DE1122272B - Method and device for counting quantities in a pipeline of flowing means - Google Patents

Description

Method and device for quantity counting in a pipeline Flowing Means The present invention relates to a method of counting quantities medium flowing in a pipeline using an impeller meter tangential flow measuring wheel as well as arrangements for carrying out this process.

Because of the storage effect of the widely ramified pipe networks, with ever increasing urgency calls for counters that show the passed Amount of the measuring medium with forward and reverse flow in the same reliable and display more accurately.

This requirement was met with the previously known types of measuring wheel counters not to meet. Apart from their other shortcomings, they have the disadvantage that their measurement error characteristics are different in one direction of passage than in the other, with the deviations and errors in the lower part of the measuring range, d. H. with small passages, often reach an unacceptable level for measuring practice.

The known measuring wheel quantity counters are therefore used by the calibration authorities only approved for measurements in one and the same flow direction.

The present invention provides a measuring wheel meter, which has the desired properties. The invention is based on the genus "Measuring wheel meter with a tangential flow impeller", and the technical one to be solved The task is defined by the question: How can you use a meter of this type reach that all wings of the measuring wheel at the same time one of the same size and Tangential drive that remains constant within each individual revolution to the wing surfaces are exposed, and how can one achieve that aimed Effect remains the same in both directions, so that the counter in both Directions give the same display characteristics (measurement error curve)? One way on which one can achieve this effect is shown by the present invention.

The invention consists essentially in that as a tangential drive the measuring wheel wing, which falls in the shape of a jacket around a no-flow central zone or increasing rotating flow at the narrowest zone of a vertebral depression and a subsequent eddy source of existing spiral vortex pair is used.

The invention is therefore an application of the known flow physics Laws of spiral vortex flow, d. H. of vertebral depression and eddy source, for quantity measurement with tangential current measuring wheel meters. To build a meter, one can decide which one should serve to implement this new procedure better known per se Serve spiral vortex-shaped lines of enclosing housing parts, which in their narrowest places and taking into account a stepless as possible Transition are interconnected. The inner form of the whole then embodies one rigid envelope of a spiral vortex pair, and the measuring wheel is axially closest Place this flow path to be built in and dimensioned so that it is with its blade ring into the spiral vortex flow, which extends the central zone like a rotating out Spiral coat wrapped at a distance.

The invention and construction of tangential current measuring wheel counters, which serve their realization, are in the following with reference to some in the drawing illustrated embodiments explained in more detail. In all figures are the same or parts that correspond to one another have been given the same reference numbers.

First of all, consider the embodiment according to FIGS. 1 to 3. Of the Counter is a tangential current measuring wheel counter. The measuring wheel is denoted by 1. That Housing has two helically curved line parts 2 and 3, each of which the one to bring the measuring means up to the measuring wheel, the other to lead it away from the measuring wheel is used, and in which the line cross-section of the feeding part with the approach to the measuring wheel, that of the discharging part with the distance from the measuring wheel increases (diffuser).

The housing part 2 has the connecting piece 4, the housing part 3 the nozzle 5. The part 2 is on its top by a lid-shaped Flange 6, the part 3 on its underside by a corresponding flange 7 locked. The flange 6 carries a cylindrical extension 8, the flange 7 an appropriately trained approach 9. These approaches are through the floors 10 and 11 completed, on which the bearings 12 and 13 of the standing Measuring wheel shaft 14 are arranged. The measuring wheel 1 has a central disk here 15 with a bowl-shaped edge 16 in which the wings or blades 17, preferably are arranged upright radially to the shaft 14 (Fig. 3). The rotation of the shaft 14 is here in the manner customary in measuring wheel counters by means of a worm 18 (Fig. 1) and the usual gears on a located under the counter cap 19 Display unit 21 transferred.

The screw shape of the two housing parts 2 and 3 is now chosen so that they follow the regularity and the flow shape of a distance around the measuring wheel axis rotating spiral vortex follows, so that the flow is on the side of its approach a vertebral depression on the blade ring of the measuring wheel, on the side where it leads away from there a source of eddy forms. Both parts meet at their narrowest points together, and the arrangement is made so that the transition of the streamlines from the sink in the source takes place at least approximately steplessly. This transition will be explained in detail later.

Fig. 2 shows on the left side a plan view with the lid 6 and a section through the cylindrical extension 8, on the right side one Horizontal section through the housing part 2. The course of the outer wall can be seen 2 'and the inner wall 2 ", the continuation of which on the left side of the figure with dashed lines Lines is made visible. Between these walls there are still guiding means (blades 22, 23, 24 or the like) recognizable, of which again those on the left side are indicated with dashed lines. Through the walls 2 ', 2 "and the conducting means 22, 23, 24 is the means to be measured, the measuring wheel in the desired spiral vortex shape almost tangential with the desired acceleration curve, d. H. almost vertical to the wing surfaces 17, supplied and while maintaining the direction of rotation of the measuring wheel with the corresponding spiral vortex shape and the corresponding deceleration curve from the blade ring of the measuring wheel 1 between the walls 3 'and 3 "to the outside Connection piece 5 passed or vice versa. The spiral vortex movement is at work here of the measuring means in a natural way promoting the pressure recovery.

As Fig. 1 shows, in this embodiment, the housing parts 2 and 3 conical, the part 2 with the plane of symmetry I-I des Measuring wheel the angle o, the part 3 forms the angle fl. This training serves in Connection with the bowl-shaped measuring wheel rim 16 to the medium to be measured as possible trouble-free from one to the other housing part, d. H. from the sink shape into the source shape to transfer. It is easy to see that this transition is minimal an error occurs when a is fl and the lines of symmetry II and III of the two Housing parts are parallel or merge into one another at axis point 0. Are the Angle x and ß are different in size, so the flow becomes when crossing from one to the other other housing part within the cup-shaped measuring wheel rim 16 and deflected thereby generates an axial thrust which relieves the lower support bearing the shaft 14 can be used. It is quite possible that one for the cutting profile of the trajectory instead of a tapered one also a half- spherical, elliptical, parabolic with a truncated crown or another suitable one Shape can choose. In either of these cases, there will be an unconstrained flow in both Directions made possible.

The guide means, here the blades 22, 23, 24, can be of any suitable type Receive training. So you can z. B. subdivided instead of continuous guide vanes apply and arrange their parts or sections offset or shifted to one another, in order to achieve an improved flushing of their walls and to make it more difficult for dirt to accumulate. In order for the velocity profile of the flow as it enters the blade ring of the measuring wheel to gain a correction option, one can use the expiring part of the guide vanes straight or flat and with a trip edge (bend or the like) provided. Since it can happen that the guide channels deviate from each other Have flow resistances, you can use them to regulate auxiliary links (flaps, Displacement body or the like.) Provide through which it is possible to these resistances to change as needed. The simplest means for this purpose can be screws or the like, which are screwed through the housing wall into the guide channel concerned will. Such additional resistances, which allow an uneven Compensate for the loading of the measuring wheel blades or blades, are to be compensated for with measuring wheel meters known per se and not the subject of the invention.

In some cases it is necessary to have a flow control facility to be provided in the meter, e.g. B. to change its measuring range to the lowest possible night consumption. For this purpose, a thin-walled, between the measuring wheel and the housing parts 2 and 3 inserted movably arranged cylinder resp.

Serve double cylinder, which is coaxially to the shaft 14, in Is displaceable or pivotable in the direction of its axis and during this movement the Inflow cross-section to the measuring wheel and the outflow cross-section from the measuring wheel in steps or continuously changes and by which at the same time one provided in the counter drive variable translation is set accordingly. A special graphic one Representation of this version appears to be dispensable.

In the embodiment according to FIGS. 1 to 3, the measuring wheel has wing surfaces perpendicular to the flow, which when the flow changes act in one sense or the other as driving or damping or braking surfaces. To make this interaction even more contrasting and for this purpose that To reduce the moment of inertia of the measuring wheel as much as possible, one can use the shell-shaped Omit guide 16 on the measuring wheel (Fig. 1) and make it part of the housing, like this that the measuring wheel then only consists of the disk 15 and the blades or blades 17 consists.

For this purpose, the tray guide 16 is according to the line 1-1 divided and their upper half with the lid-shaped flange 6 of theirs lower united with the opposite flange cover 7 of the other housing part. The measuring wheel disk can be located in the gap remaining between the housing parts 15 move freely with the required play, with their wings 17 in the Circulate the annular space enclosed by the shell halves. A special graphic one Representation of this variant appears to be dispensable.

Because, as shown above, the measuring wheel is extremely light and can be kept smooth and because of the drive described all of its wings in both directions of flow through a pair of spiral vortices an equally large and constant within the individual rotation of the measuring wheel Tangential drive are exposed, shows the built and working according to the invention Counters are equally good in both flow directions. The translation remains between the measuring wheel 1 and the counter 21 in both cases the same because the Wing surfaces 17 do not deflect the spiral vortex flow encircling the measuring wheel, but are hit almost vertically by it and taken away.

This is the same correct display in both flow directions use yourself to check the meter after a certain period of operation Input and output by turning the meter or switching within the pipe system, in which it is built in, interchanged. Result in both directions of flow same displays, the meter is OK, otherwise it is clearing displayed.

In the embodiment of FIGS. 1 to 3 go the lower Wall of the housing part 2 and the upper part of the housing 3 (cf. at 25) directly into each other. But you can also move the two housing parts away from each other and as a connecting piece between them a cylindrical, coaxial with the measuring wheel shaft 14 Arrange the pipe section.

This structural variant, which is also not shown, can be used arrive at an enlargement of the wing surface 17, so that the drive torque on Measuring wheel 1 reinforced by the flow in the ratio of the area enlargement and this increases the display accuracy of the counter.

A number of further exemplary embodiments of the invention are shown in FIG. 4, in which they are shown in a combination for the sake of simplicity are. Here the housing parts 26 and 27 correspond to the parts 2 and 3 of FIG. 1. A conical guide body 28 with guide plates 29 is arranged coaxially in part 26, which have the shape of helical surfaces and the guide body 28 against the outer wall prop up. The measuring medium flow entering, for example, part 26 is there the characteristics of a spiral vortex (vertebral depression) given, its speed reaches its maximum at the blade ring 17 of the measuring wheel 1.

The housing part 27 into which the flow now enters and in which it is guided away from the measuring wheel with corresponding vortex source characteristics formed here according to another embodiment of the invention. He owns a conical shell with a cylindrical core 30, which is supported by the baffles 31 is worn, these having the same sense of winding as the baffles 29. Instead of the housing parts or spiral eddy guides 27, 30, 31, one can as indicated on the left-hand side of FIG. 4 (reference number 32), but also such use in the manner of the housing part 3 of FIG.

The measuring wheel 1 then has only half a shell 16 and its wings 17 are adapted to the flow guidance. The arrangement of the counting and display mechanism is then about the same as in the embodiment according to Fig. 1 (parts 8, 10, 12, 18, 19, 21).

Claims (6)

PATENT CLAIMS: 1. Method for counting quantities in a line flowing medium using an impeller meter with tangential flow Wing ring, characterized in that the measuring wheel wing is used as a tangential drive the jacket-shaped rotating, falling or rising, around a no-flow central zone Flow at the narrowest zone one from a vertebral depression and one adjoining it Eddy source existing spiral vortex pair is used. 2. Arrangement for carrying out the method specified in claim 1, characterized in that the measuring wheel meter housing consists of a pair at its closest Places merging into one another, spiral vortex-shaped lines that are known per se forming parts, the measuring wheel (1) in the flowless central zone of the Transition is stored and with its wing rim (17) in the encircling this zone Spiral vortex flow reaches into it. 3. Arrangement according to claim 2, characterized in that at the transition from one to the other of the two vortex forms (sink and source) Housing parts the inner limitation or guidance of the vortex shape against the flowless Central zone by an outwardly extending over the circumference of the measuring wheel (1) Open shell (16) is formed, in which the measuring wheel wings (17) sit. 4. Arrangement according to claim 2, characterized in that when used an ordinary impeller with free-standing blades on both sides of the transition between the line parts enveloping the two vortex forms a measuring wheel facing all around running half-shell is provided, with the measuring wheel and moves its wing ring in the annular space formed by these half-shells. 5. Arrangement according to claims 2 to 4, characterized in that that at least one of the two line parts which enclose the spiral vortex flow, as a pipe section (26 or 27) with an axially built-in displacement body (28 or 30) and surrounding this displacement body according to the flow shape of a spiral vortex and guide walls (29 or 31) supporting it against the pipe wall (26 or 27) is. 6. Arrangement according to claims 2 to 5, in which only one of the two line parts enveloping the spiral vortex flow as a pipe section with axial built-in displacer, characterized in that as an inner flow guide in the transition from one to the other line part one on the circumference of the measuring wheel (1) provided, all-round half-shell (16) is used. Considered publications: German Patent Specifications No. 298 245, 663 674; British Patent No. 529,615; U.S. Patent No. 1 005 875.