KR200389317Y1 - Light unit using LED - Google Patents

Abstract

The present invention provides a sliding convex lens in front of a light source made of a light emitting diode to compensate for the shortcomings of the light emitting diode through the diffusion characteristics of the convex lens itself, and adjusts the light diffusion range and sharpness according to the position of the convex lens. The present invention relates to a luminaire using a light emitting diode.

The present invention is connected to a printed circuit board disposed inside the cylindrical case, the high-brightness LED for emitting a light to the front is fitted around the hatshade; A convex lens disposed in front of the high brightness LED to diffuse light emitted through the high brightness LED; It is composed of a cylindrical lens cap that adjusts the position of the convex lens by sliding the body to the outside of the case while the convex lens is accommodated inside the distal end. The high brightness LED consumes little power. Of course, the diffusion characteristics of the convex lens can reveal a wide area over the same level as the general luminaire, and the convex lens can be moved to diffuse the light emitted from the high-brightness LED to the wide area in the vicinity of the luminaire, or to be clear in a narrow range. It can be adjusted in various ways, such as lightening it.

Description

Light unit using LED

The present invention relates to a luminaire using a light emitting diode, and more particularly, to install a convex lens slidably in front of the light source of the light emitting diode to compensate for the shortcomings of the light emitting diode through the diffusion characteristics of the convex lens itself. Depending on the position of the lens, the light diffusion range and sharpness can be adjusted.

As is well known, luminaires are classified according to lighting methods such as incandescent lamps and fluorescent lamps. Recently, most households use fluorescent lamps in consideration of power saving and lifespan.

These fluorescent lamps are also classified into various types according to their shape. In the past, a fluorescent lamp having a straight tube type is used. In recent years, a circular fluorescent lamp (circle line) is used as a lamp in consideration of design, brightness, and eye fatigue. In the living room, PL lamps (bi-directional or four-way) and three-wavelength lamps are often used.

In addition, the street lamp is mainly used in consideration of the brightness and life of high-pressure mercury lamp, sodium lamp, fluorescent lamp.

However, these luminaires themselves light up and illuminate the outside, helping to prevent inconvenience in daily life at night or in a dark place, but the brightness and diffusion range are fixed at the time of initial manufacture so that the user can adjust them artificially. There is a disadvantage that can not, and also has a disadvantage that the life is very short, the power consumption is increased.

The present invention has been proposed in view of this point, and the lampshade is covered around the light source of at least one high-brightness LED, and the convex lens is slidably positioned in front of the lampshade to extend the life through the high-brightness LED. Of course, while providing more than the equivalent amount of light while minimizing power consumption, it is to provide a luminaire using a light emitting diode that can selectively diffuse the light in a wide range or brighten depending on the position of the convex lens.

Hereinafter, the present invention will be described in detail with reference to the embodiments presented.

1 is a configuration diagram of a luminaire using a light emitting diode according to the present invention, Figure 2 is an illustration of a convex lens applied to the present invention, Figure 3 is a diagram showing the operation of the convex range of the luminaire according to the present invention.

In the lamp 100 using the light emitting diode according to the present invention, a cylindrical case 101 is mounted on a ceiling or a wall, and a printed circuit board 102 for controlling the lamp is fixed inside the case 101. In front of the printed circuit board 102 is located a heat sink 103 for radiating heat generated during operation of the printed circuit board 102 to the outside, at least one high-brightness LED 104 is printed through the heat sink 103 Positioned to be in contact with the circuit board 102, the hatshade 105 is fitted around the high-brightness LED 104 to assist in emitting light forward.

The front of the high-brightness LED 104 is provided with a convex lens 106 for diffusing the light emitted from the high-brightness LED 104, having a larger inner diameter than the outer diameter of the case 101 is formed in a cylindrical shape, the front end of the convex lens In order to hold the 106, a lens cap 110 having a small diameter portion 111 formed narrower than an outer diameter of the convex lens 106 is provided, and the case 101 is provided with the convex lens 106 in the small diameter portion 111. Slidably inserted into the outer side of the lens cap, the fixing bolts 112 are provided at both sides of the lens cap 110 to adjust the lens cap 110 and to fix the position thereof.

Here, the convex lens 106 according to the present invention may be configured so that one side is convex and the opposite side is flat, as shown in FIG. 2, so that the convex portion is disposed to face forward, and one side is convex and the opposite side is curvature of the convex portion. Rather, it may be arranged to be concave with a small curvature so that the convex portions face forward, and both sides may be convex with different curvatures, so that the more convex portions may face forward.

Referring to the operation of the luminaire using the light emitting diode according to the present invention configured as described in detail as follows.

First, when a switch (not shown) is pressed, power is applied to the high brightness LED 104 through the printed circuit board 102 so that the high brightness LED 104 emits light, and the light is reflected by the lampshade 105 around the light. Projected forward.

At this time, the front of the high-brightness LED 104 is provided with a convex lens 106 to diffuse the light projected forward to a wider area, the light diffusion range is different depending on the shape of the convex lens 106. You lose.

That is, as shown in FIG. 2, when the convex lens 106 is configured such that one side is convex and the opposite surface is flat, and the convex surface is disposed forward, the focal length D becomes short, and the convex lens 106 is When one side is convex and the other side is concave with a curvature smaller than the curvature of the convex part, and the convex surface is disposed to face forward, the focal length D 'is convex on one side and the opposite side is convex on a flat structure. In the structure in which the length of the convex lens 106 is longer than that of the lens 106, and both sides of the convex lens 106 have different curvatures, and the convex portion is disposed toward the front, the focal length D ″ is the structure described above. By becoming shorter than this, the relationship of D '> D> D "is established.

The shorter the focal length, the better the light diffusion characteristic, and the longer the focal length, the light is diffused in a narrow range, but the sharpness is good. Each of the convex lenses 106 having the above-described structure according to the present invention When applied to a luminaire using a high-brightness LED, the focal length varies depending on the shape of the convex lens 106 to diffuse the light emitted from the high-brightness LED 104 at a wider angle, or to increase the sharpness while spreading to a more narrow range. Therefore, the convex lens 106 may be selectively applied according to the type or use of the luminaire 100.

In addition, in the present invention, the position of the convex lens 105 disposed in front of the high brightness LED 104 can be selectively moved. For example, when the convex lens 106 is positioned close to the high brightness LED 104, the high brightness LED ( The focal length of the light emitted from the light becomes shorter, and the light diffuses through the focal length of the convex lens 106 to a large area. When the convex lens 106 is located as far away from the high-brightness LED 104 as possible, the high-brightness LED ( The focal length of the light emitted from 104 becomes longer and the light spreading area becomes narrower as it corresponds, but the light can be clearly projected to a longer distance. You can optionally adjust it.

Of course, after the installation of the luminaire 100, the position of the convex lens 106 is adjusted to the optimum state through the lens cap 110, and then the lens cap 110 is fixed through the fixing bolt 112, which is necessary during use. Obviously, the position of the lens cap 110 can be adjusted according to the present invention.

In addition, in the present invention, since the DC power is utilized due to the characteristics of the high-brightness LED 104, the power consumption is almost consumed, and for this purpose, only the adapter for changing the AC power to DC power is required.

In addition, the present invention has been described using only one high brightness LED 104 as an example, but in some cases, a plurality of high brightness LEDs 104 may be formed. In particular, when a plurality of high-brightness LEDs 104 are disposed at equal intervals in the circumferential direction along the edge of the convex lens 106, the brightness as well as the diffusion characteristics can be further improved, and a plurality of convex lenses 106 can also be employed. It may be.

As described above, the present invention is a high-brightness LED and a convex lens is applied to the luminaire, so the power consumption is not consumed very much, and through the diffusion characteristics of the convex lens, it is possible to illuminate a wide area over the level equivalent to that of a general luminaire. In addition, since the convex lens is configured to be movable, the light emitted from the high-brightness LED can be diffused to a large area in the vicinity of the luminaire, or can be clearly reflected in a narrow range. The advantage is that selective use is possible.

1 is a block diagram of a luminaire using a light emitting diode according to the present invention.

2 is an exemplary view of a convex lens applied to the present invention,

(a) is convex on one side and flat on the other side.

(b) where one side is convex and the other side is concave.

(c) is when both sides are formed convexly with different curvature.

3 is an operational state diagram according to the movement of the convex lens of the luminaire according to the present invention,

(a) is the case where the high brightness LED and the convex lens are in close proximity.

(b) is the case where the high-brightness LED and the convex lens are far apart.

*** Explanation of symbols for the main parts of the drawing ***

100: luminaire 101: case

102: printed circuit board 103: heat sink

104: high brightness LED 105: lampshade

106: convex lens 110: lens cap

111: small diameter portion 112: fixing bolt

Claims (2)

A high brightness LED 104 connected to the printed circuit board 102 disposed inside the cylindrical case 101 and having a hat shade 105 fitted therein to emit light forward; A convex lens (106) disposed in front of the high brightness LED (104) to diffuse light emitted through the high brightness LED (104); And Including the cylindrical lens cap 110 to adjust the position of the convex lens 106 is inserted into the outer body of the case 101 while the body accommodates the convex lens 106 inside the front end portion. Luminaire using a light emitting diode, characterized in that. The method of claim 1, The convex lens 106 is configured such that one side is convex and the opposite side is flat so that the convex portions are directed forward, or one side is convex and the opposite side is concave with a curvature smaller than the curvature of the convex portions. A luminaire using a light emitting diode, characterized in that the portion is disposed to face forward, or both sides are formed convex with different curvature, so that the more convex portion is facing forward.