KR100430007B1 - Feeder structure for plasma lighting system - Google Patents

Abstract

The present invention relates to an electrodeless illumination system, and the present invention relates to at least one vertex of the end of the electromagnetic feeder unit for inducing electromagnetic waves into the electromagnetic resonance unit in an electrodeless illumination system that generates a resonance frequency using LC resonance technology. By forming to have, the electric field is concentrated at the end of the electromagnetic feeder unit, and through this to supply a strong electric field to the bulb can be greatly reduced the initial lighting time.

Description

Feeder structure of induction lighting system {FEEDER STRUCTURE FOR PLASMA LIGHTING SYSTEM}

The present invention relates to an electrodeless illumination system using electromagnetic waves, and more particularly, to a feeder structure of an electrodeless illumination system that can reduce initial lighting time in an electrodeless illumination system having a feeder unit inside the resonator to use LC resonance. will be.

In general, an electrodeless lighting system (PLS) is a system in which electromagnetic waves generated from a high frequency oscillator (magnetron) used in a microwave oven make a plasma of an inert gas in a light bulb, and a compound or a metal compound emits light continuously. It is a lighting device that can provide an excellent amount of light without an electrode.

This electrodeless lighting system can generate 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 illumination system.

As shown in the related art, a conventional electrodeless lighting system includes a magnetron 2, a high pressure generator 3, a waveguide 4, and the like inside a casing 1, and a light bulb 5 and an outside of the casing 1, respectively. 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. ), 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 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 illumination 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 wave radiates 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.

In such an electrodeless lighting system, the strength of the electric field required for the initial discharge is determined by the size or shape of the bulb 5 or the type of material or gas pressure enclosed in the bulb 5. The intensity is required several times greater than the intensity of the electric field required to maintain the light emission. To this end, conventionally, mercury is added to the inside of the bulb 5 to reduce the strength of the required electric field, or an additional field strengthening member is added to the inside of the resonator 6 to increase the strength of the electric field applied to the bulb 5. It is being sought.

However, the mercury may be added to the bulb 5 as well as to shorten the lighting time, but this still remains a problem in that it cannot be re-lit for a predetermined time until the pressure of the gas decreases after the light is turned off. On the other hand, adding a separate electric field reinforcing member has a problem that increases the number of parts and the number of assembly work to increase the production cost.

The present invention has been made in view of the problems of the conventional electrodeless lighting system as described above, electrodeless lighting that can facilitate the initial lighting by allowing a stronger electric field to be collected in the bulb without adding a separate material or member It is an object of the present invention to provide a feeder structure of the system.

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

Figure 2 is a longitudinal sectional view showing an example of the electrodeless illumination system of the present invention.

Figure 3 is a longitudinal sectional view showing an example of the electrodeless illumination system of the present invention.

Figure 4 is a perspective view of the main portion shown to explain the feeder in the electrodeless illumination system of the present invention.

5 is a perspective view showing a modification of the feeder unit of the present invention.

Figure 6 is a detailed view showing the main portion of the electric field reinforced member embedded in the feeder unit of the present invention.

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

10: power supply 20: magnetron

30: electromagnetic wave feeder unit 31: electric field strengthening stage

32: electric field strengthening member 40: resonant frequency generator

41: inductor 42: capacitor

50: electromagnetic wave resonance unit 60: lamp unit

61 light bulb 70 reflector

In order to achieve the object of the present invention, the power supply unit, an electromagnetic wave generation unit for generating an electromagnetic wave of a specific frequency connected to the power supply unit, an electromagnetic wave feeder unit for guiding electromagnetic waves by connecting to the outlet of the electromagnetic wave generation unit, and an electromagnetic wave feeder unit A resonant frequency generator having an inductor and a capacitor to select a frequency of a specific band from the guided electromagnetic waves, and a predetermined cavity to accommodate the electromagnetic feeder and the resonant frequency generator together Electromagnetic resonator which traps electromagnetic waves and has a resonant frequency, and the inert gas is encapsulated in the electromagnetic resonator by enclosing the luminescent material and the inert gas together and resonating in the electromagnetic resonator. In an electrodeless lighting system composed of a lamp unit that emits light, The wave feeder unit provide a feeder structure of an electrodeless lighting system, characterized in that to form the ends which are adjacent to the lamp unit so as to at least of one or more vertices.

EMBODIMENT OF THE INVENTION Hereinafter, the feeder structure of the electrodeless illumination system by this invention is demonstrated in detail based on one Example shown in an accompanying drawing.

4 is a perspective view illustrating main parts of the feeder in the electrodeless illumination system of the present invention, FIG. 5 is a perspective view showing a modified example of the feeder in the electrodeless illumination system of the present invention, and FIG. 6 is a feeder in the electrodeless illumination system of the present invention. It is the detail which showed the main part which embedded the electric field strengthening member in the part.

As shown in the present invention, the electromagnetic wave generated by the magnetron, which is an electromagnetic wave generating unit, is introduced into the electromagnetic resonance unit to form the electromagnetic feeder unit in various shapes so that the materials encapsulated in the bulb emit a plasma and the electric field is formed in the electric bulb. To focus.

That is, as shown in FIG. 2, the electrodeless illumination system is connected to the power supply unit 10 to generate an electromagnetic wave, and is connected to an outlet of the electromagnetic wave generator 20 to guide the electromagnetic wave. In addition, an inductor and a capacitor may be used to select a frequency of a specific band from the electromagnetic feeder 30 to form an appropriate supply and distribution of electromagnetic waves, and electromagnetic waves guided through the electromagnetic feeder 30. A resonant frequency generating unit 40, and provided with a predetermined cavity (cavity) to accommodate the electromagnetic feeder unit 30 and the resonant frequency generating unit 40 (electromagnetic resonator) to trap the electromagnetic wave to have a resonant frequency ( 50) and a lamp unit 60 disposed at the front side of the resonant frequency generating unit 40 and encapsulating a light emitting material, an inert gas, and a discharge catalyst material therein to emit light by electromagnetic waves, and the lamp unit 60 and Resonant frequency Interposed between the part (40) constitutes a reflection-diameter (70) for reflecting a light emitted from the lamp unit 60 toward the front side.

The electromagnetic feeder unit 30 is formed in a generally circular round rod shape, one end of which penetrates the bottom surface of the electromagnetic resonance unit 50 and is connected to an antenna of the magnetron, which is the electromagnetic wave generator 20, while the other end generates a resonance frequency. Passing through the central portion of the portion 40 extends to the periphery of the lamp unit 60.

In addition, the electromagnetic wave feeder unit 30 may be formed in the shape of a round rod, as shown in FIG. 4, but may form an electric field strengthening stage 31 having a 'conical' shape having an end point adjacent to the bulb.

In addition, as shown in FIG. 5, the electric field strengthening stage 31 may be formed in an 'angular pyramid' or 'wedge cross section' or 'spherical' or 'tapered' or square 'or' polygon 'shape.

In addition, as shown in (e) and (f) of FIG. 5, the electromagnetic feeder unit 30 may be formed in a rectangular or polygonal cross-sectional shape in a circular cross-sectional shape of the column shape, or may be formed in a tapered cross-sectional shape. . Moreover, a cross-sectional shape can also be formed in several or more shape in the longitudinal direction.

Meanwhile, as shown in FIG. 6, an electric field reinforcing member 31 is embedded at the end of the electromagnetic feeder unit 30 to increase the strength of the electric field, but the electric field reinforcing member 33 is twisted into a helical shape or is fixed. You can also buy at intervals.

In the drawings, reference numeral 51 denotes a resonator unit body, 52 denotes a reticular body, and 61 denotes a light bulb.

The feeder structure of the electrodeless illumination 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 10 to the magnetron 20, which is an electromagnetic wave generator, and the magnetron 20 generates electromagnetic waves having high frequency energy.

The electromagnetic wave is guided into the electromagnetic resonator 50 through the electromagnetic feeder 30 and resonates within the electromagnetic resonator 50. In this process, a frequency signal is applied to the inductor 41 and the capacitor 42. The inductor 41 and the capacitor 42 select an appropriate resonance frequency.

Electromagnetic waves of this resonant frequency band discharge the inert gas enclosed in the bulb 61 of the lamp unit 60 while resonating inside the resonator unit body 51 of the electromagnetic resonance unit 50, and generates heat generated by the discharge. The light emitting material is vaporized to form a plasma, and the plasma emits high intensity white natural light by continuously maintaining the discharge by electromagnetic waves. This light is reflected to the front side by the reflector 70 and passes through the network 52 to illuminate the required space.

At this time, when the end of the electromagnetic wave feeder unit 30 adjacent to the light bulb 61 is formed in an angular shape, a spherical shape, or a tapered shape, the electric field is concentrated and the intensity of the electric field is increased, thereby encapsulating the inside of the light bulb 61. By applying a stronger electric field to one inert gas, the initial lighting time can be remarkably reduced by allowing the inert gas to be easily converted into plasma during the initial lighting.

On the other hand, even when a separate electric field strengthening member 32 is embedded in the electromagnetic feeder unit 30, the strength of the electric field applied to the electric bulb by the electric field strengthening member 32 can be increased, and thus the lamp unit at the time of initial lighting. It is possible to reduce the lighting time by causing the inert gas in the 60 to plasma more quickly. In this case, as the electric field reinforcing member 32 is embedded in the electromagnetic feeder unit 30 to be provided, there is no need to provide a separate support for installing the electric field reinforcing member 32, thereby increasing the number of parts. Can be prevented.

The present invention is to provide a strong electric field to the bulb by variously forming the structure of the electromagnetic feeder to guide the electromagnetic waves into the electromagnetic resonance portion in the electrodeless lighting system that generates the resonance frequency using LC resonance technology to facilitate the concentration of the electric field By doing so, the initial lighting time can be greatly reduced.

Claims (3)

A power supply unit, an electromagnetic wave generation unit connected to the power supply unit to generate an electromagnetic wave of a specific frequency, an electromagnetic wave feeder unit connected to an outlet of the electromagnetic wave generation unit to guide the electromagnetic wave and to form an appropriate supply and distribution of the electromagnetic wave, and an electromagnetic wave Resonant frequency generating unit having an inductor and a capacitor to select a frequency of a specific band among the electromagnetic waves guided through the feeder, and a predetermined cavity to accommodate the electromagnetic feeder and the resonant frequency generating unit together An electromagnetic wave resonator which traps electromagnetic waves and has a resonant frequency, and inert gas encapsulates the light emitting material and the inert gas together with the electromagnetic wave resonant in the electromagnetic resonator and discharges the luminescent material into plasma. Electrodeless lighting consisting of a lamp unit that emits light while emitting light In the system, A feeder structure of an electrodeless illumination system, characterized in that the electromagnetic feeder portion is formed to have at least one vertex at an end adjacent to the lamp portion. The method of claim 1, A feeder structure of an electrodeless illumination system, characterized in that the electromagnetic feeder portion is formed such that the end portion adjacent to the lamp portion has a narrower cross-sectional area than the opposite end portion. The method of claim 1, A feeder structure of an electrodeless illumination system, characterized in that an electromagnetic feeder unit embeds an electric field strengthening member therein.