KR100421387B1 - Wave guide structure of microwave lighting system - Google Patents

Abstract

The present invention relates to a waveguide structure of a lighting system using microwaves, the present invention relates to a magnetron for generating microwaves, a waveguide for inducing microwaves to the resonator by communicating with the outlet of the magnetron and the inlet of the resonator, and a waveguide In a lighting system using a microwave including a light bulb excited by a microwave induced in the light emitting material and a resonator that receives a light bulb and traps the light while the light is emitted from the light bulb, the waveguide is directed in the direction of light irradiation. It is formed into a long rectangular shape to form an inlet and an outlet on both sides, and the magnetron is connected to the inlet of one side, while the other side of the outlet is configured to communicate with the resonator, thereby reducing the overall width of the lighting system Use lighting devices even when the installation space is narrow It can be installed.

Description

Waveguide structure of lighting system using microwaves {WAVE GUIDE STRUCTURE OF 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, which is suitable for reducing the width of a system in consideration of constraints on 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 inside 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 is formed in a cylindrical shape with a through hole 4a through which the shaft portion 5b of the light bulb 5 penetrates in the center thereof, and the outlet (antenna) 2a of the magnetron 2 is formed on the main wall thereof. An inlet portion 4b communicating therethrough is formed, and an outlet portion 4c through which microwaves pass through is formed on one side coupled to the resonator 6.

In the drawings, reference numeral M denotes a light bulb 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 3, the high pressure generator 3 boosts AC power to supply the boosted high pressure to the magnetron 2, and the magnetron 2 oscillates by the high pressure. Generates microwaves with a high frequency, the microwaves radiate through the waveguide 4 into the resonator 6 to discharge the encapsulated material in the bulb 5 to generate light having a unique emission spectrum, This light brightened the space while reflecting forward by the reflector 7.

However, in the conventional microwave lighting system as described above, since the magnetron 2 is mounted on the circumferential wall of the waveguide 4, the width of the entire system is increased by the width of the magnetron 2, and the installation area is limited. In the above there was a problem that comes with constraints in installing the above lighting system.

The present invention has been made in view of the problems of the conventional microwave lighting system as described above, to provide a waveguide structure of the lighting system using a microwave to be suitable for installation in a narrow space of the installation space. There is this.

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

Figure 2 is a longitudinal sectional view shown to explain the waveguide in the conventional illumination system using microwaves.

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

Figure 4 is a longitudinal sectional view shown to explain the waveguide in the lighting system using the present invention microwave.

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

10: casing 11: air passage section

11a: air inlet 12: air guide

20: magnetron 30: high pressure generator

40: waveguide 41: inlet

42 outlet portion 43 through hole

50 light bulb 51 light emitting unit

52: shaft 53: bulb motor

60: resonator 70: reflector

80: cooling fan assembly 81: cooling fan

82: fan motor M: mirror

In order to achieve the object of the present invention, the magnetron generating a microwave and the magnetron is formed in a rectangular shape so that the outlet portion of the magnetron communicates laterally with respect to the irradiation direction of light and the inlet of the resonator communicates in a straight line with respect to the irradiation direction of light. Waveguide that induces microwaves generated by the resonator, microwaves excited by the microwaves induced in the waveguide, and a light emitting material that encapsulates the light, and a microwave including a resonator that receives the light bulb and confines the microwave while transmitting light In the lighting system, the waveguide provides a waveguide structure of a microwave system using a microwave, characterized in that the cross-sectional area of the end portion of the resonator is gradually enlarged toward the magnetron toward the resonator.

EMBODIMENT OF THE INVENTION Hereinafter, the waveguide structure of the illumination system using the microwave which concerns on this invention is demonstrated in detail based on one Example shown in an accompanying drawing.

Figure 3 is a longitudinal cross-sectional view showing an example of the illumination system using a microwave of the present invention, Figure 4 is a longitudinal sectional view shown to explain the waveguide in the illumination system using a microwave of the present invention.

As shown therein, the illumination system using microwaves according to the present invention includes a casing 10 having an inner space and having air inlets 11a and air outlets (not shown) communicating with the interior spaces, respectively; A magnetron 20 mounted inside the casing 10 to generate microwaves, and a high pressure generator 30 arranged in line with the magnetron 20 so as to boost and supply commercial AC power to the magnetron 20 at high pressure; The waveguide 40 communicates with the outlet of the magnetron 20 and transmits the microwaves generated by the magnetron 20, and the magnetron 20 and the high pressure generator 30 are arranged in line and enclose a light emitting material therein. The material encapsulated by the microwave energy transmitted through the waveguide 40 is covered with a light bulb 50 for generating light while plasma is formed, and the front of the waveguide 40 and the light bulb 50 to block microwaves. The light emitted from the light bulb 50 passes through the resonator 60, the reflector 70 that receives the resonator 60 and reflects the light generated by the light bulb 50 to go straight, the magnetron 20, and the high pressure generator. (30) and arranged in line with the bulb 50 is composed of a cooling fan assembly 80 for cooling the inside of the casing (10).

The casing 10 has a longitudinal shape that is long in the longitudinal direction with respect to the bulb so that the air passage part 11 receives the magnetron 20, the high pressure generator 30, and the cooling fan assembly 80 sequentially from the bulb 50 side. ).

A cooling fan 81 is mounted on the inner surface of the air inlet 11a so that the inlet side of the cooling fan 81 to be described later corresponds, and the dust contained in the air when the air is inhaled on the outer surface of the air inlet 11a. It is preferable to mount an air filter (not shown) to filter out the back.

The air inlet 11a may be formed at one end surface of the air passage part 11, but may be formed at each side of one end in some cases.

In addition, the air flowing into the air passage portion 11 through the air inlet 11a is collected between the middle portion of the air passage portion 11, that is, the high pressure generator 30 and the magnetron 20, to the magnetron 20. An air guide 12 having an air guide 12a in the center portion is also formed in the transverse direction so as to concentrate supply.

The magnetron 20 is disposed in line with the light bulb 50, and is coupled to the side surface of the waveguide 40 in the width direction in consideration of the waveguide 40 being formed in a long rectangular shape in the longitudinal direction.

The high pressure generator 30 is disposed in a line with the magnetron 20 with the air guide 12 therebetween and fixedly installed therein.

The waveguide 40 is formed in the shape of a 'memory' cross section in planar projection, one side of which passes through the shaft portion 52 of the bulb 50 to be described later in the longitudinal direction, and the other side of the outlet of the magnetron 20 in the width direction ( Antenna) 21. The waveguide 40 is formed in a long rectangular shape in the direction of light irradiation as shown in Fig. 4, and forms an inlet portion 41 and an outlet portion 42 on both sides thereof. The inlet portion 41 on one side communicates with the antenna 21 of the magnetron 20, while the outlet portion 42 on the other side is coupled to communicate with the opening side of the resonator 60. Waveguide 40 Silver is formed in the same cross-sectional area from the inlet side to a predetermined length, but after that to form an extended portion (unsigned) by gradually increasing the cross-sectional area toward the outlet 42. It is preferable to form this extension eccentrically in the direction of the magnetron 20 so that the center of the reflector 70 including the bulb 50 can be placed in the center of the system, so that the entire system can be miniaturized.

The light bulb 50 includes a light emitting portion 51 formed in a 'sphere' shape to enclose a light emitting material, and a shaft portion 52 welded to the light emitting portion 51 and extending into the casing 10.

The shaft portion 52 of the bulb 50 penetrates one side of the waveguide 40 in the longitudinal direction and is coupled to the bulb motor 53 whose end rotates the bulb 50 at the middle of the magnetron 20.

The cooling fan assembly 80 is coupled to the cooling fan 81 which is fixed to the inner surface of the air inlet 11a provided in the air passage part 11 of the casing 10 and the rotation center of the cooling fan 81. It consists of a fan motor 82 mounted inside one air passage section 11.

Reference numeral 43 in the figure denotes a through hole through which the shaft portion of the bulb penetrates, and M denotes a mirror that passes through microwaves but reflects light.

That is, when the high voltage generator 30 boosts AC power and supplies high pressure to the magnetron 20, the magnetron 20 generates microwaves by oscillating by high pressure, and the microwaves generate the resonator 60 through the waveguide 40. Radiating inside to discharge the encapsulated material in the bulb 50 to generate light, the light reflects forward by the reflector 70 and the mirror (M) to brighten the space.

At this time, when the fan motor 82 is driven by the controller to rotate the cooling fan 81 which is an axial flow fan, external air is driven by the cooling fan 81 through the air inlet 11a of the air passage part 11. After cooling, the high pressure generator 30 and the magnetron 20 are cooled and discharged to the outside of the casing 10 through the other air outlet (not shown).

Here, the waveguide 40 is formed long in the irradiation direction of the light and mounted so as to communicate with the magnetron 20 on the side, and the outlet side for coupling the resonator 60 is formed eccentrically extending toward the magnetron 20 to form the center of the system Combining the light bulb on the side in the irradiation direction of the light, and combining the resonator 60 and the reflector 70 including the light bulb 50 to almost coincide with the center line of the above system, and the center line of the light bulb 50. By installing the high pressure generator 30 and the cooling fan 81 in a straight line, the width of the illumination system using microwaves can be greatly reduced. Moreover, as the outlet side of the waveguide 40 is expanded, a relatively large diameter is formed. The resonator 60 can be easily and tightly assembled.

In the illumination system using microwaves according to the present invention, the waveguide is formed long in the irradiation direction of the light, and the outlet side is eccentrically formed so that the bulb, the magnetron, the high pressure generator, and the cooling fan are arranged in a line, so that the entire illumination system is provided. By reducing the width, the lighting device can be easily installed even when the installation space is narrow.

Claims (2)

A magnetron that generates microwaves and a waveguide that induces microwaves generated in the magnetron to the resonator by forming a rectangle so that the outlet portion of the magnetron communicates laterally with respect to the irradiation direction of light and the inlet of the resonator communicates in a straight line with respect to the irradiation direction of light. In the lighting system using a microwave including a light bulb which is excited by a microwave induced in the waveguide and the encapsulating material emits light, and a resonator which receives the light bulb and traps the microwave while transmitting light from the light bulb, The waveguide is a waveguide structure of a lighting system using microwaves, characterized in that the cross-sectional area of the end portion of the resonator toward the resonator gradually expands eccentrically toward the magnetron. The method of claim 1, The light bulb extends the shaft portion from the light emitting portion in which the light emitting material is enclosed, and the shaft is coupled to penetrate the extension portion of the waveguide.