KR20060036838A - Electrodeless lighting device using plasma - Google Patents

Abstract

The electrodeless illuminator using the plasma of the present invention includes a case having a predetermined space therein, a magnetron installed inside the case and generating microwaves, an inlet and an inlet coupled to an output of the magnetron. A waveguide having a slot formed therein, a resonator installed in communication with the slot of the waveguide to resonate the microwaves emitted through the slot, and a microwave installed inside the resonator and released into the resonator through the slot. A bulb in which a luminescent material that emits plasma and emits light is encapsulated, a motor coupled to the lower end of the bulb shaft of the bulb to rotate the bulb so that it is not locally heated, and one end of which is connected to one side of the magnetron, and the other end of the bulb Parts fixed to the case and installed inside the case In addition to the fixing, the heat transfer member serving as a heat transfer path and a load dissipation and heat dissipation member having one end fixed to the heat transfer member and the other end fixed to the waveguide, and the load applied intensively to the heat transfer member are distributed and heat released. It is dispersed by the member to prevent the coupling part of the component is distorted, and the heat of the waveguide is released to the outside through the load distribution and the heat dissipation member and the heat transfer member to block the heat transfer to the motor.

Description

Electrodeless lighting equipment using plasma {ELECTRODELESS LIGHTING DEVICE USING PLASMA}

1 is a perspective view showing the structure of an electrodeless lighting device using a plasma according to the present invention.

2 is a longitudinal cross-sectional view of FIG.

Figure 3 is an enlarged cross-sectional view showing the configuration of the main part of the present invention.

Figure 4 is an exploded perspective view showing a screw fastening structure of the present invention.

Explanation of symbols on the main parts of the drawings

101: Case 102: Magnetron

103 waveguide 104 resonator

105: bulb 105a: bulb shaft

106: motor 109: heat transfer member

110: load distribution and heat dissipation member 110a: flange portion

10a ': Bolt insertion hole

The present invention relates to an electrodeless illuminator using plasma, and more particularly, to an electrodeless illuminator using plasma, in which load applied to a heat transfer member is dispersed to prevent deformation of components.

ELCTRODELESS LIGHTING DEVICE using plasma transmits microwave power generated from the antenna probe of the magnetron, which is a power source, to the resonator through the waveguide, and is applied to the electrodeless bulb installed inside the resonator to make the bulb visible. It is a lighting device that emits light or ultraviolet rays, and has a long life and excellent lighting effect compared to generally used incandescent and fluorescent lamps.

In addition, in the electrodeless lighting device as described above, one side of the microwave generator is coupled to the inside of the case by a heat transfer member, so that the heat generated from the magnetron is naturally discharged through the case and the lamp unit is fixed to the case. .

However, in the electrodeless lighting apparatus using the conventional plasma as described above, the lamp assembly installed inside the case is connected to the anode of the magnetron by a heat transfer member having one end connected to the inside of the case and the other end fixed to the inner side of the case. Due to the weight of the assembly, the distortion of the components are generated, in the case of severe, there is a problem that the leakage of microwaves may occur due to the gap between the joints between the components.

The object of the present invention devised in view of the above problems is                         

The present invention provides an electrodeless illuminator using plasma suitable for distributing the load of the lamp assembly installed inside the casing so that the lamp assembly can be stably maintained in the case.

In addition, the present invention provides an electrodeless illuminator using a plasma suitable for allowing the motor to be protected by sufficiently dissipating heat generated in the waveguide.

Another object of the present invention is to provide an electrodeless illuminator using a plasma suitable for easily coupling components installed to distribute a load of a lamp assembly.

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

A case having a predetermined space therein,

A magnetron installed inside the casing and generating microwaves,

A waveguide having an inlet and an outlet slot coupled to an output of the magnetron;

A resonator installed in communication with the slot of the waveguide and resonating the microwaves emitted through the slot;

A bulb which is installed inside the resonator and discharges plasma by microwaves emitted through the slot into the resonator, and is filled with a light emitting material that emits light;

A motor coupled to the lower end of the bulb shaft of the bulb to rotate the bulb so that it is not locally heated;

One end is connected to one side of the magnetron and the other end is fixed to the case to fix the components installed inside the case and the heat transfer member which is a heat transfer path,

One end is fixed to the heat transfer member and the other end is fixed to one side of the waveguide to distribute the load applied to the heat transfer member by the components, and to distribute the heat to the waveguide and to dissipate heat transferred to the waveguide. To,

Provided is an electrodeless illuminator using a plasma comprising a configuration.

Hereinafter, with reference to the embodiment of the accompanying drawings, the electrodeless lighting device using the present invention plasma configured as described above in more detail as follows.

1 is a perspective view showing the structure of an electrodeless lighting device using a plasma according to the present invention, Figure 2 is a longitudinal sectional view of Figure 1, Figure 3 is an enlarged cross-sectional view showing the configuration of the main portion of the present invention, as shown therein In the electrodeless lighting device provided with the present invention, a magnetron (102) for generating a microwave (MICROWAVE) is provided inside the case (CASE) 101.

In addition, the upper end of the magnetron 102 is coupled to the inlet portion formed on the lower side of the tubular waveguide (WAVEGUIDE) 103 formed in a tubular shape, and formed on the waveguide 103 on the other side of the waveguide 103. The resonator 104 on the cylindrical network is coupled to communicate with the slot.

In addition, a rectangular bulb (BULB) 105 is formed inside the resonator 104 in which plasma is formed by microwaves resonating in the resonator 104 and a light emitting material emitting light is enclosed. The bulb 105 is rotated by the motor 106 to which the motor shaft 106a is connected to the lower end of the bulb shaft 105a.

In addition, a reflection shade 107 is installed outside the case 101 to surround the resonator 104 so that light emitted from the bulb 105 is reflected by the reflection shade 107 after passing through the resonator 104. It is.

In addition, between the magnetron 102 and the case 101, one end is coupled to the anode 102a of the magnetron 102 and the other end is heat transfer fixed to the inner surface of the case 101 by bolts 108 The member 109 is provided, and one end is fixed to the side surface of the waveguide 103 between the heat transfer member 109 and the waveguide 103 and the other end is fixed to the upper surface of the heat transfer member 109 so as to perform the heat transfer. The load distribution and heat dissipation member 110 is provided to distribute the load concentrated on the member 109 and to transfer the heat generated in the waveguide 103 to the heat transfer member 109.

The load dissipation and heat dissipation member 110 is made of an aluminum or copper material having excellent heat transfer rate, and is preferably installed in a shape of a memory (a).

In addition, in the flange portion 110a formed at the end of the load distribution and heat dissipation member 110, as shown in FIG. 4, the bolt insertion hole 110a ′ having a long width larger than the vertical width a is formed. Is formed, a certain amount of play occurs when the bolt 111 is fastened to the bolt hole 112 of the counterpart so that the bolt 111 can be fastened easily.

In the electrodeless illuminator using the plasma provided according to the present invention, which is configured as described above, when a high voltage is supplied to the magnetron 102, the microwave is generated by the high voltage applied to the magnetron 102. The microwave is transmitted through the waveguide 103 and is radiated into the resonator 104 through the slot 103b of the waveguide 103.

In addition, as described above, the microwaves radiated into the resonator 104 generate resonance by the inside of the resonator 104 and discharge light emitting materials encapsulated in the bulb 105 to generate light by the plasma. The light generated as described above is transmitted through the resonator 104 and reflected by the reflector 107 to be shined forward.

Meanwhile, as described above, the components installed inside the case 101 are fixed to the inside of the case 101 by the thermal shear member 109 provided between the magnetron 102 and the case 101, and the magnetron 102. Heat generated from the heat is transferred to the case 101 through the heat transfer member 109 and is cooled by heat exchange with external air.

In addition, a load distribution and heat dissipation member 110 are installed on both the heat transfer member 109 and the waveguide 103 so that both ends thereof are fixed, and the waveguide 103 is heated by the heat generated by the bulb 105. Since heat is emitted to the case 101 side through the heat transfer member 109, the waveguide 103 is heated to block heat from being transferred to the motor 106 side.

In addition, a bolt insertion hole 110a 'having a large width b is formed in the flange portion 110a formed at both ends of the load distribution and heat dissipation member 110, so that the bolt hole 112 formed in the waveguide 103 is formed. ) Or fastening the bolt 111 to the bolt hole 112 formed in the heat transfer member 109.

As described in detail above, in the electrodeless illuminator using the present invention, one end is fixed to a heat transfer member provided between the magnetron and the case, and the other end is disposed with the waveguide and the load dissipation and heat dissipation member fixed to the side of the waveguide. Installed between the heat transfer members, loads concentrated on the heat transfer members are distributed by load distribution and heat dissipation member, so that the joints between parts are not distorted, and the heat of the waveguide is released to the outside It has the effect of blocking heat transfer to the furnace.

In addition, by forming a bolt coupling hole having a large width in the flange portion formed at the end of the load distribution and the heat dissipation member, there is an effect that there is a play when the bolt is coupled to the bolt hole of the counterpart can be quickly assembled.

Claims (4)

A case having a predetermined space therein, A magnetron installed inside the casing and generating microwaves, A waveguide having an inlet and an outlet slot coupled to an output of the magnetron; A resonator installed in communication with the slot of the waveguide and resonating the microwaves emitted through the slot; A bulb which is installed inside the resonator and discharges plasma by microwaves emitted through the slot into the resonator, and is filled with a light emitting material that emits light; A motor coupled to the lower end of the bulb shaft of the bulb to rotate the bulb so that it is not locally heated; One end is connected to one side of the magnetron and the other end is fixed to the case to fix the components installed inside the case and the heat transfer member which is a heat transfer path, One end is fixed to the heat transfer member and the other end is fixed to one side of the waveguide to distribute the load applied to the heat transfer member by the components, and to distribute the heat to the waveguide and to dissipate heat transferred to the waveguide. To, Electrodeless lighting device using a plasma, characterized in that configured to include. The method of claim 1, The load distribution and heat dissipation member Electrodeless lighting device using a plasma, characterized in that made of aluminum or copper material. The method according to claim 1 or 2, The load distribution and heat dissipation member Electrodeless lighting device using a plasma, characterized in that consisting of a memory (a). The method according to claim 1 or 2, The bolt insertion hole formed in the flange portion of the load dissipation and heat dissipation member is a non-electrode lighting device using a plasma, characterized in that formed in the form of a long hole (b) is larger than the vertical width (a).

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