CN201892181U - LED bulb heat dissipation structure - Google Patents

Abstract

A heat dissipation structure for an LED-type bulb comprises: the heat dissipation assembly is provided with a first body, a heat dissipation part and a conductive part, the heat dissipation part is arranged on the outer side of the first body, and the conductive part is arranged at one end of the first body; the heat conducting assembly is provided with a second body, a heat conducting part and a heat conducting end, the second body is erected at one end of the first body opposite to the heat conducting part, the heat conducting end is connected to the first body, and the heat conducting part is arranged on the periphery of the second body and provided with a plurality of LED modules; therefore, the LED type bulb heat dissipation structure can not only improve the heat dissipation efficiency of the LED module, but also greatly improve the irradiation angle of the LED module.

Description

LED bulb heat dissipation structure

technical field

A heat dissipation structure of an LED light bulb, especially a heat dissipation structure of an LED light bulb that can achieve 360-degree illumination and also has a heat dissipation effect.

Background technique

LED has the characteristics of long life, power saving, small size, and no mercury pollution, which meets the needs of environmental protection. With the advancement of chip packaging technology, the application field has gradually expanded from indicator lights to lighting and panel backlighting.

LED generates "light" and "heat" by exciting the chip with input electric energy. As far as the current technology is concerned, the ratio of light and heat released is about 25%: 75% heat.

The light and heat of LED have two characteristics: the first is that its light is directional, its light emitting direction is hemispherical, and the irradiation angle of LED is about 20 degrees, so its direct light is the strongest, but the side light The light is weak; the second is that when its temperature is too high, it will cause light decay, so it is necessary to strengthen heat dissipation to maintain normal luminous flux.

There are two kinds of commonly used technology LEDs, one is LAMP type point light source package (plug-in type), and the other is SMD type point light source type package (surface mount type), which is divided into high power ( Operating current above 350mA) high-brightness LEDs, which emit strong light and high temperature, are mostly used in light bulbs or street lamps; and low-power (operating current 20mA-100mA) indicator LEDs, which emit weak light, are mostly used in signal lights or directions Indicator lights (such as traffic lights, vehicle direction lights).

Commonly used light bulb designs use this type of "point light source" LED. Their common disadvantages include the use of "indirect lighting" which reduces the brightness of the bulb, and the huge "radiator" limits the appearance of the bulb. , also increases the manufacturing cost, and when multiple low-current LEDs are connected in series and in parallel, the circuit is complex with many contacts, high failure rate, and poor stability, which does not meet the characteristics of long service life of LEDs. To sum up, LED bulbs of common technology The disadvantages are as follows:

1. Most light bulbs use high-power LEDs (above 350mA) to cover the "optical lens" and then attach them flat to the heat sink. The LEDs are covered with a "hemispherical" fog surface lamp shell to transfer the light emitted by the LEDs. The light is refracted by the "optical lens" to the "fogged lamp housing", and then refracted out of the lamp housing. This design is refracted twice for "indirect lighting". The refraction process will lose some brightness and is limited by the The "point" light source packaging method and the "hemispherical" lamp housing shape have a small light angle, and the lamp housing needs to be "matte" so that the lamp housing can produce the effect of refraction and slow emission. If you use a "transparent" lamp The shell cannot produce the refraction effect, so the limitation of the shell is one of the disadvantages of this type of design.

2. High-power LED bulbs will generate high temperature, so a large heat sink is needed to assist in heat dissipation, which affects the appearance of the bulb. The way to dissipate heat is to apply "thermal paste" under the LED and then fix it flat with screws. On the heatsink made of aluminum-zinc alloy casting or aluminum extrusion lathe, however, the "thermal paste" itself is a kind of silica gel, which has poor thermal conductivity and the heat dissipation effect is extremely limited, and the alloy casting or aluminum alloy Extruded heat sinks are bulky and cumbersome to manufacture, and a set of molds must be developed for each size or shape of LED bulbs, which takes a long time and high capital costs. Another shortcoming.

3. Light bulbs composed of low-power "indicating LEDs", because "indicating LEDs" are not originally designed for lighting, most of their external packaging materials are epoxy resin EPOXY, which cannot block ultraviolet rays, is easy to age, and is not resistant to High temperature and difficult heat dissipation lead to insufficient brightness attenuation, and when dozens or even hundreds of LEDs are connected in series or parallel, the circuit is complicated, there are many contacts, the failure rate is high, and the stability is poor.

Utility model content

The main purpose of the utility model is to provide a heat dissipation structure of an LED bulb that can achieve 360-degree illumination and has heat dissipation effect.

In order to achieve the above purpose, the utility model provides a heat dissipation structure for LED light bulbs. The heat dissipation structure for LED light bulbs includes: a heat dissipation component, a heat conduction component, and the heat dissipation component has a first body, a heat dissipation part, a Conductive part, the heat dissipation part is provided outside the first body, the conductive part is provided at one end of the first body; the heat conduction assembly has a second body, a heat conduction part, and a heat conduction end, the The second body stands upright from one end of the first body opposite to the conductive part, the heat conduction end is connected to the first body, the heat conduction part is provided on the peripheral side of the second body and is provided with a plurality of LED modules; therefore The heat dissipation structure of the LED light bulb can not only improve the heat dissipation efficiency of the LED module, but also improve the irradiation angle of the LED module; therefore, the utility model has the following advantages:

1. Nearly 360-degree irradiation angle;

2. Excellent cooling efficiency.

Description of drawings

Fig. 1 is the three-dimensional exploded view of the embodiment of the heat dissipation structure of the LED light bulb of the present invention;

Fig. 2 is a three-dimensional combination diagram of an embodiment of the heat dissipation structure of the LED light bulb of the present invention;

Fig. 3 is a diagram of the use state of the embodiment of the heat dissipation structure of the LED light bulb of the present invention.

[Description of main component symbols]

Heat dissipation structure of LED light bulb 1 First heat conducting surface 1221

Heat dissipation component 11 Second heat conduction surface 1222

The first body 111 The third heat conducting surface 1223

Heat dissipation part 112 The fourth heat conducting surface 1224

Conductive part 113 Heat conducting end 123

Conductive surface 1131 LED module 2

Conductive terminal 1132 LED bulb 21

Thread 1133 Substrate 22

Heat conduction component 12 Lamp holder 3

Second body 121 Orifice 31

Heat conduction part 122 Internal thread 32

Detailed ways

The above-mentioned purpose of the utility model and its structural and functional characteristics will be described according to the preferred embodiments of the accompanying drawings.

Please refer to Fig. 1 and Fig. 2, three-dimensional disassembly and assembly diagrams of the present utility model, as shown in the figure, the LED light bulb heat dissipation structure 1 of the present utility model includes: a heat dissipation component 11, a heat conduction component 12;

The heat dissipation assembly 11 has a first body 111, a heat dissipation portion 112, and a conductive portion 113, the heat dissipation portion 112 is arranged outside the first body 111, and the conductive portion 113 is arranged on the first body 111. one end.

The heat dissipation portion 112 is any one of a heat dissipation fin or a heat dissipation fin post. In this embodiment, a heat dissipation fin is used as an illustration, but it is not limited thereto.

The conductive portion 113 is connected to the heat dissipation portion 112 , and the conductive portion 113 further has a conductive surface 1131 and a conductive end 1132 , and the conductive surface 1131 has a plurality of threads 1133 .

The heat conduction assembly 12 has a second body 121 , a heat conduction portion 122 , and a heat conduction end 123 . The second body 121 stands on the end of the first body 111 opposite to the conduction portion 113 . It is disposed at one end of the second body 121 and connected to the first body 111 , and the heat conduction portion 122 is disposed at a peripheral side of the second body 121 and provided with a plurality of LED modules 2 .

The heat conduction part 122 also has a first heat conduction surface 1221, a second heat conduction surface 1222, a third heat conduction surface 1223, a fourth heat conduction surface 1224, and the first, second, third and fourth heat conduction surfaces 1221, 1222 , 1223, and 1224 are respectively provided with a plurality of LED modules 2, and the LED module 2 has at least one LED bulb 21 and a substrate 22. The LED bulb 21 is arranged on one side of the substrate 22, and the substrate 22 is attached to The heat conducting part 122 .

Please refer to FIG. 3 , which is a diagram of the use state of the utility model. As shown in the figure, when the LED-type light bulb heat dissipation structure 1 of the present invention is in use, the conductive part 113 of the heat dissipation assembly 11 is correspondingly screwed into a lamp holder 3, so that The lamp holder 3 has an orifice 31, the orifice 31 has a plurality of internal threads 32, and the plurality of threads 1133 through the conductive surface 1131 are correspondingly screwed into the internal threads 32 of the lamp holder 3, so that the heat dissipation The component 11 is fixed on the lamp holder 3, transmits power to the conductive part 113 through the lamp holder 3, and the conductive part 113 supplies the power to the LED module 2 for use. When the LED module 2 emits light Heat will be generated, and the LED module 2 transfers the heat to the heat dissipation component 11 through the heat conduction component 12 , and radiates the heat through the heat dissipation portion 112 of the heat dissipation component 11 .

In addition, because the LED module 2 is arranged on the heat conduction part 122 of the heat conduction component 12, and the heat conduction component 12 is connected with the heat dissipation component 11 in an upright manner, and the heat conduction part 122 has first, second 1, 3, and 4 heat conducting surfaces 1221, 1222, 1223, 1224. Therefore, because the LED module 2 is arranged on different heat conducting surfaces, the LED module 2 can achieve a wide-angle lighting effect.

To sum up, the LED light bulb heat dissipation structure of the present utility model can indeed achieve its efficacy and purpose when used, so the utility model is indeed a very practical creation, and it meets the application requirements for new patents, so it is legally Submit an application, and hope that the review committee will approve the case as soon as possible, so as to protect the hard work of the creator.

Claims (5)

1. a LED type bulb heat radiation structure is characterized in that, comprising:

A radiating subassembly has one first body, a radiating part, a conductive part, and described radiating part is located at described first body outside, and described conductive part is located at an end of described first body;

A heat-conductive assembly, have one second body, a heat-conducting part, a heat conduction end, described second body rises sheer from the other end of the opposite described conductive part of described first body, described heat conduction end connects described first body, and described heat-conducting part is located at all sides of described second body and is provided with plural led module.

2. LED type bulb heat radiation structure as claimed in claim 1 is characterized in that,

Described radiating part is radiating fin or heat radiating fin post.

3. LED type bulb heat radiation structure as claimed in claim 1 is characterized in that,

Described conductive part has a conducting surface, a conducting end, and described conducting surface connects described conducting end, and described conducting surface has plural screw thread

4. LED type bulb heat radiation structure as claimed in claim 1 is characterized in that,

Described heat-conducting part has one first thermal conductive surface, second thermal conductive surface, the 3rd thermal conductive surface, the 4th thermal conductive surface, and described first, second, third and fourth thermal conductive surface is respectively equipped with plural led module.

5. as claim 1 or 4 described LED type bulb heat radiation structures, it is characterized in that described led module has at least one LED bulb, a substrate.

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