device are already factory-functioned, ie factory-functional components of an already factory-functional magnetic-inductive flowmeter are.

In the following, only the first embodiment of a magnetically inductive flow meter stems will be described, that is to say the embodiment in which the measuring tube on the one hand and the magnetic field generating device on the other hand are initially separate components which, when brought into operation together, result in a functioning magnetic-inductive flow measuring system. However, what is described below is also readily applicable to the second embodiment of magnetic-inductive flow measuring systems, in which the two functional units, the measuring tube and the magnetic field generating device are already factory-operated, ie components of an already factory-functional electromagnetic flowmeter. Reference is made, by way of example, to DE 692 32 633 C2, DE 199 07 864 A1, DE 100 64 738 B4, DE 102 43 748 A1, DE 10 2008 005 258 to magnetic-inductive flow measuring devices known in the prior art AI and DE 10 201 1 1 12 703 Al and EP 0 704 682 AI and EP 0 834 057 AI.

In magnetic-inductive flow measuring systems of the type in question usually includes a magnetic field coil to the magnetic field generating device. This magnetic field coil usually has a coil core, and on the coil core close on both sides of the pole pieces. The coil core and the pole pieces are usually made of magnetically good conductive material, ie material with a high permeability, and the pole pieces overlap on both sides of the measuring tube. To the functioning of the magnetic-inductive flow measuring systems in question functionally important and functionally important magnetic circuit thus include the coil core, the both sides of the coil core subsequent pole pieces and the air gap formed between the pole shoes, in which - in the functional state - is the measuring tube.

As explained in detail, the longitudinal axis of the measuring tube, the magnetic field direction and the virtual connecting line of the two measuring electrodes form a right-angled tripod. If the longitudinal axis of the measuring tube is referred to as the X-axis and the magnetic field direction as the Y-axis, then the virtual connecting line of the two measuring electrodes is the Z-axis of the right-angled tripod; The virtual connecting line of the two measuring electrodes thus extends both perpendicular to the longitudinal axis of the measuring tube and perpendicular to the magnetic field direction.

From what has been explained above, the problem arises that a measuring electrode with its measuring contact (and the corresponding mating contact) on one side of the measuring tube and the other measuring electrode with its measuring contact (and the associated mating contact) on the other side of the measuring tube is located. This has both constructive and connective disadvantages, and at least partially eliminating these disadvantages is one of the objects of the invention. The measuring tube according to the invention, in which the previously derived and indicated object is achieved, is initially and essentially characterized in that the measuring contacts of the measuring electrodes are designed and provided on the measuring tube such that they essentially only pass through a direction substantially perpendicular to the magnetic field direction translational movement with the mating contacts can be brought into electrically conductive contact. This teaching according to the invention is advantageous both for the above-described first embodiment of magnetic-inductive flow measuring systems in which the measuring tube on the one hand and the magnetic field generating device on the other hand initially separate components, which only when they are brought together with each other, a functioning magnetic induction Flow measuring system, as well as advantageous for the second embodiment, in which the measuring tube on the one hand and the magnetic field generating device on the other hand are components of a factory-functional magnetic-inductive flowmeter. In both cases, it is particularly realized that each of the two measuring contacts of the measuring tube, which must be provided on the one hand on one side of the measuring tube and on the other side of the measuring tube, are readily accessible from one side of the corresponding mating contact or with the corresponding counter-contact can be brought into electrically conductive contact.

In particular, there are various possibilities for designing and developing the above-described first teaching according to the invention.

A first preferred embodiment of the measuring tube according to the invention is characterized in that the measuring contact of the measuring electrode provided on the side of the measuring tube facing away from the magnetic field coil is extended at least on one side perpendicular to the virtual connecting line of the two measuring electrodes. This embodiment is intended for a second functional unit of magnetic-inductive flow measuring systems of the type in question, in which the counter-contact associated with the measuring contact described above is extended until it makes contact with the corresponding measuring contact. In this embodiment, therefore, the mating contact, the second functional unit, which must come into electrically conductive contact with the measuring contact, which faces away from the magnetic field coil Side of the measuring tube is provided, the measuring tube practically engage over its entire diameter or overlap.

Another preferred embodiment of the measuring tube according to the invention is characterized in that the measuring contact of the measuring electrode provided on one side of the measuring tube is extended at least on one side in the circumferential direction of the measuring tube. This embodiment requires a second functional unit of magnetic-inductive flow measuring systems of the type in question, in which the counter-contact associated with the measuring contact described above is extended to ontaktierung with the corresponding measuring contact. In this embodiment, therefore, a measuring contact is circular arc-shaped. In this case, the circular-arc-shaped measuring contact may comprise somewhat less than 180 °, namely so much less that it does not come into contact with the measuring contact of the other measuring electrode.

That which was previously carried out, as it were, with respect to the measuring contact of the measuring electrode provided on the side of the measuring tube facing away from the magnetic field coil naturally relates to the measuring contact of the measuring electrode provided outside the measuring tube. Within the measuring tube, the measuring electrode, whose outer measuring contact is designed in a special way, as well as the other measuring electrode, so be executed, as the extensive belongs to the prior art.

In magnetic-inductive flow measuring systems, the measuring tube often has at least one preferably annular ground electrode. If such a ground electrode is provided, the teaching of the invention can also be realized in that the ground electrode is one of the two measuring electrodes and is designed as explained in detail above.

In the magnetic-inductive flow measuring systems for which the measuring tubes according to the invention are intended, in the case of the second functional unit, a checking contact can be assigned to each of the two mating contacts. The two check contacts on the one hand and the two measuring contacts of the measuring tube on the other hand are designed and arranged so that the check contacts then and only then electrically conductive contact with have the associated mating contacts, although the mating contacts have electrically conductive contact with the associated measuring contacts. For this embodiment of magnetic-inductive flow measuring systems, the measuring tube is designed so that each of the measuring contacts has a galvanically connected with them check Gegenkontakt. This can be realized in a simple manner in that each of the two check counter contacts and the associated measuring contact are made in one piece.

Not infrequently, magnetic-inductive flow measuring systems of the type in question are required for measuring tubes with different flow cross sections, that is to say with different inner diameters. To have to use different magnetic-inductive flow measuring systems, is at least application technology and customer undesirable. Consequently, another teaching of the invention, which in connection with the previously described teachings of the invention, but also detached therefrom, is of particular importance to realize a magneto-inductive flow measurement system as a whole so that readily measuring tubes with different flow cross-sections, ie with different inner diameters are used or can be used.

Measuring tubes with different flow cross-sections, ie with different inner diameters, can then be used without any problems, if the different measuring tubes each have the same outer diameter and the same measuring contacts, ie only with respect to the flow cross-sections, that is with respect to the inner diameter, are different.

The above-described realization of readily usable measuring tubes with different flow cross-sections, that is, with different diameters, can be problematic in terms of manufacturing technology. Consequently, another implementation of readily usable measuring tubes with different flow cross sections, ie with different inner diameters, is characterized in that the different usable or. each measuring tube used have the same or corresponding measuring contacts. It is therefore sufficient if the measuring tubes, regardless of the flow cross-section, ie independent of the inner diameter, where, where they are brought with their measuring contacts with the corresponding mating contacts in the second functional unit of the subject magnetic-inductive Strömungsmesssy systems in electrically conductive contact, equal, but at least functionally the same.

If measuring tubes with different flow cross-sections, ie with different inside diameters, are used in magnetic-inductive flow measuring systems, this can be taken into account by the user. Thus, it can enter the evaluation unit, which can be part of a magnetic-inductive flow-measuring system, but can also be realized separately from a magnetic-inductive flow-measuring system, the flow cross-section, ie enter the inner diameter of the usable or inserted measuring tube. However, a particular embodiment of a measuring tube according to the invention is characterized in that it is provided with a measuring tube identification element. Of course, this embodiment only makes sense if, in the second functional unit of the magnetic-inductive flow measuring systems in question, a measuring tube interrogation element associated with the measuring tube identification element of the measuring tubes is provided in the measuring system housing. In this embodiment, therefore, the effective flow cross-section, ie the effective inner diameter, is automatically taken into account with the insertion of the appropriately equipped measuring tube for flow measurement.

As stated, there are various ways to design and develop the measuring tube according to the invention for magnetic-inductive flow measuring systems. Reference is made to the independent claims 1 and 8, to the claims subordinate to these claims and to the following description of exemplary embodiments in conjunction with the drawing. In the drawing show

1 shows schematically the basic structure of a magnetic-inductive flow measuring system,

Fig. 2 is a very schematic representation for explaining one for the

Invention essential teaching, Fig. 3, like FIG. 2, is a very schematic representation for explaining another teaching essential to the invention,

Fig. 4 very schematically, a possible embodiment of a magnetic-inductive flow measuring system with an inserted measuring tube and again very schematically, another embodiment of a magnetic-inductive flow measuring system in which a measuring tube according to the invention is not yet used.

To the in Figures 1, 4 and 5 only schematically shown magnetic inductive Strömungsmesss stemen include, first and substantially, an inventive measuring tube 1 for the flow of an electrically conductive medium and a magnetic field generating device 2 for generating an at least perpendicular to the longitudinal axis of the measuring tube. 1 extending, preferably alternating magnetic field and two the measuring voltage induced in the electrically conductive medium, preferably the medium touching measuring electrodes 3, 4, wherein the measuring electrodes 3, 4 outside of the measuring tube 1 accessible measuring contacts 5, 6 have.

In principle, magnetic-inductive flow measuring systems also include an evaluation unit and a measuring system housing. The evaluation unit, not shown, may be part of the magnetic-inductive flow measuring system, but the evaluation unit can also be realized as a separate component.

The measuring tube 1 according to the invention with the measuring electrodes 3, 4 and the measuring contacts 5 and 6 forms a first functional unit, and counter contacts 7, 8 corresponding to the measuring contacts 5, 6 of the measuring electrodes 3, 4, the magnetic field generating device 2 and the evaluation unit (if one such is present) form a second functional unit. The mating contacts 7, 8, the magnetic field generating device 2 and the evaluation unit (if such is present) are provided in the measuring system housing, not shown. In the magneto-inductive Durchflussmesssy system shown schematically in FIG. 1 belongs to the magnetic field generating device 2, a magnetic field coil 9, which has a spool not shown in detail. On the spool core, not shown, close on both sides pole pieces 10, 1 1 at. The spool core, not shown, and the pole shoes 10, Π normally consist of magnetically highly conductive material, and, as indicated in FIG. 1, the pole shoes 10, 11 overlap the measuring tube 1 on both sides.

As explained above, two different embodiments of magnetic-inductive flow measuring systems are possible, namely a first embodiment, in which the two functional units explained above are separate components which are first brought into operation together, yield a functioning electromagnetic flow measuring system, and a second Embodiment in which the two previously described functional units are already brought into operation with one another at the factory, ie components of a magneto-inductive flowmeter which are already in operation at the factory and which have been brought into operation at the factory.

For the illustrated magnetic-inductive flow measuring system, it is first of all true that the measuring contacts 5, 6 of the measuring electrodes 3, 4 are provided on the measuring tube 1 and the mating contacts 7, 8 corresponding to the measuring contacts 5, 6 of the measuring electrodes 3, 4 in the measuring system (not shown) Housing are arranged so that the measuring contacts 5, 6 can be brought into an electrically conductive contact with the mating contacts 7, 8 by a substantially only translational movement substantially perpendicular to the magnetic field direction. This can be realized in different ways.

A first realization possibility is indicated in FIGS. 2 and 3. In this case, the measuring contact 6 of the measuring electrode 4 provided at the side of the measuring tube 1 facing away from the magnetic coil 9 is extended at least on one side parallel to the magnetic field direction and the counter contact 8 assigned to the measuring contact 6 described above is extended until it makes contact with the corresponding measuring contact 6. Another realization possibility, not shown, is characterized in that the measuring contact of the measuring device provided on the side of the measuring tube facing away from the magnetic field coil extended electrode at least on one side in the circumferential direction of the measuring tube and the counter-contact associated with the measuring contact described above is extended to the contact with the corresponding measuring contact.

In magnetic-inductive Durchfiussmessgeräten the measuring tube often has at least one preferably annular ground electrode. In such an embodiment, the ground electrode may be one of the two measuring electrodes.

FIG. 3 serves to explain a teaching of the invention, which is of particular importance in connection with what has been explained above, but also detached from it. In this case, it is provided that each of the two mating contacts 7, 8 provided in the second functional unit is assigned a checking contact 12, 13 and that the two checking contacts 12, 13 on the one hand and the two measuring contacts 5, 6 of the measuring tube 1 on the other hand are designed and arranged in this way are that the check contacts 12, 13 then and only then have electrically conductive contact with the associated mating contacts 7, 8, although the mating contacts 7, 8 have electrically conductive contact with the associated measuring contacts 5, 6 of the measuring tube 1. Here, the check contacts 12, 13 a galvanically associated with the associated measuring contacts 5, 6 Verification counter contact 14, 15 assigned. This is realized in a simple manner in that each of the two check mating contacts 14, 15 and the respectively associated measuring contact 5, 6 are made in one piece.

As stated above, magnetic-inductive flow measuring systems are often required for measuring tubes 1 with different flow cross-sections, that is to say with different inner diameters. In connection with this, it is of particular importance to realize a magnetic-inductive flow measuring system which can be used or used without difficulty measuring tubes 1 with different flow cross-sections, that is, with different inner diameters. The essential teaching of the invention is thus also the disposal position of a plurality of measuring tubes with different flow cross-sections, that is, with different inner diameters, which readily with second functional units of the magnetic-inductive flow measuring systems in question assembled into a functioning electromagnetic flowmeter, assembled, and combined.

Measuring tubes 1 of a plurality of measuring tubes 1 with different flow cross-sections, ie with different inner diameters, can then be used without problems if the different measuring tubes 1 each have the same outer diameter and the same measuring contacts 5, 6, ie if the measuring tubes 1 only with respect to the flow cross sections, ie in terms of the inner diameter, differ.

Another realization of readily usable measuring tubes 1 of a plurality of measuring tubes 1 with different flow cross-sections, ie with different inner diameters, is characterized in that the different usable or inserted measuring tubes 1 each have the same or corresponding measuring contacts 5, 6. It is sufficient, if the measuring tubes 1 of a plurality of measuring tubes 1, regardless of the flow cross-section, ie independent of the inner diameter, where it with their measuring contacts 5, 6 with the corresponding mating contacts 7, 8 in the second functional unit of the magnetic in question - Inductive flow measuring systems are brought into electrically conductive contact, equal, but at least functionally the same.

In magnetic-inductive flow measurement systems, the user can consider the use of measuring tubes with different flow cross-sections, ie with different inner diameters itself, namely the fact that it is realized in the evaluation, which may be part of a magnetic-inductive flow measuring system, but also separated from such a flow measuring system may be, the flow cross-section, that inputs the inner diameter of the measuring tube used in each case. However, this is complicated and can lead to incorrect entries in particular. Consequently, another teaching of the invention is to provide each measuring tube with a measuring tube identification element. In this embodiment, a measuring tube interrogation element associated with the measuring tube identification element of the measuring tubes must then be provided in the measuring system housing, an embodiment which is not illustrated, but is readily understandable for itself. For the exemplary embodiments of magnetic-inductive flow measuring systems shown only very schematically in FIGS. 4 and 5, it is possible to magnetically move the cover by means of an upwardly pivotable cover 16 (FIG. 4) or with the aid of a flap 17 (FIG Inductive flow measuring stem can be opened so that the respective measuring tubes 1 to be used with their measuring electrodes 3, 4 and the associated measuring contacts 5, 6 can be readily used.

Embodiments of magnetic-inductive flow measuring systems, which have no moving parts such as a cover 16 in the embodiment of FIG. 4 or a flap 17 in the embodiment of FIG. 5, are preferable to the embodiments shown in FIGS. 4 and 5.

Claims

Claims:

1 . Measuring tube for magnetic-inductive flow measuring systems, wherein the Durc hfl ussmesssy systems the measuring tube for the flow of an electrically conductive medium and a magnetic field generating means for generating at least also perpendicular to the longitudinal axis of the measuring tube extending, preferably changing magnetic field, at least two induced in the electrically conductive medium The measuring electrodes on the outside of the measuring tube accessible measuring contacts, wherein the measuring tube with the measuring electrodes a first functional unit and corresponding to the measuring contacts of the measuring electrodes mating contacts, the magnetic field generating device and the evaluation (as far as a such is) form a second functional unit and wherein the mating contacts, the magnetic field generating device and the evaluation unit (as far as such exists is) provided in a measuring system housing,

characterized,

in that the measuring contacts (5, 6) of the measuring electrodes (3, 4) are designed and provided on the measuring tube (1) in such a way that they move with the mating contacts (7, 8) through an essentially only translational movement substantially perpendicular to the magnetic field direction. can be brought into electrically conductive contact.

2. Measuring tube according to claim 1, characterized in that the measuring contact (6) on one side of the measuring tube (1) provided measuring electrode (4) at least on one side perpendicular to the virtual connecting line of the two measuring electrodes (3, 4) is extended.

3. Measuring tube according to claim 1, characterized in that the measuring contact (6) on one side of the measuring tube (1) provided measuring electrode (4) is extended at least on one side in the circumferential direction of the measuring tube (1).

4. Measuring tube according to one of claims 1 to 3, wherein the measuring tube has at least one preferably annular ground electrode, characterized in that the ground electrode one of the two measuring electrodes (5, 6) and is designed according to one of claims 1 to 3.

5. Measuring tube according to one of claims 1 to 4, characterized in that each of the two measuring contacts (5, 6) has a galvanically connected to them Verification counter contact (14, 15).

6. measuring tube according to claim 5, characterized in that each of the two Verprüfungsgegenkontakte (14, 15) and the associated measuring contact (5, 6) are made in one piece.

7. Measuring tube according to one of claims 1 to 6, characterized in that it is provided with a measuring tube identification element.

8. A plurality of measuring tubes for magnetic-inductive flow measuring systems, wherein the flow measuring systems, the measuring tube for the flow of an electrically conductive medium and a magnetic field generating means for generating a at least perpendicular to the longitudinal axis of the measuring tube extending, preferably alternating magnetic field, at least two in the electrically the measuring electrodes have on the outside of the measuring tube accessible measuring contacts, wherein the measuring tube with the measuring electrodes a first functional unit and corresponding to the measuring contacts of the measuring electrodes mating contacts, the magnetic field generating device and the evaluation unit (if one is present) form a second functional unit and wherein the mating contacts, the magnetic field generating device and the evaluation unit (as far as such is present) are provided in a measuring system housing,

characterized,

that the measuring tubes (1) with different flow cross-sections, that is to say with different inner diameters, can be inserted without further ado into the second functional unit.

9. A plurality of measuring tubes according to claim 8, characterized in that the different, usable measuring tubes (1) each have the same outer diameter and the same measuring contacts (5, 6).

10. A plurality of measuring tubes according to claim 8, characterized in that the different, usable measuring tubes (1) each have the same or corresponding measuring contacts (5, 6).