KR102150662B1 - The heat sink for lighting apparatus - Google Patents

Abstract

A heat sink for a lighting apparatus according to the invention includes: a heat dissipating body in the form of a flat plate, receiving heat, emitting heat to the outside, and having a fitting hole through the upper surface thereof; and a coupling means for fixing a PCB, a heating electric element, or a heat radiation rib to the heat radiation body after being forcibly fitted in the fitting hole in the form of a rivet, wherein the coupling means includes a first cylindrical bolt coupling member, a first polygonal nut-type rotation preventing member, and a first bolt fixing hole. Therefore, it is effective in the installation, maintenance and prevention of loss of bolts or nuts installed on the heat sink, and effectively dissipates heat.

Description

Heat sink for lighting apparatus {The heat sink for lighting apparatus}

The present invention relates to a heat sink for a lighting device, and more particularly, to a heat sink for a lighting device to prevent deterioration of the lighting device or the heating electric element by emitting heat transmitted from the lighting device or the heating electric element.

In recent years, the use of energy-saving and eco-friendly LEDs (Light-Emitting Diodes) is increasing.

However, in the case of the LED, more than 50% of the supplied power is converted into thermal energy, and the temperature increase accordingly causes the light output to decrease and wavelength shift, and thus the lifespan of the LED is drastically reduced.

Accordingly, in the case of high-brightness, high-power lighting devices, such as security lights and street lights, to which power of tens to hundreds of watts is applied, a sophisticated heat dissipation design for securing luminous efficiency and reliability is required.

In general, the thermal path and thermal resistance of LED lighting is the internal thermal resistance of the packaging structure from the PN junction of the LED, the thermal resistance of the substrate from the soldering position to the PCB board, and the generated heat to the atmosphere. It consists of the heat resistance of the cooling device to radiate.

In general, in high-power LED lighting, an aluminum heat sink is used as a cooling device for dissipating heat conducted on a PCB substrate to the atmosphere.

However, the existing heat sink is a type of extruded aluminum or a shape that has been sharpened by cutting aluminum with a drill, and it is difficult to change the structure according to the heat dissipation conditions, and to control the amount of heat dissipation after installation, the entire heat sink must be replaced. There was a problem.

On the other hand, as the prior art of the present invention, the "high power LED lighting device with a magnesium extruded heat sink" of the application number "10-2012-0142674" has been applied and registered, but the high power LED lighting device having the magnesium extruded heat sink Has a substrate supporting at least one LED element, a plate-shaped base portion, a plurality of radiating fins having a plurality of stepwise cross-sections arranged in parallel with each other on one surface of the base portion and narrowing stepwise, and a material containing 90% or more of magnesium And a heat sink that is extruded into a furnace, a heat transfer plate interposed between the substrate and the heat sink and made of a material having a higher thermal conductivity than the heat sink, and a fastening bolt that passes through the substrate and the heat transfer plate and is fastened to the heat sink.

However, the high-power LED lighting device with the magnesium extruded heat sink is difficult to change in structure due to the heat sink that is extruded as an integral unit, and the entire heat sink must be replaced to adjust the amount of heat dissipation after installation. There was an inconvenience of having to make a screw tap after drilling the hole.

In addition, there was a problem that the electric circuit could be short due to metal powder generated when drilling a hole in the heat sink using an electric drill or processing the screw tap, and a minute gap was generated between the fastening bolt and the screw tap. There is a problem that heat dissipation efficiency may be lowered.

In addition, when drilling a hole in a heat sink using an electric drill or machining a thread tap, there was an inconvenience of having to grind the edge of the hole using a file or the like in order to remove the metal burr left on the surface.

In addition, when installing the board on the existing heat sink, there was a problem that the nut must be fastened to the tip of the bolt penetrating the heat sink, so that the nut may be lost during installation and repair. There was a problem that the circuit could be shorted.

Korean patent registration number "10-1427119" (2014.8.6)

Accordingly, an object of the present invention is to provide a heat sink for a lighting device capable of preventing the bolt or nut installed on the heat sink from being lost during installation or maintenance in order to solve the above problem.

Another object of the present invention is to provide a heat sink for a lighting device capable of effectively discharging heat generated from a lighting device or a heating electric element by increasing the thermal conductivity of the heat sink.

Another object of the present invention is to provide a heat sink for a lighting device capable of adjusting the heat dissipation performance of a heat sink according to the amount of heat generated.

Another object of the present invention is to provide a heat sink for a lighting device that can freely change the structure of the heat sink according to the structure or size of the outer case of the lighting device.

The heat dissipation plate for a lighting device according to the present invention for achieving the above object is a heat dissipating body in the form of a flat plate, receiving heat generated from a PCB or a heating electric element, emitting it to the outside, and having a fitting hole in the upper surface thereof; The fitting hole is forcibly fitted in the form of a rivet, and consists of a coupling means for fixing a PCB, a heating electric element, or a heat radiation rib to the heat radiation body, and the coupling means is a nut having a bolt fixing hole in the center. ) Shape, a bolt shape protruding to the upper or lower portion of the heat dissipating body, or a rod shape protruding to the upper or lower portion of the heat dissipating body, and one end of the coupling means and the fitting hole is processed into a polygonal shape, and the As a first embodiment, the coupling means includes a first cylindrical bolt coupling member in a cylindrical shape, and a first polygonal nut type integrally coupled with the first cylindrical bolt coupling member on the bottom surface of the first cylindrical bolt coupling member in a polygonal shape. A rotation preventing member and a first bolt fixing hole processed to a predetermined depth in the center of the upper surface of the first cylindrical bolt coupling member or passing through the first cylindrical bolt coupling member and the first polygonal nut-type rotation preventing member, and the fitting The hole is a first embodiment, the first circular hole processed to a predetermined depth so that the first cylindrical bolt coupling member is forcibly fitted to the upper surface of the heat dissipating body 1, and the first circular hole at the bottom of the heat dissipating body And a first polygonal hole processed to a predetermined depth so that the first polygonal nut-type rotation preventing member is forcibly fitted, and the fitting hole is a second circular shape penetrating the upper surface of the radiating body. As a second embodiment, the coupling means is a second cylindrical bolt coupling member through which a second bolt fixing hole is penetrated so that the bolt is fastened to an upper surface while being forcibly fitted into the second circular hole.

The heat sink for a lighting device according to the present invention having such a structure has an effect of preventing the bolt or nut installed on the heat sink from being lost during installation or maintenance.

The present invention has the effect of effectively discharging heat generated from a lighting device or a heating electric element by making the coupling means in close contact with the heat dissipating body.

The present invention has the effect of adjusting the heat dissipation performance of the heat dissipation plate by adding or removing the heat dissipation rib according to the amount of heat generated by the PCB or the heating electric element even after the heat sink is installed.

In addition, a PCB, a heating electric element, or a heat radiation rib can be freely disposed on the heat dissipating body regardless of a predetermined position, and when installing a PCB, a heating electric element or a heat radiation rib on the heat radiation body, either a nut or a bolt is fastened to the coupling means. As it is done, it has the effect of reducing the weight of the product.

By forcibly inserting the coupling means only at a predetermined position on the heat dissipating body, there is an effect of preventing the installation position of the PCB or the heating electric element or the heat dissipating rib installed on the heat dissipating body from being changed due to an error of an operator.

1A is an upper perspective view of a heat dissipating body in which a coupling means is installed.
1B is a lower perspective view of a heat radiation body in which a coupling means is installed.
Figure 2 is an exemplary view showing an embodiment of the coupling means.
3A and 3B are exemplary views for explaining a first embodiment of a coupling means.
Figure 4 is an exemplary view for explaining a second embodiment of the coupling means.
5 is a combined state diagram showing a state in which the heat radiation ribs are coupled to the heat radiation body.
6 and 7 are perspective views of heat dissipation ribs.
Fig. 8 is an exemplary view showing a state in which fixing pieces provided on a pair of heat dissipating ribs abut each other.
Figure 9 is an exploded perspective view for showing the coupling of the coupling means.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figures 1a and 1b, the heat sink for a lighting device according to the present invention receives heat generated from a PCB or a heating electric element in the form of a flat plate, emits it to the outside, and has a fitting hole 11 having a shape penetrated on a plane. The formed heat dissipation body 1 and the fitting hole 11 are forcibly fitted in a rivet shape to be fixedly coupled to the body 1 to form an integral body, and a PCB, a heating electric element, or a heat dissipation rib 3 It consists of a coupling means (2) for fixing.

In more detail, one end of the coupling means 2 is formed larger than the inner diameter of the fitting hole 11 formed in the heat dissipating body 1, and is fixedly coupled to the heat dissipating body 1 when forced to be fitted to the heat dissipating body ( It is to be able to be integrated with 1).

This is to more efficiently dissipate heat generated from a device that requires heat dissipation through mechanical coupling through force-fitting the heat dissipation body 1 of a conventional metal material and the coupling means 2 of the same metal material, In addition, when the device is coupled to the heat dissipating body 1 serving as a heat sink, it is intended to be in close contact without being spaced apart.

In addition, as shown in Figure 2, the coupling means 2 has a nut shape in which a bolt fixing hole of a predetermined depth is processed in the center, or a bolt protruding upward or downward of the heat dissipating body 1 ( Bolt) shape or a rod shape protruding from the top or bottom of the heat dissipation body (1).

One end of the coupling means 2 and the fitting hole 11 is processed into a polygonal shape so that the coupling means 2 is not rotated when a bolt or nut is fixed to the fitting hole 11.

As in the first embodiment shown in FIGS. 3A and 3B, the coupling means 2 includes a first cylindrical bolt coupling member 21 in a cylindrical shape, and the first cylindrical bolt coupling member 21 in a polygonal shape. The first polygonal nut-type rotation preventing member 22 integrally coupled with the first cylindrical bolt coupling member 21 on the bottom surface, and the first cylindrical bolt coupling member 21 are processed to a predetermined depth in the center of the upper surface or the A first cylindrical bolt coupling member 21 and a first bolt fixing hole 221 passing through the first polygonal nut-type rotation preventing member 22 may be formed.

In addition, the fitting hole 11 has a predetermined depth so that the first cylindrical bolt coupling member 21 is forcibly fitted to the upper surface of the heat dissipating body 1, as in the first embodiment shown in FIGS. 3A and 3B. The processed first circular hole 111 is communicated with the first circular hole 111 on the bottom of the heat dissipating body 1 and the first polygonal nut-type rotation preventing member 22 is forcibly fitted to a predetermined depth. It includes the processed first polygonal hole 112.

The cross section of the first polygonal nut-shaped rotation preventing member 22 and the first polygonal hole 112 has a planar shape surrounded by three or more line segments.

In addition, the fitting hole 11 is a second circular hole 113 penetrating the upper surface of the heat dissipating body 1, as in the first embodiment shown in FIG. 4, and the coupling means 2 2 It is a second cylindrical bolt coupling member 23 through which the second bolt fixing hole 231 is inserted into the circular hole 113 and the bolt is fastened to the upper surface thereof.

At the top of the heat dissipation body 1, as shown in Fig. 5, two or more heat dissipation ribs 3 for externally discharging heat transferred from the heat dissipation body 1 in a'L' shape are mounted, and the heat dissipation On the bottom of the main body 1, a PCB or a heating electric element is mounted.

The heat dissipation rib 3 has a heat dissipation piece 31 erected in a vertical direction of the heat dissipation body 1 in a flat plate shape, and an upper surface of the heat dissipation main body 1 in a flat plate shape, as shown in Figs. Consisting of a fixing piece 32 that faces and has one end fixedly coupled to the lower end of the radiating piece 31 and fixedly coupled to the upper surface of the radiating body 1 through the coupling means 2, the fixing piece 32 The other end (A) of) is inclined in the form of an inclined plane.

The angle between the heat dissipation piece 31 and the fixing piece 32 is 90 degrees.

As shown in Figure 6, the heat dissipation piece 31 is provided with two or more heat dissipation blades 311 protruding to the front of the heat dissipation piece 31, and one side of the heat dissipation blade 311 is '1 A'shape-shaped heat dissipation slit hole 312 (Slit Hole) is passed through.

The heat dissipation blade 311 provided in the heat dissipation piece 31 increases the heat dissipation efficiency of the heat dissipation piece 31 by increasing a contact area with air, and the heat dissipation slit hole 312 is formed from the heat dissipation body 1 The heat transferred to the heat dissipation piece 31 is discharged to the outside through the heat dissipation slit hole 312, and external air can enter and exit through the heat dissipation slit hole 312. The heat dissipation efficiency can be increased.

The left and right sides of the heat dissipation piece 31 are processed to be concave to prevent the hand from being cut when the left and right sides of the heat dissipation piece 31 are held by hand, and to facilitate gripping of the heat dissipation piece 31.

In addition, as shown in Fig. 8, the other end (A) of the fixing piece 32 inclined in an inclined shape while being provided in any one of the heat dissipation ribs 3 of a pair of adjacent to each other While being fitted to one heat dissipation rib 3, the other end (A) of the fixing piece 32 inclined in the form of an inclined face and face each other.

Such a structure can increase the heat dissipation efficiency of the heat dissipation plate for the lighting device by allowing a plurality of heat dissipation ribs 3 to be densely disposed in a limited space of the heat dissipation body 1.

In addition, two or more fixing holes 321 are passed through the fixing pieces 32 provided in the heat dissipation ribs 3, and the fixing holes 321 are fitted to the upper end of the coupling means 2.

As shown in Fig. 9, the heat dissipation body 1 is fixed through the heat dissipation body 1 and a third bolt is fixed to the bottom of the heat dissipation body 1 in order to bolt a PCB or a heating electric element to the bottom of the heat dissipation body 1 The hole 421 further includes a heat source coupling means 4 processed.

As shown in FIG. 9, the heat source coupling means 4 is integrally coupled with the cylindrical interference fitting member 41 on the bottom surface of the cylindrical interference fitting member 41 and the bottom surface Including a second polygonal nut-type rotation preventing member 42 processed with a third bolt fixing hole 421, and the PCB or the heating electric element is radiated by a bolt fastened to the third bolt fixing hole 421 It is fixedly coupled to the bottom of the body (1).

In addition, a third circular hole 114 of a predetermined depth is processed so that the cylindrical interference fitting member 41 is forcibly fitted in the front surface of the heat dissipating body 1, and the third circular hole 114 is formed on the rear surface of the radiating body 1 The second polygonal hole 115 having a predetermined depth is processed to communicate with the hole 114 and to force the second polygonal nut-type rotation preventing member 42 to be inserted.

A cross section of the second polygonal nut-shaped rotation preventing member 42 and the second polygonal hole 115 has a planar shape surrounded by three or more line segments.

The heat sink for a lighting device according to the present invention having such a structure can prevent a bolt or nut installed on the heat sink from being lost during installation or maintenance.

In addition, according to the present invention, the coupling means 2 may be closely fixed to the heat dissipating body 1 so that heat generated from a lighting device or a heating electric element can be effectively discharged.

In addition, the present invention can adjust the heat dissipation performance of the heat dissipation plate by adding or removing the heat dissipation rib 3 according to the amount of heat generated by the PCB or the electric heating element even after the heat dissipation plate is installed.

In addition, a PCB, a heating electric element, or a heat radiation rib can be freely disposed on the heat dissipation body 1, regardless of a predetermined position, and it is combined when a PCB, a heating electric element or a heat radiation rib 3 is installed on the heat radiation body 1 It is possible to reduce the weight of the product by fastening either a nut or a bolt to the means (2).

In addition, by forcibly inserting the coupling means (2) only at a predetermined position on the heat dissipation body (1), it is possible to prevent the installation position of the PCB, heating electric element or heat dissipation rib installed on the heat dissipation body (1) due to operator error. I can.

1. Heat dissipation body 11. Fitting hole
111. 1st circular hole 112. 1st polygonal hole
113. The 2nd Round Hole 114. The 3rd Round Hole
115. Second polygonal hole 2. Combining means
21. First cylindrical bolt coupling member 211. First bolt fixing hole
22. The first polygonal nut type rotation preventing member 23. The second cylindrical bolt coupling member
231. Second bolt fixing hole
3. Radiation rib 31. Radiation piece
311. Radiation wing 312. Radiation slit hole
32. Fixing piece 321. Fixing hole
4. Heat source coupling means 41. Cylindrical force-fitting member
42. The second polygon nut type rotation preventing member 421. The third bolt fixing hole

Claims (5)

A heat dissipation body (1) in a flat plate shape, receiving heat generated from a PCB or a heating electric element, and discharging it to the outside, and having a through hole (11) formed therein;
The fitting means (2) is forcibly fitted into the fitting hole (11) in the form of a rivet and is fixedly coupled to the heat dissipating body (1) to be formed integrally, and to fix the PCB or the heating electric element or the heat radiating rib (3) ), but
The coupling means (2) is a nut shape in which a bolt fixing hole is machined in the center, a bolt shape protruding from the top or bottom of the heat dissipation body 1, or the upper part of the heat dissipation body 1 Or a rod-shaped protruding downward, in order to efficiently dissipate heat generated from the heat dissipation body (1), one end of the coupling means (2) is less than the inner diameter of the fitting hole (11) formed in the heat dissipation body (1) It is formed large and is fixedly coupled to the heat dissipation body (1) when it is forcibly fitted, and is constituted integrally with the heat dissipation body (1), so that the PCB, the heating electric element, or the heat dissipation rib (3) can be freely arranged regardless of the predetermined position. A heat sink for a lighting device, characterized in that the weight of the product can be reduced by allowing either a nut or a bolt to be fastened to the means (2).
delete The method of claim 1,
One end of the coupling means (2) and the fitting hole (11) is a heat sink for a lighting device, characterized in that processed into a polygonal shape.
The method of claim 1,
The coupling means (2) comprises a first cylindrical bolt coupling member (21) in a cylindrical shape,
A first polygonal nut-shaped rotation preventing member 22 integrally coupled with the first cylindrical bolt coupling member 21 on the bottom surface of the first cylindrical bolt coupling member 21 in a polygonal shape,
And a first bolt fixing hole processed to a predetermined depth in the center of the upper surface of the first cylindrical bolt coupling member 21 or passing through the first cylindrical bolt coupling member 21 and the first polygonal nut-type rotation preventing member 22. Consists of (221),
The fitting hole 11 includes a first circular hole 111 processed to a predetermined depth so that the first cylindrical bolt coupling member 21 is forcibly fitted to the upper surface of the heat dissipating body 1,
A first polygonal hole 112 processed to a predetermined depth so that the first polygonal nut-type rotation preventing member 22 is forcibly inserted into the lower surface of the heat dissipating body 1 A heat sink for a lighting device, characterized in that the.
The method of claim 1,
The fitting hole 11 is a second circular hole 113 penetrating the upper surface of the radiating body 1,
The coupling means (2) is a second cylindrical bolt coupling member (23) through which the second bolt fixing hole (231) is forcibly fitted into the second circular hole (113) so that the bolt is fastened to the top surface. Heat sink for lighting devices.

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