JP2014059233A - Corner reflector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a corner reflector that descends while sustaining gyration with a stable velocity toward the same gyration direction upon descending.SOLUTION: A corner reflector 10 reflecting a radio wave comprises: a balloon 1b that is inflated by a gas pressure when gas is supplied to the inside; and a radio wave reflection film 1a that is attached to the balloon 1b and reflects the radio wave. The radio wave reflection film 1a constitutes eight radio wave reflection areas by sharing the same center and being mutually orthogonal, and includes an umbrella body 2 to be expanded by inflation of the balloon 1b. The umbrella body 2 is attached to the radio wave reflection film so as to cover a part of the balloon 1b, while having a gap provided between the balloon 1b and the umbrella body, and has one or more vent holes 2a penetrating from the gap toward the outside. The vent holes 2a are directed toward a direction inclined with respect to a straight line connecting the center to an installation positions of the vent holes 2a. The inclination includes a horizontal component.

Description

  The present invention relates to a corner reflector that functions as a decoy or the like by reflecting radio waves.

The corner reflector is described in Patent Document 1, for example. The corner reflector of patent document 1 has the structure of FIG. As shown in FIG. 1, the corner reflector has eight sets of three radio wave reflection films 21 that are orthogonal to each other. As a result, regardless of the angle at which the radio wave enters the corner reflector, it can be reflected by the corner reflector in the direction in which the radio wave has entered.
For example, as shown in FIG. 2, both the radio wave A and the radio wave B can be reflected in the incident direction by the radio wave reflection films 21 orthogonal to each other.

  The corner reflector is emitted from a flying object, a ship, the ground, etc., and then expands into the shape of FIG. 1 in the air or on the water. For this purpose, the corner reflector includes a balloon 23 as in the example of FIG. The balloon 23 becomes spherical when inflated. Due to this expansion, the radio wave reflection film 21 is attached to the inside of the balloon 23 so that each radio wave reflection film 21 is developed as shown in FIG. In the example of FIG. 1, the cylinder 25 inflates the balloon into a spherical shape by supplying gas into the balloon 23.

  With the configuration described above, for example, when a radio wave is incident on a corner reflector deployed in the air from a tracking radar device or a radar seeker of a missile, the corner reflector reflects in the direction in which the radio wave is incident as shown in FIG. Can do. As a result, the corner reflector can be used as a decoy for the radar.

  In addition, there exists the following patent document 2 as another prior art document of this application.

Japanese Patent Laid-Open No. 04-355388 JP 09-190585 A

About the corner reflector as described in the said patent document, in order to deceive an enemy for a long time, the device for lengthening the time to float in the air is required.
In contrast, as shown in FIG. 3, a method of hanging a corner reflector on a parachute and lowering the corner reflector or a corner reflector that is lighter is used.
FIG. 3A is a view from the time when the ship 31 having the launch pad 32 releases the flying object 33 until the parachute 35 and the corner reflector 34 are deployed.
In this figure, after the parachute 35 and the corner reflector 34 are emitted from the flying body 33, the deployment is performed at an appropriate timing.

FIG. 3B is a diagram of a corner reflector in which the weight is reduced and the descent speed is suppressed by using air resistance.
In this figure, after launching and deploying in the same manner as in FIG. 3A, the corner reflector 36 is restored to its original shape in order to perform three-dimensional expansion (shafts 37a and 37b). 37c) is covered with a radio wave reflection film 37d. With such a configuration, the corner reflector 36 that has been stretched is configured to freely fall by suppressing the descent speed by utilizing air resistance.

However, when using a parachute as described above, it is possible to suppress the speed, but there is a problem that the accommodation volume of the parachute becomes large, and there is also a problem that the suspension rope is entangled and not properly deployed. Conceivable.
Further, in the case of the above free fall, since the radio wave reflection surface is flat, it may be difficult to sufficiently suppress the speed.

To deal with these problems, it is conceivable to use a corner reflector 38 provided with an umbrella 39 having a hemispherical shape when deployed as shown in FIG.
Since this corner reflector 38 does not use a suspension cable as shown in FIG. 3A, it is possible to appropriately deploy the suspension cable without being intertwined when descending, and in FIG. Unlike the shape of the corner reflector, since a spherical corner reflector is used, it is possible to suppress the descent speed.

Here, the corner reflector has different radio wave reflection capabilities depending on an angle and a position with respect to a radio wave emission source. For this reason, it is required to use a configuration in which there is no difference in radio wave reflection capability as much as possible regardless of the positional relationship between the radio wave emission source and the corner reflector.
Therefore, for example, in the case of a balloon having a spherical shape like the corner reflector 38 shown in FIG. 4, the configuration assumes that the balloon descends while turning around the rotation axis 39 a passing through the center of the corner reflector 38. It has become.

  However, the turning of the corner reflector 39 is uncertain depending on the air volume and the direction of the wind at the time of descent, and therefore turning at a constant pace cannot be controlled. Therefore, depending on the wind direction, etc., turning may stop at an angle where the radio wave reflection capability is weak with respect to the radio wave reflection source, and it may be found that the decoy is used to deceive the radio wave reflection source. There was a risk.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a corner reflector that performs a descent while continuing a turn at a stable speed toward the same turning direction during the descent.

In order to achieve the above object, according to the present invention, a corner reflector that reflects radio waves,
A balloon that expands with gas pressure when gas is supplied inside,
A radio wave reflection film that reflects radio waves attached to the balloon, and
The radio wave reflection film is expanded by the expansion of the balloon, shares the same center, and is orthogonal to each other to form eight radio wave reflection regions,
Furthermore, it comprises an umbrella body that expands by expansion of the balloon,
The umbrella is attached so as to cover a part of the balloon while providing a gap with the outer periphery of the balloon, and has one or more vent holes penetrating from the gap toward the outside. Have
The vent is oriented in a direction tilted with respect to a straight line connecting the center and the installation position of the vent,
A corner reflector is provided in which the tilt includes a horizontal component.

  According to the present invention, the vent is provided in a horizontal direction when the balloon is dropped.

Further, according to the first embodiment of the present invention, the balloon is a spherical balloon that expands into a spherical shape by supplying gas therein,
The radio wave reflecting film is attached to the inner wall of the spherical balloon.

Furthermore, according to the second embodiment of the present invention, the balloon is three annular balloons that are inflated by being supplied with a gas therein and are each annular.
The three annular balloons share the same center, and are formed so as to be orthogonal to each other two annular balloons when inflated,
The radio wave reflection film is attached to the outer wall of the annular balloon.

The corner reflector in the present invention is provided with an umbrella body connected to the balloon so as to cover a part of the balloon.
Thereby, when the corner reflector is lowered, the descent speed can be suppressed by air entering the gap between the umbrella and the balloon.
Furthermore, since the umbrella body has one or more vent holes that penetrate the umbrella body, the air that has entered the gap between the umbrella body and the balloon as it descends can be discharged outside the umbrella body. Therefore, it is possible to descend while maintaining the turning at a stable speed in a certain turning direction.

The structure of the corner reflector of patent document 1 is shown. It is a figure explaining the effect | action of a corner reflector. It is a figure of the corner reflector of a prior art. It is a perspective view which shows the corner reflector which has an umbrella body of a prior art. It is a perspective view which shows the corner reflector of this invention. It is a perspective view which shows the state in which the corner reflector of this invention is turning. It is a perspective view which shows the corner reflector using the spherical balloon of this invention. It is sectional drawing of the corner reflector using the spherical balloon of this invention. It is a perspective view of the corner reflector in the state which attached the gas cylinder of this invention.

  A preferred embodiment of the present invention will be described with reference to the drawings. In addition, the same code | symbol is attached | subjected to the common part in each figure, and the overlapping description is abbreviate | omitted.

FIG. 5 (A) is a perspective view showing an annular balloon used in the corner reflector in the present invention, and FIG. 5 (B) is a perspective view showing the corner reflector in the present invention.
In this figure, 1 is a corner reflector body, 1a is a radio wave reflecting film, 1b is an annular balloon, 2 is an umbrella, 2a is a vent, and 10 is a corner reflector.

In this example, the corner reflector body 1 is assumed to be composed of a radio wave reflection film 1a and an annular balloon 1b.
In this example, the radio wave reflection film 1a is formed of conductive fibers.
The conductive fiber may be, for example, a nylon fiber coated with a metal film (copper, silver, etc.).
In this example, the radio wave reflecting film 1a is composed of twelve sector-shaped films (center angle is 90 °), and has a structure in which the planes are assembled orthogonally when expanded. With this structure, when the annular balloon 1b is inflated, a total of eight sets of radio wave reflection areas composed of three radio wave reflection films 1a orthogonal to each other are provided.
In this example, there is a gap between the outer periphery of each radio wave reflecting film 1a and the annular balloon 1b, and the radio wave reflecting film 1a and the annular balloon 1b are formed by a plurality of wires or the like (not shown). Although it is assumed that they are connected, even when the annular balloon 1b is inflated, the outer periphery of each radio wave reflecting film 1a is designed to be in close contact with the annular balloon 1b. Good.

When the gas is supplied to the inside, the annular body balloon 1b is inflated by the gas pressure and becomes an annular shape.
The annular balloon 1b can expand the corner reflector body 1 with a gas amount that is significantly smaller than that of other shaped balloons (for example, spherical balloons). Therefore, there is a merit that the time required for extending the corner reflector body 1 can be shortened.
The annular balloon 1b may be formed of a plastic film such as polyolefin or polyvinyl chloride.
Preferably, it is desirable to prevent the annular balloon 1b from expanding beyond a predetermined limit volume by wrapping the outer periphery of the annular balloon 1b with restraining fibers.

In this example, the umbrella body 2 has a hemispherical shape when deployed, is attached to the outer wall of the annular balloon 1b, and is expanded as the annular balloon 1b expands.
When the shape of the annular balloon 1b is not spherical, the umbrella body 2 may have a shape along the outer wall of the annular balloon 1b.

Since the umbrella body 2 has no suspension cord compared to the parachute used in the prior art, it is possible to eliminate the risk that the umbrella body 2 does not expand due to entanglement. Moreover, it can open compulsorily and rapidly by expansion | swelling of the annular body balloon 1b. Furthermore, the accommodation volume can be suppressed by using a thin and light cloth for the umbrella 2.
The umbrella 2 may be made of nylon or the like used in conventional parachutes.

As shown in FIG. 5B, the umbrella body 2 has one or more vent holes 2a through which the umbrella body penetrates.
In this example, four vent holes 2a are provided, but one or more vent holes may be set. However, when two or more are installed, in order to stably turn the corner reflector 10, all the vents 2a are directed horizontally when the corner reflector 10 is dropped vertically, and at equal intervals. It is desirable to install.

For example, when the umbrella body 2 is manufactured by sewing a plurality of planar members (not shown), the ventilation hole 2a may be configured to provide the ventilation hole 2a by sewing together with a part thereof being loosened. .
Moreover, the structure which provides the ventilation hole 2a by preparing two or more plastic cylindrical-shaped members (not shown) and fixing this in the form penetrated with respect to the umbrella body 2 at equal intervals may be sufficient.

FIG. 6 is a perspective view showing a state where the corner reflector of the present invention is turning.
When the corner reflector 10 descends, air enters the gap between the umbrella body 2 and the corner reflector body 1, thereby suppressing the descending speed of the corner reflector 10. In this case, since the umbrella body 2 has the vent 2a, the air that has entered the gap between the umbrella 2 and the corner reflector body 1 is discharged to the outside by the vent 2a.
As a result, when the corner reflector 10 is lowered, the corner reflector 10 turns around the rotation shaft 3 in a certain turning direction.
Therefore, in order to make it easy for air to enter the gap between the umbrella body 2 and the corner reflector body 1, a configuration in which the umbrella body 2 is attached in a form that does not adhere to the corner reflector 10 is desirable. When the umbrella body 2 is brought into close contact with the corner reflector 10, the lower end of the umbrella body 2 is above the center of the annular balloon 1b in order to allow air to enter the umbrella body 2. It is necessary to design in such a size.

Here, with respect to the direction of the vent 2a, in order to achieve the purpose of assisting the turning of the corner reflector 10, the corner reflector 10 has a straight line connecting the center of the corner reflector 10 and the installation position of the vent 2a. It is necessary to be attached in a direction having a component in the turning direction (horizontal direction).
Specifically, for example, when the vent 2a is attached in a state in which the corner reflector 10 is directed vertically upward when the corner reflector 10 is vertically dropped, air is not discharged in a direction that assists the turning of the corner reflector 10, and thus the present invention. You will not be able to achieve your goal.
Furthermore, for example, even when the corner reflector 10 is attached in the same direction as a straight line connecting the center of the corner reflector 10 and the installation position of the vent 2a, air is not discharged in the direction that assists the turning of the corner reflector 10 in the same manner. The goal cannot be achieved.
In other words, the vent 2a needs to be installed in a direction that has a component in the turning direction (horizontal direction) even slightly with respect to a straight line connecting the center of the corner reflector 10 and the installation position of the vent 2a. It will be.

Furthermore, by providing two or more vent holes 2a in the umbrella body 2 with an equal interval, it is possible to improve the stability of turning about the rotation shaft 3.
In addition, the turning speed can be adjusted by adjusting the size of the vent 2a.

FIG. 7 is a perspective view showing a corner reflector using the spherical balloon of the present invention.
FIG. 7A is a perspective view showing a spherical balloon used in the corner reflector according to the present invention, and FIG. 7B is a perspective view showing the corner reflector according to the present invention.
In the above description, the corner reflector 10 using the annular balloon 1b has been described. However, for example, a configuration using the spherical balloon of FIG.
In this figure, 11 is a corner reflector body, 11a is a radio wave reflecting film, 11b is a spherical balloon, 12 is an umbrella, 12a is a vent, and 20 is a corner reflector.

  In the corner reflector 20 using the spherical balloon 11b in FIG. 7B, unlike the corner reflector 10 using the annular balloon 1b, a configuration is provided in which a gap is provided between the umbrella body 12 and the corner reflector body 11. Is mandatory. This is because if the umbrella body 12 is attached so as to be in close contact with the outer wall of the spherical balloon 11b, it becomes impossible to provide a space for air to enter between the umbrella body 12 and the spherical balloon 11b.

  Therefore, as shown in the sectional view of the corner reflector 20 using the spherical balloon 11b shown in FIG. 8, by providing the connecting member 14 between the umbrella body 12 and the corner reflector body 11, the umbrella body 12 and the corner reflector body 11 are provided. It is necessary to have a configuration in which a gap is provided between the two.

FIG. 9 is a perspective view of the corner reflector with the gas cylinder of the present invention attached.
The gas cylinder 5 is inflated by injecting gas into the annular balloon 1b when the corner reflector 10 is released from a flying body launched from a ship or the like, and at the same time, the umbrella body 2 is expanded.

When the annular balloon 1b is inflated and the umbrella body 2 is deployed, the gas cylinder 5 uses the intersection of the perpendicular line descending from the center of gravity of the annular balloon 1b and the surface of the annular balloon 1b as a connecting portion. Connected.
By connecting at such a position, the gas cylinder 5 can function as the posture stabilization weight of the corner reflector 10 even after the gas is injected.

  In this example, the gas cylinder 5 is injecting gas when the corner reflector 10 is released from the flying object, but starts to inject gas after a certain time has elapsed since being released from the flying object, or The gas injection may be started by remote control.

  The gas cylinder 5 may be, for example, a gas generator using explosives, and is operated so as to supply gas into the annular balloon 1b at a predetermined timing.

The present invention is not limited to the above-described embodiment, and various changes can be made without departing from the scope of the present invention.
The corner reflector 10 of the present invention may be used for purposes other than the use as a decoy. For example, you may use the corner reflector 10 of this invention in order to notify a victim's whereabouts like patent document 2. FIG.

1 corner reflector body, 1a radio wave reflection film,
1b Annular balloon (balloon),
2 Umbrella, 2a Vent, 3 Rotating shaft, 5 Gas cylinder,
10 corner reflector, 11 corner reflector body,
11a radio wave reflecting film, 11b spherical balloon (balloon),
12 umbrellas, 12a vents, 14 connecting members,
20 Corner reflector

Claims (4)

A corner reflector that reflects radio waves,
A balloon that expands with gas pressure when gas is supplied inside,
A radio wave reflection film that reflects radio waves attached to the balloon, and
The radio wave reflection film is expanded by the expansion of the balloon, shares the same center, and is orthogonal to each other to form eight radio wave reflection regions,
Furthermore, it comprises an umbrella body that expands by expansion of the balloon,
The umbrella is attached so as to cover a part of the balloon while providing a gap with the outer periphery of the balloon, and has one or more vent holes penetrating from the gap toward the outside. Have
The vent is oriented in a direction tilted with respect to a straight line connecting the center and the installation position of the vent,
The corner reflector according to claim 1, wherein the tilt includes a horizontal component.   The corner reflector according to claim 1, wherein the vent is provided in a shape directed in a horizontal direction when the balloon is vertically dropped. The balloon is a spherical balloon that expands into a spherical shape by supplying gas therein,
The corner reflector according to claim 1, wherein the radio wave reflecting film is attached to an inner wall of the spherical balloon. The balloons are three annular balloons that are inflated when gas is supplied to the inside and are each annular.
The three annular balloons share the same center, and are formed so as to be orthogonal to each other two annular balloons when inflated,
The corner reflector according to claim 1 or 2, wherein the radio wave reflection film is attached to an outer wall of the annular balloon.

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