KR101364643B1 - Acoustic sensor for maneuver equipment obstruct-bomb - Google Patents

Abstract

The present invention relates to an acoustic sensor (1) for a maneuver holding bullet including a main housing (10) having an internal space (11); a protection grid (20) which is joined to one side of the main housing (10) and which has an acoustic inlet (21); a microphone unit (90) accepted in the internal space (11) to obtain sound from the acoustic inlet (21); and an acoustic impedance matching part (A) which is placed in the microphone unit (90) and the internal space (11) to match external acoustic impedance to internal acoustic impedance by distributing sound from the acoustic inlet (21).

Description

Acoustic Sensor for Mobile Judges {ACOUSTIC SENSOR FOR MANEUVER EQUIPMENT OBSTRUCT-BOMB}

The present invention relates to an acoustic sensor for detecting sound, and more particularly, to obtain sound generated from a mobile device even in an extreme environment exposed to various external environments such as rainfall, wind, and dust, such as outdoors (fields). The present invention relates to an acoustic sensor for a mobile low level projectile.

The acoustic sensor converts acoustic energy in the air into an electrical signal, and includes an ultrasonic sensor, a vibration sensor, and a noise sensor. There are various kinds of noise sensors, such as dynamic type, piezoelectric type, and condenser type.

The condenser microphone, which is known to have the best performance among acoustic sensors, applies a polarization voltage between two adjacent charging plates, and measures a sound pressure signal by generating a charge due to a change in distance of the charging plate vibrating by sound pressure. These condenser microphones are widely used as measurement microphones because of their excellent frequency characteristics and good signal-to-noise ratio.

Such acoustic sensors are widely used in military equipment. Acoustic sensors for military purposes include unmanned ground sensors, airborne acoustic sensors for unmanned ground sensors (UGS) that allow airdropping at military strategic points on the ground to detect enemy maneuvering equipment, and maneuvering for detecting maneuvering equipment approaching from a distance. Acoustic sensor for low bombs.

The acoustic sensor for the mobile low level bomb is installed in the mobile low level bomb and acquires the sound generated by the moving equipment of the moving enemy and transmits it to the low level low level bomb. Mobile JB uses the information transmitted from the acoustic sensor for Mobile JG to find the location of the mobile device and fly to the mobile device to disable the mobile device.

As such, the acoustic sensor used in the mobile low ground coal requires accurate sound acquisition for accurate detection, and is used in extreme environments such as outdoors and wars, and thus, should have environmental resistance to external environments such as heat and moisture.

(KR) Patent 10-1146561 (KR) Registered Patent 10-0946753 (KR) Registered Patent 10-0724100 (KR) Patent Publication 10-2012-0130310

An object of the present invention is to provide an acoustic sensor for mobile low ground coal having a structure that can improve the accuracy of sound acquisition.

In addition, another object of the present invention is to provide an acoustic sensor for starting low coal having environmental resistance.

According to an embodiment of the present invention for realizing the above object, the acoustic sensor 1 for starting low-altitude coal has a main housing 10 having an inner space portion 11 and one side of the main housing 10. A protection grid 20 coupled to the sound inlet hole 21, a microphone unit 90 received in the inner space part 11 and acquiring sound introduced through the sound inlet hole 21, and It includes an acoustic impedance matching unit (A) provided in the inner space 11 and distributes the sound introduced through the sound inlet hole 21 to match the external acoustic impedance and the internal acoustic impedance.

According to an example related to the present invention, the acoustic impedance matching unit A includes an accommodating part 41 in which the microphone unit 90 is mounted, an acoustic hole 42 in communication with the accommodating part 41, and And a matching block drum 40 having a matching hole 43 branched from the sound hole 42 so that a part of the sound is distributed, and wound around an outer circumference of the matching block drum 40. It includes a matching tube 50 in communication with the attenuated sound flowing into the matching hole 43 to achieve an acoustic impedance matching.

The acoustic sensor 1 for the starting low-alcohol may further include a windbreak net 30 installed between the microphone unit 90 and the protection grid 20 to protect the vibration membrane of the microphone unit 90. A portion of the matching block drum 40 may be inserted into the mounting groove 12 of the main housing 10 so that the sound hole 42 communicates with the windbreak network 30.

The acoustic impedance matching unit A may further include a matching pin 44 having one end inserted into the matching hole 43 and the other end connected to the matching tube 50.

The sound hole 42 may be formed to extend along the axis of the microphone unit 90 so that the incoming sound can be directly transmitted to the microphone unit 90.

In addition, the acoustic sensor 1 for the starting low-altitude coal is disposed to cover the dehumidifying agent 75 for dehumidifying the acoustic impedance matching unit A and the matching block 40 and the dehumidifying agent 75 therein. A dehumidifying agent cover 70 having a space for filling and having a seating portion thereon, a transparent window 76 installed at the seating portion 73 so that the state of the dehumidifying agent 75 can be visually checked, and It may further include a housing cover 80 coupled to the other side of the main housing 10 so as to cover the dehumidifying agent cover 70 and having a confirmation port 81 corresponding to the transparent window 76.

The matching block drum 40 may be formed with a dehumidifying hole 46 for communicating a space in which the matching tube 50 is installed and a space in which the dehumidifying agent 75 is installed.

A vent cover 60 may be installed on the matching block drum 40 so as to cover the opening of the accommodation portion 41, and a wiring of a cable connected to the microphone unit 90 is provided on the vent cover 60. The cable through-hole 61 for the dehumidification, the through hole 62 for communicating the space in which the accommodating portion 41 and the dehumidifying agent 75 is installed may be formed.

The main housing 10 may have a connector groove 16 to which the connector 16 of the cable may be fixed.

In addition, the matching block drum 40 may be made of polyacetal, which is a formaldehyde polymer.

According to the present invention, a part of the sound passing through the windbreak network is immediately transmitted to the microphone unit without bending, and the other part is introduced into the matching tube through the matching hole to achieve acoustic impedance matching. As a result, the microphone unit can obtain more accurate sound.

In addition, since the matching tube is installed around the matching block drum to minimize the volume, the size of the acoustic sensor for the starting low-velocity bomb can be miniaturized.

In addition, according to the present invention, the components forming the exterior including the main housing may be formed of a metal material to protect the internal components during an external impact, and the internal components are not affected by moisture as a dehumidifier is provided therein. .

1 is a conceptual diagram showing an example of a moving low-jeep installed acoustic sensor.
Figure 2 is a perspective view of the acoustic sensor for starting low coal showing an embodiment of the present invention.
3 is an exploded perspective view of the acoustic sensor for starting low-altitude coal shown in FIG.
4 is a cross-sectional view of the acoustic sensor for starting low coal shown in FIG.
5 is an exploded cross-sectional view of the acoustic sensor for starting low-altitude coal shown in FIG. 4.

EMBODIMENT OF THE INVENTION Hereinafter, the acoustic sensor for starting low coals which concerns on this invention is demonstrated in detail with reference to drawings.

As used herein, the singular forms "a", "an" and "the" include plural referents unless the context clearly dictates otherwise.

1 is a conceptual diagram illustrating an example of a starting low-velocity bomb in which an acoustic sensor is installed.

Referring to FIG. 1, the acoustic sensor 1 of the present invention is used in a starting low-velocity bomb to neutralize enemy maneuvering equipment. A plurality of acoustic sensor 1 for the activated low bombs are installed in the activated low coal to obtain a sound (sound source) generated from the activated equipment, and transfer the acquired sound to the controller of the activated low coal, so that the activated low Identify the location so that you can attack.

As such, the acoustic sensor 1 for the mobile low ground level requires accuracy of sound acquisition for precise detection, and is used in extreme environments such as outdoors (fields) and wars, and thus, environmentally friendly to external environments such as heat and moisture. Should have

Hereinafter, with reference to Figs. 2 to 5 will be described in detail with respect to the acoustic sensor 1 for the starting low-velocity that can satisfy the above requirements.

FIG. 2 is a perspective view of an acoustic sensor 1 for starting low coal, showing an embodiment of the present invention, and FIG. 3 is an exploded perspective view of the acoustic sensor 1 for starting low coal, shown in FIG. 2, and FIG. FIG. 5 is a cross-sectional view of the acoustic sensor 1 for the start low coal, and FIG. 5 is an exploded cross-sectional view of the acoustic sensor 1 for the start low coal.

2 to 5, the acoustic sensor 1 for the starting low-altitude missile includes a main housing 10, a protection grid 20, a microphone unit 90, and an acoustic impedance matching unit A. Referring to FIGS.

The main housing 10 has an inner space 11 for accommodating various internal components. As shown in the drawing, the main housing 10 may be formed in a cylindrical shape, and a band-shaped groove for installation may be formed on an outer circumference thereof. In addition, a connector groove 16 may be formed in the main housing 10 in which the connector 16 of the cable may be fixed.

The main housing 10 may be formed of a material (eg, a metal material, a composite material, etc.) resistant to external shock so as to protect internal components during external shock. For example, the aluminum housing 70 may be used as the main housing 10 having excellent heat resistance and ductility, and being light and strong.

The protection grid 20 may be installed at one side of the main housing 10, and the screw part 10-1 for the installation may be formed at the main housing 10. The protection grid 20 may be formed with a threaded groove 22 for coupling with the threaded portion 10-1 of the main housing 10.

The protection grid 20 is coupled to one side of the main housing 10 to form an end appearance of the acoustic sensor 1 for the moving low bombs. The protection grid 20 may be formed of the same material as the main housing 10.

The protection grid 20 has a sound inlet 21 through which sound can be introduced. The sound inlet hole 21 may be provided in plurality.

On the other hand, the main housing 10 is provided with a wind screen hole 13 for receiving the wind screen 30. The windbreak net 30 installed in the windbreak hole 13 is formed to protect the vibration membrane of the microphone unit 90 and to prevent foreign substances, such as wind noise and dust.

The microphone unit 90 is accommodated in the inner space 11 to obtain a sound flowing through the sound inlet hole 21. The microphone unit 90 may be an electret condenser microphone (ECM).

The protection grid 20 is installed at the end of the main housing 10 to fix and protect the wind screen 30, while protecting the microphone unit 90 from external shocks or the environment, and to minimize acoustic disturbances.

The acoustic impedance matching unit A is provided in the internal space 11 and distributes the sound introduced through the sound inlet 21 to match the external acoustic impedance with the internal acoustic impedance.

Impedance in a circuit is the ratio of voltage and current at a particular structure and circuit location. However, the impedance in sound is defined as the ratio of sound pressure and volume velocity, and the value of acoustic impedance is affected by the shape of the structure, sound velocity, and reflected wave. Considering these conditions, matching the external acoustic impedance with the internal acoustic impedance is impedance matching.

The acoustic impedance matching unit A matches the external acoustic impedance with the internal acoustic impedance, and includes a matching block drum 40 and a matching tube 50.

The matching block drum 40 has a matching tube winding 45 so that the matching tube 50 can be wound and installed, and may have a cylindrical shape as shown. In addition, the matching block drum 40 may be formed of polyacetal, a formaldehyde polymer.

The matching block drum 40 is branched from the sound hole 42 so that a part of the sound is distributed and a sound hole 42 communicating with the accommodation part 41 to which the microphone unit 90 is mounted. The matching hole 43 is provided.

The accommodation part 41 may be provided with a mounting groove 41a for mounting the microphone unit 90.

The sound hole 42 may be formed to extend along the axis of the microphone unit 90 so that incoming sound can be directly transmitted to the microphone unit 90. In other words, the sound hole 42 may be formed to communicate with the receiving portion 41 in a straight line. In particular, the sound flowing into the sound hole 42 is transmitted to the microphone unit 90 without bending or bending, and the microphone unit 90 installed in the mounting groove 41a is also installed in the same direction as the movement direction of the sound. .

The matching hole 43 may be formed to be perpendicular to the sound hole 42, and may be provided at both sides of the sound hole 42.

A portion of the matching block drum 40 is inserted into the mounting groove 12 of the main housing 10 so that the sound hole 42 communicates with the windbreak network 30.

The matching tube 50 is wound around the outer periphery of the matching block drum 40 and communicates with the matching hole 43 to attenuate the sound flowing into the matching hole 43 to achieve acoustic impedance matching.

Matching tube 50 may be composed of a single tube, both ends are connected to the matching pin 44 installed in the matching hole 43, respectively. One end of the matching pin 44 is inserted into the matching hole 43, and the other end is connected to the matching tube 50 to connect the matching butt 50 and the matching hole 43. The matching tube 50 is preferably formed of an elastic material (for example, silicon, rubber, etc.).

According to the above structure, part of the sound flowing through the sound hole 42 is introduced into the matching tube 50 through the matching hole 43, and the other part is transferred to the microphone unit 90. The sound flowing into the matching tube 50 achieves impedance matching by matching the external acoustic impedance of the matching block drum 40 with the internal acoustic impedance.

As such, according to the present invention, a part of the sound passing through the windbreak net 30 is transmitted to the microphone unit 90 directly without being folded, and the other part is introduced into the matching tube 50 through the matching hole 43 and the sound. Impedance matching is achieved. As a result, the microphone unit 90 can obtain a more accurate sound.

In addition, since the matching tube 50 is installed wound around the matching block drum 40 so as to minimize the volume, the size of the acoustic sensor 1 for the starting low-velocity bullet can be miniaturized.

Hereinafter, a description will be given of the acoustic sensor 1 for the starting low-altitude coal, which can be prevented from deteriorating due to moisture.

In order to prevent deterioration due to moisture, the acoustic sensor for starting low-altitude coal further includes a vent cover 60, a dehumidifier cover 70, a dehumidifier 75, a transparent window 76, and a housing cover 80.

The vent block 60 is installed in the matching block drum 40 to cover the opening of the accommodating part 41 to protect the microphone unit 90 installed in the accommodating part 41.

The dehumidifier cover 70 is disposed to cover the matching block drum 40 to provide a space 71 in which the dehumidifier 75 is filled. The dehumidifier cover 70 may be supported at an end of the matching block drum 40, and at least a part of the dehumidifier cover 70 may be accommodated in the inner space part 11.

The dehumidifying agent 75 is filled in the space 71 defined by the matching block drum 40 and the cover for the dehumidifying agent 70 to remove moisture from the acoustic impedance matching part A. FIG.

The dehumidifier cover 70 has a seating portion at an upper portion thereof, and the transparent window 76 is installed at the seating portion 73 so that the state of the dehumidifying agent 75 can be visually confirmed. On the other hand, a communication hole 72 is provided between the space 71 in which the dehumidifying agent 75 is filled and the seating portion 73 in which the transparent window 76 is mounted.

The housing cover 80 is coupled to the other side of the main housing 10 to cover the dehumidifying agent cover 70. The housing cover 80 may be formed with a screw groove 82 for coupling with the screw portion 10-2 of the main housing 10.

The housing cover 80 is installed on the other side of the main housing 10 to form an end appearance of the acoustic sensor for starting low-altitude coal, and functions to protect internal components accommodated in the inner space part 11. The housing cover 20 may be formed of the same material as the main housing 10.

The housing cover 80 includes a confirmation port 81 corresponding to the transparent window 76, so that the user can check whether the dehumidifying agent 75 is discolored through the transparent window 76 exposed through the confirmation window 81. It is done to be.

On the other hand, the matching block drum 40, a dehumidification hole 46 for communicating the space in which the matching tube 50 is installed and the space 71 in which the dehumidifying agent 75 is installed may be formed. The dehumidifier 75 removes moisture from the space where the matching tube 50 is installed, thereby preventing the function of the matching tube 50 from deteriorating due to moisture.

In addition, the vent cover 60, the dehumidification for communicating the cable through-hole 61 for the wiring of the cable connected to the microphone unit 90, the space in which the accommodating portion 41 and the dehumidifying agent 75 is installed The through hole 62 may be formed.

According to the present invention having the above configuration, the components forming the exterior including the main housing 10 is formed of a metal material to protect the internal components during an external impact, the dehumidifier 75 is provided therein the internal components May not be affected by moisture.

Referring to Figure 4, briefly described again with respect to the acoustic sensor 1 for the operation low ground coal of the present invention, when the sound is introduced through the sound inlet hole 21 of the protection grid 20, the windbreak network 30 After passing through, it enters the sound hole 42 of the matching block drum 40.

Part of the sound flowing into the sound hole 42 is introduced into the matching tube 50 through the matching hole 43, and the other part is transmitted to the microphone unit 90 positioned in a straight line.

At this time, acoustic impedance matching is performed by the sound transmitted to the matching tube 50. Matching tube 50 is preferably a predetermined length or more for the acoustic impedance matching, in order to secure the installation space of the matching tube 50, the matching tube 50 is wound around the outer periphery of the matching block drum 40 It was.

The space 71 in which the dehumidifying agent 75 is installed is configured to communicate with the space in which the matching tube 50 is installed and the space in which the microphone unit 90 is installed, thereby preventing the functional degradation due to moisture. In addition, since the dehumidifier 75 is configured to be easily identified with the naked eye from the outside, it is easy to check whether the dehumidifier 75 is replaced.

The acoustic sensor for starting low-altitude coal described above is not limited to the method and configuration of the embodiment described above. The present invention can be applied variously within a range in which technical ideas are protected.

10: main housing 11: internal space
12: mounting groove 13: hole for the wind screen
20: protection grid 21: sound inlet
30: windbreak
A: Impedance Matching Unit
40: matching block drum 41: receiving portion
42: sound hole 43: matching hole
44: matching pin 45: matching tube wound
46: dehumidification hole
50: matching tube
60: vent cover 61: cable through hole
62: through hole for dehumidification
70: dehumidification cover
75: dehumidifier 76: transparent window
90: microphone unit

Claims (10)

In the acoustic sensor 1 for the starting low-elevation coal, which is installed in the low-elevation coal, and acquires sound generated by the starting equipment,
A main housing 10 having an inner space 11;
A protection grid 20 coupled to one side of the main housing 10 and having an acoustic inlet 21;
A microphone unit (90) accommodated in the inner space part (11) to obtain a sound flowing through the sound inlet hole (21); And
A sound provided for the inner space part 11, including a sound impedance matching unit (A) for distributing the sound introduced through the sound inlet hole 21 to match the external acoustic impedance and the internal acoustic impedance Sensor (1). The method of claim 1,
The acoustic impedance matching unit (A),
The accommodating part 41 to which the microphone unit 90 is mounted, the sound hole 42 communicating with the accommodating part 41, and the matching hole branched from the sound hole 42 so that a part of the sound is distributed. A matching block drum 40 having a 43; And
Winding around the outer periphery of the matching block drum 40, the mobile communication for the low ground including a matching tube (50) to achieve the acoustic impedance matching by attenuating the sound flowing into the matching hole 43 to the matching hole 43 Acoustic sensor (1). 3. The method of claim 2,
It is further provided between the microphone unit 90 and the protection grid 20, and further comprises a wind screen 30 for protecting the vibration membrane of the microphone unit 90,
A portion of the matching block drum 40 is inserted into the mounting groove 12 of the main housing 10, the sound hole 42 is characterized in that for communicating with the windbreak net 30 Acoustic sensor (1). 3. The method of claim 2,
The acoustic impedance matching unit (A),
One end is inserted into the matching hole (43), the other end of the acoustic sensor for starting low-altitude bullet further comprises a matching pin (44) connected to the matching tube (50). 3. The method of claim 2,
The sound hole 42, the acoustic sensor 1 for the starting low-altitude coal, characterized in that is formed to extend along the axis of the microphone unit 90 so that the incoming sound can be directly transmitted to the microphone unit 90. . 3. The method of claim 2,
A dehumidifying agent (75) for dehumidifying the acoustic impedance matching unit (A);
A dehumidifying agent cover 70 disposed to cover the matching block drum 40 to provide a space in which the dehumidifying agent 75 is filled, and having a seating portion at an upper portion thereof;
A transparent window 76 installed on the seating part 73 so that the state of the dehumidifying agent 75 can be visually checked; And
It is coupled to the other side of the main housing 10 so as to cover the dehumidifying agent cover 70, the starting block further comprises a housing cover 80 having a confirmation port 81 corresponding to the transparent window 76 Acoustic sensor for bullets (1). The method according to claim 6,
The matching block drum 40, a dehumidifying hole 46 for communicating a space in which the matching tube 50 is installed and the space in which the dehumidifying agent 75 is installed is formed, the acoustic sensor for starting low coal. (One). The method according to claim 6,
The matching block drum 40 is provided with a vent cover 60 to cover the opening of the receiving portion 41,
The vent cover 60 communicates a cable through-hole 61 for wiring the cable connected to the microphone unit 90, and a space in which the accommodating portion 41 and the dehumidifying agent 75 are installed. Dehumidifying through-hole 62 is formed, the acoustic sensor for starting low-altitude bullet (1), characterized in that formed. 9. The method of claim 8,
The main housing (10) is characterized in that the connector groove (16) for fixing the connector 16 of the cable is formed, the acoustic sensor for starting low-altitude bullet (1). 3. The method of claim 2,
The matching block drum 40 is made of polyacetal, which is a formaldehyde polymer acoustic sensor (1), characterized in that the.

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