KR20150009191A - Deception target for guided missile - Google Patents

Abstract

The present invention relates to an inflatable guided missile deception body and, more specifically, to an inflatable guided missile deception body, which is capable of protecting a target from an external attack by floating, on the sea, a three-dimensional pseudo target expanded by compressed air in the naval battle. To achieve this, the inflatable guided missile deception body includes a polyhedron configured to form an air tube along the edge of a three-dimensional figure surrounded by polygonal surfaces, wherein the air tube is automatically expanded by a gas injector coupled to an air inlet; a cover configured to form a polygonal reflecting surface by enveloping the polyhedron; and a reflective coating layer formed by coating the reflecting surface with a metallic electromagnetic reflective material.

Description

Deception target for guided missile.

[0001] The present invention relates to an air inflatable guided vehicle, more particularly, to an air inflatable guided vehicle having an air inflatable guided vehicle capable of protecting a target from an external attack by floating a three- .

Generally, a guided car is used to induce a radar signal to deceive guided vehicles, such as airborne vehicles that avoid aircraft missiles, or sonar vehicles that deceive submarine torpedoes.

A conventional fake target deployment system disclosed in U.S. Patent No. 5,814,754 (issued on September 29, 1998) is known in the prior art related to the guided car. This is because, as illustrated in FIG. 1, a false target 2 is disposed at a distance from the target 1 to attract the missile M, so that the missile can mislead the target and attack the false target. The technical structure is described in detail and will be more readily understood when reference is made thereto.

However, in the prior art, there is a problem in that the shape of the object is uneven and the risk of malfunction is high, while the attracting ability of the missile is considerably reduced and impractical. In addition, the inside air of the fake target is not shielded easily, and the inside air can not be easily maintained, and the shape can not be maintained. Especially, when the fake target is blown in the wind or when it is raining or can not be used at sea, .

1. U.S. Pat. No. 5,814,754 (Sep. 29, 1998).

SUMMARY OF THE INVENTION An object of the present invention is to provide a tamper-evident body that expands by compressed air to expand the requirement for proposal (RFP) of a three-dimensional reflection surface and increase the reflectance of a guidance car radar signal, And the airbag guided vehicle body guards the air guided vehicle.

Another object of the present invention is that the polyhedron is assembled or separated by an engaging means provided at an outer corner (side) and a vertex, and it is possible to construct various types of three-dimensional dejectors according to the engaging structure, And an object of the present invention is to provide an air inflatable guided vehicle which can enlarge the area and further increase the reflection efficiency.

The present invention relates to an airtight guided car charger comprising: a polyhedron formed by forming an air tube along the edge of a three-dimensional figure surrounded by a polygonal surface, the air tube being adapted to be inflated automatically by a gas injector coupled to an air inlet; A cover which surrounds the polyhedron to form a polygonal reflecting surface; And a reflective coating layer on which the reflective electromagnetic wave reflective material is applied to the reflective surface.

According to another aspect of the present invention, there is provided a reflective coating layer on the inner surface of the concave portion, the concave portion being recessed inwardly of the polyhedron.

According to the present invention, the polyhedron is provided with a connecting line connecting the vertex and the center of the polyhedron in a straight line.

According to the present invention, the polyhedron is provided with a coupling means for fixing the cover to the corner and the apex.

In the present invention, a compactly folded diaphragm is floated on the sea so that a gas injector is exposed to water and a compressed gas is injected into the air tube to rapidly expand the three-dimensional polyhedron, and by a plurality of reflection coating layers provided on the surface of the polyhedron, It is possible to deceive the signal efficiently and to direct the attack of the missile to a false target.

Further, the present invention can be constituted by various forms of three-dimensional polyhedrons such as a triangular plane, a square plane, a pentagonal plane, and the like, as well as its shape and size can be changed, and the specifications (size or volume) Surface area, and the like, and can be effectively applied. Further, the reflectivity of the radar signal, that is, the efficiency of induction (the efficiency of deception) is improved, and excellent scalability and variability are obtained.

Further, the present invention provides an effect of expanding the reflection area to the inner surface through the concave recessed portion of the deck body and improving the deodorizing efficiency of the guided vehicle. Also, by connecting the corners of the polyhedron with connecting lines, the shape of the deceased body is kept constant during expansion, and is uniformly stabilized without being distorted or biased. In addition, in the present invention, the cover surrounding the polyhedron is fixed by the engaging means so that the shape of the cover is kept constant without being entangled or disturbed when folded or unfolded.

As described above, the air inflatable guided vehicle of the present invention has the effect of neutralizing the attack power of the enemy in marine combat and safely protecting the target (army) from external attack.

Brief Description of the Drawings Fig. 1 is a view showing a conventional guided missile according to the prior art.
2 is a view showing an internal polyhedron 10 of an air inflatable type inductively powered vehicle according to a preferred embodiment of the present invention.
FIG. 3 is a view showing an air inflatable guided-missile-car body 100 according to the present invention. FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. A detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

The air inflatable guided missile type vehicle body 100 according to the present invention according to the drawing is formed by forming an air tube 12 along a three-dimensional shape edge 13 surrounded by a polygonal surface, A polyhedron 10 adapted to be inflated automatically by a gas injector 18 coupled to the gas injector 18; A cover 20 covering the polyhedron 10 to form a polygonal reflecting surface; And a reflective coating layer (30) on which the reflective electromagnetic wave reflective material is applied to the reflective surface.

The above is explained in more detail as follows.

First, the air inflatable guided-carburetor (100) of the present invention comprises a polyhedron (10) expanded by air, a cover (20) surrounding the polyhedron, and a reflective coating layer (30,30a) provided on the reflective surface of the cover.

The polyhedron 10 has a three-dimensional structure surrounded by polygonal surfaces and has an air tube 12 formed along the edge 13 and the corner point 14. The air tube 12 is formed of a polygonal shape such as a triangle, A plurality of reflective surfaces are provided inside the tube 12. Referring to FIG. 1, the polyhedron 10 forms a triangular or quadrangular reflective surface on the circumferential surface of the polyhedron by orienting one corner of the triangular pyramid toward the center, will be.

The polyhedron 10 is provided with a connecting line 17 connecting the vertex 14 and the central portion of the polyhedron 10 in a straight line. That is, the polyhedron 10 collects the connection lines 17 coupled to the outer corner 14 at the center of the polyhedron, and maintains its shape uniformly when the diaphragm is deployed. That is, the connecting line 17 connects the vertexes and the center of the polyhedron in a straight line, and pulls the air tube in tension while the tensile force acts on the air tube. On the other hand, the connection line is provided with attachment means such as shackles and rings, and is easily detachable to a ring of a vertex or the like, and is provided with an adjustment member for varying the length and tensile force of the connection line.

The air tube 12 is provided with one or a plurality of air injection openings 16 for injecting gas, and a gas injector 18 is coupled to the air injection opening to expand the air tube. The gas injector 18 is for injecting a compressed gas, and is composed of an automatic gas injector or an electromagnetic automatic gas injector. The gas injector 18 is provided with one or a plurality of injectors at equal intervals according to the size of the air tube. First of all, the automatic gas injector is composed of a gas cylinder, a bobbin, and a water sensor. As the water sensing sensor is exposed to water, the gas cylinder is opened by the bobbin to which the elastic force of the spring acts, the compressed gas (CO 2) is forcedly injected into the air inlet 16, (10). Alternatively, the electromagnet type automatic gas injector is configured such that the electromagnet is in contact with water having electrical conductivity, and at the same time electric current is conducted, the bobbin is operated to open the gas cylinder and inject the compressed gas into the air tube. The gas cylinder rapidly expands the air tube by supplying a compressed gas at an average pressure of 100 to 110 mmhg, and is manually operable by a male-type erector 19 connected to the bobbin.

The air tube 12 is preferably composed of a coating material (TPU 0.18MM) coated on both sides of a raw material of nylon 120 denier, and is composed of synthetic rubber, synthetic resin, etc. having watertightness (watertightness) and water resistance.

The cover 20 forms a polygonal panel (reflecting surface) corresponding to each surface of the polyhedron, and joins the edges of the panels with sewing so as to surround the polyhedron to form a reflecting surface on each surface.

According to the present invention, the cover 20 is formed with a recessed portion 22 recessed inwardly of the polyhedron 10, and a reflective coating layer 30a is provided on the inner surface of the recessed portion 22. [ That is, the cover 20 surrounds the polyhedron and forms a triangular reflective surface on the periphery as shown in FIG. 3, and a concave recessed portion 22 is formed therebetween.

The cover 20 is provided with at least one or a plurality of cut-out portions 24 for introducing a polyhedron into selected edges 13 of the polyhedron. The cut-out portion 24 is provided with a fastener, a velcro tape, A button or the like so as to easily open or shut off. That is, the cover 20 has a function of inserting a polyhedron inward through the cutout 24 and fixing a vertex connecting line at the center, or engaging the cover with the fixing means, and fixing the edges (sides) And the like.

The reflective coating layers 30 and 30a are formed on the outer surface of the cover and on the inner surface of the recessed portion 22, that is, on the reflective surface of the deaf-mute body, to increase the reflectance of the radar signal. The reflective coating layer (30, 30a) is formed on the surface of the fabric with a thin metallic electromagnetic wave reflecting material having a good reflectance of a radar signal. The reflective coating layers 30 and 30a are made of copper (Cu), chromium (Cr), aluminum (Al) or the like having high electromagnetic wave reflectivity and preferably have a coating layer of brass And the surface of the coating layer is plated with chromium, the reflectance of the electromagnetic wave (radar signal) is excellent, so that the radar signal of the guided vehicle detects and attacks the deceased.

The reflective coating layers 30 and 30a may be integrally formed or separately manufactured depending on the size (size) of the deactivated object. That is, a metallic coating layer is formed on the reflective surface of the cover 20 to make the reflective coating layer integrally or the cover 20 is formed using nylon oxspot 420 denier, and the metallic coating layer The reflective coating plate may be separately manufactured and attached.

The polyhedron 10 has a coupling means 40 for fixing the cover 20 to the corner 13 and the corner point 14 so that the air tube expands and the cover is unfolded to a certain shape. The engaging means 40 is constituted by a fixing pin and a ring, a buckle, a button, a Velcro tape and the like.

By using the hooks of the coupling means 40 provided at the corners and the vertexes, the hand-held body 100 can be easily lifted and collected and can be connected to other hand-held bodies, thereby enlarging the size of the hand- Configuration is possible.

As described above, the air inflatable guided missile type imager 100 of the present invention is stored in a storage bag in a compactly folded state, and detects an enemy guided missile attack and throws it at sea. The gas injector is operated to inject compressed gas into the polyhedron to swiftly inflate and to float on the sea to deceive the radar signal of the missile. Particularly, the three-dimensional reflection surface provided on the circumferential surface of the hand-held body has excellent multi-faceted three-dimensional reflection action and has excellent degeneration efficiency. On the other hand, the de-icing body expands to the size of 4 ~ 12M when deployed, and it forms a fake target similar to the target warship or larger than the target, so guided missiles are guided to detect this fake target, It becomes effectively deceitful.

10: polyhedron 12: air tube 13: corner (side) 14: corner point
16: air inlet 17: connecting line 18: air inlet 19:
20: cover 22: recessed portion 24: incised portion 30: reflective coating layer
40: coupling means

Claims (4)

In the air inflatable guided vehicle,
The air tube 12 is formed along the edge 13 of the three-dimensional figure enclosed by the polygonal surface and the air tube 12 is deformed by the gas injector 18 coupled to the air inlet 16, (10);
A cover 20 covering the polyhedron 10 to form a polygonal reflecting surface;
And a reflective coating layer (30) on which the reflective electromagnetic wave reflective material is applied to the reflective surface.
The method according to claim 1,
Wherein the cover (20) is provided with a recessed portion (22) recessed inwardly of the polyhedron (10) and a reflective coating layer (30a) is formed on the inner surface of the recessed portion (22).
The method according to claim 1,
Wherein the polyhedron (10) is provided with a connecting line (17) for connecting the vertex (14) and the center portion in a straight line.
The method according to claim 1,
Wherein the polyhedron (10) is provided with a coupling means (40) for fixing the cover (20) to the corner (13) and the apex (14).

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