KR100750365B1 - A retractable trihedron radar reflector for life boats and small boats - Google Patents

Abstract

A receiving-type trihedron radar reflector for a life boat and the radar reflector is provided to increase detection probability by scattering a radar signal for the ship in all directions, thereby improving radar reflection performance of the life boat and the small ship. In a receiving-type trihedron radar reflector for a life boat and the radar reflector, a radar reflector body(100) is composed of an outer shell(110) contracted or expanded according to the charging state of compressed helium gas and an inner reflector(120) folded and contained in an inner space of the outer shell at normal times and automatically unfolded in an emergency when the volume of the outer shell is expanded by injecting the compressed helium gas. The radar reflector body floats in the air by expanding the volume of the outer shell through charging of the compressed helium gas. A radar reflector receiving box(200) temporally contains the radar reflector body if the compressed helium gas is charged in an inner space of the outer shell. A rope(300) joins the radar reflector body to the radar reflector receiving box so that the radar reflector body, floating while the compressed helium gas is filled in the inner space of the outer shell, is kept afloat in the air separately from the radar reflector receiving box in a predetermined gap without completely separating the radar reflector body to the air. The expanded shape of the inner reflector forms one sphere comprising 12 reflecting plates of the same fan-shape and size by radially combining 8 trihedron-type reflector elements with good reflection characteristic, with centering on the same center of a sphere. Spring hinges are installed at least one of three inner edges of each reflector element. The reflecting plates are folded or unfolded by the spring hinges.

Description

Retractable Trihedron Radar Reflector for Life Boats and Small Boats}

1 is a view showing a lifeboat and a small ship accommodating radar reflector using a trihedron-shaped reflector according to the present invention to realize its function.

Figure 2 is a perspective view showing a state in which the internal reflector that is one component of the present invention is unfolded.

Figure 3 is a view from above of the unfolded state of the internal reflector which is one component of the present invention.

4 is a view showing the RCS characteristics of a lifeboat and a small ship accommodating radar reflector using a trihedron-shaped reflector according to the present invention.

<Description of Major Symbols in Drawing>

100: the radar reflector body

110: outer cell

120: internal reflector

130: spring hinge

200: radar reflector storage box

300: rope

The present invention relates to a radar reflector. More specifically, the present invention relates to a lifeboat and a small ship accommodating radar reflector using a trihedron shaped reflector.

Good visibility of radar signals in the event of poor visibility due to areas of high sea traffic or fog is critical to the safety and viability of the ship, especially for small ships or evacuation lifeboats in distress during bad weather and accidents. It is directly connected to the element.

Nevertheless, lifeboats and small ships are usually made of rubber or plastic, which is usually a non-conductor, so the radar reflectivity of the hull is considerably reduced. The reality is that they rely on expensive EPIRB equipment using satellites and satellites.

Therefore, it is necessary to attach a separate radar reflector for these lifeboats and small ships, but the existing radar reflectors are fixed in shape and attached to the structure of the hull. The attachment of radar reflectors is very difficult.

The present invention has been proposed to solve the above problems, usually stored in a folded state on the hull and then expanded in an emergency to rise above the hull to reflect the radar from the outside structure or material of lifeboats and small ships, etc. It is an object of the present invention to provide a lifeboat and a small ship accommodating radar reflector using a trihedron type reflector capable of functioning as a radar reflector irrespective of the purpose.

Other objects and advantages of the present invention will be described below, which are not limited to the matters set forth in the claims and the disclosure of the embodiments thereof, but also to the broader ranges by means and combinations within the range readily recited therefrom. Add that it will be included.

In order to achieve the above object, the present invention, the outer cell 110, the volume of the contraction or expansion depending on whether the compressed helium gas is filled, and existing in the inner space of the outer cell 110, but the outer cell in normal The inner reflector 120 exists in the folded state in the inner space of the inner cell 110 and expands automatically when the volume of the outer cell 110 expands due to the filling of the compressed helium gas. It comprises a, the radar reflector main body 100 is to rise to the air due to the expansion of the volume of the outer cell 110 by the filling of the compressed helium gas; A radar reflector storage box 200 temporarily storing the radar reflector main body 100 in a state in which the compressed helium gas is not filled in the inner space of the outer subcell 110; And the radar reflector main body 100, which floats with the compressed helium gas filled in the inner space of the outer cell 110, is not completely spaced in the air and floats in the air at a predetermined distance from the radar reflector storage box 200. A lifeboat and a small-sized accommodating radar reflector using a trihedron-shaped reflector including a rope 300 for binding the radar reflector main body 100 to the radar reflector storage box 200 to maintain a state To present.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are assigned to the same components as much as possible, even if shown on different drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, the following will describe a preferred embodiment of the present invention, but the technical idea of the present invention is not limited thereto and may be variously modified and modified by those skilled in the art.

1 is a view showing a lifeboat and a small ship accommodating radar reflector using a trihedron-shaped reflector according to the present invention to realize its function, and FIGS. 2 and 3 are one configuration of the present invention. It is a figure which shows the state in which the internal reflector which is an element is unfolded.

The radar reflector body 100 is an element that performs the essential function of the present invention to reflect radar from the outside. The radar reflector main body 100 includes an outer cell 110 and an inner reflector 120, and when the volume of the outer cell 110 is expanded by the filling of the compressed helium gas, it rises to the air.

The outer cell 110 is formed in the form of a balloon, which has a property of contracting or expanding its volume depending on whether the compressed helium gas is filled. When the compressed helium gas is filled into the inside, a spherical shape is formed due to an increase in the internal pressure. When the helium gas is expanded and the compressed helium gas escapes to the outside, it contracts due to the decrease of the internal pressure. The outer cell 110 is preferably made of a rubber material excellent in shrinking or expanding properties.

The inner reflector 120 is present in the inner space of the outer cell 110. The inner reflector 120 is unfolded, as shown in FIGS. The trihedron reflector elements are radially coupled to each other based on the same centripetal point to form a single spherical shape consisting of a total of 12 reflectors having the same fan shape and size as a whole.

As the internal reflector 120 takes the shape of a sphere, the reflection characteristics of the lifeboat and the small ship accommodating radar reflector using the trihedron-shaped reflector according to the present invention are considerably as described below. An improvement effect occurs.

In general, the reflection characteristics of the reflector can be expressed as a radar cross section (RCS), which is a ratio of the radar signal power projected on the surface of an object to the back-scattered signal power in the direction of the radar. It is a value quantifying how much the object reflects or scatters the radar signal. On the other hand, in the case of the radar reflector, the quantitative value of the RCS is important, but the orientation is also an important factor. In other words, if an object scatters radar signals only in a specific direction, the probability that ships, aircraft, and land radars will detect the object will be reduced, whereas if an object scatters signals in all directions, the probability of detection of the object will increase. Will be.

As shown in FIG. 4, the directionality of the RCS is clearly revealed when displayed in the polar coordinate system, and the internal reflector 120 according to the present invention exhibits omni-directional characteristics.

Meanwhile, as illustrated in FIGS. 2 and 3, a spring hinge 130 is positioned at any one or more positions of three inner edges existing for each reflector element constituting the inner reflector 120. Each of the reflecting plates may be folded or unfolded by the 130. As a result, the inner reflector 120 is normally folded in the inner space of the outer cell 110 in a contracted state, but when the volume of the outer cell 110 expands due to the filling of the compressed helium gas, the spring hinge ( Each reflector is automatically unfolded by the elastic force of 130 to take the form of a spherical radar reflector.

The internal reflector 120 is preferably made of anodized aluminum flat plate or light plastic foam coated with a thin aluminum foil in order to have high reflectivity and light weight.

The radar reflector storage box 200 serves to temporarily receive the radar reflector main body 100 in a state in which the compressed helium gas is not filled in the inner space of the outer cell 110 at normal times. On the other hand, when the volume of the outer cell 110 is expanded by the filling of the compressed helium gas in an emergency, the radar reflector main body 100 is to escape the radar reflector storage box 200 to rise to the air.

In the present invention, the material of the radar reflector storage box 200 is not particularly limited, but in view of the fact that the present invention is utilized for rescue in the event of lifeboats and small vessels, the radar reflector storage box 200 is external It is very preferable to be made of a material which is not damaged by the impact (for example, the impact caused by waves) and does not corrode by sea water.

Rope 300, as shown in Figure 1, the radar reflector main body 100, which is floating in the compressed helium gas filled in the inner space of the outer cell 110 is not completely spaced in the air radar reflector storage box It serves to bind the radar reflector main body 100 to the radar reflector storage box 200 to maintain a state in which it floats in the air at a certain distance from the (200).

The rope 300 is preferably made of a stretchy and tough nylon material, and further preferably, the length of the rope 300 is 8 meters to 12 meters to induce an accurate tomtom effect by the radar reflector body 100.

The above description is merely illustrative of the technical idea of the present invention, and various modifications, changes, and substitutions may be made by those skilled in the art without departing from the essential characteristics of the present invention. will be. Accordingly, the embodiments disclosed in the present invention and the accompanying drawings are not intended to limit the technical spirit of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by the embodiments and the accompanying drawings. . The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

As described above, the lifeboat and the small-sized accommodating radar reflector using the trihedron-shaped reflector according to the present invention are normally folded and folded on the hull and emerge from the hull and emerge from the outside to emerge from the outside. By reflecting the radar, it can serve as a radar reflector irrespective of the structure or material of lifeboats and small ships. In addition, the lifeboat and the small ship accommodating radar reflector using the trihedron-shaped reflector according to the present invention scatter the radar signal to the hull in all directions, thereby significantly increasing the detection probability.

As a result, the present invention not only significantly increases the radar reflectivity of lifeboats and small ships, but also induces an economic synergy effect that replaces expensive equipment used for emergency rescue of conventional lifeboats and small ships.

Other effects of the present invention, as well as those described in the above-described embodiments and claims of the present invention, as well as potential effects that may occur within the range that can be easily estimated therefrom and potential advantages that contribute to industrial development It will be added that it will be covered by a wider scope.

Claims (9)

delete delete delete delete Depending on whether the compressed helium gas is filled, the volume of the outer cell 110 contracts or expands, and is present in the inner space of the outer cell 110, but normally exists in the folded state in the inner space of the outer cell 110 In the meantime, when the volume of the outer cell 110 is expanded by the filling of the compressed helium gas, the inner reflector 120 is automatically expanded to take the form of a radar reflector. Radar reflector main body 100 by which when the volume of the outer cell 110 is expanded by this to rise to the air by this; A radar reflector accommodating box 200 for temporarily accommodating the radar reflector main body 100 in a state in which the compressed helium gas is not filled in the inner space of the outer cell 110; And the radar reflector main body 100, which floats with the compressed helium gas filled in the inner space of the outer cell 110, is not completely spaced in the air and floats in the air at a predetermined distance from the radar reflector storage box 200. A lifeboat and a small-sized accommodating radar reflector using a trihedron-shaped reflector including a rope 300 for binding the radar reflector main body 100 to the radar reflector storage box 200 to maintain a state To The inner reflector 120 has a total of 12 triangular reflector elements having excellent reflecting properties and having a same fan shape and size as a whole as a result of combining radial elements with respect to the same center point. Form a sphere consisting of two reflectors, The spring hinge 130 is located at any one or more positions of three inner edges existing for each reflector element, and the triangular body is characterized in that the respective reflecting plates are folded or unfolded by each spring hinge 130. Retractable radar reflector for lifeboats and small ships using Trihedron) reflectors. The method of claim 5, The internal reflector 120, A lifeboat and a small-sized accommodating radar reflector using a trihedron-shaped reflector, characterized by being made of anodized aluminum flat plate. The method of claim 5, The internal reflector 120, A lifeboat and a small-sized accommodating radar reflector using a trihedron-shaped reflector, which is made of a light plastic foam coated with a thin aluminum foil on its surface. delete delete

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