RU2650834C1 - Towed streamer hydro-acoustic module and method of its manufacture - Google Patents

Abstract

FIELD: antenna equipment.

SUBSTANCE: invention relates to the marine flexible extended towed antennas equipment serving to measure the sound field in water and used in geophysics and hydro acoustics. In the hydrophone module, acoustic pressure receivers are rigidly connected by a kapron thread, at which ends rectangular printed circuit boards are fixed. Resulting chain is pulled through the hose measuring section so that the printed circuit boards ends and nylon threads extend beyond the hose, after which the hose ends are sintered under the press to form a sealing seam. At that, the final hose sections, the normal planes of the printed circuit board, take the shape of a conical profile.

EFFECT: this hydrophone module design is light, technological and allows to reduce the hydrophone module sensitivity to longitudinal vibration by reducing the fluid flow effect in the towed streamer at the ends of the hydrophone module.

2 cl, 1 dwg

Description

The invention relates to techniques for marine flexible extended towed antennas, used to measure the sound field in water and used in geophysics and hydroacoustics.

The most widespread hose technology is seismicos, which consist of a set of vibration-isolating sections connected by sealed power electrical connectors to working sections containing hydrophones interconnected by communication wires, power cables fixed to power connectors, and a gel-like filler of the inner volume of the hose.

The hydrophone modules of a flexible extended towed antenna are known [1], for example, according to Utility Model Patent No. 50318. The hydrophone module contains a sealed flexible hose filled with a gel, and a number of piezoceramic cylindrical hydrophones with end caps located along the hose at a certain distance from each other. The hydrophones are held inside the hose with rubber bushings with petals, the size of which is equal to the inner radius of the flexible hose and larger than the radius of the cylindrical hydrophones. Each hydrophone is equipped with two bushings fixed in corresponding recesses in the centers of the end caps.

Closest to the claimed is the hydrophone module [2] of a towed streamer with piezoceramic cylindrical hydrophones, described in RF patent 2319985 "Hydrophonic module of a flexible long antenna and the method of filling it with a liquid filler". The hydrophone module of a flexible long antenna contains a flexible hose with sealing elements on the ends of the hose, a liquid-like filler and a number of piezoceramic hydrophones held on the axis of the hose by means of supporting elements at a certain distance from each other, electrically connected by wires connected to the electrical terminals of the end sealing elements. Both sealing elements are made in the form of durable disks made of structural electrically insulating material with rubber disks vulcanized on one side with a diameter equal to the inner diameter of the hose. In the solid discs at the edge, a hole is made filled with vulcanized rubber. The sealing elements are fastened with a hose on the lateral cylindrical surface of the rubber discs with glue.

The patent [2] also describes a method for manufacturing a hydrophone module, which includes assembling the module and filling it with a liquid-like aggregate. A fully fabricated sealed module is installed vertically obliquely, syringe needles are inserted into the rubber-filled hole of the upper and lower sealing elements, a filler fluid is pumped from the container into the lower needle, and air is displaced from the inner volume of the hydrophone module through the upper needle. As soon as aggregate fluid begins to flow through the upper needle, the needle is removed and the liquid continues to be pumped through the lower needle, controlling the outer diameter of the hose with a gauge, when the specified outer diameter of the hose is reached, the lower needle is removed.

The disadvantage of the hydrophone module described above and the method of its manufacture is the complexity of the module design and its manufacturing technology, in addition, the structure has a relatively large weight and, therefore, a large inertial mass, and the presence of a large number of mechanical parts determines the significant laboriousness of the assembly.

In addition, the presence of a large weight reduces the vibration resistance of the structure due to the presence of excess inertial mass and frontal resistance of the end caps during longitudinal vibrations of the hydrophone module in the gel and produces, when longitudinal vibrations occur, excessive pseudosound pressure on the hydrophones of the module.

The objective of the claimed invention is to increase vibration resistance, simplifying the design and manufacturing technology of the hydrophone module.

The technical result consists in minimizing the weight of the hydrophone module, giving the ends of the hose shell of the module a streamlined shape, reducing the number of module parts and additional assembly operations, reducing the weight of the receiver, simplifying its manufacturing technology and, as a result, its cost and involves automating a number of its manufacturing operations, t .e. serial suitability.

To achieve the claimed technical result, a hydrophone module of a flexible seismic scythe containing a hose with end sealing elements, a liquid-like filler and a set of acoustic pressure receivers installed along the axis of the hose at a certain distance from each other and electrically connected by wires connected to the electrical terminals of the end sealing hose of the elements , new features have been introduced, namely: the flexible polyurethane hose is equipped with a sealing polyurethane ring, inside the diameter of which is equal to the outer diameter of the polyurethane hose, the installation of acoustic pressure receivers is carried out by means of at least one nylon thread connecting the acoustic pressure receivers into a circuit, with each end sealing element being made in the form of a seam formed by sintering a rectangular printed circuit board located along the longitudinal the axis of the hose with the sheath of the receiving module, with the nylon threads and the end sections of the printed circuit board protruding beyond the longitudinal dimensions of the hose, and the cross section of the end sections of the hose with a plane normal to the plane of the printed circuit board has a cone shape.

Moreover, in a method of manufacturing a hydrophone module flexible seismic streamers, including

- installation of sealed acoustic pressure receivers along the axis of the hose from thermoplastic polyurethane;

- electrical installation of the hydrophone module;

- hose sealing with end elements;

- filling the hose with a liquid-like filler using two syringes introduced into the end sealing elements of the hose, through one of which a liquid-like filler is supplied, and the second air displaced by it comes out until the hose is completely filled and the required overpressure is created, it also introduced the following new features, namely:

- first, sealed acoustic pressure receivers are connected to the circuit by kapron thread in compliance with a given distance between them;

- attach rectangular printed circuit boards to the ends of the thread;

- solder the electrical leads of sealed acoustic transducers to the contacts of the printed circuit boards;

- the formed chain is pulled through the measuring segment of the hose so that the printed circuit boards and nylon thread protrude beyond the ends of the hose for a length that allows sealing and external installation of the hydrophone module in the seismic section;

- each printed circuit board and kapron thread are degreased and polyurethane adhesive is applied to them;

- each end of the hose with a thermal press heated to the plasticity temperature of the polyurethane is compressed with the formation of a sandwich from the printed circuit board and nylon thread until a seam is formed in the end of the hose for 3-5 minutes,

- filling the hose with a liquid-like filler with syringes is done by punctures through the cylindrical surface of the hose shell, and the sealing polyurethane ring is tightened until filling, pressing the outer surface of the hose shell and syringes at the puncture sites with polyurethane glue applied on the outer surface of the hose shell and the inner surface of the sealing ring;

- after filling the internal volume and removing air, the syringes are removed from the module’s shell, and the sealing ring compresses the filled hose along the outer surface with puncture places from the needles and prevents the leakage of liquid-like filler from the hose shell punctures.

The technical result of the invention is provided by simplifying the design by eliminating the end caps and provides the possibility of an automated operation of forming sealed ends of such hydrophone modules. Moreover, the formed conical profile of the end face of the hose shell provides minimal resistance to longitudinal vibrations of the hydrophone module, i.e. increases its vibration resistance, minimizing pseudo-sound pressure in the internal volume of the hydrophone module.

The invention is illustrated in FIG. 1, which shows the design of the claimed hydrophone module.

The hose 1 (Fig. 1) is flexible, made of thermoplastic polyurethane and is equipped with a sealing polyurethane ring 6, the inner diameter of which is equal to the outer diameter of the polyurethane hose. Acoustic pressure receivers 2 are placed inside the hose 1 with electrical leads 4 soldered inside the hose from the acoustic pressure receivers 2, nylon threads 5 and printed circuit boards 3. Pressure receivers 2 are interconnected by nylon thread 5, forming a chain that is placed along the axis of the hose 1. On the ends of the chain with thread 5 are fixed to the printed circuit boards 3. The ends of the hose 1 with the printed circuit boards 3 located in the plane of the longitudinal axis of the hose, the nylon threads 5 are clamped along the plane by gluing and heat treatment, as a result its form hermetic seams 8. Nylon thread 5 for mounting in the streamer sections, the ends of the circuit board 3 protrude beyond the longitudinal dimensions of the hose, and the cross section of end portions of the hose 1 in a plane perpendicular to the planes of the printed circuit board, forms a conical profile 7.

In accordance with the claimed method, the hydrophone module is made as follows: through the measuring segment of the polyurethane hose 1, acoustic pressure receivers 2 and printed circuit boards 3 are rigidly connected with each other using nylon thread 5 so that the printed circuit boards 3 protrude by the ends of the polyurethane hose 1, providing the ability to conduct external mounting of printed circuit boards 3 in the section of seismic streamers. The printed circuit boards 3, soldered by electric wires 4 from the acoustic pressure receivers 2, and the kapron thread 5 are degreased and polyurethane adhesive is applied to them, after which the free parts of the polyurethane hose 1 are pressed with the help of a thermal press heated to the plastic temperature of the polyurethane and pressed through a sandwich from the printed circuit board and kapron threads 5 for the formation of a tight seam 8 for 3-5 minutes

After forming the end face 7 of the polyurethane tube 1, a check of the electrical and electro-acoustic parameters and a leak test are carried out. Filling the hose with a liquid-like filler with syringes 10 is carried out through punctures in the cylindrical surface of the hose 1, and the sealing polyurethane ring 6 is installed before filling with an interference fit, pressing the outer surface of the hose shell 1 and syringes 10 at the puncture sites with the outer surface of the hose shell 1 and the inner surface of the sealing rings 6 with polyurethane adhesive. After filling the internal volume and removing air, the syringes 10 are removed from the module shell, and the sealing ring 6 compresses the filled hose 1 and prevents the liquid-like aggregate 9 from flowing out before gel formation.

After filling, the electro-acoustic parameters of the hydrophone module are monitored.

Performing the profile ends of the hydrophone module in the form of a streamlined cone reduces the flow resistance and the pressure that occurs during longitudinal vibrations of the seismic streamer in its internal volume and affects the hydrophone module by at least ten times [3].

A good illustration of the occurrence of drag force due to asymmetric flow around the body are the values of drag coefficients of bodies of various shapes presented in the table.

The presented information allows us to assume that the proposed hydrophone module for the geophysical seismic streamer provides minimal resistance to longitudinal vibration in the seismic streamer, i.e. minimal vibration sensitivity, and the proposed manufacturing technology allows to reduce its complexity, reduce mass and organize its mass production, and thus the technical result is achieved.

Information sources

1. RF patent 2319985 for the invention "Hydrophonic module of a flexible long antenna and the method of filling it with liquid filler" G01V 1/38, published March 20, 2008

2. Patent No. 50318 for the utility model “Hydrophone Modules of a Flexible Extended Towed Antenna”, according to the utility model patent, G01V 1/38, published December 27, 2005.

3. The mechanics of continuous media. Lectures. V.A. Aleshkevich, L.G. Dedenko, V.A. Karavaev (Faculty of Physics, Moscow State University). Publishing House of the Physics Department of Moscow State University www.nature.ru.

Claims (2)

1. The hydrophone module of a flexible seismic scythe, containing a hose with end, hose sealing elements, a liquid-like filler and a set of acoustic pressure detectors installed along the axis of the hose at a certain distance from each other and electrically connected by wires connected to the electrical terminals of the end sealing elements of the hose, characterized in that the flexible polyurethane hose is equipped with a sealing polyurethane ring, the inner diameter of which is equal to the outer diameter of the polyurethane of the hose, the installation of acoustic pressure receivers is carried out by means of at least one nylon string connecting the acoustic pressure receivers into a circuit, each end sealing element of the hose being made in the form of a seam formed by sintering a rectangular printed circuit board located along the longitudinal axis of the hose, with kapron threads and the end sections of the printed circuit board protrude beyond the longitudinal dimensions of the hose, and the section of the end sections of the hose with the plane normal to the plane of the printed circuit board has the shape of a con mustache. 2. A method of manufacturing a hydrophone module of a flexible seismic scythe, including installing sealed acoustic pressure receivers along the axis of the hose from thermoplastic polyurethane, electrical installation of the hydrophone module, sealing the hose with end elements and filling the hose with a liquid-like filler using two syringes inserted into the inner volume of the hose shell through one from which a liquid-like aggregate is supplied, and the second air displaced by it exits until the hose is completely filled and of excess pressure in it, characterized in that the sealed acoustic pressure receivers are first connected to the circuit with kapron filament, observing the specified distance between them, and rectangular printed circuit boards are connected to the ends of the filament, the electrical leads of the sealed acoustic transducers are soldered to the contacts of the printed circuit boards, through a measuring a segment of the hose is pulled over the formed chain so that the printed circuit boards and kapron thread protrude beyond the ends of the hose for a length that allows external about installing the hydrophone module in the seismic cable section, each circuit board and nylon string are degreased and polyurethane glue is applied to them, after which each end of the hose is pressed with the help of a thermal press heated to the plastic temperature of polyurethane to form a sandwich from the printed circuit board and nylon filament until formation a tight seam in the end of the hose for 3-5 minutes, and filling the hose with a liquid-like filler with syringes is done through punctures in the cylindrical surface of the hose, sealing polyurethane The o-ring is installed before filling with an interference fit, pressing the outer surface of the hose shell and syringes at the puncture sites with the polyurethane adhesive applied to the outer surface of the hose shell and the inner surface of the sealing ring, after filling the internal volume and removing air, the syringes are removed from the module shell and the sealing ring compresses filled hose.

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