KR100464058B1 - Plasma lighting system - Google Patents

Abstract

The present invention relates to an electrodeless lamp system, and the present invention relates to a magnetron for generating electromagnetic waves by connecting to a power supply, and to an outlet of the magnetron and to encapsulating a light emitting material and an inert gas therein in the electromagnetic wave generator. Formed as a conductor to select a frequency of a specific band from the lamp that emits light while the inert gas plasma discharges the light emitting material by the electromagnetic waves, and the electromagnetic wave guided by the magnetron by connecting the lamp to the outlet of the magnetron. An inductor, a resonator having a predetermined resonance space and accommodating the lamp in the resonance space and fixedly installed on one side of the magnetron so as to communicate with the outlet of the magnetron, and an outlet of the magnetron to accommodate the lamp and the resonator to reflect light Magnesium including reflector to fix on the side By directly coupling the theory to the waveguide resonator removed to obtain the electrodeless lamp system, a more compact and simplified.

Description

Induction Lamp System {PLASMA LIGHTING SYSTEM}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electrodeless lamp system using electromagnetic waves, and more particularly, to an electrodeless lamp system capable of compacting a lamp structure by incorporating a feeder inside the resonator to use LC resonance.

In general, an electrodeless lamp system (PLS: Plasma Lighting System) allows a compound or a metal compound to emit light continuously while electromagnetic waves generated from a high frequency oscillator (magnetron) used in a microwave oven make an inert gas in a bulb into a plasma state. It is a lighting device that can provide an excellent amount of light without an electrode.

This electrodeless lamp system can produce four luminous fluxes of 400W metal halides with one PLS and energy savings of more than 20%. In addition, since the light is emitted by the plasma light emitting principle without filament, it can be used for a long time without deterioration of the luminous flux, and since it realizes the same continuous light spectrum as natural white light, it not only protects eyesight but also reduces the emission of ultraviolet rays and infrared rays, thereby providing a comfortable lighting environment. Can provide.

1 is a longitudinal sectional view showing an example of a conventional electrodeless lamp system.

As shown in the drawing, a conventional electrodeless lamp system includes a magnetron 2, a high pressure generator 3, a waveguide 4, and the like inside the casing 1, and a light bulb 5 and The resonator 6 is installed to guide the electromagnetic waves oscillated from the magnetron 2 to the resonator 6 using the waveguide 4 to emit light while the inert gas in the bulb 5 becomes plasma.

Looking at this in more detail, a magnetron (2) mounted inside the casing (1) to generate electromagnetic waves, a high-voltage generator (3) for boosting and supplying commercial AC power to the magnetron (2) at high pressure, and the magnetron (2) Waveguide (4), which communicates with the outlet of the magnetron (2) and transmits the electromagnetic waves generated by the magnetron (2), and the luminescent material encapsulated by the electromagnetic wave energy by enclosing the luminescent material, the inert gas, and the discharge catalyst material inside the plasma. And a resonator 6 through which the light emitted from the light bulb 5 passes through the light bulb 5 for generating light, and covers the waveguide 4 and the front of the light bulb 5 to block electromagnetic waves. ) And a reflector (7) for intensively reflecting light generated from the bulb to the straight line, and a dielectric mirror (8) mounted inside the resonator (6) at the rear side of the bulb (5) for reflecting light while passing electromagnetic waves; On one side of the casing (1) It is composed of a swing torch (2) and the high-voltage generator 3, a cooling fan assembly (9) for cooling.

In the drawings, reference numeral M1 denotes a bulb motor for rotating a light bulb, and M2 denotes a fan motor for rotating a cooling fan.

The conventional electrodeless lamp system as described above operates as follows.

When a driving signal is input to the high pressure generator 3 according to the command of the control unit, the high pressure generator 3 boosts the AC power to supply the boosted high pressure to the magnetron 2, and the magnetron 2 oscillates by the high pressure. Generates electromagnetic waves with very high frequencies.

The electromagnetic waves radiate into the resonator 6 through the waveguide 4 to excite the inert gas enclosed in the bulb 5 to generate a light having a unique emission spectrum while continuously emitting a luminescent material. The light was reflected by the reflector 7 and the dielectric mirror 8 to brighten the space.

However, in the conventional electrodeless lamp system as described above, as the waveguide 4 having a predetermined internal volume is installed between the magnetron 2 and the resonator 6, the total size of the system is increased by the volume of the waveguide 4. Increasingly, there was a limit to miniaturizing the product.

The present invention has been made in view of the problems of the conventional electrodeless lamp system as described above, and provides a more compact electrodeless lamp system by allowing electromagnetic waves to be induced by a resonator even after removing the waveguide. have.

1 is a cross-sectional view showing an example of a conventional electrodeless lamp system,

2 is an exploded perspective view showing an example of the electrodeless lamp system of the present invention;

3 is a cross-sectional view illustrating an example of the electrodeless lamp system of the present invention;

4 is an enlarged detailed view of part “A” of FIG. 3;

5 to 7 are perspective views showing examples of the inductor in the present invention.

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

10: casing 20: power supply

30: magnetron 40: lamp

41: light emitting part 42: support part

43: pseudo-electrode 50: inductor

51: first fixing part 52: second fixing part

53 through hole 60 resonator

61: first resonator 62: second resonator

63: stub 64: dielectric mirror

70: reflection shade

In order to achieve the object of the present invention, by connecting the power supply to the magnetron for generating electromagnetic waves, connected to the outlet of the magnetron and the inside of the light emitting material and inert gas to be filled together by the electromagnetic wave delivered from the electromagnetic wave generator A lamp that emits light while the inert gas plasma-discharges the light emitting material, an inductor formed of a conductor connecting the outlet of the magnetron to the lamp and selecting a frequency of a specific band among electromagnetic waves guided from the magnetron, A resonator having a resonant space and accommodating the lamp in the resonant space and fixedly installed at one side of the magnetron to communicate with the outlet of the magnetron, and fixedly installed at the outlet side of the magnetron to accommodate the lamp and the resonator to reflect light Providing an electrodeless lamp system with a reflector .

Hereinafter, the electrodeless lamp system according to the present invention will be described in detail with reference to the embodiment shown in the accompanying drawings.

2 is an exploded perspective view of an example of the electrodeless lamp system of the present invention, and FIG. 3 is a cross-sectional view illustrating an example of the electrodeless lamp system of the present invention, and FIG. 4 is an enlarged detail of an “A” part of FIG. 3. 5 to 7 are perspective views showing examples of the inductor in the present invention.

As shown in the drawing, the electrodeless lamp system according to the present invention significantly reduces the size of the electrodeless lamp system by directly connecting the magnetron to the resonator.

2 and 3, 10 is a casing. The magnetron 30 to be described later is inserted into and fixed to the casing 10.

2 and 3 show the power supply unit 20 to apply AC power to the magnetron 30 inside the casing 10 so that electromagnetic waves are generated from the magnetron 30.

2 and 3, 30 is a magnetron as an electromagnetic wave generating unit. The magnetron 30 is used in an electrodeless lamp system using electromagnetic waves as known, and converts electrical energy into high frequency energy such as electromagnetic waves, and induces the high frequency energy to a resonator of the lighting system to inert gas and light emitting material in the lamp. Excitation to generate light.

2 and 3, 40 is a lamp. The lamp 40 has a predetermined internal volume, is formed in a spherical shape, and is formed integrally extending in the light emitting part 41 and the light emitting part 41 to seal the encapsulating material so as to emit light while making plasma therein. It consists of a support 42 for supporting through the through-hole of the reflection shade (to be described later).

The light emitting part 41 is formed in a spherical or cylindrical shape, and is made of a material having high light transmittance and extremely low dielectric loss, such as quartz, and accommodated in the second resonator part of the resonator.

The encapsulating material includes a light emitting material such as a metal, a halogen group compound, sulfur or celen, which forms a plasma during the operation of the lamp and drives light emission, and an argon (Ar) or krypton for forming a plasma inside the light emitting part 41 at the initial stage of light emission. (Xe), inert gas such as krypton (Kr), and a discharge catalyst material to facilitate initial discharge, such as mercury, to facilitate lighting, or to control the spectrum of light generated.

The support part 42 is formed of the same material as the light emitting part 41 and is inserted into the second fixing part () of the inductor 50, which will be described later, and fixed with an adhesive. It is preferable that a similar electrode 43 made of a conductor such as tungsten be inserted into the support 42 as shown in FIG.

It is preferable that the similar electrode 43 has a diameter of 1/5 or less of the maximum diameter of the inductor so as to prevent damage of the support 42 due to a difference in thermal expansion rate.

50 in FIG. 2 and FIG. 3 are inductors. The inductor 50 is negatively formed at both ends of the inductor 50 to be accommodated in the first resonator part () of the resonator () to be described later.

In addition, the inductor 50 is formed by forming a first fixing part 51 for fixing the antenna 31 of the magnetron 30 and a second fixing part 52 for fixing the support part 42 of the lamp 40. . Preferably, the first fixing part 51 and the second fixing part 52 are formed to be substantially equal to the outer diameter of the antenna 31 and the outer diameter of the support part 42.

In addition, as shown in FIGS. 4 and 5, the similar electrodes 43 pass through the centers of the first fixing part 51 and the second fixing part 52 to be connected to the antenna 31 of the magnetron 30. The through hole 53 is formed to be.

In addition, when the diameter of the antenna 31 is larger than the diameter of the support part 42, the second fixing part 52 may prevent the loss of electromagnetic waves due to a sudden change in thickness. It is preferable to form gradually the outer diameter of the) toward the end.

In addition, the end portion of the second fixing part 52 side of the inductor 50 may have a circumference as shown in FIG. 6 so as to have elasticity when inserting the supporting part 42 of the lamp 40 or to easily inject an adhesive. It is preferable to form several uneven grooves 52a along the direction.

Here, the inductor 50 may be formed in a spring shape as shown in FIG. In this case, it is preferable to further include an antenna cap 54 between the inductor 50 and the antenna 31 of the magnetron 30 so as to sandwich and fix the antenna 31 of the inductor 50 and the magnetron 30, respectively. Do.

2 and 3, 60 shows a resonator, and the resonator 60 is formed in a cylindrical structure with a main surface blocked, and formed in a mesh-shaped cylindrical structure with a first resonator 61 coupled to the magnetron 30. A second resonator 62 is connected to the first resonator 61.

The first resonator 61 has front and rear sides formed in an open structure, but a flange 61a is formed at an end coupled to the casing 10 so as to be screwed. Further, an annular or block shaped stub 63 is provided on the side surface of the flange 61a of the first resonator 61 and the inner circumferential surface of the first resonator 61 to guide the electromagnetic wave toward the lamp through impedance matching.

The second resonator 62 is formed in a mesh shape having a high aperture ratio so that the first resonator 61 is open and the other side is blocked, but light can pass therethrough.

In addition, between the first resonator 61 and the second resonator 62, a reflection mirror 64 having a dielectric coating layer formed on an outer surface (i.e., opposite to the support of the lamp) is provided. It is desirable to increase the brightness.

Although not illustrated in the drawings, the resonator 60 may integrally form the first resonator 61 and the second resonator 62.

2 and 3, 70 is a reflection shade reflecting light emitted from the lamp in a specific direction. The reflection shade 70 is formed in an ellipse or similar shape having a predetermined curvature and installed between the lamp and the resonator 60. In addition, the reflection shade 70 is formed of a dielectric material such as quartz or aluminum so that the electromagnetic waves transmitted from the magnetron 30 can freely move in the resonator 60.

The electrodeless lamp system of the present invention as described above has the following effects.

In response to a command from the controller, power is supplied from the power supply unit 20 to the magnetron 30, and the magnetron 30 generates electromagnetic waves having high frequency energy.

The electromagnetic wave is guided into the second resonator 62 through the inductor 50 to resonate at an appropriate resonant frequency, and the electromagnetic wave resonates inside the second resonator 62. The inert gas enclosed in (41) is discharged, and heat generated by the discharge vaporizes a light emitting material to form a plasma, and the plasma emits high intensity white natural light by continuously maintaining the discharge by electromagnetic waves. do.

The light is reflected to the front side by the reflection mirror and the reflector 70 and passes through the second resonator 62 of the resonator 60 to illuminate the required space.

At this time, by installing the pseudo electrode 43 in the lamp 40 to increase the intensity of the electric field applied to the light emitting portion 41, the inert gas in the light emitting portion 41 during the initial lighting to make the plasma more quickly to reduce the lighting time Can be.

In the electrodeless lamp system according to the present invention, the magnetron is directly coupled to the resonator to remove the waveguide, thereby making it possible to obtain a more compact and simplified electrodeless lamp system.

Claims (12)

A magnetron connected to a power supply to generate electromagnetic waves, A lamp connected to the outlet of the magnetron and encapsulating a light emitting material and an inert gas therein so that the inert gas emits light while the inert gas plasma discharges the light emitting material by electromagnetic waves transmitted from the electromagnetic wave generating unit; An inductor formed of a conductor connecting the outlet of the magnetron and a lamp to select a frequency of a specific band among electromagnetic waves guided by the magnetron, A resonator having a predetermined resonance space and accommodating the lamp in the resonance space and fixedly installed at one side of the magnetron so that the outlet of the magnetron communicates with the lamp; An electrodeless lamp system comprising a reflection shade fixedly installed at the outlet side of the magnetron to accommodate the lamp and the resonator to reflect light. The method of claim 1, The inductor includes an first fixing part inserted into and fixed to an outlet of the magnetron, and a second fixing part formed on the other side of the first fixing part to insert and fix the lamp. The method of claim 2, The electrodeless lamp system, characterized in that the second fixing portion to form a smaller diameter toward the end. The method of claim 3, The electrodeless lamp system, characterized in that the end of the second fixing portion is formed to be uneven with a plurality of grooves along the circumferential direction. The method of claim 2, The electrodeless lamp system, characterized in that the first fixing portion and the second fixing portion to form a through hole in the boundary portion so as to communicate with each other. The method of claim 1, Inductor lamp system, characterized in that the inductor is a spring shape. The method of claim 6, And an antenna cap between the inductor and the outlet of the magnetron, the antenna cap being fitted between both ends of the inductor and the magnetron. The method of claim 1, The lamp is an electrodeless lamp system, characterized in that to insert a similar electrode made of a conductor so as to increase the strength of the electric field therein. The method of claim 8, The electrode of the electrodeless lamp system, characterized in that the diameter of the pseudo-electrode is less than 1/5 the maximum diameter of the inductor. The method of claim 1, The resonator is formed in a cylindrical structure in which the main surface is clogged to receive an inductor, and is formed in a structure in which the direction of propagation of the electromagnetic waves is open. The resonator is coupled to the magnetron, and one side in contact with the first resonator is formed in an open structure to emit light from the lamp. An electrodeless lamp system comprising: a second resonator unit accommodating the unit and the rest of which is formed in a cylindrical structure having a mesh shape and connected to the first resonator unit. The method of claim 10, The electrodeless lamp system of claim 1, further comprising a reflective mirror having a dielectric coating layer formed on an outer surface at a boundary between the first resonator and the second resonator. The method of claim 10, The first resonator unit further comprises a stub for guiding electromagnetic waves to the second resonator therein, the electrodeless lamp system.