RU2154941C1 - Device for scaring rodents and its acoustic transducer - Google Patents

Abstract

FIELD: protection of warehouses, living apartments, acoustic signal generators. SUBSTANCE: device has power supply unit, as well as connected control unit, modulator, sweeping frequency oscillator, amplifier and acoustic transducer. Acoustic transducer is designed as wide-band and is spread over complete area of room entrance. Sweeping frequency oscillator provides possibility to change its frequency within range of 10 Hz - 40 kHz. Acoustic transducer has at least one extended member, which is made from magnetostrictive material and gas permanent magnetic field generation unit and unit for generation or receiving of alternating magnetic field. Vectors of respective magnetic fields are aligned to longitudinal axis of said member, which is mechanically connected to at least one clipper of lateral oscillations of at least two member points in direction of each of vectors of generated or received permanent and alternating magnetic fields. This ensures that central piece of member moves in perpendicular to its longitudinal axis towards direction of generation or reception of acoustic signal. EFFECT: increased efficiency of rodent scaring, generation of acoustic field with flat leading edge. 24 cl, 12 dwg

Description

 The invention relates to means of influence on rodents for the protection of warehouses, premises, etc. and means for generating an appropriate acoustic signal.

 Systems for repelling unwanted biological creatures are widely known, which include a generator, amplifier, and acoustic transducer (see, for example, USSR copyright certificates N 1457876, 1551314 and others).

 In this case, the effectiveness of scaring away is extremely small, since the biological creature becomes addicted to the repellent signal and there is no further response to it in the future.

 Closest to the claimed is a system for repelling rodents, including a power supply, as well as interconnected control panel, modulator, oscillating frequency generator, amplifier and acoustic transducer (USSR copyright certificate N 1683620). During the operation of this system, the oscillating frequency generator supplies a variable signal to the amplifier, and the modulator controls the operation of the oscillating frequency generator, which makes it possible to reduce the degree of rodents getting used to the repellent signal.

 However, the effectiveness of this system is still insufficient.

 The objective of the present invention in terms of the system is to increase its efficiency.

 This problem is solved due to the fact that in a system for scaring away rodents, including a power supply unit, as well as interconnected control panel, modulator, oscillating frequency generator, amplifier and acoustic transducer, the acoustic transducer is made broadband and is integrated over the entire area of the technological opening of the room, and the oscillating frequency generator is configured to change its frequency in the range of 10 Hz - 40 kHz.

 Moreover, it is equipped with an additional pulse-width modulator, the output of which is connected to the oscillating frequency generator, and the input is connected to the control panel.

 The control panel is advisable to perform in the form of a controller associated with read-only memory.

 In this case, the system can be equipped with a directional microphone, the output of which through the corresponding amplification unit is connected to the input of the control panel, and the microphone itself can be performed with a maximum frequency response in the range of (20-30) kHz.

 The system can be equipped with a unit for creating visual repellent signals, the input of which is connected to the control panel and / or the aerosol spray unit, the input of which is connected to the output of the control panel and / or the low-frequency vibration generating unit, the input of which is connected to the output of the control panel, the creation unit low-frequency vibration can be made in the form of an electromagnetic "ratchet".

 The system, in addition, can be equipped with an electromagnetic field generating unit, the input of which is communicated with the output of the control panel.

 In FIG. 1 is a block diagram of a rodent repellent system.

 The system for repelling rodents includes a power supply 1, as well as interconnected remote control 2, a modulator 3, a generator 4 of a pumping frequency, an amplifier 5 and an acoustic transducer 6, which is made broadband and integrated throughout the technological opening of the room (not shown), and the oscillator 4 of the pumping frequency is configured to change its frequency in the range of 10 Hz - 40 kHz. The system is also equipped with an additional pulse-width modulator 7, the output of which is connected to the oscillating frequency generator 4, and the input is connected to the control panel 2. Remote control 2, it is advisable to perform in the form of a controller 8 associated with read-only memory 9, the controller may also have a keyboard 10.

 The system is also equipped with a directional microphone 11, the output of which through the corresponding amplification unit 12 is connected to the input of the control panel 2, and the microphone 11 itself is made with a maximum frequency response in the range of (20-30) kHz.

 The system is also equipped with a block 13 for creating visual repellent signals, a block 14 for turning on the aerosol spray, a block 15 for creating a low-frequency vibration, the inputs of which are connected to the output of the control panel 2, while the block 15 for creating a low-frequency vibration can be made in the form of an electromagnetic “ratchet”.

 To increase efficiency, the system can be equipped with a block 16 for creating an electromagnetic field, the input of which is communicated with the output of the control panel 2.

 The system operates as follows.

 After turning on the power supply 1, the control panel 2 starts working according to the program, which controls the modulators 3 and 7, which specify the frequency ranges of the generator 4, the signal from which is amplified by the amplifier 5 and emitted by the acoustic transducer 6. To increase the repelling effect, blocks 13 can be turned on, creating bright light flashes, block 14, including nebulizers in the protected area, block 15, through which vibrations that repel rodents are created, and block 16, which acts on rodent receptors, are electromagnetic field, enhancing the effect of scaring. When you turn on the microphone 11, the signal emitted by rodents is amplified and fed to the remote control 2, which according to the program includes the corresponding unit from the above.

 However, the presence of an acoustic transducer (AP) 6, which can be located in the technological opening and, in addition, makes it possible to create acoustic radiation in a wide frequency range, is very significant.

 The scope of the AP 6 are technical applications that use the emission or reception of acoustic signals, such as sound, in acoustic speakers or microphones. This application is most effective in cases where the location of the AP 6 is limited either by a special form (small thickness, the ability to be integrated into body parts, etc.) or by external factors (increased pressure, humidity, temperature, etc.), see, for example, the FRG application N 3832616 A1.

Magnetostrictive acoustic transducers 6 (MAP) are widely known in the art and are based on the direct magnetostrictive effect, consisting in changing the length l of the emitter 17 when changing its magnetic state by Δl. The ratio λ = Δl / l is called magnetostriction. The value of λ for traditional magnetostrictive materials is of the order of 10 ^-4 - 10 ^-5 .

 To increase the efficiency (return) MAP 6 is used in resonance mode, mainly for radiation in a liquid, see, for example, US patent N 4642802.

To maintain "linearity" between the input signal (alternating magnetic field H _~ ) and the output signal - moving MAP 6 - use magnetization, that is, a constant magnetic field H ₌ , linearizing the dependence of λ on the alternating magnetic field.

 The relatively small value of λ limits the scope of application of MAP 6 mainly to resonant modes of radiation into the liquid, because, for example, for air, even a meter (l = 1 m) emitter 17, mounted on one side, will have a maximum displacement of the order of Δl = λl ≈ 0.1 mm (Fig. 2).

Recently, to increase the displacements of MAP 6, new magnetostrictive materials with significantly higher magnetostriction (up to 10 ^-3 ) have been used. However, these alloys are very expensive. In addition, their practical application requires the creation of very high magnetic fields.

что для параметров выше рассмотренного примера (l = 1 м, λ = 10^-4) составляет 1 см, т.е. на два порядка большую величину.It is proposed to increase the effective movement in MAP 6 for a given material and in a wide frequency range due to the introduction of at least one limiter of longitudinal displacements of the MAP 6 element - emitter 17, at least two of its points 18 (Fig. 3), and the displacement limit in the direction of each of the vectors generated or received direct and alternating fields, which are realized by means 19 for creating a permanent magnetic field (H ₌₎ and means 20 for generating or receiving a magnetic alternating n la (H _~).
In this case, the displacement of the middle part of element 17 of MAP 6, as shown by calculations confirmed by experimental studies, is of the order of

that for the parameters of the above example (l = 1 m, λ = 10 ^-4 ) is 1 cm, i.e. two orders of magnitude larger.

 To achieve this effect, the element 17 of the MAP 6 must have a length, i.e. be made in the form of a plate or rod (string) with a ratio of thickness (diameter) to length of the order of 0.01 - 0.001.

 The limiter as a structural element can be performed in various ways.

For example, for a radiator 17 ⁺ made of a material with positive magnetostriction (see Fig. 4), the limiter can be the same element 17 ^- connected to the element 17 ⁺ at a number of points (at least at two points), but made of negative magnetostrictive material.

In FIG. 5 shows the results of measurements of oscillations of the composite member made of Fe-Co alloy (17 ⁺⁾ and nickel (17 ^-) with common windings 19 and 20. The length of each of the elements 17 and 17 ^{+ -} - 300 mm, thickness - 0.15 mm

 Another structural element that acts as a limiter of longitudinal vibrations can be an inertial mass 21 "m" located at least at one end of an extended element 17 (Fig. 6). In addition to the transverse movement of the middle part of the element 17, the consequence of this decision is the transfer (reception) of force to the base 22.

 To increase the level of radiation (reception) of sound, a more developed surface is needed than the side surface of MAP 6.

 Therefore, when performing a limiter in the form of a membrane 23 (Fig. 7) connected to an extended element 17, at least at two points 18, MAP 6 turns into a rather effective sound source (receiver). The sound quality is improved if, along with the membrane 23, a limiter in the form of a rigid frame 24 (Fig. 8) is used, to which the membrane 23 is attached (glued).

 The frequency response of the sound source (receiver) shown in FIG. 7, with a frame size of 100 x 60 mm, is shown in FIG. nine.

 It is noteworthy that this characteristic practically does not change under the influence of moisture and temperature (immersion in hot water, etc.) while fulfilling the obvious requirements for the material of the membrane 23, frame 24 and insulation of the winding (their heat and moisture resistance). Most modern microphones and speakers designed to work in the air are very sensitive to changes in external climatic conditions.

 With an increase in sensitivity (volume) by increasing the length of the element 17 to maintain linearity (sound quality), the element 17 together with the membrane 23 is installed with a deflection, the value of which does not exceed 15% of its length, and the element 17 itself is spring-loaded in the direction of this deflection by the elastic elements 25 (Fig. 10).

 The analysis shows that there is an optimal value of springing and deflection in terms of volume and linearity for each combination of parameters of the MAP 6 elements and its structural environment.

 The efficiency of using the membrane 23 as a radiating surface increases with a decrease in the work of the forces stretching the membrane in the direction of the axis of the element 17. This can be achieved by reducing the stiffness of the membrane 23 in the direction of the axis of the element 17 compared to its rigidity in the direction perpendicular to the axis of the element 17 (in membrane plane). Such a mechanical anisotropy of the properties of the membrane 23 is realized, for example, by its corrugation (see Fig. 10).

 To expand the frequency range, especially in the high-frequency region, the reduction in the mass of element 17 of MAP 6, including due to the mass of the winding. In the case of the special use of certain types of amplifiers for a sound source (Fig. 11) or the use of the residual magnetization of the material of the MAP element 6 in the range (1.05-1.2) T for a sound receiver (Fig. 12), it is possible to solve the problem using one (and only) winding 26.

 In modern amplifiers, circuits of class AB and B are used, in which there is a constant voltage approximately equal to half the supply voltage E to the isolation capacitor C at point A (Fig. 11).

 This constant voltage E / 2 can be used to create a constant magnetic field (magnetization).

 Thus, from the output stage, consisting, for example, of transistors of different conductivity T1 and T2, there are voltages on the same winding 26 of MAP 6, which create constant and alternating magnetic fields.

 Naturally, in this case, the isolation capacitor C (shown in FIG. 11 by a dashed line) is excluded from the circuit.

 When used as means for creating a constant magnetic field and means for creating (receiving) an alternating magnetic field of two galvanically isolated windings 19, 20 in FIG. 3, 4, located on the element 17 and connected with the corresponding current sources (amplifiers), the possibility of controlling the sensitivity and linearity of MAP 6 is expanded.

 Naturally, to create a constant magnetic field in MAP 6, a permanent magnet of the corresponding configuration can also be used.

Compared with the known acoustic transducers operating in the audio frequency range, the proposed transducer has the following main advantages:
allows to significantly reduce weight and size indicators;
provides easy integration into household items - partitions, furniture, photo frames, etc .;
more resistant to external mechanical and climatic influences, for example, it can work in conditions of elevated and low temperatures, high humidity: in vegetable stores, warehouses and other premises that are potentially attractive to rodents, a pool, outdoors in the rain, etc .;
allows you to get a distributed source (receiver) of sound, the dimensions of which are commensurate with the dimensions of the voiced room; the sound level in this case, to a first approximation, weakly depends on the distance to the source within this room;
allows you to save the broadband nature of radiation in one element.

 The application of the proposed magnetostrictive acoustic transducer allows high-efficiency and easy-to-manufacture emitters and receivers of acoustic vibrations to be implemented, which can be performed in a wide range of linear sizes (from a few centimeters to several meters), while maintaining a minimum size in thickness (of the order of a millimeter) and resistance to external influences (temperature, pressure, humidity).

Claims (24)

 1. A system for repelling rodents, including a power supply unit, as well as a connected control panel, modulator, oscillating frequency generator, amplifier and acoustic transducer, characterized in that the acoustic transducer is made broadband and is integrated over the entire area of the technological opening of the room, and the oscillator frequency is configured to change its frequency in the range of 10 Hz - 40 kHz.  2. The system according to claim 1, characterized in that it is equipped with an additional pulse-width modulator, the output of which is connected to the oscillating frequency generator, and the input is connected to the control panel.  3. The system according to claim 1, characterized in that the control panel is made in the form of a controller associated with a read-only memory device.  4. The system according to claim 1, characterized in that it is equipped with a directional microphone, the output of which through the corresponding amplification unit is connected to the input of the control panel.  5. The system according to claim 1, characterized in that the microphone is made with a maximum frequency response in the range of 20 - 30 kHz.  6. The system according to claim 1, characterized in that it is equipped with a unit for creating visual repellent signals, the input of which is connected to the control panel.  7. The system according to claim 1, characterized in that it is equipped with an aerosol atomizer switching unit, the input of which is in communication with the output of the control panel.  8. The system according to claim 1, characterized in that it is equipped with a low-frequency vibration generating unit, the input of which is connected to the output of the control panel.  9. The system according to claim 1, characterized in that the unit for creating low-frequency vibration is made in the form of an electromagnetic “ratchet”.  10. The system according to claim 1, characterized in that it is equipped with a unit for creating an electromagnetic field, the input of which is communicated with the output of the control panel.  11. An acoustic transducer comprising at least one main extended element of magnetostrictive material with means for creating a constant magnetic field and means for generating or receiving an alternating magnetic field whose vectors coincide with the longitudinal axis of this element, the latter being mechanically connected with at least one limiter of longitudinal displacements of at least two of its points in the direction of each of the vectors of the generated or received constant and variable m gnitnogo field movably median part of the element perpendicular to its longitudinal axis in the direction of generating or receiving an acoustic signal.  12. The Converter according to claim 11, characterized in that the main extended element is made in the form of a rod.  13. The Converter according to claim 11, characterized in that the main extended element is made in the form of a plate.  14. The Converter according to claim 11, characterized in that the main extended element is made in the form of a string.  15. The Converter according to claim 11, characterized in that the limiter is made in the form of a rigid frame mechanically connected to the two ends of the main extended element.  16. The Converter according to item 13, characterized in that it is equipped with an additional element of magnetostrictive material, with a magnetostriction sign opposite to the magnetostriction sign of the material of the main extended element, and mechanically connected at least at two points with the main extended element.  17. The Converter according to claim 11, characterized in that the part of the movement limiter is made in the form of at least one inertial mass connected to the corresponding end of the extended element.  18. The Converter according to claim 11, characterized in that the limiter is made in the form of a membrane with which the extended element is connected at least at two points.  19. The Converter according to claim 11, characterized in that the element is installed with a deflection, the value of which does not exceed 15% of the length of the element, and the element itself is spring-loaded in the direction of this deflection.  20. The Converter according to claim 11, characterized in that the means for creating a constant magnetic field and the means for generating or receiving an alternating magnetic field are made in the form of corresponding individual windings located on the element and connected to respective current sources or amplifiers.  21. The Converter according to claim 11, characterized in that the means for creating a constant magnetic field and means for generating an alternating magnetic field are made in the form of a common winding located on the element and connected to the output of the corresponding current amplifier.  22. The Converter according to claim 11, characterized in that the means for creating a constant magnetic field is made in the form of at least one permanent magnet.  23. The Converter according to claim 11, characterized in that the magnetostrictive material of the element itself, having a residual magnetization of at least (1.05 - 1.2) T, is used as a means to create a constant magnetic field.  24. The Converter according to p. 18, characterized in that the membrane is made with anisotropy of mechanical properties and its rigidity in the direction of the longitudinal axis of at least one extended element is less than in the direction perpendicular to the axis of this element.

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