DE20107894U1 - Ultrasonic flow meter - Google Patents

Description

ULTRASONIC FLOW METER

This invention relates to an ultrasonic flow meter for measuring fluid flow, such as water flow, for later use in calculating, for example, water consumption or heat consumption in the household.

Typically, household flow meters are mechanically constructed in such a way that a small rotor is arranged in the flow tube itself and flows are calculated from the rotation speed of the rotor, which can then be used to determine heat consumption. These flow meters are arranged in special flow meter housings, which can be built into a wall, for example.

Ultrasonic flow meters are ultrasound-based and work by emitting ultrasound from transducers with or against the flow of the fluid. The emitted ultrasound is then picked up by transducers and the difference in transmission time can be used to calculate flow and water consumption.

In order to be able to obtain the advantages of using ultrasound for flow measurement, it is of interest to be able to arrange ultrasonic flow meters in the already existing flow meter housings so that the mechanical flow meters can be replaced without having to remove the often bricked-in flow meter housings. However, this causes problems because there is very little space in the flow meter housings and therefore a sufficiently accurate flow measurement cannot be obtained due to a very short measuring tube.

It is an object of the invention to provide an ultrasonic flow meter for placement in existing flow meter housings so that accurate flow measurement is achieved.

This object is achieved according to the invention by an ultrasonic flow meter comprising a measuring tube, reflectors and ultrasonic transducers. The reflectors are arranged at the ends of the measuring tube so that a reflector surface of a first

reflector against a reflector surface of a second reflector and wherein the reflector surfaces have a first angle to a plane parallel to the direction of flow through the measuring tube. Furthermore, a first and a second ultrasonic transducer are arranged above the first and second reflectors, respectively, wherein the propagation directions of the transducers form a second angle to a plane parallel to the direction of flow and wherein the ultrasonic transducers point towards the reflector surfaces. The ultrasonic transducers are arranged such that the ultrasonic transducer at one end of the measuring tube points away from the ultrasonic transducer at the other end of the measuring tube.
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This allows maximum utilization of the space in the flowmeter housing so that a long measuring tube can be used and an accurate flow measurement can be achieved by increasing the shot length in the direction of flow.

In one embodiment, the second angle between the ultrasonic transducers and the plane parallel to the flow direction is between 15° and 35°. This has been found to be useful in a particular type of ultrasonic flow meter, and 25° has given very good results in the specific embodiment described below.

In a particular embodiment, the measuring tube is rotated in relation to the inlet and outlet of the flow meter housing so that the central axis of the measuring tube forms an angle of between 30° and 60° with a central axis through the inlet and outlet and that the tube is connected to means for dividing the flow meter housing into an inlet distribution chamber and an outlet distribution chamber.

This creates an inlet distribution chamber and an outlet distribution chamber, eliminating any differences in velocity profiles in the inlet and thus any measurement inaccuracies associated with varying inlet profiles. 30

In a particularly advantageous embodiment, the measuring tube is rotated in relation to the inlet and outlet of the flow meter housing so that the central axis of the measuring tube forms an angle of 45°.

In one embodiment according to the invention, the means for dividing the flow meter housing are provided by barrier walls arranged perpendicular to the measuring tube and on each side of the measuring tube, so that the ends of the barrier walls adjoin tightly to the side wall of the flow meter housing and divide the flow meter housing into an inlet distribution chamber and an outlet distribution chamber. This has proven to be a convenient construction.

The invention is described in more detail below with reference to the drawing, in which

Fig. 1a shows a cross-section of an ultrasonic flow meter according to the invention in a side view,

Fig. 1b shows a cross-section of an ultrasonic flow meter according to the invention in a side view, the ultrasonic flow meter having a conical cylindrical shape,

Fig. 2 shows a cross-section of an ultrasonic flow meter according to the invention in a plan view,

Fig. 3 shows a cross-section of an ultrasonic flow meter according to the invention in a plan view, wherein the measuring tube is rotated at an angle in relation to the inlet and outlet.

Fig. 1a shows a cross-section of an ultrasonic flow meter 1 according to the invention in a side view. The ultrasonic flow meter 1 is arranged in a flow meter housing 3. The flow meter housing 3 comprises an inlet 5 and an outlet 7. The inlet 5 and the outlet 7 have an inner diameter corresponding to, for example, a water pipe, whereby the flow meter housing 3 can be arranged in a tight connection between two water pipes.

The ultrasonic flow meter 1 comprises a measuring tube 9, and at each end of the measuring tube 9 reflectors with reflector surfaces 11, 13 are arranged at a first angle α to a flow plane parallel to the flow direction. The reflector surfaces 11, 13 are arranged such that the reflector surface 11 at one end of the measuring tube 9 is directed against the reflector surface 13 at the other end of the measuring tube 9. Ultrasonic transducers 15 and 17 are arranged above the reflector surfaces 11, 13. These ultrasonic transducers are arranged at an angle β to the flow plane such that the ultrasonic transducer 15 at one end of the measuring tube 9 points away from the ultrasonic transducer 17 at the other end of the measuring tube 9.

When water is passed through the measuring tube 9, the ultrasonic flow meter 1 can use ultrasound to measure the flow velocity. The ultrasonic flow meter 1 is designed in such a way that ultrasound emitted in one direction of propagation by one transducer 15, 17 is reflected by the two reflector surfaces 11, 13 on the other transducer 15, 17 against its direction of propagation, the other transducer 15, 17 acting as a receiver. Accordingly, the second transducer 15, 17 can act as a transmitter and the first transducer 15, 17 as a receiver, so that measurements are taken both with and against the flow in the measuring tube 9. The two ultrasound signals can be emitted simultaneously or shifted. Since the sound takes more time to travel against the flow direction than along the flow direction, a difference in the two transmission times can be used to determine the flow direction.

The shot length is the center distance in the flow direction between the reflector surfaces 11, 13. In the present invention, the shot length is maximized without changing the external dimensions of the ultrasonic flow meter by arranging the ultrasonic transducers 15, 17 at an angle β to the flow plane such that an ultrasonic transducer 15, 17 at one end of the measuring tube 9 points away from another ultrasonic transducer 15, 17 at the other end of the measuring tube 9.

The angle β is selected depending on the distance between the reflectors and the angle α of the reflector surfaces to the flow plane. In addition, β also depends on the distance between the ultrasonic transducers 15,17.

Fig. 1b shows a cross-section of an ultrasonic flow meter 1 according to the invention in a side view, the ultrasonic flow meter 1 having a conical cylindrical shape. This makes it possible for the ultrasonic flow meter 1 to also fit into known flow meter housings 3 designed for flow meters 1 with a flat, conical shape. The flow meter housing is not shown.

Fig. 2 shows a cross-section of an ultrasonic flow meter 1 arranged in a flow meter housing 3 in a plan view. The measuring tube 9 is located in direct extension of the inlet and outlet 5, 7 in the flow meter housing. Reflector surfaces 11, 13 can be seen at each end of the measuring tube 9.

Fig. 3 shows a cross-section of an alternative ultrasonic flow meter 1 according to the invention in a plan view, wherein the measuring tube 9 is rotated at an angle ν in relation to a central axis through the inlet and outlet 5, 7. Two barrier walls 23, 25 are arranged perpendicular to the measuring tube, the ends of the barrier walls 23, 25 closely adjoining the side wall of the flow meter housing 1. This forms an inlet distribution chamber 27 and an outlet distribution chamber 29, whereby differences in velocity profiles in the inlet and thus measurement inaccuracies associated with varying inlet profiles are removed. The inlet profile depends on the pipe route to the flow meter 1, and differences in the inlet profile cause differences in the relationship between the measured average velocity in the measuring tube 9 and in the flow. The angle ν is chosen to be suitably large so that an inlet distribution chamber is formed which creates uniform inlet profiles to the measuring tube, but the angle must not be so large that an air hole can form in the measuring tube, since the ultrasound can then not be transferred from one transducer to the other transducer.

Claims (6)

1. Ultrasonic flow meter comprising a measuring tube, reflectors and ultrasonic transducers, the reflectors being arranged at the ends of the measuring tube so that a reflector surface of a first reflector faces a reflector surface of a second reflector and the reflector surfaces have a first angle to a plane parallel to the flow direction through the measuring tube, furthermore a first and a second ultrasonic transducer being arranged above the first and second reflectors respectively, the propagation directions of the transducers forming a second angle to a plane parallel to the flow direction and the ultrasonic transducers pointing towards the reflector surfaces, characterized in that the ultrasonic transducers are arranged such that the ultrasonic transducer at one end of the measuring tube points away from the ultrasonic transducer at the other end of the measuring tube. 2. Ultrasonic flow meter according to claim 1, characterized in that the second angle between the ultrasonic transducers and the plane parallel to the flow direction is between 15° and 35°. 3. Ultrasonic flow meter according to claim 1 and 2, characterized in that the second angle between the ultrasonic transducers and the plane parallel to the flow direction is 25°. 4. Ultrasonic flow meter according to claims 1-3, characterized in that the measuring tube is rotated in relation to the inlet and outlet of the flow meter housing so that the central axis of the measuring tube forms an angle of between 30° and 60° with a central axis through the inlet and outlet and that the tube is connected to means for dividing the flow meter housing into an inlet distribution chamber and an outlet distribution chamber. 5. Ultrasonic flow meter according to claim 4, characterized in that the measuring tube is rotated in relation to the inlet and outlet of the flow meter housing so that the central axis of the measuring tube forms an angle of 45°. 6. Ultrasonic flow meter according to claim 4-5, characterized in that the means for dividing the flow meter housing are represented by barrier walls arranged perpendicular to the measuring tube and on each side of the measuring tube, so that the ends of the barrier walls adjoin tightly to the side wall of the flow meter housing and divide the flow meter housing into an inlet distribution chamber and an outlet distribution chamber.