KR100400403B1 - Structure for preventing heat of globe in plasma lighting system - Google Patents

Abstract

The present invention relates to a reflector heating prevention structure of an electrodeless lighting device, the present invention is formed in a spherical shape is fixed to the casing and coupled to the casing, fixedly coupled to the casing to be located inside the reflector is generated in the electromagnetic wave generating means A resonator for generating an electric field by electromagnetic waves, an electrodeless lamp in which light is emitted while a plasma is generated by a material filled in the resonator by an electric field generated in the resonator, and between the resonator and the reflector And a heat concentrating preventing means for preventing heat generated from the electrodeless lamp from intensively heating the proximal portion of the reflector. The reflector for reflecting light emitted in an omnidirectional manner while generating plasma in the electrodeless lamp. Concentrated by heat generated with light in the electrodeless lamp By preventing heat deformation and breakage and deformation, the lifespan of the reflector may be extended, thereby reducing maintenance costs and increasing reliability.

Description

Reflector heating prevention structure of electrodeless lighting equipment {STRUCTURE FOR PREVENTING HEAT OF GLOBE IN PLASMA LIGHTING SYSTEM}

The present invention relates to a reflector heating prevention structure of an electrodeless lighting device, and in particular, a reflector for reflecting light emitted omnidirectionally while generating plasma in an electrodeless lamp is heated and deformed by heat generated together with light in the electrodeless lamp. The anti-reflective heating prevention structure of the electrodeless lamp which can prevent this from happening is related.

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, which has been filed by the present applicant, and as shown in the drawing, the electrodeless illuminator first generates a high voltage on the inner surface of the casing 10 having a predetermined shape. The casing 10 is provided at a predetermined interval from the high voltage generating means 20 in which the generating means 20 is mounted and an electromagnetic wave generating means 30 which receives the high voltage generated by the high voltage generating means 20 and generates electromagnetic waves. ) It is mounted on the inner front side.

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 driving motor 70 for rotating the electrodeless lamp 60 and a connecting shaft 71 connecting the first driving motor 70 and the electrodeless lamp 60 are provided. It is provided. In addition, a cooling fan 80 and a second driving motor 81 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 90 is provided to guide the flow of air generated by the cooling fan 80 to the high voltage generating means 20 and the electromagnetic wave generating means 30.

And the reflector 100 is formed in a spherical shape is fixedly coupled to the casing 10 to surround the resonator 50.

The reflector 100 is formed after the reflector 101 formed in a spherical shape and the neck portion 102 and the neck portion 102 extending through and bent in a cylindrical shape having a predetermined length on one side of the reflecting portion 101. It is formed to be extended to be bent to have an area of the coupling portion 103 is coupled to the casing 10 side. The reflector 100 may be a polymer material that is a diffuse reflection material.

The reflector 100 has a coupling portion 103 fixedly coupled to one side of the casing 10 so that the resonator 50 is positioned inside the reflector 101. The electrodeless lamp 60 is positioned inside the resonator 50, and a mirror 110 reflecting light is mounted inside the resonator 50 such that the electrodeless lamp 60 is positioned behind the electrodeless lamp 60.

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 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.

As the plasma is generated in the electrodeless lamp 60, the light emitted through the mirror 110 and the reflector 100 is reflected in all directions.

At the same time, the first driving motor 70 operates to rotate the electrodeless lamp 60 to cool the electrodeless lamp 60, and the first driving motor 70 operates to cool the fan. As the 80 is rotated, external air flows through the air duct 90 to cool the high voltage generating means 20 and the electromagnetic wave generating means 30.

However, in the conventional structure as described above, high temperature heat is generated in the process of emitting light while the plasma is generated in the electrodeless lamp 60, and thus the high temperature heat generated in the electrodeless lamp 60 is not generated. The reflector 100 is transmitted to a portion of the reflector 100 adjacent to the electrode lamp 60 so that the reflector 100 is deformed or damaged. In particular, when the electrodeless lighting device is installed, the casing 10 is located on the upper side and the reflector 100 is on the lower side. When installed so as to be located in the electrodeless lamp 60 and the reflector neck 102 adjacent to the heating is concentrated so that there was a problem that the neck 102 of the reflector 100 is easily deformed and broken.

An object of the present invention devised in view of the above point is to prevent the reflector for reflecting the light emitted in a omni-directional direction while generating a plasma in the electrodeless lamp is heat-deformed by the heat generated with the light in the electrodeless lamp It is to provide an anti-reflective heating structure of the electrodeless lamp.

1 is a cross-sectional view showing an example of a conventional electrodeless lighting device,

Figure 2 is an electrodeless illuminator equipped with an electrodeless lighting device reflector heating prevention structure of the present invention,

3 is a cross-sectional view showing an operating state of the electrodeless lighting device reflector heating prevention structure of the present invention.

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

10; Casing 30; Electromagnetic wave generating means

50; Resonator 60; Induction lamp

120; Heat concentrating means 121; First reflection rubber part

122; Support shaft 123; 2nd reflection rubber part

121a, 123a; Horizontal section 121b, 123b; Vertical section

121c, 123c; Cross section

In order to achieve the object of the present invention as described above to form an electric sphere by the reflector is formed in a spherical shape and fixedly coupled to the casing, and fixedly coupled to the casing so as to be located inside the reflector to generate an electric field generated by the electromagnetic wave generating means A resonator, an electrodeless lamp positioned within the resonator and filled with the material generated by an electric field generated by the resonator to generate a plasma, and positioned between the resonator and the reflector to be generated in the electrodeless lamp The anti-reflective heating preventing structure of the electrodeless illuminator is provided comprising a heat concentrating preventing means for preventing the heat from being concentrated on the central portion of the reflector.

Hereinafter, the electrodeless illuminator reflector heating prevention structure of the present invention will be described according to the embodiment shown in the accompanying drawings.

FIG. 2 illustrates an electrodeless illuminator provided with an embodiment of the electrodeless illuminator reflector heating preventing structure of the present invention. Referring to this, first, the electrodeless illuminator

The high voltage generating means 20 for generating a high voltage is mounted on the inner surface of the casing 10 having a predetermined shape, and the electromagnetic wave generating means 30 for receiving the high voltage generated by the high voltage generating means 20 to generate electromagnetic waves is the high voltage. It is mounted on the inner front of the casing 10 at a predetermined interval from the generating means 20.

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 driving motor 70 for rotating the electrodeless lamp 60 and a connecting shaft 71 connecting the first driving motor 70 and the electrodeless lamp 60 are provided. It is provided. In addition, a cooling fan 80 and a second driving motor 81 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 90 is provided to guide the flow of air generated by the cooling fan 80 to the high voltage generating means 20 and the electromagnetic wave generating means 30.

And the reflector 100 is formed in a spherical shape is fixedly coupled to the casing 10 to surround the resonator 50.

The reflector 100 is formed after the reflector 101 formed in a spherical shape and the neck portion 102 and the neck portion 102 extending through and bent in a cylindrical shape having a predetermined length on one side of the reflecting portion 101. It is formed to be extended to be bent to have an area of the coupling portion 103 is coupled to the casing 10 side. The reflector 100 may be a polymer material that is a diffuse reflection material.

The reflector 100 has a coupling portion 103 fixedly coupled to one side of the casing 10 so that the resonator 50 is positioned inside the reflector 101. The electrodeless lamp 60 is positioned inside the resonator 50, and a mirror 110 reflecting light is mounted inside the resonator 50 such that the electrodeless lamp 60 is positioned behind the electrodeless lamp 60.

In addition, between the resonator 50 and the reflector 100, heat concentration preventing means 120 is provided to prevent heat generated in the electrodeless lamp 60 from heating the proximal portion of the reflector 100. .

The heat concentrating preventing means 120 is formed in an annular shape having a predetermined thickness and width so that the one side is fixed to the first reflection rubber part 121 fixedly coupled to the casing 10 so as to surround the resonator 50. The electrodeless second reflective rubber part 123 is formed to have a plurality of support shafts 122 extended to have a predetermined length in the longitudinal direction of the first reflective rubber part 121 and an annular shape having a predetermined thickness and width. It is connected and supported at the ends of the plurality of support shafts 122 to surround the lamp 60 and the resonator 50.

The support shaft 122 is a round bar having a predetermined outer diameter and length, one side of which is connected to the first reflecting rubber portion 121 and the other side of which is connected to the second reflecting rubber portion 123. The reflection rubber part 121 and the second reflection rubber part 123 are maintained at a predetermined interval.

The second reflecting rubber part 123 is positioned on the side of the resonator 50 to surround the electrodeless lamp 60, and the straight line distance of the neck 102 of the electrodeless lamp 60 and the reflector 100 is provided. Located between the inside of the neck 102 of the reflector 100 and is located on the side of the resonator 50.

The width cross-sectional shapes of the first and second reflective rubber parts 121 and 123 are horizontal cross sections 121a and 123a having a predetermined length in the vertical direction of the resonator 50 and the horizontal cross sections 121a. 123a and a vertical section 121b, 123b having a predetermined length in the longitudinal direction of the resonator 50, and a vertical section 121b, 123b followed by the vertical section 121b, 123b. It is preferable that the inclined end surfaces 121c and 123c are inclined to have a predetermined length. Both ends of the support shaft 122 are coupled to the horizontal cross-sectional side of the first reflective rubber portion 121 and the horizontal cross-sectional surfaces 121a and 123a of the second reflective rubber portion 123, respectively.

In addition, as another modification of the heat concentration preventing means 120, two or more reflective rubber parts are formed.

Hereinafter, the operational effects of the electrodeless lighting device reflector heating prevention structure of the present invention will be described.

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 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.

As the plasma is generated in the electrodeless lamp 60, the light emitted through the mirror 110 and the reflector 100 is reflected in all directions.

At the same time, the first driving motor 70 operates to rotate the electrodeless lamp 60 to cool the electrodeless lamp 60, and the first driving motor 70 operates to cool the fan. As the 80 is rotated, external air flows through the air duct 90 to cool the high voltage generating means 20 and the electromagnetic wave generating means 30.

In addition, as the plasma is generated in the electrodeless lamp 60, high temperature heat is generated together with the process of emitting light, and thus the high temperature heat generated by the electrodeless lamp 60 is illustrated in FIG. 3. It is blocked by the heat concentration preventing means 120 to prevent the central portion of the electrodeless lamp 60 adjacent to the electrodeless lamp 60 to be concentrated heating.

That is, the electrodeless lamp 60 is located in the reflector 101 of the reflector 100 so as to be located directly above the neck 102 of the reflector 100 due to its structure and function. ) Is connected to the neck (102) of the reflector (100) connecting shaft (71). Accordingly, the heat generated while generating the plasma in the electrodeless lamp 60 is the neck 102 of the reflector 100 adjacent to the electrodeless lamp 60 and the reflector 101 connected to the neck 102. At this time, it is transmitted to the neck portion 102 of the reflector 100 and the reflecting portion 101 adjacent to the neck portion 102 by the first reflecting rubber portion 121 constituting the heat concentration preventing means 120 The heat is reflected and reflected by the reflector 101 of the reflector 100 which is far from the electrodeless lamp 60 so that the portion of the reflector 100 adjacent to the electrodeless lamp 60 is concentrated and deformed. To prevent damage or damage.

In addition, the second reflective rubber part 123 constituting the heat concentration preventing means 120 reflects the heat passing through the first reflective rubber part 121 in a double manner and is located on the neck 102 side of the reflector. In addition to reflecting the heat transmitted, the heat transmitted to the neck 102 side of the reflector flows to the reflector 101 side of the reflector 100 through the first and second reflecting rubber parts 121 and 123. You will be guided.

As described above, the reflector heating prevention structure of the electrodeless lighting device according to the present invention is a reflector for reflecting the light emitted in a omni-directional lamp omnidirectionally by the heat generated with the light in the electrodeless lamp Preventing breakage and deformation due to concentrated heating deformation extends the life of the reflector, thereby reducing maintenance costs and increasing reliability.

Claims (4)

A resonator formed in a spherical shape and fixedly coupled to the casing, a resonator fixedly coupled to the casing so as to be located inside the reflector, and generating an electric field by electromagnetic waves generated by an electromagnetic wave generating means, and located in the resonator, A material filled therein by the generated electric field generates a plasma, and is located between the electrodeless lamp which emits light and the resonator and the reflector, so that the heat generated from the electrodeless lamp concentrates heating the proximal portion of the reflector. Reflective heating preventing structure of the electrodeless lighting device, characterized in that it comprises a heat concentrating prevention means for preventing. The method of claim 1, wherein the heat concentrating preventing means is formed in an annular shape having a predetermined thickness and width, the first reflection rubber portion, one side of which is fixedly coupled to the casing to surround the resonator, and the first reflection rubber portion A plurality of support shafts extending to have a predetermined length in the longitudinal direction, and a second reflection rubber connected to the ends of the plurality of support shafts so as to surround the electrodeless lamp and the resonator so as to have an annular shape having a predetermined thickness and width. Reflector heating prevention structure of the electrodeless lighting device, characterized in that provided with. The width cross-sectional shape of the first reflecting rubber portion and the second reflecting rubber portion has a horizontal cross section having a predetermined length in the vertical direction of the resonator and a predetermined length in the longitudinal direction of the resonator following the horizontal cross section. And a vertical cross section and an inclined cross section inclined to have a predetermined length inclined to the vertical cross section following the vertical cross section. The anti-reflective heating structure of claim 2, wherein two or more reflective rubber parts are formed.