TWM467819U - LED lighting device and heat dissipation device thereof - Google Patents

Description

LED lighting device and its radiator (1)

The present invention relates to a heat sink, and more particularly to an LED lighting device and a heat sink therefor.

During the LED illumination process, approximately 80% of the energy is transferred to the environment through waste heat. However, high temperature operating environments will impose restrictions on the use of electronic packaging components, including lifetime, product reliability, and light decay.

The conventional LED lighting assembly includes a circuit board and a plurality of LED components electrically connected to the circuit board, and the heat system generated by the LED component can be dispersed by the heat sink by using a heat sink disposed on the LED lighting component. Thereby extending the life of the LED component, improving the reliability of the LED component, and reducing the light decay phenomenon of the LED component.

However, in the conventional heat sink, an aluminum extruded or aluminum die-cast heat sink is mostly used, or a plurality of fin modules connected by a heat pipe are disposed on the back surface of the LED light emitting component. The blind spots of these designs pay too much attention to the area of the fins and neglect the importance of air circulation, which causes the problem of poor heat dissipation of the LED lighting components to be delayed.

Furthermore, aluminum extruded heat sinks or finned heat sinks can only be aired in a direction parallel to the fins. When the heat sink is too large, for example, if the area of the heat sink is too large or too long, the air cannot enter at all. The center of the heat sink (where the heating element is located) results in a significant reduction in heat dissipation. In order to solve this problem, the groove is generally perpendicular to the direction of the aluminum extruded fin, but this method cannot solve the problem completely, because if the width of the groove is not large enough, the effect is limited; If the width is too large, it will waste too much heat dissipation area of the fins. In addition to the high difficulty, the heat dissipation effect is still limited.

In addition, the above-mentioned conventional heat sink can only be applied to a low-power LED lighting component at most, and the LED lighting component which is increasingly high in power demand (for example, 1000-5000 watts) is obviously unapplicable, resulting in no high-power LED lighting component. A suitable heat sink can be used to dissipate heat.

One of the purposes of the present invention is to provide an LED lighting device and a heat sink thereof, which can improve the heat dissipation problem of the LED lighting assembly by extending from the LED lighting assembly and allowing the air to flow up and down.

The second purpose of the present invention is to provide an LED lighting device and a heat sink thereof, which can form a gas passage between any adjacent two fin modules by a special connection method, and the gas passage and the fin passage can be as a checkerboard. It is criss-crossed and connected to increase the heat dissipation area and allow air to circulate anywhere in the radiator, greatly improving the heat dissipation effect.

The third purpose of the present invention is to provide an LED lighting device and a heat sink thereof, which further enhances the heat dissipation capability by further superimposing the heat sink on the layer by layer according to the heat dissipation requirement, and is more suitable for the current power demand. The higher the LED lighting assembly.

In order to achieve the above object, the present invention provides a heat sink including a heat dissipation structure for air circulation, the heat dissipation structure comprising: a plurality of heat conducting rods spaced apart from each other and each of the heat conducting rods having a protruding portion, each of the heat conducting portions The rod also has a plurality of planes; and a plurality of fin modules are respectively connected to opposite planes of the planes of each of the protruding sections, and each of the fin modules comprises a plurality of fins spaced apart from each other, adjacent to two A finned space is formed between the fin modules, and a fin passage is formed between adjacent fins, and air flows longitudinally through the gas permeable spaces and the fin passages.

The present invention further provides an LED lighting device comprising: an LED lighting assembly; and a heat sink comprising a heat dissipation structure for air circulation. The heat dissipating structure comprises: a plurality of heat conducting rods spaced apart from each other and juxtaposed to the back surface of the LED lighting assembly, each of the heat conducting rods having a protruding portion horizontally extending from at least one side of the LED lighting assembly, each of the heat conducting rods Further having a plurality of planes; and a plurality of fin modules respectively connected to opposite planes of the planes of each of the protrusions, each of the fin modules including a plurality of fins spaced apart from each other, adjacent to the two A finned space is formed between the fin modules, and a fin passage is formed between adjacent fins, and air flows longitudinally through the gas permeable spaces and the fin passages.

Compared with the prior art, the present invention has the following effects: whether it is a single-layer or double-layer heat dissipation structure, it can be a side-wing heat dissipation that allows air to flow up and down, thereby improving the heat dissipation problem of the LED light-emitting component.

1‧‧‧LED lighting components

11‧‧‧ boards

12‧‧‧LED components

13‧‧‧Light shell

131‧‧‧Back

14‧‧‧ shaft

2‧‧‧heatsink

2a‧‧‧heating structure

2b‧‧‧Another heat dissipation structure

21‧‧‧Conducting rod

211‧‧‧Extension

212‧‧‧ another extension

22, 22a‧‧‧Fin module

221‧‧‧Fins

222‧‧‧ recess

2221‧‧‧Rectangular gap

2222‧‧‧ oblique gap

223‧‧‧ gas passage

224‧‧‧ gas passage

225‧‧‧Fin Channel

23‧‧‧column heat-conducting rod

24‧‧‧ Ventilation interval

The first figure is an exploded perspective view of the first embodiment of the inventive LED lighting device.

The second figure is an exploded perspective view of a second embodiment of the inventive LED lighting device.

The third figure is a three-dimensional combination diagram based on the second figure.

The fourth figure is a side view of the creation according to the third figure.

The fifth figure is a top view of the second embodiment of the inventive LED lighting device.

The sixth figure is a front view of the first and second embodiments of the inventive LED lighting device.

The seventh figure is a front view of the third embodiment of the inventive LED lighting device.

The eighth figure is a perspective view of a fourth embodiment of the inventive LED lighting device.

The ninth drawing is a front view of the fifth embodiment of the inventive LED lighting device.

The tenth figure is a side view showing the adjustment of the illumination angle of the LED lighting device.

In order to further understand the features, features and technical contents of the present invention, please refer to the following detailed description of the present invention and the accompanying drawings, which are only for reference and description, and are not intended to limit the present invention.

The present invention provides an LED lighting device and a heat sink thereof. As shown in the fourth figure, the LED lighting device includes an LED lighting assembly 1 and a heat sink 2, and the LED lighting assembly 1 can only include a plurality of LED components electrically connected. The circuit board 11 of 12 may further include a lamp housing 13 and the circuit board 11 is disposed in the lamp housing 13 (as shown in the figure, the circuit board 11 is flat on the front surface of the lamp housing 13), and the light emitting surface of the lamp housing 13 is also covered with A lampshade with no symbol. The LED lighting assembly 1 also has a rotating shaft (refer to the third drawing) 14.

As shown in the first embodiment (see also the second to sixth figures), the heat sink 2 of the present invention includes a heat dissipating structure 2a for dissipating heat by air circulation, and the heat dissipating structure 2a includes a plurality of heat conducting rods 21 and a plurality of Fin module 22.

The heat conducting rod 21 has a plurality of planes (which may be flat heat conducting rods as shown), including an upper plane and a lower plane (not labeled) opposite to each other. The heat conducting rods 21 are connected to the back surface 131 of the LED lighting assembly 1 in a side by side arrangement, and each of the heat conducting rods 21 has a protruding portion 211 extending horizontally from at least one side of the LED lighting unit 1. In the present embodiment, the heat conducting rod 21 also has another projecting section 212 horizontally projecting from the other side of the LED lighting assembly 1, and the projecting section 211 and the other projecting section 212 are opposed to each other.

The fin module 22 includes a plurality of fins (see FIG. 3 and FIG. 5) 221 spaced apart from each other, and a gas-permeable space 24 is formed between adjacent two fin modules 22, and a fin is formed between adjacent two fins 221 The sheet channels (see Figures 3 and 5) 225, the air is longitudinally circulated through the gas permeable spaces 24 and the fin channels 225.

As shown in the first figure, the fin modules 22 are respectively connected up-and-down oppositely to the upper plane and the lower plane of each of the protruding sections 211 and the upper and lower planes of the respective other protruding sections 212; of course, the fin mode The group 22 can also be connected only to the upper or lower plane (not shown) of the protruding section 211 and the other protruding section 212, as long as it is sufficient for heat dissipation, that is, the first embodiment is a fin module 22 Connected to a heat conducting rod 21. As for the second embodiment shown in the second to sixth embodiments or the third, fourth, and fifth embodiments shown in the seventh, eighth, and ninth views, respectively, a fin module 22 is connected to the adjacent one. The second heat conducting rod 21 (as shown in the second to the tenth figure), but the creation is not limited, the second to fifth embodiments can also be connected to a heat conducting rod 21 by a fin module 22 (not shown in the figure) In the following description of the second to fifth embodiments, the connection mode (as shown in the first figure) in which a fin module 22 is connected to a heat conducting rod 21 is also illustrated to simplify the explanatory text. Narration.

With the design of the first and second embodiments, air can be longitudinally circulated to the opposite side wings of the LED lighting assembly 1, that is, extending beyond the opposite sides of the LED lighting assembly 1 and connected with a plurality of fin modules. The protruding portion 211 of the group 22 and the other protruding portion 212 are not blocked by the LED lighting assembly 1, so that the longitudinal circulation of the air can be ensured to facilitate the heat dissipation (because the hot air rises, the cold air drops), and the heat dissipation is improved. efficacy. In addition, the rotating shaft 14 is not necessarily perpendicular to the heat conducting rod 21 as shown in the fifth figure, and may have an angle other than 90 degrees with the heat conducting rod 21, but in any case, as long as the lighting angle is adjusted before and after The longitudinally flowing air can flow smoothly. For example, since the direction of the fins 221 is perpendicular to the rotating shaft 14 as shown in the fifth figure (or both are parallel to the heat conducting rod 21), as shown in the tenth figure. It is shown that even though the LED illumination device adjusts the illumination angle by rotating its rotating shaft 14, the entire surface of the fin 221 is still parallel to the longitudinal flow direction of the air, and the longitudinally flowing air will still circulate from the fin passage 225 without being finned. 221 itself blocks, so that the heat can be carried out smoothly.

A recess 222 is defined in one side of the fin 221, and a recess 222 is defined in each of the opposite sides of the fin 221 in the first and second embodiments. The recess 222 can be a notch of various shapes, such as The six figures (first and second embodiments) are combined with the first to fifth figures and the eighth and ninth figures. The concave portion 222 can be a rectangular notch 2221, and between the opposite sides and the bottom edge of each fin 221 That is, each of the rectangular notches 2221 is formed, and the four rectangular notches 2221 (see FIG. 6) can be enclosed into a rectangular opening, and the plurality of openings are connected in series to form a rectangular gas passage 223; as shown in the seventh figure (third embodiment) The recess 222 can also be an oblique notch 2222. Each of the opposite sides and the bottom edge of each fin 221 is formed with a diagonal notch 2222, and the four oblique notches 2222 can be combined to form a diamond or a parallelogram. The openings, which are connected in series, are combined into a diamond-shaped or parallelogram-shaped gas passage 224. In actual operation, the gas passages 223, 224 may also be composed of only two rectangular notches 2221 or any two oblique notches 2222, but not shown.

In detail, each of the fin modules 22 is connected to the upper plane or the lower plane of the heat conducting rod 21 with the bottom edges of all the fins 221 thereof, so that any adjacent four fin modules 22 can pass through the respective recesses. 222 is formed with a rectangular gas passage 223 or a rhombic, parallelogram gas passage 224. Of course, each of the protruding segments 211 or each of the other protruding segments 212 can be connected to a plurality of fin modules 22, and each of the fin modules 22 of each of the heat conducting rods 21 is respectively located on each straight line, so that the gas passages 223 or 224 Also connected in series, as shown, the upper or lower surface of the extended section 211 (or another extended section 212) is connected to the two fin modules 22 in parallel. As shown in the first and second figures and in conjunction with the fifth figure, the length of the fin module 22 is greater than the width of the protruding portions 211, 212, so that the fin module 22 also has a protrusion protruding from the heat conducting rod 21 The portion (not shown) allows the longitudinally flowing air to circulate and contact the protruding portion, thereby facilitating the air to carry away the heat on the fins 221 of the protruding portion, thereby smoothly dissipating heat.

The heat conducting rod 21 is directly connected to the back surface of the circuit board 11 of the LED lighting unit 1 (not shown), and horizontally protrudes from the opposite sides of the circuit board 11 to the protruding portion 211 and the other protruding portion 212; The rear surface 131 of the lamp housing 13 (shown in Figures 4 and 6) of the LED lighting assembly 1 can be connected, and the protruding portion 211 and the other protruding portion 212 are horizontally protruded from opposite sides of the lamp housing 13, respectively. Both of these practices can conduct heat from the LED element 12 to the fin module 22 via the heat conducting rod 21.

In addition, as shown in FIGS. 4 and 6, when heat is conducted to the heat-conductive lamp housing 13 via the circuit board 11, the heat is transferred to the fin module 22 by a plurality of heat-conducting rods 21 for heat dissipation. At this time, since the fin module 22 is connected to the upper and lower planes of the heat conducting rod 21, the number of the fins 211 is large, so that the heat dissipating area is greatly increased; and most of the gas passages 223 (or 224) are coupled with the majority. The fin passages 225 are in cross-flow communication with each other so that air can arbitrarily flow between the gas passages 223 (or 224) and the fin passages 225, which are criss-crossed by the checkerboard, without any hindrance, that is, can flow anywhere in the radiator 2. In other words, the heat dissipation area and the heat dissipation effect of the first, second and third embodiments of the present invention will be improved a lot, and thus it is suitable for the LED lighting assembly 1 having a required power of, for example, about 1000 watts.

As shown in the eighth embodiment, the fourth embodiment of the present invention is substantially the same as the second embodiment, and only a plurality of heat dissipating members are further added. The heat dissipating member may be any heat dissipating structure (not shown), and of course For the other fin module 22a of the fin module 22, all the fin modules 22a are connected to the back surface 131 of the LED lighting assembly 1 to further improve the heat dissipation effect.

The fifth embodiment of the present invention, as shown in the ninth embodiment, is substantially the same as the second embodiment, and only the heat sink 2 is added to the two-layer arrangement and connected by the columnar heat-conducting rod 23. As shown in the figure, the heat sink 2 includes the lower heat dissipation structure 2a, the upper heat dissipation structure 2b, and a plurality of columnar heat conduction rods 23 connected between the heat dissipation structure 2a and the other heat dissipation structure 2b. An upright connection between the heat dissipation structure 2a and the other heat dissipation structure 2b, and one end of the columnar heat conduction rod 23 is connected to the upper surface of the heat conduction rod 21 of the heat dissipation structure 2a (and between the extension section 211 and the other extension section 212) The upper end of the columnar heat conducting rod 23 is connected to the lower plane of the heat conducting rod 21 of the other heat dissipating structure 2b (and is the lower plane between the protruding section 211 and the other protruding section 212).

Thereby, the heat dissipation area and the heat dissipation effect are doubled to be suitable for the LED lighting assembly 1 requiring higher power (for example, 2000 to 5000 watts or even 5000 watts or more). In addition, of course, the heat sink 2 can be layered up to the next layer (for example, three or more layers of heat dissipation structure, but not shown in the figure), the creation is not limited.

In summary, the present invention has the following effects compared with the prior art system: by extending from the LED lighting assembly 1 and allowing the air to circulate longitudinally, the side-wing heat dissipation method can improve the heat dissipation performance and improve the heat dissipation of the LED lighting assembly. problem. Moreover, by the connection of the special heat conducting rod 21, the fin module 22 and the fins 221, the heat dissipation area is greatly increased, and the gas passage 223 (or 224) and the fin passage 225 are like a checkerboard. Cross-crossing and cross-connecting each other, allowing air to circulate freely and flowing anywhere in the radiator 2, greatly improving the heat dissipation effect, thereby improving the conventional heat-dissipation area and preventing the air from entering a specific position of the radiator (for example, the center of the radiator). Missing.

In addition, the creative system has other functions: by superimposing the heat sink on the layer by layer, the heat dissipation capability can be further improved.

The above is only a preferred and feasible embodiment of the present invention, and thus does not limit the scope of the patent of the creation, and the equivalent structural changes that are made by using the present specification and the contents of the schema are all included in the creation. Within the scope of the rights, it is given to Chen Ming.

1‧‧‧LED lighting components

13‧‧‧Light shell

131‧‧‧Back

14‧‧‧ shaft

2‧‧‧heatsink

2a‧‧‧heating structure

21‧‧‧Conducting rod

211‧‧‧Extension

212‧‧‧ another extension

22‧‧‧Fin module

221‧‧‧Fins

222‧‧‧ recess

223‧‧‧ gas passage

225‧‧‧Fin Channel

24‧‧‧ Ventilation interval

Claims (15)

A heat sink includes a heat dissipation structure for air circulation, the heat dissipation structure comprising:
a plurality of heat conducting rods are juxtaposed to each other and each of the heat conducting rods has a protruding section, each of the heat conducting rods further having a plurality of planes; and a plurality of fin modules are respectively connected to the planes of each of the protruding sections Each of the fin modules includes a plurality of fins spaced apart from each other, and a gap between the two adjacent fin modules is formed, and a fin passage is formed between the adjacent fins. Air is longitudinally circulated through the gas permeable spaces and the fin passages. The heat sink of claim 1, wherein each of the heat conducting rods further has another protruding portion, and the protruding portion and the other protruding portion of each of the heat conducting rods are opposite to each other, and the fin modules are also Connected to opposite planes of the planes of each of the other extended segments, respectively. The heat sink of claim 2, further comprising another heat dissipating structure and a plurality of columnar heat conducting rods, the columnar heat conducting rods being erected between the heat dissipating structure and the other heat dissipating structure, each of the heat conducting rods The opposite two planes are an upper plane and a lower plane, and one end of the columnar heat conducting rods is connected to the lower side of each of the heat conducting rods of the heat dissipating structure between the protruding section and the other protruding section The other end of the columnar heat conducting rods is connected to the upper surface of each of the heat conducting rods of the heat dissipating structure between the protruding portion and the other protruding portion. The heat sink of claim 1, wherein at least one side of each of the fins defines a recess, and a gas passage is formed through each of the adjacent fin modules. The heat sink of claim 4, wherein the other side of each of the fins also has a recess, and the side and the other side of each of the fins are opposite to each other, and are adjacent to each other. A gas passage is formed between the fin modules through the recesses. The heat sink of claim 4, wherein the recess of each of the fins is a notch, and the notch is formed between a side edge and a bottom edge of each of the fins, and each of the fin modules is formed. The bottom edge of each of the fins is connected to one of the planes of the opposite planes of the heat conducting rod. An LED lighting device comprising:
An LED lighting assembly; and a heat sink comprising a heat dissipation structure for air circulation, the heat dissipation structure comprising:
a plurality of heat conducting rods are spaced apart from each other and juxtaposed to the back surface of the LED lighting assembly, each of the heat conducting rods having a protruding portion extending horizontally from at least one side of the LED lighting assembly, each of the heat conducting rods having a plurality of planes; And a plurality of fin modules respectively connected to opposite planes of the planes of each of the protruding segments, each of the fin modules comprising a plurality of fins spaced apart from each other, and adjacent to the two fin modules The interlayer forms a gas-permeable space, and a fin passage is formed between adjacent two fins, and air flows longitudinally through the gas-permeable spaces and the fin passages. The LED lighting device of claim 7, wherein each of the heat conducting rods has the protruding portion horizontally extending from a side of the LED lighting assembly, each of the heat conducting rods further having another light emitting component from the LED Another protruding portion extending horizontally from one side, the protruding portion of each of the heat conducting rods and the other protruding portion are opposite to each other, and the fin modules are also respectively connected to each of the other protruding portions The opposite two planes in these planes. The LED lighting device of claim 8, wherein the heat sink further comprises another heat dissipating structure and a plurality of columnar heat conducting rods, the columnar heat conducting rods being erected between the heat dissipating structure and the other heat dissipating structure, The opposite planes of each of the heat conducting rods are an upper plane and a lower plane, and one ends of the columnar heat conducting rods are connected to each of the protruding portion between the protruding portion and the other protruding portion. The lower end of the heat conducting rod, the other end of the columnar heat conducting rod is connected to the upper plane of each of the heat conducting rods of the heat dissipating structure between the protruding portion and the other protruding portion. The LED lighting device of claim 7, wherein at least one side of each of the fins defines a recess, and a gas passage is formed through each of the adjacent fin modules. The LED lighting device of claim 10, wherein the other side of each of the fins also has a recess, and the side and the other side of each of the fins are opposite to each other, and are adjacent to each other. A gas passage is formed between the fin modules through the recesses. The LED lighting device of claim 10, wherein the recess of each of the fins is a notch, and the notch is formed between a side edge and a bottom edge of each of the fins, and each of the fin molds is formed. The group is connected to one of the planes of the opposite planes of the heat conducting rod with the bottom edge of each of the fins. The LED lighting device of claim 7, wherein the LED lighting component comprises a circuit board electrically connected to a plurality of LED components, each of the heat conducting bars being directly connected to the back of the circuit board, and The protruding section is horizontally protruded from at least one side of the circuit board. The LED lighting device of claim 7, wherein the LED lighting component comprises a lamp housing and a circuit board electrically connected to the plurality of LED components, the circuit board is flatly attached to the front surface of the lamp housing, and each of the heat conduction The rod is coupled to the back of the lamp housing and extends horizontally from at least one side of the lamp housing. The LED lighting device of claim 7, wherein the heat sink further comprises a plurality of heat sinks, each of the heat sinks being coupled to a back surface of the LED lighting assembly.