KR101044047B1 - Anion generating led lamp with improved efficiency of radiating heat - Google Patents

Abstract

PURPOSE: An anion generating LED lamp with improved efficiency of emitting heat is provided to form a heat emitting hole on the outer circumference of the housing of an LED lamp. CONSTITUTION: A cylindrical case(100) includes an opened upper part and an opened lower part. A cylindrical housing(200) is installed in the case. The housing comprises a light emitting part mounting surface, an anion brush support stand(215), and a planar part. An anion module is installed in the housing. A light transmitting cover(400) includes a brush outlet(410) and an anion brush protecting fixture(420). A light emitting unit(300) includes an LED module(310), an LED module bracket, and a plurality of light emitting plates(330). A socket unit(500) includes a socket cover(520), a power unit, and a socket(530).

Description

Anion generating LED lamp with improved efficiency of radiating heat

According to the present invention, the through hole formed by the heat dissipation groove of the floodlight cover and the heat dissipation groove rail of the case and the heat dissipation hole of the housing and the heat dissipation hole of the socket communicate with each other to smoothly inflow and discharge of the outside air. The present invention relates to an anion LED lamp having improved heat dissipation efficiency by which the LED module bracket and the heat dissipation plate provided in the unit facilitate heat dissipation of the LED module.

Conventional lighting devices have been used for the purpose of simply illuminating a dark place, and have also been developed for the purpose of use. However, as living standards have been improved and eco-friendly parts are required, high-efficiency fluorescent lamps have replaced the incandescent bulbs. In order to use these fluorescent lamps more efficiently, a plurality of fluorescent lamps having different phases are paralleled. The main focus has been the development of fluorescent lamps to reduce eye fatigue by placing and socket-type fluorescent lamps that can be used directly in conventional incandescent light bulb sockets.

However, since there is a limit in overlapping wavelengths of fluorescent lamps, the development of light bulbs using LEDs that emit light close to natural light has been made. With the growing interest, the development of a device in which an anion generator having an air cleaning function is combined with a lighting device has been made.

In general, anion neutralizes and precipitates gas pollutants such as nitrogen oxides, sulfur oxides, hydrocarbons and carbon monoxide, and volatile organic compounds such as formaldehyde and toluene to purify the air, and removes bacteria, bacteria and odors to clean the air. It is known to have the effect of keeping it.

As an LED lighting device having such anion generating function, for example, Korean Utility Model Model No. 20-0421556, the above design is, as shown in Figure 1, the cover 10, the lower surface is opened, and the cover The housing 20 is coupled to the lower surface of the (10) and the base is formed in the lower portion, anion generating chip and LED substrate provided in the housing 20, and formed from the anion generating chip extending from the outside of the cover It consists of anion generating part 30 which protrudes in the peripheral edge.

However, LEDs should be particularly careful about heat dissipation because current characteristics deteriorate as the temperature increases due to the characteristics of the diode, and the current flows inside, and the lifetime is shortened along with the reduction of the allowable current amount and luminous efficiency. The design of the present invention has a problem that the heat dissipation hole for heat dissipation of the LED substrate, that is, there is no configuration of the intake hole and the exhaust hole, so that the heat dissipation of the LED sensitive to temperature change can not be effectively carried out. In the above-described configuration, the negative ion generating unit is directly exposed to the upper end of the cover, so that the metal fiber may be damaged by rubbing hands or mops on the metal fiber of the negative ion generating unit while wiping the cover.

Therefore, the present invention for solving the above-described problem, the heat dissipation groove 435 of the floodlight cover 400 and the heat dissipation groove rail 135 formed in the case 100, and the heat dissipation hole of the housing 200 ( 230 and the heat dissipation hole 521 of the socket 500 are in communication with each other to facilitate the inflow of the outside air and the discharge of the introduced air, the LED module bracket 320 and the heat sink provided in the light emitting unit 300 ( The purpose of the present invention is to provide an anion LED lamp having improved heat dissipation efficiency by which heat dissipation of the LED module 310 is easily performed by 330.

In addition, the present invention, the heat dissipation plate 330 is provided to surround the outer periphery of the housing 200, the heat dissipation hole 230 is formed in an arc shape on the outer periphery of the housing 200, the air introduced into the heat dissipation plate 330 It is an object of the present invention to provide an anion LED lamp is improved heat dissipation efficiency is easily guided to increase the heat dissipation efficiency.

In addition, the present invention, an anion brush protector 420 is formed on the upper portion of the transparent cover 400, anion of improved heat dissipation efficiency to prevent the anion brush 610 from rubbing and damage during installation, use, cleaning, etc. of the lamp The purpose is to provide an LED lamp.

Anion LED lamp with improved heat dissipation efficiency of the present invention, the upper and lower cylindrical case 100 is opened; It is provided in the case 100, the upper portion of the light emitting portion mounting surface 210 is formed, the cylindrical anion brush support 215 is formed in the center of the light emitting portion mounting surface 210 protrudes upwards, The lower portion of the outer peripheral portion is formed with a flat portion 240 vertically extending, the inside is provided with an anion module 600, the cylindrical housing coupled to the lower end of the case 100 by the flat portion 240 200; Is formed of a circular transparent plate is mounted on the upper end of the case 100, an anion brush discharge port 410 is formed in the center, a circular anion brush protector 420 around the anion brush discharge port 410 A translucent cover 400 protruding in an upward direction; The LED module 310 is mounted on the light emitting unit mounting surface 210 of the housing 200, and the LEDs 312 are mounted in a plurality of symmetrical shapes on the printed circuit board 311, and the lower part of the LED module 310. The LED module bracket 320 coupled to the LED module bracket 320 is mounted to a lower portion of the LED module bracket 320, and both ends of the heat sink 330 are bent downward, wherein the LED module 310, the LED module bracket 320 ) And a light emitting part 300 in which through holes 315, 325, and 335 are formed to penetrate the anion brush support 215 at the center of the heat sink 330. And a socket cover 520 which is formed in a hemispherical shape with an upper opening and is mounted to the lower portion of the case 100, and is provided inside the socket cover 520 to the LED module 310 and the anion module 600. A socket part 500 including a power supply part 510 for supplying power and a socket 530 provided under the socket cover 520; It is configured to include, the outer periphery of the transparent cover 400 is formed around the circumferential surface 430 of the band-shaped formed with a heat dissipation groove 435 at equal intervals extending in the downward direction, the flat portion of the housing 200 An arc-shaped heat dissipation hole 230 is formed in the 240, and a plurality of heat dissipation holes 521 are formed under the socket cover 520 of the socket part 500, so that the heat dissipation groove 435 and the heat dissipation hole ( 230 and the heat dissipation hole 521 is characterized in that the mutual communication.

The present invention provides a through hole formed by the heat dissipation groove 435 of the floodlight cover 400 and the heat dissipation groove rail 135 of the case 100, and the heat dissipation hole 230 and the socket 500 of the housing 200. The heat dissipation hole 521 communicates with each other to facilitate the inflow of external air and the discharge of the introduced air, and the LED module 310 is provided by the LED module bracket 320 and the heat sink 330 provided in the light emitting unit 300. There is an effect that the heat radiation of the easily made.

In addition, the present invention, the heat dissipation plate 330 is provided to surround the outer periphery of the housing 200, the heat dissipation hole 230 is formed in an arc shape on the outer periphery of the housing 200, the air introduced into the heat dissipation plate 330 Easily induced to) has the effect of increasing the heat radiation efficiency.

In addition, according to the present invention, the anion brush protector 420 is formed on the translucent cover 400, so that the anion brush 610 is not damaged due to friction during installation, use, and cleaning of the lamp.

1 is a perspective view of a conventional anion LED lamp.
Figure 2 is a perspective view of an anion LED lamp having improved heat dissipation efficiency according to an embodiment of the present invention.
Figure 3 is an exploded perspective view of the anion LED lamp having improved heat dissipation efficiency according to an embodiment of the present invention.
Figure 4 is a cross-sectional view of the anion LED lamp is improved heat radiation efficiency according to an embodiment of the present invention.
5 is a bottom view of the housing of the anion LED lamp having improved heat dissipation efficiency according to an embodiment of the present invention.

Hereinafter, a detailed description will be made based on the accompanying anion LED lamp having improved heat dissipation efficiency according to an embodiment of the present invention.

1 is a perspective view of a conventional anion LED lamp, FIG. 2 is a perspective view of an anion LED lamp having improved heat dissipation efficiency according to an embodiment of the present invention, and FIG. 3 is an anion having improved heat dissipation efficiency according to an embodiment of the present invention. Figure 4 is an exploded perspective view of the LED lamp, Figure 4 is a cross-sectional view of the anion LED lamp with improved heat dissipation efficiency according to an embodiment of the present invention, Figure 5 is a housing of the anion LED lamp with improved heat dissipation efficiency according to an embodiment of the present invention Bottom view.

Anion LED lamp of the improved heat dissipation efficiency of the present invention, as shown in Figures 2 to 5,

A case 100 having an upper and a lower opening to be hollowed inside, a housing 200 provided inside the case 100 and having a light emitting unit mounting surface 210 formed thereon, and mounted on an upper portion of the housing 200. It is configured to include a light emitting unit 300, a light-transmitting cover 400 is coupled to the upper end of the case 100 and the socket 500 is coupled to the lower end of the case 100.

The case 100 is formed in a cylindrical shape with the upper and lower openings, and has an upper diameter lower than the lower diameter, and has a shape of a light receiving narrow. The opening of the upper portion is combined with a floodlight cover 400, and the lower opening has a socket portion. 500 are combined to form the shape of the lamp. On the other hand, the cylindrical housing 200 is formed at the lower end of the case 100 extending vertically upward, the air movement path is formed in the space formed by the outer periphery of the housing 200 and the inner periphery of the case 100.

The upper end of the case 100 is formed with a plurality of projection cover coupling projections 136 for coupling with the transparent cover 400, the outer periphery, the upper end of the case 100 is formed in such a shape that the cross section is outwardly stepped The stepped portion of the translucent cover 400 formed inwardly stepped is inserted into the case 100 and then fixed by the translucent cover coupling protrusion 136. In addition, when the case 100 is combined with the floodlight cover 400, when the outside air is guided to the inside, a vortex phenomenon occurs due to the step difference of the stepped portion. In order to reduce the vortex phenomenon, the top surface of the stepped portion has a flat shape. A plurality of heat dissipation groove rails 135 extending upward from the inner circumference of the case 100 to the upper end of the case 100 are formed at positions corresponding to the heat dissipation grooves 435 of the floodlight cover 400.

At this time, the outward stepped means that the shape of the cross-section is high and the inside is low, likewise the inward stepped means that the shape of the cross-section is high and the outside is low, in the description of the formation direction of the step It is applied uniformly throughout.

The housing 200 is formed in a cylindrical shape and is provided inside the case 100, and a light emitting portion mounting surface 210 is formed at an upper portion thereof, and a light emitting portion mounting surface 210 is vertically extended at a lower end portion of the outer circumference thereof. It is coupled to the lower end of the case 100, an anion module 600 is provided therein.

In more detail, the housing 200 is vertically upwardly disposed at the lower opening of the case 100 to form a cylindrical shape, and a protrusion protruding from one side of the horizontal cross section to have a 'c' shape to the outside ( 220 is formed, and a projection 220 having a 'c' shape is formed on the opposite side of the protruding one side to the outside so that the negative ion module 600 having a rectangular frame shape is accommodated therein, wherein the housing 200 protrudes The inside of the 220 is a cube-shaped buffer member 225 is provided to be in close contact with the lower surface of the light emitting unit mounting surface 210, even if the lamp is mounted upside down and the negative ion module 600 and the light emitting unit mounting surface 210 and A space is formed between the negative ion module 600 so that the negative ion brush 610 is not damaged.

The upper surface of the housing 200 is closed so that the light emitting unit mounting surface 210 is formed so that the light emitting unit 300 can be mounted. An anion is mounted inside the housing 200 at the center of the light emitting unit mounting surface 210. A cylindrical anion brush support 215 is formed to support the anion brush 610 of the module 600 to be guided to the upper floodlight cover 400, and the light emitting part 300 is provided on both sides of the anion brush support 215. The light emitting unit fixing hole 213 is formed to protrude so that the light emitting unit fixing screw 314 may be fixed. In addition, a power line through hole 217 may be formed at one side of the light emitting unit mounting surface 210 to supply power to the LED module 310.

On the other hand, when the housing 200 is provided vertically upward from the lower opening of the case 100, the housing 200 outside the housing 200 so that the housing 200 is spaced apart from the case 100 by a predetermined interval at the lower peripheral edge of the housing 200; The flat portion 240 is formed in the vertical direction of the peripheral edge, wherein the flat portion 240 in contact with the outer circumference of the housing 200 is formed with an arc-shaped heat dissipation hole 230 along the outer circumference of the housing 200, Air guided into the space between the case 100 and the housing 200 by the above-described heat dissipation hole 230 is supplied to the socket portion 500 to be described later and discharged to the outside, or flowed in from the socket portion 500. The outside air is guided to the space between the case 100 and the housing 200 and supplied to the heat sink 330, thereby dissipating the light emitting part 300. In addition, in this case, the housing 200 is coupled to and supported by the flat portion 240 only by the protrusion 220 formed on the outer circumference, and the flat portion in which the heat dissipation hole 230 is formed to reinforce the coupling force of the housing 200 is formed. A coupling part 245 extending from one end surface of the 240 and coupled to the outer periphery of the housing 200 may be formed across the heat dissipation hole 230. In addition, the planar portion 240 is formed in the housing 200, the coupling portion 245 is reduced in the area of the heat dissipation hole 230 or used in a place where the outside temperature is high to increase the heat dissipation efficiency heat dissipation hole 230 An auxiliary heat dissipation hole 235 may be further formed between the case 100 and the inner circumference, and the auxiliary heat dissipation hole 235 is formed in plural in a predetermined length in a range that does not impair the coupling durability of the housing 200.

Transmissive cover 400 is formed of a disk-shaped transparent material protruding downward, the outer periphery is coupled to the upper end of the case 100 so that the light emitting portion 300 is included in the combined light emitting portion 300 It serves to emit the emitted light to the outside, and also serves to supply air into the case 100 or to discharge the air inside the case 100 to the outside.

In more detail, the floodlight cover 400 is formed of a circular transparent plate formed of polycarbonate (PC) or the like, and anion brushes connected from the anion module 600 are formed at the center of the floodlight cover 400. Anion brush outlet 410 is formed so that the 610 may protrude to the outside, and a circular anion brush protector 420 is outwardly around the anion brush outlet 410 outside the anion brush outlet 410. Is formed to protrude.

The anion brush outlet 410 is in close contact with the narrow gap between the negative ion brush 610 is narrowed from the bottom to the upper end of the longitudinal shape of the anion brush outlet 410 so that the anion brush 610 protrudes to a predetermined length or less. To be fixed. At this time, the degree of protrusion of the anion brush 610 is preferably to be less than the height of the anion brush protector 420 is formed, which is rubbed on the anion brush 610 by a mop or a hand in the installation, use, cleaning, etc. of the lamp. This is to prevent the negative ion brush 610 from being damaged.

The outer periphery of the transparent cover 400 is formed to extend downward to form a circumferential surface 430, wherein the lower end of the circumferential surface 430 is formed to be stepped inwardly and inserted into the upper end of the case 100 described above. A first case coupling groove 436 is formed at an inner circumference of the circumferential surface 430 so that the light-transmitting cover coupling protrusion 136 of the case 100 is engaged and fixed.

The circumferential surface 430 has a plurality of heat dissipation grooves 435 cut upward from the lower end of the circumferential surface 430 at equal intervals along the outer circumference. The heat dissipation groove 435 is disposed to face the heat dissipation groove rail 135 formed in the case 100 when the floodlight cover 400 is mounted to the case 100, and at this time, the heat dissipation groove 435 is a cut top It is formed to a depth that does not contact the heat radiating groove rail 135 of the case 100 to the through hole formed by the heat radiating groove 435 and the heat radiating groove rail 135 to communicate with the outside and the inside of the lamp by the air outside the lamp To the inside or to exhaust the air inside the lamp.

The floodlight cover 400 is preferably replaced every six months, but due to the nature of the negative ion emission lamp, a lot of dust is accumulated on the top surface of the floodlight cover 400, so when using it in a dusty place, it is necessary to wipe it frequently from time to time. Due to the anion brush protector 420 formed on the upper portion of the 400, the transparent cover 400 can be easily cleaned without damaging the anion brush 610.

The light emitting unit 300 includes an LED module 310 having a plurality of LEDs 312 mounted in a symmetrical form, and a heat dissipation plate 330 that is coupled to a lower portion of the LED module 310 to collect heat emitted from the LED module 310. The LED module bracket 320 and a plurality of heat sinks 330 mounted on the lower part of the LED module bracket 320 to transmit to the outside to radiate the heat conducted from the LED module bracket 320 to the outside.

The LED module 310 allows a plurality of LEDs 312 to be symmetrically mounted on the circular printed circuit board 311 to emit light, and anion brush support formed in the housing 200 at the center of the printed circuit board 311. The through hole 315 is formed to penetrate 215. Fixing screw holes 313 are formed at both sides of the through hole 315 of the LED module 310 so that the light emitting part fixing screw 314 penetrates and is fixed to the light emitting part fixing hole 213 of the housing 200. In the vicinity of the outer circumference of the LED module 310, a plurality of coupling screw holes 316 for coupling with the LED module bracket 320 to be described below are formed to allow the LED module coupling screw 317 to penetrate.

The LED module bracket 320 collects heat generated when the LED 312 of the LED module 310 emits light and transfers the heat generated to the heat sink 330 to be described below. The LED module bracket 320 is usually made of a metal plate such as copper or aluminum. do. The through hole 325 is formed in the center of the LED module bracket 320 so that the anion brush support 215 penetrates like the LED module 310, and the light emitting part fixing screw 314 is formed on both sides of the through hole 325. A fixing screw hole 323 is formed to penetrate. In addition, the LED module coupling hole 326 is formed in the outer circumferential direction of the LED module bracket 320 so that the above-described LED module 310 can be coupled to allow the LED module coupling screw 317 to be inserted and fixed.

The LED module bracket 320 may be formed in a circular or polygonal shape, but may be formed in a regular hexagon to form a sense of unity with the heat dissipation plate 330 to be described below and to increase heat dissipation efficiency, depending on the number of heat dissipation plates 330. Square, octagonal shape, etc. is also possible, of course.

The heat sink 330 is mounted to the lower portion of the LED module bracket 320 in order to discharge heat conducted from the LED module bracket 320 to the outside, and is formed in a plate shape in the vicinity of the outer circumference of the LED module bracket 320 described above. Both ends are bent downward to form a 'c' shape, and the bent portion is mounted to be located in a space formed between the case 100 and the housing 200. The plurality of heat sinks 330 are arranged in a staggered manner to surround the outer periphery of the housing 200. According to an embodiment of the present invention, the number of heat sinks 330 is preferably three, and the heat sinks ( If the number of the 330 is less than three, the difference in the density of air that does not surround the outer periphery of the housing 200 or the air guided into the circular space is in contact with the heat sink 330 is severe, and the heat radiation efficiency is reduced, If the number of the 330 is greater than three, the area per unit of the heat sink 330 is reduced, so that the area in contact with the LED module bracket 320 of the upper portion is also small, so that the smooth heat conduction is not made.

Through-holes 335 are formed in the center of each heat sink 330 such that the anion brush support 215 of the housing 200 penetrates like the LED module 310 and the LED module bracket 320. ) And fixing screw holes 333 are formed at positions corresponding to the fixing screw holes 313 and 323 formed in the LED module bracket 320, respectively, so that the light emitting part fixing screw 314 is formed from the LED module 310. It passes through the bracket 320 to each heat sink 330 to be fixed to the light emitting portion fixing hole 213 of the housing 200. A heat dissipation auxiliary material such as a thermal grease or a thermal compound may be applied between the heat sink 330, the LED module bracket 320, and each heat sink 330, and the heat sink 330 is typically used. It may be formed of graphite or the like, but may be formed of carbon graphite, aluminum, copper, or the like, but the material is not limited thereto.

The socket 500 includes a power supply unit 510 for supplying power to the LED module 310 and the negative ion module 600, and a plurality of heat dissipation holes 521 formed at a lower portion thereof, and the power supply unit 510 is fixed therein. The socket cover 520 and the socket 530 provided on the lower portion of the socket cover 520 is formed so that the power supply holder 522 is formed.

The power supply unit 510 is composed of a Switched Mode Power Supply (SMPS) configured by mounting an element on a circular substrate, and supplies stable power to the LED module 310 and the negative ion module 600 even when the external voltage is changed. On one side of the power supply fixing hole 511 is formed is fixed to the power supply holder 522 of the socket cover 520 by a power supply fixing screw 512 or the like.

The socket cover 520 has a hemispherical shape with an open upper portion, and a power supply holder 522 extends on one inner side thereof, and a socket 530 is provided below.

A plurality of heat dissipation holes 521 are formed on the lower surface of the socket cover 520 to supply external air to the heat dissipation holes 230 formed in the housing 200 or to flow in from the heat dissipation holes 230 of the housing 200. It serves to release air to the outside. The upper end of the socket cover 520 is formed to be outwardly stepped, and the inward stepped stepped part of the case 100 is inserted and mounted therein, and the case 100 to the second case coupling groove 526 formed at the upper end of the socket cover 520. The socket cover engaging projection 126 of the engagement is fixed. On one side of the socket cover 520, the power supply holder 522 is formed to protrude vertically upwards, and the power supply unit 510 fixing screw penetrating the power supply fixing hole 511 formed in the power supply unit 510 is inserted and fixed thereto. At this time, the distance between the outer periphery of the power supply unit 510 and the inner periphery of the socket cover 520 is spaced by a predetermined interval to ensure the movement path of the air.

Looking at the heat dissipation process of the negative ion LED lamp having improved heat dissipation efficiency according to the embodiment of the present invention having the above configuration,

Outside air flows into the socket cover 520 through the heat dissipation hole 521 formed in the socket cover 520 of the socket part 500, and the introduced air fills a gap between the power supply part 510 and the socket cover 520. It is supplied to the heat dissipation hole 230 of the housing 200 located above. The air supplied to the heat dissipation hole 230 is guided to the space formed by the housing 200 and the case 100. At this time, heat is exchanged with the heat dissipation plate 330 located in the space and absorbs heat from the heat dissipation plate 330. One air is discharged to the outside through a through hole formed by the heat dissipation groove rail 135 and the heat dissipation groove 435 of the floodlight cover 400 formed at the upper end of the case 100. On the other hand, a part of the air guided to the upper portion of the case 100 is led to the upper portion of the LED module 310, the LED 312 is mounted, the air passing through the heat dissipation process of the LED module 310 is formed through the upper plane of the floodlight Guided to the outside along the surface of the cover 400 is discharged to the outside through the through-hole formed by the heat radiation groove rail 135 and the heat radiation groove 435.

On the other hand, in the embodiment of the present invention has been shown and described with respect to the configuration in which the socket portion 500 of the lamp is directed downward, but may be installed so that the socket portion 500 of the lamp is directed upward, in this case The outside air is introduced into the through hole formed by the heat dissipation groove 435 of the floodlight cover 400 and the heat dissipation groove rail 135 of the case 100, and the air introduced is the case 100 and the housing 200. It is guided to the space to be formed and is heat exchanged with the heat sink 330 is supplied to the socket portion 500 through the heat dissipation hole 230 of the housing 200, a part of the introduced air is led to the LED module 310 The heat dissipation process of the LED module 310 is guided outward along the surface of the flat substrate, and is supplied to the socket part 500 through the heat dissipation hole 230 formed in the housing 200. The air supplied to the socket part 500 through the heat dissipation hole 230 of the housing 200 passes through the gap between the socket cover 520 and the power supply part 510 and passes through the heat dissipation hole 521 formed in the socket cover 520. Through the outside.

On the other hand, the air around the heat generating member having a higher temperature than the surroundings is warmed by the heat generating member so that the density is relatively low, and the air is drawn in and discharged because the air is drawn upward toward the upper direction by the convection phenomenon. It is preferable to describe so that the part of the air is moved first, but in describing the technical idea of the present invention, it is efficient to sequentially explain the intake point and the exhaust point of the air, and this heat dissipation process is obvious to those skilled in the art. Detailed description will be omitted.

The present invention having the above-described configuration includes a through hole formed by the heat dissipation groove 435 of the floodlight cover 400 and the heat dissipation groove rail 135 of the case 100, the heat dissipation hole 230 and the socket of the housing 200. The heat radiating holes 521 of the part 500 communicate with each other to facilitate the inflow of the outside air and the discharge of the inflowed air, and are provided by the LED module bracket 320 and the heat sink 330 provided in the light emitting part 300. There is an effect that the heat radiation of the LED module 310 is easily made,

In addition, the present invention, the heat dissipation plate 330 is provided to surround the outer periphery of the housing 200, the heat dissipation hole 230 is formed in an arc shape on the outer periphery of the housing 200, the air introduced into the heat dissipation plate 330 Easily induced to) has the effect of increasing the heat dissipation efficiency,

In addition, according to the present invention, the anion brush protector 420 is formed on the translucent cover 400, so that the anion brush 610 is not damaged due to friction during installation, use, and cleaning of the lamp.

100: case 200: housing
210: light emitting portion mounting surface 215: anion brush support
230: heat dissipation hole 240: flat portion
300: light emitting unit 310: LED module
320: LED module bracket 330: heat sink
400: floodlight cover 410: anion brush discharge port
420: anion brush protector 435: heat dissipation groove
500: socket portion 521: heat sink

Claims (4)

A cylindrical case 100 having upper and lower openings;
It is provided in the case 100, the upper portion of the light emitting portion mounting surface 210 is formed, the cylindrical anion brush support 215 is formed in the center of the light emitting portion mounting surface 210 protrudes upwards, The lower portion of the outer peripheral portion is formed with a flat portion 240 vertically extending, the inside is provided with an anion module 600, the cylindrical housing coupled to the lower end of the case 100 by the flat portion 240 200;
Is formed of a circular transparent plate is mounted on the upper end of the case 100, an anion brush discharge port 410 is formed in the center, a circular anion brush protector 420 around the anion brush discharge port 410 A translucent cover 400 protruding in an upward direction;
The LED module 310 is mounted on the light emitting unit mounting surface 210 of the housing 200, and the LEDs 312 are mounted in a plurality of symmetrical shapes on the printed circuit board 311, and the lower part of the LED module 310. The LED module bracket 320 coupled to the LED module bracket 320 is mounted to a lower portion of the LED module bracket 320, and both ends of the heat sink 330 are bent downward, wherein the LED module 310, the LED module bracket 320 ) And a light emitting part 300 in which through holes 315, 325, and 335 are formed to penetrate the anion brush support 215 at the center of the heat sink 330. And
A socket cover 520 which is formed in a hemispherical shape with an upper opening and is mounted on the lower portion of the case 100, and is provided in the socket cover 520 to supply power to the LED module 310 and the negative ion module 600. A socket part 500 including a power supply part 510 for supplying power and a socket 530 provided under the socket cover 520;
Consists of including
The outer periphery of the floodlight cover 400 is formed with a circumferential surface 430 having a heat dissipation groove 435 formed at equal intervals extending downward, and the flat portion 240 of the housing 200 has an arc shape. A heat dissipation hole 230 is formed, and a plurality of heat dissipation holes 521 are formed under the socket cover 520 of the socket part 500, so that the heat dissipation grooves 435, the heat dissipation holes 230, and the heat dissipation holes ( 521) anion led lamp with improved heat dissipation efficiency, characterized in that the mutual communication. The method of claim 1,
The case 100 is a heat dissipation groove rail 135 extending from the inner periphery of the case 100 to an upper end of the case 100 at a position corresponding to the heat dissipation groove 435 of the floodlight cover 400. Anion LED lamp with improved heat dissipation efficiency, characterized in that it further comprises a). The method of claim 2,
The housing 200 has a protrusion 220 having a shape in which both sides of the horizontal cross section facing each other in a horizontal cross section protrude outwards in a 'c' shape so that the negative ion module 600 is accommodated therein, and the protrusion 220 is formed. Heat dissipation efficiency improved anion LED lamp, characterized in that the inside of the hexahedral buffer member 225 is provided to be in close contact with the lower surface of the light emitting portion mounting surface (210). The method of claim 3, wherein
The floodlight cover 400 is formed so that the longitudinal cross-sectional shape of the negative ion brush discharge port 410 is gradually narrowed from the bottom to the upper portion so that the negative ion brush 610 protrudes below the height at which the negative ion brush protector 420 is formed. Anion LED lamp with improved heat dissipation efficiency.

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