KR200454488Y1 - Lighting equipment - Google Patents

Abstract

LED module having at least one LED element is coupled to the module coupling portion having a hole formed in the center portion having a frusto-conical shape and a fricto-conical shape; A heat sink assembly comprising a reflection shade body having a reflection surface and a reflection shade body integrally protruding from an outer rear end of the reflection shade body portion around the hole and coupled to another device; An LED module coupled to the reflection shade body; And a lens coupled to an edge portion of the reflection shade body, wherein the heat sink assembly is connected to the front edge portion at the rear end of the reflection shade body and protrudes at a constant interval in the circumferential direction from an outer surface of the reflection shade body. And a plurality of main heat dissipation ribs radially arranged at a rear end of the reflector shade body portion, and disposed outside the front edge of the reflector shade portion with a radius larger than an edge of the reflector shade portion and between the main heat dissipation ribs. Rather than the auxiliary heat dissipation ribs formed at a lower height and the edge of the reflection shade portion with a radius larger than the edge of the reflection shade portion, the heat sink portion having a ring portion connected to the bottom of the main heat dissipation ribs, and the edge portion of the reflection shade body Thus formed, between the ring portion and the main heat dissipation ribs Illumination apparatus, characterized in that the heat sink assembly further comprises a plurality of heat dissipation holes to guide the vertical flow of air to radiate heat generated in the interior of the reflection shade body, penetrating up and down and extending upward Is disclosed.

Lighting, LED, Reflector, Heat Sink, Heat Dissipation, Cooling

Description

Lighting apparatus

The present invention relates to a lighting apparatus, and to a lighting apparatus that can efficiently cool the generated heat together with the role of supporting and reflecting the light that generates heat when driving, such as LED lighting.

In general, various lighting lamps including a head lamp, a rear combination lamp, a street lamp, and a fluorescent lamp of an automobile use a general bulb (BULB) as a light source.

However, bulbs have a short service life and low impact resistance. Recently, bulbs have been widely used as light sources with high intensity LEDs (Light Emitting Diodes) having excellent impact resistance.

In particular, the high-brightness LED, as is well known, can be used as a light source for a variety of lighting, including headlamps and rear combination lamps of automobiles and street lamps and fluorescent lamps, the scope of application is very wide.

Such high-brightness LEDs generate very high heat when they are turned on, and therefore, there are many difficulties in applying and designing them by the exothermic temperature of high heat.

In addition, the LED as described above may have a structure in which the reflector is installed for each individual LED, depending on the size of the lighting device, may have a configuration for installing a plurality of LEDs in one large reflector. Even in such a case, a technical part that can effectively reflect the light of the LED and cool the heat is very important.

The present invention was devised in view of the above, and an object of the present invention is to provide a lighting device having an improved structure to reflect light forward while effectively radiating heat generated from an LED.

The lighting device of the present invention for achieving the above object is a reflection shade body portion having a module coupling portion to which the LED module having one or more LED elements are coupled and has a hole formed in the center and truncated cone shape, the front of the reflection shade body portion It is formed to extend round to the circular arc from the edge and the reflection shade portion having a light reflection surface therein, and the reflection shade body having a coupling protrusion formed integrally projecting to the outer rear end of the reflection shade body portion around the hole and coupled to other devices A heat sink assembly configured; An LED module coupled to the reflection shade body; And a lens coupled to the edge portion of the reflecting shade body.

The heat sink assembly is connected to the front edge portion at the rear end side of the reflection shade body and is formed to protrude at regular intervals in the circumferential direction from the outer surface of the reflection shade body and a plurality of main heat radiation radially arranged at the rear end of the reflection shade body portion A heat sink having ribs and auxiliary heat dissipation ribs disposed outside the front edge of the reflection shade part with a radius larger than an edge of the reflection shade part and formed to be lower than the main heat dissipation ribs between the main heat dissipation ribs; It is formed along the edge portion of the reflector shade body, and is formed to extend upward and downward between the ring portion and the main heat dissipation ribs and to expand upward, so that the air flows up and down to dissipate heat generated inside the reflector shade body. Heat sink assembly further comprises a plurality of heat sinks to guide the Characterized in that.

On the other hand, in the lighting apparatus of the present invention, preferably, the heat sink portion further extends in a tubular shape in the rear end direction from the ring portion, further comprising a cylindrical heat dissipation portion surrounding the outside of the heat sink portion.

On the other hand, in the lighting device of the present invention, preferably, the coupling protrusion may be a lighting device, characterized in that the pin type or socket type.

According to the lighting apparatus of the present invention, since the heat sink is integrally formed in the reflection shade body, it is possible to effectively dissipate heat generated when the LED is driven.

In particular, a heat radiating hole for guiding the flow of air is formed between the edge of the reflecting shade and the heat sink, so that the air is smoothly guided and moved from the bottom to the top of the heat sink, thereby increasing heat dissipation efficiency. Can reduce the life span.

Therefore, maintenance of the lighting apparatus is easy and the management cost can be reduced.

Hereinafter, a lighting apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 to 4 will be described a lighting device 10 according to a first embodiment of the present invention.

The lighting device 10 according to the first embodiment of the present invention, the heat sink assembly 20, the front of the LED module 30 and the heat sink assembly 20 installed inside the heat sink assembly 20. It is characterized in that the lens 40 is coupled to the heat sink portion 23 has a main heat dissipation rib 23a, a ring portion 23b and an auxiliary heat dissipation rib 23c.

The heat sink assembly 20 includes a reflection shade body 21 and a heat sink portion 23.

The reflection shade body 21 has a reflection hole body portion 21a having a passage hole h1 through which a signal cable (not shown), etc., passes and has a roughly truncated cone shape, and at the front edge of the reflection shade body portion 21a. It has a reflection shade portion 21b extending in a round shape, and a coupling projection portion 21c protruding from the rear end outer surface of the reflection shade body portion 21a and communicating with the passage hole h1.

The reflection shade body portion 21a, the reflection shade portion 21b, and the coupling protrusion portion 21c are preferably integrally formed with each other, and may be formed of an aluminum material having good thermal conductivity and lightness. On the inner surface of the reflecting shade body portion 21a, the module coupling portion 21d to which the LED module 30 is mounted and coupled is formed to enter a predetermined depth.

The module coupling portion 21d is connected to the through hole h1.

The reflection shade 21b is formed integrally with the reflection shade body 21a, and is formed to extend in a circular arc shape at the lower edge of the reflection shade body 21a, thereby generating light generated by the LED module 30. The inner circumferential surface of the reflection shade 21b is preferably a reflective surface S1 coated or smoothly surface-treated to effectively reflect light.

The coupling protrusion 21c is a portion for coupling the reflector 20 to a separate device, for example, a vehicle, a building, or other electronic product, and is formed to protrude to the rear of the reflector body 21a. The pin 21e is provided. Therefore, the lighting device 10 can be coupled to a predetermined electronic product or component in a pin type.

The heat sink 23 is connected to the front edge portion from the outer side (rear end) of the reflection shade body portion 21a, and the plurality of main heat dissipation ribs 23a protrude from the outer surface of the reflection shade body 21. And an auxiliary heat dissipation rib 23c formed between the ring part 23b disposed outside the front edge of the reflection shade 21b and the main heat dissipation rib 23a at a radius larger than the edge of the reflection shade 21b. ).

The main heat dissipation ribs 23a are disposed at regular intervals in the circumferential direction from the outside of the reflection shade body portion 21a, and are preferably formed to be radially arranged at the rear end of the reflection shade body portion 21a. In addition, the main heat dissipation ribs 23a are formed to protrude higher from the outer side of the reflector body portion 21a toward the front edge from the rear end of the reflector body portion 21a. The main heat dissipation ribs 23a may be formed of an aluminum material having good thermal conductivity, and more preferably, may be integrally formed with the reflection shade body 21.

The ring part 23b is disposed outside the front edge of the reflector part 21b with a radius larger than the edge of the reflector part 21b and is connected to the lower ends of the main heat dissipation ribs 23a. According to the above configuration, the ring portion 23b and the reflector shade 21b are spaced apart, and a heat dissipation hole h2 is formed between the ring portion 23b and the main heat dissipation ribs 23a. The heat dissipation hole h2 is formed to have a predetermined length to form a predetermined air flow path between the ring portion 23b and the outer surface of the reflector shade 21b, and is formed to extend upward. The ring portion 23b as described above may also be integrally formed of the same material as the main heat dissipation rib 23a.

The auxiliary heat dissipation ribs 23c are formed therebetween to connect the main heat dissipation ribs 23a with each other, and are formed to be connected in a direction crossing the main heat dissipation ribs 23a. In addition, the auxiliary heat dissipation ribs 23c are formed at a lower height than the main heat dissipation ribs 23a, so that air circulated through the heat dissipation holes h2 can be moved along the main heat dissipation ribs 23a. The auxiliary heat dissipation ribs 23c may be formed to be spaced apart by a plurality of stages based on the length direction of the main heat dissipation ribs 23a. As the auxiliary heat dissipation rib 23c is further formed, the heat sink 23 may increase the contact area with air, that is, the heat exchange area, and thus may further increase heat dissipation efficiency. The auxiliary heat dissipation rib 23c may also be formed of the same material as the main heat dissipation rib 23a.

According to the configuration of the heat sink 23, heat generated when the LED module 30 is driven inside the reflection shade body 21 is effectively transferred to the heat sink portion 23 via the reflection shade body 21. In addition, the main heat dissipation ribs 23a, the auxiliary heat dissipation ribs 23c, and the ring part 23b of the heat sink 23 dissipate heat through heat exchange with air. In addition, the outside air is smoothly circulated to the inside of the heat sink 23 through the heat dissipation hole h2, so that the air cooling effect through the heat sink 23 can be further improved, thereby increasing heat dissipation efficiency. There is an advantage, by effectively cooling the heat generated in the lighting that generates a high heat when driving, such as high-brightness LED, it is possible to increase the life of the heat generating unit, that is, the LED module 30 and increase the efficiency.

Meanwhile, in the first embodiment, the LED module 30 includes a substrate 31 and an LED device 32 coupled to the substrate 31. The substrate 31 is seated and coupled to the module coupling part 21d. The LED element 32 is installed on the substrate 31, and is driven by a power source applied through a signal cable (electric cable) connected to the substrate 31 to emit light, and simultaneously generate heat.

On the other hand, in the first embodiment has been described as an example that there is one LED device 32, this is only an example, it may have a configuration in which a plurality of LED devices are installed on one substrate. In addition, a plurality of substrates and LED elements may be installed in a modular state.

On the other hand, in the first embodiment, the lens 40 is seated and coupled inside the front edge of the reflector body 20. The lens 40 protects the LED module 30 and serves to guide the light. A lens seating portion 21e on which the lens 40 is seated is formed at an inner portion of the edge of the reflection shade 21b.

On the other hand, the subject innovation provides a second embodiment, as shown in Figure 5, according to the lighting device 10 ', the protrusion coupling portion (21c') of the reflection shade body portion 21 is coupled in the form of a socket It has a configuration that can be done. Therefore, a screw line is formed on the outer circumference of the protrusion coupling portion 21c '.

On the other hand, the subject innovation provides a third embodiment, as shown in Figure 6, according to the illumination device 100, in the structure of Figures 1 to 5, the heat sink 23 is formed in a tubular shape It is characterized by further including the cylindrical heat dissipation unit 23e.

In the structure of FIGS. 1-5 of the said cylindrical heat radiation part 23e, it is integrally formed with the ring part 23b, and has a structure extended cylindrically back from the ring part 23b. In addition, the cylindrical heat dissipation part 23e is formed at a height corresponding to the height of the reflector body portion 21. By further providing the cylindrical heat dissipation unit 23e, not only the contact area with air can be increased, but also the air flow is guided up and down in a straight line so that the air flows quickly, thereby increasing heat exchange efficiency. .

As described above, since the lighting apparatuses according to the first to third embodiments of the present invention have a structure in which the heat sink is integrally formed with the reflector, the heat generated from the LED module can be cooled more effectively. In addition, it is possible to cool the temperature of the lighting device so as not to rise above 60 ° C. By properly controlling the temperature of the lighting device, the luminous intensity of the LED can be prevented from being lowered, and ultimately, the life of the LED can be extended. .

FIG. 7 illustrates the luminescence and lifespan of LEDs according to temperature. As can be seen through the graph shown in FIG. 7, when the light output rate of the LED is reduced by 30%, the temperature is 60 ° C. or less. Even if it is controlled only, it can be seen that the service life can be extended by 2 times or more than the driving temperature of 100 ℃ or more.

Therefore, in the LED lighting, lowering the light emission temperature is a very important consideration. According to the present invention, the light emission temperature can be effectively lowered, and the life of the LED light can be extended.

On the other hand, in the case of the lighting apparatus according to the first to the third embodiment, it has been described with an example that the reflection shade body and the heat sink unit is formed as an example, this is merely illustrative. That is, as in the fourth embodiment illustrated in FIG. 8, the heat sink assembly 200 may have a configuration in which the reflection shade body 210 and the heat sink 220 are provided as separate components and coupled to each other. In this case, the heat sink 220 may have a configuration similar to that of the heat sink assemblies of the first to third embodiments, the LED module 230 is installed inside, and inside the end of the reflector body 210. The lens 240 is fitted and coupled. Even in the case of the lighting device having such a configuration, the circulation and circulation of air can be made smooth by the configuration and shape of the heat sink 220, and the cooling efficiency can be increased through the smooth circulation of the air. As described above, it should be understood that the reflection shade body and the heat sink portion of the present invention may be integrally formed with each other, or may be made of separate components and detachably coupled to each other. In the case of FIG. 8, the coupling part of the LED module 230 may include a coupling support part 211 formed at the center of the reflection shade body 210, and the LED module 230 may be disposed between the heat sink 220 and the reflection shade body 210. May be formed.

As described above, the configuration of the present invention has been described with reference to embodiments, but this is merely an embodiment of the present invention, and the scope of the present invention includes variations of the technical idea equivalent thereto.

1 is a perspective view showing a lighting apparatus according to a first embodiment of the present invention.

2 is a rear view of the lighting apparatus shown in FIG.

3 is a side view of the lighting apparatus shown in FIG.

4 is a cross-sectional view of the lighting apparatus shown in FIG.

5 is a view showing a lighting apparatus according to a second embodiment of the present invention.

6 is a view showing a lighting apparatus according to a third embodiment of the present invention.

7 is a graph showing the life relationship according to the temperature of the LED light through the experiment.

Figure 8 is a short side view showing a lighting apparatus according to a fourth embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

10,10 ', 200 .. Lighting device 20 .. Reflective shade

21 .. Reflective shade body 23, 23 '.. Heat sink

30.LED module 40.Lens

Claims (3)

LED module having at least one LED element is coupled to the module coupling portion having a hole formed in the center portion having a frusto-conical shape and a fricto-conical shape; A heat sink assembly comprising a reflection shade body having a reflection surface and a reflection shade body integrally protruding from an outer rear end of the reflection shade body portion around the hole and coupled to another device; An LED module coupled to the reflection shade body; And, Including; lens coupled to the edge of the reflecting shade body, The heat sink assembly, A plurality of main heat dissipation ribs connected to the front edge portion at the rear end of the reflection shade body and protruding at regular intervals in the circumferential direction from the outer surface of the reflection shade body and arranged radially at the rear end of the reflection shade body portion; The outer edge of the reflector shade is disposed outside the front edge of the reflector shade with a radius larger than the edge of the reflector portion, and the radius of the reflector shade is greater than that of the auxiliary heat dissipation ribs formed between the main heat dissipation ribs and having a lower height than the main heat dissipation ribs. A heat sink portion disposed at and having a ring portion connected to a lower end of the main heat dissipation ribs; It is formed along the edge of the reflecting shade body, and is formed to extend between the ring portion and the main heat dissipation ribs up and down to expand upward, so as to radiate heat generated in the interior of the reflecting shade body up and down And a heat sink assembly further comprising a plurality of heat dissipation holes for guiding the flow. The method of claim 1, wherein the heat sink portion, And a tubular heat dissipation unit extending in a tubular shape from the ring portion in the rear end direction and surrounding the outer side of the heat sink portion. The method of claim 1, wherein the coupling protrusion, Lighting device, characterized in that the pin type or socket type.

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