KR100393818B1 - Microwave lighting system - Google Patents

Abstract

The present invention relates to a lighting system using a microwave, the present invention is equipped with a magnetron for generating a microwave, a magnetron is installed so as to communicate with the magnetron is enclosed with a resonator through which the microwave is condensed and the light, and a light emitting material that is excited by the microwave to emit light And a circular polarization generator for converting microwaves into circularly polarized waves interposed between the magnetron and the resonator between the magnetron and the resonator, thereby miniaturizing the system and allowing the microwaves to be circularly polarized into the resonator. Light uniformity is improved by plasma-forming the light-emitting material that is introduced into the bulb evenly.

Description

Lighting system using microwaves {MICROWAVE LIGHTING SYSTEM}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lighting system using microwaves, and more particularly, to a lighting system using microwaves suitable for reducing the width of the system and increasing the light uniformity in consideration of the limitation of the installation space.

In general, a luminaire using microwaves is a device that applies microwaves to an electrodeless plasma bulb and emits visible or ultraviolet light therefrom, and has a longer lamp life and superior lighting effects than conventional incandescent or fluorescent lamps. .

1 is a longitudinal sectional view showing an example of an illumination system using microwaves.

As shown in the drawing, a conventional microwave lighting system includes a magnetron 2 mounted inside the casing 1 to generate microwaves, 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) communicating with the outlet of the magnetron (2) to transmit microwaves generated by the magnetron (2), and microwave energy enclosed with a luminescent material therein and transmitted through the waveguide (4). The light bulb 5 which emits light while the encapsulated material is excited and is converted into plasma, and the light emitted from the light bulb 5 while covering the waveguide 4 and the light bulb 5 in front of the waveguide 4 are blocked. A resonator 6 passing through, a reflector 7 which receives the resonator 6 and concentrates and reflects light generated from a light bulb, and a magnetron 2 and a high pressure generator 3 on one side of the casing 1 Cooling) Consists of a cooling fan assembly (8).

The waveguide 4 has a predetermined inner space and is formed in an annular shape, and the resonator 6 is communicatively coupled to one side thereof, and the outlet portion of the magnetron 2 is inserted into and coupled to one circumferential wall of the magnetron 2. On the opposite circumferential side, the high pressure generator 3 is provided.

The light bulb 5 is welded to the light emitting portion 5a and the light emitting portion 5a in which the light emitting material is enclosed, and passes through the central opening side of the waveguide 4 as described above. It consists of the shaft part 5b couple | bonded with ().

In the figure, reference numeral 8a denotes a fan housing, 8b a cooling fan, and 8c a fan motor.

The lighting system using the conventional microwave as described above operates as follows.

That is, when the control unit inputs a driving signal to the high pressure generator 2, the high pressure generator 2 boosts AC power to supply the boosted high pressure to the magnetron 1, and the magnetron 1 oscillates by the high pressure. Produces microwaves having a high frequency, the generated microwaves discharge through the waveguide 4 into the resonator 3 and discharge the encapsulated material in the bulb 5 to generate light having a unique emission spectrum, This light was reflected by the reflector and the dielectric mirror (M) to the front to brighten the space.

However, the above-described conventional microwave illumination system uses a waveguide between the magnetron 2 and the resonator 6 to form a cylindrical shape for inducing microwaves, and thus has a predetermined internal space. As the overall size of the system increased by the volume of (4), there was a limit in miniaturizing the product.

In addition, in the conventional waveguide 4, the microwave oscillates in the form of a linear polarization wave, which has the characteristic that the magnitude of the electric field is adjusted only in one direction on a plane perpendicular to the propagation direction of the radio wave. Therefore, there is a problem that the light uniformity is lowered as microwaves do not uniformly excite the light emitting material inside the bulb because strong and weak portions are generated due to mutual interference.

The present invention has been made in view of the problems of the conventional lighting system using a microwave as described above, to provide a lighting system using a microwave that can reduce the total area of the waveguide to minimize the size of the system to minimize the object of the present invention. There is this.

Another object of the present invention is to provide an illumination system using microwaves that can improve light uniformity by causing the microwaves oscillating in the magnetron to radiate to the resonator in a circular polarization form.

1 is a longitudinal sectional view showing an example of a lighting system using a conventional microwave.

Figure 2 is a partial longitudinal cross-sectional view showing an example of the illumination system using the present invention microwave.

Figure 3 is a longitudinal sectional view showing an example of a waveguide in the illumination system using the present invention microwave.

Figure 4 is a perspective view showing an example of a waveguide in the lighting system using the present invention microwave.

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

1: casing 2: magnetron

5 bulb 6 resonator

7 reflector 10 circular polarization generator

11: circularly polarized feeder 11a: shortened groove

12: ground plate 12a: antenna through hole

12b: fastening hole 13: center pin

In order to achieve the object of the present invention, a magnetron for generating a microwave, and a magnetron is installed so as to communicate with the magnetron to enclose a resonator through which the microwave is confined and light, and a light emitting material that is excited by the microwave to be contained within the resonator It provides a lighting system using a microwave including a light bulb, and a circular polarization generating means for converting the microwave into a circular polarization form interposed between the magnetron and the resonator.

Hereinafter, a lighting system using a microwave according to the present invention will be described in detail based on an embodiment shown in the accompanying drawings.

2 is a partial longitudinal sectional view showing an example of a lighting system using a microwave of the present invention, Figure 3 is a longitudinal sectional view showing an example of a waveguide in the lighting system using a microwave of the present invention, Figure 4 is a lighting system using a microwave of the present invention Is a perspective view showing an example of a waveguide.

As shown in the drawing, the illumination system using microwaves according to the present invention includes a magnetron 2 mounted inside the casing 1 to generate microwaves, and boosting and supplying commercial AC power to the magnetron 2 at high pressure. The high-pressure generator (not shown) and the light-emitting material are sealed inside, and the material encapsulated by the microwave energy generated by the magnetron 2 is converted into a plasma to generate light while covering the front of the light bulb 5 and the light bulb 5. The microwave generated by the magnetron 2 is interposed between the magnetron 2 and the resonator 6 and the resonator 6 through which the light emitted from the light bulb 5 passes while being coupled to the casing 1 to block the microwave. A circular polarization generator 10 for converting the circular polarization to a circular polarization, and a reflector 7 for receiving the resonator 6 and reflecting the light generated from the light bulb 5 to go straight.

The magnetron 2 is in close contact with the bottom surface of the ground plate 12 of the circularly polarized wave generator 10 which will be described later, and the antenna 2a, which is an exit portion thereof, passes through the antenna through hole 12a provided in the ground plate 12 and has a circular polarization. Inserted into the antenna connection (not shown) provided on the bottom of the feeder (11).

The light bulb 5 includes a light emitting portion 5a formed in a 'sphere' shape to enclose a light emitting material, and a shaft portion 5b extending to the inside of the casing 1 by welding to the light emitting portion 5a.

The shaft portion 5b sequentially penetrates through the circular polarization feeder 11 and the ground plate 12 of the circular polarization generator 10, which will be described later, and its end is connected to the rotating shaft of the electric bulb motor (not shown) inside the casing 1. To combine.

As shown in FIGS. 3 and 4, the circularly polarized wave generator 10 is formed in a disk shape and forms different axis lengths of a short axis (a) and a long axis (b) orthogonal to a plane to exit the magnetron 2. The circular polarization feeder 11 to which the negative antenna 2a is coupled, and the ground plate to which the antenna 2a of the magnetron 2 is penetrated and connected to one side of the circular polarization feeder 11 at predetermined intervals ( 12).

The circularly polarized feeder 11 is formed in a circular shape so as to be inserted into the resonator 6, and forms shortened grooves 11a and 11a so that the outer peripheral surfaces of both ends of one of two axes orthogonal to each other in a plane are engraved. In addition, a center pin 13 connected to the ground plate 12 described above is press-fitted at the center of the circularly polarized feeder 11. The center pin 13 may vary its position depending on the type of bulb.

In addition, the circularly polarized feeder 11 protrudes from the antenna coupling portion (not shown) coupled to the antenna 2a of the magnetron 2 on one side of the bottom surface so that the feeding point P2 is formed on one side of the upper surface thereof.

The ground plate 12 forms an antenna through hole 12a through which the antenna 2a of the magnetron 2 penetrates in the center thereof, and seals the opening side of the resonator 6 to cover the opening side end. Fasten the edge to the casing (1) in the state.

On the other hand, in the circular polarization feeder 11 and the ground plate 12, a bulb through-hole (not shown) is formed in a line so that the shaft portion 5b of the bulb 5 passes through, or the bulb 5 is circularly polarized. It may be arranged obliquely without passing through the generator 10.

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

In the figure, reference numeral 12b denotes a fastening hole, and P1 denotes a center point.

Effects of the lighting system using the present invention microwave as described above are as follows.

That is, the magnetron 2 generates microwaves while oscillating by high pressure, and the microwaves emit light into the resonator 6 through the circularly polarized feeder 11 to discharge the encapsulated material in the bulb 5 to generate light. This light illuminates the space while reflecting forward by the reflector 7 and the dielectric mirror M. FIG.

At this time, the microwaves oscillating in the magnetron (2) is a circularly polarized form in which the vector direction of the electric field rotates clockwise or counterclockwise with time on a plane perpendicular to the propagation direction of the radio wave while passing through the circular plate feeder (11). As a result, the microwaves uniformly come into contact with the entire light emitting portion 5a of the light bulb 5, and the light emitting material enclosed therein also emits light uniformly while making the plasma light emitting portion 5a of the light bulb 5 uniform. The optical uniformity of the light generated by the NW is increased, which greatly improves the reliability of the system.

Meanwhile, a circularly polarized feeder 11 which is a part of the circularly polarized wave generator 10 positioned between the magnetron 2 and the resonator 6 is formed into a thin plate, inserted into the resonator 6, and the circularly polarized wave generator 10 is formed. The cylindrical ground waveguide 4 is secured to the casing 1 while the thin ground plate 12, which is another part of the ground plate 12, is brought into close contact with the end of the resonator 6, and the magnetron 2 is tightly assembled to the bottom of the ground plate 12. The space occupied by this magnetron and the space occupied by the magnetron 2 in the width direction are significantly reduced, so that the overall size of the system can be reduced.

The illumination system using microwaves according to the present invention is configured through a circular polarization generator having a patch structure between the magnetron and the resonator, thereby miniaturizing the system, and of course microwaves into the resonator in the form of circular polarization. Light uniformity is improved by plasma-forming the light-emitting material that is introduced into the bulb evenly.

Claims (5)

A magnetron that generates microwaves, Mounted in communication with the magnetron, the resonator that traps microwaves and passes light, A light bulb encapsulating a light emitting material that is excited by microwaves and accommodated inside the resonator, An illumination system using microwaves, including a circular polarization generator that converts microwaves into circularly polarized wave form between a magnetron and a resonator. The method of claim 1, The circular polarization generator is formed in a disk shape and differently formed axial lengths of both axes orthogonal to the plane to form a circular polarization feeder coupled to the outlet of the magnetron, An illumination system using a microwave, characterized in that consisting of a ground plate that is coupled through the outlet portion of the magnetron and connected at a predetermined interval on one side of the circularly polarized feeder. The method of claim 2, The circularly polarized feeder is formed in a circular shape, the illumination system using a microwave, characterized in that to form a groove dig the outer peripheral surface of both ends of any one of the two axes orthogonal to each other on the plane. The method of claim 2, Wherein the circularly polarized feeder is inserted into the interior of the resonator while the ground plate is a lighting system using a microwave, characterized in that the sealing coupled to one side of the resonator. The method of claim 1, The light bulb is composed of a light emitting portion encapsulated with a light emitting material, and a shaft portion coupled to the rotating shaft of the motor in combination with the light emitting portion, The axial part of the illumination system using a microwave, characterized in that formed through the circular polarization generator.