EP1293960A2 - Ultrasonic transmitter and receiver having an ultrasonic transducer and waveguide - Google Patents

Abstract

The ultrasonic transceiver system has an ultrasonic converter (1) at one end of an ultrasonic waveguide (2) within a mantle (3). An impedance jump is between the ultrasonic converter and the mantle zone next to it, by a circular groove (6) around the mantle. The groove can be filled with a different material from the mantle.

Description

The invention relates to an ultrasonic wave transmitter or receiver, with an ultrasonic transducer, an ultrasonic waveguide and a Sheath, the ultrasound waveguide being arranged within the sheath the ultrasonic transducer is arranged at one end of the ultrasonic waveguide and from the ultrasonic transducer at this end of the ultrasonic waveguide Ultrasound waves can be transmitted to or received by the latter are.

Such ultrasonic wave transmitters or receivers are e.g. B. in Ultrasonic flow meters and in vortex frequency flow meters used. Piezo crystals are typically used as ultrasonic transducers used with which ultrasonic waves can be generated or detected.

In principle, it would be possible to use an ultrasonic wave transmitter or receiver to provide only an ultrasonic transducer with which Ultrasonic waves can be generated or detected. To do this, the However, ultrasonic transducers can be arranged directly where the ultrasonic waves to be coupled in or detected. However, this is problematic in that than that piezocrystals, as stated previously, typically used for ultrasonic transducers, above a certain temperature, the so-called Curie temperature, can no longer be used. There is no ferroelectric above the Curie temperature or ferromagnetic phase of the crystal more, the prerequisite for piezoelectric properties of the crystal. However, e.g. B. the flowing Medium, the flow measured with the ultrasonic flow meter should be very hot, so that its temperature is above the Curie temperature of the piezo crystal, there is a certain requirement for reliable operation thermal insulation of the ultrasonic transducer from the hot medium required. For this reason, ultrasonic wave transmission or Receiving devices used ultrasonic waveguide, the one hand heat insulation of the ultrasound transducer as good as possible from the hot medium and on the other hand a lossless and undisturbed transmission of the ultrasonic signal should ensure. With such an ultrasonic waveguide can then generate ultrasonic waves generated by an ultrasonic transducer be coupled into the flowing medium or by the ultrasonic transducer ultrasonic waves are extracted from the hot medium, while the ultrasound transducer is physically distant from the hot medium and is at least to some extent thermally insulated from it.

In conventional ultrasonic wave transmitters or receivers z. B. ultrasonic waveguide used, as described in WO 96/41157. A plurality of each other is used as the ultrasonic waveguide parallel, very thin rods are used, the individual rod diameters each much lower than the wavelength of the to be guided Ultrasound signal are. Typically, the bars become close together fitted into a tube that provides lateral support for the bars and thus represents a jacket for the ultrasonic waveguide. In this way a compact ultrasonic waveguide is realized. From WO 96/41157 such a construction is also known for an ultrasonic waveguide, in the case of sheets which are essentially circularly curved into one another at a distance are arranged to each other. These are also in a tube, the thus represents an outer jacket for the ultrasonic waveguide. Finally Such an ultrasonic waveguide is known from EP 1 098 295, which consists of a rolled-up foil, which fits into a metallic Tube is inserted. It is provided that for the transmission of ultrasonic waves the layer thickness in the frequency range from 15 kHz to 20 MHz the film is less than 0.1 mm. The material used for this film is typically used a metal.

The ultrasonic wave transmitting / receiving devices with those previously described Ultrasonic waveguides have in common that at one end of the ultrasonic waveguide the ultrasonic transducer is arranged such that the Ultrasonic transducer can be coupled into the ultrasonic waveguide or can be received by it. This is typically the case proceeded that the ultrasound transducer directly, i.e. with physical contact, is placed on one end of the ultrasonic waveguide. The previous one described ultrasound waveguide is made of a rolled-up film generally provided that the ends of the ultrasonic waveguide are welded and are face to face. The ultrasonic transducer is then on this welded and face-turned surface of the ultrasonic waveguide.

The problem with the ultrasonic wave transmission devices described above is that ultrasonic waves generated by the ultrasonic transducer not only coupled into the ultrasonic waveguide but also into the jacket surrounding the ultrasonic waveguide. The same applies, if the ultrasound transducer is provided for the detection of ultrasound waves when there is an ultrasonic wave receiving device. Then get there namely ultrasound waves not only through the ultrasound waveguide but also over the jacket to the ultrasonic transducer. So it comes in Case that on the one hand an ultrasonic wave transmitter and on the other hand an ultrasonic wave receiving device is provided for that not only ultrasonic waves emitted or detected via the ultrasonic waveguide but also sent or received via the respective coat Ultrasonic waves are detected. In addition, is the ultrasonic wave transmission or receiving device via its jacket z. B. in the Wall of a pipe installed in which a flowing medium is guided, whose flow rate is to be determined, it happens that not only ultrasound waves passing through the medium are detected, but also those that extend over the wall of the tube from the ultrasonic wave transmission device move to the ultrasonic wave receiving device. This phenomenon is called cross coupling or crosstalk and possibly leads to an overlay or complete disruption of the measurement signal actually of interest.

The problem associated with this becomes particularly clear when one realizes that when ultrasound waves are transferred between two different media, the transmission coefficient applies, disregarding geometric effects: T = 4 (e.g. 1 / z 2 ) / (1 + z 1 / z 2 ) 2 ,

In this case, z ₁ and z _{2 represent} the characteristic impedances of the first and second medium, between which the transition of the ultrasonic waves takes place. In the transition from steel to air, the aforementioned transmission coefficient T is approximately 0.004%. This corresponds to the fact that a substantial part of the acoustic energy, namely 99.996%, is lost. A significant part of this lost energy is found in the unwanted cross coupling. The cross coupling thus essentially determines the signal-to-noise ratio of a measuring device working with ultrasonic wave transmitting and / or receiving devices.

Accordingly, the object of the invention is an ultrasonic wave transmission Specify or receive device with the unwanted cross-coupling are largely avoidable.

Based on the ultrasonic wave transmission or receiving device is the previously derived and shown task according to the invention solved in that between the ultrasonic transducer and an area of impedance in the area of the jacket facing away from the ultrasonic transducer is provided.

The impedance jump provided according to the invention thus makes a Achieved area of the shell of the ultrasonic wave transmission device in which Ultrasound waves unwanted in the jacket by the ultrasound transducer are severely weakened. Correspondingly, in an inventive Ultrasonic wave receiving device achieved a range in which Coat of the ultrasonic wave receiving device detected to the ultrasonic transducer guided ultrasonic waves are greatly weakened. In both In fact, the ultrasound waves that travel over the jacket must Pass impedance jump, once coming from the ultrasonic transducer and once to the ultrasonic transducer, depending on the Size of the impedance jump a weakening of the intensity of the ultrasonic waves essentially according to the formula given above for the Transmission coefficient takes place.

Such an impedance jump according to the invention in the cladding of the ultrasonic wave transmission or receiving device can be realized in different ways become. According to a preferred development of the invention, for. B. provided that the jacket is spaced from the ultrasonic transducer is. In this way, the ultrasonic transducer is directly facing At the end of the mantle an air gap is realized, which, as referenced above executed on the transmission coefficient, to very considerable Damping leads. In this context, it is according to a preferred one Development of the invention provides that the distance range with a different from the material of the jacket and from the material of the ultrasonic transducer Material is filled. This is particularly advantageous if a geometrically uniform transition from the ultrasonic transducer to the Jacket of the ultrasonic wave transmission or reception device required a recess is not permitted.

Alternatively, according to a preferred development of the invention, the Impedance jump provided in the jacket itself. This is e.g. B. thereby realizable, that the impedance jump is formed by a recess in the jacket becomes. The recess may, for. B. one or more holes Holes must be formed. These can only be blind holes also be through holes that extend over the entire thickness of the Stretch coat. The recess can also be of one, preferably circumferential, groove be formed. With regard to this groove, it is also possible that it extends over the entire thickness of the jacket, but the groove can extend extend only over part of the thickness of the jacket. In particular in this context it is possible that the groove along its circumference is different depth.

Basically, the same applies to the formation of the impedance jump in the jacket itself, namely through a recess formed in the jacket that this at least in part with one of the material of the jacket and of that Material of the ultrasonic transducer different material can be filled.

According to a further preferred development of the invention, the ultrasonic wave transmission used or receiving device in a measuring device, which contains or contains a medium such as a gas or a liquid has a leading container. As a medium containing or leading Containers come in particular into a tank or a pipe. So z. B. as a medium-leading container a tube for an ultrasonic flow meter conceivable. In such a measuring device is now in accordance the preferred development of the invention provides that a previously described Ultrasonic wave transmission device and / or a previously described Ultrasonic wave receiving device above that of the ultrasonic transducer area of the jacket facing away from the wall of the container is. In the case of an ultrasonic wave transmission device, only the part is thus of the cladding in contact with the wall in which the ultrasonic waves are already are significantly weakened. The unwanted, about the wall of the container cross-coupling is thus greatly reduced. on the other hand likes in the case of an ultrasonic wave receiving device over the wall a coupling of ultrasonic waves via cross coupling take place in the area of the jacket over which the ultrasonic wave receiving device is fixed in the wall of the container. Because of the Impedance jump, however, that separates this area from the area that leads to the Ultrasonic transducer leads, this is only significantly reduced Cross coupling component can be detected.

In principle, it is possible to use the ultrasound wave transmission device and / or the ultrasonic wave receiving device directly in the wall of the container to fix. According to a preferred development, however, it is provided that that to attach the ultrasonic wave transmitter or / and a flange is provided for the ultrasonic wave receiving device, an additional attenuation of the cross coupling can be achieved that between the flange and the jacket of the ultrasonic wave transmitter or the ultrasonic wave receiving device, a damping ring is provided. When choosing the material for the damping ring should turn care should be taken to ensure that the greatest possible jump in impedance occurs. Since the jacket of the ultrasonic wave transmitting or receiving device is typically made of a metal and the wall of the container typically also made of metal, come for the damping ring typically plastic or rubber materials.

Fig.1

eine Ultraschallwellensende- bzw. -empfangsvorrichtung gemäß einem ersten bevorzugten Ausführungsbeispiel der Erfindung im Vergleich mit einer herkömmlichen Ultraschallwellensende- bzw. -empfangsvorrichtung,

Fig. 2

eine Ultraschallwellensende- bzw. -empfangsvorrichtung gemäß einem zweiten bevorzugten Ausführungsbeispiel der Erfindung,

Fig. 3

Modifikationen der Ausnehmung in dem Mantel der Ultraschallwellensende- bzw. -empfangsvorrichtung gemäß dem ersten bzw. dem zweiten bevorzugten Ausführungsbeispiel der Erfindung,

Fig. 4

eine Ultraschallwellensende- bzw. -empfangsvorrichtung gemäß einem dritten bevorzugten Ausführungsbeispiel der Erfindung,

Fig. 5

eine Ultraschallwellensende- bzw. -empfangsvorrichtung gemäß einem vierten bevorzugten Ausführungsbeispiel der Erfindung,

Fig. 6

den Einbau von Ultraschallwellensende- bzw. -empfangsvorrichtungen gemäß dem ersten bevorzugten Ausführungsbeispiel der Erfindung in ein Meßrohr eines Ultraschallwellendurchflußmeßgeräts und

Fig. 7

die Anordnung der Ultraschallwellensende- bzw. -empfangsvorrichtung gemäß dem ersten bevorzugten Ausführungsbeispiel der Erfindung in der Wandung eines Behältnisses über einen Dämpfungsring.

In particular, there are now a multitude of possibilities for designing and developing the ultrasound wave transmitter or receiver device according to the invention. For this purpose, reference is made to the claims subordinate to claim 1 and the following detailed description of preferred exemplary embodiments of the invention with reference to the drawing. In the drawing shows

Fig.1

an ultrasonic wave transmitter or receiver according to a first preferred embodiment of the invention in comparison with a conventional ultrasonic wave transmitter or receiver,

Fig. 2

an ultrasonic wave transmitting or receiving device according to a second preferred embodiment of the invention,

Fig. 3

Modifications of the recess in the jacket of the ultrasonic wave transmitting or receiving device according to the first or the second preferred exemplary embodiment of the invention,

Fig. 4

an ultrasonic wave transmitting or receiving device according to a third preferred embodiment of the invention,

Fig. 5

an ultrasonic wave transmitting or receiving device according to a fourth preferred embodiment of the invention,

Fig. 6

the installation of ultrasonic wave transmitting or receiving devices according to the first preferred embodiment of the invention in a measuring tube of an ultrasonic wave flow meter and

Fig. 7

the arrangement of the ultrasonic wave transmission or reception device according to the first preferred embodiment of the invention in the wall of a container via a damping ring.

From Fig. 1 is an ultrasonic wave transmission or reception device according to a first preferred embodiment of the invention in comparison with a conventional ultrasonic wave transmitter or receiver seen. The ultrasonic wave transmitting or receiving device shown on the right in FIG. 1 according to the first preferred embodiment of the The invention has an ultrasound transducer 1, an ultrasound waveguide 2 and a jacket 3 that surrounds the ultrasonic waveguide 2. The ultrasonic waveguide 2 consists of a thin rolled-up metal foil, whose thickness is about 0.1 mm and the ends 4 turned and are welded. For attaching the ultrasonic wave transmitter or receiver according to the first preferred embodiment of the Invention, a flange 5 is welded to the jacket 3. About this Flange 5 can be the ultrasonic wave transmitting or receiving device according to the first preferred embodiment of the invention, as in Fig. 1 not shown, for. B. attached to a measuring tube Fix the connection flange. The jacket 3, like the ultrasound waveguide 2, from a metal. In the jacket 3 is above the flange 5, that is in one region of the jacket 3 facing the ultrasonic transducer 1, a recess 6 provided. This recess 6 is designed as a circumferential groove 3 and extends over the entire thickness of the jacket 3.

In the conventional ultrasonic wave transmission shown on the left in FIG. no such recess is provided, wherein the structure of the conventional ultrasonic wave transmitting or receiving device is otherwise practically the same. Due to the or receiving device according to the first preferred embodiment the recess 6 provided by the invention becomes however completely different behavior of the ultrasonic wave transmitter or receiver with respect to the ultrasound transducer 1 coupled into the jacket 3 Ultrasound waves achieved.

As indicated by arrows, conventional ultrasonic wave transmitters can or receiving device coupled into the jacket 3 Ultrasonic waves directly over the flange 5 in the not shown Wall of the measuring tube into which the ultrasonic wave transmitting or receiving device is installed, transmitted. In contrast to that this direct route via the jacket adjacent to the ultrasonic transducer 1 3 in the ultrasonic wave receiving device according to the first preferred embodiment of the invention due to the recess 6 essentially denied in the jacket 3. Ultrasonic waves can only over the flange 5 into the wall of the measuring tube, not shown arrive by completely passing through the ultrasonic waveguide 2 and at its end 4 facing away from the ultrasound transducer 1 into the jacket 3 couple, then after running back in the jacket 3 towards the Finally, couple the ultrasonic transducer 1 into the flange 5. To this On the one hand, the intensity is coupled into the measuring tube via the flange 5 Ultrasonic waves are much lower, however, on the other hand also the path of the ultrasonic waves causing the cross coupling in this way much longer, so that the originating from the cross coupling Interference signal is expected to be significantly after the actual measurement signal can be directly from the ultrasonic wave transmitter to the Ultrasonic wave receiving device is running. This is discrimination of the measurement signal against interference much easier.

From Fig. 2 is now an ultrasonic wave transmitting or receiving device according to a second preferred embodiment of the invention. The structure of this corresponds essentially to that shown in FIG. 1 Ultrasonic wave transmitting or receiving device according to the first preferred embodiment of the invention, except for the fact that the recess 6 is filled with a material 7 that of the material of the jacket 3 and the material of the ultrasonic transducer 1 different is. In the present case, a plastic material is selected for filling the recess 6 Service.

3 shows further design options for the recesses 6 shown in the jacket 3 of the ultrasonic wave transmitting or receiving devices. 3, the recess 6 can namely in shape of bores, in the form of an oblique groove over a partial circumference of the jacket 3 or in the form of an oblique groove be provided, which extends over the entire peripheral region of the jacket 3.

4 and 5 are now ultrasonic wave transmitting and receiving devices according to a third or fourth preferred embodiment the invention can be seen. In both cases it is provided that the impedance jump not in the jacket 3 of the ultrasonic wave transmitting or receiving device itself, but between the ultrasonic transducer 1 and the Sheath 3 is provided. In both cases, the jacket 3 is not enough up to the ultrasound transducer 1, so it is at a distance from the ultrasound transducer 1 arranged. 5 is the fourth preferred exemplary embodiment the invention advantageous in that the further up Jacket 3 better protection of the ultrasonic transducer 1 facing End 4 of the ultrasonic waveguide 2 and the ultrasonic transducer 1 offers itself.

From Fig. 6 it can be seen how ultrasonic wave or receiving devices according to the first preferred embodiment described above the invention in a measuring tube 8 of an ultrasonic wave flow meter are installed, namely in each case via a connecting flange 9. In Fig. 6 it is shown that the path of the cross coupling ultrasonic waves of the one ultrasonic transducer 1 via the flange 5 of the Ultrasonic wave transmission device, the one connecting flange 9, the wall 10 of the measuring tube 8, the other connecting flange 9, the flange 5 of the Ultrasonic wave receiving device to the other ultrasonic transducer 1 is significantly longer than the direct route via the respective ultrasonic transducers 1 opposite ends 4 of the ultrasonic waveguide 2 of the ultrasonic wave transmission device or the ultrasonic wave receiving device. For this reason, the ultrasonic waves corresponding to the cross coupling hit time clearly after the actual measurement signal, so that the measurement signal discriminates relatively easily compared to the cross coupling can be selected if a pulse mode is selected.

7 shows how an ultrasonic wave transmitting or receiving device according to the first preferred embodiment described above the invention via a damping ring 11 in the wall 12 of a container is installed. The damping ring 11 is in the present case a rubber material, so that additional damping of the Cross coupling constituting ultrasonic waves takes place.

Claims (9)

Ultrasonic wave transmitter or receiver, with an ultrasonic transducer (1), an ultrasonic waveguide (2) and a jacket (3), the ultrasonic waveguide (2) being arranged inside the jacket (3), the ultrasonic transducer (1) at one end ( 4) of the ultrasound waveguide (2) is arranged and from the ultrasound transducer (1) at this end (4) of the ultrasound waveguide (2) ultrasound waves can be transmitted to or received by it, characterized in that between the ultrasound transducer (1) and the A region of the jacket (3) facing away from the ultrasonic transducer (1) is provided with an impedance jump. Ultrasonic wave transmitting or receiving device according to claim 1, characterized in that the jacket (3) is arranged at a distance from the ultrasonic transducer (1). Ultrasonic wave transmitting or receiving device according to Claim 2, characterized in that the spacing area is filled with a material which is different from the material of the jacket (3) and from the material of the ultrasonic transducer (2). Ultrasonic wave transmitting or receiving device according to claim 1, characterized in that the impedance jump is formed by a recess (6) in the jacket (3). Ultrasonic wave transmitting or receiving device according to claim 4, characterized in that the recess (6) is formed by at least one bore. Ultrasonic wave transmitting or receiving device according to claim 4, characterized in that the recess (6) is formed by a preferably circumferential groove. Ultrasonic wave transmitting or receiving device according to one of Claims 4 to 6, characterized in that the recess (6) is at least partially filled with a material (7) which is different from the material of the jacket (3) and from the material of the ultrasonic transducer (1) , Measuring device with a container containing or carrying a medium, characterized in that an ultrasonic wave transmitting device and / or an ultrasonic wave receiving device according to one of Claims 1 to 7 via the region of the jacket (3) in the wall (8, 12) facing away from the ultrasonic transducer (1) ) of the container is attached. Measuring device according to claim 8, characterized in that a flange (9) is provided for fastening the ultrasonic wave transmitting device and / or the ultrasonic wave receiving device and a damping ring (11) is provided between the flange (9) and the jacket (3) of the ultrasonic wave transmitting device or the ultrasonic wave receiving device is.

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