KR101018654B1 - Electrodeless lighting device using plasma - Google Patents

Abstract

The present invention relates to a device for radiating heat of an electrodeless bulb used in a lighting apparatus using plasma.

A wave guide for guiding electromagnetic waves generated from the microwave generator; A resonator installed at one side of the waveguide to shield external emission of the electromagnetic wave; A first support part protruding upward from the one side of the waveguide in which the resonator is installed; An electrodeless light bulb having a light emitting portion connected to a first end of the first support portion to generate light; In the lighting apparatus using a plasma comprising a, wherein the first support portion is adjacent to the light emitting portion for heat dissipation of the light emitting portion, to generate wind toward the light emitting portion when the electrodeless bulb rotates. A first fan member having at least one first wing using the same material as the electrodeless light bulb 60; It is characterized by consisting of.

Therefore, the present invention provides an effect of preventing the case of the electrodeless bulb is broken in advance by further increasing the heat radiation efficiency of the light emitting unit.

Plasma, lighting, electrodeless bulb, heat dissipation

Description

Heat-dissipating device for electrodeless bulb for lighting equipment using plasma {ELECTRODELESS LIGHTING DEVICE USING PLASMA}

The present invention relates to an electrodeless light bulb used in a lighting device using a plasma, in particular through the fan member connected to the first support portion or the second support portion to generate wind when the electrode electrode bulb rotates, more than 1,000 degrees Celsius The present invention relates to a device for increasing heat dissipation efficiency of a light emitting unit that generates heat.

In recent years, the world's oil price has been soaring due to the limited dependence on electricity, gas and oil resources. On the other hand, mankind has seriously raised environmental pollution due to the increase of greenhouse gases caused by the use of petroleum energy. have.

Accordingly, attention has been focused on the reduction of energy that can be used continuously in an environmentally friendly manner without generating environmental pollution, and in particular, the development of various lighting devices that can significantly reduce the air space is actively progressed. There is a trend.

1 is a cross-sectional view showing a part of a conventional lighting device using a plasma.

In general, an electrodeless lighting apparatus using a plasma includes a high voltage generator 20, a microwave generator 30, a waveguide 40, and the like inside the body 10. In addition, the outside of the body portion 10 is provided with a resonator 50 and an electrodeless light bulb 60 to the electromagnetic wave generated in the microwave generator 30 at about 2.4 gigahertz (GHz) to the waveguide 40 Is introduced into the resonator 50 using the strong electric field formed in the resonator 50, and flows into the light emitting part 61 of the electrodeless light bulb 60. As the inert gas and the light emitting material become a plasma discharge (or may be referred to as " light emitting ") at a high temperature, continuous light is emitted and moved forward by the mirror 70 and the reflector 80. It is the principle that illuminates the space while reflecting.

Preferably, the light emitting part 61 is formed of a material having high light transmittance and extremely low dielectric loss, such as quartz, and the encapsulating material encapsulated in the light emitting part 61 forms a high density plasma. Light emitting materials such as metals, halogenated compounds, sulfur, celenium, etc., which lead to discharge, and inert gases such as argon gas and krypton gas, and mercury for forming plasma in the light emitting part 61 at the initial stage of light emission; As described above, the catalyst is composed of a discharge catalyst material for facilitating the onset of the initial discharge and facilitating the lighting, or for controlling the spectrum of light generated.

The waveguide 40 is formed of a cylindrical tube, is connected to the microwave generating portion 30, and also has a ring having a certain height on one side (40a) located on the top of the waveguide 40 ( The waveguide 40 and the resonator 50 are coupled to each other through a ring-shaped resonator coupling member 41.

In addition, the resonator 50 is provided in the reflection shade 80, the electrode electrode bulb 60 is accommodated in the inner space, the microwave generating unit 30 along the circumferential direction of the inner space Shielding the external emission of the electromagnetic wave generated in the) and transmitted to the electrodeless light bulb 60, and has a net structure for transmitting high temperature light generated from the light emitting portion 61 of the electrodeless light bulb 60 to the outside. It is made of a cylindrical mesh (Mesh) (51).

In addition, the mirror 70 is formed in a disk shape having the same diameter as the diameter of the resonator coupling member 41, is disposed in contact with the top surface of the resonator coupling member 41, wherein the mirror ( In the center of the 70, the electrodeless bulb 60 provided at a predetermined length in the upward direction from one side portion 40a of the waveguide 40 is configured to be exposed to the outside of the waveguide 40.

On the other hand, the electrodeless light bulb 60 has a spherical light emitting portion 61 having a predetermined internal volume in which the encapsulating material is encapsulated, and a first support portion 62 formed integrally with the light emitting portion 61. Consists of.

The first support part 62 is installed through the center of the waveguide 40, and is connected to a motor shaft (not shown) of the driving motor 90 so that the electrodeless light bulb 60 may be approximately 2,000 to 5,000. It rotates at a constant speed of revolution (RPM).

At this time, if the electrodeless bulb 60 is not rotated, the light emitting part 61 is damaged due to the high temperature as mentioned above, or the light emitting part 61 and the first support part 62 are connected to each other. The problem occurs that the first end is broken and melted due to high temperature.

In addition, since the light emitter 61 generates light by a high temperature plasma discharge, the internal temperature of the light emitter 61 is about 2,000 degrees Celsius, and the external surface temperature is about 1,000 degrees Celsius lower than this. As a matter of fact, a separate heat dissipation measure is required for the high temperature.

Therefore, additional installation of at least one or more cooling fans 100 is required as a heat dissipation measure of the light emitting part 61, and further, the capacity of the driving motor 110 for driving the cooling fan 100 is further increased. Only if it is selected as a large heat dissipation effect is a general problem.

The present invention for solving the conventional problems as described above by generating a wind when the electrodeless bulb is rotated through the fan member connected to the first support portion or the second support portion provided in the electrodeless bulb, 1,000 degrees Celsius The purpose of the present invention is to increase the heat dissipation efficiency of the light emitting part that generates heat, thereby preventing the light emitting part from being damaged due to high heat.

Means for solving the problems of the present invention as described above includes a waveguide for guiding the electromagnetic wave generated in the microwave generator; A resonator installed at one side of the waveguide to shield external emission of the electromagnetic wave; A first support part protruding upward from the one side of the waveguide in which the resonator is installed; An electrodeless light bulb having a light emitting portion connected to a first end of the first support portion to generate light; In the lighting apparatus using a plasma comprising a, wherein the first support portion is adjacent to the light emitting portion for heat radiation of the light emitting portion, to generate wind toward the light emitting portion when the electrodeless bulb is rotated. Using the same material as the electrodeless bulb 60 A first fan member having at least one first wing is provided.

In addition, the light emitting portion at a position opposite to the first supporting portion includes a second supporting portion which is connected to the second end and is provided coaxially with the first supporting portion. It is characterized by that.

In addition, at least one agent made of the same material as the electrodeless bulb 60 so as to be connected to the third end of the second support portion to generate wind toward the light emitting portion when the electrodeless bulb rotates. A second fan member having two wings is provided.

Hereinafter, the objects and solutions to the present invention will become more apparent from the detailed description of the various embodiments shown in the accompanying drawings.

As described above, the present invention provides an effect of preventing the case where the electrodeless bulb is broken by further increasing the heat dissipation efficiency of the light emitting unit that generates heat above 1,000 degrees Celsius.

In addition, the present invention provides another effect of further reducing the occurrence of failure of peripheral components due to the high heat of the light emitting unit.

In addition, the present invention can further reduce the manufacturing cost of the product because it can reduce the capacity of the heat radiation fan is installed to cool the high heat of the light emitting unit.

In describing a specific embodiment of the present invention, it is illustrated by the drawings of the present invention, the configuration and operation thereof will be described as at least one embodiment, whereby the technical spirit and core of the present invention General configurations and operations should not be limited.

For reference, in designating reference numerals in the drawings to be described in the present invention, it should be noted that the same components are given the same reference numerals as much as possible, even if shown in different drawings.

Hereinafter, a heat dissipation device of an electrodeless bulb for a lighting device using a plasma of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a cross-sectional view of a first embodiment showing a partial cutaway of an apparatus for radiating an electrodeless light bulb of a lighting apparatus using a plasma according to the present invention.

As a means for solving the problem of the present invention is installed in the waveguide 40 for guiding the electromagnetic wave generated in the microwave generator 30 and one side portion (40a) of the waveguide 40 to shield the external emission of the electromagnetic wave The resonator 50 is configured.

In addition, the first support portion 62 and the first support portion 62 of the first support portion 62 protruding upward from the one side portion 40a of the waveguide 40 provided with the resonator 50 are installed. It consists of an illumination device using a plasma including an electrodeless light bulb 60 having a light emitting portion 61 that is connected to an end portion 62a to generate light.

At this time, since the light emitting portion 61 is generated by the high-temperature plasma discharge as mentioned above, the internal temperature of the light emitting portion 61 is about 2,000 degrees Celsius or more, and the external surface temperature is higher than this. The low heat is about 1,000 degrees Celsius or more, so it generates heat at a great temperature, so a separate heat dissipation measure is required.

In addition, the first support part 62 is adjacent to the light emitting part 61 for heat dissipation of the light emitting part 61, so that the light emitting part 61 is rotated when the electrodeless light bulb 60 rotates. It characterized in that the first fan member (130) having at least one first wing (131) for generating wind toward the wind is made of the same material as the electrodeless bulb (60).

In addition, as shown in FIG. 5, a plurality of protrusions 132 are formed on the front surface of the wing in which wind is generated to increase the heat dissipation area on the first wing 131, and the same position as that of the protrusion 132. By forming the recess 132a on the rear surface, the heat radiating action of the light emitting part 61 is further maximized.

In addition, the torsion angle K1 of the first wing 131 is 5 degrees to the center Y1 of the first support part 62 so that wind is generated toward the light emitting part 61 as shown in FIG. 4. Characterized in that it is installed in the range of 65 degrees, more preferably by giving the torsion angle (K1) to 15 degrees, the heat radiation action on the light emitting portion 61 will be more advantageous by using the wind generated accordingly.

In addition, the length (L11) of the first wing 131 is characterized in that provided in the range of 0.8 to 1.2 times the diameter of the light emitting portion 61.

At this time, if the length L11 of the first wing 131 is too long, the amount of wind is generated, which is advantageous for the heat dissipation of the light emitting part 61, and thus driving the electrodeless bulb 60 to rotate. The load on the motor 90 may be increased. On the contrary, if the length L11 of the first wing 131 is too short, the amount of wind generated is small, so that the heat dissipation of the light emitting part 61 is decreased. It would be desirable to select one.

3 is a cross-sectional view of a second embodiment showing a partial cut-out of a device for radiating an electrodeless light bulb of a lighting apparatus using a plasma according to the present invention.

On the other hand, as a configuration added to the first embodiment, the light emitting portion 61 at a position facing the first support portion 62 is connected to a second end portion 65a. The second support part 65 using the same material as the electrodeless light bulb 60 is coaxially formed with the first support part 62.

At this time, at least one second that is connected to the third end portion 65b of the second support portion 65 to generate wind toward the light emitting portion 61 when the electrodeless light bulb 60 rotates. The second fan member 130a having the wings 131a is made of the same material as the electrodeless light bulb 60.

Similarly, as shown in FIG. 6, the torsion angles K1 and K2 of the first wing 131 and the second wing 131a may have a first support part 62 such that wind is generated toward the light emitting part 61. And 5 degrees to 65 degrees with respect to the center Y1 of the second support portion 65, respectively. More preferably, the torsion angles K1 and K2 are set to 15 degrees. Accordingly, the wind generated from the first wing 131 and the second wing 131a at the same time will be more advantageous in terms of maximizing the heat dissipation effect on the light emitting part 61.

6 and 7, the first wing 131 and the second wing 131a are positioned at the same distance (L1 = L2) from the center X1 of the light emitting part 61 as a starting point. By installing the first support portion 62 and the second support portion 65 located on the outer circumferential surface facing each other, the light emission using the wind generated simultaneously from the first wing 131 and the second wing 131a. It will be possible to maximize the heat dissipation effect on the portion (61).

In addition, the length (L11) (L11a) of the first wing 131 and the second wing 131a is the same, characterized in that installed in the range of 0.8 to 1.2 times the diameter of the light emitting portion 61, The action of the length (L1) (L2) for the addition and subtraction is already described above and will be omitted.

In addition, as shown in FIG. 8, the first wing 131 and the second wing 131a form a plurality of protrusions 132 on the front surface of the wing in which wind is generated to increase the heat dissipation area, and the protrusions By forming the recess 132a on the rear surface of the same position as that of 132, the heat radiation of the light emitting part 61 is further maximized.

Herein, the protrusion 132 and the recess 132a may be formed in a circular shape, a semicircle, a triangle, a square, and the like, but the shape and size thereof are not limited thereto.

It will be apparent to those skilled in the art that various changes, modifications, and the like can be made without departing from the technical spirit of the present invention through the above description.

Therefore, the technical scope of the present invention should not be limited to the contents described in the embodiments as mentioned, but should be defined by the claims of the present invention.

1 is a cross-sectional view showing a part of a conventional lighting device using a plasma.

FIG. 2 is a cross-sectional view of a first embodiment showing a partial cutaway of an apparatus for radiating an electrodeless light bulb of a lighting apparatus using a plasma according to the present invention.

3 is a cross-sectional view of a second embodiment showing a partial cut-out of a device for radiating an electrodeless light bulb of a lighting apparatus using a plasma according to the present invention.

4 is a cross-sectional view of a first embodiment showing the state in which the fan member is installed in the electrodeless bulb in FIG. 2 according to the present invention.

5 is a cross-sectional view of a second embodiment showing a state in which the fan member is installed in the electrodeless bulb in FIG. 2 according to the present invention.

FIG. 6 is a cross-sectional view of a first embodiment in detail illustrating a state in which a fan member is installed in an electrodeless light bulb according to the present invention.

7 is a cross-sectional view of a second embodiment showing a state in which the fan member is installed in the electrodeless bulb in FIG. 3 according to the present invention.

8 and 7 according to the present invention, a cross-sectional view of one embodiment showing in detail the state of the projection and the recess provided in the fan member.

Explanation of symbols on the main parts of the drawings

10: Body part 20: High voltage generating part

30: microwave generating unit 40: waveguide

41: resonator coupling member 40a: one side

50: resonator 51: mesh

60 electrodeless bulb 61 light emitting unit

62: first support portion 62a: first end portion

65: second support 65a: second end

65b: third end 70: mirror

80: reflection shade 90, 110: drive motor

130: first fan member 130a: second fan member

131: first wing 131a: second wing

132: protrusion 132a: groove

Claims (3)

A waveguide 40 for guiding electromagnetic waves generated by the microwave generator 30; A resonator 50 installed at one side portion 40a of the waveguide 40 to shield external emission of the electromagnetic wave; A first support portion 62 protruding upward from the one side portion 40a of the waveguide 40 in which the resonator 50 is installed; An electrodeless light bulb (60) having a light emitting portion (61) connected to a first end portion (62a) of the first support portion (62) to generate light; In the lighting apparatus using a plasma comprising a, The first support 62 generates wind toward the light emitting part 61 when the electrodeless light bulb 60 rotates adjacent to the light emitting part 61 to radiate heat of the light emitting part 61. In order to use the same material as the electrodeless bulb 60, in order to increase the heat dissipation area, a plurality of protrusions 132 is formed on the front of the wind generating wing, the rear of the same position as the protrusion 132 At least one recessed portion 132a is formed therein and has a torsion angle K1 in a range of 5 degrees to 65 degrees toward the light emitting portion 61 with respect to the center Y1 of the first support portion 62. A first fan member 130 provided with the first wings 131 and above; And A second support part (65) provided in the light emitting part (61) at a position opposite to the first support part (62), the second end part (65a) being coaxially provided with the first support part (62); The electrodeless bulb 60 is connected to the third end portion 65b of the second support portion 65 to generate wind toward the light emitting portion 61 when the electrodeless bulb 60 is rotated. The same material is used, and a plurality of protrusions 132 are formed on the front surface of the wind generating wind to increase the heat dissipation area, and the groove portion 132a is formed on the rear side of the same position as the protrusion 132. At least one second wing 131a having a torsion angle K2 in a range of 5 degrees to 65 degrees is installed toward the light emitting part 61 with respect to the center Y1 of the second support part 65. Second fan member 130a; Radiating device of the electrodeless bulb for lighting equipment using a plasma, characterized in that consisting of. According to claim 1, wherein the first wing 131 and the second wing (131a) is the first support portion located at the point of the same distance (L1 = L2) starting from the center (X1) of the light emitting portion 61 ( 62) and the heat dissipation device of the electrodeless bulb for a lighting device using a plasma, characterized in that installed on the outer circumferential surface of the second support portion 65 facing each other. According to claim 1, wherein the length (L11) (L11a) of the first wing 131 and the second wing (131a) is the same, characterized in that installed in the range of 0.8 to 1.2 times the diameter of the light emitting portion (61). Radiating device of an electrodeless bulb for lighting equipment using a plasma.

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