KR20170037246A - Marine lantern using modular LED lighting - Google Patents

Abstract

The present invention relates to a prefabricated marine lantern using an LED light source, which is composed of an LED block configured by arranging a lens on the upper side of an LED substrate and combining a heat sink with the lower side of the LED board, and a platform which supplies power to the LED board of the LED block. A required number of LED blocks are slidably combined to the upper side of the platform along a height direction sequentially. The LED blocks are simply assembled by selecting the required amount and kind of the LED blocks. Accordingly, the light intensity and light color required in the marine lantern can be easily adjusted.

Description

 {Marine lantern using modular LED lighting}

The present invention relates to a prefabricated light fixture using an LED light source, and more particularly, to an LED light fixture for mounting a LED block including an LED substrate and a heat sink on a required number of platforms in a sliding manner so as to easily match the required light quantity and light color. The present invention relates to a prefabricated marine lighting apparatus using an LED light source.

Generally used marine lanterns generate high luminosity, and when a day is overcast or fogged, or at night, the ship will see the light from the lanterns and mark the route so that safe operation and return to port It is used as an induction light to induce.

These marine lanterns use LEDs with superior distinguishability by allowing light to be emitted with a high luminous intensity to a long distance with low power consumption and low power consumption in recent years. It is being replaced. At this time, the structure of the marine luminaires is a structure in which the upper reflector is folded by the hinge means in the lower reflector so as to be excellent in installation and maintenance, and a plurality of LEDs are integrally arranged tightly on the circular substrate And the light generated from the light emitting module body is transmitted through the lens to generate light in all directions.

However, there is a problem that LEDs installed at closely spaced LEDs are damaged due to heat generated by itself and high heat generated from other surrounding LEDs, so that when the LEDs are replaced, not only the broken LEDs but also LEDs There is a problem in that it is inconvenient to replace the entire light emitting module and the cost of replacement increases accordingly.

In order to solve the problems described above, Patent Document 2 of the prior art document discloses that when a high-brightness LED module is independently installed in a small amount, heat generated by the LED module is dissipated, A light emitting module body is formed by mounting a plurality of heat dissipation units mounted with one independently formed LED module on the plate at regular intervals while coupling the LED module mounted with the substrate to the front side of the heat dissipation unit by tightening means, A light emitting module is disclosed in which an LED module for an indicator LED can be easily replaced with a body mounted on a frame on which a lens is mounted.

However, in the LED module of the conventional marine lifetime which has been replaced as described above, a limited number of LED modules are screwed to each plate for stacking the layers, which is inconvenient for assembly. In the conventional marine lifetime LED, It focuses on replacing and repairing already installed LED module rather than adjusting the number of modules. It is structured so that it does not have to be related to the installation by adjusting the light quantity and color of LED properly. In addition, the conventional method of manufacturing an LED module for a marine luminaires is manufactured by a conventional method, and thus there is a problem that the advantages of the LED light source can not be taken advantage of.

The feature of this design is to modularize the LED light source, LED driver, light source platform, platform housing, etc. constituting the illuminator, and to implement the resolution light source by assembling necessary quantity and type.

Korean Patent No. 10-1175860 Korean Patent No. 10-1175861

SUMMARY OF THE INVENTION The present invention has been conceived in order to solve all of the above problems, and it is an object of the present invention to solve the above-mentioned problems by providing a plurality of LED blocks including an LED substrate and a heat sink, And an LED light source that can easily and quickly install and assemble a desired number of LED blocks according to light quantity and light color.

Another object of the present invention is to provide a prefabricated marine light changer using an LED light source in which replacement or partial replacement of the LED block slidably coupled when the LED block fails can be carried out very easily.

In order to achieve the above-mentioned object, the prefabricated marine luminaires using the LED light source of the present invention comprises an LED block having a lens arranged on an upper part of the LED substrate and a heat sink coupled to the lower part, And a platform in which the LED blocks are sequentially and slidably coupled along the height direction by a necessary number of times on the upper surface.

In addition, it is preferable that an LED is mounted on a hole formed in a central portion of the LED substrate, and power is supplied to the LED through a constant voltage circuit provided on the LED substrate.

It is preferable that the heat sink is screwed to the LED substrate through a screw attached to the center of the LED substrate.

In addition, it is preferable that a lens fixing pin formed on both sides of the lens is inserted into a hole formed on both sides of the heat sink, and the lens is coupled to the heat sink together with the LED substrate.

Preferably, the LED block and the platform are slidably coupled to each other by a slide rail formed on the LED block and a guide rail provided on the platform and having a rail groove into which the slide rail is inserted.

Preferably, the platform is formed in a polygonal shape, and a rail connector is provided for each polygonal corner on the upper surface, and guide rails are connected to the rail connectors.

It is also preferable that slide rails formed on both sides of the LED substrate are inserted into the rail grooves formed on the respective surfaces of the opposing guide rails between the edges of the platform and the slide rails.

Further, the rail grooves of the guide rails are formed by the substrate rail grooves to which the LED substrates are connected and the heat-radiating rail grooves to which the heat sinks are connected. The slide rails and the heat sinks It is preferable to insert the rail and slide-coupled.

And a constant voltage circuit embedded in the platform to supply power to the LED substrate through the substrate rail groove electrically connected to the rail connector.

It is preferable that the constant-voltage circuit is connected to the +, - circuit alternately with the connector two by two.

According to the prefabricated marine lighting apparatus using the LED light source of the present invention, the required amount and type of LED blocks can be selected and assembled easily. Thus, it is possible to easily match the light quantity and the light color required in the marine luminaires .

In addition, since the LED block is easily replaced with a malfunction, the reliability of the marine vessel can be enhanced. In addition, the maintenance cost of the marine vessel can be reduced due to partial replacement of the malfunction.

1 is a perspective view of a prefabricated marine light changer using an LED light source according to the present invention;
2 is a front view and a side view of an LED block lens of a prefabricated marine light changer using an LED light source according to the present invention
FIG. 3 is a front view of an LED substrate of a prefabricated marine luminaires using an LED light source according to the present invention before the LED is mounted, a front view after the LED is mounted, and a side view of the LED substrate
4 is a front view and a side view of a heat sink of a prefabricated marine light changer using an LED light source according to the present invention
5 is a view showing an energy generation direction of the LED
6 is a cross-sectional view of a LED of a prefabricated marine light source using an LED light source according to the present invention, an LED board and a heat sink combined with each other
7 is a side view, a perspective view, and a cut-away perspective view of the LED substrate fixed to the heat sink through the thermal conductive screw for the LED substrate;
8 is a view showing the result of analysis of the temperature distribution when fixing the LED substrate to the heat sink through the thermally conductive screw
9 is a side view and a perspective view showing an LED substrate fixed to a heat sink with an adhesive;
10 is a view showing a result of analysis of the temperature distribution when fixing the LED substrate to the heat sink through the heat conductive adhesive
11 is a top view of the platform to which the LED block is coupled
12 is a perspective view of a portion of the platform to which the LED block is coupled,

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a prefabricated living room lighting apparatus using an LED light source according to the present invention will be described in detail with reference to the accompanying drawings. It is to be understood that the present invention is not limited to the disclosed embodiments, but may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to inform.

FIG. 1 is a perspective view of a prefabricated light fixture using an LED light source according to the present invention.

As shown in FIG. 1, a prefabricated light fixture using an LED light source according to the present invention includes a plurality of LED blocks 3 selectively installed on a guide rail 2 on a platform 1, The slide rail formed on the LED block 3 is inserted into the rail groove formed on the surface of the guide rail 2 facing each other between the guide rails 2 vertically erected on the platform 1, A plurality of block 0 (3) are provided along the circumference and height direction of the platform 1. An upper cover 19 is covered on the upper part of the platform 1 after the LED blocks 3 are installed.

The LED block 3 is composed of the lens 4, the LED substrate 5, and the heat dissipating plate 6, and a specific configuration thereof will be described in the following order.

2 is a front view and a side view of an LED block lens of a prefabricated marine light changer using an LED light source according to the present invention.

As shown in FIG. 2, the lens 4 is one of the components of the LED block 3, and functions to cover and protect the upper portion of the LED substrate 5 while passing light therethrough. On both sides of the lower end of the lens 4, a lens fixing pin 4a for fitting and fixing to a heat dissipating plate described later is protruded.

FIG. 3 is a front view of an LED substrate of a prefabricated marine luminaires using an LED light source according to the present invention before mounting the LED, a front view after the LED is mounted, and a side view of the LED substrate.

3, the LED substrate 5 made of epoxy is also one of the components of the LED block 3. The LED substrate 5, on which the lens 4 is covered as described above, And a PCB circuit pattern 8 is formed on both sides, and the components of the constant-voltage constant-current circuit 9 are inserted into the holes 7. The LED 5a is mounted at the hole 7 in the central portion of the LED substrate 5 and the LED 5a is connected to the positive and negative electrodes of the PCB circuit pattern 8. The positive electrode is connected to the positive And is connected to the LED 5a through the circuit 9. On the bottom surface of the hole 7 of the LED substrate 5, a thermally conductive screw 10 having a good thermal conductivity for fixing and fixing a heat sink 6 to be described later is attached.

4 is a front view and a side view of a heat sink of a prefabricated light bulb using an LED light source according to the present invention.

4, the heat sink 6 is also one of the components of the LED block 3. The heat sink 6 is composed of a heat dissipation body 6a and a plurality of heat dissipation fins 6b connected to the lower end And a lens fixing hole 11 into which the lens fixing pin 4a of the lens 4 is inserted are formed on both sides of the upper surface of the heat dissipating main body 6a and a thermally conductive screw 10 are inserted and screwed to form a conductive screw hole 12. On both sides of the heat dissipating main body 6a, slide rails 13a for slidingly engaging with the guide rails 2 of a platform 1 described later are respectively protruded.

As described above, the reason why the heat conductive screw 10 having such good thermal conductivity is attached to the lower surface of the LED substrate 5 and screwed to the heat dissipating fin 6 is as follows. Generally, the LED 5a The LED 5a is mounted on the screw 10 so that the heat generated from the LED 5a is directly transmitted to the heat dissipation fin 6b of the heat dissipating plate 6 And the LED substrate 5 can be screwed to the heat sink 6 by the heat conductive screw 10 so as to be conveniently mounted.

6 is a cross-sectional view of a LED of a prefabricated light bulb using an LED light source according to the present invention, an LED substrate and a heat sink combined with each other.

6, the heat conductive screw 10 once attached to the LED substrate 5 is inserted into the conductive screw hole 12 of the heat sink 6 and screwed thereto so that the LED substrate 5 and the heat sink 6 And the lens fixing pin 4a formed on the lens 4 is fixed to the lens fixing portion 4b formed on the heat sink 6 while covering the lens 4 above the LED substrate 5 coupled with the heat sink 6. [ And the LED block 3 is completed by inserting it into the hole 11 and fixing it. At this time, both sides of the LED substrate 5 in the longitudinal direction are protruded by the length of the slide rail 13a protruding from both sides of the heat dissipating plate 6, so that the protruded portion is used as another slide rail 13b.

The following is a comparison between the performance of the heat conductive screw and the adhesive for bonding the LED substrate and the heat sink in the LED block of the present invention.

7 is a side view, a perspective view and a cut-away perspective view of the LED substrate fixed to the heat sink through the thermal conductive screw for the LED substrate, and FIG. 8 is a view showing a result of the temperature distribution analysis when the LED substrate is fixed to the heat sink through the heat conductive screw.

As shown in Fig. 7, when the LED substrate 5 with the LED 5a mounted thereon and the heat sink 6 are screwed to each other through the heat conductive screw 10, as shown in Fig. 8, The analysis of the temperature distribution of the heat exchanger 6 clearly shows that the temperature is evenly distributed. That is, the temperature difference is not large at any position of the heat sink 6. [

FIG. 9 is a side view and a perspective view of fixing the LED substrate to the heat sink with an adhesive, and FIG. 10 is a view showing a result of analysis of the temperature distribution when the LED substrate is fixed to the heat sink through the heat conductive adhesive.

9, when the LED substrate 5 with the LED 5a mounted thereon and the heat sink 6 are fixed to each other through the conductive adhesive agent 14, the heat sink 6, as shown in Fig. 10, The temperature distribution of the heat dissipation plate 6 can be easily determined according to the position of the heat dissipation plate 6. That is, it can be seen that the difference in temperature is great depending on the position of the heat sink 6. [

7 and 9 are thermally conductive aluminum attached to the LED.

It is possible to combine the LED substrate 5 and the heat sink 6 with the heat conductive screw 10 in the present invention by using the conductive adhesive 14 instead of joining the LED substrate 5 and the heat sink 6 The temperature distribution of the heat sink 6 is generally uniform and the heat distribution is uniform because the difference between the maximum temperature and the minimum temperature of the heat sink 6 is small. Therefore, even if the LED 5a is used for a long time, It is possible.

FIG. 11 is a plan view of a platform to which the LED block is coupled, and FIG. 12 is a perspective view of a part of the platform to which the LED block is coupled.

11, the platform 1 in which the LED block 3 is slidably coupled is formed in a hexagon box shape, and the guide rail 2 is inserted into every hexagonal corner of the upper surface to electrically connect the guide rail 2 And a rail connector 16 are respectively installed. In addition, a constant voltage circuit 17 for adjusting the power supplied from the battery is provided in the center of the platform 1, and a circuit for supplying power to each of the rail connectors 16 is connected thereto. At this time, the circuits connected to the respective rail connectors 16 are alternately connected to the rail connectors 16 by a +, - circuit. From this, the + and - power sources are selectively supplied to the respective guide rails 2 through the rail connector 16.

12, guide rails 2 for sequentially slidingly connecting a plurality of LED blocks 3 to each rail connector 16 of the platform 1 are connected to each other. Each of these guide rails 2 is provided with a board rail groove 18a and a board rail groove 18b as rail grooves on opposite surfaces of the guide rail 2a on the side of the platform 1 and the guide rail 2b on the circuit side, And the heat sink rail grooves 18b are formed side by side. Therefore, the slide rail 13b formed on the LED substrate 5 of the LED block 3 is inserted into the substrate rail groove 18a and is slidably engaged with the slide rail 13a formed on the heat sink 6. In the heat sink rail groove 18b, (13a) is inserted and slidably engaged. Here, the substrate rail groove 18a is a groove to which power is supplied, and the heat sink rail groove 18b is a groove for supporting the LED block 3 itself. The sliding engagement of the LED block 5 is performed for each of the guide rails 2a and 2b opposed to each other along the upper surface of the platform 1 and is connected to the guide rails 2a and 2b ) Layer is piled up even in the height direction of itself.

As a result, the prefabricated resolver using the LED light source of the present invention is mounted on the platform 1 along with the LED 5a in such a manner that the LED substrate 5 is radially outwardly directed, Since the LED block 3 can be installed only at a necessary portion around the platform 1 or only at a required height in the height direction by installing the block 5, The position and the number of the LED blocks 3 can be adjusted freely. That is, the number and type of the LED blocks 5 are selected according to the brightness of the luminous bulb and the type of light (light quantity and light color), and the LED block 5 is slidably coupled to the platform 1 so that the installation is easily completed. It is not necessary to perform other operations such as shifting to the sliding operation.

Although the present invention has been described with reference to the drawings, it is to be understood that the invention is not limited to the disclosed embodiments and drawings, It will be understood by those skilled in the art that various changes may be made.

1: platform 2, 2a, 2b: guide rail
3: LED block 4: lens
4a: Lens fixing pin 5: LED substrate
5a: LED 6: heat sink
6a: Radiating body 6b: Radiating pin
7: Hall 8: PCB circuit pattern
9: Constant voltage ㅇ Constant current circuit 10: Heat conduction screw
11: Lens fixing hole 12: Conductive screw hole
13a, 13b: slide rail 14: conductive adhesive
15: Thermal conductive aluminum 16: Rail connector
17: constant voltage circuit 18a: substrate rail groove
18b: heat sink rail groove 19: upper cover

Claims (10)

A LED block including a lens disposed on an upper portion of the LED substrate and a heat sink coupled to the lower portion, and a platform for supplying power to the LED substrate of the LED block, wherein the LED block is slidably coupled Wherein the platform is made of a LED light source. The method according to claim 1,
Wherein the LED substrate is provided with an LED in a hole formed in a central portion thereof and power is supplied to the LED through a constant voltage circuit installed on the LED substrate. 3. The method of claim 2,
Wherein the heat dissipation plate is screwed to the LED substrate through a screw mounted on a central portion of the LED substrate. The method according to claim 1,
Wherein the lens has a lens fixing pin formed on both sides of the lens in a hole formed in both sides of the heat sink, and is coupled to the heat sink together with the LED substrate. The method according to claim 1,
The slide coupling of the LED block and the platform,
And a guide rail provided on the platform and formed with a rail groove into which the slide rail is inserted, wherein the guide rail is formed on the LED block. 6. The method of claim 5,
Wherein the platform is formed in a polygonal shape, and a rail connector is provided for each corner of the polygon on the upper surface, and guide rails are connected to the rail connectors, respectively. The method according to claim 6,
Wherein slide rails formed on both sides of the LED substrate are inserted into slide grooves formed on respective surfaces of opposing guide rails between edges of corners of the platform and are slidably coupled to each other. group. 8. The method of claim 7,
The rail grooves of the guide rails are formed by a substrate rail groove to which the LED substrate is connected and a heat radiating rail groove to which the heat sink is connected. The slide rail is formed on both sides of the LED substrate, Wherein the LED light source is used as a light source. 8. The method of claim 7,
Further comprising a constant voltage circuit built in the platform to supply power to the LED substrate through the substrate rail groove and electrically connected to the rail connector. 10. The method of claim 9,
Wherein the constant voltage circuit is connected to the + and - circuits alternately in two by one connector.

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