Hydroacoustic device

Abstract

The invention relates to hydroacoustics and more specifically to hydroacoustic devices comprising, disposed in a single housing, a converter of liquid-medium oscillations and electrical signals, capable of receiving and/or transmitting hydroacoustic signals, the converter being disposed on a board which is connected to a switch cable for providing power and transmitting electrical signals, and may be used as a receiver and/or transmitter of hydroacoustic signals in water. According to the invention, the housing of the to hydroacoustic device is formed by the outer surfaces of the converter and board, and by a protective material which coats all of said surfaces, said material allowing for a transmission of hydroacoustic oscillations and being capable of transitioning from a highly-elastic or viscous-flow state to a solid state. The achieved technical result consists in simplifying the design of the device.

Claims

1. A hydroacoustic device adapted to be used in a liquid medium, the hydroacoustic device comprising, disposed in a single waterproof housing: a converter of liquid-medium oscillations and electrical signals, the converter being capable of receiving and/or transmitting hydroacoustic signals, the converter having a cylindrical shape, a first disk-shaped printed or wire circuit board comprising a receive/transmission signal path connected to a switch cable for providing power and transmitting electrical signals, a diameter of the first disk-shaped printed or wire circuit board being equal to a diameter of the cylindrical-shaped converter, the first disk-shaped printed or wire circuit board being adapted to be used as a structural support element of the single housing, a second disk-shaped printed or wire circuit board, the second disk-shaped printed or wire circuit board having a diameter equal to a diameter of the cylindrical-shaped converter, and a protective material allowing for a transmission of hydroacoustic oscillations and being a waterproof compound, wherein the cylindrical-shaped converter comprises a first base disposed on the first disk-shaped printed or wire circuit board, and a second base disposed on the second disk-shaped printed or wire circuit board, wherein each of the first disk-shaped printed or wire circuit board and the second disk-shaped printed or wire circuit board comprises a first outer surface oriented away from the converter and a second inner surface oriented toward the cylindrical-shaped converter, wherein the cylindrical-shaped converter comprises a first inner surface oriented toward the first and second disk-shaped printed or wire circuit boards and a second outer surface oriented away from the first and second disk-shaped printed or wire circuit boards, wherein the single waterproof housing of the hydroacoustic device comprises: the first outer surface of the first disk-shaped printed or wire circuit board, the first outer surface of the second disk-shaped printed or wire circuit board, the second outer surface of the cylindrical-shaped converter, and the protective material which coats all of the first outer surface of the first printed or wire circuit board, the first surface of the second printed or wire circuit board, and the second outer surface of the cylindrical converter, wherein the hydroacoustic device comprises a support rod positioned only inside the single housing between the first inner surface of the converter and the second inner surface of the board and extending from the second inner surface of the first disk-shaped printed or wire circuit board to the second inner surface of the second disk-shaped printed or wire circuit board, the support rod being positioned to additionally support a load resulting from an external pressure of the liquid medium to end surfaces of the single housing.

2. The hydroacoustic device according to claim 1, wherein the device comprises an interlayer metallization sealing disposed between the first inner surface of the cylindrical-shaped converter and the second inner surface of each of the first and second disk-shaped printed or wire circuit boards.

3. The hydroacoustic device according claim 2, wherein the single housing comprises an external metallization sealing disposed between the second outer surface of each of the first and second disk-shaped printed or wire circuit boards and the second outer surface of the cylindrical-shaped converter and, the external metallization sealing being opposite to the interlayer metallization sealing.

4. The hydroacoustic device according to claim 1, wherein each of the first and second disk-shaped boards is a printed board.

5. The hydroacoustic device according to claim 1, wherein each of the first and second disk-shaped boards is a wire circuit board.

6. The hydroacoustic device according to claim 1, wherein the device is capable of operating at a 150 m depth of the liquid medium.

7. The hydroacoustic device according to claim 1, wherein the first disk-shaped printed or wire circuit board comprises at least one of following apparatuses: (a) power amplifier; (b) input pre-amplifier; (c) input and output band pass filters; (d) analog-to-digital converter; (e) digital-to-analog converter; (f) digital signal processor.

8. The hydroacoustic device according to claim 1, wherein the single housing comprises a rubber seal introduced between the cylindrical-shaped converter and the first disk-shaped printed or wire circuit board.

9. The hydroacoustic device according to claim 1, wherein the single housing comprises a mounting slot formed into the protective material.

Description

BRIEF DESCRIPTION OF DRAWINGS

(1) Other distinguishing features and advantages of the invention are readily apparent from the description below which includes but is not limited to the following features, with reference to the figures attached:

(2) FIG. 1 represents schematically an external side view of a hydroacoustic device, in its hemispheric realization, according to the invention,

(3) FIG. 2 represents schematically an A-A vertical section of the hydroacoustic device, in its hemispheric realization, according to the invention,

(4) FIG. 3 represents schematically an external side view of a hydroacoustic device, in its cylindrical realization, according to the invention,

(5) FIG. 4 represents schematically an A-A vertical section of the hydroacoustic device, in its cylindrical realization, according to the invention,

(6) FIG. 5 represents schematically a B-B horizontal section of the hydroacoustic device, in its cylindrical realization, according to the invention,

(7) FIG. 6 represents operating stages of the hydroacoustic device according to the invention.

(8) FIGS. 1-5 show:

(9) 1—protective material,

(10) 2—printed or wire circuit board with elements and/or receive/transmission path,

(11) 2′—additional printed or wire circuit board (embodiment of FIGS. 3-5)

(12) 3—rubber seal,

(13) 4—converter,

(14) 4a—lower base of the converter (embodiment of FIGS. 3-5),

(15) 4b—upper base of the converter (embodiment of FIGS. 3-5),

(16) 5—assignment for a switch cable for providing power and transmitting electrical signals,

(17) 6—interlayer metallization sealing,

(18) 7—external metallization sealing,

(19) 8—mounting slot,

(20) 9—support rod,

(21) 10—switch cable for providing power and transmitting electrical signals.

(22) According to FIGS. 1-5, the hydroacoustic device comprises, disposed in a single housing, a converter 4 of liquid-medium oscillations and electrical signals, capable of receiving and/or transmitting hydroacoustic signals, the converter being disposed on a board 2 which is connected to a switch cable 10 for providing power and transmitting electrical signals. The housing of the hydroacoustic device is formed by the outer surfaces of the converter 4 and board 2, and by a protective material 1 which coats all of said surfaces, said material allowing for a transmission of the hydroacoustic oscillations and being a waterproof compound.

(23) The converter 4 may be piezoceramic, magnetostriction and other converters of the liquid-medium oscillations and the electrical signals capable of receiving and/or transmitting hydroacoustic signals. Their shapes may be different: cylindrical, circular or hemispheric. FIGS. 1 and 2 represent examples of the converter 4 having an hemispherical form, while FIGS. 3, 4 and 5 represent examples of the converter 4 having a cylindrical form. In the embodiment of FIGS. 3-5, the printed or wire circuit board 2 is a first printed or wire circuit board, and there is a second printed or wire circuit board 2′. As visible in FIG. 4, the printed or wire circuit boards 2, 2′ are disk-shaped and they have a same diameter equal to the diameter of the cylindrical-shaped converter 4. The lower base 4a of the cylindrical-shaped converter 4 is disposed on the first disk-shaped printed or wire circuit board 2, and the per base 4b of the cylindrical-shaped converter 4 is disposed on the second disk-shaped printed or wire circuit board 2′.

(24) The board may be a printed or a wire circuit board containing a receive, transmission or combined receive/transmission signal path capable (in any configuration) of comprising the following:

(25) power amplifier,

(26) input pre-amplifier,

(27) input and output band pass filters,

(28) analog-to-digital converter,

(29) digital-to-analog converter,

(30) digital signal processor, etc.

(31) At the same time, the design may include additional mounting elements (for example, for circular or cylindrical converter element: a support rod 9 positioned inside the cylindrical transmitter and additionally supporting the load from end surfaces of the cylinder). In the embodiment of FIGS. 3-5, as visible in FIG. 4, the support rod 9 extends from the inner surface of the first disk-shaped printed or wire circuit board 2 to the inner surface of the second disk-shaped printed or wire circuit board 2′, the support rod 9 being positioned to additionally support a load resulting from an external pressure of the liquid medium to end surfaces of the single housing.

(32) The hydroacoustic device is leakproof by coating it with a waterproof compound material, a thermoplastic, a vulcanization in a rubber housing or by any other method that ensures that the device is sufficiently insulated against the operating medium while retaining its acoustic transparency. In the embodiment of FIGS. 3-5, as visible in FIG. 4, the single waterproof housing of the hydroacoustic device includes:

(33) the outer surface of the disk-shaped printed or wire circuit board 2,

(34) the outer surface of the additional disk-shaped printed or wire circuit board 2′,

(35) the outer surface of the cylindrical-shaped converter 4, and

(36) the protective material 1 which coats all of the outer surface of the printed or wire circuit board 2, the outer surface of the additional printed or wire circuit board 2′, and the outer surface of the cylindrical converter 4.

Embodiment of the Invention

(37) The hydroacoustic device is manufactured as follows. (A non-limiting example of embodiment is provided). According to the FIG. 6:

(38) Stage A1. The housing of the hydroacoustic device is formed from the elements such as the converter 4 and the printed board 2, onto which the converter 4 is mounted.

(39) Stage A2. The required electrical elements are placed onto the board.

(40) Stage A3. The hydroacoustic device is connected to the switch cable 10.

(41) Stage A4. An external surface of the hydroacoustic device is covered with the pre-heated protective material 1 to ensure that it is insulated against the liquid medium.

(42) Stage A5. The protective material 1 is cooled and hardened.

(43) Now the hydroacoustic device can be used in the liquid medium. A load resulting from an external pressure of the liquid medium is carried by the converter and also by other supporting elements. It is converted to electric signals, processed, if required, and transmitted via the switch cable 10.

(44) The above optional embodiments of the invention are given herein by way of example and allow for new options or modifications for any eligible application. Some of the phases can be omitted or switched.

INDUSTRIAL APPLICABILITY

(45) The claimed hydroacoustic device may be implemented by a person skilled in the art in practice and ensures that the claimed objectives are met after implementation. The opportunity for practical embodiment of the invention by a person skilled in the art results from the fact that for each attribute included in the claim as based on the description, an equivalent material embodiment is known, which leads to the conclusion that the invention meets the requirement of “industrial applicability” and “complete disclosure”.

(46) An industrial prototype of the hydroacoustic device in a hemispheric form (see FIGS. 1 and 2) as well as in a cylindrical form (see FIGS. 3, 4 and 5) has been manufactured, according to the invention, by the applicant “Underwater Communications and Navigation Laboratory” Limited Liability Company. Polyurethane was used as protective material.

(47) Trial runs of the hydroacoustic device demonstrated that it was capable of:

(48) reception of hydroacoustic signals,

(49) transmission of hydroacoustic signals.

(50) operation at the depth of 150 m.

(51) The housing is acoustically transparent and leakproof for the liquid media.

(52) This invention makes it possible to simplify the design of receivers, transmitters and receiver/transmitters by combining the converter and signal forming and/or processing equipment and by using them as structural support elements. At the same time, all relevant signal conversions take place inside the item, thus lowering requirements for noise immunity and length of the switch cables. An additional economic benefit can be achieved by eliminating housings (metal, plastic or composite, etc.) from the design of the device, simplifying the device manufacturing process and simplifying switching and connecting hardware design for additional cost cuts.

(53) Thus, the technical result achieved by means of the above effects consists in simplifying the design of the device.