KR100498399B1 - Insulation structure of wave guide for electrodeless lighting system - Google Patents

Abstract

The present invention relates to an insulation structure of a waveguide for an electrodeless lighting device, and has an inlet portion penetrating through one side to insert and insert a microwave generation portion of a magnetron, and a space portion for guiding the microwave portion into the oscillated portion from the inlet portion. A waveguide for an electrodeless lighting device having an outlet portion formed with a guide microwave excited to excite the light emitting material inside the bulb, wherein the waveguide includes an insulating layer around an inner circumferential surface of the inlet portion. Heat is formed by microwaves that penetrate through one side of the inner space of the inner portion of the magnetron and form a local insulation layer around the inlet portion to which the microwave generator is inserted and coupled. To prevent the occurrence of To prevent the magnetron is broken by the heat has an effect.

Description

INSULATION STRUCTURE OF WAVE GUIDE FOR ELECTRODELESS LIGHTING SYSTEM}

The present invention relates to an electrodeless lighting device, and more particularly, most of the microwaves applied to the resonator by impedance mismatching at the initial stage of the emission of light bulbs are reflected and returned to the magnetron to increase the temperature around the magnetron's antenna. It relates to a waveguide insulating structure of an electrodeless lighting device for preventing the life of the.

In general, the ELECTRODELESS LIGHTING SYSTEM transmits the electromagnetic energy generated from the microwave generator to the resonator through the waveguide, which is applied to the electrodeless bulb installed inside the resonator so that the bulb emits visible or ultraviolet light. As an illuminating device, it has a long life compared to incandescent and fluorescent lamps, and has an excellent effect of lighting.

Hereinafter, a conventional electrodeless illuminator will be described with reference to the drawings. 1 is a longitudinal cross-sectional view of a conventional electrodeless lighting device. As shown in the figure, the magnetron 102 mounted inside the casing 101 to generate microwaves, the high pressure generator 103 for boosting and supplying commercial AC power to the magnetron 102 at high pressure, and the magnetron ( The microwave part generator 102a of the 102 is communicatively coupled to the waveguide 104 which delivers the microwaves generated by the microwave generator 102a, and the light emitting material is sealed in the inside of the waveguide 104. The light bulb 105 generates light while the material encapsulated by the transmitted microwave energy is plasma-formed, and the light is emitted from the light bulb 105 while blocking the microwaves by blocking the waveguide 104 and the light bulb 105. Is mounted inside the resonator 106 through which the silver passes, the reflector 107 which receives the resonator 106 and intensively reflects light generated by the light bulb 105, and the inside of the resonator 106 behind the light bulb 105. So Passing the micro wave while light is composed of a reflective dielectric mirror 108 and, by having at one side of the casing 101, the magnetron 102 and the high-voltage generator 103, a cooling fan assembly 113 for cooling to.

In the drawings, reference numeral 109 denotes an electric bulb rotation motor, 109a a motor shaft, 110 a fan motor, 111 a cooling fan, 112 a cooling fan housing, 112a a suction hole, and 112b a discharge hole.

By such a configuration, the conventional electrodeless lighting device boosts the applied commercial power in the high pressure generator 107 to supply the boosted high voltage to the magnetron 101, and the magnetron 101 supplies the high voltage generator 103. Oscillation by the high pressure supplied from generates microwaves having a very high frequency, and the generated microwaves are discharged into the resonator 106 through the waveguide 104 to discharge the encapsulated material in the bulb 105 It generates light having a unique emission spectrum, and the light generated from the bulb 105 is reflected forward through the dielectric mirror 108 and the reflector 107 to illuminate the space.

However, the impedance inside the resonator 106 varies greatly depending on the state of the bulb 105. That is, since the impedance of the cold state in which the light bulb 105 does not emit light and the state in which the discharge is started inside the light bulb 105 immediately after light emission and the state in which the light bulb 105 maintains stable light emission differ greatly, When matching for a particular state, it is difficult to simultaneously satisfy the impedance matching in the resonator 106 according to the state of each bulb 105 because impedance matching in other states is significantly shifted.

Therefore, the microwaves are mismatched at the beginning of the light emission of the bulb, so that most of the microwaves applied to the resonator are reflected and returned to the magnetron, which causes the operation of the magnetron to become unstable or oscillates abnormally. There is a problem that the temperature of the magnetron is raised to greatly shorten the life of the magnetron.

According to the present invention devised to solve the above problems, a waveguide for an electrodeless lighting device for preventing damage caused by the microwave reflected back to the oscillator according to the imbalance of the impedance matching inside the resonator during the initial emission of the electrodeless lighting device It is an object to provide an insulating structure.

In order to achieve the above object, the present invention, the inlet is provided through one side to be inserted and coupled to the microwave generating portion of the magnetron, a space portion for guiding the microwave in the oscillated from the inlet is formed, A waveguide for an electrodeless lighting device having an exit portion in which a resonator is communicatively coupled so that microwaves are excited to emit an encapsulation material inside a bulb, the waveguide being caused by the concentration of microwaves reflected by the impedance mismatching inside the resonator. It is achieved by the insulating structure of the waveguide for an electrodeless lighting device, characterized in that an insulating layer is provided to insulate around the inner circumferential surface of the inlet to prevent breakage.

Here, the insulating layer is preferably formed of a coating formed of a synthetic resin resistant to heat.

Hereinafter, the insulation structure of the waveguide for an electrodeless lighting device of the present invention will be described in detail with reference to the accompanying drawings.

Hereinafter, the waveguide for an electrodeless lighting device of the present invention will be described with reference to the accompanying drawings. Figure 2 is a longitudinal sectional view of the electrodeless illuminator of the present invention, Figure 3 is an exploded perspective view of the waveguide of the electrodeless illuminator of the present invention, Figure 4 is a side cross-sectional view of the waveguide for the electrodeless illuminator of the present invention, Figure 5 4 is a cross-sectional view taken along the AA portion of FIG. 4, and FIG. 6 is an enlarged cross-sectional view taken along a portion B of FIG. 4.

As shown in the drawing, the electrodeless lighting device of the present invention has a magnetron 2 mounted inside the casing 1 to generate microwaves, and a high voltage for boosting and supplying commercial AC power to the magnetron 2 at a high pressure. The waveguide 4 communicates with the generator 3, the outlet of the magnetron 2, and delivers the microwaves generated by the magnetron 2, and the micro-encapsulated light-emitting material inside the waveguide 4; The light bulb 5 generates light while the material encapsulated by the wave energy is plasma-formed, and is covered in front of the waveguide 4 and the light bulb 5 to block microwaves while passing the light emitted from the light bulb 5. And a resonator (6), a dielectric mirror (8) which is mounted inside the resonator (6) at the rear side of the bulb (5), and reflects light while microwaves pass therethrough, and accommodates the resonator (6) in the bulb (5). Let the light go straight And it provided at one side of the reflector 7 and the casing (1) for reflecting one consists of a cooling fan assembly 13 for cooling the magnetron 2 and the high-voltage generator (3).

As shown in FIG. 2 or FIG. 3, the waveguide 4 has a main body portion 4a for guiding microwaves generated from the magnetron 2 provided at a side thereof, and an upper side of the main body portion 4a. The cover 4b is coupled to the flange and transmits the microwaves into the resonator 6 through an outlet portion 4c extending upward.

The main body portion 4a has a cylindrical space portion 4h formed therein to form a passage through which microwaves are transmitted, and an electric bulb rotating motor for rotating and cooling the light bulb inside the space portion 4h. The motor shaft accommodating part 4d which accommodates the motor shaft 9a of 9 through is formed.

In addition, a coupling surface 4e to which the magnetron 2 is coupled is formed on an outer side surface of the cylinder forming the space portion 4h, and penetrates through the center of the coupling surface 4e of the magnetron 2. An inlet portion 4f into which the microwave output portion 6a is inserted and coupled is formed, and the microwaves introduced through the inlet portion 4f are blocked off through the outlet portion 4c of the cover portion 4b. A wall 4g is formed, and a first flange portion 4i is formed along the upper outer circumferential surface to fix the cover portion 4b.

In addition, the cover part 4b is formed with a second flange part 4j coupled to correspond to the first flange part 4i of the main body part 4a to cover the upper opening of the main body part 4a, An outlet portion 4h is formed which protrudes above the center of the second flange portion 4j to communicate with the resonator 6.

In addition, in order to prevent the heat generated by the returning microwave reflected by the impedance ratio matching of the initial stage of light emission of the bulb 5 to the inner space 4c around the inlet of the main body 4a, It is characterized in that the insulating layer 20 is formed with a coating.

The insulating layer 20 is formed of a synthetic resin series having a strong resistance to heat such as teflon, myler, glassine, and the like.

In the drawings, reference numeral 10 denotes a fan motor, 11 a cooling fan, 12 a cooling fan housing, 12a a suction hole, and 12b a discharge hole.

By such a configuration, the electrodeless illuminator of the present invention will be described as follows.

 First, when a commercial power is applied to the high voltage generator 3 accommodated inside the case 1 to boost the high voltage, a high voltage is generated, and the high voltage generated as described above is supplied to the magnetron 2, and the high voltage applied to the magnetron 2 is applied. By the microwave generated by the microwave generation unit 2a coupled to the inlet portion of the waveguide.

Then, the microwaves oscillated by the microwave generator 2a are guided through the inner space 4c of the waveguide 4, and are transferred into the resonator 6 extending and coupled to the outlet 4h. As a result, the inert gas enclosed in the bulb 5 is maintained in an extremely ionized plasma state so that the metal compound generates continuous light.

At this time, the bulb 5 generates heat around the inlet part by concentrating on the microwaves reflected by the impedance ratio matching inside the resonator during initial emission, thereby shortening the life of the magnetron.

Accordingly, heat generation is prevented by an insulation layer coated locally around the inlet, and heat is prevented from being transferred to the magnetron to prevent breakage.

Then, the impedance matching in the stable state after the light emission of the bulb 5 starts is made, and the amount of heat generated by the microwaves reflected from the resonator is reduced.

On the other hand, the light generated by the light bulb 5 is collected by the dielectric mirror 8 and the reflection shade 7 and is reflected into the life pipe (not shown) coupled to the front of the reflection shade 7 proceeds while being partially transmitted. I light up the environment.

As described above, according to the present invention, by matching the impedance ratio generated during the initial light emission of the bulb by forming a local insulating layer around the inlet portion through which the microwave generating portion of the magnetron penetrates through one side of the inner space portion of the waveguide It is effective to prevent heat from being generated by the microwaves reflected by the microwaves and to prevent the magnetron from being damaged by the generated heat.

1 is a longitudinal sectional view of a conventional electrodeless illuminator,

2 is a longitudinal sectional view of the electrodeless illuminator of the present invention;

3 is an exploded view of the waveguide of the electrodeless illuminator of the present invention;

4 is a longitudinal sectional view of the waveguide of the electrodeless illuminator of the present invention;

5 is a cross-sectional view A-A portion of FIG.

* Description of the main parts of the drawings *

1: casing 2: magnetron

3: high pressure generator 4: waveguide

4a: main body 4b: cover

4c: space portion 4d: motor shaft accommodation portion

4e: mating surface 4f: inlet

4g: barrier wall 4h: outlet portion coupled

4h: exit section 4i: first flange section

4j: second flange portion 5: light bulb

6: resonator 6a: microwave output

7: reflection shade 8: dielectric mirror

20: insulation layer

Claims (2)

An inlet part is provided through one side to be inserted and coupled to the microwave generating part of the magnetron, and a space part for guiding the microwaves is formed in the oscillated inside the inlet part, and the guided microwave is excited to encapsulate the inside of the bulb. In the waveguide for an electrodeless lighting device, the outlet portion is formed in which the resonator is coupled in communication so as to emit light, The waveguide is provided for an electrodeless lighting device, characterized in that it is provided with an insulating layer to insulate around the inner peripheral surface of the inlet to prevent damage to the magnetron and the resonator due to the concentration of microwaves reflected by the impedance mismatching inside the resonator Insulation structure of waveguide. The method of claim 1, The insulating layer is an insulating structure of a waveguide for an electrodeless lighting device, characterized in that the coating is formed of heat-resistant synthetic resin series.