KR101568386B1 - LED lighting apparatus for both-sided luminescence - Google Patents

Abstract

The present invention relates to an LED lighting apparatus for both-sided luminescence which bidirectionally and simultaneously emits light to the indoor ceiling part and bottom part of a building. Light emitting pipes are arranged with a constant distance in parallel in a space between a pair of PCBs fixed by wires extended from the ceiling part of the building downwards. An LED inserted into the opening of both ends of each of the pipes, bidirectionally emits light to the upper part and the lower part of the space between the PCBs. Thereby, the LED lighting apparatus uniformly brightens the interior space of the building without glariness and can provide a soft, comfortable, and high-quality lighting environment for a user.

Description

[0001] The present invention relates to a double-sided light emitting diode (LED)

And a double-sided emission type LED lighting device for simultaneously irradiating light in both the ceiling side and the floor side of a building

Conventional indoor lighting devices have mainly used fluorescent lamps and incandescent lamps as light sources, but they have a problem of high power consumption and short life span as compared with brightness. Accordingly, in recent years, an outdoor lighting device using an LED (Light Emitting Diode) as a light source has become popular. LEDs have much lower power consumption and longer life than fluorescent or incandescent lamps. Korean Patent No. 10-1453938 and Korean Patent No. 10-1454424 disclose that a conventional LED illumination device is a one-sided light emitting type that irradiates light to the bottom side of a building, so that shading and glare on the ceiling of the building occur . Because of this shade, the brightness of the interior of the building is not uniform and the brightness of the building's interior is dark compared to the brightness of the LED light. The glare caused by the concentration of the light on a part of the interior of the building increases the fatigue of the eyes.

The conventional indirect lighting method for solving the shade and glare of the ceiling of the building has a problem that the illumination efficiency is very low because the ceiling or the wall of the building having a very low reflectance is irradiated with light, resulting in a waste of electric power. Since the printed circuit board on which the LED is mounted is enclosed by a housing, a case, a cover, and the like in order to prevent the LED light from being directly projected on the user's eyes and to prevent foreign matter from penetrating into the LED, There is a problem that it is difficult to be released.

The shade and the glare on the ceiling of the building disappear and a wider space can be illuminated with a uniform illuminance by using a smaller number of LEDs as well as a double-sided light emitting type illuminating device . The present invention is not limited to the above-described technical problems, and another technical problem may be derived from the following description.

There is provided a double-sided emission type LED lighting device comprising a pair of printed circuit boards fixed by a plurality of fixing members protruding downward from a ceiling side of a building so that conductive pattern surfaces face each other, A plurality of pairs of LEDs, each pair of which is mounted on a conductive pattern facing each other on a pair of printed circuit boards so that each pair of light emitting sides are opposed to each other, And a pair of LEDs, which are closest to each other and are opposed to each other among the plurality of LEDs, are inserted into openings at both ends of the pair of LEDs, and both ends of the LEDs are sandwiched between the pair of printed circuit boards, And a plurality of light emitting tubes for emitting light radiated from the plurality of light emitting elements, Space is arranged in parallel with each other at a predetermined interval in between the pair of the printed circuit board to emit light into the space of the upper and lower sides of the two-way between the pair of printed circuit boards.

A part of the luminous flux irradiated to the inner surface of each light emitting tube from each of the LEDs inserted into the openings at both ends of each of the light emitting tubes passes through the wall of each of the light emitting tubes, And the entire surface of each of the light emitting tubes can emit light by being reflected once and passing through the wall of each of the light emitting tubes. A diffusing lens for diffusing the light of each of the LEDs is provided on each of the LEDs inserted into the openings at both ends of each of the light emitting tubes. Light emitted from the LEDs is emitted by the diffusion lens, As shown in Fig. A plurality of protrusions are continuously formed in the longitudinal direction of each of the light emitting tubes on the inner surface of each of the light emitting tubes, and a part of the light beams emitted from the respective pairs of LEDs is formed on a plurality of projections formed on the inner surface of each of the light emitting tubes The brightness of the lower surface of each of the light emitting tubes can be made brighter than the brightness of the upper surface of each of the light emitting tubes.

Wherein each of the LEDs is mounted on each of the printed circuit boards so that light emitted from the respective LEDs inserted in the openings at both ends of each of the light emitting tubes reaches the inner surface of each of the light emitting tubes, Light emitted straight from each of the LEDs tilted and mounted on the substrate reaches the lower inner side of each of the light emitting tubes so that the brightness of the lower side of the outer side of each of the light emitting tubes becomes brighter than the brightness of the upper side of each of the light emitting tubes have. And a diffusion sheet for diffusing light emitted from each of the light emitting tubes may be attached to the outer surface of each of the light emitting tubes.

Wherein at least one opening having a height lower than the height of each of the LEDs inserted in the openings at both ends of each of the light emitting tubes is formed on both side walls of each of the light emitting tubes, So that the heat of each of the LEDs can be emitted to the outside of each of the light emitting tubes.

The double-sided emission type LED lighting device further includes a power supply box installed on a surface of the ceiling of the building or an internal space to supply power to the plurality of pairs of LEDs, And the other end of each of the printed circuit boards is engaged with a hole formed at both ends of each of the printed circuit boards so that each of the printed circuit boards is fixed by a plurality of wires which are linearly tightened by the load on the side of each printed circuit board , Each of the wires connected between the output terminals of the electric supply box and the input terminals of the pair of printed circuit boards can be wound in a helical manner on each of the plurality of linearly tensioned wires.

Wherein the power supply box is provided with a first LED drive circuit for outputting power for driving the first group of LEDs mounted on the conductive pattern of the first one of the pair of printed circuit boards, A second LED drive circuit for outputting a power for driving a second group of LEDs mounted in a line on a conductive pattern of a second printed circuit board among the plurality of the first printed circuit boards, Each of the two wires connected between the two output terminals of the first LED drive circuit and the two input terminals of the first printed circuit board among the two wires hanging in the holes at both ends of the first printed circuit board And two output terminals of the second LED drive circuit and two input terminals of the second printed circuit board Each of the two wires connected between the first printed circuit board and the second printed circuit board can be wound in a helical manner on each of the two wires caught in the holes at both ends of the first printed circuit board.

Wherein the double-sided emission type LED lighting apparatus further comprises a plurality of transparent tubes arranged in parallel with the plurality of light emitting tubes in a space between the pair of printed circuit boards, Wherein one end of each transparent tube is screwed to a first printed circuit board of the pair of printed circuit boards and the other end of each transparent tube is screwed to a second printed circuit board of the pair of printed circuit boards, The light emitting tube can be fitted between the pair of printed circuit boards. Wherein the double-sided emission type LED illumination device is inserted between a peripheral surface of both ends of each light emitting tube and each transparent tube and a conductive pattern side surface of each of the pair of printed circuit boards in a ring shape, And a plurality of rubber packings on which the surface is pressed as the pair of printed circuit boards are closely contacted.

The double-sided light emitting type LED lighting device includes a pair of printed circuit boards each having an inner surface attached to an outer surface opposite to a conductive pattern surface of each of the pair of printed circuit boards and electrically connected to the anode of each printed circuit board on each outer surface, And a pair of radiator plates laminated with a cathode conductive plate electrically connected to the cathode of each printed circuit board.

A plurality of light emitting tubes are arranged parallel to each other at regular intervals in a space between a pair of printed circuit boards fixed by a plurality of wires arranged downward from a ceiling side of a building, So that the shade and the glare on the ceiling of the building by the conventional single-sided LED lighting device which emits light toward the bottom side of the building disappear. As a result, the interior of the building is uniformly brightened without glare as a whole, thereby providing a smooth and comfortable high-quality lighting environment to the user.

In addition, since each printed circuit board is fixed by a plurality of wires which are not located inside the housing, the case and the cover, and are downwardly extended from the ceiling side of the building, most of the outer surface can be exposed to the air. Thus, the heat transferred from each LED to each printed circuit board can be released to the air, so that the heat dissipation of the LEDs through each printed circuit board is greatly facilitated. It is possible to provide excellent heat dissipation performance of an LED by using only a general substrate without introducing a special heat dissipation structure.

A part of the light beams irradiated to the inner surface of each light emitting tube from each of the LEDs inserted in the openings at both ends of each light emitting tube transmits through the wall of each light emitting tube and the remainder is reflected at least once on the inner surface of each light emitting tube, Since light is emitted in both directions above and below the space between the pair of printed circuit boards by using light emission of the entire surface of each light emitting tube which is generated by penetrating the wall of the pipe, It is possible to provide an LED illumination device having a significantly higher illumination efficiency than an indirect illumination type LED illumination device.

A plurality of projections are continuously formed in the longitudinal direction of each light emitting tube on the inner surface of each light emitting tube. A part of the light emitted from each pair of LEDs is reflected by a plurality of projections formed on the inner surface of each light emitting tube The LEDs are tilted and mounted on the respective printed circuit boards so that the light emitted from the respective LEDs inserted into the openings at both ends of the light emitting tube can be directed to the inner bottom side of each light emitting tube The brightness of the lower outer side of each arc tube can be made brighter than the brightness of the upper side of each outer tube. In this way, the illumination efficiency can be maximized by increasing the amount of light irradiated on the bottom side of the building.

At least one opening having a height lower than the height of each of the LEDs inserted in the openings at both ends of each light emitting tube is formed on each side wall of each light emitting tube. The inside of each light emitting tube is vented to the outside of each light emitting tube, The heat of the LED can be emitted to the outside of each arc tube. Thus, while the light sources of the LEDs are not exposed to the user's eyes, the heat of each of the LEDs is not accumulated in the inner space of each of the light emitting tubes, but is discharged to the outside of each of the light emitting tubes. As a result, Failure, shortened life span, and the like can be prevented.

Further, each of the printed circuit boards is fixed by a plurality of wires linearly tightened by the load on the side of each printed circuit board, and is connected between the output terminals of the electric supply box and the input terminals of the pair of printed circuit boards Each of the wires is rolled tightly in a spiral shape on each of a plurality of straightly tensioned wires to form a very simple structure. The wires and wires on the top of the space between the pair of printed circuit boards, Shading can be minimized.

The power supply box may further include a first LED drive circuit for outputting power for driving the first group of LEDs mounted on the conductive pattern of the first printed circuit board among the pair of printed circuit boards, A second LED driver circuit for outputting a power source for driving a second group of LEDs mounted in a line at regular intervals on a conductive pattern of the second printed circuit board, Each light emitting tube can emit light even if any one of the circuits fails. As a result, the inconvenience of the residents due to the unexpected turn-off of the interior of the building disappears.

In addition, each of the inner surfaces is attached to the outer surface of the pair of printed circuit boards opposite to the conductive pattern surface, and the outer surface of each of the pair of printed circuit boards is electrically connected to the anode of each printed circuit board. Emitting diode type illuminating device can be improved at a low cost without using a separate expensive heat-radiating member such as an aluminum heat sink or the like by a pair of radiator plates in which a cathode-plate conductive plate electrically connected to the light- have.

1 is a perspective view of a double-side emission type LED lighting apparatus according to an embodiment of the present invention.
2 is a plan view of the double-sided emission type illumination device shown in Fig.
Fig. 3 is a view showing various embodiments of each arc tube of the double-sided emission type illumination apparatus shown in Figs. 1-2.
FIG. 4 is a view showing the light traveling path inside the arc tube shown in FIG. 3 (a). FIG.
5 is a perspective view of a double-side emission type LED lighting device according to another embodiment of the present invention.
6 is a perspective view of a double-side emission type LED lighting apparatus according to another embodiment of the present invention.
7 is a plan view of the double-sided emission type LED lighting apparatus shown in Fig.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Embodiments of the present invention relate to an LED lighting device installed in a building and using a plurality of LEDs (Light Emitting Diodes) as a light source. In particular, embodiments of the present invention relate to a double-sided light emitting diode illumination device for simultaneously irradiating light to the bottom side and the ceiling of a building. A specific example of the LED to be applied to the embodiments to be described below is an SMD (Surface Mount Device) type LED chip which can be mounted on a printed circuit board (PCB). In the following description, a direct current may be abbreviated to "DC ".

FIG. 1 is a perspective view of a double-side emission type LED lighting apparatus according to an embodiment of the present invention, and FIG. 2 is a plan view of the double-side emission type illumination apparatus shown in FIG. 2, the double-sided LED light device according to the present embodiment includes a pair of printed circuit boards 11 and 12, a plurality of fixing members 20, a plurality of pairs of LEDs 31 and 32, A plurality of transparent tubes 50, a plurality of rubber packings 60, a plurality of engaging members 70, and a power supply box 80. The plurality of light emitting tubes 40, the plurality of transparent tubes 50, Hereinafter, in addition to the above-described main components, additional components may appear in describing the above-described components or in describing other embodiments of the present invention.

The pair of printed circuit boards 11 and 12 are fixed by a plurality of fixing members 20 protruding downward from the ceiling side of the building so that their respective conductive pattern surfaces face each other. Each of the fixing members 20 is preferably a wire 20 as shown in Fig. 1 for the reason as described below, but may be modified into other types of members such as metal or synthetic resin plates. Hereinafter, the present embodiment will be described in which each fixing member 20 is specified by a wire 20. That is, the pair of printed circuit boards 11 and 12 are fixed by a plurality of wires 20, which are downwardly extended from the ceiling side of the building, so that their respective conductive pattern planes face each other. The pair of printed circuit boards 11 and 12 may be composed of a rectangular first printed circuit board 11 and a second printed circuit board 12 of the same size.

Korean Patent No. 10-1453938 and Korean Patent No. 10-1454424 disclose a conventional LED illumination device that prevents the LED light from being directly applied to the user's eyes and prevents the LED from being impregnated with the LED, The heat transmitted from the LED to the printed circuit board is difficult to be released because the printed circuit board on which the LEDs are mounted is surrounded by the housing, the case, and the cover. In the present embodiment, since the printed circuit boards 11 and 12 are fixed by a plurality of wires 20 which are not located inside the housing, the case, and the cover but are downwardly extended from the ceiling side of the building, Lt; / RTI > Accordingly, the heat transferred from each of the LEDs 31 and 32 to the respective printed circuit boards 11 and 12 can be released to the air, so that heat dissipation of the LEDs through the printed circuit boards 11 and 12 is very easy do. Conventionally, in order to improve the heat radiation performance of the LED through the printed circuit board, an aluminum heat sink or the like is attached to a printed circuit board or a special heat radiation structure is introduced. However, this embodiment does not require a separate heat sink or a special heat radiation structure, -4 (Flame Retardant-4) epoxy resin, it is possible to provide an excellent LED heat dissipation performance.

One end of each wire 20 corresponding to each fixing member 20 is attached to the ceiling side of the building and the other end is hooked to a hole formed at each end of each printed circuit board 11, 11 and 12 can be fixed by two wires 20 which are linearly tightened by the load on each printed circuit board 11 and 12 side. One end of each wire 20 may be formed into a ring shape. A screw inserted into one ring-shaped end of each wire 20 is stuck on the ceiling surface of the building or the surface of the power supply box 80 mounted in the ceiling inner space of the building so that one end of each wire 20 is connected to the ceiling of the building As shown in Fig. The other end of each wire 20 may be formed in a hook shape. Each of the printed circuit boards 11 and 12 can be fixed by the respective wires 20 by engaging the other end of the claw shape of each wire 20 with a hole formed at both ends of the printed circuit boards 11 and 12 have.

As shown in Fig. 1, the other end of the claw shape of the two wires 20, one end of which is attached to the ceiling of the building, is hooked on a hole formed at both ends of the first printed circuit board 11, The circuit board 11 can be horizontally installed in the air by two wires 20. Likewise, the other end of the claw shape of the two wires 20 once attached to the ceiling side of the building is engaged with the hole formed at both ends of the second printed circuit board 12, so that the second printed circuit board 12 Can be horizontally installed in the air by two wires (20). The wire 20 may be made of a high strength material such as steel. Since the LED lighting apparatus according to the present embodiment can be fixed to the ceiling only by fixing the pair of printed circuit boards 11 and 12 by the four wires 20, A case, a cover, and the like are not required, and the manufacturing cost of the LED illumination device can be reduced.

The plurality of LEDs 21 and 22 are mounted on the conductive patterns of the pair of printed circuit boards 11 and 12 so that the light emitting sides of the pairs are opposed to each other, Each pair emits light in the opposite direction to each other. The plurality of LEDs 21 and 22 are electrically connected to the first group of LEDs 21 and the second group of LEDs 21 mounted on the conductive pattern surface of the first printed circuit board 11 at regular intervals, And a second group of LEDs 32 mounted in a line on the pattern surface at regular intervals. A pair of LEDs are inserted into one luminous tube while being opposed to each other among the first group of LEDs 21 and the second group of LEDs 32. [ As described above, in this embodiment, one light emitting tube emits light by using two LEDs inserted therein. As shown in FIGS. 1-2, each LED group can be composed of seven LEDs, and seven light emitting tubes 40 can emit light using these LED groups. The number of LEDs constituting each LED group can be variously changed, and accordingly, the number of luminous tubes can be variously changed.

The LEDs 31 and 32 are SMD type LED chips that can be mounted on the first printed circuit board 11 or the second printed circuit board 12 in a rectangular parallelepiped shape. A positive terminal and a negative terminal are protruded from the lower surface of each of the LEDs 31 and 32 and electrically connected to the conductive pattern of the first printed circuit board 11 or the second printed circuit board 12, And 32 are attached to the conductive patterns of the first printed circuit board 11 or the second printed circuit board 12. The four side surfaces of the LEDs 31 and 32 protrude from the conductive pattern surface of the first printed circuit board 11 or the second printed circuit board 12 and are positioned in the inner space of each light emitting tube 40 .

The four side edges of each of the LEDs 31 and 32 are brought into contact with the inner surface of each light emitting tube 40 so that the LEDs 31 and 32 can be fixed to the inner space of each light emitting tube 40. If the inner diameter of each luminous bulb 40 is larger than the diagonal length of each of the LEDs 31 and 32 so that the four side edges of the LEDs 31 and 32 are in contact with the inner surface of the luminous bulb 40 A filling material such as a rubber packing may be inserted between the circumference of each of the LEDs 31 and 32 and the inner surface of each light emitting tube 40 in order to fix the LEDs 31 and 32. An upper surface of each of the LEDs 31 and 32 mounted on one of the pair of printed circuit boards 11 and 12 is located in an inner space of each light emitting tube 40 and emits light toward another printed circuit board.

In the conventional LED lighting device as described above, since a large number of LEDs are densely arranged in a lattice pattern on one printed circuit board, the heat generated from a large number of LEDs is concentrated on one printed circuit board do. The concentration of heat due to the arrangement of the LED grid due to the one-sided light emission induces a high temperature in each LED, which causes deterioration, failure, and shortening of life of the LED, and a heat dissipating member such as a heat sink is required. . On the other hand, in the LED lighting apparatus according to the present embodiment, since a plurality of LEDs 31 and 32 are arranged in a row on each of the pair of printed circuit boards 11 and 12 to emit light on both sides, heat concentration due to the arrangement of the LED grid Disappear. As described above, according to the present embodiment, deterioration of the LED due to the heat generation of the LED, failure and shortening of the life time of the LED can be prevented and the special heat dissipating member is not needed, The manufacturing cost can be reduced.

A plurality of pairs of LEDs 31 and 32, which are closest to each other and are opposed to each other among a plurality of pairs of LEDs 31 and 32, are inserted into openings at both ends of the plurality of bulbs 40, And is inserted between the printed circuit boards 11 and 12. Each of the LEDs 31 and 32 receives light emitted from each pair of LEDs 31 and 32 so that the entire surface thereof emits light. 1-2, the plurality of light emitting tubes 40 are arranged parallel to each other at regular intervals in a space between a pair of the printed circuit boards 11, 12, so that a pair of printed circuit boards 11, 12, so that the light is emitted in both directions from the upper side and the lower side of the space. Each light emitting tube 40 may be a material having a high light transmittance, for example, a cylindrical tube made of polycarbonate or the like.

Since the conventional LED lighting device as described above is a one-sided light emitting type that irradiates light to the bottom side of a building, shading and glare on the ceiling of the building occur. Conventional indirect lighting methods for solving the shade and glare of the building ceiling have very low illumination efficiency because they irradiate light to the ceiling or walls of buildings with very low reflectance. According to this embodiment, a plurality of light emitting tubes 40 are arranged in a space between a pair of printed circuit boards 11 and 12 fixed by a plurality of wires 20 extending downward from the ceiling side of the building, Are arranged in parallel to each other and emit light in both directions above and below the space between the pair of printed circuit boards (11, 12), the shade and glare on the ceiling of the building disappear and a smaller number of LEDs Not only can a wider space be illuminated with a uniform illumination, but also has a very high illumination efficiency as compared with indirect illumination. As a result, it is possible to provide a smooth and comfortable high-quality lighting environment to the user while reducing the manufacturing cost and power consumption of the LED illumination device.

Fig. 3 is a view showing various embodiments of each arc tube 40 of the double-sided emission type illumination apparatus shown in Figs. 1-2. Since most of the light emitted from each of the LEDs 31 and 32 inserted in the openings at both ends of each light emitting tube 40 is emitted to the respective light emitting And does not reach the inner surface of the pipe 40. A diffusing lens 41 for diffusing the light of each of the LEDs 31 and 32 is provided on each of the LEDs 31 and 32 inserted into the openings at both ends of each arc tube 40, Can be installed. Accordingly, light emitted straight from the LEDs 31 and 32 can be diffused by the diffusion lens 41 and reach the inner surface of each light-emitting tube 40. [ On the other hand, in the case where the diffusing lens 41 is incorporated in each of the LEDs 31 and 32, a separate diffusing lens 41 need not be provided.

Fig. 4 is a view showing a path of light propagation in the arc tube 40 shown in Fig. 3 (a). 4, a part of the luminous flux irradiated to the inner surface of each arc tube 40 from each of the LEDs 31 and 32 inserted into the openings at both ends of each arc tube 40 is supplied to each arc tube 40, and the remainder is reflected at least once on the inner surface of each arc tube 40, and is transmitted through the wall of each arc tube 40, so that the entire surface of each arc tube 40 emits light. The luminous flux irradiated to the inner surface of each luminous bulb 40 is reflected by the inner air of each luminous bulb 40 due to the change in the medium between the air inside the bulb 40 and the material of the luminous bulb 40, Part of the light is refracted at the boundary of the wall of the reflector 40 and the remainder is reflected. The reflected light flux is similarly partially refracted and the remainder is reflected. Most of the luminous flux irradiated to the inner surface of each arc tube 40 travels inside each arc tube 40 while repeating such reflection. As a result, the luminous flux irradiated to the inner surface of each arc tube 40, (40). The light flux refracted at the boundary between the inner air of each arc tube 40 and the wall of each arc tube 40 is transmitted through the wall of each arc tube 40 and exits to the outside, Can emit light.

The double-sided LED light device shown in Figs. 1-2 is typically installed much closer to the indoor ceiling of the building than the indoor floor of the building. Since the ceiling surface of the building is generally made of a material having a low light reflectance, the space between the pair of printed circuit boards 11 and 12 is formed by each light emitting tube 40 as shown in Fig. 3 (a) The amount of light irradiated to the bottom side of the building is reduced and the illumination efficiency is reduced. In the present embodiment, the LEDs 31 and 32 are inserted into the openings at both ends of the arc tube 40, so that the light of each of the LEDs 31 and 32 is emitted The glare can not be directly applied to the human eye and thus the glare is intrinsically blocked by the arc tube 40. 3 (b), 3 (c), and 3 (d) show a light-emitting tube 40 for making the brightness of the lower side of the space between the pair of printed circuit boards 11, ) Are shown.

As shown in FIG. 3 (b), a plurality of projections may be continuously formed in the longitudinal direction of each light emitting tube 40 above the inner surface of each light emitting tube 40. For example, at the upper side of the inner surface of each arc tube 40, the projection in the longitudinal direction of each arc tube 40 is triangular in shape and the transverse section is trapezoidal in a length corresponding to the distance between the pair of LEDs 31 and 32 Can be continuously formed. The upper side of the inner surface of each light emitting tube 40 having a plurality of projections has a larger surface area than the inner surface of each light emitting tube 40 having a smooth inner surface so that much more light is reflected. That is, a part of the light flux emitted from each pair of LEDs 31 and 32 is reflected by a plurality of protrusions formed on the inner surface of each light emitting tube 40 and directed to the lower side of the inner surface of each light emitting tube 40, The brightness of the lower side of the outer surface of the tube 40 becomes brighter than the brightness of the upper side of the outer surface of each of the arc tubes 40. [ Here, the upper side of the inner surface of each arc tube 40 refers to one side of the inner surface of each arc tube 40 facing toward the ceiling of the building, and the upper side of the inner surface of each arc tube 40 faces toward the indoor bottom side of the building And the other side of the inner surface of each arc tube 40.

Light emitted from the respective LEDs 31 and 32 inserted into the openings at both ends of each arc tube 40 reaches the lower side of the inner surface of each arc tube 40 as shown in Figure 3 (c) The LEDs 31 and 32 can be mounted on the printed circuit boards 11 and 12 by being tilted. Light emitted from the respective LEDs 31 and 32 tilted and mounted on the respective printed circuit boards 11 and 12 reaches the lower inner side of each light emitting tube 40, Is brighter than the brightness of the upper side of the outer surface of each light emitting tube (40). For example, when the LEDs 31 and 32 are tilted at desired angles and positioned on the printed circuit boards 11 and 12, the LEDs 31 and 32 The LEDs 31 and 32 are tilted on the respective printed circuit boards 11 and 12 by solder which is thicker bonded to one lead of each of the LEDs 31 and 32 by soldering the leads of the LEDs 31 and 32 Can be mounted.

In the embodiment shown in FIG. 3 (b), a plurality of projections are formed on the inner surface of each light emitting tube 40, so that it is not easy to manufacture the light emitting tube 40, The manufacturing cost is increased accordingly. In the embodiment shown in FIG. 3 (c), only by tilting and mounting the LEDs 31 and 32 on the printed circuit boards 11 and 12, the brightness of the lower side of each light- 40, the luminous bulb 40 is easily manufactured, and the diffusion lens 41 is not required, and the manufacturing cost is low. In addition, the light loss due to the diffusion lens 41 disappears, and the illumination efficiency can be improved. Further, in order to maximally improve the illumination efficiency of the embodiment shown in FIG. 3 (c), light emitted from the edge of the light emitting portion of each of the LEDs 31 and 32 is emitted to the inner surface of both ends of each light emitting tube 40 It is preferable that the LEDs 31 and 32 are mounted on the printed circuit boards 11 and 12 by being tilted.

A diffusing sheet 42 for diffusing light emitted from each light emitting tube 40 is formed on the outer surface of each light emitting tube 40 shown in Figure 3 (c) as shown in Figure 3 (d) . In the case where the light emitting tube 40 is made of a material having high light transmittance such as polycarbonate, the embodiment shown in FIG. 3 (c) may cause slight glare because it does not use a diffusion lens. The diffusion sheet 42 can be attached to the entire outer surface of each light emitting tube 40 in order to more completely block the glare caused by the light source of each of the LEDs 31 and 32 and smoothly create the atmosphere of the building interior The light emitted from the outer surface of each light emitting tube 40 is further diffused by the diffusion sheet 42.

The heat of the respective LEDs 31 and 32 inserted into the openings at both ends of the arc tube 40 is accumulated in the inner space of each arc tube 40 and the LEDs 31 and 32, Can be overheated. 1, at both side walls of each arc tube 40, at least one opening 401 (FIG. 1) having a height lower than the height of each of the LEDs 31, 32 inserted into the openings at both ends of each arc tube 40 The inside of each light emitting tube 40 is vented to the outside of each light emitting tube 40 so that the heat of each of the LEDs 31 and 32 can be emitted to the outside of each light emitting tube 40. The heat of each of the LEDs 31 and 32 is not accumulated in the inner space of each light emitting tube 40 and the light emitted from each of the light emitting tubes 40 is not accumulated in the inner space of each light emitting tube 40, The LEDs 31 and 32 may be prevented from being deteriorated or shortened in life due to overheating of the LEDs 31 and 32 without being glare.

A plurality of transparent tubes (40) are arranged in parallel with a plurality of light emitting tubes (40) in a space between a pair of printed circuit boards (11, 12). As shown in FIGS. 1-2, two transparent tubes 50 may be provided on both sides of the seven arc tubes 40. Each transparent tube 50 may be a cylindrical tube made of a material having a high light transmittance, such as polycarbonate or the like, as in the case of the arc tube 40 in order to minimize the power of the light tube. Do. The length of each transparent tube 50 is the same as the length of the arc tube 40, and threads are formed on the inner surface of the openings at both ends thereof. One end of each transparent tube 50 is screwed to the first printed circuit board 11 of the pair of printed circuit boards 11 and 12 so that the pair of printed circuit boards 11 and 12 are in close contact with each other, The other end of the tube 50 is screwed to the second printed circuit board 12 of the pair of printed circuit boards 11 and 12 so that the plurality of light emitting tubes 40 are connected to the pair of printed circuit boards 11 and 12, As shown in FIG.

1-2, a plurality of coupling members 70, for example, four bolts, are passed through both end holes of a pair of printed circuit boards 11, 12, and then two transparent tubes 50, The two transparent tubes 50 and the pair of printed circuit boards 11 and 12 can be screwed into each other. Instead of the transparent tube 50, four bolts and four nuts, which are longer than the sum of the lengths of the two transparent tubes 50 and the thicknesses of the pair of printed circuit boards 11 and 12, (40) may be fitted between a pair of printed circuit boards (11, 12). However, the light emitted from each light emitting tube 40 can not transmit through such a long bolt, so that shading due to light shielding of the bolt may occur.

The plurality of rubber packings 50 are ring-shaped and are arranged between the circumferential surfaces of both ends of each arc tube 40 and each transparent tube 50 and between the conductive pattern surfaces of the pair of printed circuit boards 11 and 12 The surfaces of the pair of printed circuit boards 11 and 12 are pressed together by the screw connection between the transparent tube 50 and the pair of printed circuit boards 11 and 12. Even if the lengths of the seven light emitting tubes 40 and the two transparent tubes 50 are made equal, the lengths of the seven light emitting tubes 40 and the two transparent tubes 50 may be slightly different . In order to compensate for the difference in length between each of the seven light emitting tubes 40 and the two transparent tubes 50 and to protect the respective ends thereof, seven light emitting tubes 40 and two transparent tubes 50, A rubber packing 50 is inserted between the conductive pattern surfaces of the printed circuit boards 11 and 12. [

As described above, since each light emitting tube 40 can be fitted between the first printed circuit board 11 and the second printed circuit board 12 with a very simple structure, the housing, the case, the cover It is possible to reduce the manufacturing cost of the LED illumination device. In addition, the bolts fastened to the openings at both ends of the two transparent tubes 50 are slightly loosened so that the pair of printed circuit boards 11 and 12 are in close contact with each other. By the elasticity of the rubber packing 60, (40) can be pushed either way. If any one of the LEDs mounted on the first printed circuit board 11 and the second printed circuit board 12 breaks down, only one luminous tube into which the inserted LEDs are inserted can be repaired in a very simple manner.

The power supply box 80 is installed on the surface or inside space of the ceiling of the building, and supplies power to a plurality of LEDs 31 and 32. The power supply box 80 is provided with an LED drive circuit including a rectifier for converting the alternating current of the commercial power source into a direct current, a DC / DC converter for changing the output voltage of the rectifier to the drive voltage of the LED, and the like. Such an LED drive circuit is a technique well known to those skilled in the art to which this embodiment belongs, and therefore, the illustration thereof will be omitted because it is not characteristic in any aspect. As described above, each of the printed circuit boards 11 and 12 can be fixed by two wires 20 that are linearly tightened by the load on the printed circuit boards 11 and 12 side. Each of the wires 21 connected between the output terminals of the power supply box 80 and the input terminals of the pair of printed circuit boards 11 and 12 is wound on each of a plurality of wire- So that it can be closely wound in a shape. As shown in Fig. 1, wires (20) electrically connecting the respective output terminals of the power supply box (80) to the respective input terminals of the pair of printed circuit boards (11, 12) The wire 20 and the wire 21 located at the upper part of the space between the pair of printed circuit boards 11 and 12 are formed in a very simple structure by being coiled in a spiral shape, The shade of the side can be minimized.

The LED driver circuit includes electronic devices such as a switching transistor, a capacitor, and the like which are shorter in life time than the LED and have a low durability. Accordingly, in the conventional LED lighting device, it is often found that the LED is not turned on due to failure of an LED driving circuit, which is referred to as a switching mode power supply (SMPS), rather than a failure of the LED itself. Since each pair of LEDs 31 and 32 is inserted into the openings at both ends of each light emitting tube 30, each light emitting tube 40 can emit light with a somewhat lower brightness even if one of the LEDs is turned off. In this embodiment, in order to prevent the LED illumination device from being turned off due to the failure of the LED drive circuit, the LED drive circuit for the first group of LEDs 31 mounted on the first printed circuit board 11, The LED driving circuit for the second group of LEDs 32 mounted on the circuit board 12 operates independently.

That is, the power supply box 80 is provided with a first LED drive circuit for outputting power for driving the first group of LEDs 31 mounted on the conductive pattern of the first printed circuit board 11, And a second LED driver circuit for outputting a power source for driving the second group of LEDs 32 mounted on the conductive pattern of the circuit board 12 is incorporated. Accordingly, even if either the first LED driving circuit or the second LED driving circuit fails, any one of the pair of LEDs 31 and 32 inserted in the openings at both ends of each light emitting tube 30 is turned on Each light emitting tube 40 can emit light even when one of the LEDs is turned off. It is rare that the first LED drive circuit and the second LED drive circuit fail at the same time. Therefore, the two LED drive circuits are alternately repaired in response to a sudden failure or aging of the respective LED drive circuits, Brightness above the illuminance can be maintained. As a result, the inconvenience of the residents due to the unexpected turn-off of the interior of the building disappears.

1, two output terminals of the first LED drive circuit among the output terminals of the power supply box 80 are connected to two input terminals of the first printed circuit board 11, Each of the first printed circuit board 21 and the second printed circuit board 11 is tightly wound in a spiral manner on each of the two wires 20 caught in the holes at both ends of the first printed circuit board 11, Each of the two wires 21 connected between the two input terminals of the first printed circuit board 12 is spirally wound around each of the two wires 20 caught in the holes at both ends of the first printed circuit board 11. Accordingly, the shadow of the ceiling due to the light shielding of the four wires 20 and the four wires 21 located at the upper part of the space between the pair of printed circuit boards 11 and 12 can be minimized.

5 is a perspective view of a double-side emission type LED lighting device according to another embodiment of the present invention. 5, the double-sided LED light device according to the present embodiment includes a pair of printed circuit boards 11 and 12, a plurality of wires 20, a plurality of LEDs 31 and 32, A tube 40, a plurality of transparent tubes 50, a plurality of rubber packings 60, a plurality of engaging members 70, a power supply box 80, and a reflector 90. 5 is the same as the embodiment shown in Figs. 1-2 except that the reflector 90 is added. Therefore, the following description will focus on differences from the embodiment shown in Figs. 1-2 The detailed description of each configuration not shown in the following will be replaced with a description of the embodiment shown in FIGS. 1-2.

Most of the fluorescent lamps currently used for indoor lighting are installed in the form of being embedded in the ceiling of a building. When the double-sided emission type LED illumination device shown in Figs. 1-2 is used to replace such a fluorescent lamp, it can be installed in a form embedded in the ceiling of a building. In this case, the light emitted to the upper side of the space between the pair of printed circuit boards 11 and 12 by the plurality of light-emitting tubes 40 is irradiated only inside the embedding area of the building ceiling, . In this embodiment, the reflector 90 (or 90) is provided on the upper side of the pair of printed circuit boards 11, 12 in order to reflect the light emitted to the upper side of the space between the pair of printed circuit boards 11, ) Is installed.

The reflector 90 is positioned on the upper side of the pair of printed circuit boards 11 and 12 and reflects downward the light emitted to the upper side of the space between the pair of printed circuit boards 11 and 12, . The reflector 90 is composed of a rectangular flat plate and four trapezoidal inclined plates which are bent downward from four sides of the flat plate. One end of each wire 20 can be attached to the reflector 90 by fastening one end of each wire 20 to the bolt inserted into the hole of the edge of the flat plate of the reflector 90. The angle between the flat plate of the reflector 90 and the swash plate determines the irradiation range of the double-sided emission type illumination device according to this embodiment and the luminous flux of the irradiation area. The reflector shade 90 may be installed in a form embedded in the depression of the building ceiling or close to the ceiling of the building. The reflector 90 may be manufactured by coating stainless steel or the like and a metal plate with a reflective material such as silver, aluminum, or the like.

FIG. 6 is a perspective view of a double-side emission type LED lighting device according to another embodiment of the present invention, and FIG. 7 is a plan view of the double-side emission type LED lighting device shown in FIG. 6-7, a double-sided LED light device according to the present embodiment includes a pair of printed circuit boards 11 and 12, a plurality of wires 20, a plurality of LEDs 31 and 32, A plurality of transparent tubes 50, a plurality of rubber packings 60, a plurality of engaging members 70, a power supply box 80, a pair of radiator plates 101 and 102, And a cover 110. The embodiment shown in Figs. 6-7 is the same as the embodiment shown in Figs. 1-2 except that a pair of radiator plates 101, 102 and a cover 110 are added. 6-7, focusing on the differences from the embodiment shown in FIG. 2, and the detailed description of each configuration not shown below will be made with reference to the embodiment shown in FIGS. 1-2 Let's do it.

In an interior space, such as a kitchen, the lighting of the overall feeling of softness rather than the brightness of the interior takes precedence over the location of the building ceiling, for example, at a height of two thirds of the distance between the ceiling and the floor Is installed. For example, as shown in FIG. 6, one end of a plurality of wires 20 attached to a pair of printed circuit boards 11 and 12 is gathered and elongated in a twisted manner, The double-sided light emitting diode illumination device can be installed at a position which is considerably spaced from the ceiling of the building. In order to improve the aesthetics of the interior of the building, a cover 110 covering the entire outer surface of the double-side emission type LED illumination device shown in Figs. 1-2 can be covered. For example, the double-sided emission type LED illumination device shown in Figs. 1-2 can be covered with a spherical transparent cover 110. Fig.

6, the inside of the cover 110 covering the entire outer surface of the pair of printed circuit boards 11 and 12 is formed with a plurality of wires 20 and a hole through which the electric wire 21 passes, The heat of the respective LEDs 31 and 32 can be accumulated in the inner space of the cover 110. [ Accordingly, in the embodiment shown in Fig. 6, a further improved heat radiation performance is required. Each of the pair of radiator plates 101 and 102 is attached to an outer surface of the pair of printed circuit boards 11 and 12 opposite to the conductive pattern surface of the pair of radiator plates 101 and 102. Each of the printed circuit boards 11 and 12 A cathode plate 1001 in the form of a through plate electrically connected to the anode of the printed circuit boards 11 and 12 and a cathode plate 1002 in the form of a through plate electrically connected to the cathodes of the printed circuit boards 11 and 12 are laminated. The positive electrode plate 1001 and the negative electrode plate 1002 of each of the radiator plates 101 and 102 may be made of copper having a high thermal conductivity like the conductive patterns of the printed circuit boards 11 and 12. The entire outer surface of each of the radiator plates 101 and 102 is coated with copper in order to maximize the area of the positive electrode plate 1001 and the negative electrode plate 1002 of each of the radiator plates 101 and 102, A narrow gap for insulation between the cathode plates 1002 can be etched. One side of the copper plate in which the narrow gap is etched in this way becomes the positive electrode plate 1001 and the other side becomes the negative electrode plate 1002. [

The inner surface of the pair of radiating plates 101 and 102 is attached to the outer surface of the first printed circuit board 11 opposite to the conductive pattern surface of the first printed circuit board 11 and is electrically connected to the anode of the first printed circuit board 11, A first radiator plate 101 in which a cathode plate 1001 in the form of a plate and a cathode plate 1002 in the form of a through plate electrically connected to cathodes of the first printed circuit board 11 are laminated, A positive electrode plate 1001 in the form of a through hole and electrically connected to the negative electrode of the second printed circuit board 12 is formed on the outer surface of the positive electrode plate 1001 on the opposite side of the conductive pattern surface of the second printed circuit board 12, And a second radiator plate 102 on which a cathode plate 1002 in the form of a channel is laminated. The positive electrode plate 1001 of each of the heat dissipating plates 101 and 102 is electrically connected to each of the printed circuit boards 11 and 12 through a conductive coupling member 70 such as a bolt passing through both end holes of the printed circuit boards 11 and 12, 11 and 12, respectively. The negative electrode plate 1002 of each of the heat dissipating plates 101 and 102 can be electrically connected to the negative electrode of each printed circuit board 11 and 12 in the same manner.

The thermal conduction rate is proportional to the thermal conductivity, the constant of the material that represents the degree of heat transfer, and the area of the plate to which heat is transferred. Since the leads of the LEDs 31 and 32 are soldered to the respective printed circuit boards 11 and 12, the heat generated by the LEDs 31 and 32 is transmitted to the anode plate 1001 of each of the heat dissipating plates 101 and 102 And is directly transferred to the cathode plate 1002. The positive electrode plate 1001 and the negative electrode plate 1002 of each of the heat dissipation plates 101 and 102 can receive most of the heat generated in the LEDs 31 and 32 and discharge it to the outside through a wide surface thereof in a short time. As described above, the present embodiment can improve the heat radiation performance of the double-sided emission type LED lighting apparatus at a low cost by using an inexpensive printed circuit board as a heat radiation member without using expensive expensive heat radiation members such as aluminum heat sinks.

8 is a perspective view of a double-side emission type LED lighting apparatus according to another embodiment of the present invention. Referring to FIG. 8, the double-sided LED light device according to the present embodiment includes a pair of printed circuit boards 11 and 12, a plurality of wires 20, a plurality of LEDs 31 and 32, A plurality of transparent pipes 50, a plurality of rubber packings 60, a plurality of coupling members 70, a power supply box 80, a pair of radiator plates 101 and 102, a cover 120 ), A base plate 121, and a bracket 122. The embodiment shown in Fig. 8 is different from the embodiment shown in Fig. 6 except that the spherical cover 110 shown in Fig. 6 is replaced with a rectangular box-shaped cover 120, a rectangular plate-shaped base plate 121 and a bracket 122 6-7. Therefore, the embodiment shown in FIG. 8 will be described focusing on the difference from the embodiment shown in FIGS. 6-7. Hereinafter, the configuration shown in FIG. A detailed description thereof will be omitted in the description of the embodiment shown in Fig.

In an indoor space such as a living room, a room, etc., unlike a kitchen, an illumination light is usually attached to a building ceiling scene. As shown in Fig. 8, the double-sided emission type LED illumination device shown in Fig. 7 can be covered with a rectangular-box-shaped transparent cover 120. Fig. A base plate 121 of a metal material is coupled to the upper opening of the cover 120 for attaching the cover 120 to the ceiling of the double-side emission type LED lighting apparatus shown in FIG. The base plate 121 can be attached to the ceiling of the building using the bracket 122. Reflective materials such as silver and aluminum are coated on the lower surface of the base plate 121 to reflect the light of the LEDs 31 and 32 toward the bottom of the building. The power supply box 80 is mounted on the upper surface of the base plate 121 so that the light shielding of the power supply box 80 can be removed.

The present invention has been described with reference to the preferred embodiments. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the disclosed embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is defined by the appended claims rather than by the foregoing description, and all differences within the scope of equivalents thereof should be construed as being included in the present invention.

11, 12 ... a pair of printed circuit boards
20 ... plural wires
31, 32 ... plural pairs of LED
40 ... plural luminous tubes
41 ... diffuse lens
42 ... diffusion sheet
50 ... plural transparent tubes
60 ... Multiple rubber packing
70 ... a plurality of coupling members
80 ... Power supply box
90 ... Reflector
101, 102 ... a pair of radiator plates
1001 ... Bipolar plate
1002 ... negative plate
110, 120 ... Cover
121 ... base plate
122 ... bracket

Claims (12)

A pair of printed circuit boards (11, 12) fixed by a plurality of fixing members (20) protruding downward from the ceiling side of the building and positioned so that the conductive pattern surfaces face each other;
Wherein the pair of printed circuit boards (11, 12) are mounted on the conductive patterns facing each other so that the pairs of light emitting sides are opposed to each other, A plurality of pairs of LEDs 31 and 32 for emitting light; And
The pair of printed circuit boards 11 and 12 are connected to the openings at both ends of the pair of LEDs 31 and 32 so that both ends of the pair of LEDs 31 and 32, And a plurality of light emitting tubes (40) each of which is illuminated on the entire surface by receiving light emitted from each of the pair of LEDs (31, 32)
The plurality of arc tubes (40) are arranged parallel to each other at regular intervals in a space between the pair of printed circuit boards (11, 12), and are arranged on the upper side of the space between the pair of printed circuit boards And the lower side,
Further comprising a plurality of transparent tubes (50) arranged in parallel with the plurality of arc tubes (40) in a space between the pair of printed circuit boards (11, 12)
One end of each transparent tube 50 is connected to the first printed circuit board 11 of the pair of printed circuit boards 11 and 12 so as to be in close contact with the pair of printed circuit boards 11 and 12, And the other end of each transparent tube 50 is screwed to the second printed circuit board 12 of the pair of printed circuit boards 11 and 12 so that the plurality of light emitting tubes 40 And is fitted between the circuit boards (11, 12). The method according to claim 1,
A part of the luminous flux irradiated to the inner surfaces of the respective arc tubes 40 from the respective LEDs 31 and 32 inserted into the openings at both ends of the arc tubes 40 is discharged to the outside And the remainder is reflected at least once on the inner surface of each of the arc tubes 40, and is transmitted through the wall of each of the arc tubes 40, so that the entire surface of each of the arc tubes 40 emits light. A light emitting diode (LED) 3. The method of claim 2,
A diffusing lens 41 for diffusing the light of each of the LEDs 31 and 32 is provided on each of the LEDs 31 and 32 inserted into the openings at both ends of the respective arc tube 40, , 32) is diffused by the diffusion lens (41) and reaches the inner surface of each light emitting tube (40). The method of claim 3,
A plurality of protrusions are continuously formed in the longitudinal direction of each of the light emitting tubes (40) on the inner surface of each of the light emitting tubes (40)
A part of the luminous flux emitted from each of the pairs of LEDs 31 and 32 is reflected by a plurality of projections formed on the inner surface of each of the luminous bulbs 40 and directed toward the lower inner surface of the luminous bulbs 40, And the brightness of the lower side of the outer surface of each light emitting tube (40) is brighter than the brightness of the upper side of the outer surface of each light emitting tube (40). 3. The method of claim 2,
The respective LEDs 31 and 32 are arranged such that light emitted from the respective LEDs 31 and 32 inserted into the openings at both ends of the respective arc tubes 40 reaches the inner surface of the respective arc tubes 40 Is mounted on each of the printed circuit boards (11, 12) by tilting,
Light emitted from the respective LEDs 31 and 32 tilted and mounted on the printed circuit boards 11 and 12 reaches the lower inner surface of the light emitting tube 40, And the brightness of the lower side of the outer surface of the light emitting tube (40) is brighter than the brightness of the upper side of the outer surface of the light emitting tube (40). 6. The method of claim 5,
Wherein a diffusion sheet (42) for diffusing light emitted from each light emitting tube (40) is attached to the outer surface of each light emitting tube (40). The method according to claim 1,
At least one opening 401 having a height lower than the height of each of the LEDs 31 and 32 inserted into the openings at both ends of the light emitting tube 40 is formed on both side walls of the light emitting tube 40, The inside of each arc tube 40 is vented to the outside of each arc tube 40 so that heat of the LEDs 31 and 32 can be emitted to the outside of each arc tube 40 Double - sided emission type LED lighting device. The method according to claim 1,
Further comprising a power supply box (80) installed on the surface or inside space of the ceiling of the building to supply power to the plurality of pairs of LEDs (31, 32)
One end of each wire 20 corresponding to each fixing member 20 is attached to the ceiling side of the building and the other end is hooked to a hole formed at both ends of the printed circuit boards 11 and 12, The circuit boards 11 and 12 are fixed by a plurality of wires 20 which are linearly tensioned by the loads on the printed circuit boards 11 and 12,
Each of the electric wires connected between the output terminals of the power supply box 80 and the input terminals of the pair of printed circuit boards 11 and 12 is wound on each of the plurality of wire- Shaped LED light source. 9. The method of claim 8,
The power supply box 80 is provided with a first LED driving circuit (not shown) for outputting power for driving the first group of LEDs 31 mounted on the conductive pattern of the first printed circuit board among the pair of printed circuit boards, And a second LED driving circuit for outputting a power for driving a second group of LEDs 32 mounted in a line on a conductive pattern of the second printed circuit board of the pair of printed circuit boards at regular intervals And,
Each of the two output terminals of the first LED drive circuit among the output terminals of the power supply box 80 and the two wires 21 connected between the two input terminals of the first printed circuit board 11 The first and second printed circuit boards 11 and 12 are tightly wound in a spiral manner on each of the two wires 20 caught at both ends of the first printed circuit board 11, ) Are wound tightly in a spiral shape on each of the two wires (20) caught in the holes at both ends of the first printed circuit board (11) Side light-emitting-type LED illumination device. delete The method according to claim 1,
Each of which is inserted between a peripheral surface of both ends of each of the light emitting tubes 40 and the transparent tubes 50 and a surface of a conductive pattern side of each of the pair of printed circuit boards 11 and 12, Further comprising a plurality of rubber packings (60) whose surfaces are pressed as the pair of printed circuit boards (11, 12) are tightly joined together by the bonding. The method according to claim 1,
Each inner surface of which is attached to the outer surface of the opposite side of the conductive pattern surface of each of the pair of printed circuit boards 11 and 12 and is connected to the outer surface of each of the printed circuit boards 11 and 12, And a pair of radiator plates (101, 102) in which a conductive plate (1001) and a cathode conductive plate (1002) in the form of a through plate electrically connected to the cathodes of the printed circuit boards (11, 12) Shaped LED illumination device.

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