NL8004709A - Inductive flowmeter with three electrodes in plastics tube - has magnetic core mounted outside tube, clamped by bolt and embedded in expanded plastics - Google Patents

Abstract

The inductive flowmeter consists of a plastics tube (10) of round cross-section, equipped with three electrodes, two of which (11,12) are measuring electrodes, subtending on angle of less than 180 degrees at the centre of the tube and symmetrically disposed w.r.t. an electromagnetic core (14) mounted outside the plastics tube (10) and held in place by a centrally located bolt (15). An earthing electrode (16) is fitted at the end of the bolt. A magnetic flux conductor is fitted, and is in the form of a metal plate (18), with a base part (183) and two side wings (181,182). The tube is accommodated coaxially but eccentrically on a cylindrical housing (21) fitted with expanded plastics. The earth connection is made to a tag fitted under the head of the bolt (15) on the side remote from the plastics tube (10).

Description

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Inductive flow meter.

The invention relates to an inductive flow meter with a tube, on whose inner edge measuring electrodes are arranged, and with an electron magnet which generates a magnetic field in the interior of the tube.

Inductive flow meters work according to the induction principle, according to which an electrical voltage induced in an electric conductor, which is moved in a magnetic field, the magnitude of which is proportional to the speed of movement. In this way, the flow rate of a liquid flowing through a tube can be measured without movable mechanical parts. The electron magnet generates a magnetic field in the tube. The electric charge carriers present in the flowing liquid cause the generation of an electric field, which can be measured with the aid of electrodes arranged on the pipe walls. The voltage measured at the electrodes is a measure of the flow, that is, the product of liquid cross-section and velocity.

In the known inductive flow meters (German Utility Model 77 2L163}, the magnetic field is generally generated by two 20 magnets, which are arranged on both sides of the tube.

The coil and measuring electrode arrangement has been chosen such that, as far as possible, the entire radiation image is collected in the cross section of the tube. For the magnet arrangement, this means that the magnetic field is distributed symmetrically over the entire cross section of the tube. As a rule, this aim leads to costly solutions with symmetrical coils, feedback suspensions and electrode arrangements.

An inductive flow meter with only a single coil is also known (US Pat. No. 80 0 4 70 9 * 2 2 770 130). Here too, however, the magnetic field is distributed as evenly as possible over the cross-section of the housing and the measuring electrodes are applied at two opposite locations or at a common tube diameter. The advantage of a magnetic field distribution and a measuring electrode arrangement covering the entire cross section of the tube is that a relatively high measuring accuracy is also achieved with asymmetrical flow profiles, for example immediately behind curves or valves. However, the high mechanical costs and the loss of a noticeable signal as a result of the magnetic stray flux occurring between the magnets and the relatively distant electrodes are disadvantageous.

Finally, an inductive flow meter is known (United States Patent Specification 3 372 589), in which (tegenover) two opposite sides of the tube wall are arranged with U-shaped magnets on the tube, each of which cooperates with an electrode pair. An electrode of the electrode pair is always located between the pole pieces of the associated magnet, and the other electrode is outside the magnet. The ringed electrodes of a pair of 20 have a small angular distance from one another with respect to the pipe circumference. In a medium value circuit, the mean value is formed from the voltages occurring on both sides of the tube wall on the electrode pairs. This measuring arrangement provides accurate results even with uneven distribution of curves in the cross-section of the tube, but is complicated and expensive.

The object of the invention is to provide an inductive flow meter of the above-mentioned type, which has a simple construction and can be manufactured inexpensively, yet nevertheless has a sufficiently high measuring accuracy when maintaining sufficiently long inflow and outflow paths.

According to the invention this is achieved in that the measuring electrodes are arranged on the tube with an angular distance relative to the tube-elongation angle which is smaller than 180 ° and symmetrical to the center line of the core of the electromagnet.

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This solution can be realized with low installation and construction costs, because only part of the cross-section of the pipe is used for the measurement. Only a single coil is present, which generates a non-homogeneous magnetic field in the tube, which is mainly limited to half the cross section of the tube. The induced voltage between the two measuring electrodes is measured within this half.

If the liquid straw is distributed sufficiently evenly over the cross-section of the tube, the flow measurement in a partial area of the cross-section of the tube is sufficient to achieve accurate measurement results. The comparatively small distance which the measuring electrodes have from one another is particularly advantageous. This distance is considerably smaller than the pipe diameter. Since the measuring electrodes do not lie diametrically opposite one another, but are arranged displaced relative to the coil, practically the entire magnetic field generated by the coil is involved in the induction of the active signal, that is to say the scattering losses are kept low.

Preferably, the angular distance of the electrodes 20 is about 90 °.

At an effective further development of the invention, at the end of the electro-magnet which faces away from the tube, a magnetic current conductor projecting at least in the vicinity of the tube wall can be arranged on the magnetic core. The magnetic flow conductor concentrates the magnetic field outside the tube in order to keep the stray losses there. Inside, the magnetic field runs freely between the end of the magnetic current conductor and the front end of the magnetic core.

In an effective further development of the invention, the magnetic flow conductor consists of a steel plate which rests with a base part against the rear end face of the magnetic core and which has non-bent legs that run symmetrically to the axis of the magnetic core in the vicinity of the pipe wall .

This construction has the advantage that only a single magnetic current conductor is present, which by means of two bent legs generates two symmetrical magnetic field halves in the interior of the 80 0 4 70 9 ίτ 4 tube, which is on the front side of the core. of the electromagnet together.

The tube can be either a plastic tube or a metal tube fitted with a plastic coating. In both cases, differences 5 only occur with regard to the sealing of the measuring electrodes. The electrode construction in a plastic-coated metal tube is conventional, while in a plastic tube a screw turned through the tube wall is used, which is sealed on the outside by a conically shaped sealing ring 10.

In an effective further development of the invention it has been determined that the tube, viewed in cross-section, is arranged eccentrically in a housing and that the electromagnet is arranged in the region of the greatest distance between the tube and the housing. The housing encloses the assembly group consisting of the tube on the electromagnetic eccentrically to the tube, so that the housing with a relatively small volume can be constructed. A further advantage is that the flow transducer can also be used in difficult installation conditions, since the housing protrudes only a little from the end of the tube, so that the flow transducer can also be mounted there on the pipe, where other parts are located near the pipe. Bad weird one side must have enough freedom to fit the house.

The housing can for instance consist of a ring which encloses the electromagnets and the electrodes as well as the connecting lines thereof and whose inner space is filled with a plastic or foam material, respectively. All elements of the flow meter are then encapsulated underneath. The plastic or foam material closes the tube, which is also a solid part of the through-flow catheter and has flanges for connection with other pipelines.

In order to achieve a sufficiently turbulence-free and rotationally symmetrical flow, a rectilinear flow path in front of the measuring point of at least approximately five times the diameter of the pipe and a rectilinear flow path behind the 8004709 k 5 measuring point of approximately the length of the diameter of the pipe must be apprehended.

The invention will be explained in more detail below with reference to the drawing, in which, by way of example, the embodiment of a flow meter according to the invention is shown. In the drawing shows:

Fig. 1 is a longitudinal section through an inductive flow transducer, and FIG. 2 is a section taken on the line II-II of FIG. 1.

In the exemplary embodiment of Figs. 1-3, a plastic tube 10 with a round cross section is shown, on which a total of three electrodes are provided, which protrude into the interior of the tube. Two measuring electrodes 11 and 12 are arranged in a common transverse plane of the tube 10 and shown in FIG.

2 are arranged in the lower half of the cross-section of the tube in such a way that they enclose an arterial angle a of approximately 90 ° relative to the tube 10. The measuring electrodes 11 and 12 are arranged symmetrically with respect to the core 13 of the electromagnet 14. This means that each measuring electrode 11, 12 lies with respect to the longitudinal axis of the core 13 in a circumferential angle of a / 2 up to the tube 10. The core 13 is directed radially to the tube 10 and, together with the measuring electrodes 11 and 12, lies in a common transverse plane of the tube 10.

The core 13 of the electromagnet 14 has an internally threaded axial bore into which a screw bolt 15 is screwed. The threaded bolt 15, which extends longitudinally through the core 13, is screwed into a threaded bore of the wall of the tube 10 and forms with its front tip 30 a grounding electrode 16. Against the rear end of the core 13 is the base part of a magnetic current conductor which consists of a substantially U-shaped bent metal plate 18.

The flat base part is indicated by 183. The legs 181 and 182 protrude obliquely in the lateral direction and come with the free ends near the wall of the tube 10. In the base part 183 there is an opening through which the screw bolt 15 is inserted, 80 0 4 70 9 * 6 so that the screw bolt 15 rests with its screw head on the base part 83 and presses it against the rear side of the core.

In this manner, the magnetic current occurring at the rear end of the core 13 is distributed over the legs 181 and 182 of the metal plate 18. At the free ends of the legs 181 and 182, the magnetic current exits to pass through the wall of the tube 10 into the interior of the tube and to enter the front end face of the core 13. (¾) in this manner, a magnetic field 10 is generated in a partial region of the cross-section of the tube 10. The measuring electrodes 11 and 12 are arranged in the region of this magnetic field. The legs 181 and 182 are arranged symmetrically in the measuring plane to the center line of the electromagnet 14, as are the measuring electrodes 11 and 12.

The coil winding 17 of the electromagnet 14 is wound on a support body 19 in which the core 13 is placed.

The rear end of the support body 19, like the rear end of the core 13, is covered by the base portion 183 of the metal sheet 18. Between the base part 183 and the head of the screw bolt 15 there is a contact disc 20, which is connected to an earth connection. In this way, the ground electrode 16, which is located centrally between the measuring electrodes 11 and 12, is applied to the ground potential.

The measuring arrangement described in full is enclosed by a housing 21, which may for instance consist of plastic.

25 The housing is annular and has a circular cross-section.

Its interior is filled with plastic or foam 22.

A conduit lead-through piece 23, which is located on a front side of the housing, is also filled in full, through which the operating lines for the electromagnet magnets 14, the earth connection line as well as the measuring lines 24 and 25 coming from the measuring electrodes 11 and 12 are passed.

As shown in Fig. 2, the measuring lines 24 and 25 are each guided over a partial area of approximately 130 ° cm. The pipe circumference to unite at the point lying diametrically opposite the earthing electrode 16. From there, the measuring lines in 80 0 4 70 9> 1 7 have a shielded cable led to the lead-through lead-through 23, the shielding of which forms the grounding conductor.

As can be seen from the figures, the housing 21 is arranged eccentrically up to the tube 10. The electromagnet 14 is in the region of the greatest distance between the tube 10 and the housing 21.

Flanges 26 and 27 are provided at the ends of the tube 10 in order to connect the flow-through motor to other lines.

The coil winding 17 is applied to an alternating voltage which generates a magnetic alternating field in the interior of the tube 10. Subsequently, in the case of liquid radiating in the tube 10, an electric alternating field is formed at the measuring electrodes 11 and 12. The magnetic field emanating from the core 13, in particular, extends through the lower region of the cross-section of the tube, in which the measuring electrodes 11 and 12 are located. The measurement of the flow rates therefore takes place in the lower region of the cross-section of the pipe, however it is representative of the entire cross-section of the pipe if the flow rate in the total cross-section of the pipe is almost symmetrical,

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Claims (9)

1. Inductive flow meter with a tube with a single electromagnet arranged under the tube, which draws up a magnetic field through the tube wall in the interior of the tube, and with two electrodes arranged symmetrically to the vertical tube diameter on the tube wall, with characterized in that the measuring electrodes (11 and 12) on the tube (10) are arranged syranetrically to the center line of the core (13) of the electromagnet (14) with an angular distance, which is smaller than 180 °, which is related to the tube start. . Inductive flow meter according to claim 1, 10, characterized in that the angular distance of the measuring electrodes (11 and 12) is approximately 90 °. Inductive flow meter according to claim 1 or 2, characterized in that at the end of the electromagnet (14) remote from the tube (10), at least one magnetic flow conductor (18) projecting in the vicinity of the tube wall and the core (13) is fitted. Inductive flow meter according to claim 3, characterized in that the magnetic flow conductor consists of a metal plate (18), which rests with a base part (183) on the rear 2Q end face of the core (13) and which has bent legs (181 and 182). ), which are symmetrical towards the center line of the core (13) and close to the pipe wall. Inductive flow meter according to any one of claims 1 to 4, characterized in that the electromagnet (14) is mounted on the tube (10) with a fastening member (15) penetrating through the tube wall, and in that the fastening member with an outlet connection is connected. Inductive flow meter according to any one of the preceding claims, characterized in that the tube (10) is arranged eccentrically in a housing (21) in cross-section, and in that the electromagnet (14) is in the region of the greatest distance. between the tube (10) and the housing (21). Inductive flow meter according to claim 6, characterized in that the inner space of the housing (21) is filled with a plastic or foam material, respectively, the tube 80 0 4 70 9 k (10). Inductive flow meter according to claim 6 or 7, characterized in that the housing consists of plastic and has a substantially round cross section. 9. Device as shown in the drawing and / or discussed on the basis thereof. 80 0 4 70 9