KR20070087928A - Plasma lighting system having glass resonator - Google Patents

Abstract

A plasma lighting system having a glass resonator is provided to shield emission of microwaves generated from a microwave generation unit to an outside of the resonator by forming an electromagnetic wave shielding part around the resonator. An electrodeless bulb(60) is filled with a charged emission material in order to generate light by plasmarizing the charged emission material. A resonator(50) includes an internal space for storing the electrodeless bulb. The resonator is formed with a cylindrical shape of glass material in order to transmit the light generated from the electrodeless bulb. An electromagnetic wave shielding part is formed around the resonator in order to form a resonance mode by shielding the emission of microwaves to the outside. The microwaves are generated from a microwave generation unit and are applied to the internal space.

Description

Electrodeless Illuminator with Glass Resonator {PLASMA LIGHTING SYSTEM HAVING GLASS RESONATOR}

1 is a plan view showing the structure of a conventional electrodeless lighting device,

FIG. 2 is a cross-sectional view taken along the line 'II-II' of FIG. 1;

3 is a plan view showing the structure of an electrodeless lighting device having a glass resonator according to an embodiment of the present invention;

4 is a cross-sectional view taken along the line "IV-IV" of FIG.

5 is a cross-sectional view showing the structure of a resonator of an electrodeless lighting device having a glass resonator according to another embodiment of the present invention.

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

20: high voltage generator 30: microwave generator

40: waveguide 50: resonator

51: mesh 52: glass resonator

53 electrical conductor 54 first glass resonator

55: electromagnetic wave filter 56: second glass resonator

60 electrodeless light bulb

The present invention relates to an electrodeless lighting apparatus having a glass resonator, and more particularly, to increase the amount of microwaves focused on the electrodeless bulb side, thereby increasing the luminous efficiency of the electrodeless bulb, and the microwaves are external to the resonator. The present invention relates to an electrodeless lighting device having a glass resonator that can prevent leakage of a device and prevent malfunction of other external devices of the same frequency band.

In general, an electrodeless illuminator is a gas filled in the electrodeless light bulb, while microwave energy generated from a microwave generator that generates microwaves, such as a magnetron, is transmitted to the resonator bulb through the waveguide and applied to the electrodeless bulb mounted inside the resonator. It is a device that generates light by exciting the conversion to a plasma state.

An electrodeless lighting device is an electrodeless bulb that has no electrodes or filaments inside the bulb, and has a very long or semi-permanent lifetime, and emits light as the charging material charged inside the electrodeless bulb becomes plasma to emit light such as natural light. .

1 is a plan view showing the structure of a conventional electrodeless lighting device, Figure 2 is a cross-sectional view taken along the line 'II-II' of FIG.

As shown in these drawings, a conventional electrodeless lighting device includes a high voltage generator 20 for generating a high voltage when power is applied to one side of an inner space of a casing 10 having a constant inner space, and a fixed voltage is generated. Microwave generator 30 for oscillating microwave having a high frequency when the high voltage generated by the unit 20 is applied, and a waveguide 40 for guiding the microwave applied from the microwave generator 30, the casing 10 A resonator 50 which shields the external emission of the microwave guided by the waveguide 40 to the resonance mode and is rotatably disposed at the center of the resonator 50 and enclosed therein by the resonance mode. The inert gas is configured to include an electrode-less bulb 60 to generate light while being plasma.

The waveguide 40 is a cylindrical tube, one side of which is connected to the microwave generator 30, and an upper surface of the waveguide 40 has a predetermined height along the height direction of the waveguide 40. ) Is formed to protrude.

The resonator coupling member 41 is formed in a ring shape having a diameter smaller than that of the waveguide 40, the center of which is penetrated, and the resonator 50 is fixedly coupled to the outer surface.

The resonator 50 accommodates the electrodeless light bulb 60 in the inner space, shields the external emission of microwaves along the circumferential direction of the inner space, transmits the light to the electrodeless light bulb 60, and the light generated from the electrodeless light bulb 60. It is made of a cylindrical mesh 51 having a mesh structure so as to transmit to the outside, and the outer shape of the resonator 50 is formed of a steel material to maintain the cylindrical shape.

The mirror 70 has a disk shape having a diameter equal to the diameter of the resonator coupling member 41, and is disposed to be in contact with the top surface of the resonator coupling member 41, and the height direction of the waveguide 40 is located at the center of the mirror 70. The electrodeless light bulb 60 extends to a predetermined length so as to be exposed to the outside of the waveguide 40.

On the other hand, the electrodeless bulb 60 is composed of a spherical light emitting portion 61 having a predetermined internal volume in which the encapsulation material is encapsulated, and a fixing portion 62 integrally formed with the same material as the light emitting portion 61. It is.

The light emitting part 61 is installed inside the casing 10, and the fixing part 62 is installed to pass through the center of the waveguide 40, and the fixing part 62 thus installed is the casing 10. It is connected to the motor shaft of the drive motor 90 installed in the interior is to rotate at a constant speed.

The light emitter 61 is preferably made of a material having high light transmittance and extremely low dielectric loss, such as quartz, and the encapsulation material encapsulated inside the light emitter 61 forms a plasma to drive light emission. Light emitting materials such as metals, halogenated compounds, sulfur or selenium, inert gases such as argon gas and krypton gas for forming plasma inside the light emitting unit 61 at the initial stage of light emission, and initial discharge like mercury It is made of a discharge catalyst material for facilitating or adjusting the spectrum of light generated.

In the drawings, reference numeral 70 denotes a mirror, 80 a reflection shade, 100 a cooling fan, 110 a second driving motor for rotating the cooling fan, and 120 an air duct.

By such a configuration, in the conventional electrodeless lighting device, when a driving signal is input to the high voltage generator 20, the high voltage generator 20 boosts AC power to supply the boosted high voltage to the microwave generator 30. The microwave generator 30 generates a microwave having a very high frequency while oscillating by a high voltage. The microwave is radiated through the waveguide 40 into the resonator 50 to excite the inert gas charged in the electrodeless light bulb 60 to emit light having a unique emission spectrum as the luminescent material is continuously plasmaled. After the light reaches the surface of the mirror 70 disposed behind the electrodeless bulb 60, the light is reflected toward the electrodeless bulb 60 to illuminate the space.

By the way, in the conventional electrodeless lighting device, when the microwave generated from the microwave generator 30 is guided by the waveguide 40 to form a resonance mode inside the resonator 50, the mesh of the resonator 50 is formed. A portion of the microwave is leaked to the outside through the opening of the 51 to reduce the amount of microwaves focused on the electrodeless light bulb 60, so that the light efficiency of the electrodeless light bulb 60 is reduced, and the same frequency as that of the leaked microwave is reduced. There is a problem that may cause malfunction to other external devices.

Accordingly, an object of the present invention is to increase the amount of microwaves focused on the electrodeless bulb to increase the luminous efficiency of the electrodeless bulb, and prevent the microwaves from leaking to the outside of the resonator to prevent malfunction of other external devices of the same frequency band. It is to provide an electrodeless lighting device having a glass resonator that can be prevented.

The above object, according to the present invention, the electrodeless bulb which emits light by plasma-forming the light emitting material therein; Receives the electrodeless bulb in the inner space and the light generated from the electrodeless bulb is formed of a cylindrical glass material to transmit, and resonant mode by shielding the external emission of the microwave generated by the microwave generator and applied to the inner space A resonator having an electromagnetic wave shield on a circumferential surface thereof so as to be made; It is achieved by an electrodeless illuminator with a glass resonator, characterized in that it comprises a.

Here, the electromagnetic wave shield is effectively a thin film-type electrical conductor deposited on the outer circumferential surface of the glass resonator.

This is to easily form the electrical conductor in the glass resonator.

On the other hand, the electromagnetic wave shield may be formed of a thin film-type electrical conductor deposited on the inner peripheral surface of the glass resonator.

This is to shield the electrical conductors from contact with the outside to prevent damage to their surfaces.

On the other hand, the above object, according to another field of the present invention, the electrodeless bulb which emits light by plasma-forming the light emitting material therein; The first glass resonator is formed of a glass material and has a cylindrical shape so as to receive the electrodeless bulb in an inner space and transmit light generated from the electrodeless bulb, and the outside of the microwave generated by the microwave generator and applied to the inner space. A resonator including an electromagnetic shielding part provided on an outer circumferential surface of the first glass resonator to shield the emission, and a second glass resonator formed of a cylindrical glass material provided on an outer circumferential surface of the electromagnetic shielding part; It is achieved by an electrodeless illuminator with a glass resonator, characterized in that it comprises a.

Here, the electromagnetic wave blocking unit is effectively an electromagnetic wave blocking filter that is covered on the outer circumferential surface of the first glass resonator.

This is because it is easy to install by manufacturing a separate electromagnetic wave filter and covering the outer peripheral surface of the first glass resonator.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

However, the same reference numerals are given to the same parts as in the conventional configuration, and detailed description thereof will be omitted.

3 is a plan view illustrating a structure of an electrodeless lighting device having a glass resonator according to an embodiment of the present invention, FIG. 4 is a cross-sectional view taken along the line 'IV-IV' of FIG. 3, and FIG. FIG. 10 is a cross-sectional view illustrating a structure of a resonator of an electrodeless lighting device having a glass resonator according to another embodiment of the present invention.

As shown in these drawings, an electrodeless lighting device having a glass resonator according to an embodiment of the present invention includes an electrodeless bulb 60 in which a light emitting material charged therein is converted into plasma to emit light. It accommodates the electrodeless bulb 60 and transmits the light generated from the electrodeless bulb 60 and shields the external emission of the microwave generated by the microwave generator 30 and applied to the inner space so that the resonance mode is achieved. In an electrodeless lighting device comprising a resonator 50 for causing the electrode bulb 60 to emit light, the resonator 50 accommodates the electrodeless bulb 60 in an inner space and is generated in the electrodeless bulb 60. The light to be transmitted is formed of a glass material of cylindrical shape, and the resonance mode is achieved by shielding the external emission of the microwave generated by the microwave generator 30 and applied to the internal space. It characterized in that it includes parts of the electromagnetic shield surface.

The resonator 50 is formed to have a cylindrical shape and the material is formed of a transparent glass material so as to emit a large amount of light generated from the electrodeless bulb 60 to the outside, thus, the conventional porous mesh 51 structure Since there is no need to form, there is an advantageous effect in the process.

The electromagnetic shield is an electrical conductor 53 which is deposited in the form of a transparent conductive film by sputtering on the outer circumferential surface or the inner circumferential surface of the resonator 50 having a cylindrical glass material.

The sputtering method is a technique commonly used to form a thin film as a technique of striking an inert element such as argon on a metal plate to drive out metal molecules and then attaching a film to the surface.

When the electric conductor 53 is formed on the outer circumferential surface of the resonator 50, the process of depositing it in the form of a conductive film is easier than when forming the inner circumferential surface, and when the electric conductor 53 is formed on the inner circumferential surface of the resonator 50. There is an advantage in that it can prevent the contact with the outside of the electrical conductor 53, thereby preventing damage.

In the formation of the electrical conductor 53, materials such as gold (Au), silver (Ag), platen (Pt), and aluminum (Al) having good electrical conductivity are generally used, and visible light transmittance is used to minimize visible light transmission loss. It is preferable to make 0.9 or more and to make the thickness into a few micrometers unit.

By such a configuration, in the electrodeless lighting device having the glass resonator according to the present invention, when a driving signal is input to the high voltage generator 20, the high voltage generator 20 boosts an AC power to generate a high voltage boosted by a microwave generator. The microwave generator 30 generates a microwave having a very high frequency while oscillating by a high voltage.

The microwave is radiated through the waveguide 40 into the resonator 50 to excite the inert gas charged in the electrodeless light bulb 60 so that the light emitting material is continuously plasma-formed. In this case, the resonator 50 Since the electrical conductor 52 has a very thin thickness of several micrometers, light transmits and most microwaves reflect, so that external leakage of microwaves can be prevented, and the microwaves inside the resonator 50 are resonators 50. Since the light is reflected from the inside of the electrodeless bulb 60, a large amount of microwave energy is transmitted to the electrodeless bulb 60.

In the electrodeless light bulb 60 receiving the microwave energy as described above, light having a unique emission spectrum is generated, and the light reaches the surface of the mirror 70 disposed behind the electrodeless light bulb 60. It is reflected to the front of the electrodeless bulb 60 to illuminate the space.

FIG. 5 is a cross-sectional view illustrating a structure of a resonator of an electrodeless lighting device having a glass resonator according to another embodiment of the present invention, and like reference numerals refer to like parts, and a detailed description thereof will be omitted. FIG. Shall be.

As shown in the figure, the resonator 50, the first glass is formed of a glass material so as to receive the electrodeless light bulb 60 in the inner space and transmit the light generated from the electrodeless light bulb 60 has a cylindrical shape An electromagnetic wave shielding portion provided on the outer circumferential surface of the first glass resonator 54 to shield the external emission of the microwaves generated by the microwave generating unit 20 and applied to the internal space to achieve a resonance mode; The second glass resonator 56 is formed of a cylindrical glass material and provided on the outer circumferential surface of the electromagnetic wave shielding part.

The electromagnetic wave blocking unit is formed of an electromagnetic wave blocking filter 55 which is covered on the outer circumferential surface of the first glass resonator 54, and the electromagnetic wave blocking filter 55 is formed to have a thickness of several μs in the electrodeless light bulb 60. It is desirable to allow the light to be transmitted to the outside and to block the external emission of the microwaves.

Unlike the embodiment of the present invention, since the electromagnetic wave blocking filter 55 is manufactured and covered on the first glass resonator 54, when the electromagnetic wave blocking filter 55 is damaged, the entire resonator 50 needs to be replaced. Without the damaged electromagnetic wave filter 55 only need to replace the resonator 50 can be used semi-permanently, since the second glass resonator 56 is written on the outer peripheral surface of the electromagnetic wave filter 55 55) It is effective to prevent the damage to the maximum.

By such a configuration, in the electrodeless lighting device having the glass resonator according to the present invention, when a driving signal is input to the high voltage generator 20, the high voltage generator 20 boosts an AC power to generate a high voltage boosted by a microwave generator. The microwave generator 30 generates a microwave having a very high frequency while oscillating by a high voltage.

The microwave is radiated through the waveguide 40 into the resonator 50 to excite the inert gas charged in the electrodeless light bulb 60 so that the light emitting material is continuously plasmaized. 55), because the thickness is very thin, the light transmits and most of the microwave reflects, thus preventing external leakage of microwaves. The microwaves inside the resonator 50 are separated from the inside of the resonator 50. Since the reflected light is focused on the electrodeless bulb 60, a large amount of microwave energy is transmitted to the electrodeless bulb 60.

In the electrodeless light bulb 60 receiving the microwave energy as described above, light having a unique emission spectrum is generated, and the light reaches the surface of the mirror 70 disposed behind the electrodeless light bulb 60. It is reflected to the front of the electrodeless bulb 60 to illuminate the space.

As described above, according to the present invention, there is provided an electrodeless light bulb which emits light by plasma-forming a light emitting material; Receives the electrodeless bulb in the inner space and the light generated from the electrodeless bulb is formed of a cylindrical glass material to transmit, and resonant mode by shielding the external emission of the microwave generated by the microwave generator and applied to the inner space By providing a resonator having an electromagnetic wave shield on the circumferential surface of the electrode, the amount of microwaves focused on the electrodeless bulb can be increased to increase the luminous efficiency of the electrodeless bulb, and prevent the microwaves from leaking to the outside of the resonator. Therefore, there is an effect that can prevent the malfunction of other external devices in the same frequency band.

Claims (6)

An electrodeless bulb in which the light emitting material filled therein becomes plasma and emits light; Receives the electrodeless bulb in the inner space and the light generated from the electrodeless bulb is formed of a cylindrical glass material to transmit, and resonant mode by shielding the external emission of the microwave generated by the microwave generator and applied to the inner space A resonator having an electromagnetic wave shield on a circumferential surface thereof so as to be made; Electrodeless illumination device having a glass resonator, characterized in that it comprises a. The method of claim 1, The electromagnetic shielding unit is an electrodeless lighting device having a glass resonator, characterized in that the thin film-type electrical conductor deposited on the outer peripheral surface of the glass resonator. The method of claim 1, The electromagnetic shielding unit is an electrodeless lighting device having a glass resonator, characterized in that the thin film-type electrical conductor deposited on the inner peripheral surface of the glass resonator. An electrodeless bulb in which the light emitting material filled therein becomes plasma and emits light; The first glass resonator is formed of a glass material and has a cylindrical shape so as to receive the electrodeless bulb in an inner space and transmit light generated from the electrodeless bulb, and the outside of the microwave generated by the microwave generator and applied to the inner space. A resonator including an electromagnetic shielding part provided on an outer circumferential surface of the first glass resonator to shield the emission, and a second glass resonator formed of a cylindrical glass material provided on an outer circumferential surface of the electromagnetic shielding part; Electrodeless illumination device having a glass resonator, characterized in that it comprises a. The method of claim 4, wherein And said electromagnetic wave shield is an electromagnetic wave shielding filter written on an outer circumferential surface of said first glass resonator. The method according to any one of claims 1 to 5, The electrical conductor is an electrodeless lighting device having a glass resonator, characterized in that formed of any one of gold (Au), silver (Ag), platinum (Pt), aluminum (Al).

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