ES2365901A1 - Ultrasonic transducer. (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Ultrasonic transducer, characterized in that It comprises: four coils forming a pair of Helmholtz coils, a flexible multilayer membrane located in the center of the pair of Helmholtz coils, comprising the flexible membrane at least a layer of a material with piezoelectric properties and another layer of a material with magnetoelectric properties, and an encapsulation to keep the Helmholtz and membrane coils together.

Description

Ultrasonic transducer

The present invention refers to a ultrasonic transducer

Ultrasonic transducers convert a electrical signal 1 at ultrasonic frequencies in a pressure signal acoustics that propagates through the air.

The present invention discloses a Ultrasonic transducer with a new construction that provides advantages and new features over those currently existing.

An objective of the present invention is to give know an ultrasonic transducer in which you can do without Its construction of magnetic components.

Another objective of the present invention is to give know a transducer that, thanks to its construction three-dimensional, allows focusing without using lenses Sonic or parametric arrays.

Another objective of the present invention is to give know an ultrasonic transducer that has a lower consumption of energy compared to currently existing transducers.

Another additional objective of the present invention is to present an ultrasonic transducer that allows a large coverage and great directionality in ranges in which the commercially available transducers lack enough accuracy.

In particular, the present invention consists of an ultrasonic transducer comprising:

- four identical coils forming a pair of helmholtz coils,

- a multilayer flexible membrane located in the center of the Helmholtz coil pair, the flexible membrane comprising at least one layer of a material with piezoelectric properties and another layer of a material of magnetoelectric properties
cas, and

- an encapsulation to keep the coils of Helmholtz and membrane attached.

Preferably, the membrane consists of a four layer structure, two layers a nature material magnetoelectric, (preferably FeBSiC), and two layers of piezoelectric nature (preferably P (VDF-TrFe)). Preferably, the layers of the membrane remains dimorphically bonded, so that they remain in contact with each other the faces of the layers with opposite polarity.

In this structure, the application of a field magnetic to the membrane will cause elongation of one of the layers magnetoelectric and the contraction of the other, curving the membrane, product of surface tensions (tangential) created on the same. In turn, the application of an electric field on the piezoelectric layers will cause another curvature effect on the membrane in the same direction. In this way, applying a field Continuous electrical or magnetic a curved element is constructed to from the membrane. The curvature formed in the membrane has two functions: first, a superficial expansion or contraction of the membrane supposes, due to the curvature, a displacement of the same in the third dimension, thus creating a pressure field in the air. Second, the variation of the curvature of the membrane according to the electric field and intensity applied allows adjust the focal point of the curved element which means power Define a focus gain of the transducer. The result of "focus" ultrasound is that these will produce greater intensity at short distances and rapid dispersion of sound beyond focus point, which converts the transducer into a device Short distance, characteristic required in certain Applications. The present invention allows to use the phenomenon known in English as "scattering sound by sound", which it consists of sending information modulating an ultrasonic carrier and take advantage of the demodulation exerted by the air on the ultrasound in order to obtain audible sounds. The value of this resonance in turn allows an acceptable size for small transducers By mounting magneto-piezoelectric get high membrane tensions with the application of magnetic fields of small magnitude, which require significantly lower voltages to those required to generate the same membrane voltage only with application of electric field on the layer piezoelectric This effect is due to the interaction of tensions. between the magnetoelectric and piezoelectric layers.

The Helmholtz coil consists of the facing and parallel arrangement of two coils with the same identical radios, spaced between them that same radius with the in order to create a uniform magnetic field normal to the coils in where the membrane will be positioned. This magnetic field creates some tensions on the magnetoelectric layers which will cause high voltages in the piezoelectric layers. To create the curvature therefore, a polarization voltage is applied continuous, and then applying another alternating voltage are achieved generate ultrasound as explained above. Preferably, the coils will have the same radius as the membrane. In this way a maximum transduction of voltage over the piezoelectric layer maintaining a size minimized for the transducer. In use, preferably, the frequency of the alternating magnetic field of polarization must be equal to the resonant frequency of the membrane for a maximum transduction These AC and DC voltages are preferably applied to the coils are also applied on the membrane to increase the tension in the piezoelectric layers, thus increasing The pressure generated. Although this tension is significantly less than that produced by the fields magnetic, this step provides capacitive reactance to the transducer impedance since pure inductive loads such as the coils can cause voltage spikes during ignition or stop (due to DC voltage) that can damage the amplifier of transducer control The usual solution is then to add a circuit capacitor

The encapsulation holds the coils and the membrane in the correct position, but it can also prevent ultrasonic dispersion on the sides. This dispersion is secondary with respect to focused ultrasound since, although the Helmholtz coil evenly distributes the magnetic field to along its axis being constant in the center of the membrane, in the area closest to the coils the amplitude of the magnetic field is slightly lower Due to this fact greater tensions are created in the zone of greater freedom of movement of the membrane, the zone close to the center of the membrane, and lower tensions in the areas that limit with the encapsulation, concentrating even more the ultrasound in the acoustic axis.

For a better understanding of the invention, attached to the title of explanatory example but not limiting, some drawings of an embodiment of the present invention.

Figure 1 is a perspective view exploded of a transducer according to the present invention.

Figure 2 is a perspective view schematic of the transducer of figure 1, with the components mounted.

Figure 3 shows another perspective view exploded in which the arrangement of elements can be observed that fix the membrane.

Figure 4 shows a perspective view exploded in which the central layout is shown in detail Of elements.

In figure 5 it has been represented in a way Schematic way of joining way.

Figure 6 is another exploded view of the transducer, from a different point of view.

The transducer shown in the figures is composed of three elements: four identical coils, (1), (2), (3), (4) to form two pairs of Helmholtz coils, one thin membrane (9) formed by several layers of different properties and the encapsulated (5), (6) to maintain the Helmholtz coils (1), (2), (3), (4) and membrane (9) attached.

The membrane (9) of the example consists of a four-layer structure, two layers of Metaglas, a material of Magnetoelectric nature, whose composition is FeBSiC, and two layers of P (VDF-TrFe) of piezoelectric nature. The layers are dimly bonded, so that they adhere with epoxy resin the faces with opposite polarity forming a flexible element. The application of a magnetic field to the membrane will cause the elongation of one of the magnetoelectric layers and the contraction of the other, curving the membrane, product of the surface tensions (tangential) created on it. To its time, the application of an electric field on the layers piezoelectric will cause the same curvature effect on the membrane in the same direction. In this way, applying a field Continuous electrical or magnetic a curved element is constructed to from the membrane.

The resonance of the membrane (9) is defined by its mass, thickness and, above all, its size, which can be adjusted according to function. The example transducer is designed to have a resonance around 60 kHz. The present invention makes it possible to use the phenomenon known in English as "scattering sound by sound", which consists in sending information modulating an ultrasonic carrier and taking advantage of the demodulation exerted by the air on the ultrasound in order to obtain audible sounds. The value of this resonance in turn allows an acceptable size for small transducers. The magneto / piezoelectric assembly achieves high membrane tensions with the application of magnetic fields of small magnitude, which require voltages significantly lower than those required to generate the same membrane voltage only with application of electric field on the piezoelectric layer. This effect is due to the interaction of tensions between the magnetoelectric layers and the
piezoelectric

Coils (1), (2), (3), (4) are used to form a coil of Helmholtz. As seen in the figures, two coils are positioned facing each other and parallel with them identical radios, spaced between them that same radius with the in order to create a uniform magnetic field normal to the coils in where the membrane will be positioned. This magnetic field creates some tensions on the magnetoelectric layers which will cause high voltages in the piezoelectric layers. To create the curvature from the membrane a continuous polarization voltage is applied, and then applying another alternating voltage we will generate ultrasound as explained above. The reels (1), (2), (3), (4) of the example are chosen and / or designed to create a magnetic field that provides maximum magnetoelectric effect with the minimum necessary voltage and with approximately the same radius than the membrane, this for maximum voltage transduction over the piezoelectric layer maintaining the size required for the transducer The frequency of the alternating magnetic field of polarization must be equal to the resonant frequency of the membrane (9) for maximum transduction. These AC and DC voltages applied to the coils (1), (2), (3), (4) are also applied on the membrane (9) to increase the tension in the layers piezoelectric, thus increasing the pressure generated. In spite of that this tension is significantly less than that produced by effect of magnetic fields, this step provides reactance capacitive to transducer impedance since loads pure inductors such as coils can cause voltage spikes during power on or off (due to DC voltage) that can damage The transducer control amplifier. The usual solution is Then add a capacitor to the circuit.

The encapsulation (5), (6) holds together the coils (1), (2), (3), (4) and the membrane in the correct position (9). A smooth plastic material may be preferred since thus the reflection of ultrasonic frequencies is greater and, in turn, the directivity of the transducer is increased due to the fact that prevents the dispersion of ultrasound on the sides. This dispersion is secondary with respect to focused ultrasound since, although the Helmholtz coil evenly distributes the magnetic field along its axis being constant in the center of the membrane, in the area closest to the coils the amplitude of the magnetic field is slightly lower. Because of this fact it create greater tensions in the area of greater freedom of movement of the membrane, the area near the center of the membrane, and smaller tensions in the areas that limit the encapsulation (5), (6), ultrasound concentrating even more on the acoustic axis. He encapsulated consists of two parts (5), (6) containing two coils each of them, and these two parts are joined together with a plug configuration (11) - hollow (12) (pin-hole setup). One of the pieces has "pins" (11) of plastic that fit exactly with the holes of the other part (12). This lace system is located exactly in the middle of the transducer since they "pins" (11) are used to hold the membrane (9) just between the two pieces and in turn to polarize the membrane by two thin layers of metal (7), (10) located at the ends that form The lace of each piece.

The metal layers (7), (10) polarize the membrane transversely while the coils, as we have commented above, they will do so longitudinally.

One end of the transducer can fill with porous material parallel to the membrane. This extreme will correspond to the rear of the transducer to reduce the ultrasonic dispersion in it. The encapsulation is closed by back with an open circular door to prevent compression of the rear air similar to the speakers Bassreflex

All coils and metal polarizer of membrane (which will act as a capacitive element) will be preferably connected in parallel to achieve the minimum transducer supply voltage. One reason why set two coils of Helmholtz (1), (2), (3), (4) is that the resulting magnetic field must be applied in both directions x e and to create a normal directivity pattern to the membrane symmetrical in both axes. The membrane is held by the pins (11) of the front piece (5) when inserted into the holes of the piece rear (6). Its location corresponds to the center of all coils so that it benefits the most from the magnetic field created.

In general, everything that does not affect, alter, change or modify the essence of what is described, it will be understood within the present invention.

Claims (13)

1. Ultrasonic transducer, characterized in that it comprises: - four coils forming a pair of coils of Helmholtz, - a flexible multilayer membrane located in the center of the pair of Helmholtz coils, comprising the membrane flexible at least one layer of a material with properties piezoelectric and another layer of a property material magnetoelectric, and - an encapsulation to keep the coils of Helmholtz and membrane attached. 2. Transducer according to claim 1, characterized in that the membrane comprises four layers. 3. Transducer according to claim 2, characterized in that it comprises two layers with magnetoelectric properties and two layers with piezoelectric properties. 4. Transducer according to any one of claims 1 to 3, characterized in that the layers are distributed so that layers of opposite polarity are brought into contact with each other. 5. Transducer according to any one of claims 1 to 4, characterized in that the four coils are identical. 6. Transducer according to any of claims 1 to 5, characterized in that the membrane has the same diameter as the coils. 7. Transducer according to any one of claims 1 to 6, characterized in that it applies the voltage applied to the coils on the membrane. 8. Transducer according to any one of claims 1 to 7, characterized in that the encapsulation is arranged to prevent ultrasonic dispersion on the sides. 9. Transducer according to claim 8, characterized in that the encapsulation is formed by two parts of smooth plastic joined together with a pin-hollow configuration in which the membrane is also fastened. 10. Transducer according to any of claims 1 to 9, characterized in that it has metallic layers in contact with the membrane, to polarize it. 11. Transducer according to any one of claims 1 to 10, characterized in that one end of the encapsulation is filled with a porous material parallel to the membrane, the encapsulation ending at said end in an open circular door. 12. Transducer according to any one of claims 1 to 11, characterized in that the material with piezoelectric properties is P (VDF-TrFe) 13. Transducer according to any of claims 1 to 11, characterized in that the material with magnetoelectric properties is FeBSiC.