FR2507424A1 - SELF-ADHESIVE PIEZOELECTRIC TRANSDUCER AND DEVICE FOR IMPLEMENTING THE TRANSDUCER - Google Patents

Abstract

The self-adhesive piezoelectric transducer is intended for medical and industrial ultrasonic applications. It comprises a piezoelectric ribbon of the desired length, which consists of a flexible organic material which is provided with two conductive coatings and at least two electrical terminals. Furthermore, the transducer comprises an adhesive having acoustic characteristics in the form of a simple application of a resin adhesive or in the form of a double-sided adhesive band. The invention also creates a device for applying the transducer.

Description

SELF-ADHESIVE PIEZOELECTRIC TRANSDUCER AND
TRANSDUCER IMPLEMENTATION DEVICE
The present invention relates to a self-adhesive piezoelectric transducer and a device for implementing the transducer.

 Piezoelectric transducers are reversible devices capable of transforming mechanical stress signals into electrical signals. They are found in two major applications medical ultrasound and non-destructive industrial control. Traditionally, transducers have consisted of a piezoelectric ceramic chip, such as tungsten polyzincate (PZT). Their use requires a mechanical coupling means and often an adaptation of the acoustic impedances. This is achieved by the use of an acoustic coupling liquid or gel and mechanical attachment to the body to be examined. The present invention makes it possible to avoid these means.

 I1 is known, for example in French patent application NO 79/00200, filed in the name of THOMSON-CSF, plastic transducers made of organic material of polymers or copolymers in which an electric field allows piezoelectricity to be induced. This is the case for polyvinylidene PVF 2, polytetrafluoroethylene PTFE and their copolymers. In a transducer thus formed, a layer of flexible piezoelectric material is included between two conductive metallic films.

Any deformation caused by an acoustic wave received by the transducer is converted into a modulation of the amplitude of the bias voltage of the transducer. The present invention presents a particularly advantageous form of such transducers.

 Indeed, the present invention, a piezoelectric transducer comprises a piezoelectric film of a flexible organic material, two metal frames, electrical terminals and an adhesive layer of a sticky material with acoustic characteristic and is intended to be cut to any dimensions by to the implementation device. In such a device, a reserve of transducer in continuous strip is stored. The user, for a determined width cuts any length at will of the stored transducer. The transducer obtained is ready to operate.

 Another advantage of the transducer according to the invention is to operate without a damper for the rear acoustic wave. It is often advantageous in acoustic emission to work without a rear shock absorber when the monitored material is made of a hard material.

The absence of a shock absorber reduces the mass of the transducer. It follows that the reflection rate of the acoustic waves on the sensor is reduced.

The invention will be better understood using the following description and the figures which are:
FIG. 1: a diagram of a section of a piece of transducer according to the invention,
FIG. 2: a diagram of an exemplary embodiment of the transducer,
- Figure 3: a diagram of the transducer implementation device, - - Figure 4: a multi-element transducer.

 A transducer according to the invention comprises a strip of plastic material 2. Two plates 1, 3 make it possible to provide the electrical polarization and to collect the electrical signals. Such a strip is available on the market in different dimensions of width, length and thickness. A strip of reduced thickness has the advantage of very low mechanical rigidity.

 On one side of the transducer strip, a thin adhesive tape 4 is deposited. This tape is intended to ensure good acoustic adaptation of the entire surface of the transducer to the monitored surface. In addition, it allows a removable mechanical attachment of the transducer to the monitored object without the use of external means as it is known up to now. Particularly, this avoids fixing by drilling or by belts in the case of industrial installations. A simple preparation of the surface, an operation already required by the transducers of the prior art, is to be carried out before the installation of the self-adhesive transducer.

 The strip transducer may include electrical connection terminals during its manufacture. The metallic films 1, 3 are extended laterally by terminals, for example pierced with a hole intended to receive an electrical wire for connection to the acoustic monitoring device. Such terminals can be cut at regular intervals. Only one of them for a given armature of the given transducer is connected to one of the electric blades of the examination apparatus.

 This arrangement of the transducer allows very rapid implementation even when it is necessary to install a large number of monitoring sensors as is the case for monitoring an industrial installation (refinery, nuclear power station, etc.).

 In another embodiment, the terminals can be placed on the transducer just before installation thereof. Each terminal has a series of teeth intended to penetrate the transducer up to the conductive armature 1 or 3 with which it is desired to obtain an electrical connection. The terminal can in turn be forced in and then glued to the surface of the transducer.

 The adhesive layer 4 can be produced by a thin coating of a layer of an adhesive resin. The thickness and the acoustic characteristic of the resin are chosen so that the acoustic impedance is compatible with good coupling. It could also consist of a tape with two adhesive sides, Pune being reserved for the piezoelectric strip-tape contact and the other for the tape-surface contact to be checked. The acoustic characteristics of the adhesive layer are exploited to achieve an impedance adaptation between the piezoelectric strip and the controlled surface.

 The device for implementing the transducer ready for use, simultaneously makes it possible to store the reserve of transducer and to prepare the desired length of transducer. It is possible. to use a minimum device for the implementation. This minimum device includes a drum that receives the wound transducer tape and a manual cutting tool.

 If the transducer tape is not equipped with its terminals, an installation of electrical terminals must be added.

 The manual cutting tool may be a sharp instrument such as a razor blade or a pair of scissors.

 The shape of the electrical terminals determines the structure of the installation device. In Figure 2 is shown a clip 5 before it is fixed to the transducer 6 by the delivery device, near the edge of the transducer 6. It should be noted that the transducer is thin. The clip is in the shape of an inverted U. A part 7, perpendicular to the plane containing the metal frame 12, receives indentations which are intended to penetrate into the transducer tape until the frame 12 is pierced, establishing electrical contact. A tail 9 in the cylinder portion is welded to the body of the clip 5 thus producing a terminal ready to be mounted on the transducer. For the electrical connection, it suffices to introduce into the tail 9 the stripped end of an electrical connection conductor and to ensure the fixing by crushing the cylinder portion with the pliers.

The positioning device makes it possible to introduce the clip on either side of the transducer along the axis of arrow 10, the toothed part on the side of the armature to be connected. A crushing along the axis of the arrow 11 makes it possible to fix the clip to the transducer and to make electrical contact with the frame 12. An inverted clip, placed on the opposite edge or on the same edge of the transducer, allows to complete the labeling of the transducer. More generally, it is possible to lay a plurality of pairs of terminals along the transducer.

 In another embodiment, the transducer tape itself carries terminals deposited in the manufacture of the piezoelectric tape at regular intervals. Whatever the length of the transducer chosen, it is possible to have at least one pair of electrical connection terminals.

 In the case where the transducer tape receives a coating of adhesive resin, the tape is directly ready for use. If the transducer must receive double-sided adhesive tape, it is possible to place the adhesive tape on the piezoelectric tape at the same time as you wish to install the transducer. Such a device is shown in FIG. 3. A drum 13 receives the wound reserve of ribbon transducer 17. A drum 14 receives the wound reserve of adhesive tape with acoustic impedance adapter 18. Two rollers 15, 16 ensure the contact of the two ribbons during extracting the transducer so that it is ready for use.

 To identify the length of the transducer extracted, it is possible to couple one of the rollers 15 or 16 (here the roller i6 linked to the adhesive tape) to a counter 19 calibrated in length of unwound tape.

In another version, it is possible to deposit at the manufacture of the transducer roller equidistant marks which allow the operator to deposit the desired length.

 Different widths of tape are possible as well as different thicknesses depending on the acoustic and mechanical characteristics required of the transducer.

In another variant, a device for implementing the transducer according to the invention comprises:
- means for storing the transducer,
- means for extracting a requested length of transducer,
means for fixing the terminals to the transducer,
- means for cutting the transducer to the requested length.

 In a removable case, the transducer is wound on a drum, either single if the adhesive tape is in place, or else in two parts as it has been described if the adhesive tape is delivered separate. The extraction of the transducer tape can be manual or mechanized. A counter can supplement the extraction means.

Finally, means for fixing the terminals to the transducer, if these are delivered separately, allow, for example in the manner described above, to prepare the transducer which is then occupied so that the size of the transducer tape extracted corresponds to the length requested from the transducer fitted with these terminals.

 The cutting means can be manual or integrated into the device. They consist of a conventional scissor device which can be actuated by the same movement as that which drives the means for fixing the terminals to the transducer.

 The present invention is applicable to multi-element bar transducers, in particular in the case of sector scanning echographs. For this, it is necessary that in the piezoelectric tape the conductive armatures are cut into electrically insulated slices. Only the part between two polarized frames will respond like a transducer. In Figure 4, a fraction of piezoelectric tape with three transducers is shown. The piezoelectric strip 20 coats two armatures 21, 22. These comprise terminals 220, 221, 222 and 210, 211, 212. Each armature comprises alternating conductive sectors 23, 24, 25 or 26, 27, 28 and insulating sectors 29, 30, 31 or 32, 33, 34.

 It is also applicable in industrial control by acoustic emission where the large number of measurement points is a factor which makes it necessary to reduce the time and material for installing the transducers. The use of PVF 2 and piezoelectric organic polymers is particularly recommendable in acoustic missions where the sensors only work in reception.

Indeed, these piezoelectric polymers have good characteristics on reception. In addition, the possibility of depositing an adaptation layer between the transducer and the monitored surface improves the reception efficiency. Finally, the intercepted vibratory energy flow increases with the size of the sensor. According to local conditions, the invention makes it possible to produce sensors of different lengths.

 In the case where the structure tested is made of a flexible material in the course of deformation, the transducer according to the invention has the advantage of following these movements faithfully thanks to the bonding.

This is the case for use in medical surveillance to make cardiac sensors stuck on the patient's chest or for any other use, for example for monitoring pregnancy.

Claims (15)

 1. Piezoelectric transducer, characterized in that it comprises at least:  - electrical connection means (5),  - a ribbon of flexible organic material (2),  - a thin adhesive tape (1) with acoustic characteristic.  2. Transducer according to claim 1, characterized in that the piezoelectric tape is made of a polymer material.  3. Transducer according to claim 2, characterized in that the polymeric material is based on polyvinylidene fluoride (PVF 2) or polytetrafluoroethylene (PTFE).  - two terminals (5) located on the outer surface of each side of the piezoelectric tape.  - two thin metallic conductive films (1, 3) embedded without contact with each other in the piezoelectric tape,  4. Transducer according to claim I, characterized in that the electrical connection means consist of:  5. Transducer according to claim 4, characterized in that each terminal (5) has a flat part intended to be fixed to the surface of the piezoelectric tape and a claw (7) which penetrates in contact with the metallic thin film (12).  6. Transducer according to claim 1, characterized in that the thin adhesive layer (4) is constituted by a thin tape with two sticky faces, with acoustic characteristics.  7. A transducer according to claim 1, characterized in that the adhesive layer (i) consists of a coating of glue with acoustic characteristic ensuring the adaptation of impedance.  8. Transducer according to claim 7, characterized in that the adhesive is based on a cellulose support.  9. A transducer according to claim 4, characterized in that each thin metallic film (1, 3) is extended outside the strip of flexible organic material (2), laterally, by at least one electrical connection terminal.  10. Transducer according to claim 4, characterized in that each metal film (1, 3) consists of alternately conductive (23 - 25, 26 - 28) and insulating (29 - 31, 32 - 34) zones.  11. Device for implementing the transducer according to claim 1, characterized in that it comprises:  - means for storing the transducer,  - means for extracting a requested length of transducer,  means for fixing the terminals to the transducer to be cut,  - means for cutting the transducer.  12. Device according to claim 11, characterized in that the storage means comprise a drum carrying the transducer.  13. Device according to claim 11, characterized in that the means for extracting a predetermined length of transducer comprise a counter (19) for measuring the unwound length of transducer.  14. Device according to claim 11, characterized in that the means for fixing the terminals and the means for cutting the transducer to the requested length are controlled simultaneously.  15. Device according to claim 11, characterized in that the storage means of the transducer comprise a drum (13) on which is wound the flexible piezoelectric tape (17) and a drum (14) on which is wound the adhesive tape (18 ).