KR20140080828A - Times jeosik route indication based light-emittingelement rotated - Google Patents

Abstract

The present invention relates to a rotation type lantern for informing a location by a light emitting from a lighthouse. When a sailing ship cannot identify a current location due to equipment malfunction and the like, light flickers by a certain number of times per certain unit of time allocated for each location of an area so that identifying the current location is possible based on the number of flickers of light from the lighthouse. In particular, by forming an LED module assembly, which is obtained by assembling LED modules, to have multiple surfaces, the number of flickering of the light emitting element is realized by the light emission from the multiple surfaces when the light emitting element rotates. To this end, one surface of the light emitting element is realized by forming the LED assembly through connecting the LED modules up and down or left and right by a connecting element, and the LED assembly has desired multiple surfaces and is assembled in a block shape by various connection elements to implement the light emitting element, so that not only the number of flickering, according to the number of rotation of the light emitting element, is realized, but also light can be changed to have various shapes and sizes.

Description

[0001] The present invention relates to a light emitting element,

The present invention relates to a rotary light changer for indicating the position of a lighthouse by a light, and in the case where a navigating ship can not recognize its current position due to a malfunction or the like, by the number of flashes of the lighthouse In order to enable the recognition of the current position, the number of times of glitter is expressed in a predetermined time unit by location in the area, so that the location can be recognized.

Particularly, such a glittering light emitting element forms a multi-facet of the LED module assembly in which the LED module is assembled, thereby realizing the number of flashes by the light emission by the multi-facet when the light emitting element rotates.

In order to display a glare in a state where the light emitting element is fixed, a lens mounted on the outer periphery of the light emitting element must be rotated. At this time, the lens is divided into a plurality of sections at regular intervals, The number of flashes of the light emitting element is realized by the rotation speed of the rotary frame in a state in which the light emitting elements are maintained in the light emission state by the width of the lens and the partition mounted on the opening of the rotary frame.

Therefore, the luminous element is required to have high luminous power in order to ensure visibility even at a remote place (50 km). Such a bulb with high luminous power is hardly produced, but it is formed as a single bulb. The lighthouse will lose its function.

In addition, such bulbs requiring high power are required to be improved in modern society, which requires high power and saving energy.

In recent years, there has been an attempt to replace such bulbs requiring high luminous power by using LEDs, but it is impossible to realize a high luminous power due to the characteristics of LEDs. In order to realize such high luminous power, In this case, even when a large number of LEDs are fixed on a substrate, the Fresnel lens is used as a circular Fresnel lens. Therefore, the Fresnel lens can not be used in a light source requiring a high light power for a long distance.

Therefore, in the present invention, it is possible to obtain a high luminous power while realizing a light emitting element by using an LED, and by forming a light emitting element on a single surface by using a straight line of the LED to rotate the light emitting element, Not only the number of glittering implementations, but also the visibility at a distance is excellent.

For this purpose, each LED module is connected vertically or horizontally by a connecting element to form an LED assembly to implement one side of the light emitting element, and such LED assembly is formed by various types of connecting elements By assembling them in a block manner, the light emitting element can be realized. Thus, it is possible to realize the number of times of flashing according to the number of revolutions of the luminescence enzyme, and to be able to change into various shapes and sizes.

Accordingly, by integrating the LED having the straightness in a block manner, the light emitting element can be rotated to realize the light emitting element, and the number of flashes can be adjusted by the number of faces and the number of revolutions of the multi face. Further, It is possible to quickly cope with the change of the size of the element, and the aspheric lens is mounted on the LED having the straightness, so that the focusing of the light is excellent and high power can be obtained by the low power.

1 is a cross-sectional view of an LED module having an individual structure in which each lens of the present invention is mounted;
Fig. 2 is a state in which a fixing pin for block connection is mounted on the back surface of a heat sink constituting an LED module having an individual structure in which each lens of the present invention is mounted. Fig.
Fig. 3 is an external view of the lens of the present invention
4 is an assembled structure of the lens of the present invention,
5 is a side view of the LED heat sink of the present invention.
6 is a state in which the present invention is assembled into four sides.
7 is a schematic view of the light emitting element of the present invention being rotated;
FIGS. 8A and 8B are views showing a state in which the LED module of the present invention is assembled up and down in the singular and plural. FIG.
9 is a perspective view of one embodiment of the up-and-down assembly of FIG.
10 is a perspective view of an embodiment of an assembling structure of the LED module of the present invention.
11 is a view showing the LED module of the present invention assembled into six surfaces.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 to 11, each LED module 10 is connected vertically or horizontally by a connection element 20 to form an LED assembly 30 to form a light emitting element 100 And the LED assembly 30 is assembled in block form by various types of connection elements 20 while forming a desired surface, thereby realizing the light emitting element 100. [

In this case, the LED module 10 embodying the light emitting element 100 formed of the LED assembly 30 according to the present invention may vertically, horizontally, vertically and horizontally, as shown in FIGS. 8A and 8B, It is possible to connect them in singular form or to connect them in plural.

In addition, when the LED assembly 30 is used to form a polyhedron on two sides, three sides, or six sides, a connecting element corresponding to each other connecting element is used.

Each of the LED modules 10 forming the LED assembly 30 includes an LED 12 mounted on the heat sink 11 and a lens body 12 mounted on the heat sink 11, 13 and the lens body 13 are provided with an aspherical lens 14 forward and a rear lens 15 attached to the lens body 13 at the rear thereof.

In this state, the lens body 13 mounted on the heat sink 11 accommodates the LED 12, and a space is formed at a certain distance from the regular-surface lens 15.

The light emitting element 100 is mounted on a rotating body 200 driven by a motor 300 and is rotated. The electric power is supplied to the light emitting element 100 by using a carbon brush 400, It is.

It is needless to say that this scheme does not limit the object of the present invention, and various schemes for power supply can be used.

Accordingly, when the light emitting element 100 is rotated, the number of flashes can be limited to various forms according to the number of turns of the LED assembly 30 assembled by the multi-faceted selection of the LED assembly 30 or the multi- It will be.

In addition, by using the LED, it is possible to obtain a high light amount by the individual lenses of each LED while being low in power.

100: light emitting element 200: rotating body
300: motor 400: carbon brush
10: LED module 11: heat sink
12: LED 13: lens body
14: aspherical lens 15: regular lens
20: Connecting element
30: LED assembly

Claims (6)

Each of the LED modules 10 is connected to the LED assembly 30 by being vertically or horizontally connected by the connecting element 20,
The LED assembly is configured to implement one surface of the light emitting element 100 having multiple surfaces,
The LED assembly 30 includes a light emitting element that is assembled in blocks by various connecting elements 20 according to the shape of a polyhedron. The LED module (10) according to claim 1, wherein the LED module (10) embodying the light emitting element (100) formed of the LED assembly (30) is connected to the LED assemblies (30) And a plurality of light emitting elements connected to the light emitting elements are rotated. The light emitting device according to claim 1, wherein when the LED assembly (30) is used to form a polyhedron on two, three, or six sides, a light emitting element Light. The LED module according to any one of claims 1 to 3, wherein each LED module (10) forming the LED assembly (30) comprises an LED (12) mounted on a heat sink (11) An aspherical lens 14 is formed in the lens body 13 in front of the lens body 13 to be mounted on the heat sink 11 while accommodating the lens body 13, And a light emitting element mounted on the light emitting element. The rotary lifting device according to claim 4, wherein a light emitting element having a space spaced by a predetermined distance from the regular-spherical surface lens (15) is accommodated by the lens body (13) mounted on the heat sink (11) while accommodating the LED . The light emitting element 100 is mounted on a rotating body 200 driven by a motor 300 and is rotated. The electric power is supplied to the light emitting element 100 by using a carbon brush 400, Wherein the light emitting element is rotated.

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