KR20110005556A - Electrodeless lighting system - Google Patents

Abstract

PURPOSE: An electrodeless lighting system is provided to reduce the size of a mirror and to maintain the same reflection effect by forming a dielectric mirror in a bulb in a one body. CONSTITUTION: A resonator(150) resonates when microwave flows into. An electrodeless bulb(160) is installed inside the resonator. A motor revolves the bulb. A bulb support stand transfers the torque of the motor to the bulb. A dielectric mirror(180) is formed in the bulb support stand in a one body.

Description

Electrodeless Lighting Equipment {ELECTRODELESS LIGHTING SYSTEM}

The present invention relates to an electrodeless illuminator using microwaves, and more particularly to an electrodeless illuminator in which a dielectric mirror is integrally formed with a bulb.

In general, an electrodeless lighting device transmits microwaves generated from a microwave generator such as a magnetron to a resonator through a waveguide, and excites a filling material of an electrodeless light bulb provided inside the resonator. Is a device that generates light by converting the filling gas into a plasma state.

The electrodeless lighting device is an electrodeless bulb having no electrode or filament inside the bulb, and has a very long or semi-permanent lifespan, and emits light as natural light becomes charged by the filling material charged inside the electrodeless bulb. It will emit light.

1 illustrates a general shape of an electrodeless lighting device, which includes a casing 10, a high voltage generator 20 installed inside the casing 10 to generate a high voltage, and a high voltage generator 20. The magnetron 30 to generate a microwave by applying a high voltage, and is installed in the inner space of the casing 10 and coupled to the magnetron 30 to guide the microwave having a high frequency oscillated from the magnetron 300 And a resonator 50 coupled to the outlet side of the waveguide 40 to shield the external emission of microwaves to form a resonance mode, and disposed inside the resonator 50 to be excited by microwaves. And an electrodeless bulb 60 provided with a light emitting material to emit light, and installed in the casing 10 to accommodate the resonator 50 to forward the light emitted from the electrodeless bulb 60. Reflecting shade 70 for condensing is included.

In addition, the resonator 50 has a cylindrical shape in which a lower surface is open as seen in FIG. 1, and an open lower surface is fixedly attached to the casing. In order to attach the resonator 50 to the casing 10, a resonator mounting portion 55 is fixed to support the casing. In addition, a light bulb support 90 coupled to one side of the electrodeless bulb 60 to support the electrodeless bulb is further provided. The electrodeless bulb is connected to the motor (M) provided below by the bulb support. That is, the motor M rotates the electrodeless bulb through the bulb support 90.

In addition, a dielectric under the electrodeless light bulb 60 reflects light in order to prevent light emitted from the bulb from being radiated downward and absorbed by the waveguide as shown in FIG. A mirror 80 is provided. In addition, since the electrodeless bulb 60 is connected to the motor through the bulb holder 90, the bulb holder 90 passes through the dielectric mirror 90 so as to pass through the center of the dielectric mirror 80. Through holes should be formed in the

However, not only it is not easy to form a through hole in the center of the dielectric mirror 80, but also a disadvantage in terms of cost because the dielectric mirror must cover the entire diameter of the cylindrical resonator.

The present invention has been made to solve the above problems, and an object thereof is to provide a means for reducing the size of the dielectric mirror provided in the electrodeless lighting device and exhibiting the same reflection effect.

It is also an object of the present invention to provide a means for connecting the electrodeless bulb and the motor without the through hole in the dielectric mirror of the electrodeless lighting device.

In order to achieve the above object, the present invention is a resonator in which microwave is introduced and resonates; An electrodeless light bulb which is installed inside the resonator and emits light by microwaves in which a light emitting material is filled and resonates therein; A motor for rotating the bulb; And a light bulb support having one end connected to the motor and the other end connected to the bulb to transmit rotational force of the motor to the bulb. It is formed integrally with the bulb support, and provides a non-electrode lighting apparatus comprising a; dielectric mirror for passing the microwave while reflecting light from the bulb.

Since the bulb support and the dielectric mirror are rotated by the above configuration, the bulb support does not need to separately form a through hole for passing the dielectric mirror.

The resonator has a cylindrical mesh structure, and further includes a resonator mounting part for attaching and fixing one end of the resonator.

In addition, the dielectric mirror is spaced apart from the resonator mounting portion by a predetermined distance and is provided between the resonator mounting portion and the bulb.

The dielectric mirror may have a circular plate shape perpendicular to the bulb support, or the dielectric mirror may have a circular plate shape perpendicular to the bulb support, and an edgeless electrode having a bent surface bent toward the bulb may be formed at an edge thereof. It may be a luminaire.

Alternatively, the dielectric mirror may be formed in a curved shape having a predetermined curved surface in the bulb support.

The diameter of the dielectric mirror, the electrodeless illumination device, characterized in that the imaginary line connecting the point where the resonator and the resonator mounting portion in contact with the center of the bulb can pass through the surface of the dielectric mirror.

According to the above configuration, while reducing the size of the dielectric mirror provided in the electrodeless illuminator, the microwave passes and reflects the light emitted from the electrodeless light bulb. The bulb support can connect the electrodeless bulb and the motor without the need to reduce the time and cost required to manufacture the dielectric mirror, resulting in a beneficial effect of reducing the manufacturing cost of the electrodeless lighting device.

Hereinafter, the electrodeless lighting device according to the present invention will be described in detail based on the embodiment shown in the accompanying drawings.

2 shows a schematic cross section of an electrodeless lighting device according to an embodiment of the present invention. Referring to this, the electrodeless lighting device according to the present invention, the casing 110, the high voltage generator 120 is installed in the casing 110 to generate a high voltage, and is generated in the high voltage generator 120 Magnetron 130 is applied to a high voltage to generate a microwave having a high frequency, and installed in the inner space of the casing 110 and coupled to the magnetron 130 to guide the microwave having a high frequency oscillated from the magnetron 130 And a resonator 150 coupled to the outlet side of the waveguide 140 to shield the external emission of microwaves to form a resonance mode, and disposed inside the resonator 150 to be excited by microwaves. Light emitted from the electrodeless bulb 160 by being installed at the casing 110 to accommodate the resonator 150 and the electrodeless bulb 160 having a light emitting material to emit light. It includes the reflector 170 to converge in the forward direction and, and a motor (M) for rotating the electrodeless bulb.

In addition, the resonator 150 has a cylindrical mesh structure of which one side is open, and the open side is attached to the casing 110. In order to attach the resonator 150 to the casing 110, a resonator mounting part 155 for fixing the casing is provided. Further, a light bulb support 190 coupled to one side of the electrodeless light bulb 160 to support the electrodeless light bulb is further provided, and the light bulb 160 is provided below by the light bulb support 190. In addition, the motor (M) rotates the electrodeless bulb through the bulb support 190 while rotating at a constant speed.

In addition, a dielectric mirror 180 is provided below the electrodeless bulb 160 to reflect light from the bulb to the waveguide 140 and to reflect the light to the front of the electrodeless lighting device. . To this end, the dielectric mirror 180 has a property of reflecting light from the electrodeless bulb while passing the microwave. In addition, the dielectric mirror 180 according to the present invention is characterized in that it is integrally formed with the bulb support 190. That is, the bulb support 190 formed integrally with the dielectric mirror 180 connects the electrodeless bulb 160 and the motor (M). Therefore, the through hole for the bulb support 190 to penetrate the dielectric mirror 180 need not be formed. In addition, the dielectric mirror 180 is provided between the resonator mounting portion and the light bulb by being spaced apart from the resonator mounting portion 155 on which the resonator 150 is mounted.

Referring to FIG. 3, the dielectric mirror 180 is mounted in detail. As shown in FIG. 3, the dielectric mirror 180 is disposed between the electrodeless bulb and the resonator mounting unit in the vertical direction, and spaced apart from the resonator in the left and right directions of FIG. 3. It can be seen that the state is formed integrally with the bulb support. In the cross-sectional view of FIG. 3, an angle formed by a line connecting the points where the resonator 150 and the resonator mounting unit 155 meet at the center of the electrodeless light bulb 160 is called a solid angle θ. Preferably, the dielectric mirror of the present invention has a circular plate shape formed perpendicular to the bulb support, and the size of the dielectric mirror should be such that its diameter can reflect all of the light in the solid angle θ. In other words, the diameter of the dielectric mirror should be such that a virtual line connecting the point where the resonator and the resonator mounting portion are in contact with the center of the bulb may pass through the surface of the dielectric mirror.

Therefore, the diameter should be larger as the dielectric mirror is located away from the electrodeless bulb and disposed closer to the resonator mounting portion, and conversely, the diameter will be smaller as the dielectric mirror is positioned closer to the electrodeless bulb. The electrodeless bulb, the dielectric mirror, and the bulb support are preferably all formed integrally, but may be coupled to each other in a separately formed state.

In the above, the case in which the dielectric mirror has a circular plate shape formed perpendicular to the bulb support has been described, but is not necessarily limited thereto. Therefore, the dielectric mirror may have a circular plate shape formed perpendicular to the bulb support, and a bent surface bent toward the bulb may be formed at an edge thereof. In addition, the dielectric mirror may be formed in a curved shape having a predetermined surface in the bulb support.

In the electrodeless lighting device of the present invention as described above, while reducing the material cost by reducing the size of the dielectric mirror, it exhibits the same effect of passing the microwave and reflecting the light emitted from the electrodeless bulb, in particular through-holes in the dielectric mirror Since it does not have to reduce the time and cost required for manufacturing.

The electrodeless illuminator as described above is operated as follows.

That is, when a driving signal is input to the high voltage generator 120, the high voltage generator 120 boosts AC power to supply the boosted high voltage to the magnetron 130, and the magnetron 130 oscillates by the high voltage. Generate microwaves with very high frequencies.

The microwaves are emitted to the outside of the magnetron 130 through the antenna of the magnetron 130, and the emitted microwaves are impedance-matched by the microwave matching member (not shown) of the magnetron 130. 140). The microwave guided to the waveguide 140 is guided and radiated into the resonator 150 through the waveguide space S of the waveguide, and a resonance mode is formed inside the resonator 150 by the radiated microwaves. . The luminescent material charged in the electrodeless bulb 160 is excited by the resonance mode formed inside the resonator 150 to emit light having a unique emission spectrum while being continuously plasmaized. The motor M rotates the bulb support 190 at a constant speed, and the electrodeless bulb 160 and the dielectric mirror 180 formed integrally with the bulb support also rotate at a constant speed. In addition, the light emitted from the electrodeless bulb is prevented from being absorbed backward by the dielectric mirror 180 according to the present invention, that is, the waveguide, and is reflected by the reflector 170 and the dielectric mirror 180 toward the front of the lighting device. It is to illuminate the space ahead.

1 is a general shape of a conventional electrodeless lighting device,

2 is a cross-sectional view of an electrodeless lighting device according to an embodiment of the present invention,

3 is a partial detailed view of FIG. 2;

4 is a view illustrating an electrodeless light bulb and a dielectric mirror integrally connected thereto according to an embodiment of the present invention.

5 to 6 are views of an electrodeless light bulb and a dielectric mirror integrally connected thereto according to another embodiment of the present invention.

Claims (7)

A resonator in which microwaves are introduced and resonate; An electrodeless light bulb which is installed inside the resonator and emits light by microwaves in which a light emitting material is filled and resonates therein; A motor for rotating the bulb; And A light bulb support having one end connected to the motor and the other end connected to the bulb to transmit rotational force of the motor to the bulb; And a dielectric mirror formed integrally with the bulb support and allowing microwaves to pass while reflecting light from the bulb. The method of claim 1, The resonator is a cylindrical mesh structure, the electrodeless illuminator further comprises a resonator mounting portion for attaching and fixing one end of the resonator. The method of claim 2, And the dielectric mirror is spaced apart from the resonator mounting part by a predetermined distance and is provided between the resonator mounting part and the bulb. The method of claim 2, The dielectric mirror is an electrodeless lighting device, characterized in that the circular plate shape formed perpendicular to the bulb support. The method of claim 2, The dielectric mirror has a circular plate shape formed perpendicular to the bulb support, the electrodeless illumination device, characterized in that the bent surface bent toward the bulb is formed at the edge. The method of claim 2, The dielectric mirror is an electrodeless lighting device, characterized in that formed in a curved shape having a predetermined surface in the bulb support. The method according to any one of claims 4 to 6, The diameter of the dielectric mirror, the electrodeless illumination device, characterized in that the imaginary line connecting the point where the resonator and the resonator mounting portion in contact with the center of the bulb can pass through the surface of the dielectric mirror.

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