KR20030042760A - Lighting apparatus for plasma lighting system - Google Patents

Abstract

PURPOSE: A lamp apparatus of an electrodeless lighting system is provided to maintain a delightful state of illumination by reflecting the light generated from a lamp only to a front direction and reducing the effulgence of the lamp. CONSTITUTION: A wrinkled reflective portion(140) has a shape of sphere and a plurality of fine projections(E). The fine projections are formed on an inner face or an outer face of the wrinkled reflective portion. A resonator(50) is installed in the inside of the wrinkled reflective portion in order to generate the electric field by using electromagnetic waves generated from an electromagnetic wave generator(30). An electrodeless lamp(60) is installed in the inside of the resonator in order to reflect the light on the wrinkled reflective portion by generating plasma.

Description

Lighting device of electrodeless lighting equipment {LIGHTING APPARATUS FOR PLASMA LIGHTING SYSTEM}

The present invention relates to a light device of the electrodeless lighting device, and more particularly to a light device of the electrodeless lighting device to reduce the glare to achieve a comfortable lighting state and to effectively dissipate heat generated therein.

In general, an electrodeless illuminator is a device that generates light by exciting a gas filled in an electrodeless lamp and converting the gas into a plasma state.

1 illustrates an example of the electrodeless illuminator, and as shown therein, the electrodeless illuminator is mounted on a casing 10 and an inner front surface of the casing 10 to generate a high voltage. Means 20 and electromagnetic wave generating means mounted on the inner front surface of the casing 10 at predetermined intervals from the high voltage generating means 20 to generate electromagnetic waves at a high voltage generated by the high voltage generating means 20 ( 30, a waveguide 40 which guides the electromagnetic waves generated by the electromagnetic wave generating means 30 and serves as a first resonator, and is installed outside the front surface of the casing 10 so as to communicate with the waveguide 40. A second resonator 50 that excites electromagnetic waves guided through the waveguide 40 to generate a strong electric field, and is rotatably mounted in the second resonator 50 so as to be strong in the second resonator 50. By electric field The electrode filled with the gas is excited to form a plasma to generate light, and the electrodeless lamp 60 is located on the rear of the electrodeless lamp 60 to reflect the light generated from the electrodeless lamp 60 to the front And a reflector 80 for collecting the light generated by the mirror 70 and the electrodeless lamp 60 and reflecting it forward.

Inside the casing 10, a first drive motor 90 for rotating the electrodeless lamp 60 and a connecting shaft 91 connecting the first drive motor 90 and the electrodeless lamp 60 are provided. It is provided. In addition, a cooling fan 100 and a second driving motor 101 for driving the fan are mounted on the casing 10 to dissipate heat generated by the high voltage generating means 20 and the electromagnetic wave generating means 30. An air duct 110 for guiding the flow of air generated by the cooling fan 100 to the high voltage generating means 20 and the electromagnetic wave generating means 30 is provided.

Operation of the electrodeless illuminator as described above is as follows.

First, when power is applied, high voltage is generated in the high voltage generating means 20, and the electromagnetic wave generating means 30 oscillates by the high voltage generated by the high voltage generating means 20. The electromagnetic wave oscillated by the electromagnetic wave generating means 30 is transmitted to the second resonator 50 through the waveguide 40 to distribute a strong electric field in the second resonator 50, and the electrodeless lamp by the strong electric field. The material filled in 60 is discharged and vaporized to generate plasma.

The light emitted by the plasma generated from the electrodeless lamp 60 is reflected by the mirror 70 and the reflector 80 to be illuminated forward.

At the same time, as the first driving motor 90 operates to rotate the electrodeless lamp 60, the electrodeless lamp 60 is cooled, and the first driving motor 90 operates to provide a cooling fan. As the air is rotated 100, external air flows through the air duct 110 to cool the high voltage generating means 20 and the electromagnetic wave generating means 30.

Meanwhile, as illustrated in FIG. 2, the reflection shade 80 reflecting the light generated by the electrodeless lamp 60 includes a parabolic curved portion 81 and a parabolic curved portion 81 formed in a half-cut form. It has a coupling radius 82 is formed extending through the small radius of curvature and coupled to the casing 10 side and the opening 83 which is an open portion of the parabolic curved portion 81. The reflection shade 80 is formed of a metal material and is coated with a reflective film on the inner surface of the parabolic curved portion 81.

The reflection shade 80 has a coupling portion 82 fixedly coupled to the casing 10 side, wherein the electrodeless lamp 60 and the second resonator 50 are positioned inside the reflection shade 80. .

A cylindrical light guide 120 having a predetermined length and a diameter corresponding to the diameter of the opening 83 of the reflector 80 is used to illuminate the light generated by the electrodeless lamp 60 indoors and outdoors. It is coupled to be connected to the opening 83 of the reflection shade 80. One or more light guides 120 are coupled to each other.

In this structure, the light generated by the electrodeless lamp 60 is reflected by the mirror 70 and the reflector 80 to be directed to the light guide 120. The light reflected through the mirror 70 and the reflector 80 illuminates the room or the room while passing through the light guide 120.

However, such a structure has to be provided with a reflection shade 80 and a light guide 120 to illuminate the indoor or outdoor, so that the initial cost is high and the length of the reflection shade 80 and the light guide 120 is long, thus providing an installation space. It takes a lot of the disadvantages of being constrained by the installation space.

In order to overcome such disadvantages, the applicant has been elected, and as shown in Figure 3, inside the resonator 50 made of a cylindrical mesh to generate an electric field by electromagnetic waves generated by the electromagnetic wave generating means The electrode filled with the material generated inside of the resonator 50 by the electric field generated by the plasma emits light is coupled to the electrodeless lamp 60, the reflector 130 formed in the shape of a sphere surrounds the resonator 50 It is fixedly coupled to the casing (10).

However, such a structure has a disadvantage in that the glare of light emitted through the reflector 130 is large and the effect of dissipating heat generated inside the reflector 130 to the outside is small.

An object of the present invention devised in view of the above point is to provide a light device of an electrodeless lighting device that can reduce the glare to achieve a comfortable lighting state, as well as effectively dissipate heat generated therein.

1 is a cross-sectional view showing a typical electrodeless illuminator,

Figure 2 is a front sectional view showing a light device of a conventional electrodeless lighting device,

Figure 3 is a front sectional view showing another embodiment of a conventional electrodeless lighting device lighting device,

4 is a cross-sectional view of an electrodeless illuminator equipped with an electrodeless illuminator light device of the present invention;

5 and 6 are front views showing the shapes of the fine protrusions constituting the electrodeless lighting device of the present invention, respectively;

7 is a cross-sectional view showing another modified example of the pleated reflector constituting the electrodeless illuminator of the present invention.

** Explanation of symbols for main parts of drawings **

30; Electromagnetic wave generating means 50; Resonator

60; Electrodeless lamps 140; Corrugated Reflector

E; Fine projection

In order to achieve the object of the present invention as described above, an electric field is generated by a pleated reflector in which a fine protrusion is formed in its spherical shape or on its inner surface or an outer surface, and an electromagnetic wave generated inside the pleated reflector and generated by an electromagnetic wave generating means. A resonator for generating and an electrodeless lamp provided in the resonator to generate plasma by a material filled therein by an electric field generated by the resonator so that the emitted light is reflected through the corrugated reflector. Provided is a lamp device of an electrodeless lighting device characterized in that.

Hereinafter, the electrodeless lighting device of the present invention will be described according to the embodiment shown in the accompanying drawings.

4 is a view illustrating an electrodeless illuminator equipped with an embodiment of the electrodeless illuminator lamp of the present invention. Referring to this, first, the electrodeless illuminator is provided on the inner front surface of a casing 10 having a predetermined shape. The high voltage generating means 20 for generating a high voltage is mounted, and the electromagnetic wave generating means 30 for generating electromagnetic waves by receiving the high voltage generated by the high voltage generating means 20 has a predetermined distance from the high voltage generating means 20. It is placed on the inner front of the casing 10.

In addition, a waveguide 40 is provided between the electromagnetic wave generating means 30 and the high voltage generating means 20 to guide the electromagnetic waves generated by the electromagnetic wave generating means 30 and act as a vacuum, and the waveguide 40 The resonator 50, which excites electromagnetic waves transmitted to the waveguide to generate a strong electric field, is coupled to protrude out of the casing 10 so as to communicate with the waveguide 40. The resonator 50 is formed of a cylindrical mesh of which one side is blocked.

In addition, an electrodeless lamp 60 filled with a material is positioned in the resonator 50, and a material filled in the electrodeless lamp 60 forms a plasma during the operation of the lamp to initiate a light emission and a metallic material that initiates light emission. In the lamp is made of a substance that forms a plasma inside.

Inside the casing 10, a first drive motor 90 for rotating the electrodeless lamp 60 and a connecting shaft 91 connecting the first drive motor 90 and the electrodeless lamp 60 are provided. It is provided. In addition, a cooling fan 100 and a second driving motor 101 for driving the fan are mounted on the casing 10 to dissipate heat generated by the high voltage generating means 20 and the electromagnetic wave generating means 30. An air duct 110 for guiding the flow of air generated by the cooling fan 100 to the high voltage generating means 20 and the electromagnetic wave generating means 30 is provided.

In addition, a pleated reflector 140 having a fine protrusion E formed on its outer surface in a spherical shape is fixedly coupled to the casing 10 to surround the resonator 50. That is, the resonator 50 is positioned inside the corrugated reflector 140 and the electrodeless lamp 60 is positioned inside the resonator 50. The mirror 70 may be mounted inside the resonator 50 to reflect the light generated from the electrodeless lamp 60 so as to be positioned at the rear of the electrodeless lamp 60.

The pleated reflector 140 has a spherical shape and is formed through the reflecting portion 141 and the one side of the reflecting portion 141 is formed with a fine projection (E) over the outer surface and the casing 10 side and It consists of a coupling portion 142 to be coupled.

As shown in FIG. 5, the minute projection E of the corrugated reflector 140 has a point a on the side where the electrodeless lamp 60 is located and a point facing the point a. a and a vertical valley (L) formed at regular intervals with respect to the vertical axis connecting a ') and a horizontal valley (N) formed at regular intervals with respect to the horizontal axis having a phase of 90 degrees with the vertical axis. It is formed to protrude in a pentagonal shape in the area formed by the intersection where the vertical valleys (L) and the horizontal valleys (N) meet.

The angle of the curved point of the pentagon-shaped fine protrusion (E) is 70 degrees to 130 degrees and the distance between the sides and the sides is preferably 5mm or less.

As a modification of the fine projection E of the corrugated reflector 140, as shown in Figure 6, at the point (a) and the point (a) of the side where the electrodeless lamp 60 is located Vertical valleys formed at regular intervals with respect to the vertical axis connecting the points (a ') facing each other and horizontal valleys formed at regular intervals with respect to the horizontal axis having a phase of 90 degrees with the vertical axis ( N) and the vertical bone (L) and the horizontal bone (N) is formed to protrude to a predetermined height so as to form a curved end portion in the area formed by the intersection point.

The reflector 130 is preferably formed of a diffusely reflective material, and an example of the diffusely reflective material may be a polymer material.

The diffusely reflective material preferably has a light transmittance of 50% to 95%, and preferably a heat resistant temperature of 100 degrees or more.

In another embodiment of the present invention, as shown in FIG. 7, a fine protrusion E formed in the corrugated reflector 140 is formed over the inner surface of the corrugated reflector 140.

Hereinafter, the operation and effect of the electrodeless lighting device lighting device of the present invention will be described.

First, when the power source is applied to generate a high voltage in the high voltage generating means 20, the electromagnetic generating device oscillates electromagnetic waves in the electromagnetic wave generating means 30 by the high voltage generated in the high voltage generating means 20. . The electromagnetic waves oscillated by the electromagnetic wave generating means 30 are transmitted to the resonator 50 through the waveguide 40 to distribute a strong electric field in the resonator 50, and to the electrodeless lamp 60 by the strong electric field. As the filled material is discharged and vaporized, the plasma is generated.

Light emitted by the plasma generated from the electrodeless lamp 60 is light having the same characteristics as natural light, and the light emitted by the plasma is a spherical wrinkled reflector 140 having a fine protrusion E. ) Is reflected outside. The portion where the corrugated reflector 140 is coupled to the casing 10 is reflected by the mirror 70 to be reflected through the corrugated reflector 140.

Meanwhile, as the power is applied, the first driving motor 90 operates to rotate the electrodeless lamp 60 to cool the electrodeless lamp 60, and the first driving motor 90. The external air flows through the air duct 110 as the cooling fan 100 rotates to cool the high voltage generating means 20 and the electromagnetic wave generating means 30.

The present invention is because the fine projection (E) is formed over the inner surface or the outer surface of the pleated reflector 140 of the spherical shape that reflects the light emitted from the electrodeless lamp 60 to the outside, the surface area is wider than the plane and the wrinkles In addition to reducing glare of light emitted through the type reflector 140, the reflected area illuminates a large space in all directions. In addition, since the surface area becomes wider, a heat dissipation area for dissipating heat generated inside is widened. Will minimize heating.

As described above, the lighting device of the electrodeless lighting device according to the present invention not only reflects the light generated by the electrodeless lamp in all directions by the electric field generated in the resonator, but also reduces the glare to maintain a comfortable lighting state. In addition, by effectively dissipating heat generated therein, it is possible to suppress breakage due to heating of the internal parts, thereby extending the life of the parts and increasing reliability.

Claims (4)

A pleated reflector having a spherical protrusion formed in a spherical shape over an inner surface or an outer surface thereof, a resonator positioned inside the pleated reflector for generating an electric field by electromagnetic waves generated by an electromagnetic wave generating means, and provided inside the resonator; Light device of an electrodeless lighting device, characterized in that it comprises a non-electrode lamp for generating a plasma by the material filled therein by the electric field generated in the resonator to reflect the light emitted through the corrugated reflector . According to claim 1, wherein the fine projection of the corrugated reflector and the vertical valley and the vertical axis formed at regular intervals with respect to the vertical axis connecting the point on the side where the electrodeless lamp is located and the point facing the point; Electrodeless illumination device, characterized in that protruding in the form of a pentagonal in the area formed by the horizontal valley formed at a predetermined interval with respect to the horizontal axis having a phase of the 90 degree angle and the intersection points where the vertical valleys and the horizontal valleys meet Light fixture. The lamp device of claim 2, wherein a curved angle of the pentagon-shaped fine protrusion is 70 degrees to 130 degrees and a distance between the sides and the sides is 5 mm or less. According to claim 1, wherein the fine projection of the corrugated reflector is a vertical valley and the vertical axis formed at regular intervals based on a vertical axis connecting the point on the side where the electrodeless lamp is located and the point facing the point. Formed to protrude to a predetermined height to form a curved surface at an end formed in a region formed by a horizontal valley formed at a predetermined interval with respect to a horizontal axis having a phase of 90 degrees and a vertical intersection point where the vertical valleys and the horizontal valleys meet each other. A light device of an electrodeless illuminator characterized by the above-mentioned.