KR20020054162A - The microwave lighting apparatus - Google Patents

Abstract

The present invention relates to a lighting apparatus using microwaves, the configuration of which comprises a waveguide for transmitting microwaves generated from the magnetron; A light bulb which generates light while the encapsulating material is excited by the microwave energy transmitted through the waveguide; A resonator covering the waveguide and the light bulb and blocking the microwaves while passing the light emitted from the light bulb; By including the bulb position variable means connected to the bulb from the outside of the resonator or waveguide to change the bulb position in the resonator, it is possible to position the bulb in the optimum position where the microwaves are concentrated, the time to complete light emission during the initial start-up In this case, the light emission efficiency can be improved when the light emission is completed.

Description

Lighting device using microwaves {THE MICROWAVE LIGHTING APPARATUS}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lighting apparatus using microwaves, and more particularly, to a lighting apparatus using microwaves to obtain an optimal luminous efficiency by varying the position of the bulbs at initial startup and when the bulbs are fully lit when the bulb is cold.

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

1 is a cross-sectional view showing the internal structure of a lighting apparatus using microwaves.

The lighting apparatus using microwaves includes a magnetron (1) for generating microwaves, a waveguide (3) for transmitting microwaves from the magnetron (1), and a material enclosed therein by microwave energy transmitted through the waveguide (3). The light bulb 5 generates light while being plasmaized, and the resonator 10 covers the waveguide 3 and the light bulb 5 in front of the light bulb 5 to pass the light emitted from the light bulb 5 while blocking the microwaves. do.

The lighting apparatus using the microwave includes a high pressure generator 7 for boosting the commercial AC power to the magnetron 1 at a high pressure in the basic structure as described above, and the magnetron 1 and the high pressure generator 7. Various elements including a cooling device 9 for cooling, a reflector 11 for intensively reflecting light emitted from the bulb 5 forward, the high pressure generator 7, the cooling device 9, and the like. A control unit (not shown) is further configured.

When the illumination device using the microwave as described above inputs a driving signal to the high pressure generator 7 in the control unit, the high pressure generator 7 boosts AC power from the outside to supply the boosted high pressure to the magnetron 1.

The magnetron 1 generates a microwave having a very high frequency while oscillating by the high pressure supplied from the high pressure generator 7, and the generated microwave is radiated into the resonator 10 through the waveguide 3 The encapsulated material in (5) is discharged to generate light having a unique emission spectrum.

As such, the light generated from the bulb 5 is reflected forward through the mirror 12 and the reflector 11 to illuminate the illumination space.

Here, the bulb 5 generates a plasma while microwave energy in the resonator 10 excites the encapsulating material. At this time, since the bulb 5 generates a considerable amount of heat, the bulb motor 13 is disposed below the waveguide 3. ), And the bulb 5 is cooled by connecting the rotating shaft 14 between the bulb motor 13 and the bulb 5 to rotate the bulb 5.

On the other hand, as described above, the microwave to excite the encapsulation material in the bulb 5 to generate a plasma, the formation and size of the waveguide 3, the size and shape of the slot that is the outlet of the waveguide 3, the size of the resonator 10 and The density of the microwaves in the resonator 10 depends on the location or temperature of the bulb 5.

In particular, the position where the microwaves are concentrated depends on the temperature change inside the resonator 10, such as when the bulb 5 is cold at the initial startup and when the bulb 5 becomes high due to the generation of plasma.

However, in the conventional lighting apparatus using microwaves, the position where the microwaves are concentrated varies according to the temperature change in the resonator 10 as described above, but the bulb 5 in the resonator 10 is always in a fixed state. Since the position of the bulb 5 must be designed by selecting any one of an optimal position at initial startup and an optimal position at full emission, there is a problem that it is difficult to obtain the maximum luminous efficiency.

The present invention has been made to solve the above problems, by installing a bulb position variable means for changing the position of the bulb on the rotating shaft connecting the bulb motor and the bulb, the optimum position of the bulb during initial startup and full emission It is an object of the present invention to provide a lighting apparatus using a microwave so that the luminous efficiency can be improved.

1 is a cross-sectional view showing a lighting device using a microwave of the prior art,

2 is a cross-sectional view of a first embodiment showing a lighting apparatus using a microwave according to the present invention,

3 is a detail view of a portion “A” of FIG. 2;

4 is a cross-sectional view of a second embodiment showing a lighting apparatus using a microwave according to the present invention;

5 is a cross-sectional view of a third embodiment showing a lighting apparatus using a microwave according to the present invention.

<Explanation of symbols for the main parts of the drawings>

51: magnetron 53: waveguide

55 light bulb 56 reflector

57: high pressure generating unit 58: mirror

59 cooling device 60 resonator

62: bulb motor 65: rotating shaft

66: variable shaft 66a: long hole

67: fixed shaft 67a: stopper

70 control unit 80 bulb position variable mechanism

81: solenoid electromagnet 83: conductor portion

85: return spring 181: variable operating portion

182: variable motor 183: pinion

184: rack 281: solenoid actuator

283: variable force transmission lever

A lighting apparatus using a microwave of the present invention for realizing the above object is a waveguide for transmitting a microwave generated from the magnetron; A light bulb which generates light while the encapsulating material is excited by the microwave energy transmitted through the waveguide; A resonator covering the waveguide and the light bulb and blocking the microwaves while passing the light emitted from the light bulb; It is characterized in that it comprises a bulb position variable means connected to the bulb from the outside of the resonator or waveguide to change the bulb position in the resonator.

According to an embodiment of the present invention, the waveguide has a bulb motor installed at the lower portion thereof so as to rotate the bulb, and the bulb motor and the bulb are connected to a rotating shaft passing through the waveguide; The bulb position variable means includes a variable shaft and a fixed shaft coupled to each other so that the rotating shaft is divided and constrained in the rotational direction and relatively movable within a predetermined range in the axial direction, and installed in the center hole of the waveguide. It consists of a variable operating means for linearly moving the variable shaft connected to.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

FIG. 2 is a sectional view of a first embodiment in which a lighting apparatus using microwaves according to the present invention is shown, and FIG. 3 is a detail view "A" of FIG.

The lighting apparatus using the microwave of the present invention includes a magnetron 51 for generating microwaves, a high voltage generator 57 for boosting a commercial AC power to the magnetron 51 at a high pressure, and a microwave from the magnetron 51. The waveguide 53 for transmitting, the light bulb 55 for generating light while the material encapsulated therein by the microwave energy transmitted through the waveguide 53 generates light, and the waveguide 53 and the light bulb 55 A resonator 60 positioned at the front side to block the microwaves while passing the light emitted from the bulb 55, and a bulb 55 in the resonator 60 connected to the bulb 55 outside the resonator 60. It consists of the bulb position variable mechanism 80 which changes a position.

In FIG. 2, reference numeral 56 denotes a reflecting mirror that concentrates the light generated by the light bulb 55 in the forward direction, 58 denotes a mirror that reflects light generated by the light bulb 55 while microwaves pass through, and 59 denotes the mirror. A cooling device for cooling the magnetron 51 and the high pressure generator 57, etc., 70 is a control unit for controlling the high pressure generator 57, the cooling device 59, the bulb position variable mechanism (80) and the like.

The waveguide 53 has a central hole portion 53a communicating with the outside at the center thereof, and a bulb motor 62 is installed at the bottom thereof so as to rotate the bulb 55. The light bulb 55 is connected to the rotation shaft 65 passing through the central hole portion 53a of the waveguide 53.

In particular, the bulb position variable mechanism 80 is a variable shaft coupled to each other such that the rotary shaft 65 is divided and constrained in the rotational direction and relative movement within a predetermined range in the axial direction as shown in FIG. 66 and a fixed shaft 67 and a solenoid electromagnet 81 which is installed in the central hole portion 53a of the waveguide 53 to linearly move the variable shaft 66 connected to the bulb 55.

Here, the variable shaft 66 is provided with a conductor portion 83 to be movable in accordance with the generation of the magnetic force of the electromagnet 81, the electromagnet 81 on the variable shaft 66 in the fixed shaft (67). And a return spring 85 that provides an elastic force in a direction opposite to the direction of magnetic force.

The variable shaft 66 is coupled in a spline manner (S) so that the linear movement is possible while the lower end is inserted into the fixed shaft (67) and constrained in the rotational direction, and within a predetermined range from the fixed shaft (67). Long holes 66a are formed to be elongated in the axial direction so as to allow relative movement.

The fixing shaft 67 is inserted into the upper end of the long hole 66a to form a stopper 67a for restricting the vertical movement of the variable shaft 66.

Referring to the operation of the first embodiment according to the present invention configured as described above are as follows.

It is assumed that the microwaves are concentrated on the lower side of the resonator 60 when the bulb 55 is initially started, and that the microwaves are concentrated on the upper side of the resonator 60 when the bulb 55 is completely emitted after a predetermined time.

First, when the high pressure generator 57 operates according to the signal of the controller 70, microwaves generated from the magnetron 51 are transferred into the resonator 60 through the waveguide 53 to excite the encapsulating material in the bulb 55. To generate a plasma.

At this time, the light bulb 55 has a magnetic force generated in the solenoid electromagnet 81 in response to a signal from the control unit 70, the conductor portion 83 and the variable shaft 66 to overcome the force of the return spring 85 to the lower side Moving, the bulb 55 is located inside the resonator.

In addition, the controller 70 controls the light bulb 55 not to rotate by quickly raising the temperature of the light bulb 55 and not outputting a driving signal to the light bulb motor 62 so that the plasma is stabilized.

After that, when the internal temperature of the resonator 60 increases by a certain time, the controller 70 controls not to apply the solenoid electromagnet 81 to the power supply, and at this time, the variable shaft 66 and the light bulb 55. Is raised by the elastic force of the return spring (85).

At the same time, the controller 70 keeps the bulb 55 cool by operating the bulb motor 62 to rotate the bulb 55 so that the bulb 55 does not overheat.

Therefore, the present invention changes the position of the bulb 55 in response to the change in the position where the microwaves are concentrated in the resonator 60 due to the temperature change in the resonator 60. In the case of complete light emission, the excitation rate of the microwaves is increased, so that the light emission efficiency of the light bulb 55 is further increased.

4 is a cross-sectional view of a second embodiment showing a lighting apparatus using microwaves according to the present invention.

In the second embodiment of the present invention is configured to change the position of the bulb 155 using the bulb position variable mechanism 180 consisting of a rack and pinion.

That is, the bulb position variable mechanism 180 is a rotation shaft 165 connecting the bulb motor 162 and the bulb 155 is constrained in the rotation direction in the bulb motor 162 and can be moved relative to the axial direction. It is connected to the, and the central hole portion 153a of the waveguide 153 is provided with a variable operating portion 181 for linearly moving the rotating shaft 165.

The variable operation unit 181 includes a rack 184 formed on the rotation shaft 165, a variable motor 182 fixed inside the center hole 153a of the waveguide 153, and the variable motor 182. It is provided on the shaft of the pinion 183 for linearly moving the rotating shaft 165 while being engaged with the rack 184.

In addition, stoppers 166 are formed on the rotation shaft 165 so as to be caught by the waveguide 153 and the bulb motor 162 so that vertical movement is limited.

In the second embodiment of the present invention, the pinion 183 rotates when the variable motor 180 operates according to the control signal of the controller, and the rack 184 moves up and down as the pinion 183 rotates. By moving the rotating shaft 165 in the vertical direction while moving it is possible to change the position of the bulb 155.

5 is a cross-sectional view of a third embodiment showing a lighting apparatus using a microwave according to the present invention.

In the third embodiment of the present invention, the position of the bulb 255 can be changed by moving the rotating shaft 265 using the solenoid actuator 281 to the variable actuating mechanism 280.

That is, the variable actuating mechanism 280 is fixed to the variable force transmission lever 283 connected to the outside of the waveguide 253 in the rotation shaft 265 and the lower portion of the waveguide 253 and is controlled by a controller. Is applied to the solenoid actuator 281 for linearly moving the variable force transmission lever 283.

Of course, the rotary shaft 265 is constrained in the rotational direction and connected relative to the axial direction in the bulb motor 262 as in the second embodiment described above.

Accordingly, the solenoid actuator 281 moves the variable force transmission lever 283 up and down according to the signal of the controller, thereby changing the position of the light bulb 255 while the rotation shaft 265 moves up and down.

The lighting apparatus using the microwave of the present invention configured and operated as described above is configured so that the position of the bulb is different at the time of initial startup and at full emission, so that the bulb can be positioned at the optimal position where the microwaves are concentrated. This can shorten the time to full light emission, and provide the advantage that the light emission efficiency is improved during full light emission.

Claims (10)

A waveguide for transmitting microwaves generated from the magnetron; A light bulb which generates light while the encapsulating material is excited by the microwave energy transmitted through the waveguide; A resonator covering the waveguide and the light bulb and blocking the microwaves while passing the light emitted from the light bulb; Illumination device using a microwave, characterized in that it comprises a bulb position variable means for changing the bulb position in the resonator is connected to the bulb outside the resonator or waveguide. The method of claim 1, A light bulb motor is installed at a lower portion of the waveguide so as to rotate the light bulb, and the light bulb motor and the light bulb are connected to a rotating shaft passing through the waveguide; The bulb position variable means includes a variable shaft and a fixed shaft coupled to each other so that the rotating shaft is divided and constrained in the rotational direction and relatively movable within a predetermined range in the axial direction, and installed in the center hole of the waveguide. Lighting device using a microwave, characterized in that consisting of variable operating means for linearly moving the variable axis connected to. The method of claim 2, The variable operation means is made of a solenoid electromagnet, the variable shaft is provided with a conductor portion to be movable in accordance with the magnetic force generated in the electromagnet, the fixed shaft in the direction opposite to the direction of the electromagnet and magnetic force on the variable shaft Lighting device using a microwave, characterized in that composed of elastic means for providing an elastic force. The method of claim 2 or 3, The variable shaft is a microwave-based lighting device, characterized in that coupled to the spline method so that the linear movement in the state in which the lower end is inserted into the fixed shaft is constrained in the rotational direction. The method of claim 2 or 3, Means for allowing the variable shaft to move relative to the fixed shaft within a predetermined range is a long hole formed in the variable axis in the axial direction, and a stopper inserted into the long hole at the distal end of the fixed shaft to limit the movement of the variable shaft Lighting device using a microwave, characterized in that consisting of. The method of claim 1, A light bulb motor is installed at a lower portion of the waveguide so as to rotate the light bulb, and the light bulb motor and the light bulb are connected to a rotating shaft passing through the waveguide; The bulb position variable means is connected to the rotational axis is constrained in the rotational direction in the bulb motor and the relative movement in the axial direction, the variable operating means for linearly moving the rotational shaft is installed on one side of the waveguide Lighting device using microwave. The method of claim 6, The variable operation means comprises a rack formed on the rotating shaft, a variable motor fixed inside the center hole of the waveguide, and a pinion provided on the shaft of the variable motor and engaged with the rack to linearly move the rotating shaft. Lighting device using microwave. The method according to claim 6 or 7, The rotating shaft has a stopper is formed on the rotating shaft so that the up and down movement is limited to the waveguide and the bulb motor is a lighting device using a microwave. The method of claim 6, The variable operating means is a lighting device using a microwave, characterized in that consisting of a variable force transmission lever connected to the outside of the waveguide on the rotating shaft, and an actuator for linearly moving the variable force transmission lever. The method of claim 9, And said actuator is a solenoid actuator for linearly moving said variable force transmission lever as a current is applied.