DE19510127A1 - Oscillatory counter type flow-meter for liquids and gases - Google Patents

Abstract

The flow meter has an input and output openings (2,6) between which there is a flow system incorporating a nozzle (3) where a relationship between the flow throughput speed and an oscillating fluid stream is established. The flow system further incorporates a ring channel (4), and flow divider (5) and a measurement device. The nozzle incorporates a longitudinal slit with end transverse slits, which is interrupted by at least one further transverse slit which is/are as long as or shorter than the longitudinal slit. The transverse slits can assume various profile shapes and lengths .

Description

The invention relates to an oscillating jet counter for liquids and gases with the specified in the preamble of claim 1 Characteristics.

Swinging jet counters are flow meters of the fluidistor type to those who have an inlet connector in a closed housing se entering liquid is fed to a nozzle, at the A ring-shaped outlet emerges and roughly transverse to the main flow direction extending channel and subsequently in flow direction device connects a flow divider and an outlet connection. At the A fluid flows through this oscillating jet counter a fluid jet oscillating depending on the flow rate generated. The frequency of this oscillating fluid jet becomes determined. Depending on the frequency, a certain flow can then quantity can be assigned, so that based on the frequency Flow rate can be determined. Such oscillating beam counters are well known and exemplified in DE 36 09 748 C2 or DE 39 28 442 A1.

Such oscillating jet counters as flow meters are very simple and robust devices that have no moving parts and  therefore have a long lifespan. There is a certain disadvantage to see that their measurement accuracy depends on the Meßbe is rich. Is within a range of approximately two powers of ten the measurement error very small. This measurement error, however, takes on especially when crossing the lower limit, so too small NEN flow rates (creeping amounts).

Another problem is that at comparatively small Flow rates not only decrease the measuring accuracy, but nor the relationship between flow rate and frequency is more linear. The US is addressing this problem Patent 5,063,786. There will be in the cross instead of the usual cut rectangular nozzle suggested to both ends of this Longitudinal slot to provide a transverse slot of shorter length. This measure can indeed limit the linearity of the Vibration beam counter can be moved further down, however the measuring accuracy as such is in the lower measuring area rich hardly influenced.

While the Pro. Described in the aforementioned U.S. patent due to the lack of a linear relationship between frequency and flow rate in the range of low flow rates in the Practice is irrelevant because of the electronic measurement evaluation This can be easily compensated for Measuring accuracy of such an oscillating beam counter in particular still problems in the lower measuring range. So Ver search result that deviations in the measurement result at low Flow rates occur especially when there are changes occur in the degree of turbulence of the supplied flow. One leaves for example water from a high tank through one Oscillating jet counters flow and the same another time Flow rate coming from a centrifugal pump, then  Different frequencies, especially with small flow rates zen to be measured.

Otherwise, all oscillating beam counters, in which the entire Fluid amount is passed through a nozzle, the disadvantage that they cause pressure drops in the piping system in which they are installed are lead. Proceeding from this, the object of the invention the basis for training a generic oscillating jet counter in this way the that with structurally simple means, the measuring accuracy is improved at small flow rates, especially the Influence of the degree of turbulence of the flow on the flow measurement solution is largely switched off.

This task is performed with a generic oscillating jet tough ler indicated by the in the characterizing part of claim 1 benen features, namely in that the longitudinal slot of the nozzle through at least one further cross slot (intermediate cross slot) is interrupted, d. that is, at least three transverse slots, namely two end cross slots and an intermediate cross slot are seen. The arrangement of the intermediate cross slot does not have to be be symmetrical, neither in relation to the longitudinal axis nor to the Transverse axis of the longitudinal slot. So instead of one continuous intermediate slot extending on both sides of the longitudinal slot, two offset to each other orderly intermediate transverse slots may be provided, which for extend one or to the other side of the longitudinal slot.

Tests have shown that the inflow conditions in the usual measuring devices with rectangular or double T-shaped according to the cross-section of the nozzle have a special influence if the Flow at this point approaches the Reynolds number which the Separates transition area from the area of laminar flow.  

By the intermediate cross provided according to the invention slit next to the two end transverse slits decreases Influence of different inflow conditions. By opening separating the nozzle walls behind which there are whirling streets. Apparently is through this vortex produces microturbulence so that the route to Laminar flow is not given. The Strouhal Number probably plays a role here.

With the solution according to the invention, the influence of Inflow conditions especially with small flow rates significantly reduced, whereby the measuring accuracy of the oscillation beam counter can be significantly improved in this area. The linearization in U.S. Patent 5,063,786 the lower measuring range, however, is not the subject of the invention and therefore not necessary in the solution according to the invention properly given.

The training according to the invention in the area of the nozzle is ferti technically realizable without noticeable additional costs. she leads moreover, that the nozzle cross-section as such in Ver becomes larger than the rectangular nozzles previously used, so that the pressure losses when using the invention Vibration beam counter are lower than in the previously known.

The length of the intermediate cross section or sections is preferred equal to or less than the length of an end transverse slot. At asymmetrical arrangement of the or the intermediate transverse slots adjust this length accordingly, d. i.e. to one side of the Part of an intermediate transverse slot lying in the longitudinal slot is the same or less than half the length of an end cross slot dimension.  

A preferred shape of the transverse slots arises if their contours in the areas where they go to another Cross slot are adjacent, jagged or wavy is trained. This can obviously cause microturbulence can still be improved.

A also has an advantageous influence on the measuring accuracy Formation of the transverse slots in those facing away from the longitudinal slot End areas where the cross slot ends to the neighboring Cross slot are widened.

The length of a transverse slot is preferably two to two Eight times the width of the longitudinal slot. Arranged at offset Neten transverse slots, which are only to one side of the longitudinal extend slot, the length is reduced accordingly to the Half. The width of the transverse slots should be between one Fifth and a whole of the width of the longitudinal slot.

In a preferred embodiment, the length of the or Intermediate cross slots smaller than that of the end cross slots. Also the same applies here for an offset cross slit.

As experiments have shown, there is a significant increase in Measurement accuracy is given if there are at least three transverse slots are provided. This increase in measuring accuracy cannot arbitrarily increased by a large number of further transverse slots a particularly high measuring accuracy is then achieved, if one to three intermediate transverse slots are provided, namely preferably distributed at the same distance between the end cross slit.

The invention is based on in the drawing illustrated embodiments explained in more detail. Show it:

Fig. 1 is a perspective simplified view of the inherent ren components of an oscillating jet meter according to the invention,

Fig. 2 shows the measurement accuracy of three oscillating beam counters of different types depending on the flow rate and

FIGS. 3 to 9 different nozzle cross-sections according to the invention.

Fig. 1 illustrates the inner housing structure of an oscillating jet counter. The component shown there cut in the upper area consists of plastic and is formed by joining individual injection molded parts. The fluid flow identified by 1 passes through an inlet nozzle 2 ( not shown in detail ) to a nozzle 3 , which continuously reduces the free flow cross section down to the nozzle cross section. At the outlet of the nozzle 3 is a transversely to the main fluid stream 1 arranged ring channel 4 , beyond the ring channel 4 is in alignment with the nozzle 3, a flow divider 5 and then an outlet channel 6 is provided, which leads to the outlet port not shown. The ring channel 4 has an opening 7 offset from the nozzle 3 by 180 °, through which the measuring sensor system, not shown, is incorporated into the ring channel 4 .

This oscillating jet counter works in a manner known per se. It is integrated with its inlet and outlet connections into the fluid line, the flow rate of which is to be recorded. The fluid stream 1 entering via the inlet nozzle 2 passes through the nozzle 3 to the opposite flow divider 5 and then via the outlet duct 6 back into the line. Corresponding to the flow rate, the fluid flow emerging from the nozzle 3 is passed alternately to one and the other side of the flow divider 5 , as a result of which the fluid located in the annular channel 4 is set into vibrations corresponding to the deflection on the flow divider. These vibrations are detected by a measuring sensor system in the area of the opening 7 and implemented by means of evaluation electronics to determine the flow rate.

In FIG. 2, the measurement accuracy is shown of three vibrating beam counters, which differ only in the shape of the nozzle cross-section. The percentage measurement error is shown on the vertical axis and the flow rate is shown on the horizontal axis in logarithmic measure. The circular Meßpunk te derived from a vibrating beam counter with a rectangular cross-section nozzle, the rectangular measuring points of a vibratory beam counter with a nozzle shape as based in U.S. Patent 5,063,786 of FIG. 5 and the oval measuring points of an inventive nozzle cross-sectional shape as shown in FIG . 4. the measurements have been carried out once with a liquid which flows from a centrifugal pump into the oscillating jet meter and the second time with a flowing liquid from a pressure accumulator. It is clear that with nozzle cross-sections according to the prior art, in particular in the area of creeping flows, the measurement errors are significantly higher than those of an oscillating jet counter with nozzle shape according to the invention. Thus, the measurement errors are shown in Fig. 2 with the use of the vibrating beam counter according to the invention between about 2% and -1%, compared to the prior art, between 7% and -4%. The increase in measurement accuracy is therefore considerable due to the design according to the invention, in particular the dependence on the inflow conditions is significantly less than in the case of oscillating jet counters according to the prior art.

The nozzle cross sections shown with reference to FIGS. 3 to 9 all consist of a longitudinal slot 8 which is essentially rectangular in cross section. This longitudinal slot 8 is delimited at its ends by end transverse slots 9 . In the nozzle cross-sections of FIGS. 3 and 4, the end transverse slots 9 rectangular shape. One or more intermediate transverse slots 10 are arranged between the end transverse slots 9 .

As far as the numbered features that are shown with reference to FIGS . 3 to 9, in the following in the individual execution forms match, they are only referred to with reference numerals. Insofar as they differ from one another, the reference numerals are provided with a letter, letter a for deviations according to FIG. 3, letter b for deviations according to FIG. 4, letter c for deviations according to FIG. 5 etc. up to the letter g for Deviations in Fig. 9 was chosen.

In Fig. 3, three intermediate transverse slots 10 a are provided between the end transverse slots 9 over the longitudinal slot 8 , which are arranged asymmetrically such that a longer section from an intermediate transverse slot 10 a to one side and a shorter section to the other side of the longitudinal slot 8 he stretches. In this case, the longer section located intermediate the central transverse slot 10 a on the side of the longitudinal slot 8, to which the shorter portions of the other two intermediate transverse slots 10 are a.

In the embodiment according to FIG. 4, three intermediate transverse slots 10 are arranged distributed uniformly over the length of the longitudinal slot 8 between the end transverse slots 9 . The intermediate transverse slots have a rectangular shape like the one shown in FIG. 3, but are arranged symmetrically to the longitudinal slot 8 , so that the sections extending to both sides of the longitudinal slot 8 are each of the same length. While the length of the intermediate transverse slots 10 corresponds to approximately half the length of the longitudinal slot 8 in the embodiment according to FIG. 3, this length corresponds to approximately one third of that of the longitudinal slot 8 in the embodiment according to FIG. 4.

In the embodiments according to FIGS. 5 to 9 show the Endquerschlitze both 9 and the intermediate transverse slots 10 c to g of the same length, namely of about two thirds of the longitudinal slot 8.

In the embodiments according to FIGS. 5 to 9, two intermediate transverse slots are provided between the end transverse slots 9 . In all these versions, the transverse slots are widened towards their ends, in such a way that widening only takes place towards the adjacent transverse slot 9 , 10 . In the embodiment according to FIG. 5, this expansion takes place 11 c linearly from the longitudinal slot 8 the end of the corresponding cross slot 9 c, 10 c out. In the embodiment according to FIG. 8, the widenings 11 f are approximately semi-circular, so that there are zen 10 f circular in the intermediate cross slots and 9 f semi-circular widenings 11 f in the end transverse slots. In addition, the cross slots 9 f and 10 f have substantially rectangular shapes. In the embodiment of FIG. 9, the widening 11 is rectangular g.

In the nozzle cross sections shown in FIGS . 6 and 7, not only is an expansion 11 d or 11 e in the end region of the intermediate transverse slots 10 d or 10 e provided, it is also the longitudinal wall of the transverse slot 9 d, 10 d or 9 e, 10 e wavy lines, and only in the areas in which the cross-slot is adjacent to another cross-slot be. While the wall contour has approximately the shape of a sine wave in the embodiment according to FIG. 6, this is guided in a flat zigzag in the embodiment according to FIG. 7.

The size ratios specified in the introduction to the description (length and width) of the longitudinal slot 8 , end transverse slot 9 and intermediate transverse slot 10 are shown by way of example in FIGS . 3 to 5. 12 means the length of the longitudinal slot, 13 the length of an end transverse slot, 14 the length of an intermediate transverse slot, 15 the width of the longitudinal slot and 16 the width of a transverse slot.

Reference list

1 fluid flow
2 inlet sockets
3 nozzle
4 ring channel
5 flow dividers
6 outlet channel
7 opening
8 longitudinal slot
9 end cross slots
10 intermediate cross slots
11 widening
12 Length of the longitudinal slot
13 Length of an end cross slot
14 Length of an intermediate cross slot
15 width of the longitudinal slot
16 width of a cross slot

Claims (8)

1. oscillating jet counter for liquids and gases with an inlet opening ( 2 ), an outlet opening ( 6 ) and with an interposed flow system for generating an oscillating depending on the flow rate liquid jet jet consisting essentially of a nozzle ( 3 ), one arranged transversely thereto Ring channel ( 4 ), a flow divider ( 5 ) and a measuring device, wherein the nozzle ( 3 ) has a cross-section substantially rectangular longitudinal slot ( 8 ) which is broken in the end areas of a transverse slot ( 9 ) (end transverse slot) , characterized in that the longitudinal slot ( 8 ) is interrupted by at least one further transverse slot ( 10 ) (intermediate transverse slot). 2. oscillating jet counter according to claim 1, characterized in that the length of the or the intermediate transverse slots ( 10 ) is equal to or less than the length of an end transverse slot ( 9 ). 3. oscillating jet counter according to claim 1 or 2, characterized in that the contour of the transverse slots ( 9 , 10 ) in the areas in which a transverse slot ( 9 or 10 ) is adjacent to another transverse slot ( 10 or 9 ), not one straight course, preferably a jagged or wavy course. 4. oscillating jet meter according to any one of the preceding claims, characterized in that each transverse slot (9, 10) slotted at its end in the areas in which it is adjacent to another transverse slot (10, 9), adjacent to this cross (10 , 9 ) is expanded ( 11 ). 5. oscillating jet counter according to one of the preceding claims, characterized in that the length ( 13 , 14 ) of the transverse slots ( 9 , 19 ) corresponds to two to eight times the width ( 15 ) of the longitudinal slot ( 8 ). 6. oscillating jet counter according to one of the preceding claims, characterized in that the width ( 16 ) of the transverse slots ( 9 , 10 ) corresponds to a fifth to a whole of the width ( 15 ) of the longitudinal slot ( 8 ). 7. oscillating jet counter according to one of the preceding claims, characterized in that the length ( 14 ) of the or the intermediate transverse slots / s ( 10 ) is smaller than that ( 13 ) of the end transverse slots ( 9 ). 8. oscillating jet counter according to one of the preceding claims, characterized in that one to three intermediate transverse slots ( 10 ) are preferably distributed at the same distance between the end transverse slots ( 9 ).