KR20010055802A - Combined structure of resonator and reflector in electrodeless lamp - Google Patents

Abstract

PURPOSE: A reflector integral resonator for an electrodeless lamp is provided to reduce the leakage of electromagnetic wave generated from the surface of the resonator and to manufacture various lamps. CONSTITUTION: In the reflector integral resonator for the electrodeless lamp, a plurality of holes are formed at a front surface of the resonator. A reflecting coating is applied to an inner surface of the resonator. Preferably, a mesh screen can function as the holes. The reflector integral resonator for the electrodeless lamp has a cylindrical shape. Alternatively, the reflector integral resonator for the electrodeless lamp has a lamp shade shape. It is possible to prevent the electromagnetic wave from being leaked in the resonator. The light emitted from the electric lamp is efficiently transmitted and the manufacturing cost of the electrodeless lamp is reduced.

Description

Reflector-integrated resonator structure of an electrodeless lamp {COMBINED STRUCTURE OF RESONATOR AND REFLECTOR IN ELECTRODELESS LAMP}

The present invention relates to a reflector integrated resonator structure of an electrodeless lamp.

In an electrodeless lamp, electromagnetic waves generated from an electromagnetic wave generator such as a magnetron are transmitted to a resonator through a waveguide, which is applied to a light bulb installed inside the resonator to emit light. Bulbs used in electrodeless lamps are bulbs without electrodes or filaments inside. In order to light a bulb, a strong electric field must be applied to the bulb. The strength of the electric field required for this initial discharge is determined by the size or shape of the bulb and the type of inclusions or the pressure of the gas. It is several times the intensity. Therefore, a method of lowering the required electric field strength by adding mercury lamp or the like is often used to facilitate the lighting of the bulb. Alternatively, in order to increase the strength of the electric field applied to the light bulb, a method of complexing the shape of the resonator or adding a device inside the resonator may be used.

The resonator traps electromagnetic energy therein so that the bulb can be effectively supplied to the bulb, and at the same time, all or part of the surface is a mesh screen or a small pore so that light emitted from the bulb can be emitted to the outside. In order to form a pore, an etching method or the like is used. The distribution of the electromagnetic field inside the resonator is determined by the physical shape of the resonance, that is, the shape and size of the cross section of the resonator, the length of the resonator, etc., where both the size and the length mean an electrical length determined by the wavelength of the electromagnetic wave used. . In general, the resonator is designed so that a strong electric field is applied to the light bulb inside the resonator, that is, the intensity of the electric field where the light bulb is located is maximized.

1 is a cross-sectional view showing the structure of a conventional electrodeless lamp. Electromagnetic waves generated by the electromagnetic wave generator 10 such as a magnetron are applied to the light bulb 13 installed inside the resonator 12 through the waveguide 11 to emit light. The reflector 14 is attached to the front surface of the resonator 12, through which the light generated by the light bulb 13 is transmitted to the front. Depending on the shape of the reflector 14, light may be sent only forward, or may be spread to the surroundings a lot. The light guide 15 is attached to the end of the reflector 14 to send the light further.

However, such a resonator structure has a problem in that the efficiency of the lamp is lowered due to leakage of electromagnetic waves through a porous or mesh screen formed on the surface of the resonator. In addition, the optical loss is generated by separately forming the resonator and the reflector. Since the diameter of the light guide is determined according to the diameter of the reflector, there is a limit in manufacturing a lamp having various structures.

Accordingly, an object of the present invention is to provide a resonator structure that can reduce the leakage of electromagnetic waves generated through the surface of a resonator and to manufacture lamps of various types.

1 is a cross-sectional view showing the structure of a conventional electrodeless lamp.

2A to 2C are perspective views showing the shape of a reflector integrated resonator as an embodiment of the present invention.

*** Explanation of symbols for main parts of drawing ***

10: electromagnetic wave source 11: waveguide

12: Resonator 13: Bulb

14: Reflector 15: Light Guide

In order to achieve the above object, the present invention provides a resonator structure of an electrodeless lamp in which the reflector and the resonator are integrally formed.

It is a feature of the present invention to allow the reflector to function as a resonator instead of the resonator of a conventional electrodeless lamp.

Unlike conventional cylindrical resonators having pores formed not only on the front surface but also around the cylinder as a whole, the reflector and resonator integrated resonator structure of the present invention forms a porous or mesh screen only on the front surface so that light generated from the bulb is transmitted to the outside. As the area of the pores is reduced in this manner, the leaked electromagnetic waves can be significantly reduced.

In addition, reflection coating is performed inside the resonator structure of the present invention in order to reduce leakage of electromagnetic waves and to effectively transmit light generated from a light bulb. Therefore, the loss of light can also be prevented.

The reflector and resonator integrated resonator structure may have various shapes depending on the intended use. 2A to 2C show several integrated resonator shapes as specific embodiments of the present invention.

Figure 2a is a lampshade similar to the shape of the existing reflector is characterized in that a porous or mesh screen formed on the front.

2b is a resonator structure in which a conventional cylindrical resonator is improved and a pore is installed only on the front surface and a reflective coating is applied to the inside thereof. This type reduces the overall size of the lamp, making it suitable for indoor lighting or special purpose lighting.

In addition, in the case of Figure 2c is a resonator structure is extended in length than the structure of FIG. This structure is a structure in which a light guide, a reflector and a resonator are formed in one, and a resonator structure that can transmit light far away while minimizing leakage and light loss of electromagnetic waves, and may be used for outdoor lighting or military lighting. .

In addition, the reflector and the resonator integrated resonator structure of the present invention can be modified in various ways depending on the purpose of use or manufacturing conditions, as well as a cylindrical or conventional reflector shape may be a combination of the two forms.

According to the present invention can reduce the leakage of electromagnetic waves generated in the resonator can effectively transmit the light generated from the light bulb, not only to prevent the loss of light significantly, but also to reduce the production cost by simplifying the overall lamp structure. .

Claims (4)

Reflector-integrated resonator structure of an electrodeless lamp, characterized in that the pores are formed only on the front surface and reflection coating inside. 2. The reflector integrated resonator structure of claim 1, wherein the pores are mesh screens. The reflector integrated resonator structure of claim 1, wherein the reflector integrated resonator structure has a cylindrical shape. 2. The reflector integrated resonator structure as claimed in claim 1, wherein the reflector integrated resonator structure has a lampshade shape.