NL8403222A - METHOD OF REDUCING UNDESIRABLE ECHO'S IN ULTRASONIC FLOW SPEEDOMETERS. - Google Patents

Description

-1- * Λ N.V. Ned. Apparatenfabriek NEDAP in Groenlo._

Method for reducing unwanted echoes in ultrasonic flowmeters.

The invention relates to a method for reducing unwanted echoes in ultrasonic flow rate meters, operating according to the phase or transit time difference measuring principle.

The types of ultrasonic flow rate meter operating according to the phase or transit time difference principle are often composed of two opposite, parallel arranged transducers, with a calibrated measuring tube in between.

The medium to be measured flows past the transducers and through the measuring tube. An ultrasonic beam traveling downstream 10 is apparently accelerated, while an ultrasonic beam upstream is apparently delayed.

By now simultaneously transmitting a short sound beam via both transducers and, a little later, receiving the arrived sound * via the same transducers, the speed of the medium to be measured can be derived with this received sound via a phase or transit time difference measurement.

Obviously, the time during which the two sound beams are transmitted must not exceed the time required to reach the opposite transducer since it must then be switched as a receiver. The measurement therefore takes place over a very short time. In order to achieve sufficient measurement accuracy, the transmission and reception process is constantly repeated at the highest possible repetition rate.

However, a problem arises here: the transducers switched as receiver reflect a part of the sound energy, which in this way ends up in the measuring tube. This reverberation can easily be repeated several times. These echoes will mix with the signals to be measured and thereby cause measurement errors, thereby limiting the measurement accuracy of current ultrasonic flowmeters, operating according to the above methods, 8403222-2.

The first object of the invention is now to prevent or at least make these negligible echoes small. This is achieved according to the invention by providing the active surface of the transducers with one or more elevations or depressions, as a result of which in the reflected sound such an extinction pattern arises in the reflected sound that the overlapping transducer no longer receives or hardly echoes. However, measures must be taken to prevent the side lobes resulting from this reflection phenomenon from reaching the opposite transducer, for example via reflections against the inner wall of the measuring tube.

Some examples of the effect of an elevated part, according to the invention, on a transducer on the pattern of a reflected flat ultrasonic beam are shown in Figures 1 to 4. The drawn outline lines are always equal lines. sound intensity 2, the wavelength of the sound in the medium to be measured is X.

In Fig. 1, the reflective transducer 1 is flat and causes the normal reflection pattern.

In Figs. 2 and 3 an increment 3 of 1/4 X has always been made, with a varying ratio. Above the edge of the elevation, a quenching region is produced by interference. The waves reflected from plane 4 have a distance 2 x 1/4 λ- 1/2 X longer distance to reflect. They are therefore 180 ° in phase behind the waves reflected via plane 3; local blending occurs when both waves are mixed.

The shape of this quenching region can be influenced by changing the ratio - ^ -, but also, as illustrated in Fig. 4, by changing the height h. In this way, the most favorable dimensions of the increases for the present meter construction can be determined by calculation and experiment. These dimensions are of course not entirely free to choose, because the same transducer is also used as a transmitter, and the transmission characteristic is partly determined by the shape of the then radiant surface. In practice it appears that favorable results are achieved with between 0.3 and 0.7.

Note: Instead of the elevations 2 shown in the figures, depressions in the transducer surface can also be used with the same effect. Furthermore, the increases resp. floors also have other peripheral shapes, e.g.

10 annular, while the elevations resp. floors do not have to have the same dimension h over the entire surface. It is now the case that the total amount of reflected sound energy is not affected by the above measures. The reduced reflected sound intensity in the center line of the transducer therefore results in an increase in the intensity at its edge: side lobes are formed. The danger now arises that the relatively energy-rich side lobes reflect against the measuring tube wall and thus disturb the measuring signal.

A second object of the invention is now to prevent annoying reflections of the side lobes against the measuring tube wall. To this end, the pipe wall is internally covered with a layer of a material in which the propagation speed of the sound is approximately equal to or less than that in the liquid to be measured and which has a relatively high internal damping. If the medium to be measured consists of water, such a material is, for example, the plastic polysulfone.

Some embodiments of a flow rate meter according to the invention are given in Figures 5, 6, 7 and 8, 30 all based on, but not limited to, a previous patent application by the same inventor.

The embodiment according to Fig. 5 consists of a jacket 5 within which, in flared parts, the transducers 5 are located. These transducers have active surfaces, which according to the first part of the invention are provided with, in this example, raised parts to counteract undesired echoes in the axial direction of the measuring tube 7.

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The measuring tube 7 is formed by an inner lining of jacket 6 and consists of a material with a propagation speed of sound, which is approximately equal to or less than that of water and with the highest possible damping for sound. This material can be, for example, the plastic polysulfone, in which the speed of sound is approx. 1880m / sec. while in water it is about 1480m / sec. is. The boundary angle for incident sound water / polysulfone is therefore very small, so that almost all sound incident at an angle penetrates the plastic and is largely absorbed there. As a result, this obliquely incident reverberation noise originating from the side lobes does not or hardly ever reach the overlying transducer and thus does not disturb the measuring process or negligibly.

Another exemplary embodiment is shown in Fig. 6.

The distance between the transducers and the ends of the inner liner 7 mentioned in Fig. 5 is now chosen so great that the side lobe sound 8 falls outside the inner liner and dies out in the spaces 9.

A further exemplary embodiment gives fig. 7. The inner lining or measuring tube 7 is now loosely fitted inside jacket 6 and centered therein by the centering edges 10 of the transducers 5. This ensures perfect concentric radiation of the sound inside the measuring tube 7, which increases the measurement accuracy even at very low flow rates. In the exemplary embodiments 5 and 6, multiple tolerances play a role in this concentricity.

The measuring tube 7 is provided with holes 11 on either side, through which the medium to be measured is fed in or out. flows out. A seal 12, eg formed by an O-ring, separates the input and output of the meter.

Finally, Embodiment Example 8 represents an ultrasonic flow rate meter, which is made entirely of a material with the acoustic properties as required for measuring tube 7 fig. 5 to 7. The possibility arises in those cases where a strong, e.g. 6. metal jacket is not needed. Of course, intermediate shapes 340 3222 τ ν - 5 - between Figures 5 to 8 are also possible, with metal connecting pieces, for example.

3403222

Claims (13)

1. Transducer for ultrasonic flowmeters operating according to the phase or transit time difference principle, characterized in that the transducer surface active at the reverberation surface has higher and / or lower parts of such a shape and dimensions that the sound waves reflected on the reverberating waves, which is favorable for the total or almost complete prevention of annoying echoes on the transducer opposite. 2. Transducer according to claim 1, characterized in that the height difference between the higher and / or lower parts of the reflective transducer surface is 1/4 \ to 1/8 \, wherein X is the wavelength of the sound in the medium to be measured at flow rate. Transducer according to claims 1 and 2, characterized in that the active surface of the transducer is circular and concentrically has a raised or lowered portion. Transducer according to claim 3, characterized in that the concentric circular raised or lowered section has a diameter which is between 0.3 and 0.7 times that of the diameter of the total reflective surface. 5. Ultrasonic flow velocity meter operating according to the phase or transit time difference measuring principle, provided with transducers according to claims 1 to 4, characterized in that means are present for the measuring accuracy of the side lobes resulting from the interference of the reflected ultrasonic signal not to be negative influence. 840 32 22 - 7 - 6. Ultrasonic flow velocity meter according to claim 5, characterized in that the energy in the side lobes is captured and absorbed in an inner lining of the measuring tube of the meter, consisting of a material with a sound velocity approximately equal to or less than that of the dimensioned liquid and with a relatively high internal acoustic damping. Ultrasonic flow velocity meter according to claim 6, characterized in that the inner lining ends are spaced from the transducers such that the side lobes end up outside the inner lining circumference, where they can die out in acoustic spaces provided for that purpose. 8. Ultrasonic flow velocity meter according to claim 6, characterized in that the inner lining is in the form of a loose tube, which is centered by centering edges on the transducers and wherein this tube is provided with holes in the wall at the transducers to add the medium to be measured. resp. while this tube 20 is externally provided with a sealant, eg an O-ring, which divides the meter into two compartments in order to prevent short-circuiting of the medium flow outside the tube. 9. Ultrasonic flow velocity meter according to claim 5, characterized in that it consists entirely of a material with a sound velocity approximately equal to or less than that of the liquid to be measured and with a relatively high internal acoustic damping. 10. Ultrasonic flow velocity meter according to claim 9, characterized in that the connecting pieces to the medium-carrying circuit parts lying outside the meter consist of a different, strong material, eg metal. 8403222 - 8 - 1 *. 4 Ultrasonic flow velocity meter according to claims 5 to 10, characterized in that the intended material for the inner coating or the total meter is polysulfone. Ultrasonic flow velocity meter according to claims 5 to 5, characterized in that the intended fabric for the inner lining or the total meter is PTFE. Ultrasonic flow velocity meter according to claims 5 to 10, characterized in that the intended fabric for the inner lining or the total meter is polyamide. 8403222