KR20120032798A - Aviation warning light using led - Google Patents

Abstract

PURPOSE: An aviation warning light is provided to improve energy efficiency by maintaining high luminous intensity with low power through LEDs arranged in a lattice shape. CONSTITUTION: An LED unit mounting frame(111) is formed on the outer side of a light emitting body(110) in a lattice shape. An LED unit(120) is fixed to the LED unit mounting frame. A support member(130) supports the light emitting body. An external case(150) is separated from the light emitting body at a preset distance and surrounds the light emitting body. A socket base(170) is fixed under the support member.

Description

Aviation warning light using LED {AVIATION WARNING LIGHT USING LED}

The present invention relates to aviation failure lamps, and more particularly, to aviation failure lamps using LEDs.

In general, the aviation law mandates mandatory installation of aviation obstacles indicating height to prevent structures such as buildings or structures such as transmission towers from colliding with the aircraft. In particular, according to the regulations of the International Civil Aviation Organization (ICAO), not only mandatory installation of aviation obstacles, but also low-light aviation failures can emit above a certain candela (CD) value within the range of 6 to 10 degrees from the horizontal plane. Should be

As such, the aviation obstacle should be blinked so that the pilot of the aircraft can be easily identified from a long distance. Therefore, in the past, many incandescent bulbs or halogen bulbs having high brightness are used as aviation obstacle lamps, but such incandescent bulbs or halogen bulbs have a problem in that a lot of electric energy is consumed.

In addition, the aviation obstacle is usually installed on the protruding portion of the special structure made of only a skeleton, such as a communication pylon, and the conventional aviation failure, such as the flashing control device and the lamp is operated separately, there is a problem in maintenance, economic efficiency.

That is, by installing a plurality of lamps in a special structure, such as a communication pylon, by sharing one flashing control device at the bottom of the special structure, the failure of any one of the plurality of lamps or a failure of the flashing control device occurs There is a problem that you can not use the entire lamp, there is a problem that you need to replace all the facilities.

The present invention has been proposed to solve the above problems, and the object of the present invention is to provide aviation obstacles such as maintaining high brightness, simplifying maintenance, and increasing economic efficiency while reducing power consumption.

Other objects and advantages of the present invention can be understood by the following description, and will be more clearly understood by the embodiments of the present invention. Also, it will be readily appreciated that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the claims.

Aviation obstacle lamp according to an aspect of the present invention for achieving the above object, while forming a polyhedron, at least one LED unit mounting frame is formed in a lattice form on the outer surface of the polyhedron in the form of a lattice, the polygon A light emitting body having a PCB film connected to terminals of the LED unit penetrating the LED unit mounting frame on an inner surface of the face, and forming an empty space therein; The LED unit inserted into and fixed to the LED unit mounting frame of the light emitting body, the panel being inserted into and fixed to the LED unit mounting frame and fixed to a panel having a terminal pin formed at a lower portion thereof penetrating the LED unit mounting frame; An LED unit having an LED connected to the terminal pin; A flashing control device disposed in an empty space inside the light emitting body to supply power to the PCB film of the light emitting body and control lighting; A support member having a plate shape for supporting the light emitting body and the flashing control device; And a spiral socket base disposed at a lower end of the support member opposite to the light emitting body to supply power to the flashing control device.

Preferably, the light emitting body, the body of the polygonal pillar, the upper surface of the quadrangle, the upper inclined surface connecting the body of the polygonal pillar and the upper surface of the quadrangle, the lower inclined surface connecting the body of the polygonal pillar and the support member The lower surface is configured to include and oppose the upper surface is open.

The LED unit may further include a reflector between the panel and the LED, the opening being widened in the direction of the LED.

In addition, the aviation obstacle lamp further includes a light transmissive outer case that is spaced apart from the light emitting body by a predetermined distance and surrounds the light emitting body and is supported by the support member.

In addition, the flashing control device such as the aviation obstacle, the rectifying unit for rectifying the AC voltage to convert the DC power to output; A constant voltage unit converting the DC power output from the rectifier into a constant voltage and outputting the constant voltage; An illuminance detector for detecting an ambient illuminance such as an aviation obstacle and outputting an illuminance detection value; And a controller configured to selectively output the constant voltage output from the constant voltage unit to the LED according to the illuminance detection value output from the illuminance detection unit.

In this case, it is preferable that an illuminance sensor is installed in the socket base, and the illuminance detection unit detects an ambient illuminance using the illuminance sensor.

In the present invention as described above, unlike the incandescent bulb or halogen bulb by arranging a plurality of small power LEDs in the form of a lattice, it maintains high brightness at low power to increase energy efficiency. In particular, by placing a reflector beneath each small LED, the light intensity can be increased to facilitate identification of aviation obstacles at a long distance.

In addition, the present invention enables the individual operation of each aviation obstacle, such as by integrally mounting the point heat control device inside the aviation failure, simplify the maintenance and increase the economic efficiency.

In addition, the present invention employs a standard bulb base light bulbs for aviation failure lamps, it is possible to easily replace the existing incandescent bulbs with the aviation failure lights according to the present invention to reduce the cost of replacing the facility.

1 is a perspective view of a aviation obstacle and the like according to an embodiment of the present invention.
2 is an exploded perspective view of a aviation obstacle according to an embodiment of the present invention.
3 is a view showing the configuration of the blink control device of FIG.
Figure 4 is a view showing an example of installing another aviation obstacle in the present invention to the steel tower structure.

The foregoing and other objects, features and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings, in which: There will be. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a aviation obstacle and the like according to an embodiment of the present invention.

As shown in FIG. 1, the aviation obstacle lamp according to the present embodiment includes a light emitting body 110 having a lower end portion as a polyhedron and having a plurality of LEDs mounted on an outer surface thereof, and supporting the light emitting body 110. Member 130, the outer case 150, the support member which is supported by the support member 130 and spaced apart from the light emitting body 110 by a predetermined distance to surround the light emitting body 110 130) a socket base 170 secured below.

The light emitting body 110 shown in FIG. 1 connects the body 110a of the octagonal pillar, the upper surface 110b of the quadrangle, the body 110a of the octagonal pillar and the upper surface 110b of the shooting type. It consists of an upper inclined surface (110c), the lower inclined surface (110d) connecting the body 110a and the support member 130 of the octagonal pillar, the lower surface facing the upper surface (110b) is open. The lower inclined surface 110d is fixed to the support member 130, and an empty space is formed inside the light emitting body 110, and a blinking control device is located in an empty space on the open lower inclined surface 110d. Acrylic may be used as the light emitting body 110, but is not necessarily limited thereto.

In addition, the LED unit mounting frame 111 is formed in a lattice form on the outer surface of the light emitting body 110, and the LED unit 120 is fixed to each LED unit mounting frame 111. As shown in FIG. 1, each of the LED unit mounting frames 111 has a concave frame shape, and a connection terminal 119 is formed through which terminal pins 127 of the LED unit 120 are connected. The LED unit 120 is a PCB (Printed Circuit Board) panel 121 is inserted into the intaglio of the LED unit mounting frame 111 and the LED 125 to be fitted to the PCB panel 121, and the PCB And a reflector 123 fixed between the panel 121 and the LED 125.

The LED unit 120 and the LED unit mounting frame 111 is removable. The reflector 123 is a form in which the opening is widened from the bottom to the upper direction, and a material in which stainless steel is coded is used. However, the reflector 123 is not limited thereto and may be employed without limitation as long as it can reflect light. .

As described above, the LED unit 120 has a reflector 123 having an opening opening upward in the upward direction, so that the light emitted from each LED 125 is directed upward, so that brighter light spreads in all directions. Indicates. However, the reflector 123 may not necessarily be employed.

A space is formed inside the light emitting body 110, and a thin PCB film is printed on the inner surface of the light emitting body 110 in which a power line for supplying power to the LED 125 of the LED unit 120 is printed in a pattern form. The terminal pin 127 of the LED unit 120 penetrating through the connection terminal 119 of the LED unit mounting frame 111 is connected to the PCB film. Preferably, the terminal pin 127 and the PCB film of the LED unit 120 is fixed by soldering. In the empty space formed inside the light emitting body 110, there is a flashing control device for controlling the flashing of the LED (125). By installing a flashing control device in the internal empty space of the light emitting body 110, as in the prior art, a plurality of aviation failure lights share a single flashing control device, when all one of the flashing control device failure occurs operation of the aviation failure lights, etc. Solve the problem of not doing this.

The support member 130 is fixed to the lower inclined surface 110d of the light emitting body 110 to support the light emitting body 110 and surround the light transmitting outer case 150 surrounding the light emitting body 110. I support it. The support member 130 is a circular or square acrylic plate. In addition, the outer case 150 may transmit light emitted from the plurality of LEDs 125 disposed on the outer surface of the light emitting body 110, and may be reinforced acrylic to protect the light emitting body 110 from external impact. It is preferable that it is a case.

On the other hand, the socket base 170 is a conventional E39 type socket is used, so that it can utilize the existing steel tower air obstacle enclosure as it is. The power connection line of the flashing control device disposed in the empty space in the light emitting body 110 is connected to the socket base 170, the socket base 170 is connected to the socket of the pylon air obstacle enclosure is supplied with power. In addition, a photoconductive cell (CDS: Cadmium Sulfide Cell) 190 is disposed in the socket base 170 to detect illuminance to detect illuminance around the lamp.

Figure 2 is an exploded perspective view of a aviation obstacle, etc. according to an embodiment of the present invention, the light emitting body 110 may be made in one piece, but can be made open and detachable as shown in FIG. A coupling member 250 such as a coupling jaw and a locking jaw, for example, is provided at a portion where the left portion 210 and the right portion 230 of the light emitting body 110 are coupled to each other to form one body by coupling the coupling member 250. Is made with.

As shown in FIG. 2, a locking member 270 is formed at a bottom surface of the outer case 150, and the locking member is located at a portion where the locking member of the outer case 150 of the support member 130 abuts. The groove 290 to be inserted and fixed may be formed, but is not necessarily limited thereto, and the outer case 150 and the support member 130 may be fixed to each other in various forms.

And, as described with reference to Figure 1, in the empty space formed inside the light emitting body 110 is placed a flashing control device 230 for controlling the blinking of the LED 125, the light emitting body 110 The inner surface of the PCB film is laminated. The power connection line of the blink control device 230 is connected to the socket base 170.

3 is a view showing the configuration of the flashing control device of FIG. 2, as shown in FIG. 3, the flashing control device includes a rectifier 310, a constant voltage unit 330, an illuminance detector 350, and a controller 370. Include.

The rectifier 310 rectifies and converts the commercial AC power input thereto into a DC power source. Specifically, the rectifier 310 receives a commercial AC power of 220V / 5A and converts it into a 19V DC power through a down transformer and outputs the same.

The constant voltage unit 330 outputs the DC voltage output from the rectifier 310 as a constant voltage. Specifically, the constant voltage unit 330 smoothes and charges and discharges the DC voltage output from the rectifier 110 and outputs the constant voltage.

The illuminance detector 350 detects the illuminance around the lamp, and outputs an illuminance detection value according to the detected illuminance amount. The illuminance detector 350 includes a photoconductive cell (CDS: Cadmium Sulfide Cell) for detecting illuminance, and a variable resistor that varies a resistance value according to the illuminance detection amount of the photoconductive cell (CDS).

The controller 370 controls the lighting of the LED according to the illuminance detection value output by the illuminance detector 350. That is, the controller 370 turns on the LED by applying a current to the LE at night without applying a current to the LED during the day. At this time, the controller 370 periodically turns on the LED according to the flashing cycle at night time.

Figure 4 is a view showing an example of installing other aviation obstacles in the present invention to the steel tower structure, conventionally installed a separate flash control device on the lower end of the steel tower structure, as shown in Figure 4, the lower portion of the steel tower structure AC power line 410 is directly connected to the aviation lights 430-1, 430-2, 430-3 according to the present invention installed on the steel tower structure without installing a separate flashing control device. The flashing control device installed in the aviation fault lamps 430-1, 430-2, and 430-3 converts the AC power drawn from the AC power line 410 into a constant voltage and supplies the LED to the aviation fault lamp. Therefore, it is not necessary to replace all the aviation lights when each individual aviation lights have failed.

While the specification contains many features, such features should not be construed as limiting the scope of the invention or the scope of the claims. Also, the features described in the individual embodiments herein can be implemented in combination in a single embodiment. Conversely, various features described in a single embodiment herein can be implemented individually in various embodiments or at appropriate subcombinations.

The present invention described above is capable of various substitutions, modifications, and changes without departing from the technical spirit of the present invention for those skilled in the art to which the present invention pertains. It is not limited by the drawings.

110: light emitting body 130: support member
150: outer case 170: socket base
120: LED unit 111: LED unit mounting frame
123: Reflector

Claims (6)

At least one LED unit mounting frame is formed in the form of a lattice on the outer surface of the polygon, in the form of a lattice, and the terminal of the LED unit penetrates the LED unit mounting frame on the inner surface of the polygon. Is connected to the PCB film is laminated, the light emitting body to form an empty space therein;
The LED unit inserted into and fixed to the LED unit mounting frame of the light emitting body, the panel being inserted into and fixed to the LED unit mounting frame and fixed to a panel having a terminal pin formed at a lower portion thereof penetrating the LED unit mounting frame; An LED unit having an LED connected to the terminal pin;
A flashing control device disposed in an empty space inside the light emitting body to supply power to the PCB film of the light emitting body and control lighting;
A support member having a plate shape for supporting the light emitting body and the flashing control device; And
And a spiral socket base disposed at a lower end of the support member opposite to the light emitting body to supply power to the flashing control device. The method of claim 1,
The light emitting body,
It includes a body of the polygonal pillar, the upper surface of the quadrangle, the upper inclined surface connecting the body of the polygonal pillar and the upper surface of the quadrangle, the lower inclined surface connecting the body of the polygonal pillar and the support member and on the upper surface Aviation obstacle, characterized in that the opposite bottom surface is open. The method according to claim 1 or 2,
The LED unit,
Aviation obstacle lamp, characterized in that further comprising a reflector widening the opening in the direction of the LED between the panel and the LED. The method according to claim 1 or 2,
And a light transmitting outer case which is spaced apart from the light emitting body by a predetermined distance and surrounds the light emitting body and is supported by the support member. The method according to claim 1 or 2,
The flashing control device,
A rectifier for rectifying the AC voltage to convert the DC voltage to output the DC power;
A constant voltage unit converting the DC power output from the rectifier into a constant voltage and outputting the constant voltage;
An illuminance detector for detecting an ambient illuminance such as an aviation obstacle and outputting an illuminance detection value; And
And a controller for selectively outputting the constant voltage output from the constant voltage unit to the LED according to the illuminance detection value output from the illuminance detection unit. The method of claim 5, wherein
The illuminance sensor is installed in the socket base,
The illuminance detecting unit detects an ambient illuminance by using the illuminance sensor.

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