JP2009170298A - Hot cathode fluorescent lamp - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a hot cathode fluorescent lamp having improved light emitting efficiency and a longer life. <P>SOLUTION: The hot cathode fluorescent lamp comprises an arc tube (not illustrated) having stems 4 at both ends, filaments 2 arranged at both ends of the arc tube, and emitters 3 as emissive materials. It also has holding members 1 formed of insulating materials and arranged between each filament 2 and each stem 4. The emitters 3 are each held by the holding member 1 and the filament 2. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a hot cathode fluorescent lamp.

  FIG. 4 is a longitudinal sectional view of a hot cathode fluorescent lamp related to the present invention. The hot-cathode fluorescent lamp includes an arc tube 17 made of glass, stems 14 that are sealing portions provided at both ends of the arc tube 17, lead wires 15 that are hermetically inserted into the stems 14, respectively, It has a filament 12 attached to the end of a lead wire 15 housed inside the arc tube 17 and a base 19 attached to both ends of the arc tube 17. The filament 12 is coated with an emitter that is an electron-emitting material. A phosphor layer 18 is formed on the inner wall of the arc tube 17, and a small amount of rare gas and mercury are enclosed in the arc tube 17.

  In this hot cathode fluorescent lamp, when a voltage is applied between the lead wires 15 extending outward from both ends of the arc tube 17, the emitter applied to the filament 12 emits thermoelectrons, and the thermoelectrons are cathodes. When moving from the anode to the anode, the mercury atoms emit ultraviolet rays by colliding with mercury atoms in the arc tube 17, and the ultraviolet rays are converted into visible light by the phosphor layer 18 formed on the inner wall of the arc tube 17. It is comprised so that light may be emitted.

  Since the filament 12 generates a large amount of heat at the time of light emission, the filament 12 is disposed at a position away from the stem 14 so that the stem 14 is not damaged by this heat. Further, the stem 14 is formed so as to protrude greatly into the arc tube 17 so that the base 19 and the like at the end of the hot cathode fluorescent lamp are not overheated and damaged by the heat generated by the filament 12.

The filament 12 is coated with a ternary oxide mainly composed of barium oxide (BaO), calcium oxide (CaO), and strontium oxide (SrO) as an emitter. In the emitter coating process in the manufacturing process of the hot cathode fluorescent lamp, first, a ternary carbonate powder mainly composed of barium carbonate (BaCO ₃ ), calcium carbonate (CaCO ₃ ), and strontium carbonate (SrCO ₃ ) is applied to the filament 12. A paste formed with an organic solvent is applied to the filament 12. After that, exhaust is performed and the filament 12 is energized and heated to remove the organic solvent and complete the coating process through an exhaust electrode activation (decomposition) process in which the carbonate is decomposed into oxides. .

A technique related to the present invention is described in Patent Document 1, for example.
Japanese Patent Laid-Open No. 11-345596

  From the viewpoint of the environment, the hot cathode fluorescent lamp is desirably configured so as to reduce the emission amount of greenhouse gases such as carbon dioxide by saving energy. By configuring the hot cathode fluorescent lamp so that the length of the positive column during light emission is increased, the light emitting surface can be expanded with the same power, so that the light emission efficiency is improved and energy saving can be achieved. In order to increase the length of the positive column during light emission, it is necessary to dispose the filaments at both ends of the arc tube more apart.

  Further, extending the life of the hot cathode fluorescent lamp is desirable from the viewpoint of the environment because it leads to a reduction in the amount of waste and contributes to resource saving. Hot cathode fluorescent lamps often reach the end of their lives due to exhaustion and exhaustion of the emitter, which is an electron-emitting material, during light emission. Therefore, in order to extend the life of the hot cathode fluorescent lamp, it is necessary to increase the amount of emitters.

  In the hot cathode fluorescent lamp shown in FIG. 4, as described above, the stem 14 is formed so as to largely protrude into the arc tube 17, and the filament 12 is disposed at a position away from the stem 14. In order to increase the length of the positive column at the time of light emission, if the filaments 12 at both ends of the arc tube 17 are arranged apart from each other, the filaments 12 come close to the stem 14, the base 19, etc. 14 and the base 19 may be damaged by being overheated. Therefore, it is difficult for this hot cathode fluorescent lamp to improve the luminous efficiency by increasing the length of the positive column during light emission without changing the length of the arc tube.

  In this hot cathode fluorescent lamp, the emitter is applied to the filament 12, but the amount of the emitter that can be held is determined by the length of the filament 12, and if the amount of the applied emitter is too large, Cannot be held by the filament 12 and falls off from the filament 12. The filament 12 can be formed longer by changing its shape to a spiral shape or the like. However, when the shape of the filament 12 is increased, not only the shape of the filament 12 becomes unstable but also the filament 12 has a lead wire. Since the lead wire 15 is supported only by the lead wire 15, the lead wire 15 may be deformed. As a result, when the filament 12 approaches or comes into contact with the phosphor layer 18, there may be a problem that the phosphor layer 18 is damaged due to heat generation of the filament 12. Therefore, in this hot cathode fluorescent lamp, the filament must be long enough not to cause such a problem. Thus, in this hot cathode fluorescent lamp, it is difficult to extend the life by greatly increasing the amount of emitters.

  Further, in the application process of the emitter of the hot cathode fluorescent lamp, carbonate powder is made into a paste, the carbonate paste is applied to the filament 12, and then the filament 12 is energized in the exhaust electrode activation (decomposition) process. This decomposes the carbonate into oxides. Since this step needs to be performed separately for each filament 12, productivity is not good.

  Further, when the hot cathode fluorescent lamp reaches the end of its life due to the absence of the emitter in the filament, the discharge may still continue from the filament in which the emitter has disappeared or the lead wire in the arc tube. The cathode fall voltage of the hot cathode fluorescent lamp is normally several tens of volts, but in such a case, it rises to about 100 volts. Therefore, in such a case, the filament, which is a coil-shaped resistor, generates a large Joule heat, which may cause the end portion of the hot cathode fluorescent lamp to be overheated and damaged. Therefore, it is desirable that the hot cathode fluorescent lamp is configured so as not to be damaged by the heat generated by the filament.

  In addition, hot cathode fluorescent lamps emit substances such as tungsten (W) that form filaments, emitter materials, and metal materials that form lead wires during light emission. Deposit on the surface. The two lead wires inserted into the stem are insulated, but the two lead wires are connected via the scattered material deposited on the surface of the stem by depositing conductive scattered material on the surface of the stem. May be electrically connected. When the hot cathode fluorescent lamp is energized in such a state, Joule heat is generated due to a large current flowing through the scattered material on the surface of the stem, and the stem may be overheated and damaged. Therefore, it is desirable that the hot cathode fluorescent lamp is configured to prevent scattering substances from being deposited on the surface of the stem during light emission.

  In view of the above-described problems, an object of the present invention is to provide a hot cathode fluorescent lamp that is excellent in luminous efficiency and has a long lifetime.

  In order to achieve the above object, a hot cathode fluorescent lamp of the present invention includes an arc tube having sealing portions at both ends, electrodes disposed at both ends of the arc tube, an emitter that is an electron-emitting material, A hot-cathode fluorescent lamp comprising: a holding member formed of an insulating material and disposed between each of the electrodes and the sealing portion adjacent to each of the electrodes; and The emitter is held by the holding member and the electrode.

  According to the present invention, it is possible to provide a hot cathode fluorescent lamp which is excellent in luminous efficiency and has a long lifetime.

Next, embodiments of the present invention will be described with reference to the drawings.
(First embodiment)
FIG. 1 is a longitudinal sectional view of a hot cathode fluorescent lamp according to a first embodiment of the present invention, and FIG. 2 is an enlarged sectional view of an electrode portion of the hot cathode fluorescent lamp and a filament of the electrode portion. .

  As shown in FIG. 1, the hot cathode fluorescent lamp according to the present embodiment is attached to the arc tube 7 made of glass, the electrode portions 10 arranged at both ends of the arc tube 7, and both ends of the arc tube 7. And a base 9 which is made. The arc tube 7 is sealed by attaching the stem 4 provided in the electrode portion 10 to both ends of the arc tube 7 as a sealing portion. A phosphor layer 8 is formed on the inner wall of the arc tube 7, and a small amount of rare gas and mercury are sealed inside the arc tube 7.

  In addition, as shown in FIG. 2, the electrode portion 10 of the hot cathode fluorescent lamp according to the present embodiment includes two lead wires 5 hermetically inserted into each stem 4 and ceramics having insulation and heat resistance. The holding member 1 formed in a cup shape and accommodated at both inner ends of the arc tube 7, the filament 2 formed in a spiral shape and accommodated inside each holding member 1, and the inside of each holding member 1 Each of the emitters 3 is filled, and an exhaust pipe 6 whose ends extending outward from both ends of the arc tube 7 are sealed.

The holding member 1 is formed of ceramics such as alumina (Al ₂ O ₃ ), zirconia (ZrO ₂ ), and aluminum nitride (AlN). The material forming the holding member 1 may not be ceramic as long as it has insulating properties and heat resistance. As shown in FIG. 1, the holding member 1 is disposed at both ends of the arc tube 7 so that the openings face each other. The holding member 1 is held by being inserted through two lead wires 5 supported by the stem 4.

  The filament 2 is made of pure tungsten, rhenium (Re) -added tungsten, or the like, and is formed in a spiral shape. The filament 2 is attached to the end of the lead wire 5 and accommodated in the holding member 1.

As the emitter 3, an electron emitting material such as alkaline earth aluminate containing barium aluminate (BaAl ₂ O ₄ ) is used. For example, the emitter 3 is fixed in the holding member 1 by a method such as filling the holding member 1 in which the filament 2 is accommodated in a powder state and heating and firing in a hydrogen furnace. In this hot cathode fluorescent lamp, the emitter 3 is filled in the cup-shaped holding member 1, so that a much larger number of emitters are held as compared with the hot cathode fluorescent lamp in which the emitter is applied to the filament. be able to. Thus, the hot cathode fluorescent lamp has a long life.

  The emitter 3 also functions to fix the filament 2 in the holding member 1 and maintain the shape of the filament 2, and stably holds the filament 2 in the holding member 1 even if the filament 2 is formed in a spiral shape. Is done.

  Further, in this hot cathode fluorescent lamp, since the process of filling the emitter 3 into the holding member 1 can be performed in a large amount at a time, it is produced in comparison with the hot cathode fluorescent lamp having a process of individually applying the emitter to the filament. Can improve the performance.

  Further, in this hot cathode fluorescent lamp, the holding member 1 prevents the heat generated by the filament 2 from being transmitted to the stem 4 side, and the stem 4 and the base 9 are prevented from being overheated by the heat generated by the filament 2. ing. Therefore, in this hot cathode fluorescent lamp, it is possible to arrange the filament 2 at a position close to the stem 4 and reduce the protrusion of the stem 4 into the arc tube 7. Thereby, in this hot cathode fluorescent lamp, the distance between the filaments 2 at both ends can be increased, and the length of the positive column at the time of light emission can be increased accordingly, so that the luminous efficiency is improved.

  In this hot cathode fluorescent lamp, since the filament 2 is disposed at a position close to the stem 4, the length of the portion of the lead wire 5 connecting the stem 4 and the filament 2 is short. Therefore, the lead wire 5 is not greatly deformed, and the filament 2 and the holding member 1 can be stably held.

  Further, in this hot cathode fluorescent lamp, since the holding member 1 is disposed at a position close to the stem 4 between the filament 2 and the stem 4, substances scattered from the filament 2 and the emitter 3 during light emission are stem 4. Accumulation on the surface of the substrate is suppressed. Thereby, in this hot cathode fluorescent lamp, the two lead wires 5 inserted through the stem 4 are prevented from being electrically connected via the surface of the stem 4.

  Further, in this hot cathode fluorescent lamp, the holding member 1 prevents the heat generated by the filament 2 from being transmitted to the stem 4 side, and when the filament 2 has no emitter and reaches the end of its life, the filament 2 has no emitter. Therefore, even when the discharge is continued, the stem 4 and the base 9 are not easily damaged by the heat generated by the filament 2.

The hot-cathode fluorescent lamp according to this embodiment includes the flare-shaped stem 4 as the sealing portion, but the same effect can be obtained even if other members such as glass beads are provided as the sealing portion. Can do.
(Second Embodiment)
FIG. 3 is an enlarged cross-sectional view of an electrode portion of a hot cathode fluorescent lamp according to the second embodiment of the present invention and a diagram showing a filament of the electrode portion. The hot-cathode fluorescent lamp according to the present embodiment is fixed to the holding member 1a so as to cover the filament 2a, the holding member 1a formed in a disk shape, the filament 2a arranged to be engaged with the holding member 1a, and the filament 2a. And an emitter 3a. The hot cathode fluorescent lamp according to this embodiment is configured in the same manner as the hot cathode fluorescent lamp according to the first embodiment except for the configuration described below.

  The holding member 1a is formed in a disk shape with ceramics having insulating properties and heat resistance. In this hot cathode fluorescent lamp, since the emitter 3a is held not only by the filament 2a but also by the holding member 1a, more emitters can be held as compared with the hot cathode fluorescent lamp in which the emitter is applied to the filament. .

  Further, in this hot cathode fluorescent lamp, the filament 2a is engaged with the holding member 1a so that the shape of the filament 2a is maintained, and even if the filament 2a is formed in a spiral shape, it is stably held. The

  In the hot cathode fluorescent lamp according to the present embodiment, the emitter 3a is fixed and held on the holding member 1a. However, the emitter may be held by being applied to the filament 2a. Even in this case, in the present hot cathode fluorescent lamp, since the filament 2a is formed in a spiral shape and the holding member 1a functions to hold the emitter, it can hold more emitters. .

1 is a longitudinal sectional view of a hot cathode fluorescent lamp according to a first embodiment of the present invention. It is the figure which showed the expanded sectional view of the electrode part of the hot cathode fluorescent lamp shown in FIG. 1, and the filament of the electrode part. It is the figure which showed the expanded sectional view of the electrode part of the hot cathode fluorescent lamp which concerns on the 2nd Embodiment of this invention, and the filament of the electrode part. 1 is a longitudinal sectional view of a hot cathode fluorescent lamp related to the present invention.

Explanation of symbols

1, 1a Holding member 2, 2a Filament 3, 3a Emitter 4 Stem 5 Lead wire 6 Exhaust tube 7 Light emitting tube 8 Phosphor layer 9 Base 10 Electrode part

Claims (4)

In a hot cathode fluorescent lamp having an arc tube provided with sealing portions at both ends, electrodes disposed at both ends of the arc tube, and an emitter that is an electron-emitting material,
A holding member formed of an insulating material and disposed between each of the electrodes and the sealing portion adjacent to each of the electrodes;
The hot cathode fluorescent lamp, wherein the emitter is held by the holding member and the electrode.   The hot cathode fluorescent lamp according to claim 1, wherein the insulating material is ceramic. Each of the holding members is formed in a cup shape, and the openings are arranged so as to face each other,
The hot cathode fluorescent lamp according to claim 1, wherein the electrode is disposed inside each holding member, and the emitter is filled in each holding member.   The hot cathode fluorescent lamp according to any one of claims 1 to 3, wherein the electrode is disposed to be engaged with each holding member.