KR101503038B1 - Vehicle Lamp of Slim Type with 3D Multi-level Effect - Google Patents

Abstract

The purpose of the present invention is to provide a vehicle lamp which provides an excellent heat dissipation effect, reduces manufacturing costs, and reduces weight using a film type LED module. The slim vehicle lamp having a 3D effect comprises: a thermal-conductive frame made of a material such as aluminum and having a mounting unit inside the thermal-conductive frame; a thermal-conductive adhesive sheet attached to the mounting unit of the thermal-conductive frame; a film type LED module mounted on the upper side of the thermal-conductive adhesive sheet; a lower reflective sheet integrally attached to an upper surface of a film type LED module and having LED insertion holes to enable an LED to protrude; a side thermal-conductive adhesive sheet attached to side edges of the mounting unit of the thermal-conductive frame; a side film type LED module mounted on the side thermal-conductive adhesive sheet; a half mirror attached to an upper surface of the thermal-conductive frame; and a front surface color sheet attached to the upper side of the half mirror.

Description

[0001] The present invention relates to a vehicle lamp having a 3D stereoscopic effect,

The present invention relates to a slim type automobile lamp having an excellent thermal conductivity and a stereoscopic effect. Generally, a car stop is installed on the left and right sides of the rear of a car to indicate a turn signal and a brake, and a brake light is turned on when the driver depresses the brake. Therefore, the brake or the like has an important meaning that it can reduce the traveling speed by providing information to the other vehicle approaching from the rear, that the forward vehicle will stop. Therefore, the brake or the like having such a function is important in visual effect, and the present invention is characterized in that it has excellent thermal conductivity and has a 3D stereoscopic effect in a slim shape.

The prior art related to the present invention is disclosed in Korean Patent Laid-Open Publication No. 10-2013-0091920 (published on Mar. 20, 2018). 1 is a configuration diagram of the conventional backlight unit and a liquid crystal display module having the same. 1, a conventional backlight unit and a liquid crystal display module including the same include a first liquid crystal panel 210 and a second liquid crystal panel 230 that display an image by adjusting light transmittance of a liquid crystal according to input image data, The first liquid crystal panel 210 is positioned on the backlight unit 220 and the second liquid crystal panel 230 is disposed on the backlight unit 220. The backlight unit 220 includes a backlight unit 220 that emits light in both directions using a transparent OLED light source. And is located at the lower portion of the unit 220. The liquid crystal display module 200 for two-sided display includes upper and lower polarizers 240 and 250 formed on the front and back surfaces of the first liquid crystal panel 210 and the upper and lower polarizers 240 and 250 formed on the front and back surfaces of the second liquid crystal panel 230. [ And upper and lower polarizers 260 and 270. The first liquid crystal panel 210 includes a first TFT (Thin Film Transistor) array substrate 211, a first color filter substrate 213 and a second TFT 211 And a first liquid crystal layer 215 filled in the space provided by the spacer. The second liquid crystal panel 230 includes a second TFT (Thin Film Transistor) array substrate 231, a second color filter substrate 233, and a pair of substrates 231 and 233, And a second liquid crystal layer 235 filled in the space provided by the spacer. The first and second color filter substrates 213 and 233 may include a plurality of red, green, and blue sub-pixels, respectively, and may be red, green, Green, and blue subpixels, but the red, green, blue, and white subpixels may constitute one pixel. The first and second TFT array substrates 211 and 231 can switch pixel electrodes (not shown) as switching elements formed on the first and second TFT array substrates 211 and 231. For example, The first and second liquid crystal layers 215 and 235 can change the molecular arrangement of the first and second liquid crystal layers 215 and 235 according to a predetermined voltage applied from the outside. The liquid crystal molecules are composed of pixel electrodes The light from the backlight unit 220 is changed in accordance with the change in the molecular arrangement of the first and second liquid crystal layers 215 and 235, The first lower polarizer 240 is formed on the rear surface of the first TFT array substrate 211 and the first lower polarizer 240 is formed on the first color filter substrate 213. [ A second lower polarizer 260 is formed on the rear surface of the second TFT array substrate 231 and a second lower polarizer 260 is formed on the upper surface of the second color filter substrate 233, The first and second upper polarizers 250 and 270 and the first and second lower polarizers 240 and 260 have separate polarization axes and the upper polarizers 250 and 270 have separate polarization axes, The upper and lower polarization axes of the lower polarizers 240 and 260 are orthogonal to each other. What may be polarized light absorption axis. Thus, the upper and the lower polarizing plate is the light incident to absorb the light component in one direction as light having a direction component. The first lower polarizing plate 240 is used as a first substrate for growing and supporting the backlight unit 220, more specifically, the organic light emitting device, and the second lower polarizing plate 260 is used to encapsulate the organic light emitting device the second substrate is used as a second substrate for incapsulation. The backlight unit 220 is integrally formed on the rear surface of the first liquid crystal panel 210 and more specifically on the rear surface of the first lower polarizer 240. Although not shown in the drawing, 220 may be integrally formed on the rear surface of the second liquid crystal panel 230, more specifically, on the rear surface of the second lower polarizer 260. That is, the backlight unit 220 may be formed on the back surface of any one of the first lower polarizer 240 and the second lower polarizer 260. The backlight unit 220 is formed of a transparent OLED and generates a planar light source. Accordingly, the backlight unit 220 can provide a light source having a uniform brightness compared to an LED light source that is a conventional point light source. Further, since the backlight unit 220 using a transparent OLED does not require the use of a light guide plate, a diffusion sheet, and an optical sheet, a thin liquid crystal display module can be realized. Meanwhile, the seal pattern 245 is formed at the edge between the first lower polarizer 240 and the second lower polarizer 260. At this time, the seal pattern 245 is formed by ultraviolet (UV) . The seal pattern 245 may be formed of a sealant made of an organic or polymeric material, or a sealant mixed with a viscous solvent and metal particles. The seal pattern 245 is used to bond the first lower polarizer 240 and the second lower polarizer 260 to prevent contaminants such as moisture or gas from penetrating into the transparent OLED. An air gap 255 is formed between the backlight unit 220 and the second liquid crystal panel 230 through the seal pattern 245 so that the air gap 255 maintains a vacuum state.

The prior art having the above-described structure does not require a light guide plate, an optical sheet, etc., so that the manufacturing cost is low and the visibility is somewhat excellent. However, due to the PCB type substrate and complicated structure, the weight is heavy and visibility is also limited. SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a light automobile lamp that uses a film-type LED module and is low in manufacturing cost, excellent in heat radiation effect, and light. Another object of the present invention is to provide a half mirror and a reflective sheet so that a 3D stereoscopic effect is displayed, thereby achieving excellent visibility.

The slim type automobile lamp having the 3D effect of the present invention as described above has a thermally conductive frame composed of a material such as aluminum and having a mounting part formed therein, a thermally conductive adhesive sheet seated on the mounting part of the thermally conductive frame, A lower reflective sheet integrally attached to an upper surface of the film-type LED module and having an LED insertion hole to protrude the LED, and a lower reflective sheet attached to a side edge of the heat- And a front color sheet attached to an upper portion of the half mirror, wherein the half mirror is attached to the upper surface of the thermally conductive frame, and the side surface heat conductive adhesive sheet is attached to the side surface heat conductive adhesive sheet. .

The slim type automobile lamp having the 3D stereoscopic effect of the present invention having the above-described structure has an excellent effect of visibility due to the 3D stereoscopic effect. Further, since the film-type LED module is mounted, the present invention is excellent in heat radiation effect, light in weight, and easy to install. Further, another effect of the present invention is that the manufacturing is easy and the manufacturing cost is inexpensive.

1 is a configuration diagram of a conventional backlight unit and a liquid crystal display module having the same,
FIG. 2 is an exploded perspective view of a slim type automotive lamp according to a first embodiment of the present invention,
3 is a perspective view of a first embodiment of a slim type automobile lamp having a 3D stereoscopic effect of the present invention,
4 is a perspective view of a slim type automotive lamp having a 3D stereoscopic effect of the present invention before the front half mirror and the color sheet are attached,
5 is an exploded perspective view of a slim type automobile lamp having a 3D stereoscopic effect according to the second embodiment of the present invention,
6 is a perspective view of a second embodiment of a slim type automobile lamp having a 3D stereoscopic effect of the present invention,
7 is a state in which a slim type automobile lamp having a stereoscopic effect of the present invention is connected to a power source,
8 is a photograph of a slim type automobile lamp having a stereoscopic 3D effect of the present invention,
9 is a block diagram of a film type LED module applied to the present invention.

A slim type automobile lamp having the 3D effect of the present invention having the above-described objects will be described with reference to FIGS. 2 to 9 as follows.

2 is an exploded perspective view of a first embodiment of a slim type automotive lamp having a 3D stereoscopic effect of the present invention. 2, a thermally conductive frame 10 made of the same material as aluminum and having a mounting portion 15 therein, a thermally conductive adhesive sheet 20 seated on the mounting portion 15 of the thermally conductive frame 10, A film type LED module 30 mounted on the upper surface of the thermally conductive adhesive sheet 20 and a lower reflection sheet 30 integrally attached to the upper surface of the film type LED module 30 and having an LED insertion hole, A side surface heat conductive adhesive sheet 20-1 attached to the side edge of the thermally conductive frame 20-1 and a side film type LED module 30 -1), a half mirror 70 attached to the upper surface of the thermally conductive frame 10, and a front color sheet 80 attached to the upper half of the half mirror.

3 is a perspective view of a slim type automobile lamp having a 3D stereoscopic effect according to the first embodiment of the present invention. 3, the first embodiment 10 'of the slim type automobile lamp having the 3D stereoscopic effect of the present invention has a "B" -shaped thermally conductive frame 10 in which a mounting portion is formed and a mounting portion (not shown) of the thermally conductive frame 10 And a lower reflective sheet attached integrally to the upper surface of the film-type LED module, wherein the lower reflective sheet is attached to the upper surface of the film-type LED module, A side heat conductive adhesive sheet 20-1 attached to a side edge of the thermally conductive frame mounting part 15 and a side film type LED module 30-1 mounted on the side heat conductive adhesive sheet, A half mirror 70 attached to the upper surface of the thermally conductive frame, and a front color sheet 80 attached to the upper portion of the half mirror.

4 is a perspective view of a slim type automotive lamp having a 3D stereoscopic effect of the present invention before the front half mirror and the color sheet are attached. 4, a slim type automobile lamp having a 3D stereoscopic effect according to the present invention has a heat conducting frame 10 (10 ') composed of a material such as aluminum and having a mounting portion 15 formed into a " A thermally conductive adhesive sheet 20 placed on the mounting portion 15 of the thermally conductive frame 10; a film type LED module 30 mounted on the thermally conductive adhesive sheet 20; A lower reflective sheet 50 integrally attached to the upper surface of the LED module 30 and having an LED insertion hole to attach the LED to protrude therefrom, Sheet 20-1 and a side-film-type LED module 30-1 mounted on the side heat-conductive adhesive sheet 20-1. The front half mirror 70 and the front color sheet 80 are attached in a state where the film type LED module, the lower reflection sheet 50, and the side LED module are mounted as described above.

5 is an exploded perspective view of a slim type automobile lamp having a 3D stereoscopic effect according to the second embodiment of the present invention. 5, the second embodiment 20 'of the slim type automobile lamp having the 3D stereoscopic effect of the present invention includes a thermally conductive frame 10 formed of a material such as aluminum and having a mounting portion 15 formed therein, A film type LED module 30 mounted on the thermally conductive adhesive sheet 20 and mounted on the mounting portion 15 of the film type LED module 30; A lower reflection sheet 50 integrally attached to the upper surface of the heat conductive frame 10 and having an LED insertion hole to protrude the LED, a half mirror 70 attached to the upper surface of the heat conductive frame 10, And a front color sheet (80).

6 is a perspective view of a second embodiment of a slim type automotive lamp having a 3D stereoscopic effect of the present invention. 6, the second embodiment 20 'of the slim type automobile lamp having the 3D stereoscopic effect of the present invention includes a "b" -shaped thermally conductive frame 10 in which a mounting portion 15 is formed, and the thermally conductive frame 10, A film type LED module (30) which is seated on the heat conductive adhesive sheet (20), and a heat conductive adhesive sheet And a half mirror 70 attached to the upper surface of the thermally conductive frame 10, a front color sheet 70 attached to the upper half of the half mirror, (80).

7 is a state in which a slim type automobile lamp having 3D effect of the present invention is connected to a power source. 7, a power source 90 is connected to a slim type automobile lamp 10 'having a 3D stereoscopic effect according to the present invention through a connector, and the power source is connected to an electric circuit printed on a film of the film type LED module, Can be turned off.

8 is a photograph of a slim type automobile lamp having a 3D effect of the present invention. In FIG. 8, the slim type automobile lamp having the stereoscopic 3D effect of the present invention shows a state of, for example, red, and the lamp has a characteristic of excellent stereoscopic visibility when the lamp is lit.

9 is a block diagram of a film type LED module applied to the present invention. 9, the film-type LED module according to the present invention includes a step of printing a cream solder on a PCB soldering portion of a 50um PI (polyimide) film PCB or a 200um FR4 (PCB standard number) film, A step of soldering the LED chip by applying heat to the cream solder after mounting the LED, and a step of cutting the PI film ledge into a unit product standard. The unit 50um A plurality of LEDs 110 mounted on a PI (polyimide) PI film PCB or a 200um FR4 film 150 become the film-type LED module 30 and are applied to the present invention.

10: thermally conductive frame, 20: thermally conductive adhesive sheet,
30: a film-type LED module, 50: a lower reflective sheet,
70: half mirror, 80: front color sheet,
110: LED, 150: unit PI film,
210: first liquid crystal panel, 220: backlight unit

Claims (6)

In a slim type automotive lamp having a stereoscopic effect,
In the slim type automobile lamp,
A thermally conductive frame 10 having a mounting portion 15 formed therein;
A thermally conductive adhesive sheet (20) seated on a mounting portion (15) of the thermally conductive frame (10);
A film-type LED module 30 mounted on the thermally conductive adhesive sheet 20;
A lower reflective sheet (50) integrally attached to an upper surface of the film type LED module (30) and having an LED insertion hole formed therein to protrude the LED;
A side thermally conductive adhesive sheet (20-1) attached to the side surface of the thermally conductive frame;
A side-film type LED module 30-1 mounted on a side edge of the side heat-conductive adhesive sheet 20-1;
A half mirror 70 attached to the upper surface of the thermally conductive frame 10;
And a front color sheet (80) attached to an upper portion of the half mirror.
The method according to claim 1,
Wherein the thermally conductive frame (10) is a " b "shaped frame.
3. The method according to claim 1 or 2,
The film may be,
50um PI (polyimide) film PCB or 200um FR4 film PCB.



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