KR20130123574A - Led street-lamp having a multi layer radiant heat structure - Google Patents

Abstract

The present invention is to provide an LED street-lamp having a multi layer radiant heat structure that includes a multi layer radiant heat unit opening in all directions; an LED module for mounting LEDs and symmetrically inclined with a predetermined angle, a side cover unit with an external air inlet for receiving an external air from an opening part, and combined with both sides of the radiant heat unit; and a transparent cover unit installed in the lower end of the radiant heat unit to cover the LED module.

Description

LED street light with multilayer heat dissipation structure {LED STREET-LAMP HAVING A MULTI LAYER RADIANT HEAT STRUCTURE}

The present invention relates to an LED street light having a multi-layer heat dissipation structure, and more particularly, to a multi-layer heat dissipation structure having an internal heat dissipation unit that can be distributed to the outside air to increase heat dissipation efficiency and effectively prevent foreign matter from being deposited. It relates to an LED street light having.

In general, street lamps (park lights, security lights) are lighting facilities installed along the road for the safety and security of road traffic, and are usually installed upright on the road, and are installed at a certain height on the support post. It is configured to include, the interior of the lamp is provided with a light is made of illumination of the road by the light emission of the light.

In the meantime, mercury lamps, fluorescent lamps, and sodium lamps are mainly used, which requires high power consumption, resulting in heat generation problems and product life time. Therefore, in recent years, streetlights using LEDs (Light Emitting Diodes), which can obtain high illumination while having low power consumption, are increasing.

Such a conventional technology using an LED includes an LED light emitting lamp disclosed in Korean Patent Publication No. 0767738.

LED lighting lamp according to the prior art is a case, an aluminum substrate in which a plurality of LEDs are mounted in the case, a plurality of refrigerant plates, heat pipes, heat sinks, etc. mounted on the aluminum substrate to dissipate heat generated by the light emission of the LED This structure is provided.

However, these LEDs have the highest illuminance at the center of the light emitted from the LED, and the illuminance is low from the center to the edge. The conventional LED has a structure in which a plurality of LEDs are arranged on the substrate of the flat plate. There was a problem of low illumination of the affected survey area. That is, the light irradiated from the LED arranged at the edge of the substrate by the LED's irradiation angle is lost outside the irradiation area.

In addition, there is a risk of a safety accident if lost light outside the survey area shines on the eyes of pedestrians or drivers. After all, LED is also important to illuminance, but in order to prevent a safety accident, it is particularly important to prevent the emitted light from leaving a range of irradiation area.

In addition, a significantly high heat is generated when the LED emits light. In order to solve this problem, a refrigerant plate, a heater pipe, and a heat sink are conventionally provided, which results in a complexity of the structure. Therefore, there is a continuous demand for a heat dissipation structure that can be supplied at a simpler and lower cost.

An object of the present invention is to provide an LED street light having a multi-layer heat dissipation structure that can increase the heat dissipation efficiency by having an internal heat dissipation unit that can be distributed to the outside air.

Another object of the present invention is to provide an LED street light having a multi-layer heat dissipation structure capable of effectively preventing foreign matter from being deposited from the outside by providing a heat dissipation unit inside the main body.

In a preferred aspect, the present invention provides a heat dissipation unit that is open in all directions and is formed in a multilayer structure; An LED module installed at a lower end of the heat dissipation unit, symmetric with each other, inclined upward at an angle, and mounted with a plurality of LEDs at a lower end thereof; A side cover unit which is fastened to both ends of the heat dissipation unit and has an outside air inlet for introducing outside air into the opening; And a transparent cover unit installed at a lower end of the heat dissipation unit to cover the LED module.

The heat dissipation unit is disposed between the upper heat dissipation plate, a lower heat dissipation plate disposed under the upper heat dissipation plate, a heat dissipation fin formed at an upper end thereof, and a lower heat dissipation plate having the LED module installed at a lower end, and the upper heat dissipation plate and the lower heat dissipation plate. It is preferable to include a support for fixing the upper heat sink and the lower heat sink.

The support is disposed along a center boundary line between the upper heat sink and the lower heat sink, and the upper heat sink is a flat plate fixedly supported on an upper end of the support, and a pair extending inclined downward from both sides of the flat plate. Is provided with an upper inclined plate, the lower heat sink is fixed to the lower end of the support and the LED mounting plate is formed to be inclined at a predetermined angle upward on both sides of the center boundary line, and the inclined angle downward from both sides of the inclined plate It is preferable to have a pair of lower inclined plates extending to reach a predetermined gap with each of the upper inclined plates.

The heat dissipation fins may be installed at both ends of the LED mounting plate at the upper end of the supporter, and the LED module may be installed at both lower ends of the LED mounting plate at the lower end of the supporter.

The LED module is preferably slidingly coupled to the sliding groove formed at the bottom of both sides of the LED mounting plate.

Both sides of the LED mounting plate bordering the support is preferably formed to form an inclination of 10 degrees to 15 degrees with respect to the reference line perpendicular to the lower end of the support.

Compression bars are respectively disposed at the ends of the lower inclined plates, and both side portions of the cover unit are disposed between the ends of the lower inclined plates and the compression bars, and the ends of the lower inclined plates and the compression bars are bolted to each other and compressed. It is preferably fixed, but the silicon member is interposed between the end of each lower inclined plate and the pressing bar.

Each of the side cover units is provided at both ends of the heat dissipation unit, and is provided with a plurality of external air distribution holes for fitting and fixing both ends of the cover unit and allowing outside air to flow between the upper heat dissipation plate and the lower heat dissipation plate. It is preferable.

It is preferable that any one of the side cover units is installed to protrude a connector connected to an external power source to supply power to the LED module.

The present invention has the effect of increasing the heat dissipation efficiency by having an internal heat dissipation unit that can be distributed to the outside air.

In addition, the present invention has an effect that can be effectively prevented from depositing foreign matter from the outside by providing the heat dissipation unit inside the main body.

In addition, the present invention has an effect that can increase the waterproof efficiency by installing the LED module at the lower end of the lower heat dissipation unit, and airtight using the cover unit.

In addition, the present invention consists of two LED modules, and configured to follow the direction of the beam angle to each other, has the effect of spreading the angle of the beam to the outside of the cover unit.

In addition, the present invention has the effect that by configuring the connector for supplying external power to the side cover unit, the electric wire is safely waterproofed and protected from the external environment. In addition, the present invention has an effect that can be easily installed and replaced by slidingly fixing the LED module to the lower end of the lower heat sink.

1 is a combined perspective view showing the LED landscape of the present invention.
Figure 2 is another combined view showing the LED landscape of the present invention.
3 is an exploded perspective view showing the LED landscape of the present invention.
4 is a cross-sectional view taken along the line II ′ of FIG. 3.
5 is a perspective view showing a heat dissipation unit according to the present invention.
6 is a perspective view showing a side cover unit according to the present invention.
7 is a perspective view showing a pressing bar according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described the configuration and operation of the LED street light having a multi-layer heat dissipation structure of the present invention.

1 and 2 is a combined view showing the LED street light having a multi-layer heat dissipation structure of the present invention, Figure 3 is an exploded view showing the LED streets of the present invention.

1 to 3, an LED street light having a multi-layer heat dissipation structure according to the present invention includes a heat dissipation unit 100, an LED module 200, a side cover unit 300, and a cover unit 400. do.

The heat dissipation unit 100 is preferably formed of an aluminum material, the four sides are opened, it is formed of a multi-layer structure.

More specifically, the heat dissipation unit 100, the support 130 for fixing the upper heat sink 110, the lower heat sink 120 and the upper and lower heat sinks 110 and 120 to form a layer having a predetermined height difference. It is composed of

The upper heat sink 110 is composed of a flat plate 111 having a predetermined width and length, and a pair of upper inclined plate 112 extending at a predetermined width from both sides of the flat plate 111.

Each upper inclined plate 112 is inclined at a predetermined angle along the lower side at both sides of the flat plate (111). Here, each of the upper inclination plate 112 may form an inclination angle symmetric with each other.

The lower heat sink 120 is disposed below the upper heat sink 110.

The lower heat sink 120 includes an LED mounting plate 121 and a pair of lower inclined plates 122 which are inclined downward by a predetermined angle from both sides of the LED mounting plate 121 downward.

Here, the support 130 is fixed to the flat plate 111 and the LED mounting plate 121 to each other.

Preferably, the upper end of the support 130 is fixed to the lower end of the flat plate 111 along the center boundary line (c) of the flat plate 111, the lower end of the support 130 is the center boundary line of the LED mounting plate 121 It is fixed to the upper end of the LED mounting plate 121 along (c).

Here, the support 130 serves as a wall forming a predetermined thickness, length and height.

Therefore, the upper heat sink 110 and the lower heat sink 120 are configured to form a layer to each other at a predetermined height.

In addition, the upper sides of the upper and lower heat sinks 110 and 120 are opened to flow with the outside.

In addition, the LED mounting plate 121 is composed of two, it is formed to be inclined upward by a predetermined angle along both sides with respect to the center boundary line (c).

Preferably, the LED mounting plate 121 forms an inclination of 10 degrees to 15 degrees with respect to the reference line perpendicular to the support 130.

Heat dissipation fins 123 are formed at an upper end of the LED installation plate 121 formed at both sides of the support 130 disposed along the center boundary line c. The heat dissipation fins 123 are composed of fins to increase the contact area with air.

Then, the LED module 200 is installed at the lower end of the LED mounting plate 121 formed on both sides of the support 130 disposed along the center boundary line (c). The LED module 200 is composed of a PC 210 and a plurality of LEDs 220 mounted on the bottom of the PC 210.

Sliding grooves 121a are formed at the lower ends of the LED mounting plates 121.

The LED module 200 is coupled to the sliding groove 121a is formed in each of the LED mounting plate 121 is coupled. The LED module 200 is installed at the lower end of each LED mounting plate 121 is composed of two.

Therefore, the irradiation angle of the LED beam from the LED module 200 forms a beam irradiation angle within the 10 degrees to 15 degrees, and is irradiated so as to be spread downward along the support 130.

In addition, the pair of lower inclined plates 122 formed at both side portions of the LED mounting plate 121 are inclined downward to form a predetermined gap with the upper inclined plate 112.

A transparent cover unit 400 is coupled to the end of the pair of lower inclined plates 122.

The transparent cover unit 400 may be formed of a plastic material, and a predetermined pattern may be formed to diffuse the LED beam to the outside.

The cover unit 400 is formed in a plate shape, both sides thereof are disposed at the ends of the pair of lower inclined plates 122.

In addition, the pressing bar 500 is closely disposed on both sides of the cover unit 400.

Ends of the pair of lower inclined plates 122, both side portions of the cover unit 400 and the pressing bar 500 are coupled to each other by the coupling of the bolt (B).

Here, the silicon member 410 for airtightness is interposed between the ends of each lower inclined plate 122 and both sides of the cover unit 400. Therefore, the space in which the LED module 200 is installed by the silicon member 410 may be easily waterproofed.

On the other hand, the side cover unit 300 according to the present invention is composed of two, is coupled to both ends of the heat dissipation unit (100).

Each of the side cover units 300 is installed at both ends of the heat dissipation unit 100, and fixes both ends of the cover unit 400.

In addition, each side cover unit 300 is formed with a plurality of outside air distribution holes 310 for distributing outside air between the upper heat sink 110 and the lower heat sink 120.

Outside air may be easily introduced between the upper and lower heat sinks 110 and 120 where the heat dissipation fins 123 are formed through the outside air flow holes 310.

In addition, since both sides of the upper and lower heat sinks 110 and 120 form an open shape at all times, when the outside air flows into the heat radiation fin 123 and heat radiation is generated from the inside, it serves to discharge it to the outside.

In addition, any one of the side cover units 300, the connector 600 is connected to the external power source to supply power to the LED module 200 is installed so as to protrude.

Next, the operation of the LED street light having a multilayer heat dissipation structure having the above configuration will be described.

1 to 3, the upper heat sink 110 of the heat dissipation unit 100 according to the present invention is formed to be inclined downward along both sides at the center boundary line (c). Therefore, the foreign matter in the upper part can be easily dropped downward.

In addition, the heat dissipation unit 100 is formed to open in all directions. In other words, both ends of the heat dissipation unit 100 may be introduced into and discharged from the inside of the heat dissipation unit 100 through openings, and both ends of the heat dissipation unit 100 may be formed through the outside air flow holes 310 formed in the side cover unit 300. Furnace inflow and outflow is possible. Therefore, the present invention forms an internal and external heat dissipation structure.

In addition, the heat dissipation fins 123 are formed inside the heat dissipation unit 100, that is, the upper end of the lower heat dissipation plate 120. Therefore, since the outside air easily flows into the heat radiation fin 123 itself, the heat radiation efficiency can be increased.

Since the heat dissipation fins 123 are installed inside the heat dissipation unit 100, it is possible to easily solve the phenomenon in which external foreign matters accumulate or accumulate, and thereby, the heat dissipation efficiency may be easily prevented.

As shown in FIG. 3, the LED module 200 has a structure in which the LED module 200 is inclined upward so as to be symmetrical with respect to the bottom of the support.

Therefore, the LED beams irradiated from each of the LED modules 200 may be irradiated at an angle spreading along each other downward.

And, since each LED module 200 is slidingly coupled to the lower end of the LED mounting plate 121, it can be easy to work during installation and replacement assembly.

In addition, a cover unit 400 formed of plastic is installed at a lower end of the lower heat sink 120.

Both sides of the cover unit 400 are tightly coupled to the lower ends of both sides of the lower heat sink 120 in a state of being pressed by the pressing bar 500.

And both ends of the cover unit 400 is fixed to the lower end of each side cover unit 300.

In addition, since the silicon member 410 is further positioned at both ends of the cover unit 400, the airtightness can be easily maintained during the coupling as described above.

Therefore, the space in which the LED module 200 is installed can maintain waterproofness, and inflow of foreign matters can be prevented.

According to the present invention, the LED module 200 is slidingly coupled to the heat dissipation unit 100 of the multilayer structure as described above, the side cover unit 300 is coupled to both ends thereof, and the cover unit 400 is compressed to the lower end of the bar ( 500) and the bolt (B) by using, to minimize the number of parts to ensure ease of assembly, thereby having the advantage of lowering the product price.

In addition, double heat dissipation can be performed by configuring the heat dissipation unit 100 of the multi-layer structure on the upper and lower ends of the support 130.

On the other hand, to any one of the side cover unit 300, by connecting the connector 600 connected to the external power source to supply power to the LED module 200, it is possible to facilitate the external power connection. .

That is, the street lamp of the present invention has an advantage that can easily be combined with street lamps.

In addition, by using the MCPCB in the PCB in the LED module 200, the thermal damage of the module itself can be minimized, and the cover unit 400 can be configured as a transparent PC to improve the light efficiency of the LED beam.

100: heat dissipation unit 110: upper heat sink
120: lower heat dissipation 130: support
200: LED module 300: side cover unit
310: outside air distribution hall 400: cover unit
500: crimping part 600: connector

Claims (9)

A heat dissipation unit having four sides opening and formed in a multilayer structure;
An LED module installed at a lower end of the heat dissipation unit, symmetric with each other to be inclined upward at an angle, and mounted with a plurality of LEDs at a lower end thereof;
A side cover unit which is fastened to both ends of the heat dissipation unit and has an outside air inlet for introducing outside air into the opening; And
LED street light having a multi-layer heat dissipation structure, characterized in that it comprises a transparent cover unit installed on the bottom of the heat dissipation unit to cover the LED module. The method of claim 1,
The heat dissipation unit,
Top heatsink,
A lower heat sink disposed at a lower portion of the upper heat sink and having heat dissipation fins formed at an upper end thereof, and at which a bottom of the LED module is installed;
The LED street light having a multi-layer heat dissipation structure is disposed between the upper heat sink and the lower heat sink, characterized in that it comprises a support for fixing the upper heat sink and the lower heat sink. The method of claim 2,
The support is disposed along the center boundary of the upper heat sink and the lower heat sink,
The upper heat sink is provided with a flat plate fixedly supported on the upper end of the support, and a pair of upper inclined plate extending inclined at a predetermined angle downward from both sides of the flat plate,
The lower heat sink is fixed to the lower end of the support, the LED mounting plate is formed to be inclined at a predetermined angle upwards on both sides of the center boundary line, and inclined downward from both sides of the inclined plate by a predetermined angle and constant with each of the upper inclined plates LED street light having a multi-layer heat dissipation structure, characterized in that it comprises a pair of lower inclined plate extending to reach the gap of. The method of claim 3,
The heat-
It is installed at the upper end on both sides of the LED mounting plate bordering the support,
The LED module includes:
LED street light having a multi-layer heat dissipation structure, characterized in that it is installed at the lower end on both sides of the LED mounting plate bordering the support. The method of claim 4, wherein
The LED module includes:
LED street light having a multi-layer heat dissipation structure characterized in that the sliding coupling is formed in the sliding groove formed at the bottom of both sides of the LED mounting plate. 5. The method of claim 4,
Both sides of the LED mounting plate bordering the support,
LED street light having a multi-layer heat dissipation structure, characterized in that formed to form a slope of 10 degrees to 15 degrees with respect to the reference line perpendicular to the bottom of the support. 5. The method of claim 4,
Compression bars are disposed at ends of the lower inclined plates, respectively.
Both side portions of the cover unit are disposed between the ends of the lower inclined plate and the pressing bar, and the end of each lower inclined plate and the pressing bar are bolted to each other and fixed fixedly,
LED street light having a multi-layer heat dissipation structure, characterized in that the silicon member is interposed between the end of each lower inclined plate and the pressing bar. 8. The method of claim 7,
Each side cover unit,
It is installed at both ends of the heat dissipation unit, and fixed to both ends of the cover unit,
LED street light having a multi-layer heat dissipation structure characterized in that it comprises a plurality of outside air distribution holes that can distribute the outside air between the upper heat sink and the lower heat sink. The method of claim 8,
In any one of the side cover units,
LED street light having a multi-layer heat dissipation structure, characterized in that the connector is connected to the external power source to supply power to the LED module.

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