KR101196544B1 - Lamp having High-Efficiency of radiating heat - Google Patents

Abstract

The present invention relates to a luminaire that emits light using an LED lamp as a light source, and in particular, by improving the structure of the casing to dissipate heat emitted from the LED lamp to the outside by heat conduction to excellent heat dissipation effect of the luminaire.
Currently, the luminaires installed in the underground, subway, tunnels and roadsides are sealed to prevent fine dust and moisture from penetrating. In the past, fluorescent lamps were used to generate less heat, but recently, LED lamps with high luminous efficiency and long lifespan have been used. There is a problem that the heat generated due to the use of such a function caused by the heat generated, the problem of shortening the life of the luminaire occurs, in particular the luminaire is more difficult to heat radiation due to the sealed waterproof cover.
Therefore, the present invention is equipped with a heat sink for heat conduction between the lamp and the reflector plate, the shape of the heat sink is bent in the "c" shape to be able to mount the lamp without a separate fixing means to simply assemble the slide fitting method. It is possible to increase the life of the lamp and the luminaire and to prevent deterioration by allowing the heat sink to perform the heat dissipation function of the lamp fixing means and the lamp at the same time without being pulled out in a fixed state.

Description

Lamp having High-Efficiency of radiating heat

The present invention relates to a luminaire that emits light using an LED lamp as a light source, and in particular, by improving the structure of the casing to dissipate heat emitted from the LED lamp to the outside by heat conduction to excellent heat dissipation effect of the luminaire.

In general, the luminaire is installed in various places such as an underpass, subway, tunnels and roadsides, the structure of the luminaire is inserted into the interior of the case as shown in Figure 6 and the reflection plate is fixed to the upper side of the reflector The socket and the fixing member are formed so that the tube-type lamp is mounted in a state spaced apart from the reflecting plate.

In addition, the floodlight cover is mounted on the top of the lamp to have a waterproof function to prevent soot, fine dust, and moisture from penetrating by the packing, so that the humidity is high due to the difficulty of ventilation in a blocked state such as subway or tunnel. In addition, the durability and performance degradation of the luminaires are prevented from occurring, and it is also possible to perform a waterproof function in the rain even when exposed to the external environment.

However, the problem of this is that the heat generation was not large by using a conventional fluorescent lamp, but recently, a lamp equipped with an LED chip is used to secure the internal brightness. In this case, a large number of LED chips are used to secure a sufficient light source. If you use it, the heat will be more severe, so there is a problem of deterioration of the luminaire and shortening the life of the lamp.In particular, maintenance of the luminaire due to the problem of replacing the entire lamp if the LED chip is easily damaged during long-term use. Economic loss occurs due to waste of manpower due to cost and replacement work.

In particular, such a luminaire is sealed by a packing in a state in which a cover is placed on the upper part of the casing for waterproofing, which is more difficult in heat dissipation, and the LED lamp is easily affected by environmental changes such as temperature and humidity. As a result, there is a problem that it is difficult to maintain the brightness of the internal space uniformly due to the large gap in luminous efficiency, and therefore, to secure the internal brightness, a large number of luminaires must be installed.

Therefore, the present invention is provided with a heat dissipation means for absorbing the heat emitted from the lamp to prevent the lamp from being heated to a high temperature, the heat absorption is made by the heat conduction to increase the heat dissipation efficiency to increase the life of the lamp and luminaires and deterioration To prevent it.

To this end, the present invention is a luminaire comprising an electric device and a reflector plate is built into the case, the lamp is mounted and the floodlight cover is coupled to the inner space is sealed by the packing, the heat sink is attached to the reflector plate to the heat sink The heat generated from the lamp is directly conducted to the heat sink so that the heat is generated.

In addition, the heat sink is bent in a "c" shape to increase the contact area with the lamp so that the heat sink is in close contact with both sides of the lamp to achieve thermal conduction, the bent end is bent inward again to separate lamp fixing means Without the need for this, the lamp can be simply assembled by the slide-fit method, but the heat sink can perform the heat dissipation function of the lamp and the fixing means of the lamp at the same time without being pulled out of the fixed state.

Therefore, the present invention can efficiently dissipate the heat generated from the lamp to prevent the lamp from being heated to a high temperature to maintain the constant brightness of the lamp, while preventing the lamp from deteriorating function or life, and also the life of the luminaire It is possible to prevent malfunction or damage of the electronic device due to heat generation.

As a result, it is effective to reduce maintenance costs such as lamp replacement or repair of luminaires, and it is possible to secure the brightness of the interior space by preventing the deterioration of the luminaires, thereby improving luminous efficiency despite the use of a small number of luminaires. It is possible to increase the economical use.

1 is an exploded perspective view showing an embodiment of the present invention.
Figure 2 is a perspective view of the combined state of the luminaire of the present invention
3 is a cross-sectional view of the coupling state of the luminaire of the present invention
Figure 3a is a cross-sectional view of the coupling state of the luminaire showing another embodiment of the lamp
Figure 4 is a cross-sectional view of the use state showing the removal structure of the lamp of the present invention
Figure 5 is an exploded perspective view showing a coupling structure of the fixing socket of the present invention
6 is a perspective view showing a lamp mounting structure of a conventional luminaire

Hereinafter, preferred embodiments according to the present invention will be described with reference to the accompanying drawings.

As shown in FIGS. 1 to 3, the present invention is a luminaire in which a lamp 10 and a reflecting plate 20 are built in a case 30 and are kept airtight by a floodlight cover 40, and an inner space 31 is formed. In a state in which an electric device such as a power supply means or a ballast is built in the formed case 30, a reflecting plate 20 and a lamp 10 are mounted on the upper side thereof, and a heat sink 21 made of a plate is mounted on the reflecting plate 20. To be in contact with the lamp 10, and the floodlight cover 40 is assembled to seal the outer circumferential surface of the case 30 by mounting the packing 41, such as dust or water, to the inside of the case 30. It is to prevent foreign substances from entering and to have a waterproof function.

Therefore, the heat generated from the lamp 10 is thermally conducted to the heat sink 21 to dissipate heat into the air inside the case 30, and the heat conducted to the heat sink 21 is also conducted back to the reflector plate 20. While the heat dissipation is made in the entire reflecting plate 20 will be to generate more heat radiation effect.

In this case, the reflective plate 20 and the heat sink 21 is to use a metal material, it is preferable to use a particularly high aluminum aluminum thermal conductivity.

In addition, the heat dissipation plate 21 is bent in a "c" shape, while the support surface 21a is mounted on the upper surface of the reflector plate 20 while the upright surface 21b is bent upwardly to the top of the "c" shape. If the lamp 10 is accommodated in the heat sink 21 while the lamp 10 is in close contact with both the support surface (21a) and the upright surface (21b) while the lamp 10 and the heat sink 21 and the heat sink 21 and By further increasing the contact area of the reflecting plate 20 it is possible to further improve the heat dissipation effect.

And the heat sink 21 is formed at the end of the upright surface (21b) bent inwardly so that the lamp 10 is caught by the engaging portion (21c) is formed without the need for a separate lamp fixing means lamp 10 is a heat sink 21 In this case, the lamp 10 is inserted into the heat sink so that the lamp 10 is inserted into the heat sink 21 by tilting one side of the lamp 10 and inserting the other into the heat sink 21, as shown in FIG. 4. It is to be pushed so as to be horizontal, in that state the connection portion (10a) of the lamp 10 is simply assembled by fitting to the fixing socket 50 formed on one end of the reflecting plate 20 by fitting.

Therefore, when the lamp 10 is inserted into the heat sink 21, it is caught by the catching part 21c so as not to be detached arbitrarily, and when the lamp 10 is removed for replacement, the lamp 10 is pulled and fixed. After removing from the socket 50, the lamp 10 can be tilted and pulled out of the heat sink 21.

Therefore, the lamp 10 can be easily assembled by a slide-fit method, but does not come off arbitrarily in a fixed state, so that the heat sink 21 can simultaneously perform the heat dissipation function of the fixing means of the lamp 10 and the lamp 10. Will be.

In this case, the heat dissipation plate 21 may have a length sufficient to accommodate all the lengths of the lamp 10 to maximize the heat dissipation effect of the lamp 10. In this case, the lamp 10 may not be easily attached or detached. For this reason, the lamp 10 should be exposed at both ends of the heat sink 21.

At this time, if the length of the heat sink 21 is formed to be the same as the length of the lamp 10 and the incision surface 21d is formed so that the end of the lamp 10 is exposed at the end, the lamp 10 and the heat sink ( The contact area of 21 may be increased to maximize the release of heat generated from the lamp 10, while also allowing the lamp 10 to be easily attached and detached while holding a portion exposed by the cut surface 21d.

In addition, as shown in FIG. 3, when the auxiliary heat sink 11 made of plate is attached to the surface of the lamp 10 that contacts the heat sink 21, the heat generated from the lamp 10 is transferred to the auxiliary heat sink 11. After the second heat conduction, the second heat conduction is carried out by the heat sink 21, and the heat is absorbed by the auxiliary heat sink 11 to the maximum by the auxiliary heat sink 11, and then heat is released by itself. Will be able to increase even higher.

In this case, as described above, the auxiliary heat sink 11 preferably uses an aluminum material having high thermal conductivity among metals.

In addition, when the auxiliary heat sink 11 forms a heat dissipation blade 11a protruding in multiple stages on the heat sink 11, as shown in FIG. 3A, heat emitted from the lamp 10 is rubbed with air and more efficiently and quickly. It will be dissipated.

Meanwhile, as shown in FIG. 5, the reflective plate 20 forms a cutout 20a at one side to which the heat sink 21 is attached, and a fixing socket for fixing the lamp 10 to the cutout 20a. By allowing the lower end of the 50 to be embedded, the lamp 10 may be brought into close contact with the reflecting plate 20 and the heat sink 21 as much as possible. The fixing socket 50 may be cut using the mounting bracket 51. Coupling and fixing to the edge of the portion (20a) is to be mounted so that a portion of the lower end of the fixed socket 50 is buried to the lower side of the reflecting plate (20).

Therefore, the space between the lamp 10 and the reflecting plate 20 is minimized, so that the heat sink 21 can be made of a thin plate, and the lamp 10, the reflecting plate 20, and the heat sink 21 It is in close contact with each other to further increase the thermal conductivity.

10: lamp 10a: connection
11: auxiliary heat sink 11a: heat sink
20: reflector 20a: incision
21: heat sink 21a: base
21b: upright surface 21c: locking portion
21d: incision plane
30: case 31: inner space
40: floodlight 41: packing
50: fixed socket 51: mounting bracket

Claims (10)

The lamp 10 and the reflector 20 are embedded in the case 30 having the inner space 31 formed therein, and the case 30 is mounted with a floodlight cover 40 having the packing 41 mounted therein and a floodlight cover 40. In the luminaire to which the outer peripheral surface of the case 30 is sealed to prevent the inflow of foreign substances such as dust and water and to have a waterproof function,
The reflecting plate 20 is bent the plate to form a heat sink 21 to surround the lamp 10 is formed, the heat sink 21 is bent in a "c" shape of the metal plate to the support surface 21a and the upright surface ( 22b), and the upper end portion is bent inwardly so that the upper end portion is bent inwardly so that the lamp 10 is not mounted, and the cutout portion 21d for exposing the end portion of the lamp 10 is exposed. The auxiliary heat sink 11 made of a plate is attached to the outer circumferential surface of the lamp 10 so that the heat sink 11 is in contact with the heat sink 21, and each of the reflecting plate 20 and the heat sink 21 is auxiliary. The heat sink 11 is formed of aluminum, and the reflecting plate 20 has a cutout portion 20a formed at one side to which the heat sink 21 is attached so that the fixing socket 50 for fixing the lamp 10 protrudes upward. While the lower end of the fixing socket 50 is seated on the mounting bracket 51 to the edge of the incision 20a The luminaire having excellent heat dissipation effect, characterized in that the coupling is fixed to be embedded in the lower side of the reflecting plate (20). delete delete delete delete delete delete delete delete delete

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