KR102352816B1 - Lighting device having heat sink assembly with improved heat dissipation performance - Google Patents

Abstract

The present invention relates to a heat sink attachment type lighting device. In one embodiment, disclosed is a lighting device that includes a chip on board (COB) having a light emitting member; a heat sink assembly physically and thermally attached to the COB to radiate heat generated from the light emitting member of the COB to the outside; and a lighting device case surrounding the COB and having a reflector for reflecting the light emitted from the COB in a predetermined direction. The heat sink assembly may include: a disk-shaped, thermally conductive upper diffusion plate having the COB mounted on its upper surface; a disk-shaped, thermally conductive lower diffusion plate attached to the lower surface of the upper diffusion plate; a plurality of first heat pipes, each of which includes a horizontal section interposed between the upper and lower diffusion plates and a vertical section extended in the horizontal section and bent vertically downward with a predetermined length; and a heat dissipation fin unit attached to each vertical section of the plurality of first heat pipes.

Description

Lighting device having heat sink assembly with improved heat dissipation performance}

The present invention relates to a lighting device, and more particularly, to a lighting device having a heat sink assembly capable of effectively dissipating heat from a light emitting member.

A lighting device using LEDs is a means of illuminating a space by emitting light when power is supplied to a plurality of LEDs. Lighting devices using LEDs are replacing conventional lighting devices such as light bulbs and fluorescent lamps because of their long lifespan, low power consumption, and high illuminance.

However, lighting devices using LEDs have a high amount of heat generated by LEDs, so a heat sink is essential. In a conventional heat sink, a plurality of heat sinks are provided side by side in a straight line, so that they come into contact with air and emit heat generated by the LED to the outside. However, in the case of a lighting device that consumes a lot of power, such as a 1200W lamp, there is a limitation in that heat generated from the LED cannot be sufficiently cooled by simply contacting a plurality of heat sinks arranged in parallel with air.

Patent Document 1: Korean Patent Registration No. 10-1113292 (published on February 24, 2012) Patent Document 2: Korean Patent Registration No. 10-1967438 (Announced on April 10, 2019)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a heat sink assembly capable of dissipating heat generated from a light emitting member such as an LED as quickly and efficiently as possible to solve the above problem.

According to an embodiment of the present invention, there is provided a lighting device, comprising: a chip on board (COB) having a light emitting member; a heat sink assembly physically and thermally attached to the COB to radiate heat generated from the light emitting member of the COB to the outside; and a lighting device case having a reflective plate surrounding the COB and reflecting the light emitted from the COB in a predetermined direction; the upper diffuser plate of the castle; a disk-shaped, thermally conductive lower diffusion plate attached to the lower surface of the upper diffusion plate; a plurality of first heat pipes, each of which includes a horizontal section interposed between the upper and lower diffusion plates and a vertical section extending in the horizontal section and bent vertically to extend a predetermined length; and a heat dissipation fin unit attached to each vertical section of the plurality of first heat pipes, wherein each horizontal section of the plurality of first heat pipes extends from the center of the first and lower diffusion plates in a radially outward direction. The heat dissipation fin units each have a coupling portion configured to pass through the vertical section of the first heat pipe, and are integrally formed with the coupling portion and extend outwardly. Disclosed is a lighting device comprising an outer heat dissipation fin having a fin, and an inner heat dissipation fin integrally formed with the coupling portion and extending in an inward direction.

According to an embodiment of the present invention, all components constituting the heat sink assembly of the lighting device, that is, the upper diffuser plate, the lower diffuser plate, the first and second heat pipes, the heat dissipation fin unit, the upper frame, the lower frame, and the side surface All components, such as the frame, are configured to contribute to heat dissipation so that they can be rapidly moved to the lower side of the heat sink assembly along at least two heat dissipation paths generated by the LED light emitting member of the chip-on-board (COB) to be discharged, and the conventional heat sink structure It has a technical effect of dissipating the heat of the light emitting member more quickly and efficiently compared to that.

In particular, in one embodiment of the present invention, the heat of the light emitting member can be transferred to the first heat pipe more quickly by configuring the first heat pipe in a structure in which the upper diffusion plate and the lower diffusion plate are wrapped from bottom to top, and from the heat dissipation fin unit to each outside Since the heat dissipation fins and the inner heat dissipation fins are vertically erected and are disposed in radially outward and inward directions, the heat dissipation fins are in contact with the first heat pipe over the entire length of the vertical section of the first heat pipe to dissipate heat from the first heat pipe. It can be transmitted more effectively with heat sink fins.

1 is a side view of a heat sink-attached lighting device according to an embodiment of the present invention;
2 is a front view of a heat sink-attached lighting device according to an embodiment;
3 is an exploded view of a heat sink-attached lighting device according to an embodiment;
4 is a perspective view of a heat sink assembly according to an embodiment;
5 is an exploded perspective view of a heat sink assembly according to an embodiment;
6 is a cross-sectional view of an upper portion of a heat sink assembly according to an embodiment;
7 is a perspective view of an upper portion of a heat sink assembly according to an embodiment;
8 is a view for explaining an upper diffuser plate according to an embodiment;
9 is a view for explaining a heat dissipation fin according to an embodiment;
10 is a view for explaining a heat dissipation path of a heat sink assembly according to an embodiment.

The above objects, other objects, features and advantages of the present invention will be easily understood through the following preferred embodiments in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosed subject matter may be thorough and complete, and that the spirit of the present invention may be sufficiently conveyed to those skilled in the art.

In the present specification, when it is mentioned that a first component is connected to (or coupled, fastened, attached, etc.) to a second component, unless there is an express limitation, a third component is formed between the first component and the second component. It includes cases where it is indirectly connected (or coupled, fastened, attached, etc.) through a component of

In the drawings of the present specification, the thickness of the components is exaggerated for effective description of technical content. In addition, in the drawings of the present specification, the length, width, volume, size, or thickness of the components are exaggerated for effective description of technical content.

In the present specification, when terms such as “first” and “second” are used to describe components, these components should not be limited by these terms. These terms are only used to distinguish one component from another. Embodiments described and illustrated herein also include complementary embodiments thereof.

In this specification, the singular also includes the plural unless specifically stated otherwise in the phrase. The expressions 'comprising', 'consisting of', and 'consisting of' used in the specification do not exclude the presence or addition of one or more other elements in addition to the mentioned elements.

Hereinafter, the present invention will be described in detail with reference to the drawings. In describing the specific embodiments below, various specific contents have been prepared to more specifically describe the invention and help understanding. However, a reader having enough knowledge in this field to understand the present invention may recognize that it can be used without these various specific details. In some cases, it is mentioned in advance that parts which are commonly known and not largely related to the invention in describing the invention are not described in order to avoid confusion in describing the invention.

1 is a side view of a heatsink-attached lighting device according to an embodiment of the present invention, FIG. 2 is a front view of the heatsink-attached lighting device, and FIG. 3 schematically shows an exploded view of the heatsink-attached lighting device did

1 to 3 , a heat sink-attached lighting device according to an embodiment includes a heat sink assembly 100 , a COB (chip on board) 210 , a case 220 , and a protective cover 230 . can be The COB 210 is a package configured by mounting a light emitting member such as an LED on a substrate and filling a phosphor and an encapsulant thereon, and the upper surface of the heat sink assembly 100 (right surface of the heat sink assembly 100 in FIG. 1) can be attached to

The case 220 is a member configured to surround the periphery of the COB 210 and radiating light emitted from the light emitting member of the COB 210 in a specific direction or adjusting the radiation angle. In one embodiment, the case 220 may be configured to have a substantially cylindrical shape and a cross-sectional diameter to gradually increase in a direction away from the heat sink assembly 100 . The small-diameter end of the case 220 is coupled to the upper diffusion plate (110 in FIG. 4) and/or the side frame (180 in FIG. 4) of the heat sink assembly 100 to physically and can be thermally coupled.

A protective cover 230 may be attached to the large-diameter end of the case 220 by a known fastening part 225 . The protective cover 230 is configured to cover at least a portion of the case 220 and prevents the COB 210 from being polluted by foreign substances or from reducing the light emitting visibility of the COB 210 by sunlight, etc. .

Since a lot of heat is generated in the light emitting member of the COB 210 when such a lighting device 200 is used, it is necessary to rapidly radiate heat to the outside, and the heat sink assembly 100 according to an embodiment of the present invention is a COB ( 210) is configured to rapidly radiate heat generated from the light emitting member to the outside.

Hereinafter, a heat sink assembly (hereinafter also simply referred to as a “heat sink”) will be described with reference to FIGS. 4 to 10 .

4 is a perspective view of a heat sink assembly 100 according to an embodiment, FIG. 5 is an exploded perspective view, FIG. 6 is a cross-sectional view of an upper portion of the heat sink assembly, and FIG. 7 is a perspective view of an upper portion of the heat sink assembly.

4 to 7 , the heat sink assembly 100 according to an exemplary embodiment includes an upper diffusion plate 110 , a lower diffusion plate 120 , a first heat pipe 130 , and a second heat pipe 140 . , a heat dissipation fin unit 150 , an upper frame 160 , a lower frame 170 , and a side frame 180 .

For the purpose of describing the present invention, it is determined that the upper diffusion plate 110 side to which the COB 210 is attached is the upper portion of the heat sink assembly 100 and the lower frame 170 side is the lower portion of the heat sink assembly 100 . do it with

In one embodiment, the upper diffusion plate 110 is a member on which the COB 210 having the light emitting member is mounted on the upper surface, and is made of a thermally conductive material having a substantially disk shape. For example, the upper diffusion plate 110 may be made of a metal or alloy material having high thermal conductivity, and preferably made of aluminum.

As shown in FIG. 5 , the upper diffusion plate 110 includes a disk-shaped main body 111 and a plurality of coupling portions 112 extending in a radial direction from the main body 111 and protruding from the main body 111 . The coupling part 112 may include a first coupling part 112a and a second coupling part 112b having different widths. A through hole through which the coupling member 115 for coupling the upper diffusion plate 110 to the upper frame 160 passes may be formed in each coupling part 112 . The fastening member 115 may be, for example, a bolt, but this is exemplary, and it goes without saying that the upper diffusion plate 110 and the upper frame 160 may be coupled by various known coupling methods.

8 schematically illustrates a lower surface of the upper diffusion plate 110 according to an exemplary embodiment. As shown in FIG. 8 , one or more accommodating grooves 113 for accommodating the heat pipe are formed on the lower surface of the upper diffusion plate 110 . In one embodiment, each of the second heat pipes 140 may be accommodated in each of the receiving grooves 113 to be disposed in close contact with the upper diffusion plate 110 .

The lower diffusion plate 120 is, for example, a disk-shaped thermally conductive member attached to the lower surface of the upper diffusion plate 110 in close contact as shown in FIGS. 6 and 7 . The lower diffusion plate 120 may be made of a metal or alloy material having high thermal conductivity, and may be made of, for example, aluminum.

As shown in FIG. 9 , the lower diffusion plate 120 has a plurality of accommodating grooves 122 formed on its upper surface for accommodating the heat pipe. Each of the receiving grooves 122 is formed in a radially outward direction from the center of the lower diffusion plate 120 . In an embodiment, the horizontal section 130a of the first heat pipe 130 may be accommodated in each of the receiving grooves 122 to be disposed in close contact with the lower diffusion plate 120 .

The first heat pipe 130 and the second heat pipe 140 are members capable of transferring heat quickly and efficiently, and may be implemented as a known heat pipe. For example, each of the first and second heat pipes 130 and 140 has an empty space therein, and a working fluid, which is a heat transfer medium, is enclosed therein. When a high temperature is applied to a certain area of the heat pipe, the working fluid inside is vaporized to increase the internal pressure of that area, and the gas naturally flows to another area of low pressure to release heat and liquefy, and by repeating this flow, heat is generated. Heat from some high-temperature areas of the pipe can be transferred quickly to low-temperature areas.

The plurality of second heat pipes 140 are rod-shaped heat pipes having a predetermined length, and each of the second heat pipes 140 is received and coupled to the receiving groove 113 of the lower surface of the upper diffusion plate 110 . . Accordingly, as can be seen from FIGS. 6 and 7 , the side and upper surfaces of each of the second heat pipes 140 are in close contact with the upper diffusion plate 110 and are physically and thermally attached to the upper diffusion plate 110 , 2 The lower surface of the heat pipe 140 is physically and thermally attached to the upper surface of the lower diffusion plate 120 and the first heat pipe 130 in close contact.

By providing the second heat pipe 140 in this way, heat generated from the COB 210 attached to the upper diffusion plate 110 is transferred to the first heat pipe 130 below as well as the upper diffusion plate 110 . It can spread rapidly in the radial direction. That is, as shown in FIG. 8 , the accommodating grooves 113 accommodating each second heat pipe 140 are not formed in complete contact with each other, but are spaced apart regions 114 of a predetermined width between adjacent accommodating grooves 113 . ) exists. Accordingly, a portion of the heat of the upper diffusion plate 110 is horizontally diffused in the radial direction of the upper diffusion plate 110 along the second heat pipe 140 , and the remaining heat is transferred to the lower diffusion plate 120 through the separation region 114 . and the first heat pipe 130 , so that the plurality of second heat pipes 140 spaced apart from each other and disposed horizontally in this way transfer the heat of the upper diffusion plate 110 radially horizontally and downward (that is, , the lower diffusion plate 120 and the first heat pipe 130 side).

In the embodiment shown in Fig. 9, each of the first heat pipes 130 is composed of a horizontal section 130a and a vertical section 130b extending from the horizontal section 130a and bent vertically down to a predetermined length. can be The horizontal section 130a of the first heat pipe 130 is fitted into the receiving groove 122 of the lower diffusion plate 120 to be closely coupled. Accordingly, each horizontal section 130a of the plurality of first heat pipes 130 is disposed in a radial structure extending from the center 121 of the lower diffusion plate 120 in a radially outward direction and spaced apart from each other by a predetermined angle. are placed

The heat dissipation fin unit 150 is coupled to the vertical section 130b of the first heat pipe 130 . The heat dissipation fin unit 150 is a heat sink assembly centering on a coupling part 153 having a vertical through hole formed therein so that the vertical section 130b of the first heat pipe 130 is fitted and coupled thereto, and the coupling part 153 ( 100 , it may be composed of an outer heat dissipation fin 151 extending in a radially outward direction and an inner heat dissipation fin 152 extending in an inward direction. The outer heat dissipation fin 151 , the inner heat dissipation fin 152 , and the coupling part 153 may be integrally manufactured, and may be made of a lightweight metal material such as aluminum having high thermal conductivity and light weight.

The outer heat dissipation fin 151 is a substantially rectangular plate-shaped member, is vertically erected and integrally formed with the coupling portion 153, and extends radially outward. A plurality of through holes 154 are formed on the surface of each heat dissipation fin 151 to allow air to pass therethrough. In addition, in the illustrated embodiment, in order to increase the surface area of the heat dissipation fin, one outer heat dissipation fin 151 is spaced apart from each other and is vertically arranged side by side. . The first and second outer heat dissipation fins 151a and 151b have the same structure. The outer heat dissipation fin 151 may include a fastening hole 155 at an upper end thereof. In the illustrated embodiment, a first fastening hole 155a and a second fastening hole 155b are respectively formed at upper ends of the first outer heat dissipation fin 151a and the second outer heat dissipation fin 151b. A fastening member such as a bolt (165 in FIG. 5) can be fastened through the fastening hole 155, and thus the lower part of the upper frame 160 and the upper end of the heat dissipation fin unit 150 are integrated by the fastening member 165. can be combined.

In addition, although not shown in the drawing, a fastening hole (not shown) is also formed at the lower end of the outer heat dissipation fin 151, and each outer heat dissipation fin 151 is connected to the lower frame 170 by a fastening member such as a bolt (175 in FIG. 5). ) and can be integrally combined.

Meanwhile, in the embodiment of FIG. 9 , the inner heat dissipation fin 152 is a member of a substantially rectangular plate shape and is vertically erected to be integrally formed with the coupling portion 153 and extend radially inwardly. In the illustrated embodiment, one inner heat dissipation fin 152 is composed of a first inner heat dissipation fin 152a, a second inner heat dissipation fin 152b, and a third inner heat dissipation fin 152c that are spaced apart from each other and arranged vertically side by side. The surface area can be increased. In the illustrated embodiment, one inner heat dissipation fin 152 is composed of three heat dissipation fins 152a, 152b, and 152c, but the number of heat dissipation fins may vary depending on specific embodiments and the width of each heat dissipation fin (radially inward) It will be understood that the stretched length) may also vary.

Referring back to FIGS. 4 to 7 , in the illustrated embodiment, the upper frame 160 is a disk-shaped member having a plurality of penetrating regions formed on its surface. As shown in FIG. 5 , a first through region 162 having an inner diameter greater than that of the lower diffusion plate 120 is formed in the central portion of the upper frame 160 , and the through region 162 and the outer peripheral surface of the upper frame 160 . A plurality of second through-regions 163 having a small size are formed in the region therebetween. Due to the first through region 162 , the upper diffusion plate 110 and the lower diffusion plate 120 and the first and second heat pipes 130 and 140 interposed therebetween are not interfered by the upper frame 160 . and may be combined in close contact with each other. As shown in FIG. 4 or 6 , the outer heat dissipation fin 151 is located just below the second through area 163 , and thus air can flow to the outer heat dissipating fin 151 through the second through area 162 . .

Between the first through region 162 and the second through region 163 of the upper frame 160 , a fastening hole through which the fastening member 165 passes is formed, and each fastening hole is formed in each of the heat dissipation fin unit 150 . Corresponds to the fastening hole (155). Accordingly, the lower surface of the upper frame 160 and the upper end of the heat dissipation fin unit 150 may be integrally coupled by the fastening member 165 such as a bolt.

The lower frame 170 is a disk-shaped member having a plurality of penetrating regions formed on the surface thereof, and as shown in FIG. 5 , the first through region 172, the second A through region 172 and a third through region 174 are formed. The first through region 172 is formed in the central portion of the lower frame 170 , so that air may be introduced into the inner central portion of the heat sink assembly 100 .

A plurality of second through regions 173 and third through regions 174 are respectively formed along the circumferential direction. An outer heat dissipation fin 151 and an inner heat dissipation fin 152 are respectively positioned directly above the second through region 173 and the third through region 174 , so that air is discharged through the second and third through regions 173 and 174 , respectively. It can flow between (150).

Between the second through region 173 and the third through region 174 of the lower frame 170 , a fastening hole through which the fastening member 175 passes is formed along the circumferential direction, and the lower frame is formed by the fastening member 175 . The upper surface of 170 and the lower end of the heat dissipation fin unit 150 are integrally coupled.

The side frame 180 is a member connecting the upper frame 160 and the lower frame 170 . The heat sink assembly 100 may include a plurality of side frames 180 that are radially spaced apart from each other by a predetermined angle from the center.

In the illustrated embodiment, the side frame 180 may include a first side frame 180a having a relatively wide cross-sectional area and a second side frame 180b having a relatively narrow cross-sectional area. A pair of first side frames 180a may be disposed to face each other at a position symmetrical with respect to the central portion of the heat sink assembly 100, and the outer circumferential surface of the first side frame 180a is, for example, a bracket (250 in FIG. 3 ). ) and the heat sink assembly 100 may be installed in any external device or frame.

The upper and lower ends of the side frame 180 are respectively fastened to the upper frame 160 and the lower frame 170 by fastening members such as bolts. At this time, in the case of the upper side of the side frame 180 , the position is also aligned with the fastening hole of the radially extending coupling part 112 of the upper diffuser plate 110 , and thus the upper diffuser plate 110 is formed by the fastening member 115 . , the upper frame 160, and the side frame 180 may be integrally coupled.

Now, a heat dissipation path in the heat sink assembly according to an embodiment of the present invention will be described with reference to FIG. 10 . 10 schematically illustrates a portion of a side cross-section of the heat sink assembly 100 according to an exemplary embodiment.

As described above, the COB 210 is attached to the upper surface of the upper diffusion plate 110 , and the upper diffusion plate 110 and the lower diffusion plate 120 are closely coupled to each other. Also, the horizontal region 130a of the first heat pipe 130 and the second heat pipe 140 are interposed between the upper diffusion plate 110 and the lower diffusion plate 120 .

The upper frame 160 is coupled to the upper diffusion plate 110, the plurality of heat dissipation fin units 150, and the side frame 180 by fastening members 115 and 165, etc., as shown in FIG. 8, the upper frame 160 ) in full close contact with the lower surface of the upper diffusion plate 110, and the lower surface completely in close contact with the upper surface of the side frame 180 and the upper surface of the outer heat dissipation fin 151 to be physically and thermally coupled. . In addition, the lower surface of the lower frame 170 may be physically and thermally coupled to the lower surface of the side frame 180 and the lower surface of the heat dissipation fin unit 150 by means of fastening members 175 and 176 and the like.

According to this configuration, the heat sink assembly 100 of the present invention may flow the heat of the COB 210 to the lower side of the heat sink assembly 100 through at least two heat dissipation paths to radiate the heat to the outside. The first heat dissipation path is a path indicated by a dotted arrow in FIG. 10 , and the heat generated in the COB 210 is transferred to the heat dissipation fin unit 150 through the upper diffusion plate 110 and the first heat pipe 130 , and the outer heat dissipation fins After diffusion to the 151 and the inner heat dissipation fin 152, it may be discharged through heat exchange with air. In addition, some of the heat remaining in the heat dissipation fin unit 150 may be transferred to the lower frame 170 to be discharged as air from the lower frame 170 .

The second heat dissipation path is a path indicated by a solid arrow in FIG. 10, and the heat generated in the COB 210 first spreads in the upper diffusion plate 110 through the second heat pipe 140 in a radial and horizontal direction, and then in the upper frame ( 160 , and then heat is transferred from the upper frame 160 to the heat dissipation fin unit 150 and the side frame 180 , respectively. The heat transferred in this way may be heat-exchanged with air in the heat dissipation fins 151 and 152 and the side frame 180 to be discharged, and may also be transferred to some of the remaining lower frames 170 to be discharged from the lower frame 170 to the outside.

As described above, in the heat sink assembly 100 according to an embodiment of the present invention, all components constituting the assembly 100 , that is, the upper diffusion plate 110 , the lower diffusion plate 120 , and the first and second heat pipes. (130, 140), the heat dissipation fin unit 150, the upper frame 160, the lower frame 170, and the side frame 180 is configured to contribute to heat dissipation, so that the heat generated in the COB (210) at least two heat dissipation paths Accordingly, the heat of the COB 210 can be discharged more quickly and efficiently compared to the conventional heat sink structure because it can be rapidly moved to the lower side of the heat sink assembly 100 and discharged.

As described above, those of ordinary skill in the art to which the present invention pertains will understand that various modifications and variations are possible from the description of this specification. For example, in the illustrated embodiment, the upper and lower diffusion plates 110, 120, and upper and lower frames 160, 170, etc. of the heat sink assembly 100 are illustrated as having a substantially circular plane, but this is only an exemplary configuration. Of course, in some cases, the diffusion plates 110 and 120 or the frame may be formed in a rectangular plate shape. Therefore, the scope of the present invention should not be limited to the described embodiments and should be defined by the claims described below as well as the claims and equivalents.

100: heat sink assembly 110: upper diffuser plate
120: lower diffusion plate 130: first heat pipe
140: second heat pipe 150: heat dissipation fin unit
160: upper frame 170: lower frame
180: side frame 200: lighting equipment
210: chip on board (COB) 220: case
230: protective cover

Claims (3)

A heat sink-attached lighting device comprising:
a chip on board (COB) 210 having a light emitting member; and
and a heat sink assembly 100 physically and thermally attached to the COB to radiate heat generated from the light emitting member of the COB to the outside;
The heat sink assembly,
The COB 210 is mounted on the upper surface of the disk-shaped thermally conductive upper diffusion plate 110;
a disk-shaped, thermally conductive lower diffusion plate 120 attached to the lower surface of the upper diffusion plate 110;
A plurality of first heat pipes ( 130);
a plurality of second heat pipes 140 received in a receiving groove of a lower surface of the upper diffusion plate 110 and arranged side by side;
a heat dissipation fin unit 150 attached to each vertical section 130b of the plurality of first heat pipes 130;
an upper frame 160 having a disk shape having a plurality of through-regions formed on its surface and physically and thermally coupled to an upper portion of each of the plurality of heat dissipation fin units; and
A lower frame 170 having a disk shape having a plurality of penetrating regions formed on the surface and physically and thermally coupled to the lower portions of each of the plurality of heat dissipation fin units; includes;
Each of the horizontal sections 130a of the plurality of first heat pipes 130 is disposed in a radial structure extending radially outward from the center of the lower diffusion plate and spaced apart from each other by a predetermined angle;
The side and upper surfaces of each of the second heat pipes 140 are thermally coupled to each other in close contact with the upper diffusion plate 110 , and the lower surface of the second heat pipe 140 is connected to the lower diffusion plate 120 or the first heat pipe 140 . In close contact with the heat pipe 130 and thermally coupled,
Each of the heat dissipation fin units 150 includes a coupling portion 153 having a longitudinal through-hole through which the vertical section 130b of the first heat pipe is inserted and formed integrally with the coupling portion and radially outside. By including an outer heat dissipation fin 151 extending in the longitudinal direction, and an inner heat dissipation fin 152 integrally formed with the coupling portion and extending in the longitudinal direction from the inside radially,
A first heat dissipation path through which heat generated in the COB moves to the upper diffusion plate 110 , the first heat pipe 130 , the heat dissipation fin unit 150 , and the lower frame 170 , and a second heat pipe (140), the upper diffusion plate 110, the upper frame 160, the heat dissipation fin unit 150, and characterized in that heat is dissipated while moving along a second heat dissipation path moving to the lower frame 170 , Heatsink-attached lighting equipment. The method of claim 1,
Surrounding the periphery of the COB and characterized in that it further comprises a lighting device case 220 having a reflector for reflecting the light emitted from the COB in a predetermined direction, a heat sink-attached lighting device. 3. The method of claim 2,
The upper diffuser plate 110, the lower diffuser plate 120, and each heat sink unit 150 are made of aluminum, characterized in that the heat sink attached lighting device.

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