KR20110077100A - Towed underwater acoustic sensor - Google Patents

Abstract

PURPOSE: A towed underwater acoustic sensor is provided to minimize the influence of floating noise when the underwater acoustic sensor is towed and maintain the neutral buoyancy of the underwater acoustic sensor. CONSTITUTION: A towed underwater acoustic sensor includes a signal cable(200), a piezoelectric sound sensor assembly(300), and a ballast assembly(500). The signal cable is connected to the inside of the back of a self-propelling decoy. The signal cable includes a high tensile member, a signal line and a power line. The piezoelectric sound sensor assembly is connected to the backend of the signal cable. The piezoelectric sound sensor assembly senses an acoustic signal of a broad frequency band. The ballast assembly is connected to the backend of the sound sensor assembly through a stabilizer cable. The ballast assembly maintains the neutral buoyancy of the underwater acoustic sensor when the sensor is towed to stabilize the acoustic signal.

Description

TOWED UNDERWATER ACOUSTIC SENSOR}

The present invention relates to a towed hydroacoustic sensor, and more particularly, to minimize the influence of the flow noise during towing of the hydroacoustic sensor towed during driving connected to the self-destructive deception device, and to maintain the neutral buoyancy and fluctuation of the hydroacoustic sensor The present invention relates to a towed underwater acoustic sensor which can stably receive a wide frequency band acoustic signal while minimizing it.

In general, land and air use electromagnetic waves to detect targets by radar, laser, or infrared rays, but sonar (SONAR: Sound Navigation And Ranging) is used to detect targets underwater. The sonar is a device that finds threatening underwater objects so that vessels such as a submarine or submarine can sail safely. Also called sonar or sound detector.

Sonars are classified into passive sonar and active sonar, depending on the detection method. Passive sonar is a device that finds a submarine by receiving noises from engines or propellers from a long distance when the submarine is sailing.It is a line array cow towed by a cable from a submarine or a ship, or a hull attached sonar attached to the hull of a submarine. And a line array sensor for sea supervisory sound system installed in the sea. Active sonar is a device that detects enemy submarines by using signals from the ship's sonar reflected back from the target, and adjusts the depth of use by towing a cable from the ship's sonar or the ship's rear. There is a variable depth sonar.

The operating principle of the sonar uses a piezoelectric phenomenon. When the intensity of the current flowing through the crystal or the ceramic exhibiting the piezoelectric phenomenon is changed to a constant frequency, the sonar vibrates and generates sound waves of the same frequency. On the contrary, when the sound wave is received from the outside, electric energy is generated, so analyzing the electric signal can find the components of the sound wave.

Such a sonar generally has a structure in which a plurality of acoustic sensors are arranged in a specific form, the wavelength of the acoustic signal generated in each of the acoustic sensors forming the array structure, and an electric signal for driving each acoustic sensor. The acoustic signal in a specific direction is detected by considering the phase difference of the signal.

Conventionally, a tow-type line array underwater acoustic sensor for receiving torpedoes, anchorages and signals by employing a neutral buoyancy cable and arranging a low frequency acoustic sensor as the acoustic sensor has been used.

However, in order to effectively disturb or deceive high-precision acoustic torpedoes attacked by friendly ships, the torpedoes are deceived or at least avoided by multiple deception methods, such as radiating noise while self-propelled by self-propulsion. In the self-destructive deception system, which allowed time to maximize the deception effect, the hydroacoustic sensor was placed inside the deceiver body and had to be towed during driving. In order to receive a signal or a signal, a reception function of a wideband frequency band including a high frequency has been required. In addition, the self-destructive deception machine has been required to develop a hydroacoustic sensor that receives a stable sound signal by minimizing the maintenance of the neutral buoyancy and fluctuation of the hydroacoustic sensor towed during driving.

Accordingly, the present invention has been made in view of the above-described conventional problems, while minimizing the influence of flow noise during towing of the underwater acoustic sensor being towed during driving connected to the self-destructive detractor, and maintaining the neutral buoyancy and fluctuation of the underwater acoustic sensor. It is an object of the present invention to stably receive sound signals in a wide frequency band while minimizing.

In order to achieve the above object, the present invention is a tow type underwater acoustic sensor connected to the self-destructive deceiving device to detect the acoustic signal in the water,

A signal cable connected to the rear end of the self-destructive deception machine and having a high tension tension member, a signal line, and a power line; A piezoelectric acoustic sensor assembly connected to a rear end of the signal cable to sense an acoustic signal of a wideband frequency band; A stabilizer assembly connected to a rear end of the acoustic sensor assembly by a stabilizer cable to maintain neutral buoyancy of the underwater acoustic sensor when towing to stabilize the acoustic signal; Characterized in that it comprises a.

In addition, in the present invention, the acoustic sensor assembly, a piezoelectric acoustic-electric converter made of a piezoelectric ceramic vibrating body to receive the acoustic signal and convert the electrical signal, and the acoustic-electric converter is electrically connected to the acoustic-electric converter Pre-amplifier with amplification of the micro-electrical signal of the converter and frequency filtering function, an integrated sensor molding part which is miniaturized so that the acoustic-electric converter and the pre-amplifier can be integrally formed, and formed at the front end of the sensor molding part to output the preamplifier. And a connection part for connecting a signal cable to transmit a signal to the signal cable, and a molding coupling part having a connection part connected to the rear end of the sensor molding part and connected to one end of the ballast cable.

In addition, in the present invention, the sensor molding part is characterized by consisting of a sound window of a streamlined structure vacuum-molded with polyurethane in order to prevent water tightness and external impact.

Further, in the present invention, the piezoelectric ceramic vibrating body is spherical and is housed in a spherical accommodating groove formed in the sensor molding part.

In the present invention, the piezoelectric ceramic vibrating body is formed by adhering an electrode plate to a surface of a spherical piezoelectric ceramic plate.

In addition, in the present invention, the ballast assembly is connected to the other end of the ballast cable, an internal empty space having an air layer to maintain the neutral buoyancy, and a streamlined ballast stabilized integrally molded in polyurethane with the connecting portion and the internal empty space It characterized in that it comprises a molding.

According to the present invention, the acoustic-electric converter and the preamplifier made of the piezoelectric ceramic vibrating body form the sensor molding portion through the polyurethane vacuum molding, thereby miniaturizing the seawater while preventing the seawater infiltration.

In addition, by forming the piezoelectric ceramic vibrating body into a spherical shape having a non-directional characteristic, it is possible not only to receive an acoustic signal in a wide frequency band in all directions, but also to provide a stabilizer assembly having an air layer inside the rear end of the sensor molding part. It can be connected by ballast cable to maintain stable neutral buoyancy of the hydroacoustic sensor during towing and can receive stable sound signals, and minimize the influence of flow noise that can be generated during towing by forming the acoustic sensor assembly and ballast assembly in a streamlined structure. In addition, fluctuations can be minimized.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram of a tow type hydroacoustic sensor connected to the self-destructive device according to the present invention, Figure 2 shows an acoustic sensor assembly according to the present invention, (a) is an external view, (b) is an internal cross-sectional view. 3 shows a ballast assembly of a towed hydroacoustic sensor according to the present invention, (a) is an outline view, and (b) is an internal sectional view.

First, as shown in FIG. 1, the towed hydroacoustic sensor 600 according to the present invention is connected to the self-destructive deception device 100. The hydroacoustic sensor 600 is located inside the deception machine 100 mounted on a launch tube (not shown) which is normally installed on an outer surface of a submarine (not shown). Separate from the maturity 100 will have a tow-shaped structure as shown in FIG.

Since the deception device 100 is not an essential configuration of the present invention, the detailed structure thereof is not shown in the drawings. However, the deception device 100 will be briefly described for connection with the underwater acoustic sensor 600 according to the present invention. In general, the self-destructive deception device 100 is driven by the propulsion power is activated immediately after the launch through the submarine's launch tube to emit torpedoes from the ship by releasing sound waves gradually away from the submarine is driven by an internal propulsion motor And a driving device. In addition, a space is formed inside the rear end of the deception body, and the rear end is provided with a release device that is wrapped by a launch tube before launch and fixed by a torsion spring and connected to a rotation shaft of the motor.

By this structure, the underwater acoustic sensor 600 according to the present invention is connected to the decoupling device in a state in which the decompression device 100 is wound inside the deception device 100 by a signal cable 200 to be described later, the deception device 100 When the out of the launch tube, the spring fixing the release device is dismantled and the release device is peeled off and is separated from the deception machine 100.

As described above, the hydroacoustic sensor 600 according to the present invention connected to the deception device 100 includes a signal cable 200; Piezoelectric acoustic sensor assembly 300; Ballast cable 400; Ballast assembly 500; It is configured to include.

The signal cable 200 is connected to the inside of the rear end of the self-destructive deception device 100 as described above, is provided with a high-tensile tension member to withstand the underwater tension during towing, and the signal line and the power line is disposed around the outside and polyurethane outside Consists of a structure surrounded by. In addition, the signal cable 200 is preferably designed to have a long length in order to minimize the noise effect of the propulsion device of the deception device 100 when the deception device 100 is traveling.

The piezoelectric acoustic sensor assembly 300 is connected to the rear end of the signal cable 200 and is configured to detect an underwater acoustic signal of a broadband frequency band. That is, the acoustic sensor assembly 300 is electrically connected to the piezoelectric acoustic-electric converter 311 made of a piezoelectric ceramic vibrating body to receive the acoustic signal and convert the electrical signal, and the acoustic-electric converter 311. A miniature integrated type that amplifies the micro-electrical signal of the acoustic-electric converter 311 and has a pre-amplifier 312 having a frequency filtering function, and the acoustic-electric converter 311 and the pre-amplifier 312 may be integrated. A connection part 314 formed at the front end of the sensor molding part 313 and the sensor molding part 313 to connect the signal cable 200 to transmit the output signal of the preamplifier 312 to the signal cable 200; The pin is coupled to the rear end of the sensor molding part 313 and has a structure including a molding coupling part 316 having a connection part 315 for connection of one end of the ballast cable 400.

Here, the sensor molding part 313 is formed by integrally molding the acoustic-electric converter 311 and the preamplifier 312 as shown in FIG. The sensor molding part 313 includes accommodating grooves 318 and 319 for accommodating the acoustic-electric converter 311 and the preamplifier 312, and a connection part 314 having hemispherical grooves for connecting the signal cable 200. Is formed. The sensor molding part 313 of this structure has similar characteristics to water and has no loss of sound waves in order to protect components mounted therein from watertightness and external shocks and to block the inflow of seawater at deep water. Acoustic window structure is made by using polyurethane material. In addition, the sensor molding part 313 is designed in a streamlined structure to minimize the influence of the flow noise during towing.

The piezoelectric ceramic vibrating body is spherical, and is accommodated in spherical receiving grooves 318 and 319 formed in the sensor molding portion 313. The piezoelectric ceramic vibrating body is formed by adhering an electrode plate to the inner and outer surfaces of a spherical piezoelectric ceramic plate.

In order to pin-couple the molding coupling part 316 to the sensor molding part 313, corresponding pin coupling holes are formed at the rear end of the sensor molding part 313 and the front end of the molding coupling part 316. Therefore, the molding coupling part 316 may be separated from the sensor molding part 313 by removing the pin 317 fixed to the pin coupling hole. The molding coupling part 316 is formed by molding the ballast cable 400 integrally.

On the other hand, the ballast assembly 500 has a connection portion 510 for connecting the other end of the ballast cable 400, an inner empty space 511 having an air layer to maintain neutral buoyancy, the connecting portion 510 and the inner empty space 511 is integrally formed with a structure including a ballast molding unit 512 molded with polyurethane. Here, the ballast molding unit 512 is also formed by molding the empty space 511 and the ballast cable 400 in the same manner as above, the connection portion 510 is formed in the ballast molding unit 512 in the hemispherical longitudinal direction Is made by. In addition, the ballast molding unit 512 is designed in a streamlined structure together with the sensor molding unit 313 to minimize the influence of the flow noise during towing.

Referring to the operational relationship of the underwater acoustic sensor according to the present invention as described above are as follows.

When the self-destructive deception machine 100 is fired from the submarine's launch tube, the underwater acoustic sensor 300 is located inside the deception machine 100 and withdrawn to the outside while being deducted by the signal cable 200. It is arranged in the form towed to. In this state, when an acoustic signal is received from an external object, the acoustic signal is transmitted to the acoustic-electric converter 311 made of a piezoelectric ceramic vibrating body through the sensor molding unit 313, wherein the piezoelectric ceramic vibrating body is non-directional ( Since it is formed into a sphere having no characteristics, it is possible to receive an acoustic signal of a wide band frequency band in all directions.

The acoustic signal transmitted to the piezoelectric ceramic vibrating body is converted into an electrical signal by mechanical vibration, amplified by the preamplifier 312, and then transmitted to the final deceptor 100 through the signal cable 200 to transmit the deceptive signal to an external object. By sending to, it will have a deceptive effect on torpedoes or gundams. Here, the sensor molding part 313 equipped with the piezoelectric ceramic vibrating body and the preamplifier 312 may be formed through polyurethane vacuum molding, thereby minimizing the seawater penetration. In addition, by connecting the ballast assembly 500 having an air layer therein to the ballast cable 400 at the rear end of the acoustic sensor assembly 300 constituting the sensor molding part 313, the sound sensor assembly 300 is driven from behind. While pulling, the neutral buoyancy can be maintained by the air layer to receive a stable sound signal. In addition, by forming the sensor molding part 313 and the stabilizer assembly 500 in a streamlined structure, it is possible to minimize the influence of flow noise that may occur during towing and to prevent fluctuations.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Accordingly, the true scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of the same should be construed as being included in the scope of the present invention.

1 is a block diagram of a towed hydroacoustic sensor connected to the self-destructive deception device according to the present invention.

Figure 2 shows an acoustic sensor assembly of the towed hydroacoustic sensor according to the present invention, (a) is an external view, (b) is an internal cross-sectional view.

Figure 3 shows a ballast assembly of a tow-type hydroacoustic sensor according to the present invention, (a) is an external view, (b) is an internal cross-sectional view.

Description of the Related Art

100: deception

200: signal cable

300: acoustic sensor assembly

311: acoustic-electric converter

312: preamplifier

313: sensor molding part

314, 315, 510: Connection

316: molding joint

318, 319: receiving home

400: ballast cable

500: ballast assembly

511: empty interior space

512: ballast molding part

600: towing type underwater acoustic sensor

Claims (5)

In the towed hydroacoustic sensor 600 connected to the self-destructive deception device 100 to detect the underwater sound signal, A signal cable 200 connected to the rear end of the self-destructive deception device 100 and provided with a high tension tension member, a signal line, and a power line; A piezoelectric acoustic sensor assembly 300 connected to a rear end of the signal cable 200 to sense an acoustic signal of a wideband frequency band; A ballast assembly 500 connected to a rear end of the sound sensor assembly 300 by a ballast cable 400 to maintain neutral buoyancy of the underwater acoustic sensor when towing and stabilize the sound signal; A towed hydroacoustic sensor comprising a. The method of claim 1, The piezoelectric acoustic sensor assembly 300 includes a piezoelectric acoustic-electric converter 311 made of a piezoelectric ceramic vibrating body for receiving the acoustic signal and converting the electrical signal, and is electrically connected to the acoustic-electric converter 311. Miniature integrated sensor that amplifies the micro-electrical signal of the acoustic-electric converter 311 and has a frequency filtering function, and a miniaturized sensor so that the acoustic-electric converter 311 and the pre-amplifier 312 can be integrally formed. A connection part 314 formed at the front end of the molding part 313 and the sensor molding part 313 to connect the signal cable 200 to transmit the output signal of the preamplifier 312 to the signal cable 200; A towed hydroacoustic sensor comprising a molding coupling part 316 having a connection part 315 for connection of one end of a ballast cable 400 to a pin coupled to a rear end of the sensor molding part 313. The method of claim 1, The sensor molding part 313 is a tow-type underwater acoustic sensor, characterized in that made of a streamlined acoustic window vacuum-molded with polyurethane to prevent water tightness and external impact. The method of claim 2, The piezoelectric ceramic vibrating body has a spherical shape, and the towed hydroacoustic sensor is supported by a spherical receiving groove 313b formed in the sensor molding part 313. The method according to any one of claims 1 to 4, The ballast assembly 500 includes a connection part 510 for connecting the other end of the ballast cable 400, an internal empty space 511 having an air layer to maintain neutral buoyancy, and the connection part 510 and the internal empty space are integrated. A tow-type underwater acoustic sensor comprising a streamlined ballast molding unit 512 molded with polyurethane.

Images