JP2002110085A - Fluorescent discharge tube - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve a high brightness at a high degree without reducing a lamp life of a fluorescent discharge tube. SOLUTION: The fluorescent discharge tube is provided with a glass tube 2 forming a closed space 3; a pair of electrodes 8 disposed in the closed space 3 and fixed to both ends of the glass tube 2; and a fluorescent film 9 formed on a surface of the glass tube 2. Since the electrodes 8 are constituted by a metal selected from niobium, titanium, tantalum or an alloy thereof having a low sputtering rate, a wear of the metal constituting the electrode 8 is inhibited and a desired lamp life can be obtained even if a current density is 1×103 A/m2 or more. The fluorescent discharge tube can be light-emitted at a high brightness by reducing a length of non-emission area of the fluorescent discharge tube.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fluorescent discharge tube capable of reducing the length of a non-light emitting area of a discharge tube while maintaining a predetermined lamp life.

[0002]

2. Description of the Related Art A pair of electrodes are fixed to both ends of a glass tube (glass bulb) so as to face each other, and a closed space (sealed space) formed inside the glass tube is filled with rare gas and mercury vapor in a sealed state. A cold cathode fluorescent discharge tube in which a fluorescent film is coated on the inner wall of a glass tube is widely used, for example, as a backlight source for a liquid crystal display. A conventional cold cathode discharge tube includes an electrode assembly having a terminal component and a cup-shaped electrode fused to a tip end of the terminal component, and an electrode assembly having an electrode hermetically fixed at both ends and having a discharge inside. A glass tube filled with a gas (rare gas, mercury vapor), and a fluorescent film formed on the inner wall surface of the glass tube and emitting visible light when irradiated with ultraviolet light generated by a discharge between a pair of electrodes. . The electrodes are formed of nickel or the like which is excellent in workability.

[0003]

When a current is applied to the electrodes of the cold cathode fluorescent discharge tube to light the cold cathode fluorescent discharge tube,
Sputtering occurs where ions and the like collide with the electrodes,
The atoms or molecules of the electrode metal are released from the electrode into the discharge tube by sputtering. The atoms or molecules of the electrode metal combine with the mercury filled in the discharge tube to form mercury amalgam, so that the mercury in the discharge tube is consumed and the life of the discharge tube (lamp life) is reduced. Therefore, the length of the lamp life largely depends on the consumption rate of the mercury vapor filled in the discharge tube. For example, in a cold cathode fluorescent discharge tube used for a notebook personal computer, it is desired to reduce the length of a non-light emitting region of the discharge tube as much as possible together with a demand for higher luminance. Here, it is necessary to reduce the size of the electrode in order to reduce the length of the non-light-emitting region of the discharge tube. However, when the size of the electrode is reduced, the current density increases. For this reason, the amount of sputtering of the electrode increases, and the total amount of atoms or molecules of the electrode metal released from the electrode into the inside of the discharge tube increases. As a result, the lamp life decreases.

[0004] In this case, if sputtering is suppressed by increasing the pressure of the rare gas charged in the discharge tube, a desired lamp life can be maintained even if the current density increases, but the pressure of the rare gas increases. When it increases, there is a problem that the luminance is consequently reduced. In addition, an increase in gas pressure causes an increase in tube voltage, an increase in voltage at the start of discharge tube lighting, and the like. For this reason, conventionally, it has been difficult to reduce the length of the non-light emitting region while maintaining a desired lamp life. SUMMARY OF THE INVENTION An object of the present invention is to provide a high-luminance fluorescent discharge tube that can obtain a desired lamp life and reduce the length of a non-light emitting region.

[0005]

According to the present invention, there is provided a fluorescent tube comprising:
A glass tube (2) forming a closed space (3), a pair of electrodes (8) arranged in the closed space (3) and fixed to both ends of the glass tube (2), and a glass tube (2). Fluorescent film formed on the surface (9)
And emits light when a voltage is applied to the pair of electrodes (8). Since the electrode (8) is composed of a metal selected from niobium, titanium, tantalum, or an alloy thereof having a low sputtering rate, the pressure of the rare gas is high even when the current density is 1 × 10 ³ A / m ² or more. Electrode without setting (8)
Can be prevented from being consumed. Since the sputtering rates of niobium, titanium, and tantalum are lower than those of conventionally used nickel, a desired lamp life can be obtained. In addition, since the length of the non-light emitting region can be reduced by downsizing the electrode (8), conversely, the length and the total light emission amount of the light emitting region can be increased, and the fluorescent discharge tube can emit light with high luminance. .

[0006]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a fluorescent discharge tube according to the present invention applied to a cold cathode fluorescent discharge tube used for a notebook personal computer will be described with reference to FIGS. The fluorescent discharge tube (1) has a substantially cylindrical closed space inside.
An elongated glass tube (glass bulb) (2) forming (3);
A pair of electrode assemblies (4) hermetically fused to both ends of the glass tube (2), and a fluorescent film (5) formed on the inner wall surface of the glass tube (2)
And The closed space (3) is filled with a rare gas such as an argon gas and mercury vapor (discharge gas). As shown in FIG. 2, the electrode assembly (4) includes a lead portion (6) formed of, for example, nickel, an embedded portion (7) formed of, for example, tungsten, and an electrode ( 8). Since the lead-out part (6) is fused to one end of the buried part (7) by resistance welding or the like, a swelling part (9) is formed between the lead-out part (6) and the buried part (7). The formation of the bulging portion (9) is suppressed by changing the wire diameter of the two. The lead-out part (6) and the buried part (7) constitute an introduction line. The electrode (8) is fused to the other end of the buried portion (7) by resistance welding or the like. Fluorescent film (5)
Emits visible light upon irradiation with ultraviolet rays generated by the discharge between the electrodes (8).

The lead-out portion of the lead-out portion (6) led out from both ends of the glass tube (2) has external terminals (10) via solder.
Therefore, it is desirable to form the lead-out portion (6) with a metal having good solderability. One end of the buried portion (7) is introduced into the glass tube (2). Tungsten is preferably used as a material for forming the buried portion because it is in good contact with the glass material constituting this kind of glass tube (2). A pair of electrode assemblies arranged at both ends of the glass tube (2)
The inner end of the buried part (7) and the electrode (8) constituting the (4) are a glass tube (2)
Of the glass tube (2)
Is derived outside.

In the present embodiment, the cup electrode (8) welded to the buried portion (7) is formed of niobium (Nb) or a metal material containing niobium as a main component according to the present invention.
Since the metal material containing niobium as a main component may include a metal or the like other than niobium as an alloy or as a composition,
A metal in which the properties of niobium are substantially maintained.

The cup electrode (8) comprises a cylindrical side wall (8a) and a bottom wall (8b) provided at one end of the side wall (8a), and is provided at the other end of the side wall (8a). Has an opening (8c). The electrode (8) described in the present embodiment is not limited to a cup shape, and can be formed in various shapes such as a rod shape, a spiral shape, and a counter electrode shape. Further, in the present embodiment, the electrode (8) is formed of niobium having a low sputtering rate or a metal material containing niobium as a main component.
Even at 10 ³ A / m ² or more, the consumption of the metal constituting the electrode (8) is suppressed without setting the pressure of the rare gas to a high level, and at the same time, the electrode (8 ) The length can be reduced by about 50%. As a result, the length of the non-light-emitting region of the discharge tube decreases, and the length of the effective light-emitting region increases. Accordingly, the fluorescent tube can emit light with high luminance while maintaining a desired lamp life. In the present embodiment, the pressure of the rare gas filled in the glass tube (2) was 9.3 × 10 ³ Pascal.

In operation, when a voltage is applied between the pair of electrodes (8), electrons are emitted from one of the electrodes (8), and the electrons collide with mercury atoms in the glass tube (2) to emit ultraviolet rays. appear. This ultraviolet light is wavelength-converted into visible light by the fluorescent film (5) formed on the inner wall of the glass tube (2). As mentioned above,
Electrode formed of niobium harder than nickel (8)
However, even if the current density is relatively large, sputtering due to collision of mercury and ions is unlikely to occur.

In experiments conducted by the present inventor, the sputtering rates of titanium and niobium were both 0.4 or less, and the sputtering rate of tantalum was 0.6 or less.
Nickel was about 0.7. The sputtering rate S mentioned here, when the high-speed particles jumped out atoms constituting the N _s number of target from N ₁ pieces collided target material, the amount defined in S≡N ₁ / N _s. That is, even if the current density is increased, the total amount of electrode metal atoms or molecules released from the electrode (8) into the glass tube (2) does not increase so much, and the amount of mercury amalgam formed is small. In the case of the niobium-made electrode (8), even when the current density becomes 1 × 10 ³ A / m ² or more by reducing its length, the consumption of the electrode (8) by sputtering is small, and the glass tube (2) By setting the pressure of the rare gas in the parentheses) to a relatively low level, the desired lamp life can be maintained and the brightness can be increased.

In the above embodiment, the electrode is made of niobium.
Instead of forming (8), it may be formed of an alloy mainly composed of niobium, titanium or tantalum, an alloy mainly composed of titanium or tantalum, or an alloy of a metal selected from niobium, titanium and tantalum. Therefore, in the fluorescent discharge tube of the present invention, the electrode (8) can be formed from niobium, titanium, tantalum or an alloy thereof, but the electrode (8) composed of niobium has the best lamp voltage characteristics. Show characteristics.

[0013]

As described above, according to the present invention, it is possible to provide a fluorescent discharge tube capable of obtaining a desired lamp life and reducing the length of the non-light emitting region.

[Brief description of the drawings]

FIG. 1 is a sectional view of a fluorescent discharge tube according to the present invention.

FIG. 2 is an exploded perspective view of an electrode assembly used in the fluorescent discharge tube of FIG.

[Explanation of symbols]

(1) Fluorescent discharge tube, (2) Glass tube, (3) Closed space, (4) Electrode assembly, (5) Fluorescent film,
(6) ・ ・ Derivation part, (7) ・ ・ Buried part, (8) ・ ・ Electrode,

Claims (2)

[Claims] A glass tube forming a closed space, a pair of electrodes disposed in the closed space and fixed to both ends of the glass tube, and a fluorescent film formed on a surface of the glass tube. A fluorescent discharge tube that emits light by applying a voltage to the pair of electrodes, wherein the electrodes are made of a metal selected from niobium, titanium, tantalum or an alloy thereof, and a current density of a current flowing through the electrodes is 1 A fluorescent discharge tube having a density of at least 10 ³ A / m ² . 2. The fluorescent discharge tube according to claim 1, wherein the fluorescent discharge tube is a cold cathode fluorescent discharge tube used for a notebook personal computer.