KR20200024497A - built-in line type LED lighting apparatus - Google Patents

Abstract

An embedded line type LED lighting apparatus according to the present invention projects LED projection light at a 30-60 degree inclination from the inner side surface of a profile. The reflective surface provided at an inclination with a predetermined curvature reflects the LED projection light to a diffusion cover. The amount of reflectance of an upper side unit of the reflective surface is higher than that of a lower side unit of the reflective surface. The projection angle of an LED covers up to a distal end of an upper side unit of the reflective surface, but does not reach the diffusion cover beyond the upper side unit of the reflective surface.

Description

Built-in line type LED lighting apparatus

The present invention relates to LED lighting, and more particularly, to a buried line type LED lighting device inserted into a groove provided in the floor, ceiling, wall, and the like.

LED light has high photoelectric conversion efficiency, low power, no preheating time, fast turn on / off speed, no need of gas or filament for emitting light, and it is strong against impact and has a long service life. I'm replacing lighting fast. For example, LED lighting is widely used not only in large-scale factories, offices, apartment complexes, public facilities such as street lamps and parks, but also in homes, and research and development related to LED lighting have been actively performed.

In addition, the LED lighting device may be implemented in the form of a light bulb or a fluorescent copper, or may be implemented in a buried type inserted into a groove provided in the cabinet or wall or floor. Among these forms, embedded LED lighting devices are getting more attention as they can provide decorative effects as well as simple lighting. In particular, even in a buried LED lighting device, the square shape, rectangular shape, round shape, elliptical shape, etc., a very narrow area, but the length of the long-line LED lighting can provide an excellent interior effect.

Line type LED lighting device is embedded in a groove provided on the floor or ceiling. Even though the projection light of the LED chip is diffused by the diffusion plate, there is a problem that a spot phenomenon occurs in which the projection light of the LED chip remains. have. In order to prevent spots, there is a method of increasing the distance between the LED chip and the diffuser plate and thickening the diffuser plate.

However, according to the method, it is difficult to realize high illuminance due to the light loss due to the distance to the diffusion plate and the thick diffusion plate. In addition, since the distance to the diffusion plate should be secured, the cost of manufacturing the profile for mounting the LED module is high, and the depth of the buried groove inevitably increases. The deepening of the buried grooves means that it takes more time and money to form the buried grooves on the floor, the ceiling, and the wall, and the difficulty of the installation work also increases.

Another method of preventing spots is an indirect lighting method that reflects and diffuses the projection light of the LED chip. Generally, the indirect lighting method has a good effect of preventing spot phenomenon, but the method of diffusing the reflected light by projecting the LED light in the opposite direction to the final projection direction inevitably increases the light loss and the distance from the reflected light to the diffuser plate. Similarly, since the method needs to be secured, problems such as profile production cost and difficulty of working may occur.

The technical problem to be solved by the present invention is to provide a buried line type LED lighting device that can be installed on the side of the profile of the LED chip to prevent the spot phenomenon caused by the projection light of the LED chip by tilting the inside of the profile to the installation angle. It is.

Another technical problem to be solved by the present invention is to provide a buried line type LED lighting device that can reduce the thickness of the LED profile due to the side projection method can reduce the manufacturing cost, and easy to form and install the buried groove.

Another technical problem to be solved by the present invention is to provide an embedded line type LED lighting device that can implement a soft lighting atmosphere by giving an inclination to the LED projection light reflecting surface so that the reflecting distance is shortened as the distance from the LED chip increases. To provide.

Technical problems to be achieved by the present invention are not limited to the above-mentioned technical problems, and other technical problems not mentioned above will be clearly understood by those skilled in the art from the following description. Could be.

In order to solve the above technical problem, a buried line type LED lighting device according to a first embodiment of the present invention includes a horizontal base; An upper portion of the first and second vertical extensions extending from the opposite ends of the horizontal base and vertically extending from one end of each of the first and second vertical extensions extending in the longitudinal direction; Open profile; A diffusion cover inserted into a longitudinal direction of the profile along a slide groove provided inside one end of each of the first and second vertical extensions to cover an open upper portion of the profile; A plurality of LED chips are inserted in the longitudinal direction of the profile along the second slide groove inclined 30 degrees to 60 degrees inwardly of the first vertical extension, and mounted on the PCB in the longitudinal direction of the profile. An LED module for projecting light obliquely toward the second side vertical extension part; And an inclined surface connecting the inside of the other end of the first vertical extension part and the inside of one end of the second vertical extension part with a predetermined curvature, and the distance from the first vertical extension part to the diffusion cover gradually decreases. It may include a reflective surface having. In this case, the projection center axis of the plurality of LED chips corresponds to the lower side of the reflecting surface, the reflectance of the upper portion of the reflecting surface is higher than the reflectance of the lower portion of the reflecting surface, the projection angle of the plurality of LEDs of the reflecting surface The cover may be extended to the end of the upper portion, but may not reach the diffusion cover beyond the upper portion of the reflective surface.

The reflective sheet may be mounted on the upper side of the reflective surface, but the reflective sheet may not be mounted on the lower side of the reflective surface.

The reflectance of a predetermined region including a portion of the lower portion of the reflective surface corresponding to the projection center axis of the plurality of LED chips may be lower than that of other portions of the lower surface of the reflective surface.

The reflective surface may be divided into a plurality of regions, and a region having a greater distance from the first vertical extension portion may have a higher reflectance.

In order to solve the above technical problem, a buried line type LED lighting device according to a second embodiment of the present invention includes a horizontal base; An upper portion of the first and second vertical extensions extending from the opposite ends of the horizontal base and vertically extending from one end of each of the first and second vertical extensions extending in the longitudinal direction; Open profile; A diffusion cover inserted into a longitudinal direction of the profile along a slide groove provided inside one end of each of the first and second vertical extensions to cover an open upper portion of the profile; A plurality of LED chips are inserted in the longitudinal direction of the profile along the second slide groove inclined 30 degrees to 60 degrees inwardly of the first vertical extension, and mounted on the PCB in the longitudinal direction of the profile. An LED module for projecting light obliquely toward the second side vertical extension part; And an inner side of the other end of the first vertical extension part and an inner side of one end of the second vertical extension part with a predetermined curvature so that the distance to the diffusion cover gradually decreases as the distance from the first vertical extension part increases. And a plurality of protrusions for reflecting the LED chip projection light on the inclined surface, and the LED projection light reflecting area of the plurality of protrusions is wider as the distance from the first vertical extension portion increases. It may include. The projection angle of the plurality of LEDs may cover up to the end of the upper portion of the reflective surface but not reach the diffusion cover beyond the upper side of the reflective surface.

In order to solve the above technical problem, a buried line type LED lighting device according to a third embodiment of the present invention includes a horizontal base; An upper portion of the first and second vertical extensions extending from the opposite ends of the horizontal base and vertically extending from one end of each of the first and second vertical extensions extending in the longitudinal direction; Open profile; A diffusion cover inserted into a longitudinal direction of the profile along a slide groove provided inside one end of each of the first and second vertical extensions to cover an open upper portion of the profile; A plurality of LED chips are inserted in the longitudinal direction of the profile along the second slide groove inclined 30 degrees to 60 degrees inwardly of the first vertical extension, and mounted on the PCB in the longitudinal direction of the profile. An LED module for projecting light obliquely toward the second side vertical extension part; And an inner side of the other end of the first vertical extension part and an inner side of one end of the second vertical extension part with a predetermined curvature so that the distance to the diffusion cover gradually decreases as the distance from the first vertical extension part increases. A lower portion of the inclined surface is provided with a plurality of protrusions for reducing the reflectance of the LED chip projection light, wherein the portion formed with the plurality of protrusions is a predetermined area including a portion corresponding to the projection center axis of the plurality of LEDs Characteristic may include a reflective surface. The projection angle of the plurality of LEDs is preferably covered to the end of the upper portion of the reflective surface but not to the diffusion cover beyond the upper side of the reflective surface.

In the buried-line LED lighting apparatus according to the present invention, by installing the LED chip inclined inward to the side of the profile, it is possible to completely prevent the spot phenomenon of the diffuser plate by the projection light of the LED chip.

In the buried line type LED lighting apparatus according to the present invention, by applying a side projection method, the thickness of the LED profile can be extremely reduced, thereby reducing manufacturing costs and greatly improving the ease of embedding work and installation work.

The buried line type LED lighting apparatus according to the present invention may provide an excellent effect in realizing a soft lighting atmosphere by giving a slope to a reflecting surface reflecting the projection light of the LED chip mounted on the side of the profile.

1 is a perspective view of a profile that forms the basis of a buried line type LED lighting device according to the present invention.
FIG. 2 is an enlarged view of one end of the profile shown in FIG. 1. FIG.
3 is a cross-sectional view of the profile shown in FIG. 1.
4 is an enlarged view of one end of a buried line type LED lighting apparatus according to the present invention.
5 is a cross-sectional view of one end of the buried line type LED lighting device shown in FIG.
5 is a cross-sectional view of one end of the buried line type LED lighting device shown in FIG.
FIG. 6 is a conceptual view illustrating a reflection distance from a reflection surface of the buried line type LED lighting device shown in FIG. 4.
FIG. 7 is a conceptual view illustrating a concept of reflectance control on a reflective surface of a buried line type LED lighting device illustrated in FIG. 4.
8 is a conceptual view illustrating a concept of reflectance control on a reflective surface of a buried line type LED lighting device according to another embodiment of the present invention.
Figure 9 shows another example of a profile that can be mounted to a buried line LED lighting device according to the present invention.
10 is a view conceptually showing a cross section of the profile shown in FIG. 9.
11 is a view conceptually showing a cross section of another profile that can be mounted in a buried line type LED lighting device according to the present invention.
12 shows a photograph of a profile of a conventional buried line type LED lighting device.
13 is a light emitting state of a buried line-type LED lighting device according to the present invention and a buried line-type LED lighting device according to a comparative example of the present invention in which the LED module is mounted on the side of the profile, but not upright, as in the present invention. It is a photograph showing.

In order to fully understand the present invention, its operational or functional advantages, and the objects attained by the practice of the present invention, reference should be made to the accompanying drawings which illustrate preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference numerals in the drawings may refer to like elements.

1 is a perspective view of a profile 110 which forms the basis of a buried line type LED lighting device 100 according to the present invention. FIG. 2 is an enlarged view of one end of the profile 100 shown in FIG. 1. 3 is a cross-sectional view of the profile 100 shown in FIG. 1. 4 is an enlarged view of one end of a buried line type LED lighting device 100 according to the present invention.

On the other hand, the components of the buried line type LED lighting device 100 shown herein is not essential, the buried line type LED lighting device may have more or fewer components than that. This will be described in more detail with respect to the embedded line-type LED lighting device 100 and each component constituting it.

The buried line type LED lighting device 100 includes a profile 110, an LED module 130, and a diffusion cover 140. The profile 110 functions as a basic appearance or body of the buried line type LED lighting device 100, and preferably has a material of metal such as aluminum to increase the heat dissipation effect.

The profile 110 includes a horizontal base 111, a first vertical extension part 112 and a second vertical extension part 113 that face each other at both ends of the horizontal base 111 and extend vertically by a predetermined length. The first vertical extension portion 112 and the second vertical extension portion of each of the one end portion of the buried groove engaging portions 114 and 115 are provided to extend to the outside. The profile 110 has an upper open structure in which an opening between the first vertical extension part 112 and the second vertical extension part 113 is opened.

The buried groove catching portions 114 and 115 have a horizontal structure such that the ends contact the mounting surface and have a curved structure with uniform curvature. By the structure, the buried groove locking portions 114 and 115 may exert elastic force. When the buried line type LED lighting device 100 is embedded in the floor, the buried line type LED lighting device 100 is It can provide durability and stability against the force pressed at the top.

The other slide grooves 112A and 113A provided in the first vertical extension part 112 and the second vertical extension part 113 are formed in the ceiling structure when the buried line type LED lighting device 100 is embedded in the ceiling. The grooves into which a fixing member (not shown) for fixing the buried line type LED lighting device 100 is inserted. In addition, a hollow 116 is provided between the horizontal base 111 and the reflective surface 120 to reduce the weight of the profile 110 and reduce raw materials.

The LED module 130 is inserted in the longitudinal direction of the profile 110 along the second slide groove 112B provided to be inclined inside the first vertical extension part 112. In this case, each of the plurality of LED chips 131 mounted on the PCB of the LED module 130 in the longitudinal direction projects light from the first vertical extension part 112 toward the second vertical extension part 113. However, the light is projected to be inclined according to the inclination of the second slide groove (112B).

Since the LED module 130 projects light from the side of the profile 110, the buried line type LED lighting device 100 can prevent spot phenomenon while directly projecting or indirectly projecting the LED projection light onto the diffuser plate. The thickness can be significantly reduced compared to existing LED lighting devices. Therefore, the buried line-type LED lighting device 100 can significantly improve the ease of the buried groove work and installation work at the same time the manufacturing cost is low.

The diffusion cover 140 may include the profile along the slide grooves 114A and 115A provided inside one end (that is, the upper end) of each of the first vertical extension part 112 and the second vertical extension part 113. Inserted in the longitudinal direction of 110 to cover the open upper portion of the profile 110, diffuses the projection light of the LED chip 131 reflected by the reflecting surface 120 to achieve a soft light effect without spot phenomenon Can provide. This effect is supported by the reflective surface 120, which will be described in detail later.

The reflective surface 120 connects the inside of the other side (that is, the lower end) of the first vertical extension part 112 with the inside of one end (that is, the upper end part) of the second vertical extension part 113 with a predetermined curvature. Means an inclined surface. That is, the distance to the diffusion cover 140 is gradually reduced as the reflective surface 120 moves away from the first vertical extension part 112. The LED module 130 is mounted on the side of the first vertical extension part 112. As the distance from which the projection light of the LED chip 131 reaches the reflecting surface 120 increases, the reflecting distance is closer to the brightness. This is to improve uniformity.

The reflective surface 120 has a structure in which the horizontal base 111 and a portion of the lower portion share a portion, but the scope of the present invention is not limited thereto. For example, the reflective surface reflecting the projection light of the LED chip 131 may have an independent structure mechanically separated from the horizontal base 111, or the upper portion of the horizontal base 111 itself may form a reflective surface. .

Hereinafter, the reflection mechanism for the projection light of the LED chip 131 of the reflective surface 120 of the buried line-type LED lighting device 100 according to the present invention with reference to Figures 5 to 8 in more detail. .

5 is a cross-sectional view of one end of the buried line type LED lighting device 100 shown in FIG. FIG. 6 is a conceptual diagram for describing a reflection distance from the reflection surface 120 of the buried line type LED lighting device 100 illustrated in FIG. 4. FIG. 7 is a conceptual view illustrating a concept of reflectance control on the reflecting surface 120 of the buried line type LED lighting device 100 illustrated in FIG. 4. 8 is a conceptual view illustrating a concept of reflectance control on a reflective surface of a buried line type LED lighting device according to another embodiment of the present invention.

Due to the mounting inclination α of the LED module 130, the projection center axis 131A of the plurality of LED chips 131 corresponds to the lower side of the reflective surface 120. That is, the brightest part of the projection light of the LED chip 131 is reflected on a part of the lower part of the reflective surface 120. In consideration of the projection of the lower center, and in order to increase the uniformity of the light diffused by the diffusion cover 140, the reflective surface 120, as shown in Figure 6, the first vertical extension ( As the distance from 112 may be reduced, the inclined structure may reduce the reflection distance.

The projection angle β of the plurality of LED chips 131 of the LED module 130 covers the ends of the upper side of the reflective surface 120 but is mounted on the slide groove 115A beyond the upper side of the reflective surface 120. The diffusion cover 140 is characterized in that it does not reach. For reference, since the projection angle β of the LED chip 131 is divided into 1/2 symmetrically based on the projection center axis 131A, in FIG. 5, β / Notice that 2 is indicated.

If the projection angle β of the LED chip 131 covers the diffusion cover 140 beyond the upper side of the reflective surface 120, the LED chip 131 is not reflected light by the reflective surface 120. The uniformity of the diffused light may be lowered because the projected light of the direct beam reaches the diffusion cover 140. In the present invention, this problem may not occur due to the limitation of the projection angle of the LED chip 131.

Incidentally, the inclined plane clearance angle θ at the upper side of the reflective surface 120 of the projection angle of the LED chip 131 is the difference between the horizontal line of the LED chip 131 and the projection angle cover angle of the LED chip 131. Means. As the inclined plane clearance angle θ is large (that is, as the projection angle of the LED chip 131 is larger), the height of the reflective surface 120 must be increased (that is, the curvature of the reflective surface 120 must be larger), and the projection angle The problem of inhibiting uniformity of diffused light due to over can be prevented in advance.

On the other hand, as the LED inclination angle α increases, the inclined plane clearance angle θ gradually decreases, so that the height of the reflective surface 120 to prevent the problem of impairing uniformity of the diffused light due to the projection angle over may be lowered (that is, the The curvature of the reflective surface 120 can be small). Hereinafter, specific examples of the correlation between the aforementioned angles α, β, and θ and the height or curvature of the reflective surface 120 will be described.

Assume that the projection angle of the LED chip 131 is 120 degrees and the LED inclination angle α is 30 degrees, 45 degrees and 65 degrees. When the inclination angle α is 30 degrees, the upper projection angle β / 2 is 60 degrees, and the inclined plane clearance angle 30 is 30 degrees minus 30 degrees, and the inclination angle α is 45 degrees. , The upper projection angle (β / 2) is 60 degrees and the inclined plane clearance angle (θ) is 15 degrees minus 45 degrees from 60 degrees, the upper projection angle (β / 2) is 60 degrees when the LED inclination angle (α) is 60 degrees The inclined plane clearance angle θ is 60 degrees minus 60 degrees.

The curvature and height of the reflective surface 120 for each case will be described with respect to the results of each of the LED tilt angles α. The inclined plane clearance angle θ is 30 degrees when the LED inclination angle α is 30 degrees, and the inclined plane clearance angle θ is 15 degrees when the LED inclination angle α is 45 degrees, and the LED inclination angle α is If the angle is 60 degrees, the inclined plane clearance angle θ is 0 degrees. Therefore, the height of the reflective surface 120 should be higher in the order of the LED inclination angle α of 30 degrees, 45 degrees, 60 degrees. If it is assumed that the width of the reflective surface 120 is the same, the curvature of the reflective surface 120 should also increase the LED tilt angle α in the order of 30 degrees, 45 degrees, 60 degrees. That is, as the inclination angle of the LED inclination angle α increases, the height of the reflective surface 120 in the profile 110 of the buried line type LED lighting device 100 according to the present invention may be lowered, thereby reducing manufacturing costs and filling grooves. Ease of operation and installation can be improved.

However, when the LED tilt angle α exceeds 60 degrees, the brightness of the LED lighting device 100 may be drastically lowered. In addition, when the LED tilt angle α is less than 30 degrees, the effect of thickness reduction due to the tilted projection of the LED chip 131 may be weakened. Thus, in the buried line type LED lighting device 100 according to the present invention can be solved the problem of brightness reduction while maintaining the thickness reduction effect by setting the range of the LED inclination angle (alpha) to 30 degrees to 60 degrees.

Meanwhile, according to the present invention, a buried line type LED lighting apparatus 100 having a width of 5 cm to 10 cm and projecting from the side by giving an inclination of 30 to 60 degrees using an LED chip having a light emitting height of about 3 mm ) Can be implemented with a thickness between 1.0 cm and 1.5 cm. For reference, the thickness of the buried line type LED lighting device 100 according to the present invention is less than 5 times to 10 times thinner than the thickness of a conventional spotless direct / indirect LED lighting device.

In order to increase the uniformity of the light diffused by the diffusion cover 140, there is a method of making the reflectance of the upper portion of the reflecting surface 120 higher than the reflectance of the lower portion of the reflecting surface 120. For example, referring to FIG. 7 conceptually illustrating a cross section of the reflective surface 120 illustrated in FIG. 4, a reflective sheet 121 is mounted on an upper side of the reflective surface 120, but the reflective surface 120 is disposed. If the half sheet is not mounted on the lower portion of the reflective surface 120, the difference in intensity of the projection light between the upper and lower portions of the reflective surface 120 may be offset to some extent. In some cases, the reflective surface 120 is divided into a plurality of areas according to the distance from the first vertical extension part 112, and the reflectance increases gradually as the distance from the first vertical extension part 112 increases. The reflective sheet may be mounted.

On the other hand, in the example of Figure 8 divided into a plurality of areas according to the distance from the first vertical extension portion 112, the farther the distance from the first vertical extension portion 112, the higher the reflectance, each It can be seen that the reflectance in the region can be controlled by the reflective coating layer. As described above, the reflectance control is possible by the reflective sheet rather than the reflective coating layer.

Among the plurality of regions, the reflectance RR1 of the first region closest to the first vertical extension portion 112 is the lowest, which corresponds to the projection center axis of the LED chip 131 corresponding to the first region. Since the strongest part of the projection light of 131 is projected, it is to improve the uniformity of the diffused light by the diffusion cover 140 by setting the reflectance of this area to the lowest.

If the projection center axis of the LED chip 131 corresponds to the projection center axis of the LED chip 131 second to the second area closest to the first vertical extension part 112, It is preferable that the reflectance RR2 is set to the lowest. In summary, in the buried line type LED lighting device 100 according to the present invention, the central axis of the plurality of LED chips 131 included in the LED module 130 corresponds to the lower side of the reflective surface 120. It is preferable that the reflectance of the predetermined region including the portion to be lower than the reflectance of the other portion of the lower side of the reflecting surface 120.

9 shows another example of a profile 110 ′ that may be mounted to a buried line type LED lighting device 100 according to the present invention. FIG. 10 is a diagram conceptually illustrating a cross section of the profile 110 ′ shown in FIG. 9.

Compared with the profile 100 described above, the profile 110 ′ has a difference in that a plurality of protrusions 150 are provided on the reflective surface 120 to reflect projection light of the LED chip 131. The LED projection light reflecting area of the plurality of protrusions 150 provided on the reflecting surface 120 of the profile 110 ′ is wider as the distance from the first vertical extension part 112 increases. Adjusting the LED projection light reflection area of the plurality of protrusions 150 and the projection light of the LED chip 131 to the reflection surface 120, the closer the reflection distance to the diffusion cover 140 Due to the structural features, uniformity of brightness of light diffused by the diffusion cover 140 may be improved.

FIG. 11 conceptually illustrates a cross section of another profile 110 "that may be mounted to a buried line LED lighting device 100 in accordance with the present invention.

Compared to the profile 100 described above, the profile 110 ″ has a plurality of protrusions 150 ′ provided below the reflective surface 120 to reduce reflectance of the projection light of the LED chip 131. The protrusions 150 " provided on the reflective surface 120 of the profile 110 " are disposed on the projection center axis 131A of the LED chips 131 mounted on the LED module 130. It is formed in a predetermined region of the lower side of the reflective surface 120 including a corresponding portion.

Because the projection center axis 131A of the LED chip 131 corresponds to the region and the strongest part of the projection light of the LED chip 131 is projected, the diffusion cover 140 is minimized by lowering the reflectance of the region. This is to improve the uniformity of the diffused light by). Meanwhile, as illustrated in FIG. 11, the plurality of protrusions 150 ″ define a projection area corresponding to the emission height of the LED chip 131 based on at least the projection center axis 131A of the LED chip 131. It is preferably formed to include.

12 shows a photograph of a profile of a conventional buried line LED lighting device.

More specifically, the profile is a profile of a buried line type LED lighting device in which an LED module is installed on the horizontal base side of the profile to directly project LED projection light onto a diffuser plate. Referring to FIG. 12, it can be seen that the profile is closer to a rectangular shape having a longer longitudinal direction.

On the other hand, referring to Figure 3, the cross section of the profile of the LED lighting device according to the present invention shows that the transverse direction is closer to the longer rectangular shape. Judging from the above contents, the LED lighting device according to the present invention can be significantly reduced in thickness compared to the conventional buried line-type LED lighting device described above, while reducing the manufacturing cost and ease of buried groove work and installation work This means that it can be greatly improved.

13 is a light emitting state of a buried line-type LED lighting apparatus according to the present invention and a buried line-type LED lighting apparatus according to a comparative example of the present invention in which the LED module is mounted on the side of the profile, but not upright, as in the present invention. It is a photograph showing.

For reference, the pictures are taken when the LED lighting devices emit light in a state of being buried in the actual floor. Referring to FIG. 13 (a), in the LED lighting apparatus according to the present invention, since the LED module is mounted in an inclined state on the left side of the profile, no spot occurs. Referring to FIG. In the LED lighting device according to the comparative example of the LED module is mounted in the upright state on the left side of the profile it can be seen that a semi-circular spot occurred on the left side of the diffuser plate.

As such, the buried line type LED lighting device according to the present invention can significantly reduce the thickness by mounting the LED module side, it can provide a soft emotional lighting effect by preventing the spot caused by the inclined mounting of the LED module. .

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited to the above embodiments, and those skilled in the art to which the present invention pertains various modifications and variations from such descriptions. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the claims below, but also by those equivalent to the claims.

100: embedded line type LED lighting device 110: profile
120: reflecting surface 130: LED module
140: diffusion cover 150: protrusion

Claims (6)

Horizontal base; An upper portion of the first and second vertical extensions extending from the opposite ends of the horizontal base and vertically extending from one end of each of the first and second vertical extensions extending in the longitudinal direction; Open profile;
A diffusion cover inserted in a longitudinal direction of the profile along a slide groove provided inside one end of each of the first and second vertical extensions to cover an open upper portion of the profile;
A plurality of LED chips are inserted in the longitudinal direction of the profile along the second slide groove inclined 30 degrees to 60 degrees inwardly of the first vertical extension, and mounted on the PCB in the longitudinal direction of the profile. An LED module for projecting light obliquely toward the second side vertical extension part; And
An inclined surface connecting the inside of the other end of the first vertical extension part and the inside of one end of the second vertical extension part with a predetermined curvature, and the distance from the first vertical extension part to the diffusion cover gradually decreases. Including a reflective surface,
The projection center axis of the plurality of LED chips corresponds to the lower side of the reflecting surface, the reflectance of the upper portion of the reflecting surface is higher than the reflectance of the lower portion of the reflecting surface, and the projection angle of the plurality of LEDs is of the upper portion of the reflecting surface. A cover-type LED lighting device, characterized in that the cover to the end but does not reach the diffusion cover beyond the upper side of the reflective surface.
According to claim 1, wherein the reflective sheet is mounted on the upper side of the reflective surface,
The buried line-type LED lighting device, characterized in that the reflection sheet is not mounted on the lower side of the reflective surface.
The method of claim 1, wherein the reflectance of the predetermined area including a portion corresponding to the projection center axis of the plurality of LED chips in the lower portion of the reflecting surface is lower than the reflectance of other portions of the lower portion of the reflecting surface, Flush line type LED lighting device.
The method of claim 1, wherein the reflective surface is divided into a plurality of areas,
The buried line-type LED lighting apparatus, characterized in that the higher the distance from the first vertical extension portion has a higher reflectance.
Horizontal base; An upper portion of the first and second vertical extensions extending from the opposite ends of the horizontal base and vertically extending from one end of each of the first and second vertical extensions extending in the longitudinal direction; Open profile;
A diffusion cover inserted in a longitudinal direction of the profile along a slide groove provided inside one end of each of the first and second vertical extensions to cover an open upper portion of the profile;
A plurality of LED chips are inserted in the longitudinal direction of the profile along the second slide groove inclined 30 degrees to 60 degrees inwardly of the first vertical extension, and mounted on the PCB in the longitudinal direction of the profile. An LED module for projecting light obliquely toward the second side vertical extension part; And
By connecting the inside of the other end of the first vertical extension portion and the inside of one end of the second vertical extension with a predetermined curvature, the distance to the diffusion cover gradually decreases as the distance from the first vertical extension increases. The inclined surface is provided with a plurality of protrusions for reflecting the LED chip projection light, the reflective surface of the LED projection light of the plurality of protrusions is characterized in that the greater the distance from the first vertical extension portion, including a reflective surface ,
The projection angle of the plurality of LEDs cover up to the end of the upper portion of the reflective surface, but do not reach to the diffusion cover over the upper side of the reflective surface, embedded line type LED lighting device.
Horizontal base; An upper portion of the first and second vertical extensions extending from the opposite ends of the horizontal base and vertically extending from one end of each of the first and second vertical extensions extending in the longitudinal direction; Open profile;
A diffusion cover inserted in a longitudinal direction of the profile along a slide groove provided inside one end of each of the first and second vertical extensions to cover an open upper portion of the profile;
A plurality of LED chips are inserted in the longitudinal direction of the profile along the second slide groove inclined 30 degrees to 60 degrees inwardly of the first vertical extension, and mounted on the PCB in the longitudinal direction of the profile. An LED module for projecting light obliquely toward the second side vertical extension part; And
By connecting the inside of the other end of the first vertical extension portion and the inside of one end of the second vertical extension with a predetermined curvature, the distance to the diffusion cover gradually decreases as the distance from the first vertical extension increases. A lower portion of the inclined surface is provided with a plurality of protrusions for reducing the reflectance of the LED chip projection light, wherein the portion formed with the plurality of protrusions is a predetermined area including a portion corresponding to the projection center axis of the plurality of LEDs. Including a reflective surface,
The projection angle of the plurality of LEDs cover up to the end of the upper portion of the reflective surface, but do not reach the diffusion cover over the upper side of the reflective surface, buried line type LED lighting apparatus.

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