KR100724381B1 - Apparatus for cooling magnetron of plasma lighting system - Google Patents

Abstract

The present invention is a casing; A magnetron installed inside the casing and having an anode portion, a cathode portion, and a magnet to generate electromagnetic waves when a current is applied to the cathode portion; A light bulb encapsulating a light emitting material to emit light while being excited by an electromagnetic wave generated from the magnetron; A heat transfer member installed to be in contact with the casing and the magnetron such that heat generated from the magnetron is conducted to the casing; And a thermally conductive pad disposed between the magnetron and the heat transfer member or the casing and the heat transfer member so that the casing and the magnetron come into close contact with each other. By allowing fast conduction, the heat dissipation effect on the magnetron can be significantly increased.

Description

Magnetron Cooling System for Electrodeless Lighting Equipment {APPARATUS FOR COOLING MAGNETRON OF PLASMA LIGHTING SYSTEM}

1 is a longitudinal sectional view showing an example of a conventional electrodeless lighting device.

2 is a longitudinal sectional view showing an example of the electrodeless illuminator of the present invention;

3 is a cross-sectional view showing the magnetron in FIG.

Figure 4 is a cross-sectional view showing another embodiment of the electrodeless illuminator of the present invention.

** Description of symbols for the main parts of the drawing **

1: casing 2: magnetron

2a: anode 9: cooling fan

10: heat transfer member 20: thermal conductive pad

30: heat radiation fin

The present invention relates to an electrodeless lighting device using electromagnetic waves, and more particularly, to a magnetron heat dissipation device of an electrodeless lighting device that can easily emit heat generated from the magnetron.

In general, a PLS (Plasma Lighting System) uses a high frequency oscillator (magnetron) mainly used in a microwave oven, and electromagnetic waves generated from the high frequency oscillator make a buffer gas in the bulb into a plasma state. It is a device that can provide excellent amount of light without electrode by allowing metal compound to emit light continuously.

1 is a longitudinal sectional view showing an example of a conventional electrodeless lighting device.

As shown in the related art, a conventional electrodeless lighting device includes a magnetron 2 mounted inside a casing 1 to generate electromagnetic waves, and a high voltage generator for boosting and supplying commercial AC power to the magnetron 2 at a high pressure. 3) and a waveguide 4 which communicates with the outlet of the magnetron 2 and delivers the electromagnetic waves generated by the magnetron 2, and encapsulates the light emitting material, the inert gas, and the discharge catalyst material together by electromagnetic wave energy. A light emitting material 5 that emits light as the plasma is generated, and a resonator 6 which covers the waveguide 4 and the front of the light bulb 5 to block electromagnetic waves while passing the light emitted from the light bulb 5. And a reflector (7) for accommodating the resonator (6) and intensively reflecting light generated from the bulb, and a dielectric mounted inside the resonator (6) at the rear side of the bulb (5) to reflect light while passing electromagnetic waves. Of the mirror (8) and the casing (1) It is provided with the cooling fan 9 provided in one side and cooling the magnetron 2 and the high pressure generator 3. As shown in FIG.

The casing 1 is formed in a hermetic type to seal and accommodate both the magnetron 2, the high pressure generator 3, and the waveguide 4, etc., but the cooling fan 9 is accommodated on one side thereof to receive the cooling fan ( 9) the supply inlet port 1a is formed so that the outside air is sucked into the inside of the casing 1, and on the other side of the air inlet port 1a, the air sucked into the casing 1 is discharged to the outside again. The air outlet 1b is formed. In addition, an air flow path 1c is formed inside the casing 1 so as to communicate with the air suction port 1a to guide the air sucked through the cooling fan 9 to the magnetron 2 or the like.

The magnetron 2 is provided with an anode portion, a cathode portion, and a magnet, and is separately fixed to the inside of the casing 1 at a predetermined interval so as to generate microwaves when applying current to the cathode portion.

Reference numeral M1 in the drawings denotes a bulb motor for rotating the bulb, and M2 is a fan motor for rotating the cooling fan.

The conventional electrodeless lighting device as described above operates as follows.

That is, when a driving signal is input to the high pressure generator 3 according to the command of the controller, the high pressure generator 3 boosts the AC power to supply the boosted high pressure to the magnetron 2, and the magnetron 2 is driven by the high pressure. While oscillating, it generates electromagnetic waves with very high frequencies. The electromagnetic wave radiates into the resonator 6 through the waveguide 4 to excite an inert gas enclosed in the bulb 5 to generate light having a unique emission spectrum while continuously emitting plasma. This light was reflected by the reflector 7 and the dielectric mirror 8 to brighten the space.

However, in the conventional electrodeless lighting device as described above, the magnetron 2 is cooled by only using the air after inhaling air using the fan 9, but it is possible to quickly remove the high-temperature heat generated from the magnetron 2. Not only did not allow cooling, but also to increase the capacity of the fan (9) to cool the heat quickly, there was a fear of causing unpleasant discomfort to residents due to severe noise when installed indoors.

In addition, when the cooling fan 9 is used, the air intake port 1a must be formed in the casing 1, so that rainwater or the like penetrates during installation outdoors, thereby causing various parts to corrode.

The present invention has been made in view of the problems of the conventional electrodeless lighting device as described above, to provide a magnetron cooling device of the electrodeless lighting device that can quickly and quietly release heat generated from the magnetron. There is this.

Another object of the present invention is to provide a magnetron cooling device of an electrodeless lighting device that can effectively prevent rainwater or the like from penetrating into the casing during outdoor installation.

In order to achieve the object of the present invention, a casing; A magnetron installed inside the casing and having an anode portion, a cathode portion, and a magnet to generate electromagnetic waves when a current is applied to the cathode portion; A light bulb encapsulating a light emitting material to emit light while being excited by an electromagnetic wave generated from the magnetron; A heat transfer member installed to be in contact with the casing and the magnetron such that heat generated from the magnetron is conducted to the casing; And a thermally conductive pad disposed between the magnetron and the heat transfer member or the casing and the heat transfer member such that the casing and the magnetron are in close contact with each other.

EMBODIMENT OF THE INVENTION Hereinafter, the magnetron cooling apparatus of the electrodeless illuminating device by this invention is demonstrated in detail based on one Example shown in an accompanying drawing.

Figure 2 is a longitudinal sectional view showing an example of the electrodeless illuminator of the present invention, Figure 3 is a cross-sectional view showing the magnetron around in Figure 2, Figure 4 is a cross-sectional view showing another embodiment of the electrodeless illuminator of the present invention.

As shown in the drawing, the electrodeless lighting device according to the present invention includes a magnetron (2) installed inside the casing (1) to generate electromagnetic waves and to be connected to the casing (1) by the heat transfer member (10). ), A high pressure generator 3 for boosting and supplying commercial AC power to the magnetron 2 at a high pressure, and a waveguide 4 for communicating electromagnetic waves generated by the magnetron 2 by communicating with an outlet of the magnetron 2. ), A light emitting material, a buffer gas, a discharge catalyst material, and the like, which are filled with the electromagnetic wave energy to form a plasma, and the light bulb 5 generates light, and the waveguide 4 and the light bulb 5 in front of the light source. A resonator 6 through which light emitted from the light bulb 5 passes while blocking electromagnetic waves, and a reflector 7 which receives the resonator 6 and concentrates and reflects light generated from the light bulb 5 straight; Inside the resonator 6 on the rear side of the bulb 5 Electromagnetic wave passes through, while light comprises cooling the magnetron 2 and the high voltage generator 3, and provided on one side of the dielectric mirror 8 and the casing (1) for reflecting a cooling fan (9).

The casing 1 is formed in a hermetic type to seal and accommodate both the magnetron 2, the high pressure generator 3, and the waveguide 4, etc., but the cooling fan 9 is accommodated on one side thereof to receive the cooling fan ( 9) the supply inlet port 1a is formed so that the outside air is sucked into the inside of the casing 1, and on the other side of the air inlet port 1a, the air sucked into the casing 1 is discharged to the outside again. The air outlet 1b is formed. In addition, an air flow path 1c is formed in the casing 1 so as to communicate with the air intake port 1a to guide the air sucked through the cooling fan 9 to the magnetron 2 or the like.

The magnetron 2 is provided with an anode part, a cathode part, and a magnet, and is fixedly installed in the casing 1 to generate microwaves when applying current to the cathode part, and heat generated from the magnetron 2 is removed. The heat transfer member 10 is installed in contact between the heat generating portion of the magnetron 2 and the inner circumferential surface of the casing 1 so as to directly conduct it to the casing 1.

To this end, the heat transfer member 10 wraps the outer circumferential surface of the anode portion of the magnetron 2 using aluminum having excellent thermal conductivity and then contacts and fixes the inner circumferential surface of the casing 1. Herein, the magnetron 2 and the heat transfer member 10 or the casing 1 and the heat transfer member 10 may have silicon and the heat transfer member 10 in close contact with the magnetron 2 or the casing 1. It is preferable to interpose the same elastic thermal conductive pad 20.

On the other hand, when installing the lighting device of the present invention to the outside to prevent the pollution source such as rain water to penetrate the inside of the casing for this purpose to remove the cooling fan as shown in Figure 4 to form the casing (1) completely closed On the other hand, a plurality of heat dissipation fins 30 may be formed on the outer circumferential surface of the casing 1 so as to more quickly discharge heat transferred through the heat transfer member 10.

In the drawings, the same reference numerals are given to the same parts as in the prior art.

Unexplained reference numeral 2a in the figure is an anode.

The electrodeless illuminator of the present invention as described above has the following effects.

That is, when a driving signal is input to the high pressure generator 3 according to the command of the controller, the high pressure generator 3 boosts the AC power to supply the boosted high pressure to the magnetron 2, and the magnetron 2 is driven by the high pressure. While oscillating, it generates electromagnetic waves with very high frequencies. The electromagnetic wave is emitted through the waveguide 4 into the resonator 6 to excite the buffer gas enclosed in the bulb 5 to generate light having a unique emission spectrum while continuously emitting plasma. This light illuminates the space while reflecting forward by the reflector 7 and the dielectric mirror 8.

Herein, the magnetron 2 generates high temperature heat as described above, but the heat is transferred to the casing 1 through the heat transfer member 10 made of aluminum, and radiated by natural convection. To cool quickly. In this case, the heat transfer member 10 is not only formed in a single block shape, but in particular, in the case of the heat generating portion of the magnetron 2, that is, the anode 2a, the heat transfer member 10 is coupled between the heat transfer members 10. Although the heat generated by the magnetron 2 is not transmitted smoothly to the heat transfer member 10 due to the aforementioned gap while the gap caused by the processing error occurs, the heat dissipation effect of the magnetron 2 may be lowered. Likewise, when the elastic thermal conductive pad 20 is interposed between the magnetron 2 and the heat transfer member 10 or the casing 1 and the heat transfer member 10, the magnetron 2 is formed by the heat conductive pad 20. ) Or the casing 1 may be in closer contact with the heat transfer member 10, so that heat generated from the magnetron 2 may be quickly conducted to the casing 1.

On the other hand, when the cooling fan 9 is provided as shown in FIG. 2, the outside air is smoothly supplied to the magnetron 2 by the cooling fan 9 to cool the magnetron 2 more quickly. On the other hand, except for the cooling fan (9) as shown in Figure 4, instead of forming a plurality of heat radiation fins 30 in the casing (1) through the heat transfer member 10 through the heat transfer to the casing (1) The heat dissipation fin 30 allows the magnetron 2 to be cooled more effectively while being rapidly dissipated.

In this way, as the magnetron cools more quickly, even when the cooling fan assembly is installed, the cooling fan can be reduced in capacity or use time to lower the noise when installing indoors, and the casing can be formed as shown in FIG. 4. In this case, it is possible to prevent rainwater or other foreign matter from penetrating into the casing during outdoor installation, thereby preventing the corrosion and damage of various components, while improving reliability of the lighting equipment.

The magnetron cooling apparatus of the electrodeless illuminator according to the present invention is provided by contacting and installing a heat transfer member between the magnetron and the casing. The casing is in intimate contact with the heat transfer member, so that the heat of the magnetron can be quickly conducted to the casing, thereby significantly increasing the heat dissipation effect on the magnetron.

Claims (4)

Casing; A magnetron installed inside the casing and having an anode portion, a cathode portion, and a magnet to generate electromagnetic waves when a current is applied to the cathode portion; A light bulb encapsulating a light emitting material to emit light while being excited by an electromagnetic wave generated from the magnetron; A heat transfer member installed to be in contact with the casing and the magnetron such that heat generated from the magnetron is conducted to the casing; And The magnetron cooling device of the electrodeless lighting device including; the magnetron and the heat transfer member or the heat conductive pad is installed between the casing and the heat transfer member, the elastic conductive pad in close contact with the magnetron. The method of claim 1, Magnetron cooling device of the electrodeless lighting device, characterized in that the thermal conductive pad is made of silicon. The method of claim 1, One side of the casing is a magnetron cooling device of the electrodeless lighting device, characterized in that the cooling fan assembly is installed to suck the outside air to supply to the magnetron. The method of claim 1, The casing is formed to be sealed, magnetron cooling device of the electrodeless lighting device, characterized in that a plurality of heat radiation fins are installed on one side.

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