JPH04192252A - Aperture type cold cathode fluorescent lamp - Google Patents

Abstract

PURPOSE:To make light intensity distribution uniform by disposing a mercury emission body structure at a place which is not faced to the light transmitting slit section of a bulb in a cold cathode main body. CONSTITUTION:The outer surface of either (surface 11a) of surfaces 11a and 11b which are mutually formed into a roof shape in a cold cathode main body 11, is disposed in such a way as to be faced to the slit section 8 of a bulb 1, and a mercury emission body structure, for example, indium 13 which absorbs mercury in advance, is fitted onto the inner surfaces of the respective surfaces 11a and 11b. When high frequency induction heating is performed in order that mercury is emitted within the tube 1, mercury splashed out of a mercury emission body structure 13 is blocked by the surfaces 11a and 11b, by the surface 11a in particular, so that it is prevented from adhering directly onto the slit section 8. As a result, mercury avoids adhering onto the slit section 8 acting as a transparent section, the transparent section thereby will never be darkish, and the section does not interfere with light emission, thereby making it possible to prevent light intensity distribution along the bulb axial direction at the slit section 8 from being deteriorated.

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial Application Field) The present invention relates to an aperture-type fluorescent lamp using a cold cathode as an electrode.

(Prior art) Fluorescent lamps that use cold cathodes as electrodes have a longer lamp life because the electrodes generate less heat, and the tube diameter can be reduced to 15 liters or less because the bulb does not heat up much. Often used in compact fluorescent lamps.

In such a small cold cathode fluorescent lamp, in order to effectively utilize the emitted light, a slit part is provided along the tube axis of the bulb to transmit light, and light is emitted in a specific direction only from this slit part. It may be used as a so-called aperture lamp.

On the other hand, the cold cathode sealed at the end of the bulb is constructed by welding a cold cathode body made of a metal plate such as nickel to a well such as Dumet wire. It is formed into a cylindrical shape or a cylindrical shape. On the surface of this cold cathode body, there is a mercury release structure that adsorbs mercury in advance and releases the mercury into the discharge space after the lamp is completed.
For example, a getter made of a metal such as mercury-adsorbing indium, phosphorus, barium, etc. is deposited.

(Problem to be Solved by the Invention) However, when a mercury release structure is attached to the cold cathode main body, if this mercury release structure faces the aperture part of the bulb, the mercury is released into the bulb. When the structure is subjected to high-frequency induction heating, mercury scattered from the mercury-emitting structure may adhere to the aperture portion (slit portion).

Such adhesion of mercury causes darkening in the aperture portion, which is a transparent portion, and obstructs light transmission, resulting in a problem that adversely affects the distribution of light output.

The present invention aims to provide an aperture type cold cathode fluorescent lamp which reduces the adhesion of mercury to the aperture portion through which light is transmitted and prevents darkening from occurring in the aperture portion.

[Structure of the Invention (Means for Solving the Problems) In the present invention, when attaching a mercury discharge structure to a cold cathode body, the mercury discharge structure faces the light transmitting slit portion of the bulb in the cold cathode body. The feature is that it is installed in a place where it is not used.

(Function) According to the present invention, since the surface of the cold cathode main body to which the mercury emitting structure is attached is formed so as to avoid the portion facing the aperture portion of the bulb, even if mercury is emitted from the mercury emitting structure, light is not transmitted. Mercury is prevented from adhering to the transparent aperture.

(Embodiment) The present invention will be described below based on an embodiment shown in FIGS. 1 to 4.

FIG. 1 is an overall perspective view showing a straight tube aperture type cold cathode fluorescent lamp. Reference numeral 1 indicates a straight tube glass bulb, and both ends of the bulb 1 are as shown in FIG. It is closed with flare stem 2.2.

An exhaust pipe 3 is connected to the flare stem 2, and the exhaust pipe 3 communicates with the inside of the bulb 1, that is, the discharge space 5, through an exhaust hole 4 formed in the flare stem 2. In addition,
FIG. 2 shows a state in which the exhaust pipe 3 is not sealed.

A reflective film 6 is formed on the inner surface of the bulb 1, and a phosphor coating 7 made of, for example, a calcium halophosphate phosphor is formed on the inner surface of the reflective film 6.

In this case, the reflective film 6 and the phosphor film 7
As shown in the figure, a transparent part is formed in the circumferential direction where the reflective film 6 and the phosphor film 7 are not formed, that is, in the range of the opening angle θ, and this is a band-shaped part along the tube axis direction. is formed to form a slit portion 8. More specifically, the light within the bulb 1 passes only through the slit portion 8 and is emitted to the outside, so that the lamp has an aperture shape.

A cold cathode 10 is supported by the stem 2 and sealed at both ends of the bulb 1, respectively.

The cold cathode 10 is composed of a cold cathode body 11 made of a nickel plate Ni or the like, and a well 12 made of a Dumet wire or the like bonded to the cold cathode body 11. The well 12 passes through the stem 2 in an airtight manner. It is extracted externally.

The cold cathode body 11 made of the nickel plate has a roof (dogleg) shape that tapers on the side of the discharge space 5 and widens on the side of the stem 2 on the opposite side.
It is welded to 2.

The surfaces 11 of such a cold cathode body 11 mutually form a roof shape.
Either a or llb (in this example, the lla side)
The outer surface of the bulb 1 is disposed so as to face the slit portion 8 formed in the bulb 1.

and surfaces 11a of the cold cathode body 11 mutually forming a roof shape,
A mercury release structure 13 made of, for example, indium, which has adsorbed mercury in advance, and a getter 14 made of lithium, barium, etc. are attached to each of the llb.

In this case, the mercury release structure 13 is provided on the inner surface of the mutually roof-shaped surfaces 11a, llb.

That is, the mercury discharge structure 13 is attached to the back surface (inner surface - the surface facing the end of the bulb), avoiding facing the slit portion 8 of the bulb 1 and avoiding the surface facing the discharge space 5. It is being

On the other hand, the getter 14 is attached to the outer surface of the roof-shaped cold cathode main body 11, that is, the surface facing the discharge space 5, by means of coating or the like.

Note that the discharge space 5 of the bulb 1 is filled with a starting rare gas such as argon gas.

In the cold cathode fluorescent lamp having such a configuration, darkening does not occur in the slit portion 8 as the aperture portion, early blackening of the bulb 1 is prevented, the luminous flux maintenance rate is improved, and There will also be fewer flickers.

That is, in the lamp configured as described above, the outer surface of one of the roof-shaped surfaces 11a and 111b of the cold cathode main body 11 (the surface 11a in this embodiment) faces the slit portion 8 of the bulb 1. Since a mercury release structure, for example, indium 13 which has adsorbed mercury in advance, is attached to the inner surface of these surfaces 11a and llb, when high-frequency induction heating is performed to release mercury into the bulb 1, this mercury is released. The mercury scattered from the structure 13 is blocked by these surfaces 11a and 11b, particularly one surface 11a, and does not directly adhere to the slit portion 8.

Therefore, since mercury does not adhere to the slit portion 8 as a transparent portion, no darkening occurs on the transparent portion, and light transmission is not obstructed, and the distribution of light output along the tube axis direction of the slit portion 8 deteriorates. can be prevented.

Furthermore, during the lamp exhaust process, air within the bulb 1 is drawn out through the exhaust pipe 3. In this case, the air inside the valve 1 flows toward the exhaust hole 4 as shown by the arrow in FIG. The amount of water flowing along the outer surface, that is, the surface facing the discharge space 5, is overwhelmingly large. In contrast, in the case of this embodiment, the mercury release structure 13 is attached to the inner surface of the cold cathode main body 11, avoiding the outer surface, so that the mercury release structure 13 is exposed to less air in the exhaust gas. In other words, the proportion of contact with air decreases. Therefore, the mercury discharge structure 13 is less likely to be contaminated by air, and the mercury that is later discharged into the discharge space by high-frequency heating becomes difficult to form mercury oxide. As a result, in the completed lamp, less mercury oxide adheres to the bulb wall, thereby preventing early blackening of the bulb. Therefore, the luminous flux maintenance rate is improved.

The results of examining the luminous flux maintenance factor for the configuration of this example are shown in the characteristic diagram of FIG.

In FIG. 4, the solid line A is the luminous flux maintenance factor in the case of the structure of the above embodiment, and the broken line B is the luminous flux maintenance factor in the case where the mercury emitting structure 13 is formed on the outer surface of the cold cathode body 11.

This result also shows that the method of this example is effective.

Further, in the case of a lamp in which the mercury discharge structure 13 shown by the broken line B is formed on the outer surface of the cold cathode body 11, the surface of the cold cathode 10 facing the discharge space 5 is covered with the mercury discharge structure 13. In this case, indium 13 that has adsorbed mercury has a higher work function and inferior electron emission function than the cold cathode body 11 made of nickel, so spots are less likely to occur on the outer surface of the cold cathode body 11 during lighting. A phenomenon in which the spot is not fixed in one place but moves is observed, and as a result, the occurrence of flickering is noticeable.

On the other hand, in the case of this embodiment, the getter 14 is replaced by the cold cathode 10.
Since the getter 14 is attached to the surface facing the discharge space 5 in the mercury emitting structure 13, the getter 14 has better electron emission performance than the mercury emitting structure 13, so that the spot is less likely to move on the outer surface of the cold cathode body 11 during lighting. This reduces the occurrence of flickering.

In the above embodiment, the cold cathode main body 11 made of a nickel plate is configured to have a roof (dogleg) shape that is tapered on the side of the discharge space 5 and widens on the side of the stem 2 on the opposite side. However, the present invention is not limited to this.

That is, the cold cathode main body may be formed into a hollow conical shape, and in this case, the mercury discharge structure 13 may be provided on the inner surface side.

Furthermore, as shown in FIG. 5 as another embodiment, the cold cathode main body 20 may be made of nickel and formed into a cylindrical shape.

That is, in the case of the cylindrical cold cathode body 20, even if the mercury release structure 13 is provided anywhere on the inner surface, it will be surrounded by the scattered cylindrical cold cathode body 20 and will be prevented from directly adhering to the bulb. In this case as well, it is preferable to attach the getter 14 on the outside.

Furthermore, the present invention is not limited to straight tube cold cathode fluorescent lamps, but can also be applied to bent cold cathode fluorescent lamps such as ring-shaped, U-shaped, W-shaped, etc.

Furthermore, the present invention is not limited to lamps in which cold cathodes are provided at both ends of the bulb, but one electrode may be formed as a cold cathode inside the bulb, and the other electrode may be formed as an external electrode outside the bulb. It is possible to carry out even if

The structure for sealing the end of the valve is not limited to the flare stem, but may be a button stem or a pinch seal structure.

[Effects of the Invention] As explained above, according to the present invention, since the surface of the cold cathode main body to which the mercury release structure is attached is formed avoiding the portion facing the aperture portion of the bulb, mercury is released from the mercury release structure. mercury is prevented from adhering to the transparent aperture portion through which light is transmitted. For this reason,
There are advantages such as preventing problems such as darkening of the aperture section as a transparent section due to adhesion of mercury, and equalizing the light output distribution.

[Brief explanation of the drawing]

Fig. 1 is a perspective view of a cold cathode fluorescent lamp showing an embodiment of the present invention, Fig. 2 is a sectional view showing one end of the lamp before exhaust, and Fig. 3 is a cross section taken along the line ■-■ in Fig. 2. 14 is a characteristic diagram of the luminous flux maintenance factor, and FIG. 5 is a sectional view of a lamp showing another embodiment of the present invention. 1...Valve, 2...Stem, 3...Exhaust pipe, 5
...discharge space, 6...reflection film, 7...phosphor coating, 8...slit part (aperture part), 10...
Cold cathode, 11...Cold cathode body, 12...Wells,
13...Mercury release structure, 14...Getter. Applicant's representative Patent attorney Takehiko Suzue Lighting time (Hr) Figure 4 Figure 5 Procedural amendment (dynamic)

Claims (3)

[Claims] (1) A bulb with a phosphor coating formed on its inner surface is provided with a light-transmitting slit along the tube axis direction to form an aperture shape.
In an aperture-type cold cathode fluorescent lamp, a cold cathode is provided at the end of the bulb, the cold cathode is formed by connecting a cold cathode body to a well, and a mercury discharge structure is attached to a part of the surface of the cold cathode body. . An aperture type cold cathode fluorescent lamp, characterized in that the mercury emitting structure is provided in a location of the cold cathode body that does not face the light transmitting slit portion of the bulb. (2) When the cold cathode body is roof-shaped, the mercury release structure is provided on the inner surface of the cold cathode body, and the outer surface of the cold cathode body is faced to the light-transmitting slit portion of the bulb. An aperture type cold cathode fluorescent lamp according to claim 1, characterized in that: (3) The mercury release structure is placed at a location in the cold cathode body that does not face the light transmitting slit of the bulb and avoids a location where the air flow inside the bulb is high when the bulb is evacuated. The first feature is that
Or an aperture type cold cathode fluorescent lamp according to the second claim.