DE10120355A1 - Ultrasonic flow measurement of fluids such as natural gas, has acoustic transceivers that direct divergent beams of sound waves to sections of the pipe shaped to form parabolic reflectors - Google Patents

Abstract

At ends of a measurement pipe (1) are located acoustic transducers acting as transceivers. The first (2) beams a divergent beam (4) of sound waves to a section (8) of the pipe shaped to form a parabolic reflector. This directs a parallel beam (9) to a second parabolic reflector (10) which directs a convergent beam (11) to the second transducer (3). Over the resultant sound path all the individual sound waves (5-7) have the same length so that the presence of turbulence in the pipe is indicated by time delays and frequency shifts between the individual waves.

Description

The invention relates to a method and a Vorrich device for ultrasonic flow measurement of fluids in one Measuring tube, the two spaced in the flow direction, each ultrasonic transducers working as transmitters / receivers points, the ultrasound from the transducers as divergene beam of rays emitted, with reflection and focus sion along a sound path and by the transducers is received as a convergent beam.

The invention is applicable to flow measurement all fluids, but preferably on the through flow measurement of technical gases such as compressed air, stick substance, methane, oxygen and. Like .. Of essential importance device is the invention for the flow measurement of natural gas, because natural gas is a priority among gaseous energy sources position.

In the ultrasonic flow measurement signals between exchanged between the two converters. The signals follow the sound path, whereby the running time varies depending on the differences result. From these differences the Strö flow rate derived from the fluid then including the cross section of the measuring tube river results.

Method and device of the type mentioned are known from DE 195 49 162 A1. The use of le only two converters, that is, the way of working with only one Measuring channel, is constructive and therefore economical more than working with multiple measuring channels and egg A corresponding number of converters, see example as the DE 196 32 165 A1. With larger volume flows, d. that is, with larger measuring tube cross sections, all results dings the disadvantage that the flow is turbulent  and that the turbulence related to time delays and frequency lead to shifts in the measurement signals.

The invention is based, to this task to fix parts, d. that is, to increase the measurement accuracy.

To solve this problem is the Ver drive according to the invention characterized in that the Rays of the divergent beam are reflected in this way and be focused over the length of the transducer of the same length.

The latter is already mentioned in the process according to the ten DE 195 49 162 A1 not the case. The divergent beam len bundle is there on a focusing reflection surface directed and from there forming the convergent Beam of rays fed to the receiving transducer.

The invention is based on the finding that under different path lengths of the individual rays, as well Turbulence of the current, to wash out the waves front lead and therefore also time delays and Fre cause cross-shifts. So are the path lengths of the the same individual rays result in laminar flow provided no time delays and frequency shift environments. If these phenomena do occur, it is a sign that the flow is turbulent.

The same path length of the individual rays therefore offers the possibility to measure the degree of turbulence of the flow and to correct the measurement accordingly, i.e. the measurement increase accuracy.

The design of the sound path is not subject to any boundaries, provided the characteristics of the divergence, the conver and the same path lengths are met. Especially It is advantageous to use the rays of the divergent rays into a parallel beam and then into the convert convergent beams. The pa parallel bundles of rays definitely undergo deflections. Vorzu However, pulling is a sound path between the two the converters are N-shaped.  

It is also advantageous for reasons of measurement accuracy to prevent direct radiation between the transducers countries.

The invention also provides an ultrasonic flow measuring device with a measuring tube and with two each as Sen of the / ultrasonic transducers working in Flow direction are spaced in the measuring tube and together with at least one reflection surface Define sound path for the rays of ultrasound where in this device to solve the task he according to the invention is characterized in that the converter together with at least two functional reflection surfaces define the sound path in such a way that the rays of the ul trashalls over the length of the sound path of the same Length are.

The reflection surfaces are preferably paraboloid surfaces chen, in the focal points of the transducers. The Rays of the ultrasound form, seen in the direction of travel divergent bundle of rays, an adjoining paral leles bundle of rays and finally one on the received convergent beam directed at the transducer. The Fo kissing the received transducer leads to a ver strengthening of the received signal, whereby its Störemp sensitivity is reduced.

The guidance of the parallel beam can be several Experience redirections. However, it is more advantageous that Form the sound path in an N-shape.

In an essential further development of the invention, it is provided strike, the halves of the sound path in mirror image train each other, based on two to each other vertical planes, one of which is the axis of the measuring tube res contains. The sound path lies in one diametrical plane of the measuring tube.

Preferred are means for preventing direct radiation is provided between the transducers. The converter can all or part of this in recesses in the wall  of the measuring tube. Alternatively or in addition each transducer protrudes from the wall of the measuring tube be assigned to the nose, the contour of which is advantageous is designed for minimal flow disturbance.

As a rule, one becomes the cross section of the measuring tube choose circular. However, the invention is advantageous also applicable to a rectangular cross section, the Height is greater than the width, with the transducer and the Reflective surfaces in the narrow transverse walls of the measuring tube are arranged.

It is particularly advantageous to use the broad sides walls of the measuring tube to give an anti-reflection structure hen. This offers the possibility of changing the width of the measuring channel to enlarge so that the principle of waveguide left can be sen. The reflections that occur at the Sidewalls of the measuring tube are suppressed. Come to this scattering and / or absorbent surfaces in question for example, an adapted surface roughness or a λ / 4 layer.

Regardless of the cross-sectional shape of the measuring tube, the invention is intended for smaller nominal diameters in the range DN 25-DN 50 with a flow measuring range of approximately 1-200 m ³ / h and a pressure range of approximately 1-100 bar.

The invention is based on a preferred Embodiment in connection with the accompanying Drawing explained in more detail. The drawing shows in:

Figure 1 is a schematically illustrated axial section through a device according to the invention.

Fig. 2 is a diagrammatically illustrated front view of belonging.

According to Fig. 1, the device comprises a measuring tube 1, are arranged in the wall of which a first ultrasonic transducer 2 and a second ultrasonic converter 3. The transducers 2 and 3 work as transmitters / receivers and feed each other with ultrasonic signals. For the sake of simplicity, it is assumed for the sake of simplicity that the wall 2 forms the transmitter and the converter 3 forms the receiver.

The ultrasound leaves the transducer 2 in the form of a di-ray beam 4 , reproduced by an outer beam 5 , a second outer beam 6 and a central beam 7 .

The divergent beam 4 strikes a first functional reflection surface 8 , which is designed as a paraboloid surface and is arranged such that the transducer 2 is at its focal point. The divergent beam is deflected at the reflection surface 8 and converted into a parallel beam 9 .

The latter strikes a second functional reflection surface 10 , which converts the parallel beam 9 into a convergent beam 11 and focuses on the second converter 3 . The second reflection surface 10 is also designed as a paraboloid surface and is arranged such that the second transducer 3 lies in its focal point.

The beams 4 , 9 and 11 define a sound path. It is essential that the lengths of all rays, represented here by rays 5 , 6 and 7 , are of equal length over the length of this sound path. This means laminar flow provided that there are no time delays and no frequency shifts between the signals of the individual beams. So if time delays and frequency shifts are detected during the measurement, this means that the flow is subject to turbulence. The degree of turbulence can be determined and the measured values can be corrected accordingly. As a result, the accuracy of measurement increases.

The schematic front view according to FIG. 2 also shows the sound path, defined here by two outer beams 13 and the beam 7 coinciding with the vertical central axis.

The switching path is, as shown in Fig. 1, N-shaped, the central beam 7 , as shown in Fig. 2, lies in a diametrical plane.

The arrangement of the transducers 2 and 3 and the reflection surfaces 8 and 10 is such that the two halves of the sound path are mirror-symmetrical to each other, on the one hand based on a plane containing the axis of the measuring tube 1 , perpendicular to the plane of the drawing and on the other related to a plane perpendicular to the latter and also perpendicular to the plane of the drawing.

Of FIG. 1 is also clear that means are provided which prevent direct radiation between the transducers 2 and 3. These are lugs 14 which protrude somewhat into the flow, but in such a way that the flow is only minimally disturbed. An alternative possibility is to not, as shown, partially, but completely sink the transducers into the wall of the measuring tube.

Modifications are possible within the scope of the invention given. So the invention is not at one set a circular measuring tube cross section limited. Rather, rectangular cross sections are also conceivable in de the transducers and reflective surfaces in the narrow cross walls are arranged. The higher side walls can be one Have anti-reflection structure, so that the measurement larger volume flows is possible.

Above all, there is a high degree of freedom in what the design and management of the sound path. Kei In any case, it is necessary that the sound path to egg one single diametrical plane. Rather is one any guidance through the measuring tube possible. this is also valid for deviations from the N-shape and for deviations from the generation of a parallel beam. This becomes can be seen that even in the paraboloidi gene formation of the reflection surfaces and the associated Location of the transducer is not seen as a limitation, but just a preferred education. Essential  is that the sending transducer has divergent rays emit bundles and the receiving converters converge Pick up rays and that the lengths of the rays are the same over the length of the sound path.

Claims (14)

1. A method for ultrasonic flow measurement of flui in a measuring tube which has two spaced in the flow direction, each working as a transmitter / receiver, has ultrasonic transducers, the ultrasound being emitted by the transducers as a divergent bundle of rays, with reflection and focus guided along a sound path and received by the transducers as a convergent beam, characterized in that the rays of the ultrasound are reflected and focused in such a way that they are of equal length over the length of the sound path. 2. The method according to claim 1, characterized in that that the rays of the divergent bundle of rays in one parallel beam and then its rays into the convergent beams are converted. 3. The method according to claim 1 or 2, characterized shows that the sound path between the two transducers N- runs in a shape. 4. The method according to any one of claims 1 to 3, characterized characterized by direct radiation between the wall learning is prevented. 5. Ultrasonic flow meter with a measuring tube ( 1 ) and with two each working as a transmitter / receiver ultrasonic transducers ( 2 , 3 ), which are arranged in the flow direction spaced in the measuring tube ( 1 ) and together with at least one reflection surface ( 8 , 10 ) define a sound path for the beams ( 5-7 , 13 ) of ultrasound, characterized in that the transducers ( 2 , 3 ) together with at least two functional reflection surfaces ( 8 , 10 ) define the sound path in such a way that the beams ( 5 -7 ) of ultrasound are of equal length over the length of the sound path. 6. Ultrasonic flow meter according to claim 5, characterized in that the reflection surfaces ( 8 , 10 ) are paraboloid surfaces, in the focal points of which the transducers ( 2 , 3 ) are located. 7. Ultrasonic flow meter according to claim 6, characterized in that the sound path is N-shaped forms is. 8. Ultrasonic flow meter according to one of Ansprü che 5 to 7, characterized in that the halves of the sound path are mirror images of each other, in relation to two mutually perpendicular planes, one of which contains the axis of the measuring tube ( 1 ). 9. Ultrasonic flow meter according to one of claims 5 to 8, characterized by means for preventing direct radiation between the transducers ( 2 , 3 ) 10. Ultrasonic flow meter according to claim 9, characterized in that the transducers ( 2 , 3 ) are wholly or partially lowered into recesses in the wall of the measuring tube ( 1 ). 11. Ultrasonic flow meter according to claim 9 or 10, characterized in that each transducer ( 2 , 3 ) from the wall of the measuring tube ( 1 ) projecting nose ( 14 ) is assigned. 12. Ultrasonic flow meter according to claim 11, characterized in that the lugs ( 14 ) have a contour which is designed for minimal disturbance of the flow. 13. Ultrasonic flow meter according to one of the Claims 5 to 12, characterized in that the measuring tube has a rectangular cross section, the height of which is greater than the width, the transducer and the reflecting surface Chen arranged in the narrow transverse walls of the measuring tube are. 14. Ultrasonic flow meter according to claim 13, characterized in that the wide side walls of the measuring tubes have an anti-reflective structure.