DE102008055030A1 - Measuring tube of an ultrasonic flow measuring system - Google Patents

Abstract

Measuring tube (3) of an ultrasonic flow measuring system (1), which measuring tube (3) has an approximately circular measuring tube inlet (7) and an approximately circular measuring tube outlet (8), wherein the measuring tube (3) has a Meßrohrmittelteil (9) between the measuring tube inlet (7) and the measuring tube outlet (8), which Meßrohrmittelteil (9) has a cross section (15) whose width (16) is substantially smaller than the diameter (13) of the measuring tube inlet (7) and / or the diameter (14) the measuring tube outlet (8) and its height (17) is substantially larger than the diameter (13) of the measuring tube inlet (7) and / or the measuring tube outlet (8), wherein the measuring tube (3) has a first functional surface (10) and at least one second Functional surface (11), to which functional surfaces (10, 11) each at least one ultrasonic transducer (2) is acoustically coupled and which functional surfaces (10, 11) each have an approximately equal angle α to the measuring tube axis (12) a ufweisen.

Description

The The present invention relates to a measuring tube of an ultrasonic flow measuring system, which measuring tube has a different cross section in the measuring range as the measuring tube inlet and / or measuring tube outlet.

Ultrasonic flowmeters are widely used in process and automation technology. They allow in a simple way, the volume flow and / or Determine mass flow in a pipeline.

The known ultrasonic flowmeters often work after the Doppler or after the transit time difference principle.

At the Runtime difference principle, the different maturities of ultrasonic pulses relative to the flow direction of Liquid evaluated.

For this Ultrasonic pulses are at a certain angle to the tube axis sent both with and against the flow. Out the transit time difference can be the flow rate and so that with known diameter of the pipe section of the volume flow determine.

At the Doppler principle will be ultrasonic waves with a specific frequency coupled into the liquid and that of the liquid Evaluated reflected ultrasonic waves. From the frequency shift between the coupled and reflected waves also the flow rate of the liquid determine.

reflections in the liquid, however, occur only when air bubbles or impurities are present in this, so this principle mainly with contaminated liquids Use finds.

The ultrasonic waves are generated or received with the help of so-called ultrasonic transducers. For this purpose, ultrasonic transducers are firmly attached to the pipe wall of the relevant pipe section. More recently, clamp-on ultrasonic flow measurement systems have become available. In these systems, the ultrasonic transducers are pressed against the pipe wall only with a tension lock. Such systems are for. B. from the EP 686 255 B1 . US-A 44 84 478 or US-A 45 98 593 known.

Another ultrasonic flowmeter, which operates on the transit time difference principle, is from the US-A 50 52 230 known. The transit time is determined here by means of short ultrasound pulses.

One big advantage of clamp-on ultrasonic flow measuring systems is that they do not touch the measuring medium and on one already existing pipeline are attached.

The Ultrasonic transducers usually consist of a piezoelectric Element, also called piezo for short, and a coupling layer, also coupling wedge or less commonly called Vorlaufkörper. The coupling layer is usually made of plastic, the piezoelectric element exists in industrial process measuring technology usually from a piezoceramic. In the piezoelectric element, the Ultrasonic waves generated and the coupling layer to Passed pipe wall and from there into the liquid directed. Because the speed of sound in liquids and plastics are different, the ultrasonic waves broken in the transition from one medium to another. The angle of refraction is determined in the first approximation according to Snell's law. The angle of refraction is thus dependent on the ratio the propagation speeds in the media.

Between the piezoelectric element and the coupling layer can be another Coupling layer may be arranged, a so-called adaptation layer. The adaptation layer assumes the function of Transmission of the ultrasonic signal and at the same time the reduction a reflection caused by different acoustic impedances at boundary layers between two materials.

Now Various types of measuring tubes for ultrasonic flow measuring systems are also known become.

The EP 1 826 537 A2 shows a measuring tube with rectangular tube cross-section. Two ultrasonic transducers are mounted on two opposite, parallel surfaces of the measuring tube or they are spaced from each other on one of the two parallel surfaces, wherein the ultrasonic transducers approximately through the entire pipe cross section through.

In the DE 10 2006 030 942 A1 Also shown is a measuring tube with a rectangular cross-section. In this case, the measuring tube has a measuring tube inlet and a measuring tube outlet, which each allow a cross-sectional change of round cross section of the pipe system surrounding the measuring tube to a rectangular cross-section of the measuring tube. In the measuring tube inlet an additional component is provided, which swirls the flow.

The DE 102 49 542 A1 discloses a measuring tube for an ultrasonic flow measuring system with two functional surfaces, on each of which an ultrasonic transducer is mounted. The functional surfaces are an integral part of the measuring tube. In one embodiment, the functional surfaces are mounted parallel to each other on opposite sides of the measuring tube. In another embodiment, both functional surfaces had the approximately same angle to an imaginary solder on the opposite surface of the measuring tube, which opposite surface reflects the ultrasonic signal between the ultrasonic transducers.

Another measuring tube with rectangular cross section is in EP 1 130 366 A2 shown. The ultrasonic transducer is equal to the inner width of the measuring tube, whereby the entire Meßrohrquerschnitt can be durchschallt. The cross section of the measuring tube changes from a square to a rectangular cross section, wherein the height of the rectangle may be higher than the height of the square and the width of the rectangle is substantially narrower than the width of the square.

Rectangular Measuring tubes have a generally strongly slowed flow in the corners and corners of the measuring tubes. Collect deposits Get there often.

The The object of the invention is a measuring tube for a Ultrasonic flow measuring system to provide which one High-precision measurement of the flow possible and simultaneously is very inexpensive to produce.

The The object is achieved by a measuring tube of an ultrasonic flow measuring system, which measuring tube has an approximately circular measuring tube inlet and has an approximately circular measuring tube outlet, wherein the measuring tube a Meßrohrmittelteil between the measuring tube inlet and the measuring tube outlet, which Meßrohrmittelteil has a cross section has, whose width is substantially smaller than the diameter of the measuring tube inlet and / or the diameter of the measuring tube outlet and whose height is much larger as the diameter of the measuring tube inlet and / or the measuring tube outlet, wherein the measuring tube has a first functional surface and at least has a second functional surface to which functional surfaces in each case at least one ultrasonic transducer is acoustically coupled and which functional surfaces each approximate have the same angle α to the measuring tube axis.

to Determination of both the diameter and the width and the Height is in each case the area enclosed by the measuring tube used. The dimensions are thus between the inner surfaces of the measuring tube determined. The width of the measuring tube refers to it on the width at the narrowest point of the measuring tube. The height however, it refers to the height at the highest Position of the measuring tube. Has the measuring tube in the middle part of the measuring tube an axis, height and width are perpendicular to the axis Axle of the measuring tube middle part, as with the diameter of the measuring tube inlet and measuring tube outflow. The measuring axis itself is without an existing one Axle in the middle part of the measuring tube as a connecting line between the center point the measuring tube inlet and the center of the measuring tube outlet consider. Preferably, the measuring tube central part has an axis, which in the said connecting line between the center of Measuring tube inlet and center of the measuring tube outlet is located.

The Functional surfaces are preferably on the outside the measuring tube wall. They are for receiving ultrasonic transducers suitably designed. If an ultrasonic signal over the functional surface coupled into the measuring tube wall, passes the Measuring tube wall the ultrasonic signal down to its inside. There it is then coupled into the measuring medium.

In A first development of the invention are the first functional surface and the second functional surface plane parallel to each other.

In a second embodiment of the invention Solution is the first and / or second functional area at least as wide as the measuring tube at its narrowest point. The measuring tube is preferred in its middle part of the measuring tube with ultrasound signals by echoes. In this case, the entire width is particularly advantageous of the middle part of the measuring tube, ie. H. the wavefront width the radiated or the propagating in the measuring medium ultrasonic signal at least equal to the width of the measuring tube at the narrowest Job.

In a further embodiment of the invention Solution, the measuring tube has no corners and / or edges. In particular, the radii of the measuring tube are in various configurations, depending on the size of the measuring tube, larger than 0.2 mm, in particular greater than 0.5 mm, in particular larger than 1 mm, in particular greater than 2 mm. Prefers the radii of an embodiment of the measuring tube are smaller than 5 mm. A variant of the measuring tube has accordingly no Corners on. In a further developed measuring tube is in addition waived edges. A constant change of the cross section of the measuring tube from the measuring tube inlet to the middle part of the measuring tube the episode.

In a further embodiment of the invention, the measuring tube is made of a metallic and substantially straight tube with an approximately circular cross-section by forming bar. Metallic measuring tubes of this Gesatlt are of course also on Urformverfahren such. B. casting produced. However, forming methods that plastically deform the previously substantially straight measuring tube, such. As hydroforming or thermoforming, preferably.

According to one advantageous development of the invention Measuring tube, the measuring tube is made of a polymer by prototyping. However, not only polymers, but above all fiber reinforced Plastics or composites preferred.

A very advantageous development of the invention Measuring tube can be seen in that the measuring tube in one piece is trained. The measuring tube does not necessarily have to be produced by prototyping be, so be monolithic. Also a measuring tube, which first by bending a flat sheet with subsequent longitudinal seam welding is produced and then undergoes a forming process, is to be considered as one piece. On the other hand, one out of two Half shells, which z. B. by deep drawing their final Form received, welded measuring tube as not to be considered in one piece.

A advantageous development of the invention Measuring tube suggests that the measuring tube inlet and the Measuring tube outlet the substantially same cross-sectional area exhibit. Another embodiment provides for the Meßrohrmittelteil and the measuring tube inlet and / or the measuring tube outlet the approximate same cross-sectional area before.

A further advantageous embodiment of the invention Measuring tube provides that the circumference of the Meßrohrmittelteils approximately the same the circumference of the measuring tube inlet and / or the measuring tube.

at A very advantageous development of the invention is the measuring tube from the measuring tube inlet to the measuring tube outlet designed substantially symmetrical.

Of the Structure of the measuring tube has correspondingly at least one plane of symmetry, an axis of symmetry and / or a point of symmetry.

A further embodiment of the invention, however, has asymmetric Entry and / or exit regions. Entry and exit regions are the regions of the measuring tube between the measuring tube inlet and the middle part of the measuring tube respectively middle tube part and measuring tube outlet.

According to one advantageous development of the invention Solution is suggested that the measuring tube in the measuring tube middle part has two substantially plane-parallel side surfaces, which in turn determine the width of the measuring tube. The side surfaces the measuring tube are preferably at the narrowest point of the measuring tube, So at the point of the measuring tube with the smallest width, plane-parallel.

A advantageous development of the invention Measuring tube is that the cross section of the measuring tube center part has substantially the shape of a double lobe. A double club has the shape of two, with their thin ends on each other standing clubs. It takes the form of an hourglass. double Keulen are also known from quantum mechanics. For example, forms the p orbital model is a double lobe.

According to one further developed embodiment of the invention Measuring tube has the inside of the measuring tube at least partially essentially flow-parallel grooves in the measuring tube wall on. The grooves on the one hand offer the positive effect of flow guidance in the measuring tube, on the other hand they serve for the stability of the Measuring tube to reduce deformation. Is a measuring tube z. B. produced by a forming process, the grooves can not only on the inside, but also on the outside of the measuring tube. The measuring tube wall is thus laid. A another variant make one-sided and / or double-sided ribs in the measuring tube wall. Ridges earth rather than recesses, Ribs understood as protuberances. For a described measuring tube with corrugated tube wall grooves are synonymous equivalent with ribs.

According to one very advantageous embodiment of the invention, the measuring tube at least one cup-shaped indentation, wherein the Bottom surface of the cup-shaped indentation of the first Function surface and / or the second functional surface corresponds. The cup-shaped indentations are for recording at least an interpretable ultrasound transducer. The sensor housing is thus already integrated into the measuring tube, whereby it must be distinguished between one-piece measuring tube with cup-shaped indentation and glued or z. B. welded by laser Potty for receiving the ultrasonic transducer. Exist two cup-shaped recesses, so is the bottom surface the first indentation formed by the first functional surface and the bottom surface of the second indentation of the second Functional surface.

In a development of the previous embodiment of the measuring tube, the cup-shaped indentation of a sound-absorbing sealing compound is closed and / or the cup-shaped indentation is connected to the measuring tube via sound-absorbing baffles. In this case, the measuring tube is preferably integrally formed with the cup-shaped indentation. The measuring tube wall thus has sound-damping baffles even in the area of the cup-shaped indentation. The sound-absorbing sealing compound, however, is advantageously introduced after insertion of the ultrasonic transducer in the cup-shaped recess and preferably with the measuring tube form-fitting, which is not integral part of the measuring tube, or materially connected, z. B. by gluing. The sound-absorbing sealing compound advantageously has means for cable feedthrough.

Farther the problem underlying the invention is solved by a measuring system for determination and / or monitoring the flow of a measuring medium through a measuring tube which ultrasonic flow measuring system at least one ultrasonic transducer and at least one control / evaluation unit which control / evaluation unit based on the measurement signals or based on measurement data derived from the measurement signals, the volume and / or the mass flow of the flowing in the measuring tube Determined measuring medium, the ultrasonic transducer at least one electromechanical Transducer element which transmits ultrasonic signals and / or receives, with the measuring tube an approximately circular measuring tube inlet and an approximately circular Measuring tube outlet, wherein the measuring tube a Meßrohrmittelteil between the measuring tube inlet and the measuring tube outlet, which Measuring tube middle part has a cross section whose width is essential smaller than the diameter of the measuring tube inlet and / or the measuring tube outlet and whose height is much larger as the diameter of the measuring tube inlet and / or the measuring tube outlet, wherein the measuring tube has a first functional surface and at least has a second functional surface to which functional surfaces in each case at least one ultrasonic transducer is acoustically coupled and which functional surfaces each approximate have the same angle α to the measuring tube axis.

Further Embodiments of the measuring system according to the invention arise from the developments of the invention of the measuring tube.

The The invention will be explained in more detail with reference to the following figures.

1 shows an inventive measuring tube with two cup-shaped indentations in longitudinal section,

2 shows a measuring tube according to the invention with a double-lobe-shaped cross-section of the measuring tube center part in a perspective view,

3 shows a measuring tube according to the invention with wavy measuring tube side surfaces and four ultrasonic transducers in a perspective view.

In 1 is a measuring tube according to the invention 3 with two cup-shaped indentations 23 shown in longitudinal section. The measuring tube 3 has a measuring tube inlet 7 and a measuring tube outlet 8th with approximately the same cross sections and a Meßrohrmittelteil 9 between measuring tube inlet 7 and measuring tube outlet 8th , The connecting line between the center of the approximately circular measuring tube inlet 7 and the approximately circular Meßrohrauslaufs 8th is at the same time the measuring axis 12 , The measuring tube 3 is not symmetrical to its measuring tube axis 12 , but point symmetrical to the center of gravity of the cross section 15 of Meßrohrmittelteils 9 , which is on the measuring tube axis 12 lies. The height 17 of Meßrohrmittelteils 9 is much larger than the diameter 13 . 14 of the measuring tube inlet 7 and the measuring tube outlet 8th , Also the width of the measuring tube central part 9 is much smaller than the diameter 13 of the measuring tube inlet 7 and the diameter 14 of measuring tube outlet 8th , which is naturally not shown in this longitudinal section. In this form is the measuring tube 3 with the cup-shaped indentations 23 and the sound-absorbing baffles 26 in one piece by forming a previously straight pipe, z. Example by means of hydroforming, can be produced. The measuring tube 3 has no sharp corners and edges. All corner-like and edge-like areas are rounded or have radii. By this technique, it is possible to achieve a continuous and simultaneous cross-sectional change both in width and in the height of the Meßrohrquerschnitts.

In each case an electromechanical transducer element 2 is in each case a cup-shaped indentation 23 placed. It lies on the respective floor area 24 the cup-shaped indentation 23 up and connected with this. The floor surfaces 24 the cup-shaped indentations 23 serve as functional surfaces 10 . 11 with which the electromechanical transducer elements 5 are acoustically coupled. The floor surfaces 24 the cup-shaped indentations 23 respectively the functional surfaces 10 and 11 stand at an angle α on the measuring tube axis 12 , In this embodiment of the invention, the functional surfaces 10 and 11 plane parallel to each other.

The floor surfaces 24 the cup-shaped indentations 23 have an approximately circular cross-section. The circular walls of the cup-shaped indentations are essentially perpendicular to it 23 , About the sound-absorbing Schika nen 26 are the pot-shaped indentations 23 of the measuring tube 3 with the measuring tube wall 21 integrally connected, ie the sound-absorbing baffles 26 and the cup-shaped indentations 23 are part of the measuring tube wall 21 , The sound-absorbing baffles 26 can z. B. take the form of a bellows or diaphragm or bellows or, as shown here, with circular, concentrically arranged beads or waves. In addition to the sound-absorbing baffles 26 has an ultrasonic transducer 2 a sound-absorbing sealing compound 25 in the cup-shaped indentation 23 on which the pot-shaped indentation 23 closes to the outside. A cable bushing for contacting the ultrasonic transducer and its connection to a control / evaluation unit, not shown, has not been shown for the sake of clarity.

Together with the illustrated ultrasonic transducers 2 could be the measuring tube 3 as an inline ultrasonic flow measuring system 1 be understood, but without the control / evaluation unit, not shown for reasons of clarity.

2 discloses a measuring tube according to the invention 3 with an approximately circular measuring tube inlet 7 and an approximately circular measuring tube outlet 8th and a measuring tube center part 9 between the measuring tube inlet 7 and the measuring tube outlet 8th , The measuring tube middle part 9 has a cross section 15 in the form of a double lobe, whose width is substantially smaller than the diameter 13 of the measuring tube inlet 7 and the diameter of the measuring tube outlet 8th and whose height is much larger than the diameter 13 of the measuring tube inlet 7 and the measuring tube outlet 8th , The measuring tube shown has a total of four functional surfaces 10 . 11 . 27 . 28 to which in each case at least one ultrasonic transducer is acoustically coupled and which functional surfaces 10 . 11 . 27 . 28 each having an approximately equal angle to the measuring tube axis, not shown, wherein the functional surfaces 10 and 11 and the functional surfaces 27 and 28 in pairs are plane-parallel to each other.

The measuring tube 3 also has two substantially plane-parallel side surfaces 18 which, in turn, the width of the measuring tube 3 establish. Through the selected representation of the measuring tube 3 is unfortunately only one of the two side surfaces 18 to see. Furthermore, neither the width nor the height of the measuring tube 3 to see, because these within the measuring tube 3 exist between the inner sides and here the measuring tube is shown in perspective from the outside. Also only to be guessed is that the measuring tube inlet 7 and the measuring tube outlet 8th have substantially the same cross-sectional area. The symmetrical construction of the measuring tube 3 but it is very clear.

The middle part of the measuring tube 9 of the measuring tube 3 in the embodiment is approximately equal to the circumference of the measuring tube inlet 7 and the circumference of the measuring tube outlet 8th , The inner cross sections are also used. So the cross section 15 of Meßrohrmittelteils 9 has approximately the same circumference as the diameter 13 of the measuring tube inlet 7 clamped cross section of the measuring tube inlet. The same applies according to the invention for the measuring tube outlet. The measuring tube 3 is preferably made of a fiber-reinforced plastic, that is produced in a prototype process.

3 shows an ultrasonic flow measuring system 1 with a measuring tube 3 with wavy measuring tube side surfaces 18 and four ultrasonic transducers 2 , The lateral measuring tube walls 21 which the side surfaces 18 of the measuring tube 3 form, have grooves 22 both on the inside 19 as well as on the outside 20 of the measuring tube 3 on. The scores 22 on the inside 19 , that is on the measuring medium 4 facing side surface 18 of the measuring tube 3 Run substantially in the flow direction of the medium 4 in the measuring tube 3 , The wavy side surfaces 18 or measuring tube walls 21 lend to the measuring tube 3 a higher mechanical stability. The four opposing ultrasonic transducers 2 are on the measuring tube 3 from the outside, so on the outside 20 of the measuring tube 3 , put on. However, it is not a clamp-on measuring system, as the ultrasonic transducers 2 not on an existing pipeline, but on a specially designed measuring tube 3 are attached.

The ultrasonic transducers 2 stand with a total of four functional surfaces 10 . 11 . 27 . 28 of the measuring tube 3 in connection. All four functional surfaces close 10 . 11 . 27 . 28 approximately the same angle α to the measuring tube axis. The functional surfaces 10 and 11 and the functional surfaces 27 and 28 are in pairs plane-parallel.

The diameters 13 . 14 and thus the cross-sectional areas of the approximately circular measuring tube inlet 7 and the approximately circular Meßrohrauslaufs 8th are essentially the same size. The width 16 of Meßrohrmittelteils 9 at the narrowest point of the Meßrohrmittelteils 9 is relative to the diameters 13 . 14 of the measuring tube inlet 7 and the measuring tube outlet 8th smaller. Equally the height 17 of the measuring tube 3 at the highest part of the measuring tube central part 9 larger than the mentioned diameter 13 . 14 ,

Also this measuring tube 3 with the grooves 22 in the measuring tube wall 21 has no corners and no edges on the inside of the measuring tube 3 , so that Measuring medium touching part of the measuring tube 3 , on. It is integrally manufactured by forming and symmetrical.

1

Ultrasonic flow measuring system

2

ultrasound transducer

3

measuring tube

4

measuring medium

5

electromechanical transducer element

6

Control / evaluation unit

7

Measuring tube inlet

8th

Measuring tube outlet

9

Measuring tube midsection

10

First functional surface

11

Second functional surface

12

Measuring tube axis

13

diameter of the measuring tube inlet

14

diameter of measuring tube outlet

15

cross-section of Meßrohrmittelteils

16

width of Meßrohrmittelteils

17

height of Meßrohrmittelteils

18

faces of the measuring tube

19

inside of the measuring tube

20

outside of the measuring tube

21

Measuring tube wall

22

cried in the measuring tube wall

23

pot-shaped indentation

24

floor area the cup-shaped indentation

25

sealing compound

26

sound-absorbing harassment

27

third functional surface

28

Fourth functional surface

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - EP 686255 B1 [0008]
• - US 4484478 A [0008]
• - US 4598593 A [0008]
• - US 5052230 A [0009]
• - EP 1826537 A2 [0014]
• DE 102006030942 A1 [0015]
• - DE 10249542 A1 [0016]
• - EP 1130366 A2 [0017]

Claims (15)

Measuring tube ( 3 ) of an ultrasonic flow measuring system ( 1 ), which measuring tube ( 3 ) an approximately circular measuring tube inlet ( 7 ) and an approximately circular measuring tube outlet ( 8th ), wherein the measuring tube ( 3 ) a measuring tube central part ( 9 ) between the measuring tube inlet ( 7 ) and the measuring tube outlet ( 8th ), which measuring tube middle part ( 9 ) a cross section ( 15 ) whose width ( 16 ) is much smaller than the diameter ( 13 ) of the measuring tube inlet ( 7 ) and / or the diameter ( 14 ) of the measuring tube outlet ( 8th ) and its height ( 17 ) is much larger than the diameter ( 13 ) of the measuring tube inlet ( 7 ) and / or the measuring tube outlet ( 8th ), whereby the measuring tube ( 3 ) a first functional area ( 10 ) and at least one second functional area ( 11 ) to which functional surfaces ( 10 . 11 ) at least one ultrasonic transducer ( 2 ) is acoustically coupled and which functional surfaces ( 10 . 11 ) each have an approximately equal angle α to the measuring tube axis ( 12 ) exhibit. Measuring tube ( 3 ) according to claim 1, characterized in that the first functional surface ( 10 ) and the second functional area ( 11 ) are plane-parallel to each other. Measuring tube ( 3 ) according to claim 1 or 2, characterized in that the measuring tube ( 3 ) has no corners and / or edges. Measuring tube ( 3 ) according to one of claims 1 to 3, characterized in that the measuring tube ( 3 ) is produced from a metallic and substantially straight pipe with an approximately circular cross-section by forming. Measuring tube ( 3 ) according to one of claims 1 to 3, characterized in that the measuring tube ( 3 ) can be produced from a polymer by prototyping. Measuring tube ( 3 ) according to one of claims 1 to 5, characterized in that the measuring tube ( 3 ) is integrally formed. Measuring tube ( 3 ) according to one of claims 1 to 6, characterized in that the measuring tube inlet ( 7 ) and the measuring tube outlet ( 8th ) having substantially the same cross-sectional area. Measuring tube ( 3 ) according to one of claims 1 to 7, characterized in that the circumference of the Meßrohrmittelteils ( 9 ) approximately equal to the circumference of the measuring tube inlet ( 7 ) and / or the measuring tube outlet ( 8th ). Measuring tube ( 3 ) according to one of claims 1 to 8, characterized in that the measuring tube ( 3 ) from the measuring tube inlet ( 7 ) to the measuring tube outlet ( 8th ) is designed substantially symmetrical. Measuring tube ( 3 ) according to one of claims 1 to 9, characterized in that the measuring tube ( 3 ) in the middle of the measuring tube ( 9 ) two substantially plane-parallel side surfaces ( 18 ), which in turn has the width ( 16 ) of the measuring tube ( 3 ) establish. Measuring tube ( 3 ) according to one of claims 1 to 10, characterized in that the cross-section ( 15 ) of the measuring tube central part ( 9 ) has substantially the shape of a double lobe. Measuring tube ( 3 ) according to one of claims 1 to 11, characterized in that the inside ( 19 ) of the measuring tube ( 3 ) at least in some areas substantially parallel grooves ( 22 ) in the measuring tube wall ( 21 ) having. Measuring tube ( 3 ) according to one of claims 1 to 12, characterized in that the measuring tube ( 3 ) at least one cup-shaped indentation ( 23 ), wherein the bottom surface ( 24 ) of the cup-shaped indentation ( 23 ) of the first functional area ( 10 ) and / or the second functional area ( 11 ) corresponds. Measuring tube ( 3 ) according to claim 13, characterized in that the cup-shaped indentation ( 23 ) of a sound-absorbing sealing compound ( 25 ) is closable and / or that the cup-shaped indentation ( 23 ) via sound-absorbing baffles ( 26 ) with the measuring tube ( 3 ). Measuring system ( 1 ) for determining and / or monitoring the flow of a measuring medium ( 4 ) through a measuring tube ( 3 ), which ultrasonic flow measuring system has at least one ultrasonic transducer ( 2 ) and at least one control / evaluation unit ( 6 ), which control / evaluation unit ( 6 ) based on the measurement signals or on the basis of measurement data, which are derived from the measurement signals, the volume and / or the mass flow of the in the measuring tube ( 3 ) flowing measuring medium ( 4 ), wherein the ultrasonic transducer ( 2 ) at least one electromechanical transducer element ( 5 ), which transmits and / or receives ultrasonic signals, with a measuring tube ( 3 ) according to one of claims 1 to 14.