KR100806853B1 - Electrodeless fluorescent lamp - Google Patents

Abstract

An electrodeless fluorescent lamp is provided to decrease a standby time of the fluorescent lamp by rapidly diffusing mercury to an upper portion of a bulb from an amalgam container. An electrodeless fluorescent lamp includes a bulb(10), a base(20), and an antenna(30). An outer ball(11) has a discharge space therein. An inner tube(16) is formed inside the outer ball. The outer ball is bonded with a lower end of the inner tube to form the bulb. The base is coupled with a lower portion of the bulb. The antenna is coupled with a lower portion of the base and inserted into the inner tube. An amalgam container(100), which is coupled with the discharge space and contains amalgam(110) therein, is formed at the lower end of the bulb. The amalgam container contains the amalgam and is protruded into the discharge space.

Description

Electrodeless Fluorescent Lamp

1 is a partial cross-sectional view showing an electrodeless fluorescent lamp according to the present invention,

2 is a partially enlarged cross-sectional view showing another embodiment of an electrodeless fluorescent lamp according to the present invention.

※ Explanation of codes for main parts of drawing

10: Bulb 11: Outward

12: discharge space 13: fluorescent material

16: Interior 17: Exhaust Pipe

20: base 30: antenna

31: magnetic field forming portion 31a: coil

31b: Core 100: Amalgam Receptacle

110: amalgam 120: glass rod

130: protrusion 140: bead glass

The present invention relates to an electrodeless fluorescent lamp, and more particularly, by forming an amalgamation receiving portion communicating with the discharge space at the lower end of the bulb and accommodating amalgam into the discharge space, thereby switching the bulb from the amalgam when the lamp is switched on. It relates to an electrodeless fluorescent lamp that can increase the initial radiated output of the lamp by rapidly diffusing mercury inside.

In general, an electrodeless fluorescent lamp seals a bulb without a filament and 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 (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 unit formed at a lower end of a bulb in which a discharge space is formed therein, and a base and an antenna are coupled to a lower side of the bulb. Therefore, when power is supplied to the lamp and the inside of the lamp rises above a predetermined temperature, mercury diffuses from the amalgam contained in the amalgam receiving portion into the discharge space, thereby maintaining the temperature in the lamp.

However, in the conventional electrodeless fluorescent lamp as described above, since the amalgam is located below the bulb, it takes a long time 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.

Therefore, the present invention has been proposed to solve the above problems, by forming an amalgam receiving portion communicating with the discharge space at the bottom of the bulb and receiving amalgam projecting into the discharge space, the bulb of the bulb when switching on An object of the present invention is to provide an electrodeless fluorescent lamp which can rapidly diffuse mercury upwards to increase the initial radiant output of the lamp.

In order to achieve the above object, the present invention provides an outer sphere having a discharge space therein, an inner tube formed inside the outer sphere and partitioned from the discharge space, and a bulb formed by mutually bonding the lower ends of the outer and inner tubes; A base coupled to the lower side of the bulb; And an antenna coupled from the lower side of the base and inserted into the inner tube, wherein the lower end of the bulb communicates with the discharge space and has an amalgam receiving portion configured to receive amalgam, wherein the amalgam receiving portion is amalgam. It is characterized in that it is formed to protrude into the interior of the discharge space.

Preferably, a glass rod is inserted into the amalgam containing portion to be inserted below the amalgam to adjust the height of the amalgam.

In addition, the upper end of the amalgam containing portion is preferably formed with a locking projection to prevent the separation of the amalgam.

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 a partial cross-sectional view showing an electrodeless fluorescent lamp according to the present invention, Figure 2 is a partially enlarged cross-sectional view showing another embodiment of the electrodeless fluorescent lamp according to the present invention.

As shown in FIG. 1, the electrodeless fluorescent lamp according to the present invention includes a bulb 10, a base 20 coupled to the lower side of the bulb 10, and an antenna 30 coupled from below the base 20. It consists of.

The bulb 10 includes an annular outer opening 11 having a discharge space 12 therein, and an inner tube 16 formed inside the outer opening 11 and partitioned from the discharge space 12. The outer sphere 11 is coated with a fluorescent material 13 on the inner side, the discharge space 12 is formed in the interior partitioned by the inner tube (16). The discharge space 12 is filled with a discharge gas (not shown) such as an ionizable metal vapor atom and an inert gas.

As described above, the inner tube 16 is formed inside the outer opening 11 to accommodate the antenna 30 to be described below, and is formed to have a size that the antenna 30 is sufficiently inserted. The inner tube 16 has a side wall extending from the lower end thereof joined to the opened lower end of the outer opening 11 to seal the discharge space 12.

The exhaust pipe 17 is formed to protrude downward from the bottom of the bulb 10. The exhaust pipe 17 is configured to inject the discharge gas into the discharge space 12 inside the bulb 10, the inside of which is in communication with the discharge space 12, the lower end is sealed when the injection process of the discharge gas is finished Processed and closed.

The base 20 is made of a non-conductor such as plastics to be coupled to the lower end of the bulb 10 so as to be gripped by the user and to protect the interior of the fluorescent lamp to cover the exhaust pipe 17.

The antenna 30 is coupled from below the base 20 and inserted into the inner tube 16. Specifically, the magnetic field forming unit 31 provided on the upper portion of the antenna 30 is located in the inner tube 16, the lower portion of the antenna 30 is fixed to the lower end of the base 20.

The magnetic field forming unit 31 is formed of a coil 31a and a core 31b to form a magnetic field when the power is supplied from the outside. At this time, when a magnetic field is formed around the metal vapor atoms and the inert gas in the bulb 10, the metal vapor atoms and the inert gas are accelerated by the induced current, and collisions occur with each other, and the collided particles are ionized and released freely. Ultraviolet (UV) light is emitted by electrons. As such, when the emitted ultraviolet rays are irradiated onto the fluorescent material 13 coated on the inner surface of the bulb 10, visible rays are generated.

The amalgamation unit 100 is further formed at the bottom of the bulb of the electrodeless fluorescent lamp according to the present invention. The amalgamation receiving unit 100 is for storing the amalgam 110, and is formed to protrude into the discharge space 12 from the lower end of the bulb 10, the upper portion is opened to communicate with the discharge space 12. The lower end is sealed after the amalgam 110 insertion process is closed. As described above, the amalgamation receiving unit 100 is formed inside the discharge space 12 in order to increase the initial radiation output by placing the amalgam 110 close to the center area of the discharge space 12.

Here, the amalgam 110 may be located above the amalgam receiving portion 100 in various ways, it is preferable to insert the glass rod 120 below the amalgam 110 as shown in FIG. The glass rod 120 is inserted from below when the amalgam 110 is inserted into the amalgam receiving portion 100 to push up the amalgam 110 to the upper side of the amalgam receiving portion 100. In this case, the lower part of the amalgam receiving portion 100 is sealed and closed when the amalgam 110 and the glass rod 120 are completely inserted.

When the glass rod 120 is inserted into the amalgam receiving unit 100, the glass rod 120 may support the amalgam 110 thereon, and the amalgam 110 flows between the glass rod 120 and the amalgam receiving unit 100. It is desirable to have a sufficient circumference not to go. As such, when the amalgam 110 is positioned above the amalgamation receiving unit 100 by the glass rod 120, mercury may be diffused in the discharge space 12 at a higher speed.

In addition, the upper end of the amalgam receiving portion 100, it is preferable that the engaging projection 130 to prevent the separation of the amalgam 110 is formed. As shown in the enlarged view of FIG. 1, the locking protrusion 130 protruding around the upper inner circumference of the amalgamation receiving unit 100 may prevent the amalgam 110 from being separated.

On the other hand, the inside of the amalgam receiving unit 100 according to the present invention may be further provided with a bead glass 140 on the upper side of the amalgam (110). For example, when adjusting the height of the amalgam 110 according to the characteristics of the lamp as shown in Figure 2 by providing a bead glass 140 in the empty space formed above the amalgam 110, even if the lamp is subjected to vibration amalgam ( 110) there is an effect that can be fixed without shaking.

As in the present invention, when the amalgam receiving portion is formed inside the discharge space, since the amalgam is located close to the center of the discharge space, mercury can be rapidly diffused in the discharge space, thereby increasing the initial radiative output of the lamp, thereby providing a relatively short preparation time. There is an advantage it can have.

On the other hand, the present invention is not limited to the above-described typical preferred embodiment, but can be carried out in various ways without departing from the gist of the present invention, various modifications, alterations, substitutions or additions in the art Anyone who has this can easily understand it. 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.

As described above, the electrodeless fluorescent lamp according to the present invention has an amalgam receiving portion protruding into the discharge space at the lower end of the bulb and accommodating amalgam therein, and using a glass rod inside the amalgam By placing the upper part of the amalgamation part, when the lamp is switched on, the mercury diffuses rapidly from the amalgam to the upper side of the bulb, thereby increasing the initial emission output of the lamp, thereby reducing the preparation time, thereby improving reliability of the product from consumers There is an advantage to that.

Claims (3)

An outer bulb having a discharge space therein, an inner tube formed inside the outer sphere and partitioned from the discharge space, and a bulb formed by mutually bonding a lower end of the outer sphere and the inner tube; A base coupled to the lower side of the bulb; And an antenna coupled from the bottom of the base and inserted into the inner tube. The lower end of the bulb is in communication with the discharge space is formed amalgam accepting portion for receiving amalgam, The amalgamation receiving portion is an electrodeless fluorescent lamp characterized in that the amalgam receiving protruding into the discharge space. The method of claim 1, An electrodeless fluorescent lamp, characterized in that the glass rod for adjusting the height of the amalgam is inserted into the amalgam receiving portion inside the amalgam. The method according to claim 1 or 2, An electrodeless fluorescent lamp, characterized in that the upper end of the amalgamation receiving portion is formed with a projection preventing the separation of the amalgam.

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