KR100677533B1 - Magnetron cooling device for plasma lighting system - Google Patents

Abstract

A magnetron cooling apparatus of an electrodeless lighting system is provided to improve cooling efficiency with respect to a magnetron by tightly contacting the magnetron to a heat sink block. A magnetron(10) is comprised of a main frame unit(11), an input unit(12), and an output unit(13). The main frame unit has a cathode and an anode to generate electromagnetic wave. The input unit is formed on a side of the main frame unit to receive power from a power supplier. The output unit supplies the electromagnetic wave generated in the main frame unit into a resonator through a waveguide. A magnetron accommodation unit(21) is formed to accommodate the magnetron. The magnetron is inserted into the magnetron accommodation unit. A contact inclined surface is formed in an inner surface of a heat release cover(30). A heat sink block(20) is contacted to a circumference of the main frame unit of the magnetron. The heat sink block transfers the heat generated in the magnetron to the heat release cover by forming a contact inclined surface to be put on the contact inclined surface of the heat release cover.

Description

Magnetron Cooling System for Electrodeless Lighting Equipment {MAGNETRON COOLING DEVICE FOR PLASMA LIGHTING SYSTEM}

1 is a longitudinal sectional view showing an example of a conventional electrodeless lighting device;

2 is an exploded perspective view showing a magnetron cooling device in a conventional electrodeless lighting device;

3 is an exploded perspective view of the magnetron cooling device of the present invention electrodeless lighting device;

Figure 4 is a perspective view showing a state in which the magnetron coupled to the waveguide in the electrodeless lighting device of the present invention,

5 is a cross-sectional view taken along line "I-I" of FIG.

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

10: magnetron 11: the main body

11a: anode cylinder 12: input unit

13 output unit 15 top yoke

15a: Fastener 16: Lower plate yoke

20: heat dissipation block 21: block slope

30: heat dissipation cover 31: magnetron receiving portion

32: cover slope 33: fastening groove

40: heat dissipation pad

The present invention relates to an electrodeless lighting device using electromagnetic waves, and more particularly, to a magnetron cooling device of an electrodeless lighting device that can increase the contact between the heat dissipation block and the heat dissipation cover that radiate heat generated by the magnetron by conduction.

In general, a PLS (Plasma Lighting System) uses a high frequency oscillator (magnetron), which is mainly used in a microwave oven, and the electromagnetic waves generated from the high frequency oscillator convert the buffer gas in the electrodeless bulb into a plasma state. It is a device that can provide excellent amount of light without electrode by making metal compound emit light continuously while making.

1 is a longitudinal cross-sectional view showing an example of a conventional electrodeless lighting device, Figure 2 is a perspective view showing a disassembled cooling device of the magnetron in a conventional electrodeless lighting device.

As shown in the drawing, a conventional electrodeless lighting device includes a magnetron 2 that is mounted inside the casing 1 and receives an electric current from a power supply (not shown) to generate electromagnetic waves, and an output of the magnetron 2. A waveguide (3) which communicates with and transmits electromagnetic waves generated by the magnetron (2), an electrodeless light bulb (4) which generates light while the encapsulating material is plasma-formed by electromagnetic wave energy, and the waveguide (3) and the electrodeless It covers the front of the bulb 4 to resonate the electromagnetic wave at a predetermined resonant frequency while blocking the electromagnetic wave while receiving the resonator 5 and the resonator 5 to pass the light emitted from the electrodeless bulb 4. Reflector 6 for intensively reflecting the light generated by the electrode bulb 4 straight, and a dielectric mirror (7) mounted inside the resonator (5) behind the electrodeless bulb (4) to reflect the light while passing electromagnetic waves (7) ) Is included.

As shown in FIG. 2, the magnetron 2 includes a main body part 2a that generates electromagnetic waves when power is applied, an input part 2b that is formed on one side of the main body part 2a, and receives power. It is formed on the other side of (2a) and consists of the output part 2c which outputs the electromagnetic wave which arose in the main-body part 2a to the system of an electrodeless illuminating device.

The main body portion 2a has an anode cylinder 2d for accommodating a filament forming a cathode and a vane forming an anode together therein to generate high frequency energy, and the anode cylinder 2d has an anode cylinder on its outer circumferential surface. Wrap and install the heat dissipation block (8) for heat dissipation by heat conduction (2d), and fixed to the outer surface of the heat dissipation block (8) in contact with the heat dissipation cover (9) surrounding the entire magnetron (2) have.

The heat dissipation block 8 is formed in a pair of left and right so as to be post-assembled laterally inside the yoke plate 2e constituting the outer surface of the main body of the magnetron 2, and its inner circumferential surface is the outer circumferential surface of the anode cylinder 2d described above. Tighten with a long bolt to make intimate contact with. In addition, the heat dissipation block 8 is fastened with screws so that its outer surface is in intimate contact with the inner surface of the heat dissipation cover 9 described above.

8a and 8b, which are not described in the drawings, are left and right heat dissipation blocks, F is a cooling fan, and M is a bulb motor.

The conventional electrodeless lighting device as described above operates as follows.

That is, the magnetron 2 generates an electromagnetic wave having a very high frequency while oscillating by a high pressure according to a command of the control unit, and the electromagnetic wave 4 radiates into the resonator 5 through the waveguide 3, and thus the electrodeless bulb 4 The inert gas enclosed therein is excited. In this process, the light emitting material continuously emits light having a unique emission spectrum, and the light is reflected forward by the reflector 6 and the dielectric mirror 7 to illuminate the space. At this time, the magnetron (2) generates high-frequency energy mainly in the anode cylinder (2d) while generating electromagnetic energy, this heat is radiated by convection by the cooling fan (F) while the heat dissipation cover through the heat radiation block (8) It was turned over to (9) and cooled rapidly.

However, in the magnetron of the conventional electrodeless lighting device as described above, a floating phenomenon occurs between the heat dissipation block 8 and the heat dissipation cover 9 by assembling the heat dissipation block 8 and the heat dissipation cover 9 by screwing them together. While the heat conduction performance was lowered, there was a concern that the cooling effect on the magnetron 2 was lowered.

When assembling the heat dissipation block 8, insert both heat dissipation blocks 8a and 8b into the main body portion 2a of the magnetron 2, and then tighten the two heat dissipation blocks 8a and 8b with long bolts. Not only is the assembly process complicated, but the clamping force at the time of fastening the bolts deforms the body part 2a of the magnetron 2, that is, the anode cylinder 2e, or between the heat dissipation block 8 and the anode cylinder 2d. There was a fear that the cooling effect was reduced.

The present invention has been made in view of the problems of the conventional electrodeless lighting device as described above, the magnetron of the electrodeless lighting device to increase the cooling effect on the magnetron by allowing intimate contact between the heat dissipation block and the heat dissipation cover. It is an object of the present invention to provide a cooling device.

In addition, an object of the present invention is to provide a magnetron cooling device of an electrodeless lighting device that can easily prevent the heat dissipation block on the body of the magnetron, but can prevent the deterioration of the cooling effect due to deformation or assembly tolerance of the assembled part. have.

In order to achieve the object of the present invention, a main body portion having a cathode and a cathode to generate electromagnetic waves when power is applied, an input portion provided on one side of the body portion to receive power from a power supply, and a non-electrode provided on the other side of the body portion A magnetron including an output unit for supplying the electromagnetic waves generated by the main body to the inside of the resonator through the waveguide so that the light emitting material encapsulated in the light bulb is plasma-formed to generate light; A heat dissipation cover to form a magnet accommodating portion to accommodate the magnetron, and to form an inclined contact inclined surface on an inner side thereof; Electrodeless illumination including; heat radiation block for coupling to the outer circumferential surface of the main body portion of the magnetron, and a contact inclined surface on the outer surface of the magnetron to be placed on the contact inclined surface of the heat dissipation cover to conduct heat generated from the magnetron to the heat dissipation cover; Provides a magnetron chiller for the appliance.

EMBODIMENT OF THE INVENTION Hereinafter, the magnetron cooling apparatus of the electrodeless lighting device by this invention is demonstrated in detail based on one Example shown in an accompanying drawing.

3 is an exploded perspective view of the magnetron cooling apparatus of the present invention electrodeless illuminator, FIG. 4 is a perspective view illustrating a magnetron coupled to a waveguide in the electrodeless illuminator of the present invention, and FIG. -I "sectional view.

Referring to FIG. 1, an electrodeless lighting device having a magnetron cooling device according to the present invention may be built in one side of a casing 1 to receive electric power from a power supply (not shown) to generate electromagnetic waves, and to be described later. A magnetron 10 for inserting and coupling the heat dissipation block 20 to 11), a waveguide 3 for communicating with the output 13 of the magnetron 10 to transmit electromagnetic waves generated by the magnetron 10, The electrodeless bulb 4 which arrange | positions the light emitting part 4a which generate | occur | produces a light by the electromagnetic wave energy plasma, and arrange | positions in the front opening of the said casing 1, the waveguide 3, and the electrodeless bulb ( 4) and the casing to accommodate the resonator (5) and the resonator (5) to pass the light emitted from the electrodeless bulb (4) while blocking the electromagnetic waves while resonating the electromagnetic waves at a predetermined resonance frequency Electrode is installed on the front side opening of 1) Reflector 6 for intensively reflecting light generated from sphere 4, and dielectric mirror 7 for reflecting light while passing electromagnetic waves through mounting inside the resonator 5 behind the electrodeless bulb 4 It includes.

As shown in FIG. 3, the magnetron 10 includes a main body 11 that generates electromagnetic waves when power is applied, an input 12 that is formed on one side of the main body 11, and receives power. The output unit 13 is formed on the other side and outputs electromagnetic waves generated from the main body 11 to the system of the electrodeless lighting device.

As shown in FIGS. 4 and 5, the main body 11 includes an anode cylinder 11a for accommodating a filament constituting a cathode and a vane constituting a cathode together to generate high frequency energy. The magnetron 10 described above in the magnetron accommodating portion 31 of the heat dissipation cover 30 will be described later on the boundary of the main body portion 11 and the output portion 13, that is, the upper plate yoke 15 surrounding the main body portion 11. After inserting into the inlet end of the magnetron accommodating portion 31 to form a fastening piece (15a) to be screwed.

In addition, an outer circumferential surface of the anode cylinder 11a is installed by inserting in the axial direction a heat dissipation block 20 for thermally conducting and radiating heat generated from the anode cylinder 11a. The magnetron 10 is fixedly installed to contact the heat dissipation cover 30 surrounding the entire magnetron 10.

The outer surface of the heat dissipation block 20 is inclined toward the magnetron receiving portion 31 of the heat dissipation cover 30 to be described later toward the narrower direction toward the magnetron accommodating portion 31 of the heat dissipation cover 30 to be described later. The block inclined surface 21 is formed to be mounted on the cover inclined surface 32 provided.

In addition, between the block inclined surface 21 of the heat dissipation block 20 and the cover inclined surface 32 of the heat dissipation cover 30 has a predetermined elasticity so as to increase contactability while slightly shrinking when the heat dissipation block 20 is placed. A thermal conductive pad 40 made of a material having excellent thermal conductivity may be interposed.

The heat dissipation cover 30 is formed in a hollow hexahedral shape with one side opened to form a magnetron accommodating portion 31 so that the magnetron 10 can be inserted therein, and the magnetron accommodating portion 31 is formed within the heat dissipation cover 30. The heat dissipation block 20 is inclined in a direction corresponding to the block inclined surface 21 of the heat dissipation block 20, that is, toward the inlet side of the magnetron accommodating part 31 so that the heat dissipation block 20 is placed on the heat dissipation cover 30. The cover inclined surface 32 is formed. In addition, the inlet end of the magnetron accommodating portion 31 of the heat dissipation cover 30 forms a fastening groove 33 so that the fastening piece 15a of the magnetron 10 is mounted and fastened.

On the other hand, although not shown in the drawings, the plurality of heat dissipation blocks may be coupled to contact the main body portion (anode cylinder) of the magnetron by inserting a plurality of radial blocks in both the left and right sides. In this case, semi-circular coupling grooves are formed on the contact surfaces of both heat dissipation blocks.

In the drawings, the same reference numerals are given to the same parts as in the prior art.

In the drawings, reference numeral 16 denotes a lower plate yoke.

The magnetron cooling device of the electrodeless lighting device of the present invention as described above has the following effects.

That is, when a current is applied to the filament (not shown) as the cathode, the filament emits hot electrons, which are applied to the strong electric field and the magnetic field applied between the filament and the vane (not shown) and the anode cylinder 11a as the anode. By emitting high-frequency energy to the resonator 5 through the waveguide (3), the electromagnetic wave supplied to the resonator (5) is made to plasma the material encapsulated in the electrodeless bulb (4) to emit light. At this time, in the anode cylinder 11a, high heat is generated in the process of generating electromagnetic waves, but the high heat is also radiated by forced convection generated when the cooling fan F coupled to the electric bulb motor M rotates, and the anode cylinder Heat dissipation is also caused by the heat conduction generated by coupling the heat dissipation block 20 to the 11a, and the magnetron 10 can be quickly cooled.

Meanwhile, the process of assembling the magnetron, the heat dissipation block, and the heat dissipation cover is as follows.

First, an outer circumferential surface of the main body portion 11 of the magnetron 10, more precisely, extrapolates the coupling hole 20b of the heat dissipation block 20 to the outer circumferential surface of the anode cylinder 11a.

Next, the upper plate yoke 15 surrounding the main body 11 of the magnetron 10 is used to accommodate the heat dissipation block 20 and fastened to the lower plate yoke 16 surrounding the input unit 12.

Next, the entire magnetron 10 combined with the heat dissipation block 20 is inserted into the magnetron accommodating portion 31 of the heat dissipation cover 30, and the block inclined surface 21 of the heat dissipation block 20 is the cover of the heat dissipation cover 30. The heat dissipation block 20 is in close contact with the heat dissipation cover 30 by being placed on the inclined surface 32. At this time, the heat dissipation block 20 and the heat dissipation cover 30 are interposed between the block inclined surface 21 of the heat dissipation block 20 and the cover inclined surface 32 of the heat dissipation cover 30 through the heat conductive pad 40 having elasticity. ) Make closer contact.

Next, the fastening piece 15a of the magnetron 10 is brought into close contact with the fastening groove 33 of the heat dissipation cover 30, and then screwed into the magnetron 10 including the heat dissipation block 20 and the heat dissipation cover 30. Modularize to complete the assembly.

The magnetron cooling apparatus of the electrodeless illuminator according to the present invention can not only easily assemble the heat dissipation block to the magnetron, but also make intimate contact between the heat dissipation block and the heat dissipation cover. In addition, it is possible to increase the cooling effect on the magnetron by preventing the magnetron from being deformed when assembling the heat radiating block so that the heat radiating block is in close contact with the magnetron.

Claims (5)

The main body unit having the cathode and the anode to generate electromagnetic waves when the power is applied, the input unit provided on one side of the main body unit to receive power from the power supply, and the light emitting material provided on the other side of the main body unit and encapsulated in the electrodeless bulb are made into plasma. A magnetron including an output unit for supplying electromagnetic waves generated by the main body unit to the inside of the resonator through a waveguide to generate light; A heat dissipation cover to form a magnet accommodating portion to accommodate the magnetron, and to form an inclined contact inclined surface on an inner side thereof; Electrodeless illumination including; heat radiation block for coupling to the outer circumferential surface of the main body portion of the magnetron, and a contact inclined surface on the outer surface of the magnetron to be placed on the contact inclined surface of the heat dissipation cover to conduct heat generated from the magnetron to the heat dissipation cover; The device's magnetron chiller. The method of claim 1, The heat dissipation block is a magnetron cooling device for an electrodeless lighting device, characterized in that the coupling hole is formed so as to penetrate and contact the outer peripheral surface of the body portion of the magnetron and the coupling portion is inserted into the body portion of the magnetron in the axial direction. The method of claim 1, The heat dissipation block is a magnetron cooling device for an electrodeless lighting device, characterized in that the coupling grooves are formed on both sides of the main body portion of the magnetron in contact with each other so as to be radially inserted into the outer peripheral surface of the body portion of the magnetron. The method according to claim 2 or 3, Magnetron cooling device of the electrodeless lighting device, characterized in that between the contact inclined surface of the heat dissipation cover and the contact inclined surface of the heat dissipation block further comprises a heat transfer pad having excellent thermal conductivity and elasticity. The method of claim 4, wherein Magnetron cooling device of the electrodeless lighting device, characterized in that the magnetron and the heat dissipation cover is coupled to the magnetron receiving portion of the heat dissipation cover after inserting the magnetron.

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