DE102014105958A1 - LED lighting device and heat sink thereof - Google Patents

Abstract

In the case of an LED lighting device and its heat sink, the heat sink has a cooler structure for guiding an air flow, and the cooler structure comprises: a multiplicity of the heat-conducting rods which are arranged in rows at a distance from one another and on a rear side of an LED Lighting device are attached, each heat-conducting rod having an extension portion that extends horizontally on at least one side of the LED lighting device and a plurality of the surfaces; and a plurality of the cooling fin modules are fixed on two respective surfaces of each of the extension portions; each fin module has a plurality of the fins which are arranged spaced apart from one another, an air gap being formed between each two of the adjacent cooling fin modules and a fin channel between two of the adjacent fins such that air flows through these air gaps and the fin channels.

Description

BACKGROUND OF THE INVENTION

Field of the invention

The present invention relates to a heat sink, in particular to an LED lighting device and its heat sink.

Description of the Related Art:

During operation of the LED, about 80% of the total energy is transferred to the environment, in the form of waste heat. However, the high operating temperature can have a significant impact on the electronic components in terms of lifetime, product reliability and light loss.

A known LED lighting device comprises a printed circuit board and a plurality of the LED units, which are electrically connected to the circuit board. With the heat sink provided on the LED lighting device, the heat generated by the LED units can be dissipated through the heat sink, so that the life of the LED devices can be prolonged, the reliability of the LED devices can be increased, and the light loss of the LED units can be reduced.

Typically, however, most of the known heatsinks are aluminum extrusion type / aluminum extrusion or die cast aluminum type heatsink, or the back side of the LED lighting fixture is connected to a plurality of the fin header modules with heat pipes. Such constructions are inadequate in that they overlook the importance of the airflows and focus mainly on the surfaces of the cooling fins which tend to mislead the problem of poor heat dissipation of the LED lighting device without improving it.

Furthermore, the aluminum extrusion or cooling fin cooler can only allow the air to travel in the direction parallel to the ribs. If the heat sink is excessively large when z. For example, if the surface area of the heat sink is too large or too long, the air can not reach the center of the heat sink (i.e., the location of the heat generating unit), which has the effect that the heat dissipation can be greatly reduced. In order to solve this problem, it is a common practice to insert an incised slot in the direction perpendicular to the aluminum extrusion cooling fins, but the problem is not fully overcome by the limited effect of the insufficient width of the cut slot. On the other hand, if the width of the cut slit is too large, a large part of the surface of the cooling fins would be wasted for heat dissipation, which is not only difficult in practice, but also leads to a limited effect of heat dissipation.

In addition, the above heatsinks are only suitable for low power LED lighting fixtures and heatsinks. For high-power LED lighting devices (such as 1000 ~ 5000 W) today, they are clearly inadequate in view of the above problems, so there is a need for an improved heat sink suitable for high-power LED lighting devices is usable, and is able to effectively achieve heat dissipation.

OVERVIEW OF THE INVENTION

A first aspect of the present invention is to provide an LED lighting device and its heat sink capable of using the side wings, not only to extend outward from the LED lighting device, but also to allow the LED lighting device Air can flow up and down to dissipate heat to improve the problem of heat dissipation in LED lighting devices.

A second aspect of the present invention is to provide an LED lighting device and a heat sink thereof capable of forming air passages via a specific joining method and between two adjacent cooling fin modules to provide longitudinal and transverse intersections and cross-linking between Air ducts and rib channels in a manner similar to a chessboard, such that the radiator areas are increased, while the air can flow freely to all parts of the heat sink to increase the effect of heat dissipation.

A third aspect of the present invention is to stack an LED lighting device and its heat sink capable of stacking the heat sinks vertically one above the other layer by layer with increasing height, to increase the heat dissipation capacity and the requirements of the current LED lighting device to fulfill ever higher performances.

Accordingly, the present invention provides a heat sink comprising a condenser structure for air flows, and the condenser structure comprises: a plurality of the heat-conducting rods are arranged in a spaced-apart manner in rows; each of the plurality of thermally conductive rods further comprises an extension portion; each of the plurality of thermally conductive rods further comprises a plurality of surfaces; and a Plurality of cooling fin modules are fixed to two respective surfaces, the plurality of surfaces of each of the extension portions; and each of the fin modules includes a plurality of the ribs spaced apart from each other with an air gap formed between any two of the plurality of rib modules adjacent to each other and a fin channel between any two of the plurality of ribs adjacent to each other in that air flows longitudinally through the plurality of air gaps and the plurality of rib channels.

The present invention further provides an LED lighting device comprising: an LED lighting device; and a heat sink comprising a cooler structure for air streams. The radiator structure includes: a plurality of the heat conductive rods spaced apart in rows and fixed to a back side of the LED lighting device; wherein each of the plurality of heat conductive rods includes an extension portion extending horizontally on at least one side of the LED lighting device, each of the plurality of heat conductive rods further comprising a plurality of the surfaces; and a plurality of the fin modules are fixed to two corresponding surfaces of the plurality of surfaces at each of the extension portions, respectively; and each of the fin modules includes a plurality of the ribs spaced apart from one another, an air gap between any two of the plurality of fin rib modules adjacent to each other, and a fin channel between each two of the plurality of ribs adjacent to each other to each other, are formed so that air flows in the longitudinal direction through the plurality of air gaps and the plurality of rib channels.

Compared with the prior art, the present invention has the following merits: regardless of whether the radiator structure has a single-layer or double-layer structure, it can be used for heat dissipation side wing types to allow air to flow vertically therein to overcome the heat dissipation problem of the LED lighting device.

BRIEF DESCRIPTION OF THE DRAWINGS

1 Fig. 10 is an exploded view of the first embodiment of the LED lighting device of the present invention;

2 Fig. 10 is an exploded view of the second embodiment of the LED lighting device of the present invention;

3 is a perspective view of the arrangement of the present invention in 2 ;

4 is a side view of the present invention in 3 ;

5 Fig. 10 is a plan view of the second embodiment of the LED lighting device of the present invention;

6 Fig. 10 is a front view of the first and second embodiments of the LED lighting device of the present invention;

7 Fig. 10 is a front view of the third embodiment of the LED lighting device of the present invention;

8th Fig. 12 is a perspective view of the fourth embodiment of the LED lighting device of the present invention;

9 Fig. 10 is a front view of the fifth embodiment of the LED lighting device of the present invention;

10 Fig. 10 is a side view showing the adjustment of the illumination angles of the LED lighting device of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

Hereinafter, a detailed description will be given of embodiments of the present invention together with the accompanying drawings. It will be understood, however, that the appended figures are provided for illustrative purposes and should not be treated as limitations on the present invention.

The present invention provides an LED lighting device and a heat sink thereof. As in 4 For example, the LED lighting device includes an LED lighting device 1 and a heat sink 2 , The LED lighting device 1 either includes only one printed circuit board 11 with a variety of LED units 12 which are connected thereto, or further, a lamp housing 13 with the circuit board 11 inside the lamp housing 13 is arranged. That is, the circuit board 11 is flat on a front of the lamp housing 13 attached as shown in the figure. The light-emitting side of the lamp housing 13 can be further covered with lamp covers, which are shown without reference numerals. The LED lighting device 1 further comprises a rotation axis 14 (please refer 3 ).

1 shows a first version (see also 2 - 6 ) of the present invention. The heat sink 2 of the present invention a cooler structure 2a for airflows to achieve heat dissipation. The cooler structure 2a includes a plurality of thermally conductive rods 21 and a variety of cooling fin modules 22 ,

Each of the thermally conductive bars 21 includes a plurality of surfaces (may be flat thermally conductive bars, as shown in the figure) that include an upper surface and a lower surface. These thermally conductive rods 21 are spaced apart in rows and are at a rear side 131 the LED lighting device 1 attached arranged. Each of the thermally conductive bars 21 includes an extension section 211 which extends horizontally on at least one side of the LED lighting device 1 extends. In this embodiment, the heat-conducting rod comprises 21 further a further extension section 212 Standing horizontally on the other side of the LED lighting device 1 extends, and the extension section 211 and the other extension section 212 are arranged at two opposite ends.

Each of the cooling rib modules 22 includes a variety of ribs 221 , which are arranged at a distance from each other (see 3 and 5 ). An air gap 24 is between two of the cooling fin modules 22 formed adjacent to each other and a rib channel 225 is between two of the ribs 221 formed adjacent to each other, allowing air through these air gaps 24 and these rib channels 225 flows.

As in 1 shown, these are cooling fins modules 22 on the upper surface and the lower surface of each of the extension portions 211 and on the upper surface and the lower surface of each of the other extension portions 212 attached. Certainly, the cooling fins modules 22 also only on the upper surface or lower surface of the extension portion and the other extension portion 212 be attached as long as they provide sufficient heat dissipation. In other words, the first embodiment uses a rib module 22 attached to a thermally conductive rod 21 is attached. So applies to the second embodiment, shown in the 2 - 6 or for the third, fourth and fifth embodiments shown in FIG 7 - 9 that, though a ribbed module 22 with two adjacent thermally conductive rods 21 (as in 2 - 10 ), the present invention is not limited to such a configuration, and the second to fifth embodiments may all be a fin module 22 use a thermally conductive rod 21 to fix. In the following description of the second to fifth embodiments, the connection method will be with a fin module 22 that with a thermally conductive rod 21 is attached (as in 1 shown) used for illustration in a clear manner.

In the construction of the first and second embodiments, the air may flow in the longitudinal direction through the two side wings which face each other on the LED lighting device 1 are opposite. In other words, since the extension sections 211 and the other extension sections 212 located on the two opposite sides of the LED lighting device 1 with a variety of attached cooling rib modules 22 extend, not through the LED lighting device 1 can be blocked, it can be ensured that the air flows in the longitudinal direction, to facilitate the heat dissipation (due to the increase of hot air and the decrease of cool air), and to increase the effect of heat dissipation. Furthermore, it is not necessary the axis of rotation 14 perpendicular to the thermally conductive rod 21 to align, as in 5 It can also be at a different angle than 90 degrees with the thermally conductive rod 21 be aligned as long as the air flow is maintained in the longitudinal direction in order to flow smoothly either before or after the adjustment of the illumination angle can. For example, the direction of the ribs 221 , as in 5 shown perpendicular to the axis of rotation 14 (or parallel to the heat-conducting rod 21 ), therefore, as in 10 shown when the LED lighting device for an illumination angle with the axis of rotation 14 is adjusted, the entire surface of the ribs can 221 still be parallel to the longitudinal direction of the air flow so that the longitudinal air flowing through the rib channels 225 can flow without going through the ribs 221 blocked to facilitate heat dissipation.

One side of the ribs 221 can with a groove 222 be provided. In the first and second embodiments, the two grooves 222 at the lower left corner and the lower right corner of the two opposite sides of a rib 221 educated. The grooves 222 can have any shapes of cut-out sections. For example, as in 6 (the first and second embodiments) shown together with the 1 to 5 . 8th and 9 , the groove can 222 a rectangular cut-out section 2221 be. A rectangular cut-out section 2221 is at the lower left corner of one side of each rib 221 formed, and at the same time is another rectangular cut-out section 2221 at the lower right corner of the other side of the rib 221 formed, therefore, form four rectangular cut sections 2221 (please refer 6 ) a rectangular opening, and the plurality of openings are connected in series with each other to a rectangular air passage 223 to build. As in 7 (the third embodiment), the groove 222 also a sloped cut-out section 2222 be. A tilted cut-out section 2222 is at the lower left corner of one side of each rib 221 formed, and at the same time is another inclined cut-out section 2222 at the lower right corner of the other side of the rib 221 formed, therefore, four inclined cut sections 2222 a diamond or parallelogram aperture and the plurality of apertures are connected in series with each other to form a diamond or parallelogram air channel 224 to build. In an actual operation, the air ducts can 223 . 224 either through two of the rectangular cut-out sections 2221 or any two of the inclined cut-out sections 2222 be formed.

In detail, each of the cooling fin modules 22 on the upper surface or lower surface of the heat-conducting rods with the bottoms of all the ribs 221 connected in turn to either the rectangular air ducts 223 or the diamond or parallelogram air channels 224 with each of the grooves 222 between each of the four cooling fins modules side by side. Certainly, each of the extension sections 221s or each of the other extension sections 212 with the variety of cooling fin modules 22 be attached, and the cooling fins modules 22 from each of the thermally conductive rods 21 are arranged in a straight line, so the air channels 223 and 224 are fluidly connected in series, as shown in the figures, and, so that the upper surfaces or the lower surfaces of the extension portions 211 (or other extension sections 212 ) with two cooling rib modules 22 are connected parallel to each other. As in 1 and 2 along with 5 shown is the length of the cooling fins modules 22 greater than the width of the extension sections 211 . 212 so that the cooling fins modules 22 also include a protruding portion (not shown in the figure) extending outward from the heat conductive rods 21 protruding to allow the longitudinal flowing air to flow through, and to contact these protruding portions to facilitate the air, the heat from the protruding portions of the ribs 221 carry away for heat dissipation.

The thermally conductive rods 21 can directly to the back (not shown in the figure) of the circuit board 11 from the LED lighting device 1 be connected, and the extension sections 221 and the other extension sections 212 extend horizontally on two opposite sides of the circuit board 11 , Surely you can also use the back 131 (as in 4 shown and 6 ) of the lamp housing 13 from the LED lighting device 1 be connected and the extension sections 211 and the other extension sections 212 extend horizontally on two opposite sides of the lamp housing 13 , Such two choices can be the heat from the LED units 12 over the thermally conductive rods 21 to the cooling rib modules 22 transfer.

Further, as in 4 and 6 shown when the heat from the circuit board 11 to the heat-conducting lamp housing 13 is transferred, the heat, while attached to the large number of thermally conductive rods 21 and on to the cooling fin modules 22 is transferred, discharged. Because the cooling fins modules 22 on the upper and lower surfaces of the heat-conducting rods 21 are attached, and there are a large number of ribs 211 gives, the heat dissipation is increased. In addition, there are a variety of air channels 223 (or 224) with multiple rib channels 225 are cut and linked, the air can freely between the longitudinal and laterally intersecting air channels 223 (or 224 ) and rib channels 225 flow, in a manner similar to a chessboard, without obstacles, in other words, the air can pass unhindered through the heat sink 2 flow. Therefore, the radiator area and the effect of heat dissipation of the first, second and third embodiments of the present invention can be significantly increased, so that they for the LED lighting device 1 be improved with 1000 W power.

8th shows a fourth embodiment of the present invention, which is generally similar to that of the second embodiment and with a plurality of additional coolers. The cooler may be any type of cooler structure (not shown), which is certainly another fin module 22a the aforementioned rib module 22 can be. All cooling rib modules 22a are at the back 131 the LED lighting device 1 attached to improve the effect of heat dissipation.

9 shows a fifth embodiment of the present invention, which is similar to the second embodiment, and with an additional second layer, which also with columnar thermally conductive rods 23 connected is. As shown in the figure, the aforementioned heat sink comprises 2 the aforementioned light-emitting device structure 2a at a lower section, the other lighting device structure 2 B at an upper portion, and a plurality of the columnar heat conductive rods 23 are between the lighting device structure 2a , and the lighting device structure 2 B connected. The columnar thermally conductive rods 23 are vertical between the lighting device structure 2a and the other light-emitting structure 2 B connected. In addition, one end of the columnar thermally conductive rods 23 on an upper surface of the heat-conducting rods 21 the cooler structure 2a connected (and on an upper surface between the extension portion 211 and the other extension section 212 ). Another end of the columnar thermally conductive rods 23 is with a lower surface of the heat-conducting rods 21 the other radiator structure 2 B connected (and on a lower surface between the extension portion 211 and the other extension section 212 ).

Accordingly, there is a larger radiator area and a markedly improved effect of heat dissipation, so that higher working power (eg, 2000 ~ 5000 W, or even larger than 5000 W) is possible for the LED lighting device. Furthermore, the heat sink can 2 stacked on top of each other layer by layer with increasing height (such as a condenser structure with a height of three layers not shown in the figures), and the present invention is not limited to any number of the layers.

In view of the foregoing, the present invention includes the following advantages over the prior art: with the extensions of the LED lighting device 1 For example, the longitudinal air flow is able to achieve the lateral wing types of heat dissipation, to improve the effect of heat removal, and to overcome the problem of heat dissipation of the LED lighting device. In addition to the special bonding methods of thermally conductive rods 21 , Groove modules 22 and their ribs, the radiator area is significantly increased. Further, the intersecting and linking configuration is between the air channels 223 (or 224 ) and the rib channels 225 in a manner similar to a chessboard, which allows the air to pass freely into all parts of the heat sink 2 to substantially increase the effect of heat removal, so that the known problem of insufficient radiator area and lack of air, which makes it impossible to reach certain locations (such as the center of the heat sink), can be overcome ,

Further, the present invention has further advantages: by allowing the heat sink to be stacked on top of one another layer by layer with increasing height, its heat removal capacity can be further increased.

The preferred embodiments of the present invention set forth above are for illustrative purposes only and should not be treated as limitations upon the scope of the present invention. Structural modifications having equivalent properties derived from the content and the drawings of the description of the present invention are to be considered as part of the scope of the present invention.

Claims (15)

A heat sink comprising a cooler structure for air streams comprising cooler structure: a plurality of the heat conductive rods arranged in series with each other, each of the plurality of heat conductive rods includes an extension portion, each of the plurality of heat conductive rods further comprising a plurality of the surfaces, and a plurality of the fin modules associated with two corresponding surfaces of the plurality of surfaces of each of said extension portions, respectively, and each of the fin modules comprises a plurality of the cooling fins spaced from each other with an air gap between each of the two adjacent ones of the plurality of cooling fin modules, and a cooling fin channel is provided between each of the two adjacent ones of the plurality of cooling fins so that the air flows longitudinally through the plurality of air gaps and the plurality of cooling fin channels. The heat sink of claim 1, wherein each of the plurality of heat-conducting rods further comprises a further extension portion; the extension portion and the other extension portion are disposed at two opposite ends of each of the plurality of heat conductive rods; another plurality of the fin modules are also connected respectively to two corresponding surfaces of the plurality of surfaces of each of the other extension portions. The heat sink of claim 2, further comprising another radiator structure and a plurality of the columnar thermally conductive rods; the plurality of columnar thermally conductive rods are vertically mounted between the radiator structure and the further radiator structure; the two corresponding surfaces of each of the plurality of thermally conductive bars are an upper surface and a lower surface; one end of the plurality of columnar heat conductive rods is connected between the extension portion and the other extension portion of the radiator structure and on the lower surface of each of the plurality of heat conductive rods; another end of the plurality of columnar heat conductive rods is connected between the extension portion and the other extension portion of the radiator structure and on the upper surface of each of the plurality of heat conductive rods. The heat sink according to claim 1, wherein at least one side of each of said plurality of fins is grooved; and an air passage is formed through each of the grooves and between any two of the plurality of cooling fin modules that are adjacent to each other. A heat sink according to claim 4, wherein another side of each of said plurality of fins is also provided with a further groove; the one side and the other side of each of the plurality of ribs face each other, and another air passage is formed through each of the further grooves and between each four of the plurality of cooling fin modules adjacent to each other. The heat sink according to claim 4, wherein the groove of each of the plurality of ribs is a cut-out portion, the cut-out portion is formed between a side and a bottom of each of the plurality of cooling fins; Each of the plurality of cooling fin modules is connected to one of the two corresponding surfaces of the heat conductive rod to the bottom of each of the plurality of ribs. An LED lighting device comprising: an LED lighting device, and a heat sink with a cooler structure for the air streams; the cooler structure includes: a plurality of the heat-conducting rods disposed spaced apart in rows and connected to the back side of the LED lighting device; each of the plurality of heat conductive rods comprising an extension portion extending horizontally from at least one side of the LED lighting device, each of the plurality of heat conductive rods further comprising a plurality of surfaces; and a plurality of the fin modules each connected to two respective ones of the plurality of surfaces with each of the extension portions; and each of the fin modules comprises a plurality of ribs spaced apart from one another; wherein an air gap is formed between any two of the plurality of the fin modules adjacent to each other, and a fin channel is formed between any two of the plurality of ribs adjacent to each other so that air passes through the plurality of air gaps and the plurality of rib channels flow longitudinally. The LED lighting device according to claim 7, wherein each of the plurality of heat conductive rods includes an extension portion that extends horizontally on one side of the LED lighting device, wherein each of the plurality of heat conductive rods includes another extension portion extending horizontally on the other side the LED lighting device extends; the extension portion and the other extension portion are formed on two opposite sides of each of the plurality of heat conductive rods; another plurality of the fin modules are also connected to two respective surfaces of the plurality of surfaces of each of the extension portions, respectively. The LED lighting device according to claim 8, wherein the heat sink further comprises another radiator structure and a plurality of the columnar heat conductive rods, the plurality of columnar heat conductive rods are vertically connected between the radiator structure and the other radiator structure; the two opposite surfaces of each of the plurality of the electroconductive rods are an upper surface and a lower surface; one end of the plurality of columnar heat conductive rods is connected between the extension portion and the further extension portion of the radiator structure and on the lower surface of each of the plurality of heat conductive rods; another end of the plurality of columnar heat conductive rods is connected between the extension portion and the other extension portion of the radiator structure and on the upper surface of each of the plurality of heat conductive rods. The LED lighting device according to claim 7, wherein at least one side of each of the plurality of fins is grooved; and an air passage is formed through each of the grooves and between any two of the plurality of cooling fin modules that are adjacent to each other. The LED lighting device according to claim 10, wherein another side of each of the plurality of fins is also provided with another groove; the one side and the other side of each of the plurality of ribs face each other, and another air channel is formed through each of the further grooves and between each four of the plurality of cooling fin modules adjacent to each other. The LED lighting device according to claim 10, wherein the groove of each of the plurality of fins is a cut-out portion; the cut-out portion is formed between a side and a bottom of each of the plurality of cooling fins; each of the plurality of cooling fin modules is connected to one of the two corresponding surfaces of the heat conductive bar with the underside of each of the plurality of ribs. The LED lighting device according to claim 7, wherein the LED lighting device further comprises a printed circuit board; a plurality of the LED units are electrically connected to the circuit board; each of the plurality of thermally conductive bars are attached directly to the back of the circuit board; and the extension portion extends horizontally on at least one side of the circuit board. The LED lighting device according to claim 7, wherein the LED lighting device further comprises a lamp housing and a printed circuit board having a plurality of the LED units electrically connected thereto; the circuit board is fastened flat to a front side of the lamp housing; each of the plurality of heat-conducting rods is attached to a rear side of the lamp housing, and the extension portion extends horizontally on at least one side of the lamp housing. The LED lighting device according to claim 7, wherein the heat sink further comprises a plurality of coolers, each of the coolers being fixed to the back side of the LED lighting device.

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