JPH07142031A - Discharge lamp electrode - Google Patents

Abstract

PURPOSE:To reduce the tube diameter of a ceramic negative electrode fluorescent discharge lamp. CONSTITUTION:A discharge electrode 27 composed of bottomed cylindrical semiconductor ceramic to house electron emitting semiconductor ceramic 28 is provided, and the mercury getter of a discharge lamp electrode to release mercury from the mercury getter 32 housed in a metallic tube is installed on the lead wire between a tube end part and the discharge electrode. A method to pass penetratingly the lead wire in a mercury getter vessel, a method to insert the discharge electrode in the mercury getter vessel and a method to insert the mercury getter in the discharge electrode exist as an installing method. By constituting in this way, the increase in a tube diameter of a discharge lamp is prevented.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention relates to a portable personal
The present invention relates to an electrode of a backlight discharge lamp for a liquid crystal display device used in a computer, a word processor or the like.

[0002]

2. Description of the Related Art With the rapid spread of personal computers in recent years, a small personal computer or word processor suitable for carrying is rapidly spreading, and in particular, the outer shape is the same as a general business document A4 type. The size of a laptop computer called a notebook computer is popular because the cell phone is small and lightweight and the price is low.

In many cases, a liquid crystal display device is used as a display device in this notebook personal computer, but since this liquid crystal display device is not a light emitting display device, a light source is necessary to see the display contents. The simplest type of light source uses an external light source, but an internal light source is necessary because it is used in a place where the external light source is insufficient or sufficient amount of external light is required for color display. . This internal light source is called a backlight light source because it radiates light from the back surface of the liquid crystal display device, and is required to be a surface light source for displaying the entire liquid crystal display surface. Therefore, currently, electroluminescence (Electro Luminescent =
An EL) element or a fluorescent discharge lamp combined with a light guide plate is used as a backlight light source.

The structure of a backlight source using a fluorescent discharge lamp is shown in FIG. In this figure, 1 is a light guide plate made of a translucent material such as glass or acrylic resin,
The surface is provided with irregularities for radiating the light incident from the side surface of the plate in the plane direction. And the light guide plate 1
Fluorescent discharge lamps 2 and 2 are attached as light sources for making light incident on the light guide plate 1 on both side surfaces of.

In a general discharge lamp, a discharge gas is enclosed in a tube made of a transparent material such as glass, and an AC or DC voltage is applied to discharge electrodes arranged facing each other in the glass tube. A discharge is generated through the discharge gas, and light is emitted to the outside. In the case of a fluorescent discharge lamp, a low-pressure (about 1 Pa) mercury (Hg) gas is used as a discharge gas, and calcium halophosphate (3Ca) is applied to the inner wall of a glass tube with ultraviolet rays having a wavelength of 253.7 nm emitted by the mercury gas.
It is converted into visible light by irradiating a fluorescent substance such as ₃ (PO ₄ ) ₂ · CaFCl / Sb, Mn). In addition to the above, argon (Ar) gas having a pressure of about several hundred Pa is enclosed in the discharge gas in order to promote ionization of the mercury gas and facilitate discharge (Penning effect).

A cross-sectional view of a fluorescent discharge lamp 2 used for a conventional backlight light source is shown in FIG.
An enlarged sectional view of the portion is shown in FIG. 2 in this figure
Reference numeral 1 denotes a cylindrical elongated sealed glass tube container having an inner wall coated with a fluorescent substance, and lead wires 22 and 22 are provided at the left and right ends of the glass tube container 21, respectively. At the tip of the lead wire 22, tungsten filaments 23, 2 coated with an electron emitting substance such as barium oxide (BaO).
3 is attached, and mercury getters 24, 24 are arranged between the filaments 23, 23 and the tube end.

In the mercury getter (Ti ₃ Hg), mercury atoms are incorporated in the crystal lattice of titanium, and when heated, Ti ₃ Hg → Ti ₃ + Hg is obtained and mercury is released. When manufacturing a fluorescent discharge lamp, argon gas, which is a discharge starting gas, is enclosed, the tube end is closed and the entire tube is sealed, and then the mercury getters 24, 24 are heated using a high frequency induction heating device. Then, mercury vapor is released from Ti ₃ Hg. The mercury getter itself is a powder, and it is in a powder state, a state in which Ti ₃ Hg powder is applied on a nickel-plated iron thin plate, or a state in which a nickel tube is filled with Ti ₃ Hg powder. Supplied with. It should be noted that thin film titanium is a metal having a gettering action, but since mercury getter is a powder, metallic titanium after releasing mercury does not have a gettering action. Therefore, when a mercury getter is used, a getter such as Zr-Al is separately used to adsorb the residual gas.

Since this fluorescent discharge lamp is of the hot cathode type having the filament 23, not only the power consumption is large, but also the electron emitting material applied to the filament and the tungsten constituting the filament are lost by sputtering due to ion bombardment. The life of the tube is short. Further, since the filament requires a certain size, the inner diameter of the glass tube cannot be reduced, and the outer diameter of a normal glass tube is 8
It is about mm.

There is a strong demand for downsizing and power saving of a notebook personal computer in which a backlight light source using a fluorescent discharge lamp is often used, and therefore, there is also a demand for power saving and thinning of the backlight light source. strong. In order to meet this demand, a cold cathode fluorescent discharge lamp without a filament has been proposed in which an enlarged sectional view of the tube end is shown in FIG. In this cold cathode discharge lamp, instead of the filament and mercury getter of the hot cathode discharge lamp shown in FIG. 2, a cathode 26 also serving as a mercury getter is attached to a lead wire 25 in a glass tube container 21.

Unlike the hot cathode fluorescent discharge lamp shown in FIG. 2, this cold cathode fluorescent discharge lamp does not have a hot cathode, so that it consumes less power and has a long tube life. Further, since the filament is not used, the inner diameter of the glass tube container can be reduced, and the outer diameter of the glass tube container 21 can be set to about 4 mm. However, since there is no heating source for the cathode, the discharge start voltage is high, and since a large electron flow cannot be obtained, the brightness cannot be increased and the application is limited.

The inventors of the present invention have found that Japanese Patent Laid-Open Nos. 2-186527, 2-186550 and 2-21.
In Japanese Patent Application Laid-Open No. 5039 and JP-A-4-43546, a ceramic material is used as a fluorescent discharge lamp capable of solving both the problems of the hot cathode fluorescent discharge lamp and the problems of the cold cathode fluorescent discharge lamp. We proposed a fluorescent discharge lamp with a cathode.

FIG. 4 is an enlarged sectional view of the tube end portion of this ceramic cathode fluorescent discharge lamp.
The discharge electrode housed in 1 is a semiconductor ceramic porcelain having a bottomed cylindrical high melting point or good sputtering resistance, which is elastically sandwiched by a branch portion 26 formed at the end of the lead wire 25 and one of which is an opening. For example, it is composed of a cylindrical electrode 27 made of a Ba (Zr, Ta) O ₃ based semiconductor ceramic, and a lump-shaped, granular or porous electron-emitting semiconductor ceramic 28 housed in the cylindrical electrode 27. In addition, a Ta-based sputtering prevention layer is formed on the surface of the cylindrical electrode 27. The inner diameter of the cylindrical electrode 27 is 0.
9 mm, outer diameter 1.9 mm, length 2.3 mm and inner diameter 1.6 m
There are m, outer diameter 2.6mm, length 2.3mm. The mercury getter 30 of this ceramic cathode fluorescent discharge lamp is arranged radially outside of the position close to the cylindrical electrode 27.

In this ceramic cathode fluorescent discharge lamp, when discharge is started by the argon gas for starting discharge, the ionized gas produces plasma near the discharge electrode, and this plasma heats the electron-emitting semiconductor porcelain 28. The electron-emitting semiconductor porcelain 28 operates as a hot cathode.

This ceramic cathode fluorescent discharge lamp does not have a problem of a short life due to the loss of electron emitting substances and the like by sputtering. Further, since it is a hot cathode type, unlike the cold cathode type, the discharge starting voltage can be lowered and the brightness can be increased. However, since the mercury getter 30 is disposed at a position adjacent to the cylindrical electrode 27, the outer diameter of the glass tube cannot be reduced, so that the requirement for the backlight light source of the notebook personal computer is completely satisfied. Not not.

As a mounting structure for the mercury getter, a mercury getter 32 is fitted and fixed to one of the lead wires 25 of the hot cathode filament 31 housed in the glass tube container 21 as shown in FIG. Things have been proposed.
But as I said before, the mercury getter is a powder,
When heated, mercury is released. Therefore, the mercury getter powder is fixed to the lead wire 25 by pressing with pressure. Therefore, it is extremely fragile and requires careful handling during manufacturing. In order to solve these problems, the present inventors have proposed in Japanese Patent Application No. 5-87542 a structure in which a mercury getter filled in a nickel tube is attached to a lead wire between a cylindrical electrode and a tube end. No. 5-87543 proposes a structure in which a mercury getter is attached together with a cylindrical electrode.

[0016]

SUMMARY OF THE INVENTION An object of the present invention is to provide a novel structure of a fluorescent discharge lamp having a small glass tube diameter, which is suitable for use as a light source for a back light of a notebook personal computer.

Therefore, in the present invention, a cylindrical electrode constituting a ceramic cathode and a mercury getter filled in a nickel tube are arranged in series, and a lead wire is fitted into this mercury getter. In the present invention having such a configuration, mercury vapor for discharge is emitted from the mercury getter disposed adjacent to the cylindrical electrode between the cylindrical electrode and the lead wire lead portion during the production of the discharge lamp, and the discharge is performed. When the lamp is used, electrons are emitted from the electron-emitting semiconductor porcelain housed in the bottomed cylinder of the semiconductor porcelain provided at the end of the lead wire to discharge.

According to the present invention having such a structure, since the glass tube container of the ceramic cathode fluorescent discharge lamp having a small diameter can be used, the liquid crystal display device employing the ceramic cathode fluorescent discharge lamp can be made thin. Can be achieved.

[0019]

Embodiments of the present invention will be described below with reference to the drawings. Since the basic structure of the ceramic cathode discharge lamp of the present invention is the same as that of the conventional ceramic cathode discharge lamp shown in FIG. 4, the ceramic cathode discharge lamp according to the present invention will be used in the embodiments described below. The description of the outline of is omitted.

FIG. 6 shows a first embodiment of the ceramic cathode discharge lamp according to the first invention of the present application, wherein (a) is an enlarged sectional view of the tube end portion, and (b) is a line bb. The cross-sectional view cut is shown. In the figure, 21 is a cylindrical elongated hermetically sealed glass tube container having an inner wall coated with a fluorescent substance, and lead wires 25 are provided at the left and right ends of the glass tube container 21. A shallow cylindrical metal cap 33 is attached to the opposite end of the lead wire 25 from the introduction portion.

Reference numeral 27 is a cylindrical electrode made of a semiconductor ceramic having a high melting point and good sputtering resistance, for example, a Ba (Zr, Ta) O ₃ -based semiconductor ceramic. The cylindrical electrode 27 is in the shape of a cylinder with a bottom, one side of which is an opening, and in this cylindrical electrode 27, a lump-shaped, granular or porous electron-emitting semiconductor ceramic 28 is housed. The cylindrical electrode 27 has a Ta-based sputtering prevention layer formed on the surface thereof. The bottom side of the cylindrical electrode 27 is held by the metal cap 33. The mercury getter 32 is filled in a tube 34 made of a metal such as nickel having a cylindrical shape, and the lead wire 25 is fitted and inserted in the center of the tube 34 and arranged between the lead-in side of the lead wire 25 and the metal cap 33. ing.

To attach the mercury getter 32 to the lead wire 25, a nickel tube filled with the mercury getter is cut into a predetermined length, and a hole through which the lead wire 25 can be inserted is formed in the axial center thereof. Lead wire 25 in the hole
After inserting it, crimp it over the nickel tube. By doing so, the mercury getter can be securely attached without damage. In addition, it goes without saying that the configuration in which the lead wire is inserted through the center of the mercury getter container in which the metal getter is filled with the mercury getter is applicable to a discharge lamp having another configuration using the mercury getter. .

FIG. 7 shows the first application of the present invention shown in FIG.
It is a second embodiment which is a modified embodiment of the ceramic cathode discharge lamp according to the present invention, in which (a) is an enlarged sectional view of a tube end portion and (b) is a sectional view taken along line bb. In this figure, reference numeral 21 is a cylindrical elongated sealed glass tube container having an inner wall coated with a fluorescent substance, and lead wires 25 are provided at the left and right ends of the glass tube container. A shallow cylindrical metal cap 33 is provided at the end opposite to the lead-in portion of the lead wire 25.
Is attached.

The cylindrical electrode 35 is in the shape of a cylinder with a bottom, one side of which is an opening. Inside the cylindrical electrode 35, there are lump-shaped, granular or porous electron-emitting semiconductor ceramics 2.
8 is stored. The cylindrical electrode 35 has a Ta-based sputtering prevention layer formed on its surface. A small diameter portion 36 is formed outside the bottom of the cylindrical electrode 35, and the small diameter portion 36 is held by being inserted into the metal cap 33. The mercury getter 32 is filled in a tube 34 made of a metal such as nickel having a cylindrical shape, and the lead wire 25 is fitted and inserted in the center of the tube 34 and arranged between the lead-in side of the lead wire 25 and the metal cap 33. ing.

FIG. 8 shows a first embodiment of the ceramic cathode discharge lamp according to the second aspect of the present invention. FIG. 8 (a) is an enlarged sectional view of the tube end portion, and FIG. 8 (b) is a sectional view taken along line bb. The cross-sectional view cut is shown. In this figure, reference numeral 21 is a cylindrical elongated sealed glass tube container having an inner wall coated with a fluorescent substance, and lead wires 25 are provided at the left and right ends of the glass tube container. Unlike the ones shown in FIGS. 6 and 7, the cylindrical electrode 36 is formed in a bottomless cylindrical shape instead of a bottomed cylinder. A sealing member 37 having an outer diameter equal to the inner diameter of the cylindrical electrode 36 is inserted into the cylindrical electrode 36 having a bottomless cylindrical shape to form the bottom of the cylindrical electrode 36. In this way, the lumped, granular or porous electron-emitting semiconductor porcelain 28 is housed in the cylindrical electrode 36 whose bottom is formed by the sealing member 37. The cylindrical electrode 36 has a Ta-based sputtering prevention layer formed on the surface thereof.

The mercury getter 32 is filled in a tube 34 made of a metal such as nickel having a cylindrical shape, and the large diameter portion 38 of the lead wire 25 is inserted through the center of the tube 34 to introduce the lead wire 25 and the cylindrical electrode. It is arranged between 36.
The large-diameter portion 38 is not always necessary, and the sealing member 37 can be directly formed on the lead wire 25. Further, the lead wire 25 and the sealing member 37 are electrically connected to each other, so that power is supplied to the cylindrical electrode 36.

FIG. 9 shows a second embodiment of the ceramic cathode discharge lamp according to the second aspect of the present invention. (A) is an enlarged cross-sectional view of the tube end portion, and (b) is a line bb. The cross-sectional view cut is shown. This embodiment is a modification of part of the third embodiment shown in FIG. 8. In the figure, reference numeral 21 denotes a cylindrical elongated sealed glass tube container whose inner wall is coated with a fluorescent substance. Lead wires 25 are provided at the left and right ends of the tube container. Only the large-diameter portion 41 is formed at the end of the lead wire 25 opposite to the introduction portion.

The cylindrical electrode 39 has a bottomless cylindrical shape up to now, but unlike the third embodiment shown in FIG. 8, a small diameter portion 40 is formed. The large-diameter portion 41 formed on the lead wire 25 is inserted into the small-diameter portion of the cylindrical electrode 39 having the bottomless cylindrical shape to form the bottom of the cylindrical electrode 39 and to supply power to the cylindrical electrode 39. Has been done. In this way, the cylindrical electrode 39 whose bottom is formed by the large-diameter portion 41
A lump-shaped, granular or porous electron-emitting semiconductor porcelain 28 is housed therein. The cylindrical electrode 39 has a Ta-based sputtering prevention layer formed on its surface.

The mercury getter 32 is filled in a metal tube 34 made of nickel or the like having a cylindrical shape, and the large diameter portion 41 of the lead wire 25 is fitted and inserted in the center of the tube 34 and the introduction side of the lead wire 25 and the cylinder. It is arranged between the electrodes 39.
The portion of the large-diameter portion 41 that is inserted into the mercury getter 32 is not necessarily required, and the lead wire 25 can be inserted into the mercury getter.

FIG. 10 shows a third embodiment of the ceramic cathode discharge lamp according to the second invention of the present application (a).
An enlarged cross-sectional view of the pipe end is shown in FIG. 7B, and a cross-sectional view taken along line bb is shown in FIG. This embodiment is obtained by further modifying a part of the second embodiment shown in FIG. 9. In the drawing, 21 is a cylindrical elongated sealed glass tube container whose inner wall is coated with a fluorescent substance. Lead wire 2 on the left and right ends of the tube container
5 are provided. A large-diameter portion 41 is formed at the end of the lead wire 25 on the opposite side of the introduction portion, and a system stop portion 42 is formed at the tip thereof.

The cylindrical electrode 39 has the same shape as that of the second embodiment shown in FIG. 9 and has a small diameter portion 40 formed therein. However, the system stopper 42 formed at the tip of the lead wire 25 has a thin disc shape, and its diameter is 3 mm.
The inner diameter is equal to 9. The large diameter portion 41 formed on the lead wire 25 is inserted into the small diameter portion inside the cylindrical electrode 39 having this bottomless cylindrical shape, and the system stopper 42 forms the bottom of the cylindrical electrode 39 and It is configured to supply power. In this way, the lump-shaped or granular-shaped or porous electron-emitting semiconductor porcelain 28 is housed in the cylindrical electrode 39 whose bottom is formed by the system stopper 42. The cylindrical electrode 39 has a Ta-based sputtering prevention layer formed on its surface.

The mercury getter 32 is filled in a tube 34 made of a metal such as nickel having a cylindrical shape, and the large diameter portion 41 of the lead wire 25 is fitted and inserted in the center of the tube 34 and the introduction side of the lead wire 25 and the cylinder. It is arranged between the electrodes 39.
The portion of the large-diameter portion 41 that is inserted into the mercury getter 32 is not always necessary, and the system stopper 42 can be directly formed at the tip of the lead wire 25.

FIG. 11 shows a first embodiment of a ceramic cathode discharge lamp according to the third invention of the present application (a).
An enlarged cross-sectional view of the pipe end is shown in FIG. 7B, and a cross-sectional view taken along line bb is shown in FIG. In this figure, reference numeral 21 is a cylindrical elongated sealed glass tube container having an inner wall coated with a fluorescent substance, and lead wires 25 are provided on the left and right ends of the glass tube container 21. The mercury getter 45 is filled in a metal tube 46 of nickel or the like having a cylindrical shape, and the end portion 47 of the lead wire 25 is attached to the nickel tube 46.

The mercury getter 45 is arranged between the lead-in side of the lead wire 25 and the cylindrical electrode 43, the inner diameter of the nickel tube is equal to the outer shape of the cylindrical electrode 43, and one end 48 of the nickel tube is extended. The bottom of the cylindrical electrode 43 is inserted therein. 43 is a semiconductor ceramic having a high melting point and a good sputtering resistance, such as Ba (Zr,
Ta) A cylindrical electrode made of an O ₃ based semiconductor ceramic. The cylindrical electrode 43 is in the shape of a cylinder with a bottom, one side of which is an opening, and in this cylindrical electrode 43, a lump-shaped, granular or porous electron-emitting semiconductor ceramic 44 is housed. The cylindrical electrode 43 has a Ta-based sputtering prevention layer formed on the surface thereof. As a result, the mercury getter 45 and the cylindrical electrode 43 are attached to the lead wire 25, and the lead wire 25 and the cylindrical electrode 43 are electrically connected. By doing so, the mercury getter can be securely attached without damage.

FIG. 12 shows a second embodiment which is a modified embodiment of the ceramic cathode discharge lamp according to the third invention of the present application shown in FIG. 11, and FIG. 12 (a) shows an enlarged cross section of the tube end. A cross-sectional view taken along the line bb is shown in FIG. In this figure, reference numeral 21 is a cylindrical elongated sealed glass tube container having an inner wall coated with a fluorescent substance, and lead wires 25 are provided on the left and right ends of the glass tube container 21. The mercury getter 45 is filled in a metal tube 46 of nickel or the like having a cylindrical shape, and the end portion 47 of the lead wire 25 is attached to the nickel tube 46.

The mercury getter 45 is arranged between the lead-in 25 side of the lead wire 25 and the cylindrical electrode 43, and the cylindrical electrode 49 side of the nickel tube is an extension 48. A small diameter portion 49 is formed on the outside of the bottom of the cylindrical electrode 49, and the inner diameter of the nickel tube 48 and the outer shape of the cylindrical electrode 43 are made equal to each other.
It is held by being inserted into the inside 8.

FIG. 13 shows an embodiment of the ceramic cathode discharge lamp according to the fourth invention of the present application, in which (a) is an enlarged sectional view of the tube end portion and (b) is a sectional view taken along line bb. A sectional view is shown. In this figure, reference numeral 21 is a cylindrical elongated sealed glass tube container having an inner wall coated with a fluorescent substance, and lead wires 25 are provided on the left and right ends of the glass tube container 21.

The mercury getter 45 is filled in a tube 46 made of a metal such as nickel having a cylindrical shape, and the cylindrical electrode 43 is provided between the lead electrode 25 and the cylindrical electrode 43.
Is arranged in contact with. The outer diameter of the nickel tube 46 and the outer diameter of the cylindrical electrode 49 are made equal, and the nickel tube 46 is inserted into a metal tube 51 having an inner diameter equal to these outer diameters. The lead wire 25 is attached to the metal tube 51.
Has an end 47 attached thereto.

FIG. 14 shows an embodiment of a ceramic cathode discharge lamp according to the fifth aspect of the present invention. (A) is an enlarged cross-sectional view of the tube end portion, and (b) is a cross-sectional view taken along line bb. The figure is shown. In this figure, reference numeral 21 is a cylindrical elongated sealed glass tube container having an inner wall coated with a fluorescent substance, and lead wires 25 are provided on the left and right ends of the glass tube container 21. Reference numeral 52 is a cylindrical electrode made of a semiconductor ceramic having a high melting point and good sputtering resistance, for example, a Ba (Zr, Ta) O ₃ -based semiconductor ceramic. Both of the cylindrical electrodes 52 are open mouths, and have a bottomed cylindrical shape with a partition provided in the middle portion. One of the cylindrical electrodes 52 is provided with an electron-emitting semiconductor porcelain 53 in the form of lumps, particles or porous. It is stored. The cylindrical electrode 52 has a Ta-based sputtering prevention layer formed on its surface.

The mercury getter 54 is filled in a tube 55 made of a metal such as nickel, and is arranged between the lead-in side of the lead wire 25 and the cylindrical electrode 43. The outer diameter of the nickel tube and the inner diameter of the cylindrical electrode 52. Are made equal to each other, and a nickel tube filled with a mercury getter is inserted into the side of the cylindrical electrode 52 where the electron-emitting semiconductor porcelain 53 is not housed, leaving a part thereof. The end 47 of the lead wire 25 is attached to the nickel tube 55, so that
The mercury getter 54 and the cylindrical electrode 52 are attached to the lead wire 25, and the lead wire 25 and the cylindrical electrode 43 are electrically connected. By doing so, the mercury getter can be securely attached without damage.
If a metal cylinder is attached to the outside of the cylindrical electrode and the end 47 of the lead wire 25 is attached to this metal cylinder, the nickel tube 55 need not be used.

FIG. 15 shows a second embodiment which is a modification of the ceramic cathode discharge lamp according to the fifth invention of the present application shown in FIG. 14, and FIG. 15 (a) shows an enlarged cross section of the tube end. A cross-sectional view taken along the line bb is shown in FIG. In this figure, reference numeral 21 is a cylindrical elongated sealed glass tube container having an inner wall coated with a fluorescent substance, and lead wires 25 are provided on the left and right ends of the glass tube container 21. Reference numeral 52 is a cylindrical electrode made of a semiconductor ceramic having a high melting point and good sputtering resistance, for example, a Ba (Zr, Ta) O ₃ -based semiconductor ceramic. Both of the cylindrical electrodes 52 are open mouths, and have a bottomed cylindrical shape with a partition provided in the middle portion. One of the cylindrical electrodes 52 is provided with an electron-emitting semiconductor porcelain 53 in the form of lumps, particles or porous. It is stored. The cylindrical electrode 52 has a Ta-based sputtering prevention layer formed on its surface.

The mercury getter 54 is a nickel tube 55.
It is filled inside and is arranged between the lead-in side of the lead wire 25 and the cylindrical electrode 43, and the outer diameter of the nickel tube and the inner diameter of the cylindrical electrode 52 are made equal to each other. A nickel tube filled with a mercury getter is completely inserted on the side where the porcelain 53 is not housed.

A shallow cylindrical metal cap 56 is attached to the end of the lead wire 25 on the opposite side to the introduction portion, and the mercury getter 54 insertion side of the cylindrical electrode 52 is held by this metal cap 56. Since it is necessary to pass mercury vapor after the discharge tube is sealed in the metal cap 56, a hole as shown in (b) is formed. In this case, the mercury getter can be used even if it is not filled in the nickel tube.

FIG. 16 shows an embodiment of a ceramic cathode discharge lamp according to the fourth invention of the present application. (A) is an enlarged cross-sectional view of the tube end portion, and (b) is a cross-sectional view taken along line bb. The figure is shown. In this figure, reference numeral 21 is a cylindrical elongated sealed glass tube container having an inner wall coated with a fluorescent substance, and lead wires 25 are provided on the left and right ends of the glass tube container 21. Reference numeral 58 denotes a flat cylindrical electrode made of a semiconductor ceramic having a high melting point and good sputtering resistance, for example, a Ba (Zr, Ta) O ₃ -based semiconductor ceramic. The flat cylindrical electrode 58 has a bottomed cylindrical shape with one end open, and the flat cylindrical electrode 58 accommodates a lump-shaped, granular, or porous electron-emitting semiconductor porcelain 59. Further, the flat cylindrical electrode 52 has a Ta-based sputtering prevention layer formed on the surface thereof. A U-shaped support body 60 is attached to the end of the lead wire 25 on the opposite side of the introduction portion, and the flat cylindrical electrode 58 is sandwiched by the support body 60.
Further, powdery mercury getters 61 and 62 are provided on both surfaces of the support 60. With this configuration, the mercury getter in the powder state or in the state in which the Ti ₃ Hg powder is applied on the nickel-plated iron thin plate can be reliably attached without damage.

[0045]

As is apparent from the above-described embodiments, since the cylindrical electrode and the mercury getter are arranged in series in the present invention, the glass tube container of the ceramic cathode fluorescent discharge lamp has a small diameter. Can be used, and the liquid crystal display device employing this ceramic cathode fluorescent discharge lamp can be made thinner.

[Brief description of drawings]

FIG. 1 is a perspective view of a backlight for a liquid crystal display device to which a fluorescent discharge lamp is applied.

FIG. 2 is an overall sectional view and tube end sectional view of a conventional fluorescent discharge lamp for a backlight.

FIG. 3 is a sectional view of a tube end portion of another conventional fluorescent discharge lamp for a backlight.

FIG. 4 is a sectional view of a tube end portion of a fluorescent discharge lamp for backlight according to still another conventional example.

FIG. 5 is a sectional view of a tube end portion of a fluorescent discharge lamp for backlight according to still another conventional example.

FIG. 6 is a sectional view of a tube end portion of the discharge lamp according to the first embodiment of the present invention.

FIG. 7 is a sectional view of a tube end portion of a discharge lamp according to a first embodiment of the present invention and a second embodiment of the present application.

FIG. 8 is a sectional view of a tube end portion of a discharge lamp according to a first embodiment of the second invention of the present application.

FIG. 9 is a sectional view of a tube end portion of a discharge lamp according to a second embodiment of the present invention.

FIG. 10 is a sectional view of a tube end portion of a discharge lamp according to a third embodiment of the second invention of the present application.

FIG. 11 is a sectional view of a tube end portion of a discharge lamp according to a first embodiment of the third invention of the present application.

FIG. 12 is a sectional view of a tube end portion of a discharge lamp according to a second embodiment of the third invention of the present application.

FIG. 13 is a sectional view of a tube end portion of a discharge lamp according to a fourth invention example of the present application.

FIG. 14 is a sectional view of a tube end of a discharge lamp according to a fifth embodiment of the present invention.

FIG. 15 is a sectional view of a tube end portion of a discharge lamp according to a second embodiment of the fifth invention of the present application.

FIG. 16 is a sectional view of a tube end portion of a discharge lamp of a sixth invention example of the present application.

[Explanation of symbols]

 1 Light guide plate 2 Discharge lamp 5, 33, 56 Metal cap 21 Glass tube container 22, 25 Lead wire 27, 35, 36, 39, 43, 49, 52 Cylindrical electrode 28, 44, 53, 59 Electron emitting semiconductor porcelain 30 , 32, 45, 54, 61, 62 Mercury getter

Claims (6)

[Claims] 1. A bottomed cylindrical semiconductor porcelain, a lead wire led from a tube end of a glass tube, a shallow cylindrical metal cap holding the bottomed cylindrical semiconductor porcelain and attached to the lead wire, An electron-emitting semiconductor porcelain housed in a bottomed cylindrical semiconductor porcelain, a cylindrical shape arranged between the lead-out side end of the lead wire and the bottomed cylindrical semiconductor porcelain filled with a mercury getter in a metal tube. A discharge lamp electrode comprising a mercury getter container, wherein a lead wire is inserted through the center of the cylindrical mercury getter container. 2. A bottomless cylindrical semiconductor porcelain, a lead wire led out from a tube end portion of a glass tube, and a bottom portion of the bottomless cylindrical semiconductor porcelain which is inserted into the bottomless cylindrical semiconductor porcelain and formed on the lead wire. A metal member attached, an electron-emitting semiconductor porcelain housed in the bottomless cylindrical semiconductor porcelain, a mercury getter filled in a metal tube, and the lead-out side end of the lead wire and the bottomless cylindrical semiconductor porcelain. A discharge lamp electrode, comprising a cylindrical mercury getter container disposed between the discharge lamp electrodes, and a lead wire inserted through the center of the cylindrical mercury getter container. 3. A bottomed cylindrical semiconductor porcelain, a lead wire led from a tube end of a glass tube, an electron-emitting semiconductor porcelain housed in the bottomed cylindrical semiconductor porcelain, and a mercury getter in a metal tube. A cylindrical mercury getter container is provided, which is arranged between the lead-out side end of the lead wire and the bottomed cylindrical semiconductor porcelain and is extended from the bottomed cylindrical semiconductor porcelain side of the metal tube. A discharge lamp electrode connected to the metal tube and having a bottom portion of the bottomed cylindrical semiconductor porcelain inserted into the extended metal tube. 4. A bottomed cylindrical semiconductor porcelain, a lead wire led out from a tube end of a glass tube, an electron-emitting semiconductor porcelain housed in the bottomed cylindrical semiconductor porcelain, and a mercury getter in a metal tube. A cylindrical mercury getter container is provided, which is arranged between the lead-out side end of the lead wire and the bottomed cylindrical semiconductor porcelain and is extended from the bottomed cylindrical semiconductor porcelain side of the metal tube. A discharge lamp electrode connected to the metal tube and having the bottomed cylindrical semiconductor porcelain inserted in the extended metal tube. 5. A bottomed cylindrical semiconductor porcelain having openings at both ends and a bottom at an intermediate portion, a lead wire led from a tube end of a glass tube, and one opening of the bottomed cylindrical semiconductor porcelain. An electron-emitting semiconductor porcelain housed in a metal tube, a metal tube filled with a mercury getter, and arranged between the lead-out side end of the lead wire and the bottomed cylindrical semiconductor porcelain. A porcelain side is provided with an extended cylindrical mercury getter container, the lead wire is connected to the metal tube and the cylindrical mercury getter container is inserted into the other opening of the bottomed cylindrical semiconductor porcelain discharge Lamp electrode. 6. A flat-bottomed cylindrical semiconductor porcelain, a lead wire led out from a tube end of a glass tube, an electron-emitting semiconductor porcelain housed in the flat-bottomed cylindrical semiconductor porcelain, U-shaped A U-shaped plate-shaped metal supporting member for sandwiching the flat cylindrical semiconductor porcelain with bottom, and mercury getters attached to both surfaces of the U-shaped plate-shaped metal supporting member, wherein the lead wire is the U-shaped plate-shaped metal supporting member. A discharge lamp electrode connected to.