DE1228835B - Device for measuring the flow velocity of gases or liquids by means of sound waves - Google Patents

Description

Device for measuring the flow rate of gases or Liquids by sound waves The invention relates to a device for Measuring the flow velocity of gases or liquids by means of sound waves, emanating from a sound transmitter located outside the measuring section through which the flow is flowing, enforce the measuring section perpendicular to the direction of flow and become part of a measured value generating device forming electroacoustic transducers are supplied.

In known devices of this type are one outside of the flow through Two sound transmitters located outside of the measuring section through which the air flows Sound receiver arranged opposite one another, d. i.e., the sound transmitter is on one side of the measuring tube and the two one behind the other in the direction of flow Sound receivers are arranged on the opposite side of the measuring tube. The flowing medium influences the propagation of sound in such a way that that according to the flow rate of one receiver less and the one other recipients are more influenced, so that the difference is a measure of the flow velocity can be determined.

With this arrangement, however, such a high frequency is required that that a sharp focus of the sound beam is possible. It is also an accurate one Arrangement of the sound transmitter opposite the middle between the two sound receivers Prerequisite for a perfect measurement, especially what is because of the close Side-by-side arrangement of both sound receivers is not always sufficient in practice can be achieved exactly.

The object of the invention is to meet these aggravating requirements to eliminate. According to the invention, an exact measurement succeeds with a device in which the assignment of the sound wave receiver to the sound transmitter can be arbitrary, in a simple manner in that, outside the measuring section, one opposite the sound transmitter Reflection point is arranged, which reflects the sound waves on the sound transmitter in the sense of a transducer-influencing energy propagation in the direction of the measuring section axis. The distance between the reflection point and the sound wave transmitter is advantageous easily adjustable so that they are at such a distance from the sound transmitter can be brought that within the measuring section in the direction of its axis a greatest possible sound radiation takes place, or that in another case at rest Medium in the measuring section creates a vibration node. The reflection point can be designed as a simple reflection wall.

The invention is described below using a few exemplary embodiments explained in more detail.

1 and 2 are particularly useful embodiments of sound transmitters and sound receivers according to the invention in a simplified representation shown. The arrangement according to FIG. 1 is particularly suitable for connecting the Test section to a branch circuit, while the arrangement according to F i g. 2 for the Measurement of the flow velocity in main circuits is suitable. In both Cases, the sound wave transmitter 15 is perpendicular to the direction of flow outside the arranged by the medium flowing through the measuring section 16 and emits its sound energy vertically to the direction of flow to a reflection point also outside the measuring section 17, from which the sound energy reflects against the incident energy radiation will. The distance between the sound transmitter and the reflection point can be chosen so that within the measuring section in the direction of the flow axis on both sound wave receivers 18 and 19 reaches the greatest possible sound energy.

To adapt the measuring arrangement to the flow rate and the medium can have the reflection point 17 perpendicular to the incident energy radiation be arranged displaceably.

According to FIG. 1, the measuring section 16 is tubular with a cylindrical cross section and carries the sound wave receiver at both ends, in front of which inclined pipe sockets 20 and 21 open into the pipe, which are the inlet and outlet lines for the flowing medium form. According to FIG. 2, on the other hand, the tubular section lies directly in the flow path. The sound wave receivers 18 and 19 are equidistant on either side of the sound waves transmitter 15 in an axis inclined to the direction of flow on arranged on different sides of the measuring section 16. They are useful in nozzles 22 and 23 housed, which open into the measuring tube.

It can be the distance between the sound wave transmitter and the reflection point but also be dimensioned so that when the medium is at rest in the middle of the measuring tube so-called oscillation node lies, so that a minimum of the energy propagation in Direction towards the sound wave receiver is present.

When a gas flow occurs, the oscillation state becomes in the Center of the pipe then changed so that according to the flow rate a more or less great spread of energy takes place, so that by a simple one Voltage measurement the flow velocity can be detected.

The tubular measuring section 16 according to FIG. 3 can also be U-shaped be bent and have inlet and outlet lines 24 and 25 for the medium at their ends. The sound wave receivers 18 and 19 are again at the ends of the sound wave transmitters 15 and the reflection point 17 arranged in the bend of the measuring section. This is possible, since the sound can also be guided very well along curved measuring sections leaves. In this way, a spatially very tightly packed design is possible.

Claims (7)

Claims: 1. Device for measuring the flow velocity of gases or liquids by sound waves flowing through from outside the Transmitter lying in the measuring section go out, the measuring section perpendicular to the direction of flow enforce and form part of a measured value generating device forming electroacoustic Converters are supplied, d a -characterized in that outside of the measuring section a reflection point opposite the sound transmitter is arranged, which the Sound waves are reflected on the sound transmitter in the sense of a transducer-influencing Energy propagation in the direction of the measuring section axis. 2. Device according to claim 1, characterized in that the reflection point is arranged at such a distance from the sound transmitter that within the measuring section the greatest possible sound radiation takes place in the direction of its axis. 3. Device according to claim 1, characterized in that the reflection point is arranged at such a distance from the sound transmitter that when the medium is at rest in the Measurement section creates a vibration node. 4. Device according to one of the preceding claims, characterized in that that the reflection point is designed as a reflection wall and perpendicular to the measuring path axis arranged displaceably in the direction of the sound waves coming from the sound transmitter is 5. Device according to one of the preceding claims, characterized in that that the tubular measuring section has transducers at its closed ends, in front of those in the outer surface of the measuring section, the supply and discharge lines for the flowing Open to the medium. 6. Device according to one of claims 1 to 4, characterized in that that with a tubular measuring section arranged directly in the flow path the transducers on both sides of the sound transmitter in a manner known per se in one axis inclined to the direction of flow on different sides of the measuring section are arranged in separate closed nozzles. 7. Device according to claim 5, characterized in that the closed tubular measuring section U-shaped with legs of equal length and the Sound transmitter as well as the reflection point between the legs on both sides the measuring section are arranged. Documents considered: French patent specification No. 1,214,236; British Patent Nos. 824 537, 855 650; U.S. Patents No. 2,844,961, 2,894,595, 2991650; Magazine "The Review of Scientific Instruments", Vol. 25, No. 3, March 1954, pp. 201-206; Journal »Voith Research and Construction«, Issue 3 from August 1958, pp. 1.1 to 1.40.