FR2462837A1 - ULTRASONIC TRANSDUCER - Google Patents

Abstract

The ultrasound converter, which is pressure-proof, hot water resistant and insensitive to temperature changes, consists of a converter housing (1), an oscillating element (2) with a piezo disc (3), electrodes (4; 6), and a power cable (7). In the space between the floor of the housing (5) and the rear electrode (6) is an ultrasound-insulating medium, preferably a synthetic foam. The oscillating element (2) rests on a shoulder (13) of the converter housing (1), and is axially rigid and radially movable. Its outer surface is distanced from the converter housing (1), and it is sealed against the converter housing (1), and held elastically, by an elastic seal (14). Openings (16), which are permeable to water vapour, are arranged in the housing floor (5). The front electrode (4) extends to the rear face of the piezo disc (3). A plastic film or an O-ring can be used as the elastic seal (14). If the ultrasound converter is used to measure the flow rate in a pipe, the diameter of the piezo disc (3) is greater than the internal diameter of the pipe.

Description

 The present invention relates to an ultrasonic transducer, intended to radiate acoustic waves in a liquid medium and to receive such acoustic waves, comprising a pot-shaped housing, in which is fixed an oscillating element constituted by a piezoelectric disc provided with two electrodes arranged, one on its front front surface facing the liquid medium, and the other on its rear front surface facing the bottom of the case, while in the space between the bottom of the case and the a rear front surface of the oscillating element is arranged an ultrasonic isolating medium, a current conducting cable being furthermore connected to the electrodes.

An ultrasonic transducer of this type is already known (Piezoxide-Wandler, March 1973, page 110, Valvo GmbH) intended for echo sounding devices and in which the oscillating element is sealed, together with a foam rubber disc serving as ultrasonic isolating medium, by means of a sealing mass, in the transducer housing. The front front surface and the peripheral surface of the oscillating element are rigidly linked to the sealing mass. The sealing compound forms a layer of strong plastic which protects the front face.

 Ultrasonic transducers constructed in this way are well suited for echo sounding devices in seawater, where they are subjected to relatively small temperature variations.

On the other hand, their resistance to a very hot strip is insufficient to allow their use in flowmeters for heat quantity meters. Due to the different coefficients of thermal expansion of the constituent materials, there is a risk of tearing of the bonded points and the ultrasonic properties of the sealing compound which are highly dependent on temperature lead to a variable acoustic load on the piezoelectric disc and, consequently, , to a form of oscillation depending on the temperature.

The object of the invention is to create an ultrasonic transducer which, on the one hand, is resistant to very hot water and is characterized by a form of constant oscillation over a wide temperature range and which, on the other hand, nevertheless has great resistance to pressure and can be produced as a mass-produced article with little technical means.

 The invention will be better understood on reading the detailed description which follows and on examining the attached drawing which represents, by way of nonlimiting examples, some embodiments.

On this drawing
Figures 1 to 3 show three different variants of an ultrasonic transducer comprising a thickness resonance oscillator;
FIG. 4 represents an oscillating element comprising a radial resonance oscillator, and
FIG. 5 represents a part of a flow meter comprising an ultrasonic transducer.

 In Figure 1, the reference 1 designates a pot-shaped transducer housing in which is fixed an oscillating element 2. The oscillating element 2 is constituted by a cylindrical piezoelectric disc 3 relatively thin compared to its diameter, provided with an electrode 4 disposed on its front front surface facing the liquid medium, not shown, and an electrode 6 disposed on its rear front surface facing the bottom 5 of the housing. A current conducting cable 7 passes through the bottom 5 of the housing, is fixed to the latter by means of a cable gland 8 and is connected, by means of connection wires 9, 10, in a manner described more far in more detail, to the electrodes 4,6.

 The transducer housing 1 has, on the inner side of its casing Il opposite its bottom 5, for the reception of the oscillating element 2, a concentric annular recess 12 as well as a shoulder 13, preferably annular, projecting axially . This shoulder is small in relation to the surface of the oscillating ltelemellt 2 The oscillating element 2 rests, by its rear front surface, fixedly in the axial direction, on the shoulder 13 but can, on the other hand, slide in the direction radial on this one. it is clear that the shoulder 13 of the oscillating element 2, for dynamic reasons, should not rest too close to its center, but rather in the vicinity of its outer edge. The diameter of the discharge 12 is slightly larger than that of the oscillating element 2, so that the latter, at its peripheral surface, is distant from the transducer housing 1, that is to say that in the entire temperature range, even with strongly different coefficients of thermal expansion between the peripheral surface of the oscillating element 2 and the transducer housing 1, there is still a slight clearance. By means of an elastic seal 14, the oscillating element 2 is at both sealed with respect to the transducer housing I and held resiliently in axial and radial directions. In the example of FIG. 1, the seal 14 is constituted by a thin sheet of flexible plastic material, which protects the front surface from the oscillating element 2 against magnet deposits ite or the like, projects radially beyond the oscillating element 2 and is fixed in a flexible manner to the front surface of the casing II and to the front front surface of the oscillating element 2 , for example by gluing. The seal 14 can be very thin compared to the wavelength of the ultrasound or else present, as an acoustic adaptation layer, a thickness corresponding to a quarter of a wavelength.

 In the space 15 between the bottom 5 of the housing and the rear front surface of the oscillating element 2 is arranged an ultrasonic isolating medium. To avoid the formation of water of condensation in the space 15, openings 16 are provided in the bottom 5 of the housing, openings which allow at least the water vapor to pass. As an ultrasonic isolating medium in space 15, air can be used or, to make unauthorized interventions more difficult, through the openings 16, inside the ultrasonic transducer 1, a foam of plastic material.

 The piezoelectric disc 3 is, in the examples of FIGS. 1 to 3, a thickness resonance oscillator.

To avoid parasitic resonances and, consequently, complicated and highly frequency-dependent forms of oscillation, the diameter of the rear electrode 6 is at most equal to half the diameter of the piezoelectric disc 3, so that the oscillating element 2 rests on the shoulder 13 outside the rear electrode 6.

The front electrode 4 advantageously extends at least at one point of the piezoelectric disc 3 over its peripheral surface up to its front-rear surface. In this way, it is avoided having to pass one of the connection wires 9, 10 to the front side of the oscillating element 2. The connection wire 9 electrically connected to the front electrode 4 can, as shown on Figures 2 and 3, be directly soldered thereto or, as shown in Figure 1, be connected to the transducer housing 1 which, in this case, is made of metal or is covered internally with an electrically conductive layer , so that the electrical connection with the electrode 4 then takes place via the contact surfaces between the shoulder 13 and the electrode 4. If the front electrode 4 does not extend above the peripheral surface of the piezoelectric disc 3 to the rear side thereof, then the electrical connection between the electrode 4 and the transducer housing 1 can still be carried out by lining the elastic seal 14, on its rear surface, with a thin metallic layer, which then rests on the electrode 4 and on the front surface of the casing 11 of the housing. Such a metal layer which, for example, can be formed by vaporization, also plays the role of an additional barrier against water vapor.

 The ultrasonic transducer described can be used both for the radiation of acoustic waves in a liquid medium and for the reception of such acoustic waves. The use of expensive and labor-intensive sealants is avoided with this ultrasonic transducer and a construction resistant to very hot water is obtained. As the oscillating element 2 rests fixedly on a shoulder 15 of small area but, over the rest of its extent, is on the other hand only held elastically in the housing of the transducer and is practically not damped at the rear, great resistance at pressure and a form of oscillation independent of temperature are ensured and acoustic radiation on the rear side, which would lead to energy losses and a parasitic rear wall echo, are nevertheless avoided.

 In FIG. 2, the parts corresponding to those of FIG. 1 are designated by the same reference numbers as on this one. The transducer housing designated by 1 ′ differs essentially from the transducer housing 1 in FIG. 1 only in that the front face of the annular recess 12 ′ serves as a shoulder 13 ′, on which the oscillating element 2 rests by the outer edge of its rear front surface fixedly in the axial direction and movably in the radial direction.An O-ring 17, which is inserted coaxially with the oscillating element 2 between the peripheral surface thereof and the surface inner peripheral of the transducer housing 1 'formed by the outlet 12', seals the oscillating element 2 relative to the transducer housing 1 'and forms for the oscillating element, in the radial direction, an elastic support. The space 15 and the openings 16 are blocked with plastic foam for the reason mentioned above. The front electrode 4, which is advantageously made of silver, covers at least the front front surface and the peripheral surface of the piezoelectric disc 3 entirely and protects the piezoelectric disc 3 in a safe manner against deposits. Advantageously, the front electrode 4 , which extends to the rear front side of the piezoelectric disc 3, also covers the contact surface between the shoulder 13 'and the oscillating element 2 entirely and thus prevents mutual chemical influences between the housing 1' of the transducer and the piezoelectric disc 3.

The ultrasonic transducer of FIG. 3 differs from that of FIG. 2 by a layer of plastic material 18, for example glued or sprinkled, which, here again, can be thin or have a thickness of a quarter of length d wave and which protects at least the front front surface and the peripheral surface of oscillating element 2 against deposits. It is also possible, for reasons of protection and sealing, to interpose a thin sheet of plastic material between the shoulder 13 ′ and the oscillating element 2 or to arrange the layer of plastic material 18 also in the area of contact of the shoulder 13 '. The oscillating element then always remains still substantially rigidly supported in the axial direction, so that the resistance to pressure is not influenced.

 In FIG. 4 is shown an oscillating element 19, which has a piezoelectric disc 20 produced in the form of a radial resonance oscillator and which can be used, instead of the oscillating element 2, in the ultrasonic transducers described. An electrode 21 covers the entire front front surface of the piezoelectric disc 20 and forms a small connection lug 22, which extends over the peripheral surface of the piezoelectric disc 20 up to its rear front surface. With the exception of the surface occupied by the connection terminal 22, an electrode 23 covers the entire rear front surface of the piezoelectric disc 20.

FIG. 5 represents the ultrasonic transducer of FIG. 1 which, to ensure the measurement of the flow rate of a liquid medium in a measurement tube 24, is incorporated into a tubular connection 25 sealed by means of an O-ring 26 relative to the connector 25 and fixed by means of a threaded ring 27. The piezoelectric disc 3 is arranged coaxially with the measurement tube 24 and disposed at a certain distance from the mouth of the latter. The diameter of the piezoelectric disc 3 is larger than the inside diameter of the measurement tube 24, so that the radiation of a plane ultrasonic wave with constant intensity distribution is ensured in the measurement tube 24.

Claims (12)

1) Ultrasonic transducer intended to radiate acoustic waves in a liquid medium and to receive such acoustic waves, comprising a pot-shaped housing, in which is fixed an oscillating element, constituted by a piezoelectric disc provided with two electrodes arranged, l 'one on its front front surface facing the liquid medium, and the other on its rear front surface facing the bottom of the housing, while in the space between the bottom of the housing and the rear front surface of the oscillating element, is arranged an ultrasonic isolating medium, a current conducting cable being further connected to the electrodes, said ultrasonic transducer being characterized in that its housing (1; 1 ') has a shoulder (13; 13') of reduced area compared to the front surfaces of the oscillating element (2;  19), shoulder on which the oscillating element (2; 19) rests by its rear front surface in a substantially fixed manner in the axial direction but movable in the radial direction, and in that the oscillating element (2; 19), at its peripheral surface, is remote from the housing (1; 1 ') and, by means of an elastic seal (14; 17), is both sealed with respect to the housing (1; 1') and held resiliently. 2) ultrasonic transducer according to claim 1, characterized in that the shoulder (13; 13 ') is annular, and in that the oscillating element (2; 19) rests by the outer edge of its rear front surface, or in the vicinity of this outer edge, on the shoulder (13; 13 '). 3) Ultrasonic transducer according to one of claims 1 and 2, characterized in that in the bottom (5) of the housing is provided at least one opening (16) allowing water vapor to pass. 4) Ultrasonic transducer according to claim 3, characterized in that the ultrasonic isolating medium is a plastic foam. 5) Ultrasonic transducer according to one of claims 1 to 4, characterized in that the front electrode (4, 21) at at least one point of the piezoelectric disc (3; 20) extends over the peripheral surface of that -this to its rear frontal surface. 6) Ultrasonic transducer according to one of claims 1 to 5, characterized in that the front end surface of the oscillating element (2; 19) is protected by a layer of plastic material, which projects radially beyond- the oscillating element (2; 19) and forms the elastic seal (14). 7) Ultrasonic transducer according to one of claims 1 to 5, characterized in that the elastic seal (17) is an O-ring. 8) Ultrasonic transducer according to claim 7, characterized in that at least the front front surface and the peripheral surface of the oscillating element (2; 19) are protected by a layer of plastic material (18). 9) Ultrasonic transducer according to one of claims 1 to 5, characterized in that the front front surface and the peripheral surface of the oscillating element (2; 19) are protected by the front electrode (4; 21). 10) ultrasonic transducer according to claim 2, characterized in that the piezoelectric disc (3) is a thick resonance oscillator, in that the diameter of the rear electrode (6) is at most equal to half the diameter of the piezoelectric disc (3), and in that the oscillating element (2) rests on the shoulder (13) outside the rear electrode (6). 11) Ultrasonic transducer according to one of claims 1 to 9, characterized in that the piezoelectric disc (20) is a radial resonance oscillator, and in that the rear electrode (23) covers almost the entire rear front surface of the piezoelectric disc. 12) Use of the ultrasonic transducer according to one of claims 1 to 11, in a flow meter intended to measure the speed of flow of a liquid medium in a tube, this use being characterized in that the diameter of the disc piezoelectric (3; 20) is larger than the inside diameter of the tube (24).