KR20060129862A - Plasma lighting system having slopping light transmit hole - Google Patents

Abstract

A resonator of an electrodeless lighting system including a slope light transmit hole is provided to minimize reduction in a duration life of a magnetron by normally operating the magnetron at a low temperature. A wave guide guides an electromagnetic wave generated by an electromagnetic wave generator. A resonator is fixed to one end of the wave guide, and shields an external discharge of the electromagnetic wave to achieve a resonant mode. An electrodeless bulb(60) is received at an inner space of the resonator and generates light. A plurality of slope light transmit holes(53a) are formed at a periphery of the resonator in the same direction as a running direction of light so that light generated in the electrodeless bulb is irradiated to an outside of the resonator.

Description

Resonator for electrodeless lighting equipment with inclined light transmission hole {PLASMA LIGHTING SYSTEM HAVING SLOPPING LIGHT TRANSMIT HOLE}

1 is a side cross-sectional view showing the structure of a conventional electrodeless lighting device,

2 is a perspective view showing the structure of the resonator of FIG.

3 is a cross-sectional view taken along line III-III of FIG. 2;

4 is a side cross-sectional view showing the structure of a resonator of an electrodeless lighting device having an inclined opening surface according to an embodiment of the present invention;

5 is a side cross-sectional view showing the structure of a resonator of an electrodeless lighting device having a sloped opening according to another embodiment of the present invention.

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

30: electromagnetic wave generator 40: waveguide

41: resonator coupling member 50: resonator

51: fastener 52: locking jaw

53: mesh 53a: light transmission

53b: aperture 60: electrodeless bulb

70 mirror

The present invention relates to a resonator of an electrodeless lighting device having an inclined opening surface, and more particularly, to maximize the external emission of light generated in the electrodeless bulb and radiate to the outside of the resonator to maximize light emission efficiency. It relates to a resonator of an electrodeless lighting device having an inclined opening surface that can be increased.

In general, an electrodeless lighting device is a gas filled in the electrodeless light bulb as the electromagnetic energy generated from the electromagnetic wave generating unit for generating an electromagnetic wave, such as a magnetron is transferred to the resonator bulb mounted inside the resonator through a waveguide It is a device that generates light by exciting the conversion to a plasma state.

An electrodeless lighting device is an electrodeless bulb that has no electrodes or filaments inside the bulb, and has a very long or semi-permanent lifetime, and emits light as the charging material charged inside the electrodeless bulb becomes plasma to emit light such as natural light. .

1 is a side cross-sectional view showing the structure of a conventional electrodeless lighting device, Figure 2 is a perspective view showing the structure of the magnetron of Figure 1, Figure 3 is a cross-sectional view taken along the line 'III-III' of FIG. .

As shown in these figures, the conventional electrodeless lighting device includes a high voltage generator 20, an electromagnetic wave generator 30, a waveguide 40, and the like inside the casing 10, and the casing 10 of the casing 10. As shown in FIG. An inert gas in the electrodeless light bulb 60 is provided with a resonator 50 and an electrodeless light bulb 60 outside to guide the electromagnetic wave generated by the electromagnetic wave generator 30 to the resonator 50 using the waveguide 40. Becomes plasma and emits light.

The waveguide 40 is a cylindrical tube, one side of which is connected to the high voltage generator 20, and an upper surface of the waveguide 40 has a predetermined height along the height direction of the waveguide 40. ) Is formed to protrude.

The resonator coupling member 41 is formed in a ring shape having a diameter smaller than that of the waveguide 40, and the center of the resonator coupling member 41 has a disk-shaped mirror 70 having the same diameter as that of the resonator coupling member 41. It is arranged.

In the center of the mirror 70, the electrodeless light bulb 60 extends in a predetermined length along the height direction of the waveguide 40 so as to be exposed to the outside, and the circumference of the resonator coupling member 41 and the mirror 70 Along the surface, the resonator 50 is contacted and fixedly coupled to the waveguide 40.

On the outer circumferential surface of the resonator 50, which is in contact with the circumferential surfaces of the resonator coupling member 41 and the mirror 70, the fastener 51 is fixed to the outer circumferential surface of the resonator 50 so that the resonator 50 can be fixedly coupled to the waveguide 40. It is coupled to, the lower inner peripheral surface of the resonator 50 has a predetermined length along the radial direction of the resonator 50 to prevent the mirror 70 from being separated from the resonator coupling member 41 and extends along the circumferential direction The locking step 52 is formed.

The resonator 50 accommodates the electrodeless bulb 60 in the inner space, shields the external emission of electromagnetic waves along the circumferential direction of the inner space, transmits it to the electrodeless bulb 60, and the light generated from the electrodeless bulb 60. It is made of a cylindrical mesh 53 having a mesh structure so that it can be transmitted to the outside.

The lower surface of the mesh 53 is formed to penetrate and contact the outer circumferential surface of the resonator coupling member 41, and a plurality of light transmitting holes 53a penetrate through the plate surface of the side and the upper surface of the mesh 53. Formed.

The opening surface 53b of the light transmission hole 53a formed on the side surface of the mesh 53 is formed side by side along the radial direction of the mesh 53, and the light transmission hole 53a formed on the top surface of the mesh 53. The opening surface 53b of () is formed in parallel along the height direction of the mesh 53.

In the drawings, reference numeral 70 denotes a mirror, 80 reflector, 90 denotes a first driving motor for rotating a light bulb, 100 denotes a cooling fan, 110 denotes a second driving motor for rotating the cooling fan, and 120 denotes an air duct.

By such a configuration, in the conventional electrodeless lighting device, when a driving signal is input to the high voltage generator 20, the high voltage generator 20 boosts AC power to supply the boosted high voltage to the electromagnetic wave generator 30. The electromagnetic wave generator 30 generates an electromagnetic wave having a very high frequency while oscillating by a high voltage. The electromagnetic wave is radiated into the resonator 50 through the waveguide 40 to excite the inert gas charged in the electrodeless light bulb 60 to emit light having a unique emission spectrum as the luminescent material is continuously plasmaled. Will occur.

The generated light is radiated toward the outside of the resonator 50 through the light transmission hole 53a while being radiated about the electrodeless light bulb 60, that is, toward the mirror 70. The light spread out is reflected by the mirror 70 and proceeds to the front of the resonator 50, and is radiated to the outside of the resonator 50 through the light transmission hole 53a to illuminate the space.

By the way, in the conventional electrodeless lighting device, the light generated from the electrodeless bulb 60 proceeds radially and is radiated to the outside of the resonator 50 through the light transmission hole 53a to the resonator 50. Many of the formed light penetrating holes 53a are not formed in parallel with the direction of light propagation, so that the light is reflected from the opening surface 53b of the light penetrating hole 53a so that light travels in an unintended direction, thereby emitting light of the electrodeless illuminator. There is a problem that the efficiency is lowered.

Accordingly, an object of the present invention is to provide a magnetron that can be driven at a cryogenic temperature so that the magnetron is normally oscillated at a cryogenic temperature and the magnetron is normally operated at a low temperature, thereby minimizing the reduction of the life of the magnetron.

The object is, according to the present invention, a waveguide for guiding the electromagnetic wave generated in the electromagnetic wave generator; A resonator fixedly coupled to one end of the waveguide and shielding external emission of the electromagnetic wave to achieve a resonance mode; In an electrodeless lighting device comprising an electrodeless bulb that is received in the internal space of the resonator to generate light, the peripheral surface of the resonator so as to emit light generated from the electrodeless bulb to the outside of the resonator Electrodeless lighting device having an inclined light transmission hole has a plurality of light transmission holes formed through the plate surface of the resonator in the same direction as the direction of the light traveling in the radiation form in the electrodeless bulb It is achieved by the resonator of.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

Figure 4 is a side cross-sectional view showing the structure of a resonator of an electrodeless lighting device having an inclined opening in accordance with an embodiment of the present invention, Figure 5 is a non-with a slope opening in accordance with another embodiment of the present invention A side cross-sectional view showing the structure of a resonator of an electrode illuminator.

However, a description of the overall configuration of the electrodeless lighting device will be referred to FIG. 1.

As shown in the drawing, a resonator of an electrodeless lighting device having an oblique light transmitting hole according to an embodiment of the present invention includes a waveguide 40 and a waveguide for guiding electromagnetic waves generated from the electromagnetic wave generator 30. The resonator 50 is fixedly coupled to one end of the 40 and shields the external emission of electromagnetic waves so that the resonance mode is achieved, and the electrodeless bulb 60 is received in the internal space of the resonator 50 to generate light. In the electrodeless lighting device configured to include, in the circumferential surface of the resonator 50 to radiate the light generated from the electrodeless bulb 60 to the outside of the resonator 50 in the electrodeless bulb 60 in the radiation form It comprises a plurality of light transmitting holes (53c) formed through the plate surface of the resonator 50 in the same direction as the traveling direction of light to proceed.

The waveguide 40 is a cylindrical tube, one side of which is connected to the high voltage generator 20, and an upper surface of the waveguide 40 has a predetermined height along the height direction of the waveguide 40. ) Is formed to protrude.

The resonator coupling member 41 is formed in a ring shape having a diameter smaller than that of the waveguide 40, and the center of the resonator coupling member 41 has a disk-shaped mirror 70 having the same diameter as that of the resonator coupling member 41. It is arranged.

In the center of the mirror 70, the electrodeless light bulb 60 extends in a predetermined length along the height direction of the waveguide 40 so as to be exposed to the outside, and the circumference of the resonator coupling member 41 and the mirror 70 Along the surface, the resonator 50 is contacted and fixedly coupled to the waveguide 40.

On the outer circumferential surface of the resonator 50, which is in contact with the circumferential surfaces of the resonator coupling member 41 and the mirror 70, the fastener 51 is fixed to the outer circumferential surface of the resonator 50 so that the resonator 50 can be fixedly coupled to the waveguide 40. It is coupled to, the lower inner peripheral surface of the resonator 50 has a predetermined length along the radial direction of the resonator 50 to prevent the mirror 70 from being separated from the resonator coupling member 41 and extends along the circumferential direction The locking step 52 is formed.

The resonator 50 accommodates the electrodeless bulb 60 in the inner space, shields the external emission of electromagnetic waves along the circumferential direction of the inner space, transmits it to the electrodeless bulb 60, and the light generated from the electrodeless bulb 60. It is made of a cylindrical mesh 53 having a mesh structure so that it can be transmitted to the outside.

The bottom surface of the mesh 53 is formed to penetrate through contact with the outer circumferential surface of the resonator coupling member 41, and a plurality of light transmitting holes 53c penetrate the plate surface of the side and top surfaces of the mesh 53. Formed.

The light penetrating hole 53c is radiated from the electrodeless bulb 60 on the circumferential surface of the resonator 50 so as to radiate the light generated from the electrodeless bulb 60 to the outside of the resonator 50. It is formed in the same direction as the traveling direction of light.

That is, the opening surfaces 53d which form the light transmitting holes 53c arranged on the same line as the electrodeless light bulb 60 along the height direction and the radial direction of the resonator 50 are respectively the height direction of the resonator 50 and , And are formed side by side in the radial direction, and the opening surface 53d of the light transmission hole 53c disposed diagonally with respect to the electrodeless light bulb 60 is inclined along the traveling direction of the light.

The light penetrating hole 53e may be gradually expanded from the inner circumferential surface side of the resonator 50 toward the outer circumferential surface side so that more light is radiated to the outside of the resonator 50 through the light penetrating hole 53e. It may be.

In other words, the upper opening surface 53f and the lower opening surface 53f of the light transmitting hole 53e are formed to be inclined mutually so as to extend from the inner circumferential surface side of the resonator 50 toward the outer circumferential surface side.

By such a configuration, when the resonator of the electrodeless lighting device having the inclined light transmitting hole according to the embodiment of the present invention inputs a driving signal to the high voltage generator 20, the high voltage generator 20 supplies AC power. The boosted and boosted high voltage is supplied to the electromagnetic wave generator 30, and the electromagnetic wave generator 30 generates electromagnetic waves having a very high frequency while oscillating by the high voltage. The electromagnetic wave is radiated into the resonator 50 through the waveguide 40 to excite the inert gas charged in the electrodeless light bulb 60 to emit light having a unique emission spectrum as the luminescent material is continuously plasmaled. Will occur.

The generated light propagates radially around the electrodeless light bulb 60 while hitting the opening surface 53d through the light transmitting hole 53c formed in the same direction as the direction of light propagation, and is not reflected. The light emitted to the outside, the light propagated to the rear of the electrodeless light bulb 60, that is, the mirror 70, is reflected by the mirror 70, and then emitted to the outside of the resonator 50 through the light transmission hole 53c. The space is revealed.

As described above, according to the present invention, a waveguide for guiding electromagnetic waves generated by the electromagnetic wave generator; A resonator fixedly coupled to one end of the waveguide and shielding external emission of the electromagnetic wave to achieve a resonance mode; In an electrodeless lighting device comprising an electrodeless bulb that is received in the internal space of the resonator to generate light, the peripheral surface of the resonator so as to emit light generated from the electrodeless bulb to the outside of the resonator Has a plurality of light transmission holes formed through the plate surface of the resonator in the same direction as the direction of light propagating in the radiation form from the electrodeless bulb, thereby generating radiation from the electrodeless bulb to the outside of the resonator. Provided is a resonator of an electrodeless lighting device having an inclined light transmitting hole capable of maximizing external emission of light to increase luminous efficiency.

Claims (2)

A waveguide for guiding the electromagnetic waves generated by the electromagnetic wave generator; A resonator fixedly coupled to one end of the waveguide and shielding external emission of the electromagnetic wave to achieve a resonance mode; In the electrodeless lighting device comprising an electrodeless bulb that is received in the internal space of the resonator to generate light, The circumferential surface of the resonator is formed through the plate surface of the resonator in the same direction as the traveling direction of the light propagating in the radiation form from the electrodeless bulb so as to radiate the light generated from the electrodeless bulb to the outside of the resonator. A resonator of an electrodeless illuminating device having inclined light transmitting holes, comprising a plurality of light transmitting holes. The method of claim 1, The light transmitting hole is a resonator of an electrodeless lighting device having an inclined light transmitting hole, characterized in that it is formed to gradually extend from the inner peripheral surface side of the resonator toward the outer peripheral surface side along the traveling direction of light.

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