KR100844059B1 - Electrodeless fluorescent lamp - Google Patents

Abstract

An electrodeless fluorescent lamp is provided to increase an initial radiation output of a lamp by rapidly diffusing mercury to an upper side of a bulb when a lamp is switched on through a mesh-type supplementary amalgam. An electrodeless fluorescent lamp includes an outer sphere(100) in which a discharge space(110) is formed, and a stem(200) jointed to a lower section of the outer sphere and having an antenna receiving unit placed on an inner side of the outer sphere. An amalgam receiving unit(240) communicated with the discharge space is formed at a lower section of the stem. A primary amalgam(241) is installed in an inner side of the amalgam receiving unit. A mesh-type supplementary amalgam(242) is installed on an upper section of the primary amalgam in the amalgam receiving unit. The supplementary amalgam has a roll of a mesh-type strip. The supplementary amalgam is an alloy containing molybdenum.

Description

Electrodeless fluorescent lamp

The present invention relates to an electrodeless fluorescent lamp, and more particularly, to an electrodeless fluorescent lamp that can increase the initial emission output of the lamp by rapidly diffusing mercury above the bulb when the lamp is switched on.

In general, an electrodeless fluorescent lamp seals a bulb without a filament or an electrode inside a bulb, installs an external electrode outside the bulb, forms a magnetic field in the bulb by the external electrode, and emits light by gas discharge. It is characterized by having a very long life (80,000 to 100,000 hours). Due to these features, electrodeless fluorescent lamps are often used in places such as airports, high ceilings, workplaces, tunnels, and large halls where lamp replacement is difficult and expensive.

The conventional electrodeless fluorescent lamp has an exhaust pipe and an amalgamation part formed under a bulb in which a discharge space is formed, and a base and an antenna are coupled to the lower side of the bulb. Therefore, when power is supplied to the lamp and the inside of the lamp rises above a certain temperature, mercury diffuses into the discharge space from the amalgam contained in the amalgam receiving portion.

However, in the conventional electrodeless fluorescent lamp as described above, since the amalgam is located below the bulb, it takes a long time for the mercury to diffuse to the top of the bulb. As such, a conventional electrodeless fluorescent lamp has a difference in the rate at which mercury diffuses in the upper and lower portions of the bulb, and thus has a low initial radiation output (emission power for 1 second after switching on the fluorescent lamp), thus preparing a low preparation time (fluorescent lamp). Has a problem that the reliability of the product from the consumer is lowered due to an increase in the time required to reach the radiation output for optimal operation.

In addition, in the conventional electrodeless fluorescent lamp, glass beads are inserted above the amalgam, thereby preventing mercury from entering the bulb and causing staining. However, these conventional electrodeless fluorescent lamps have to be provided with the glass beads separately, which makes it difficult to manufacture and raises the cost of the product.

Therefore, the present invention has been proposed to solve the above problems, by adsorbing a part of the mercury diffused from the main amalgam in the auxiliary amalgam when the lamp is switched on to quickly diffuse the mercury to the upper side of the bulb to the initial radiation of the lamp It is an object of the present invention to provide an electrodeless fluorescent lamp capable of increasing output.

In addition, an object of the present invention is to provide an electrodeless fluorescent lamp that can be prevented from entering the mercury into the bulb even if the glass beads are not provided separately, and is easy to manufacture.

In order to achieve the above object, the present invention provides an electrodeless fluorescent lamp comprising a stem having an outer space in which a discharge space is formed therein and an antenna accommodating portion which is bonded to a lower end of the outer hole and is located inward of the outer hole. An amalgamation receiving portion communicating with the discharge space is formed at a lower side of the amalgamation receiving portion, and a main amalgam is installed inside the amalgamation receiving portion, and an auxiliary amalgam having a mesh shape is installed above the main amalgam in the amalgamation receiving portion.

At this time, the auxiliary amalgam according to the invention is characterized in that the winding of the strip of the mesh form in the form of a roll.

In addition, the auxiliary amalgam according to the present invention is preferably made of an alloy containing molybdenum.

In addition, at the upper end of the inner wall of the amalgam accepting portion, a locking protrusion may be formed to prevent separation of the auxiliary amalgam.

As described above, the electrodeless fluorescent lamp according to the present invention is installed by the main amalgam and mesh-shaped auxiliary amalgam inside the amalgamation receiving portion, by adsorbing a part of the mercury diffused from the main amalgam in the auxiliary amalgam switching on the lamp When the mercury diffuses mercury to the upper side of the bulb has the effect of increasing the initial radiation output of the lamp.

In addition, the present invention by installing the auxiliary amalgam on the upper side of the main amalgam, it is possible to prevent the occurrence of stains by entering mercury into the bulb without having to provide a separate glass bead and there is an effect that is easy to manufacture.

The following provides a preferred embodiment to help the understanding of the present invention. The following examples are provided to more easily understand the present invention, and the present invention is not limited by these examples.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the present invention.

1 is an exploded perspective view showing a state where a part of an electrodeless fluorescent lamp according to the present invention is disassembled, FIG. 2 is a partial cross-sectional view showing an embodiment of a bulb constituting the electrodeless fluorescent lamp according to the present invention, FIG. A perspective view showing an embodiment of the auxiliary amalgam according to the present invention.

As shown in FIG. 1, the electrodeless fluorescent lamp according to the present invention has a bulb 10, a base 20 coupled to a lower side of the bulb 10, and a lower side of the base 20. The antenna 30 is inserted into the inside.

As shown in FIG. 2, the bulb 10 includes an outer opening 100 having a discharge space 110 therein and a stem 200 joined to a lower end of the outer opening 100.

The outer sphere 100 is formed in a spherical shape with a lower opening, the fluorescent material 120 is coated on the inner surface. The discharge space 110 is formed inside the outer opening 100. Specifically, the discharge space 110 is formed in the space between the inner surface of the outer sphere 100 and the outer surface of the stem 200 when the stem 200 is bonded to the open lower end of the outer sphere (100). The discharge space 110 is filled with a discharge gas (not shown) such as an ionizable metal vapor atom or an inert gas.

The stem 200 is installed inside the outer opening 100 for accommodating the antenna 30 to be described below, and a support 210 coupled to an inner circumference of the lower end of the outer housing 100 and the supporting portion. It is formed in the central region of the 210 and has a cylindrical antenna receiving portion 220 protruding upward to be located inside the outer opening (100).

The supporting part 210 is bonded to the lower inner side of the outer opening 100 so as to seal the discharge space 110 of the outer opening 100 in the shape of a disc. Each of the receiving portions 210 protrudes downward and is formed with an exhaust pipe 230 and an amalgamation receiving portion 240 communicating with the discharge space 110.

The exhaust pipe 230 is configured to inject the discharge gas into the discharge space 110, the upper end is in communication with the discharge space 110 on one side of the support portion 210 and the lower end after the injection process of the discharge gas It is formed to be sealed and closed.

The amalgamation receiving unit 240 is a configuration for installing the main amalgam 241 in the inner side, is formed to extend to the other side of the bottom portion 210. The upper end of the amalgamation receiving part 240 is in communication with the discharge space 110, the lower end is formed to be closed by sealing after installing the main amalgam 241. At this time, at least one main amalgam 241 is accommodated in the inner lower portion of the amalgam receiving portion 240.

Here, the auxiliary amalgam 242 according to the present invention is installed inside the amalgam receiving unit 240. The auxiliary amalgam 242 absorbs a portion of the mercury diffused from the main amalgam 241, thereby rapidly spreading mercury above the bulb 10 when the lamp is switched on, thereby increasing the initial radiative output of the lamp.

As shown in the enlarged portion of FIG. 2, the auxiliary amalgam 242 is formed in a mesh shape so that mercury can be easily adsorbed. In detail, the auxiliary amalgam 242 is inserted from the upper side of the amalgam receiving unit 240 by winding a strip of a mesh form as shown in FIG. 3.

The auxiliary amalgam 242 may be made of nickel (Ni) or titanium (Ti) to sufficiently withstand the heat generated in the bulb 10, preferably an alloy containing molybdenum (Mo) having excellent heat resistance. Manufacture.

In addition, the upper end of the amalgam receiving portion 240 may be formed with a locking projection 243 to prevent the separation of the main amalgam 241 and the auxiliary amalgam 242. As shown in the enlarged view of FIG. 2, when the locking protrusion 243 is formed to protrude from the upper inner circumference of the amalgamation receiving unit 240, the upper end of the auxiliary amalgam 242 is caught by the locking protrusion 243. It is possible to prevent the amalgam 242 and the main amalgam 241 located below the amalgam 242 from being separated from the amalgam receiving portion 240.

The base 20 is made of an insulator such as plastics, and is coupled to the lower end of the bulb 10 to be gripped by the user and to protect the inside of the fluorescent lamp to cover the exhaust pipe 230 and the amalgamation receiving part 240.

The antenna 30 is coupled from below the base 20 and inserted into the antenna accommodating portion 220 of the stem 200. In detail, the coil 31 and the core 32 provided on the upper portion of the antenna 30 are inserted into the antenna accommodating portion 220, and the lower portion of the antenna 30 is seated and fixed to the lower end of the base 20. . The coil 31 and the core 32 form a magnetic field in the discharge space 110 of the bulb 10 when power is supplied from the outside.

As described above, when the main amalgam and the mesh-like auxiliary amalgam are provided inside the amalgam accepting portion, the auxiliary amalgam adsorbs a part of mercury diffused from the main amalgam, and when the lamp is switched on, mercury is discharged to the upper side of the bulb. There is an advantage to increase the initial radiation output of the lamp by spreading quickly.

On the other hand, the present invention is not limited to the typical preferred embodiment described above, but can be carried out in various ways without departing from the gist of the present invention various modifications, alterations, substitutions or additions are common in the art Those who have knowledge will easily understand. If the implementation by such improvement, change, replacement or addition falls within the scope of the appended claims, the technical idea should also be regarded as belonging to the present invention.

1 is an exploded perspective view showing a state where a part of an electrodeless fluorescent lamp according to the present invention is disassembled,

2 is a partial cross-sectional view showing an embodiment of a bulb constituting the electrodeless fluorescent lamp according to the present invention,

3 is a perspective view showing an embodiment of the auxiliary amalgam according to the present invention.

※ Explanation of codes for main parts of drawing

10: bulb 20: base

30: antenna 31: coil

32: core 100: outer

110: discharge space 120: fluorescent material

200: stem 210: base

220: antenna receiving portion 230: exhaust pipe

240: Amalgam receptor 241: Juamalgam

242: auxiliary amalgam 243: jamming

Claims (4)

An electrodeless fluorescent lamp comprising a stem having an outer space formed therein with a discharge space, and an antenna receiving portion bonded to a lower end of the outer hole and located inward of the outer hole, The amalgamation part is formed in the lower side of the stem in communication with the discharge space, Inside the amalgamation unit is a main amalgam is installed, An electrodeless fluorescent lamp, characterized in that the auxiliary amalgam of the mesh shape is installed above the main amalgam in the amalgam receiving portion. The method of claim 1, The auxiliary amalgam is an electrodeless fluorescent lamp, characterized in that the winding of the strip in the form of a mesh. The method according to claim 1 or 2, The auxiliary amalgam is an electrodeless fluorescent lamp, characterized in that the alloy containing molybdenum. The method according to claim 1 or 2, An electrodeless fluorescent lamp, characterized in that a locking projection formed on the upper end of the inner wall of the amalgamation receiving portion to prevent the auxiliary amalgam from being separated.

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