KR101157065B1 - Led lamp with waterproof and radiating structure - Google Patents

Abstract

PURPOSE: An LED lamp with waterproofing and radiating functions is provided to prevent contact with moisture by blocking an LED from the outside. CONSTITUTION: A LED lamp having heat dissipation and waterproof functions is composed of a spacer(100), a heat sink, a rubber plate, a pressing plate, a light transmitting cover(600), and a socket portion(700). The spacer is formed into circular. The spacer includes an exhaust groove concavely formed upward in a lower portion thereof. A plurality of exhaust holes communicated with the exhaust groove is formed on the side of the spacer forming the exhaust groove. The socket portion is combined with a top portion of the spacer. The heat sink and the light transmitting cover are combined with a lower portion of the spacer.

Description

LED lamp with heat dissipation and waterproofing {LED LAMP WITH WATERPROOF AND RADIATING STRUCTURE}

The present invention relates to an LED lamp having a heat dissipation and a waterproof function, and an LED lamp having a heat dissipation and a waterproof function to emit light by using an LED.

Commonly used lighting lamps include incandescent lamps, fluorescent lamps, PL lamps, and the like.

However, these conventional lamps have the disadvantage of high power consumption, short service life, and low impact resistance.

In addition, there is a problem that the environmental pollution is generated by embedding a heavy metal such as fluorescent material or mercury inside the lamp.

Accordingly, in recent years, power consumption can be reduced, impact resistant, prolonged service life, and environmentally friendly LED lamps are used.

In addition, since the LED has high brightness, it can be used as a light source for various lightings such as a head lamp, an indoor light, and an outdoor light of a vehicle, and thus its application range is wide.

On the other hand, high-intensity LEDs have a problem of generating very high heat when they are turned on, and when used outdoors, moisture can flow into the interior of the LED-equipped lamps, which can damage the LEDs, thus preventing the lamps from heating up. It is necessary to waterproof the lamp so that it does not come into contact with moisture.

The present invention is to solve the above problems, to block the LED from the outside to prevent contact with moisture, and to provide an LED lamp having a heat dissipation and waterproof function that can prevent overheating by circulating the heat inside to prevent overheating. Its purpose is to.

LED lamp having a heat dissipation and waterproofing function of the present invention to achieve the above object, the LED board is mounted on the outer surface and the circulation passage is formed therein air is moved, the circulation passage is formed in the inner direction A heat sink in which heat radiating fins protrude; A spacer mounted to an upper portion of the heat sink and having an exhaust hole formed at a side thereof to communicate with the circulation passage; A rubber plate mounted between the heat sink and the spacer; A pressing plate mounted between the spacer and the rubber plate to press the rubber plate in the heat sink direction; A floodlight cover having an upper end mounted below the spacer and a lower end mounted below the heat sink to cover an outer circumferential surface of the heat sink to form a sealed space; It is mounted to the upper portion of the spacer portion for connecting the LED substrate and an external power source; consisting of.

The lower surface of the rubber plate A lower closed protrusion of a closed curve shape is pressed to contact with at least one of the upper end of the heat sink or the upper end of the floodlight cover, and a sealing groove into which an O-ring is inserted is formed at the lower end of the heat sink to form a lower end of the floodlight cover. Is combined.

The heat sink may include: a main frame having an LED substrate mounted on an outer surface thereof and the circulation passage formed therein; It is coupled to the lower portion of the main frame, the LED substrate is mounted on the lower surface, made of a frame cover formed with an opening communicating with the circulation passage, the sealing groove is formed on the lower surface of the frame cover.

The inner surface of the main frame in which the circulation passage is formed is provided with a fastening portion to which the screw fastened through the rubber plate and the pressure plate is formed to protrude in an inward direction, and the rubber plate has a plurality of coupling holes through which the screw penetrates. In addition, the upper surface of the rubber plate in contact with the pressing plate is formed on the outer circumferential surface of each of the coupling hole is formed in the upper closed protrusion of the closed curve shape is connected integrally.

A plurality of connection holes are formed in the rubber plate to communicate with the enclosed space, and the spacers have a connection portion through which the electric wire is inserted into the connection hole and inserted into the connection hole to supply power to the LED substrate.

LED lamp having a heat dissipation and waterproofing function according to the present invention has the following effects.

It prevents water from entering the outer circumferential surface of the heatsink equipped with LED board to prevent the LED board from being damaged and circulates air through the circulation passage and exhaust hole to release heat generated from the LED lamp to prevent overheating of the lamp. You can prevent it.

In addition, by sealing the upper end of the heat sink and the floodlight cover with the rubber plate, and by sealing the lower end of the heat sink and the floodlight cover with an O-ring, it is possible to block the flow of moisture to the outer circumferential surface of the heat sink equipped with the LED substrate.

In addition, the upper sealing protrusion is formed to protrude on the rubber plate in contact with the pressure plate, it is possible to seal between the rubber plate and the pressure plate to increase the waterproof effect.

1 is a perspective view of an LED lamp having a heat dissipation and waterproofing function according to an embodiment of the present invention,
Figure 2 is an exploded perspective view of one direction of the LED lamp having a heat dissipation and waterproofing according to an embodiment of the present invention,
Figure 3 is an exploded perspective view of the other direction of the LED lamp having a heat dissipation and waterproofing according to an embodiment of the present invention,
4 is a plan view of a spacer according to an embodiment of the present invention;
5 is a cross-sectional view taken along line AA of FIG. 1;
6 is a cross-sectional view taken along line BB of FIG.
7 is a cross-sectional view taken along line CC of FIG. 1;
8 is a plan view of a frame cover according to an embodiment of the present invention;
9 is a plan view of a rubber plate according to an embodiment of the present invention,
10 is a plan view of a pressing plate according to an embodiment of the present invention,
11 is a view schematically showing a circulation structure of air according to an embodiment of the present invention;

1 is a perspective view of the LED lamp having a heat dissipation and waterproofing function according to an embodiment of the present invention, Figure 2 is a one-way exploded perspective view of the LED lamp having a heat dissipation and waterproofing function according to an embodiment of the present invention, Figure 3 Another direction exploded perspective view of an LED lamp having a heat dissipation and waterproofing function according to an embodiment of the present invention, Figure 4 (a) is a plan view of a spacer according to an embodiment of the present invention, Figure 4 (b) is an embodiment of the present invention 5 is a cross sectional view taken along line AA of FIG. 1, FIG. 6 is a cross sectional view taken along line BB of FIG. 1, and FIG. 7 is a cross sectional view taken along line CC of FIG. 1. 8 (a) is a plan view of a frame cover according to an embodiment of the present invention, FIG. 8 (b) is a bottom view of a frame cover according to an embodiment of the present invention, and FIG. 9 (a) is an embodiment of the present invention. 9 is a plan view of a rubber plate according to an embodiment, and FIG. 9 (b) shows an embodiment of the present invention. And the bottom surface of the rubber plate according to Fig, 10 is a plan view of the pressure plate according to an embodiment of the present invention, Figure 11 is a schematic view of the structure of the air circulation in the embodiment;

LED lamp having a heat dissipation and waterproofing function of the present invention, as shown in Figure 1 to 10, the spacer 100, heat sinks 200, 300, rubber plate 400, pressure plate 500, floodlight 600 ) And the socket 700.

The spacer 100 is formed in a circular shape as shown in FIGS. 2 and 3, and an exhaust groove 101 is formed to be concave upward.

In addition, a plurality of exhaust holes 102 communicating with the exhaust groove 101 are formed at the side surface of the spacer 100 forming the exhaust groove 101.

The spacer 100 is coupled to the socket portion 700 at the upper portion and the heat sinks 200 and 300 and the floodlight cover 600 at the lower portion thereof.

Specifically, as shown in Figure 4 (a) and 5, the upper coupling protrusion 110 is screwed with the socket portion 700 is formed on the upper surface of the spacer 100.

The upper coupling protrusion 110 is composed of three and are arranged at the same interval to each other.

In addition, as shown in Figure 4 (b) and 5, the lower coupling protrusion 120 which is screwed with the heat sinks 200, 300 protrudes on the lower surface of the spacer 100, the exhaust groove 101 is formed. Is formed.

The lower coupling protrusion 120 is composed of three and are arranged at the same interval to each other.

The upper coupling protrusion 110 and the lower coupling protrusion 120 as described above are spaced apart from each other in a circle having the same center in the spacer 100.

4 (b) and 6, a plurality of connection parts 130 having connection holes 131 are formed on the bottom surface of the spacer 100 to protrude.

The connecting portion 130 is composed of six and spaced apart from each other in a circular shape.

The connecting portion 130 is disposed outside the lower coupling protrusion 120.

The connection part 130 passes through the rubber plate 400 and the pressure plate 500 to communicate with the connection hole 131 and the sealed space C to be described later.

An electric wire is inserted into the connection hole 131 to supply power to an LED substrate (not shown) mounted on each surface of the heat sinks 200 and 300.

The heat sinks 200 and 300 are formed in a hexagonal column shape and are coupled to a lower portion of the spacer 100.

LED substrates (not shown) are mounted on the outer surfaces of the heat sinks 200 and 300, and a circulation passage 210 through which air moves is formed.

Specifically, the heat sinks 200 and 300 are formed of a main frame 200 and a frame cover 300.

The main frame 200 is formed in a hexagonal column shape, as shown in Figure 2 or 3, the LED substrate (not shown) is mounted on each outer surface.

As described above, the wires inserted into the connection holes 131 are connected to the LED substrate so that the LED emits light.

As shown in FIG. 5 or FIG. 6, the circulation passage 210 is formed in the center of the main frame 200 in a vertical direction.

The circulation passage 210 has an upper portion communicating with the exhaust groove 101 and the exhaust hole 102 and the lower portion is opened to the outside.

As shown in FIG. 7, a plurality of heat dissipation fins 220 protrude in an inner direction on an inner surface of the main frame 200 in which the purified passage is formed.

The heat dissipation fin 220 is formed long in the vertical direction along the inner surface of the main frame 200, as shown in FIG.

As shown in FIG. 7, each of the heat dissipation fins 220 formed on each inner surface of the main frame 200 is formed longer in the inner direction toward the center of one inner surface of the main frame 200.

Accordingly, while increasing the number of the heat radiation fins 220 formed on the inner surface of the main frame 200, it is possible to maximize the heat dissipation effect by contacting the heat radiation fins 220 with air.

As shown in FIG. 7, a fastening part 221 protrudes in an inner direction at a corner where each inner surface of the main frame 200 meets.

The fastening part 221 serves to dissipate heat, such as the heat dissipation fin 220, while the screws penetrating the rubber plate 400 and the pressure plate 500 are coupled to the main frame 200 and the rubber plate ( 400) and the pressure plate 500 is combined.

In addition, the coupling portion 221 is coupled to the lower coupling protrusion 120 by a screw to couple the spacer 100 and the main frame 200.

The frame cover 300 is formed in a hexagonal shape, such as the cross-sectional shape of the main frame 200 as shown in Figure 8 is coupled to the lower portion of the main frame 200.

Specifically, the frame cover 300 is coupled to the lower portion of the fastening portion 221 with a screw.

An opening 301 is formed at the center of the frame cover 300 to communicate with the circulation passage 210.

In addition, as shown in Figures 2 and 8 (a), the upper surface of the frame cover 300, the frame protrusion 310 protrudes upward.

The frame protrusion 310 protrudes toward the main frame 200 and is inserted between the heat dissipation fins 220 as shown in FIG. 7.

The frame protrusion 310 may be inserted between the heat dissipation fins 220 to fix the coupling position of the main frame 200 and the frame cover 300.

And an LED substrate (not shown) is mounted on the lower surface of the frame cover 300.

As the LED substrate is mounted on the lower surface of the frame cover 300, the LED may emit light to irradiate light in the downward direction of the lamp.

In addition, as shown in Figure 8 (b), the lower surface of the frame cover 300 is formed with a sealing groove 320 on the outside of the opening 301.

The sealing groove 320 is formed in an annular shape is the O-ring 330 is inserted.

The sealing groove 320 is inserted into the lower end of the floodlight cover 600 to be described later.

The rubber plate 400 is mounted between the spacer 100 and the heat sinks 200 and 300.

That is, the rubber plate 400 is disposed between the spacer 100 and the main frame 200 and is pressed in the direction of the main frame 200 by the pressing plate 500 to By being in close contact with the upper end, the closed space (C) is sealed.

The rubber plate 400 is formed in a disk shape as shown in Figure 9, the first center hole 401 is formed in communication with the exhaust groove 101 and the circulation passage 210 in the center.

A fixing protrusion 410 protrudes upward from an inner circumferential surface of the rubber plate 400 in which the first center hole 401 is formed.

The fixing protrusion 410 is composed of two as shown in Figure 9 (a) is disposed in a position facing each other.

That is, the mutual distance between the fixing protrusions 410 is equal to the diameter of the first center hole 401.

The fixing protrusion 410 is inserted into the fixing groove 510 formed in the pressing plate 500 to be described later to fix the coupling position of the rubber plate 400 and the pressing plate 500.

And, as shown in Figure 9, the rubber plate 400 is formed with a coupling hole 420 penetrating up and down.

The coupling holes 420 are spaced apart from each other at equal intervals, and correspond to the fastening portions 221, respectively.

In addition, the rubber plate 400 has an insertion hole 430 penetrating up and down the outer side of the coupling hole 420 is formed.

The insertion hole 430 is made of six and are arranged at the same interval.

In addition, the insertion hole 430 is disposed to correspond to the outer surface of the main frame 200 on which the LED substrate is mounted.

The connection portions 130 are respectively inserted into the insertion holes 430, and wires inserted into the connection holes 131 are connected to the LED substrates, respectively, as described above.

In addition, an upper sealing protrusion 440 is formed on the upper surface of the rubber plate 400.

The upper sealing protrusion 440 is formed on the outer circumferential surface of each of the coupling hole 420, as shown in Figure 9 (a) is formed as a closed curve of the hexagonal shape integrally connected.

The upper sealing protrusion 440 is formed inside the insertion hole 430.

The upper sealing protrusion 440 is in close contact with the lower end of the lower coupling protrusion 120 passing through the pressing plate 500 as shown in FIG.

The upper sealing protrusion 440 is pressed by the coupling force of the lower coupling protrusion 120 and the fastening portion 221 by a screw is in close contact with the lower end of the lower coupling protrusion 120.

In addition, as shown in Figure 6, the rubber plate 400 and the pressure plate 500 is coupled by a screw, the upper sealing protrusion 440 is the rubber plate 400 and the pressure plate (by screw) It is pressed by the bonding force of the 500 is in close contact with the lower surface of the pressing plate 500.

The upper sealing protrusion 440 is in close contact with the lower surface of the pressing plate 500 to seal between the rubber plate 400 and the pressing plate 500.

The upper sealing protrusion 440 seals between the rubber plate 400 and the pressure plate 500, so that the circulation passage 210 and the sealed space C are the rubber plate 400 and the pressure plate 500. Communicating therebetween can prevent water from flowing into the closed space (C).

The lower sealing protrusions 450 and 460 protrude from the lower surface of the rubber plate 400.

The lower sealing protrusions 450 and 460 may include an inner sealing protrusion 450 and an outer sealing protrusion 460.

As shown in FIG. 9 (b), the inner sealing protrusion 450 is formed of a closed curve having a hexagonal shape such as a cross-sectional shape of the main frame 200, so that the heat sinks 200 and 300, that is, the main frame 200, are closed. Abuts on the top.

The inner sealing protrusion 450 formed on the lower surface of the rubber plate 400 is formed between the coupling hole 420 and the insertion hole 430.

The internal sealing protrusion 450 is the pressure plate 500 to be described later, as shown in Figure 5 or 6 is coupled to the rubber plate 400 to the rubber plate 400 to the main frame 200 By pressing in the direction, the upper end of the main frame 200 and the lower surface of the rubber plate 400 in close contact with the upper end of the main frame 200.

The outer sealing protrusion 460 is formed in a circular closed curve as shown in Figure 9 (b), is disposed on the outer peripheral surface of the rubber plate 400 is in contact with the top of the floodlight cover 600.

And the outer sealing protrusion 460 is formed on the outside of the insertion hole 430.

The external sealing protrusion 460 is pressed by the coupling force of the spacer 100 and the floodlight cover 600 when the floodlight cover 600 is coupled to the spacer 100 as shown in FIG. 5. In close contact with the top of the floodlight cover 600 to seal the bottom of the rubber plate 400 and the top of the floodlight cover 600.

As described above, the inner sealing protrusion 450 seals the upper end of the main frame 200 and the lower surface of the rubber plate 400, and the outer sealing protrusion 460 is connected to the lower surface of the rubber plate 400. By sealing the upper end of the floodlight cover 600, it is possible to seal the sealed space (C) to be described later to prevent moisture from penetrating into the sealed space (C).

In addition, the upper surface of the main frame 200 and the lower surface of the rubber plate 400 is sealed on the outer circumferential surface of the coupling hole 420 on the lower surface of the rubber plate 400 having the coupling hole 420 formed thereon. Protruding protrusion is formed to increase the sealing effect of the closed space (C).

The rubber plate 400 may seal the closed space C without forming the upper and second sealing protrusions 440 and 450 and 460 as described above, but the upper surface of the rubber plate 400 may be closed. By forming the upper closed protrusions 440 and the lower closed protrusions 450 and 460 on the lower surface, the pressing force is concentrated on the upper closed protrusions 440 and the lower closed protrusions 450 and 460 so that the upper closed protrusions 440 and the lower closed protrusions. 450 and 460 may be in close contact with the main frame 200 and the pressure plate 500 to further increase the sealing effect of the closed space (C).

The pressing plate 500 is mounted between the spacer 100 and the rubber plate 400 to press the rubber plate 400 toward the heat sinks 200 and 300.

The pressure plate 500 is formed in a disk shape as shown in Figure 10, the second center hole to communicate with the exhaust groove 101, the circulation passage 210 and the first center hole 401 in the center 501 is formed.

A fixing groove 510 is formed on an inner circumferential surface of the rubber plate 400 on which the second center hole 501 is formed.

As shown in FIG. 10, the fixing grooves 510 are formed to correspond to the fixing protrusions 410.

As described above, the fixing protrusion 410 is inserted into the fixing groove 510 to fix the coupling position of the rubber plate 400 and the pressure plate 500.

In addition, the pressing plate 500 has a first through hole 520 penetrating up and down.

The first through hole 520 is formed to correspond to the coupling hole 420, the screw is coupled to the rubber plate 400 and the pressure plate 500 through the first through hole 520.

As described above, the pressure plate 500 is screwed with the rubber plate 400 and is in close contact with the upper sealing protrusion 440 by pressing the upper sealing protrusion 440.

Accordingly, as described above, the rubber plate 400 and the pressure plate 500 are sealed to prevent the circulation passage 210 and the sealed space C from communicating.

In addition, the lower coupling protrusion 120 is inserted into the first through hole 520 so that the spacer 100 and the rubber plate 400 are screwed together.

That is, the three lower coupling protrusions 120 are respectively inserted into the first through holes 520, and the lower first coupling protrusions 120 between the lower coupling protrusions 120 are not inserted. A screw is inserted into the ball 520 to couple the rubber plate 400 and the pressure plate 500.

In addition, a second through hole 530 is formed at an outer side of the first through hole 520 in the pressing plate 500.

The second through hole 530 is formed to correspond to the insertion hole 430, respectively, and the connection part 130 is inserted.

Accordingly, the connection portion 130 is inserted into the insertion hole 430 and the second through hole 530 so that the connection hole 131 and the closed space (C) communicate.

The floodlight cover 600 is formed in a cylindrical shape as shown in Figure 2 or 3, the upper end is mounted to the lower portion of the spacer 100, the lower end is mounted to the lower portion of the heat sink (200, 300) Covers the outer circumferential surfaces of the heat sinks 200 and 300.

In detail, as shown in FIG. 5, a hook groove 140 is formed on the lower inner circumferential surface of the spacer 100 to which the floodlight cover 600 is coupled, and the hook groove is formed on the upper outer circumferential surface of the floodlight cover 600. A hook protrusion 610 is formed to be coupled to the 140 so that the floodlight cover 600 is hooked to the spacer 100.

The floodlight cover 600 covers the heat sinks 200 and 300 to protect the LED substrate and the LEDs mounted on the outer circumferential surfaces of the heat sinks 200 and 300, and the light generated from the LEDs transmits to brighten the outside of the lamp.

5 to 7, the sealed space C is formed between the floodlight cover 600 and the heat sinks 200 and 300 coupled to the spacer 100.

The LED substrate is disposed in the enclosed space (C) is cut off from the outside.

As described above, an upper end of the floodlight cover 600 is in contact with the external sealing protrusion 460.

The floodlight cover 600 is in close contact with the external sealing protrusion 460 by pressing the external sealing protrusion 460 by a coupling force coupled with the spacer 100.

And the lower end of the floodlight cover 600 is bent in the upper direction is coupled to the sealing groove 320.

O-ring 330 is inserted into the sealing groove 320 as described above, the lower end of the floodlight cover 600 by the coupling force of the spacer 100 and the floodlight cover 600 is the O-ring 330 The O-ring 330 is in close contact with the lower end of the floodlight cover 600 by pressing upward.

A suction port 620 is formed at a lower end of the floodlight cover 600 to communicate with the circulation passage 210 and the opening 301.

The inlet 620 is formed in a circular shape, and outside air is introduced into the circulation passage 210 through the inlet 620.

As such, the upper end of the floodlight cover 600 is in close contact with the outer sealing protrusion 460, and the lower end of the floodlight cover 600 is inserted into the sealing groove 320 to be in close contact with the O-ring 330. As a result, the sealed space C may be blocked from the outside to prevent moisture from flowing into the sealed space C.

In addition, as described above, the closed space C and the circulation passage 210 are blocked by the inner closed protrusion 450 and the upper closed protrusion 440.

As described above, by sealing the sealed space C in which the LED substrate is disposed, the LED substrate may be prevented from being damaged by blocking moisture from flowing into the sealed space C.

The socket part 700 is mounted on the spacer 100 as shown in FIG. 3 or 4 to connect the LED substrate to an external power source.

In detail, the socket part 700 is screwed to the spacer 100 by the upper coupling protrusion 110.

In addition, a switching mode power supply (SMPS) is inserted into the socket 700.

The SMPS (not shown) converts an AC current connected from the outside into a DC current, and is inserted into the connection hole 131 to supply a DC current to the LED substrate through wires connected to the SMPS and the LED substrate, respectively.

As such, the LED which is supplied with power to the LED substrate emits high heat.

As shown in FIG. 11, heat generated from the LED is transferred to the heat sinks 200 and 300, that is, the main frame 200 and the frame cover 300, and the circulation passage 210 through the heat dissipation fin 220. Heat transfer occurs to the air introduced into

The heat transferred from the heat dissipation fin 220 warms the air and the warmed air rises.

In addition, external cold air flows into the circulation passage 210 through the suction port 620 to continuously generate heat transfer from the heat dissipation fin 220 to the cold air.

The warmed air rises along the circulation passage 210 to move to the exhaust groove 101 formed in the spacer 100 and is discharged to the outside through the exhaust hole 102.

As described above, air circulates through the inlet 620, the circulation passage 210, the exhaust groove 101, and the exhaust hole 102 and cools the lamp.

As such, the air is circulated into the lamp to release heat generated from the LED lamp, thereby preventing overheating of the lamp.

The LED lamp having the heat dissipation and waterproofing function of the present invention is not limited to the above-described embodiment, and may be variously modified and implemented within the range in which the technical idea of the present invention is permitted.

100: spacer, 101: exhaust groove, 102: exhaust hole, 110: upper coupling protrusion, 120: lower coupling protrusion, 130: connection portion, 131: connection hole, 140: hook groove, 200: main frame, 210: circulation passage, 220: heat dissipation fin, 221: fastening portion, 300: frame cover, 301: opening, 310: frame projection, 320: sealing groove, 330: O-ring, 400: rubber plate, 401: first center hole, 410: fixing protrusion, 420: coupling hole, 430: insertion hole, 440: upper sealing protrusion, 450: inner sealing protrusion, 460: outer sealing protrusion, 500: pressure plate, 501: second center hole, 510: fixed groove, 520: first through Ball, 530: second through hole, 600: floodlight cover, 610: hook projection, 620: suction port, 700: socket part,

Claims (5)

A heat sink in which an LED substrate is mounted on an outer surface and a circulation passage through which air moves is formed, and a heat dissipation fin protrudes in an inner direction on an inner surface on which the circulation passage is formed;
A spacer mounted to an upper portion of the heat sink and having an exhaust hole formed at a side thereof to communicate with the circulation passage;
A rubber plate mounted between the heat sink and the spacer;
A pressing plate mounted between the spacer and the rubber plate to press the rubber plate in the heat sink direction;
A floodlight cover having an upper end mounted below the spacer and a lower end mounted below the heat sink to cover an outer circumferential surface of the heat sink to form a sealed space;
LED lamp having a heat dissipation and waterproof function, characterized in that consisting of; the socket portion is mounted on the spacer to connect the LED substrate and an external power source. The method of claim 1,
The lower surface of the rubber plate A lower closed protrusion of a closed curve shape is pressed to contact with at least one of the upper end of the heat sink or the upper end of the floodlight cover,
LEDs having heat dissipation and waterproofing, characterized in that the bottom of the heat sink is formed with a sealing groove is inserted into the O-ring is coupled to the bottom of the floodlight cover. The method of claim 2,
The heat sink,
A main frame having an LED substrate mounted on an outer surface thereof and having the circulation passage therein;
Is coupled to the lower portion of the main frame, the LED substrate is mounted on the lower surface, made of a frame cover formed with an opening opening in communication with the circulation passage,
The sealing groove is an LED lamp having a heat dissipation and waterproofing, characterized in that formed on the lower surface of the frame cover. The method of claim 3, wherein
The inner side of the main frame in which the circulation passage is formed is formed with a fastening portion which is coupled to the screw coupled through the rubber plate and the pressure plate protruding inward direction,
The rubber plate is formed with a plurality of coupling holes through which the screw penetrates,
LED lamps having heat dissipation and waterproofing, characterized in that the upper surface of the rubber plate in contact with the pressing plate is formed on the outer circumferential surface of each of the coupling hole is formed in the upper closed protrusion of the closed curve connected integrally. The method according to any one of claims 1 to 4,
The rubber plate is formed with a plurality of connecting holes in communication with the closed space,
LEDs having a heat dissipation and waterproofing function, characterized in that the spacer portion is formed through the pressure plate is inserted into the connection hole is inserted into the connection hole for supplying power to the LED substrate.

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