RU49363U1 - Piezoelectric Acoustic Transducer (OPTIONS) - Google Patents

Abstract

The utility model relates to piezoelectric ceramic bend converters and serves to convert electrical energy into mechanical energy in order to create vibrational vibrations masking an informative signal. The piezoceramic transducer includes a metal membrane coated with a dielectric layer, made with a protrusion on the periphery, through which it is rigidly connected to the inertial element and rigidly connected to the piezoceramic disk through the plate. The membrane is equipped with a protrusion for rigid attachment to the building structure, and the plate and piezoceramic disk are installed with the possibility of supplying an electrical signal. A second embodiment of the converter is also proposed, which through a protrusion on the membrane is rigidly connected to a mechanical resonator containing a second inertial element connected peripherally to a cylindrical element, the base of which is an elastic membrane. On the outer side of the membrane in the central part there is a protrusion for rigid attachment to the building structure.

Description

The utility model relates to piezoelectric ceramic bend converters and serves to convert electrical energy into mechanical energy in order to create vibrational vibrations masking an informative signal.

From the patent literature known vibration masking sound system that hides sounds in a room or building by creating vibrations of parts of the structure, including a sound generator (US Patent No. 4098370, CL N 05 K 5/00 from 1978).

The main disadvantage of the known vibration transducer is the use of acoustic waves to excite vibrational vibrations. Such a vibration converter does not guarantee interference with a given amplitude-frequency characteristic.

Closest to the proposed utility model is an electro-acoustic transducer comprising a cylindrical housing, an autonomous ring transducer assembly made in the form of an annular disk consisting of two fastened annular plates provided with an inertial element mounted between cylindrical elements in the housing. The first plate is an element that acquires piezoelectric properties under the influence of the direct current polarization potential and has transverse dimensions, which can change under the action of an alternating current conducting means of acting by the said direct current polarization potential on the first plate. The second plate is made of metal, while its transverse dimensions do not change under the influence of alternating current, and has

a sectioned electrode connected to a source of direct current polarization potential and having the opposite polarity when polarizing this element (see US Patent No. 2967957 CL 310-9.4, from 1961).

The transducer serves to excite vibrational vibrations in an environment with low acoustic impedance. The disadvantages of this known device include a complex system for transmitting oscillations of a piezoelectric element.

The technical task of the proposed utility model is to create a device with a simple design for protection against leakage of sound information by exciting vibrational vibrations in various massive building structures on which it is fixed (walls, columns, ceilings, beams, etc.), providing a given amplitude -frequency response.

The stated technical problem is achieved due to the fact that the proposed piezoelectric acoustic transducer, made with the possibility of fixing on a building structure, containing a metal membrane made with a protrusion on the periphery, through which it is rigidly connected to an inertial element, on the side of which is covered by a dielectric layer and rigidly connected with a piezoceramic disk, and on the opposite side the metal membrane in its central part is provided with a protrusion for rcoh fixing to a building structure, wherein the plate and the piezo ceramic disc mounted to an electric signal. The height of the piezoceramic disk h is in the range from 0.25 mm to 0.5 mm, and its

the diameter D ranges from 18 mm to 28 mm; an alumina layer is used as the dielectric.

To increase the amplitude of oscillations in the high frequency region, a second embodiment of the proposed utility model is presented, in which the converter contains a mechanical resonator.

According to a second embodiment, the piezoelectric acoustic transducer comprises a metal membrane made with a protrusion on the periphery, by means of which it is rigidly connected to the first inertial element, on the side of which is covered by a dielectric layer and rigidly connected to the piezoceramic disk, and on the opposite side, the metal membrane is provided with a protrusion, on which a mechanical resonator is rigidly fixed, containing a second inertial element connected peripherally to a cylindrical an element whose base is an elastic membrane, the outer side of which in the central part is provided with a protrusion for rigid attachment to a building structure. The height of the piezoceramic disc h is in the range from 0.25 mm to 0.5 mm, and its diameter D is in the range from 18 mm to 28 mm.

The natural frequency of the mechanical resonator corresponds to the upper boundary purity of the working range of the device. These converters are designed to excite vibrational vibrations in building structures with increased attenuation of vibrational vibrations in the high frequency region.

The drawings show two embodiments of the utility model.

Figure 1 depicts a diagram of a piezoelectric acoustic transducer (first option);

Figure 2 - embodiment of the Converter with a mechanical resonator (second option).

The piezoelectric acoustic transducer (the first option) includes an inertial element 1 (Figure 1), which is rigidly connected to the metal membrane 3 through the protrusion 2, made on its periphery. The membrane 3 is coated with a dielectric layer 4 and through the plate 5 is rigidly connected to the piezoceramic disk 6, for example, a layer of glue, which has high rigidity. The plate 5 and the piezoceramic disk 6 are installed with the possibility of supplying an electrical signal through a supply cable 7 with a connector 8 located in the fitting 9 made in the protrusion 2. On the opposite side of the inertial element 1, the metal membrane 3 is provided with a protrusion 10 for rigid mounting to the building structure 11 through the axial element 12.

The piezoelectric acoustic transducer according to the second embodiment includes a metal membrane 3 (FIG. 2) with a protrusion 2 on the periphery, by means of which it is rigidly connected to the first inertial element 1, from the side of which is covered with a dielectric layer 4. The membrane 3 is rigidly connected to the a piezoceramic disk 6, and on the opposite side is provided with a protrusion 10, on which a mechanical resonator is rigidly fixed. The resonator contains a second inertial element 13 connected peripherally with a cylindrical element 14, the base of which is an elastic membrane 15, the outer side of which

the central part is equipped with a threaded protrusion 16, which through the axial element 12 is rigidly attached to the building structure 11.

The amplitude-frequency characteristic of the converter is formed in such a way as to maximize compensate for the unevenness of the amplitude-frequency characteristic of the propagation of vibrational vibrations in building structures at a considerable distance from the converter.

The principle of operation of a piezoelectric acoustic transducer. Using an axial element 12 for rigid fastening, for example, an expansion bolt shield with an internal thread, the converter is rigidly attached to the excited building structure 11. An electrical signal is supplied to the converter through connector 8. Due to the transverse piezoelectric effect, the piezoceramic disk 6 of the transducer performs radial vibrations, which through a thin (0.1-0.2 mm) plate 5, a layer of dielectric 6 and adhesive (0.01 mm) cause tangential deformation of the inner surface of the membrane 3, which makes make bending vibrations. The oscillating membrane 3 fixed in the center causes oscillatory movements in the axial direction of the inertial element 1, which is rigidly connected with the protrusion 2 made on the periphery of the membrane 3. The vibrational accelerations of the inertial element 1 create an alternating force directed along the axis of the transducer, causing vibration of the building structure 11, which it is fixed.

To excite vibrational vibrations in building structures with increased attenuation of high-frequency vibrations to a piezoceramic

the acoustic transducer through the axial element 10 by means of a threaded connection is attached to a mechanical resonator. At low frequencies, the mechanical vibrations generated by the transducer act on the resonator, and due to the high rigidity of its design, they are transmitted without changes to the axial element 12, and then to construction 11. With increasing frequency of the excitation force generated by the transducer, and approaching the value of the resonant frequency , there is a rapid increase in the oscillation amplitude of the resonator, due to compensation of the elastic component of the impedance of the inertial component. At the resonant frequency, the oscillation amplitude of the resonator reaches a maximum and rapidly decreases with a further increase in frequency. The additional force acting on the excited structure due to the use of the resonator makes it possible to compensate for the loss of high-frequency components of mechanical vibrations in the material of the excited structure.

The main distinguishing features of the piezoelectric acoustic transducer.

1. The converter is designed to operate as part of active information protection systems and is a resonant mechanical system whose natural frequency, determined by the value of the inertial mass and membrane stiffness, corresponds to the lower boundary frequency of the operating range.

2. The amplitude-frequency characteristic of the coefficient of the electromechanical coupling of the converter is formed in such a way as to ensure maximum compliance with the spectrum of vibrational accelerations excited in

protected structures, the spectrum of the electrical signal supplied to the input of the Converter.

3. To create an axial alternating force, bending vibrations of the membrane are used, rigidly connected along the periphery with the inertial mass, excited by creating tangential mechanical stresses on the inner surface of the membrane.

4. The tangential mechanical stresses of the membrane are created by radial vibrations of the piezoceramic disk rigidly connected with it due to the transverse piezoelectric effect.

5. To create maximum radial forces, thin (h = 0.25 ÷ 0.5 mm) with a large diameter (D = 18 ÷ 28 mm) piezoceramic discs made of TsTSNV-1 piezoceramics are used (see "Designing sensors for measuring mechanical quantities ”under the editorship of 1. so-called professor EP Osadchy publishing house“ MECHANICAL ENGINEERING ”, Moscow, 1979), which has the best combination of the transverse piezoelectric module value and the electromechanical coupling coefficient k = 0.7.

6. To ensure electrical isolation of the external surfaces of the converter from the electrical voltage of the supplied signal, a thin layer of aluminum oxide is applied, which is deposited on the membrane surface by an electrochemical method.

7. Two types of dowels are used for fixing the transducer, vibration gears and mechanical matching of the transducer with the medium (various materials of building structures): steel стальной 8 * h36 or duralumin ⌀ 12 * h50.

8. To work on building structures with high losses of vibrational vibrations in the high frequency region, an additional mechanical resonator is installed on the converter to amplify the high-frequency component of vibrational vibrations.

Claims (5)

1. A piezoelectric acoustic transducer configured to be mounted on a building structure and comprising a piezoceramic disk, a metal membrane and an inertial element, characterized in that the metal membrane is made with a protrusion on the periphery, by means of which it is rigidly connected to the inertial element, on the side of which is coated with a dielectric layer and through the plate is rigidly connected to the piezoceramic disk, and on the opposite side the metal membrane in its central part is provided protrusion for rigid attachment to a building structure. 2. The piezoelectric acoustic transducer according to claim 1, characterized in that the height of the piezoelectric disk h is in the range from 0.25 to 0.5 mm, and its diameter D is in the range from 18 to 28 mm. 3. The piezoelectric acoustic transducer according to claim 1, characterized in that a layer of alumina is used as the dielectric. 4. A piezoelectric acoustic transducer configured to be mounted on a building structure and comprising a piezoceramic disk, a metal membrane and at least one inertial element, characterized in that the metal membrane is made with a protrusion on the periphery, through which it is rigidly connected to the first inertial element , on the side of which it is covered with a dielectric layer and through the plate is rigidly connected to the piezoceramic disk, and on the opposite side, the metal membrane is equipped with ene protrusion which is rigidly fixed mechanical resonator comprising a second inertia member connected peripherally to the cylindrical member, whose base is an elastic membrane, the outer side of which a central part provided with a projection for rigid attachment to a building structure. 5. The piezoelectric acoustic transducer according to claim 2, characterized in that the height of the piezoelectric disk h is in the range from 0.25 to 0.5 mm, and its diameter D is in the range from 18 to 28 mm.