KR101297106B1 - ＬＥＤ lighting apparatus - Google Patents

Abstract

An LED lighting apparatus according to the present invention, a light emitting unit having a substrate and an LED element provided on one surface of the substrate; A heat spreader fixed to the other surface of the substrate to disperse heat generated from the light emitting unit; A heat pipe unit coupled to the heat spreader to radiate heat; And an air cooling unit configured to cool by injecting air into the heat pipe unit.

Description

LED lighting apparatus

The present invention relates to an LED lighting apparatus, which emits light through the LED element.

In general, a lighting lamp converts electric energy into light energy, and is used to provide light or illuminate an object to identify an object at night or indoors or outdoors. In recent years, lighting is used for interior decoration or various colors , Incandescent lamps, fluorescent lamps, halogen lamps, metal halides, mercury lamps, and sodium lamps.

However, incandescent lamps are cheap, but their life is short, their luminous efficiency is low, their brightness is high, they cause glare, generate a lot of heat, and fluorescent lamps have higher energy efficiency than incandescent lamps, , The life span is short. In addition, sodium, mercury, and metal halides have high power consumption, can cause glare, and have a short life span.

Due to the above problems, recently, a lamp using a light emitting diode (LED) capable of obtaining semi-permanent, low power consumption and high efficiency illuminance has been developed for various uses.

LED lighting has advantages such as high processing speed and low power consumption, and it is increasingly being used because it is environmentally friendly and energy efficient. In addition, the LED lamps use 60 ~ 80% less power than ordinary lamps, have a semi-permanent lifetime of more than 50,000 hours, and are gaining popularity as lighting because they do not cause glare.

However, since such LED lamps use a large number of LEDs mounted on a printed circuit board, a large amount of heat is generated. Therefore, when the LED lamp is not discharged or removed from the inside smoothly for a certain period of time, the efficiency is lowered. In use, there is a problem that the life is shortened.

Republic of Korea Patent Registration No. 10-727856

The present invention has been made to solve the above problems, and an object thereof is to provide an improved LED lighting device to increase the cooling efficiency.

In order to achieve the above object, an LED lighting apparatus according to a preferred embodiment of the present invention, a light emitting unit having a substrate, and an LED element provided on one surface of the substrate; A heat spreader fixed to the other surface of the substrate to disperse heat generated from the light emitting unit; A heat pipe part coupled to the heat spreader and having a heat pipe extending outwardly; And an air cooling unit configured to cool by injecting air into the heat pipe unit.

Herein, the heat pipe part and the air cooling part are sequentially disposed from the heat spreader to the opposite side of the light emitting part, and the air cooling part includes a cover provided on the air spreader to cover the heat pipe part; And an air flow member for flowing air into the heat pipe part in the cover.

The heat pipe part may include a plurality of first heat pipes positioned at a central portion of the heat spreader; And a plurality of second heat pipes formed longer than a length of the first heat pipes and disposed around the plurality of first heat pipes, wherein the air flow member comprises: the second heat pipes inside the second heat pipes; A pumping member disposed on one heat pipe to pump air; And an air passage communicating with the pumping member and extending onto the second heat pipe to allow air to flow in a longitudinal direction with respect to the second heat pipe.

In addition, the air flow member is preferably configured such that the air discharge speed is faster than the air suction speed.

On the other hand, the present invention may further include a copper coating portion installed to increase the heat transfer efficiency between the substrate and the heat spreader.

In the LED lighting apparatus according to the present invention, by flowing the air in the longitudinal direction from the upper side with respect to the heat pipe portion by the air flow member, the copper is coated between the substrate and the heat spreader to increase the heat transfer efficiency, which is generated from the light emitting portion The cooling efficiency of heat can be improved. Accordingly, an organic component such as an insulator has an effect of preventing lifespan from being shortened in a high temperature environment due to changes in characteristics of the component according to temperature, such as causing aging at a high temperature. In addition, the mechanical strength is changed due to the temperature rise, thermal stress is generated, the dimensional change due to thermal expansion can be prevented from occurring, and furthermore, it can be prevented from causing discomfort due to the high temperature exhaust air.

1 is a longitudinal sectional view schematically showing an LED lighting apparatus according to a preferred embodiment of the present invention.
FIG. 2 is a perspective view illustrating the heat spreader, the heat pipe part, and the air cooling part of FIG. 1.
3 is a view showing that air flows from the air flow member to the heat pipe part in the LED lighting apparatus of FIG.
4 is an enlarged view illustrating A of FIG. 1.

1 is a longitudinal sectional view schematically showing an LED lighting apparatus according to a preferred embodiment of the present invention, Figure 2 is a perspective view showing the heat spreader, heat pipe portion, air cooling of Figure 1, Figure 3 LED lighting of Figure 1 Figure 4 shows the flow of air from the air flow member to the heat pipe section in the apparatus, Figure 4 is an enlarged view of A of FIG.

Referring to the drawings, the present invention provides a light emitting unit 20 having an LED element 22, a heat spreader (40) for dispersing heat of the light emitting unit 20, the heat spreader 40 A heat pipe part 60 that is coupled but has a heat pipe extending outwardly; And an air cooling unit 80 configured to cool by spraying air to the heat pipe part 60.

The light emitting unit 20 includes a substrate 21 and an LED element 22 provided on one surface of the substrate 21. In the light emitting unit 20, the substrate 21 is fixedly coupled to the other surface of the substrate 21 in contact with the heat spreader 40.

In addition, the present invention may further include a lens 90 provided at the edge of the heat spreader 40 to cover the light emitting unit 20.

The heat spreader 40 is fixed to the other surface of the substrate 21 and serves to disperse heat generated from the light emitting unit 20.

In addition, the present invention may further include a heat pipe unit 60 and an air cooling unit 80 together with the heat spreader 40.

The heat pipe part 60 is provided as a plurality of heat pipes to be in contact with the heat spreader 40 to dissipate heat, and the air cooling part 80 is configured to cool by injecting air into the heat pipes. .

Specifically, the heat pipe part 60 and the air cooling part 80 are sequentially disposed from the heat spreader 40 to the opposite side of the light emitting part 20.

Here, the heat pipe part 60 is formed with a plurality of first heat pipes 61 and a length longer than the length of the first heat pipes 61 positioned in the center portion of the heat spreader 40 A plurality of second heat pipes 62 arranged around the first heat pipe 61 may be provided.

In addition, the air cooling unit 80 includes a cover 81 installed in the heat spreader 40 to cover the heat pipe part 60, and allows air to flow from the cover 81 to the heat pipe part 60. An air flow member 82 may be provided.

At this time, the air flow member 82 utilizes a pumping member 82a having a lung structure as an example. The pumping member 82a sucks air in an up and down motion and discharges the air sucked into the inside. It is operated so that the air sucked from the outside is discharged with a predetermined pressure.

Here, the pumping member 82a may use SYNJET ^® manufactured by Nuventix.

The pumping member 82a serves to cool the light emitting unit 20 by flowing air even without a fan. As a result, the pumping member 82a pushes the air more efficiently while pushing the air more silently than the fan. Serve

Further, the air flow member 82 is preferably configured such that the air discharge speed is faster than the air suction speed, thereby further increasing the cooling efficiency.

In addition, it is possible to efficiently remove dust from the heat pipe part 60 including the cooling part 80 by the air quickly discharged from the air flow member 82.

Specifically, the air flow member 82 is disposed on the first heat pipe 61 inside the second heat pipe 62 to communicate with a pumping member 82a for pumping air from the pumping member 82a. And an air passage 82b to extend over the second heat pipe 62 to allow air to flow in a longitudinal direction with respect to the second heat pipe 62.

The air flow member 82 configured as described above flows air laterally by the pumping action of the pumping member 82a, and the air flows upwardly of the second heat pipe 62 through the air flow path 82b. And finally along the longitudinal direction of the second heat pipe 62 from the upper side to the lower side of the second heat pipe 62. Of course, the air flowing in the longitudinal direction of the second heat pipe 62 as described above also flows to the first heat pipe 61 side to perform a cooling function.

As a result, the flowing air flows along the length direction of the second heat pipe 62 in the process of flowing toward the second heat pipe 62 to increase cooling efficiency. That is, in the case where the air is cooled as a whole while flowing in the longitudinal direction from the upper side with respect to the second heat pipe 62, the flow of air is relatively higher than in the case of simply flowing in the transverse or inclined direction instead of the longitudinal direction. Since the speed is high and the flow area is also wide, high cooling capacity can be exhibited in terms of cooling efficiency.

Meanwhile, the present invention may further include a copper coating part 30 provided between the substrate 21 and the heat spreader 40.

The substrate 21 and the heat spreader 40 of the light emitting unit 20 which are in contact with each other generate contact thermal resistance therebetween. Contact thermal resistance is a problem that occurs when different objects come into contact with each other. Inhibits heat transfer.

In order to reduce the heat transfer inhibition due to the contact heat resistance, conventionally, a thermal interface material (TIM) such as a thermally conductive adhesive is used as one embodiment.

However, the present invention can increase the heat transfer efficiency by providing a copper coating 30 between the substrate 21 and the heat spreader (40).

This is because copper is a medium having a higher thermal conductivity than TIM, and heat transfer efficiency of the heat spreader 40 dispersing heat generated from the light emitting part 20 and the substrate 21 in the light emitting part 20 is reduced. A copper coating part 30 is installed between the heat spreader 40 and the light emitting part 20 so as to be a solid contact to increase the height.

According to the present invention constituted as described above, the air flow member 82 flows air along the longitudinal direction from the upper side with respect to the heat pipe part 60, the copper coating between the substrate 21 and the heat spreader 40 By increasing the heat transfer efficiency, the cooling efficiency of the heat generated from the light emitting unit 20 can be increased.

Accordingly, an organic component such as an insulator can prevent the component from changing characteristics according to temperature such that aging occurs at a high temperature, thereby shortening the lifespan in a high temperature environment. In addition, the mechanical strength is changed due to the temperature rise, thermal stress is generated, the dimensional change due to thermal expansion can be prevented from occurring, and furthermore, it can be prevented from causing discomfort due to the high temperature exhaust air.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

20 light emitting portion 21 substrate
22: LED element 40: heat spreader
60: heat pipe part 61: first heat pipe
62: second heat pipe 80: air cooling unit
81: cover 82: air flow member
82a: pumping member 82b: air flow path
90 lens

Claims (5)

A light emitting unit 20 having a substrate 21 and an LED element 22 provided on one surface of the substrate 21; A heat spreader 40 fixed to the other surface of the substrate 21 to disperse heat generated from the light emitting unit 20; A heat pipe part 60 coupled to the heat spreader 40 and having a heat pipe extending outwardly; And an air cooling unit 80 configured to cool the air by injecting air into the heat pipe unit 60, wherein the air is heated by the air cooling unit 80 to the heat pipe of the heat pipe unit 60. Is sprayed longitudinally with respect to,
The heat pipe part 60 and the air cooling part 80 are sequentially disposed from the heat spreader 40 to the opposite side of the light emitting part 20, and the air cooling part 80 is formed of the heat pipe part ( A cover 81 installed on the heat spreader 40 to cover 60; And an air flow member 82 for flowing air into the heat pipe part 60 in the cover 81.
The heat pipe part 60 includes a plurality of first heat pipes 61 positioned at the center of the heat spreader 40; And a plurality of second heat pipes 62 formed longer than the length of the first heat pipes 61 and disposed around the plurality of first heat pipes 61. ) Is a pumping member (82a) disposed on the first heat pipe (61) inside the second heat pipe (62) for pumping air; And an air flow passage (82b) communicating with the pumping member (82a) and extending onto the second heat pipe (62) to flow air in a longitudinal direction with respect to the second heat pipe (62).
LED lighting apparatus comprising a.
delete delete The method of claim 1,
The air flow member 82 is an LED lighting device, characterized in that the air discharge speed is configured to be faster than the air suction speed.
The method according to claim 1 or 4,
A copper coating part 30 disposed between the substrate 21 and the heat spreader 40 to increase heat transfer efficiency;
LED lighting apparatus further comprising a.

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