KR100565216B1 - Wave guide structure of electrodeless lighting system - Google Patents

Abstract

The waveguide structure of the electrodeless lighting device according to the present invention includes a case having a receiving space having a predetermined size therein, a high voltage generator installed in the receiving space inside the case, for boosting an AC voltage to a high voltage, and the high voltage generator. A magnetron that is installed at a certain distance and is applied with a high voltage generated from a high voltage generator to generate electromagnetic waves, a waveguide installed to communicate with an output of the magnetron, and a waveguide for guiding electromagnetic waves generated from the magnetron; And a light emitting device in which a light emitting material is encapsulated and plasma discharged by electromagnetic waves guided by the waveguide, and emits light, and a resonator which is installed to surround the light bulb, the leakage of electromagnetic waves is blocked, and the emitted light passes. Is installed to surround the outside of the resonator In the electrodeless lighting device comprising a reflector for reflecting the generated light and a bulb rotating motor installed inside the case to rotate the bulb so that the bulb is not partially heated, the waveguide of the magnetron is inserted One end wall surface of the electromagnetic wave guide space is formed parallel to the antenna, so that a predetermined distance is maintained between the end of the antenna and the inner wall surface of the electromagnetic wave guide space, so that a spark is formed between the end of the antenna and the adjacent wall surface of the electromagnetic wave guide space. It can be prevented from being generated, and therefore the burnout of the antenna due to sparking can be prevented.

Description

Waveguide Structure of Electrodeless Lighting Equipment {WAVE GUIDE STRUCTURE OF ELECTRODELESS LIGHTING SYSTEM}

1 is a perspective view showing the structure of a conventional electrodeless lighting device.

2 is a longitudinal cross-sectional view of FIG.

Figure 3 is a cross-sectional view showing a state in which the magnetron is coupled to the conventional waveguide.

Figure 4 is a perspective view partially cut away the structure of the electrodeless lighting device having a waveguide structure according to an embodiment of the present invention.

5 is a longitudinal sectional view of FIG. 4;

Figure 6 is a cross-sectional view showing a magnetron coupled to the waveguide of the present invention.

Figure 7 is a cross-sectional view showing a waveguide structure showing another embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

101: case 102: high voltage generator

103: magnetron 103a: antenna

104: waveguide 105: light bulb

106: resonator 107: reflection shade

110: electromagnetic wave induction space 110b: one end wall surface

110f: straight portion 110f ': wall surface

The present invention relates to an electrodeless lighting device, and more particularly, to a waveguide between a magnetron antenna and an inner wall surface of an electromagnetic wave guide space of a waveguide, thereby improving the life of the component. It's about structure.

ELECTRODELESS LIGHTING SYSTEM transfers electromagnetic energy generated from the electromagnetic wave generator to the resonator through the waveguide, which is applied to the electrodeless bulb installed inside the resonator to generate plasma and emit light by the plasma. A lighting device that emits visible light or ultraviolet light in a light bulb in which a light emitting material is encapsulated, and has a long life and an excellent effect of lighting compared to generally used incandescent or fluorescent lamps.

1 is a perspective view showing the structure of a conventional electrodeless lighting device, Figure 2 is a longitudinal cross-sectional view of Figure 1, Figure 3 is a cross-sectional view showing a magnetron coupled to the conventional waveguide.

As shown in the drawing, in the conventional electrodeless lighting device, a high voltage generator (HIGH VOLTAGE GENERATING UNIT) 2 is installed on one side of a case 1 to boost a commercial AC power to a high pressure. On the side, a magnetron 3 for generating electromagnetic waves at a high voltage generated by the high voltage generator 2 is provided.

In addition, a waveguide (WAVE GUIDE) 4 for guiding the electromagnetic wave MICROWAVE generated from the magnetron 3 is provided at the inner upper center of the case 1 between the magnetron 3 and the high voltage generator 2. The upper end is fixed to the opening 1a formed in the case 1.

In addition, the shaft shaft 4a is rotatably coupled to the shaft hole 4a formed in the center of the waveguide 4 in the vertical direction, and is thus moved upwardly outward through the opening 1a formed in the case 1. The protruding upper end is provided with a circular bulb (BULB) 6 in which a substance emitting light by electromagnetic wave energy is enclosed, and the lower end can cool the light bulb 6 by rotating the rotating shaft 5. The electric bulb rotation motor 8 to which the motor shaft 8a is connected by the connecting pipe 7 is coupled.

The upper end of the waveguide 4 located outside the case 1 blocks the leakage of electromagnetic waves flowing through the waveguide 4 and allows the light emitted from the light bulb 6 to pass. (RESONATOR) (9) is coupled to surround the bulb 6, the periphery of the coupled resonator (9) so as to reflect the light generated in the bulb (6) and passed through the resonator (9) A semicircular reflector 10 which is provided to surround the outside of the 9 is fixed.

In addition, a fan motor 11, a cooling fan 12, and a cooling outlet 13a may be disposed at an inner lower side of the case 1 to cool the magnetron 3 and the high voltage generator 2. Cooling fan assembly 14 consisting of a fan housing (13) is formed is provided.

In addition, the fan housing 13 is formed with a suction port 13b for suctioning external air by the rotation of the cooling fan 12, and the upper surface edge of the case 1 is sucked through the suction port 13b. Several outlets 1b are formed so that the compressed air can be discharged to the outside via the high voltage generator 2 and the magnetron 3.

In the conventional electrodeless lighting device configured as described above, when a power is applied, a high voltage is generated in the high voltage generator 2, and the high voltage generated as described above is supplied to the magnetron 3, and is applied to the magnetron 3. The high voltage generates electromagnetic waves.

The electromagnetic wave generated as described above is radiated into the resonator 9 through the waveguide 4, and discharges a material encapsulated in the light bulb 6 by the emitted electromagnetic wave to generate light by plasma. The light generated as is reflected by the reflector 10 and is illuminated forward.

When the light is generated from the bulb 6 as described above, the bulb rotation motor 8 rotates at a constant speed and rotates the rotation shaft 5 through the connection pipe 7 to fix the bulb to the end of the rotation shaft 5. By rotating (6), the bulb 6 is cooled so as not to be heated above a predetermined temperature.

In addition, the fan motor 11 installed in the inner lower part of the case 1 also rotates to rotate the cooling fan 12, and the external air sucked through the suction port 13b by the rotation of the cooling fan 12 After flowing through the discharge port 13a and cooling the high voltage generator 2 and the magnetron 3, the discharge is discharged to the outside of the case 1 through the discharge port 1b formed on the upper surface of the case 1.

On the other hand, Figure 3 is a cross-sectional view showing a state in which the magnetron is coupled to the conventional waveguide, as shown in the waveguide 4, the electromagnetic wave guide space (4a) for inducing electromagnetic waves into the interior of the resonator (9) The antenna 3a of the magnetron 3 is inserted into the electromagnetic wave induction space 4a so that the electromagnetic energy generated in the magnetron 3 is output to the electromagnetic wave induction space 4a.

However, such a conventional electrodeless illuminator is provided between the end portion 3a 'of the antenna 3a of the magnetron 3 and one end wall surface 4a' formed to be inclined in the electromagnetic wave guide space 4a of the waveguide 4. There is a problem that a short occurs, and such a break occurs that the cap of the antenna 3a is peeled off by such an electrical short.

The object of the present invention devised in view of the above problems is to ensure a sufficient distance between the antenna and the wall surface of the electromagnetic wave guide space of the waveguide to prevent the parts from being burned out by the electrical short during the operation of the device. A waveguide structure of a suitable electrodeless illuminator is provided.

In order to achieve the object of the present invention as described above

A case having a predetermined size of a receiving space therein,

A high voltage generator installed in the accommodating space inside the case and configured to boost the AC voltage to a high voltage;

A magnetron installed at a predetermined distance from the high voltage generator and receiving electromagnetic voltage generated from the high voltage generator to generate electromagnetic waves;

A waveguide installed to communicate with an output of the magnetron and for guiding electromagnetic waves generated from the magnetron;

A light bulb which is installed to protrude to the outside of the case and emits light by being discharged by plasma discharge by electromagnetic waves guided by a waveguide with a light emitting material sealed therein;

A resonator which is installed to surround the light bulb, the leakage of electromagnetic waves is blocked, and the emitted light passes;

A reflection shade installed to surround the outside of the bulb and the resonator to reflect light generated from the bulb;

In the electrodeless lighting device is provided on the inside of the case and provided with a bulb rotation motor for rotating the bulb so that the bulb is not partially heated,

An electromagnetic wave guide space is formed inside the waveguide to guide the electromagnetic wave output from the antenna of the magnetron to the resonator, and one side wall surface of the electromagnetic wave guide space adjacent to the antenna is formed parallel to the antenna to prevent electrical spark generation. A waveguide structure of an electrodeless illuminator is provided.

Hereinafter, the waveguide structure of the electrodeless lighting device of the present invention configured as described above will be described in more detail with reference to an embodiment of the accompanying drawings.

 Figure 4 is a perspective view partially cut away the structure of the electrodeless lighting device having a waveguide structure according to an embodiment of the present invention, Figure 5 is a longitudinal cross-sectional view of Figure 4, Figure 6 is a magnetron coupled to the waveguide of the present invention Cross-sectional view showing the state.

As shown in the drawing, the electrodeless lighting device having the waveguide structure of the present invention is mounted on one side of the case 101 and has a high voltage generator 102 for boosting a commercial AC power to a high pressure, and is mounted on the other side. A magnetron 103 for generating electromagnetic waves at a high voltage generated by the high voltage generator 102, a waveguide 104 for guiding electromagnetic waves generated from the magnetron 103 in communication with an outlet of the magnetron 103, and The light emitting material 105, the inert gas, and the discharge catalyst material are encapsulated together and the light emitting material encapsulated by the electromagnetic wave energy guided through the waveguide 104 becomes plasma, and the light bulb 105 emits light. Is coupled to the waveguide 104 so as to block electromagnetic waves and pass the light emitted from the light bulb 105, and the light generated by the light bulb 105 by receiving the resonator 106. A reflection shade 107 reflecting the light source, a bulb rotation motor 108 installed inside the case 101 to be connected to the light bulb 105, and rotating the light bulb 105 so as not to be partially heated, and the case ( It is provided with a cooling fan assembly 109 provided in the inner lower side of the 101 to cool the magnetron 103 and the high voltage generator 102 installed inside the case 101.

An electromagnetic wave induction space 110 having a predetermined size of a space is formed in the waveguide 104, and an electromagnetic wave induction space 110 is provided through an antenna insertion hole 104b formed at one side of the electromagnetic wave induction space 110. The antenna 103a of the magnetron 103 is coupled to the inner side of the magnetron 103.

The electromagnetic wave guide space 110 formed inside the waveguide 104 is formed between the inner circumferential wall surface 110b of the inner side and the outer circumferential wall surface 110c of the outer side to form a "C" shape at a predetermined width, and at one end thereof. One end wall surface 110d is formed parallel to the antenna 103a, and the other end wall surface 110e is inclined at a predetermined angle on the other end.

That is, one end wall surface 110d formed at one end of the electromagnetic wave guide space 110 formed in the waveguide 104 is formed in parallel with the antenna 103a so that the end of the antenna 103a and the one end wall surface 110d are separated from each other. A predetermined space is secured in the.

Effects of the electrodeless lighting device having the waveguide structure of the present invention configured as described above are as follows.

First, when power is applied, a high voltage is generated in the high voltage generator 102, and the high voltage generated as described above is supplied to the magnetron 103, and generates electromagnetic waves by the high voltage in the magnetron 103.

The electromagnetic waves generated as described above are guided into the resonant space inside the resonator 106 through the electromagnetic wave guide space 110 of the waveguide 104, and the electromagnetic waves induced inside the resonator 106 may be light bulbs. The inert gas encapsulated in 105 is excited to generate a light having a unique emission spectrum as the light emitting material continuously becomes a plasma, and the generated light is reflected by the reflection shade 107 to be illuminated forward.

Meanwhile, in the present invention, one end wall surface 110d of the electromagnetic wave guide space 110 formed around the antenna 103a of the magnetron 103 inserted into the electromagnetic wave guide space 110 of the waveguide 104 is an antenna ( As it is formed in parallel with the 103a, the gap between the end of the antenna 103a and the one end wall surface 110d does not generate a spark during operation, thereby preventing damage to the antenna 103a due to sparking. .

Figure 7 is a cross-sectional view showing a waveguide structure showing another embodiment of the present invention, as shown in this, since the basic structure is the same as the embodiment of the present invention described above, the same reference numerals for the same parts and detailed description Omit.

Here, another embodiment of the present invention forms a straight portion 110f so that the inner side of one end of the electromagnetic wave induction space 110 is formed perpendicular to the antenna 103a, and thus, is formed between the antenna 103a and the surrounding wall surface. By maintaining the spacing, generation of sparks is prevented between the antenna 103a and the wall surface 110f 'at the coupling portion of the antenna 103a.

As described in detail above, the waveguide structure of the electrodeless lighting device of the present invention is formed so that one end wall surface of the electromagnetic wave guide space of the waveguide into which the antenna of the magnetron is inserted is formed in parallel with the antenna, and the end of the antenna and the inside of the electromagnetic wave guide space. By maintaining a predetermined distance between the wall surfaces, the occurrence of sparks generated between the end of the antenna and the adjacent wall surface of the electromagnetic wave guide space is prevented, thereby preventing the burnout of the antenna due to the spark generation.

Claims (2)

A case having a predetermined size of a receiving space therein, A high voltage generator installed in the accommodating space inside the case and configured to boost the AC voltage to a high voltage; A magnetron installed at a predetermined distance from the high voltage generator and receiving electromagnetic voltage generated from the high voltage generator to generate electromagnetic waves; A waveguide installed to communicate with an output of the magnetron and for guiding electromagnetic waves generated from the magnetron; A light bulb which is installed to protrude to the outside of the case and emits light by being discharged by plasma discharge by electromagnetic waves guided by a waveguide with a light emitting material sealed therein; A resonator which is installed to surround the light bulb, the leakage of electromagnetic waves is blocked, and the emitted light passes; A reflection shade installed to surround the outside of the bulb and the resonator to reflect light generated from the bulb; In the electrodeless lighting device is provided on the inside of the case and provided with a bulb rotation motor for rotating the bulb so that the bulb is not partially heated, An electromagnetic wave guide space is formed inside the waveguide to guide the electromagnetic wave output from the antenna of the magnetron to the resonator, and one side wall surface of the electromagnetic wave guide space adjacent to the antenna is formed parallel to the antenna to prevent electrical spark generation. A waveguide structure of an electrodeless lighting device, characterized in that the so-called. The method of claim 1, A waveguide structure of an electrodeless lighting device, characterized in that one end of the electromagnetic wave guide space into which the antenna of the magnetron is inserted has a vertical portion formed perpendicular to the antenna.

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