DE1498327A1 - Device for measuring the flow rate - Google Patents

Description

Device for measuring the flow rate The invention relates to a device for measuring the flow rate from within a pipe flowing media, in which the flowing medium is inside the line Twist is imposed, the retroactive torque of which is torsionally elastic mounted member is measured to generate twist.

Such devices are known (German Patent 1 189 741) in which a stator is arranged between two torsionally elastic corrugated tubes through which the flowing medium is fed to and removed from the stator. The idler itself is stored in a suitable measuring housing with the help of a cruciate ligament arrangement. This arrangement is relative # expensive to manufacture and also causes certain difficulties during assembly, such as the corrugated pipes especially sealed against the diffuser and against the adjoining pipe must be.

! various suggestions have already been made, the disadvantages the known measuring arrangement. These suggestions bring improvements with regard to the measuring accuracy and with regard to the applicability of the known Measuring device, but the measuring devices created by it are also in the production is still complex and therefore expensive.

The present invention is based on the object of a simplification to create for measuring devices of the type mentioned at the beginning. Based on the knowledge that a simplification can be achieved if the generated torque as s angular deflection of the swirl generating member is displayed1 the invention exists in the fact that the link for twisting is a flying wheel that is inside the line is stored. The impeller is advantageously centered within the line arranged. This allows sensitive seals between torsionally elastic Parts of the line and the adjacent line. The invention # The measuring device designed is also independent of the static pressure of the flowing Medium. Furthermore, compensation devices, which the rotational movement of the Impeller prevent being dispensed with, soda # a special simple and cheap design is achieved.

The impeller is expediently made of elastic material by means of struts connected to the line and stored within the line. These pursuits can be attached to the honeycomb of the wheel and can be attached to webs leg, which are inserted into the line. The struts can be particularly easy to parallel run to the line axis, in a special embodiment as rods a round cage can be formed, the central axis of which with the line axis coincides With struts with a rectangular cross-section, it is useful to place them in Cross-section to be arranged radially around the axis of the line, so that like the previously mentioned fiIfig sne rotary motion of the impeller to a certain extent However, circumference allow tilting of the impeller out of its position relative to the pipe axis impede. Bn Bich can also a torsion tube for mounting the impeller on it pulled if precautions are taken to prevent the torsion tube from deviating from its axial position due to its low resistance @smoment against bending impede.

This could be done, for example, by suitable storage of the free end of the torsion tube or the extremely light design of the impeller.

The webs to which the struts are attached. can be in different Wise be formed, for example, they can diametrically to Line diameters run and as a flow straightener or as a pre-swirl stator be trained. But you can also catch the line radially on the inner side be formed internally facing tab-like elevations, the struts for torsionally elastic mounting of the impeller directly on the blades of the impeller can be fastened In addition to the simple arrangement of a transparent Line part for direct observation of the rotation of the impeller can expediently provided as a means for measuring the rotational movement of the impeller magnetic elements that are connected to the impeller and either the magnetic field of a measurable influence of fixed magnets or other magnetic elements that for example, can be arranged outside the line, around the rotational movement the impeller mitbesegen corresponding amount, for example, could be outside of the line for the flowing Lrjediuyn connected to a display device permanent magnet be movably arranged, the movement of the flywheel, the on the outside of at least one flail even if with a permanent magnet is provided with executes.

But it could also be one with at least one wing of the impeller electrical conductors are connected, the pivoting of which is measurable electromagnetically The field of an electromechanical fixed on the outside of the conduit is influenced.

In order to avoid all streams coming out of the measuring device If the medium is subject to a swirl, one impeller can each move in the direction of flow seen, be arranged in front of and behind the fastening webs in the line, of which one of the flow opposes the swirl of the other impeller Twist granted. This also results, as with similar devices has already been proposed, possible combinations through which, for example the deflection of one impeller is doubled by the deflection of the second impeller can be displayed on a display device.

Finally, it is also possible to include the impeller The suspension must be covered with an insulating hat to protect against aggressive flow media, which can be done particularly easily, for example, that the surfaces of the impeller and the suspension are soft rubberized.

In the drawing are exemplary embodiments of the measuring device according to the invention and explained in the following description.

Fs show: FIG. 1 an embodiment of the measuring device according to the invention, in which the flywheel is inserted at its hub by means of diametrically into the line Is attached to the bridges, Fig. 2 is a partial section through the suspension of the flywheel. 1 along the line I-I, FIG. 3 shows a section, analogous to FIG. 2s, however, with a suspension consisting of a cage-like arrangement of individual Rods, Fig. 4 is a measuring device similar to Fig. 1, but in which magnetic Means for measuring the deflection of the impeller are provided, Fig. 5 a Another embodiment of a measuring device in which the impeller with its individual Wings is attached to webs on the inner diameter of the line and FIG. 6 shows a Section through the measuring device according to Fig. 5 along the line II-II.

In Figure 1 is between the line parts 1 and 2 for the line of flowing medium in the direction of arrows 3 a pipe ring 4 by means of the flanges 5 and 6 are used. In this tubular ring 4 diametrically located webs 7 are provided, at the intersection of which the hub body 8 is arranged. Firmly with this hub body 8 are connected four struts 9, which are in the interior of a hub 10 of an impeller L1 enter and are attached there. The impeller 11 is; with multiple wings 12th equipped, which are arranged on the outside of the honeycomb 10. The attachment point the struts 9 in the interior of the hub 10 of the impeller 11 is expediently like this chosen that the center of gravity of the moment surface, which results from the at each point of the impeller 11 results in partial torques acting on the flowing medium, in the fastening plane of the struts 9 lies. As a result, 9 of the struts do not need any additional tilting moments to be added, the impeller 11 from its try to move axially central position within the line part 2 Since the However, the arrangement of the struts 9 is stable enough to support the impeller 11 this special type of fastening can also be dispensed with.

In the line part 2, a certain sector is marked with a look-through Material 13 is covered, which allows the flow of the medium in the line parts 1 and 2 caused rotation of the impeller 11 from the outside to observe.

Such a twist is determined by the struts 9 by their special Arrangement allowed. As can be seen in particular from FIG. 2, the struts have 9 rectangular cross-section and are radiant around the axis 14 - the honeycomb 10, at the same time with the axis of the pipe parts 1 and 2 and the pipe ring 4 4 coincides, arranged. Ih @ section modulus in the radial direction is therefore very large, so that a movement of the impeller 11 prevents radial to the longitudinal axis l4 will.

The moment of resistance of the struts 9 in the tangential direction to the axis 14, on the other hand, is very small, so that # a rotary movement of the impeller 11, which is caused by the flow of the medium in the line, easily is possible.

Depending on the flow velocity and the weight of the flowing The medium is opposite to the zero position, i.e. when the flow is equal to zero for example on the outer surface of the transparent. Sector 13 marked can be adjusted to a certain angle of rotation through the transparent Sector 15 is observed and attached to sector 13, for example, with the aid of a Scale can be read.

In Fig. 3 the struts 9 'are designed as bars of a round cage, whose central axis 14 in turn coincides with the axis of the line parts 1, 2 and 4. This strut arrangement also has a large section modulus radially to the axis 14 and a low section modulus in the tangential direction to the axis 14.

In Fig. 4, the line part 2 is on its outer surface with individual tabs 15, which can also be used, for example, one below the other Ring can be connected, provided on which elastic bands 16 are attached, which are similar to the struts 9 with a rectangular cross-section.

On the other path of the straps 16, an annular magnet 17 is attached. On the outer edges of the blades 12 of the impeller 11, a thin layer 18 is magnetic Material applied so that when the impeller rotates. 11 due the flow within the line part 2 also the Magnet 17 with twisted. This rotation of the magnet 17 can be measured in various ways will; for example, it could be provided that the angle of rotation of the magnet 17 is derived directly from a scale or that it is achieved by mechanical, electrical or pneumatic aids are determined Ks could of course also be provided be that the magnet with a known nozzle baffle system or another Compensation device is connected, which on inn one of the magnetic force, which is exerted on the magnetic ring 17 by the impeller 11, counteracting compensation force exercises, which prevents the magnet 17 and also the impeller 11 from rotating, even if such a compensation device - mentioned at the beginning - is more expensive the Xeßvorrichtung causes. Depending on the flow rate it will become such a nozzle baffle system a larger or smaller compensation pressure set, which can give a measure for the flow.

It is also possible to have just one wing on its outer edge with magnetic Material or to be provided with a magnetic element, which is in the zero position, i.e. when the measuring device is retired, a corresponding magnet is placed on the Outside of the tube faces so that the rotation of the vane wheel 11 in similarly quiet as just described can be determined.

In addition, there is also the option of, for example, on the edge a wing of the impeller 11 to provide an electrical conductor, the electromagnetic Field of an electromagnet sitting on the outside of the line 2 during a rotary movement of the impeller 11 influenced.

This influence can be determined on electrical rege. In this way it is also possible to measure the flow rate. However the possibilities shown in FIGS. 1 and 4 are significantly simpler and therefore Cheaper than a measuring device equipped with an electromagnet or one Measuring device with a compensation system.

In Fig. 5, the impeller 1L with its suspension is similar to that in FIG Fig. L inserted between the Leit-ungsteile 1 and 2 with the help of the pipe length 4. In contrast to the embodiment according to FIG. 1, however, in this embodiment the tubular ring 4 inside not with diametrically extending webs, but with radially provided after ininen directed tab-like elevations 19 on which the struts 9 are attached to the torsionally elastic storage of the impeller L1. From Fig. 6 shows that the struts 9 have a rectangular cross-section and similar Ärie also in FIG. 2 in the manner of a ray, that is to say radially to the axis 14 of the pipe 2 are. As a result, they also have the embodiment according to FIG. 2 in a radial manner Direction to the axis 14 a large moment of resistance, in the tangential direction to the Axis 14 However, a low moment of resistance au. The striving 9 are not serbunden at their right end with the hub of the impeller 11, but directly with the leading edge of the wing 12. The hub of the impeller 11 can thereby be kept very small uhd is in contrast to the embodiments according to FIGS. 1 and 4 independently of the strength and the form of arrangement of the struts 9.

Also in the embodiment according to FIGS. 5 and 6, the previously indicated means for measuring the rotation of the impeller 11 can be used.

Claims (20)

Claims 1. Device for measuring the flow rate of media flowing within a line, in which the flowing medium a twist is imposed within the line, its retroactive torque is measured by a torsion-elastic member aur swirl suction, thereby characterized in that the member for generating a swirl is an impeller (11) which is inside the line is stored. 2. Apparatus according to claim 1, characterized in that the impeller is arranged centrally within the line. 3. Device according to claims 1 and 2, characterized in that that the impeller (11) by means of struts (9) made of elastic material with a line part (4) connected and stored within the line (2). 4. Device according to claims 1 to 3, characterized in that that the struts (9) are attached to the hub (10) of the impeller (11). 5. Apparatus according to claim 4, characterized in that the Struts (9) in the interior of the most hollow Mab. (10) of the impeller (11) are attached. 6. Device according to claims 4 and 5, characterized in that that the struts (9) are attached to webs (7) which are in a line part (4) are used. 7. Device according to claims 1 to 3, characterized in that that the struts (9) are arranged symmetrically to the line axis (14). 8. Vorzichtung according to claim 7, characterized in that the struts (9) run parallel to each other and parallel only pipe tunnels (l4). 9. Device according to claims 7 and 8, characterized in that that the struts (9) are designed as rods of a round cage, the central axis of which (14) coincides with the line axis. 10. Device according to claims 7 and 8, characterized in that that the struts (9) have a rectangular cross-section and seen in cross-section are arranged radially around the axis (14) of the line. 11. Device according to claims 1 to 10, characterized in that that the webs (7) to which the struts (9) are attached, diametrically to the line diameter run and are designed as flow straighteners or as Vordrallleitrad. 12. Performing according to claim 11, characterized in that the The webs (7) in the middle of the line are equipped with a feet-standing hub body (8) are, which corresponds to the diameter of the Ilügelradnabe (10). 13. Device according to claims 1 to 10, characterized in that that the webs (19) on the inner circumference of the line part (4) as radially inward directed tab-like elevations are formed. 14. Apparatus according to claim 13, characterized in that dio Struts (9) are attached to the blades (12) of the impeller (11). 15. Device according to claims 1 and 2, and one or more of the other claims, characterized in that a sector (13) of the line (2) is transparent gestaltot, so that the rotary movement of the impeller (Ll) directly can be observed from the outside. 16. Device according to claims 1 and 2 and one or several of the other claims, characterized in that for measuring the rotary movement of the impeller (11) magnetic elements (18) are provided, which with the impeller are connected and either the magnetic field of a fixed magnet can be measured affect or other movable magnetic elements (17) around the rotational movement move the corresponding amount of the impeller. 17. The device according to claim 16, characterized in that the outside On the line (2) for the flowing media a device connected to a suction device Pernanentmagnet (17) is movably arranged, which controls the movements of the impeller (11), the one on the outside of at least one wing (12) also with a permanent magnet (18) is provided with outer belt. 18. Apparatus according to claim 16, characterized in that at least with a wing of the impeller (11) electrical conductors are connected, whose Pivoting the measurable magnetic field of an outside on the pipe (2) fixed electromagnets. 19. The device according to one or more det claims 5 to 12, characterized characterized in that one impeller (11) each in the direction of flow seen in front of and behind the webs (7), one of which is the flow preferably given a twist opposing the twist of the other impeller. 20. The device according to claim 1 and one of the other claims, characterized characterized in that the impeller (11) with a finally its suspension (9) is covered with an insulating skin to protect against aggressive flow media.