KR20010042052A - Fluorescent lamp - Google Patents

Abstract

A glass tube coated with a phosphor on an inner wall of the metal vapor and a rare gas, a discharge electrode provided at both ends of the glass tube, an electrode lead for supporting the discharge electrode and supplying power to the discharge electrode from outside the tube, and the glass tube And a reflecting plate provided between the tube end encapsulation of the tube end and the discharge electrode.

The reflector is a fluorescent lamp, characterized in that the radiation of the discharge generated in the glass tube and the radiation of the excitation light emitted from the phosphor toward the tube end portion by the radiation, the components of the light reflected inside the glass tube.

Description

Fluorescent Lamp {FLUORESCENT LAMP}

It is a problem to improve the lamp efficiency of the fluorescent lamp used for illumination. Although the lamp efficiency of fluorescent lamps has been improved by the improvement of the quantum efficiency of phosphors and the development of high frequency lighting technology, it is also trying to reach the limit.

The electrode portion of the fluorescent lamp emits a lot of 254 nm radiation that excites the phosphor. 3 is a result of measuring the distribution of 254 nm radiation in the tube axis direction using a germicidal lamp of GL 20. At the same time, the luminance distribution of the fluorescent lamp FL20SSEXD is shown. In this way, a large amount of 254 nm radiation is emitted in the vicinity of the positive and negative electrodes on the left and right sides of the fluorescent lamp (low-pressure mercury discharge lamp).

However, as shown in Fig. 7, the radiation of the electrode portion is emitted in the tube end portion of the 254nm radiation generated in the electrode portion and is not absorbed at the tube end portion and does not contribute to the fluorescence emission. In addition, the fluorescent light emitted from the phosphor coated on the glass tube wall absorbs light toward the tube end in the vicinity of the tube end and does not become the luminous flux of the lamp. The inventor has found this problem.

Improvement of the luminous flux can be expected by efficiently taking out 254 nm radiation or fluorescent emission not contributing to these luminous fluxes from the lamp as the luminous flux of the lamp. Above all, current fluorescent lamps are widely used and their replacement needs are large. Therefore, the purpose of the present invention is to improve lamp efficiency of fluorescent lamps without changing lamp appearance, electrode socket specifications and electrical characteristics.

The present invention relates to a fluorescent lamp that can improve the lamp efficiency.

Fig. 1 is a block diagram of an electrode vicinity of a fluorescent lamp according to the first embodiment of the present invention.

Fig. 2 is a block diagram of the electrode vicinity of the fluorescent lamp according to the second embodiment of the present invention.

3 is a luminance distribution diagram in the tube axis direction of GL 20 and the fluorescent lamp.

Fig. 4 is a block diagram of the electrode vicinity of the fluorescent lamp according to the third embodiment of the present invention.

5 is a flowchart for explaining a method of manufacturing the fluorescent lamp according to the fourth embodiment of the present invention.

6 is a cross-sectional view showing various forms of a portion facing the discharge electrode side in the embodiment of the present invention.

7 is a configuration diagram of a conventional fluorescent lamp.

* Explanation of symbols for the main parts of the drawings

1: phosphor 2: glass tube

3: discharge electrode 4: electrode lead

5: end portion 6: diffuse reflection plate

7: fluorescent plate 50: encapsulation of the tube end

50a: Enclosure main body

50b: portion toward the discharge electrode side of the encapsulation part

An object of the present invention is to provide a fluorescent lamp that can solve such a problem.

The present invention is a glass tube coated with a phosphor on the inner wall and sealed with metal vapor and rare gas, a discharge electrode provided at both ends of the glass tube, an electrode lead for supporting the discharge electrode and supplying power to the discharge electrode from outside the tube; And a reflecting plate provided between the tube end encapsulation portion of the tube end of the glass tube and the discharge electrode.

The reflecting plate is a fluorescent lamp, characterized in that the radiation of the discharge generated in the glass tube and the radiation of the excitation light emitted from the phosphor toward the tube end portion by the radiation reflects the components of the light inside the glass tube.

In addition, the present invention is a glass tube coated with a phosphor on the inner wall and sealed with metal vapor and rare gas, a discharge electrode provided at both ends of the glass tube, and an electrode lead for supporting the discharge electrode and supplying power to the discharge electrode from outside the tube. And a fluorescent plate provided between the tube end enclosing portion of the tube end of the glass tube and the discharge electrode.

The fluorescent plate is a fluorescent lamp that emits light as a component directed to the tube end portion of the radiation generated by the discharge generated in the glass tube, and reflects the component toward the tube end portion of the light generated in the glass tube inside the glass tube.

In addition, the present invention is a glass tube coated with a phosphor on the inner wall, the metal vapor and the rare gas is sealed, the discharge electrode provided on both ends of the glass tube, and the discharge electrode for supporting the discharge electrode from the outside of the tube to supply power to the discharge electrode With electrode leads,

The portion toward the discharge electrode side of the tube end encapsulation portion of the tube end portion of the glass tube is a fluorescent lamp, characterized in that it forms a reflecting surface capable of reflecting the radiation and / or light.

In addition, the present invention is a glass tube coated with a phosphor on the inner wall, the metal vapor and the rare gas is sealed, the discharge electrode provided on both ends of the glass tube, and the discharge electrode for supporting the discharge electrode from the outside of the tube to supply power to the discharge electrode With electrode leads,

A fluorescent lamp is characterized in that a fluorescent material is coated on a portion of the tube end portion of the glass tube facing the discharge electrode side.

The present invention can improve the luminous flux or the luminous flux of the fluorescent lamp with the same electrical characteristics by the above means, thereby improving lamp efficiency.

Best Mode for Carrying Out the Invention Embodiments of the present invention will be described below using the drawings.

(First embodiment)

1 shows a configuration diagram of a first embodiment of the present invention.

In Fig. 1, both tube end portions 5 (only the left side in Fig. 1) of the glass tube 2 coated with the phosphor 1 therein have an encapsulation portion 50 protruding inwardly in manufacturing. The electrode lead 4 is provided through the sealing portion 50 from the outside to the inside of the pipe. The discharge electrode 3 is attached to the inner end of the electrode lead 4. The electrode lead 4 supports the discharge electrode 3 and supplies electric power to the electrode 3 inside the tube from the outside of the tube.

In addition, a diffusion reflecting plate 6 is provided in the electrode lead 4 between the encapsulation part 50 and the discharge electrode 3. Metal vapor and rare gas are enclosed therein to form a fluorescent lamp.

This diffuse reflector 6 has a high reflectance from visible to the ultraviolet wavelength region such as BaSO ₄ or TiO ₃ in a material which is not conductive like glass or ceramic plate and can withstand the high temperature in the manufacture of fluorescent lamps. It consists of apply | coating the material which has a.

The emission of the phosphor 1 reflects the inside of the tube by the radiation generated by the discharge generated in the glass tube 2 and the radiation thereof, but the components of the radiation and the light directed toward the tube end 5 are diffused by the diffuse reflecting plate 6. Reflected inside the glass tube 2 to improve the luminous flux or the luminous flux.

(Second embodiment)

2 shows a configuration of a second embodiment of the present invention.

In Fig. 2, both tube ends 5 (only the left side in Fig. 1) of the glass tube 2 having the phosphor 1 coated therein have an encapsulation portion 50 protruding inwardly in manufacturing. The electrode lead 4 is provided through the sealing portion 50 from the outside to the inside of the pipe. The discharge electrode 3 is attached to the inner end of the electrode lead 4.

The electrode lead 4 supports the discharge electrode 3 and supplies electric power to the electrode 3 inside the tube from the outside of the tube.

Moreover, the fluorescent plate 7 is provided in the electrode lead 4 between the sealing part 50 and the discharge electrode 3. Metal vapor and rare gas are enclosed therein to form a fluorescent lamp.

The fluorescent plate 7 is formed by applying or attaching a phosphor to a material which is not conductive like a glass plate or a ceramic plate, and which can withstand high temperatures in the manufacture of a fluorescent lamp.

The fluorescent plate 7 is made to emit light by ultraviolet radiation which excites phosphors such as 254 nm and 185 nm emitted in the direction of the tube end portion 5 from the discharge of the discharge electrode 3. In addition, although the phosphor 1 applied to the tube wall of the glass tube 2 emits light due to the radiation generated by the discharge generated in the glass tube 2, the component directed toward the tube end 5 during the light emission is transferred from the fluorescent plate 7 to the glass tube. Reflects to the inside to improve the luminous flux or radiant flux.

In fact, a lamp was fabricated by attaching a fluorescent plate 7 coated with the same phosphor for EXD to the electrode lead 4 of the fluorescent lamp of FL20SSEXD. At this time, the fluorescent plate 7 was fixed at a position of 10 to 15 mm in the direction of the tube end portion 5 from the discharge electrode 3.

Lamps with fluorescent plates 7 and lamps (traditional lamps) with no fluorescent lamps (7) were manufactured at the same time, and their characteristics were compared at a lamp power of 18 W. The tube voltage and tube current of the lamp were almost the same, and the luminous flux improved about 2.3% To get the result.

(Third embodiment)

A third embodiment of the present invention will be described. The configuration of the third embodiment is a configuration intentionally different from the phosphor 1 applied to the glass tube 2 and the phosphor applied to the fluorescent plate 7 in the configuration of the second embodiment.

The FL20SSEXD fluorescent lamp shown in the second embodiment is a three-wavelength fluorescent lamp, and three or more kinds of fluorescent materials are applied to the lamp in combination. Therefore, the color of the whole lamp can be easily adjusted by changing the fluorescent substance of the fluorescent plate 7 with respect to the fluorescent lamp of the same combination ratio.

(Example 4)

4 is a fourth embodiment of the present invention. In this embodiment, the part 50b of the tube end part sealing part 50 toward the discharge electrode 3 side of the tube end part 5 has a disk shape. This disk-shaped part 50b becomes larger than the thickness of the main-body part 50a of the sealing part 50. As shown in FIG.

In the embodiment of Fig. 4, the size of the disk-shaped portion 50b is approximately the same as that of the cross section inside the glass tube 2.

On the surface of the disk-shaped portion 50b, the material of the diffuse reflection plate and the material of the fluorescent plate described in the first and second embodiments are formed. This portion 50b enables the improvement of the radiant flux and luminous flux as described in the first and second embodiments.

Next, a method of forming the disk-shaped portion 50b will be described.

In FIG. 5, first, a member for forming the tube end 5 is made. That is to prepare a glass tube 20 is open at both ends (a). Both ends of the glass tube 20 are expanded to a conical shape (b). A thin glass tube 21 and an electrode lead material 22 are inserted into the glass tube 20 (c). One of the glass tubes 20 is brought into contact with a flat die 23 (a through hole is present in the center thereof, and the tip of the electrode lead material 22 is avoided therein), and the center of the glass tube 20 is brought into contact with the flat die 23. While pressing the other mold 24 tightly, the center of the glass tube 20 is tightened and fused to the thin glass tube 21. At that time, the tip portion of the thin glass tube 21 is sealed and air is sent from the other end, so that a hole 25 is formed in the horizontal portion. As a result, the disk-shaped surface 26 is formed in the part which contacted the mold 23. Thereafter, a discharge electrode is attached to the tip of the electrode lead 22.

The discharge electrode 3 is inserted into the end of the glass tube of the fluorescent lamp, in which the member for forming the tube end portion 5 thus formed is separately prepared and fused. This completes the fluorescent lamp of the fourth embodiment.

In addition, various shapes of the disk-shaped portion 26 can be obtained by varying the shapes of the mold 23.

The shape of the reflecting plate, the fluorescent plate, and the discharge electrode side of the present invention is not limited to the shape described in the embodiments, and may be various shapes as shown in FIG. 6, that is, the radiation or light properties directed to the tube end 5. What is necessary is just to be able to prevent powder to be made to be directed to the pipe end part 5 as it is.

(A) of FIG. 6 is a type in which many protrusions were formed in the surface, (b) is a type in which many unevenness | corrugation was formed, and (c) is a groove-shaped type.

According to the invention as described above, the luminous flux of the fluorescent lamp can be improved with the same electrical characteristics as in the prior art, and the lamp efficiency is improved.

Claims (11)

A glass tube coated with a phosphor on an inner wall of the metal vapor and a rare gas, a discharge electrode provided at both ends of the glass tube, an electrode lead for supporting the discharge electrode and supplying power to the discharge electrode from outside the tube, and the glass tube And a reflecting plate provided between the tube end encapsulation of the tube end and the discharge electrode. The reflector is a fluorescent lamp, characterized in that the radiation of the discharge generated in the glass tube and the radiation of the excitation light emitted from the phosphor toward the tube end portion by the radiation, the components of the light reflected inside the glass tube. A glass tube coated with a phosphor on an inner wall of the metal vapor and a rare gas, a discharge electrode provided at both ends of the glass tube, an electrode lead for supporting the discharge electrode and supplying power to the discharge electrode from outside the tube, and the glass tube And a fluorescent plate provided between the tube end encapsulation of the tube end and the discharge electrode. And the fluorescent plate emits light as a component directed to the tube end portion of the radiation generated by the discharge generated in the glass tube, and reflects a component toward the tube end portion of the light generated in the glass tube to the inside of the glass tube. The method according to claim 1 or 2, And the fluorescent plate has a different kind of phosphor material from the phosphor material applied inside the glass tube. The method according to claim 1 or 2, The fluorescent plate has a fluorescent material of the same kind as the fluorescent material applied to the inside of the glass tube. The method of claim 1, The reflective plate or the fluorescent plate has a conical or dome shape or a plurality of protrusions and protrusions formed on the surface thereof, or the surface of which is formed such that its axis substantially coincides with the tube axis of the glass tube. Fluorescent lamp. A glass tube coated with a phosphor on an inner wall of the metal vapor and a rare gas, a discharge electrode provided at both ends of the glass tube, and an electrode lead for supporting the discharge electrode and supplying power to the discharge electrode from outside the tube; And the portion of the tube end portion of the glass tube facing the discharge electrode side forms a reflecting surface capable of reflecting the radiation and / or light. A glass tube coated with a phosphor on an inner wall and enclosed with metal vapor and a rare gas, a discharge electrode provided at both ends of the glass tube, an electrode lead for supporting the discharge electrode and supplying power to the discharge electrode from outside the tube; , A fluorescent lamp is characterized in that a fluorescent material is coated on a portion of the tube end portion of the glass tube facing the discharge electrode side. The method according to claim 6 or 7, And the portion directed toward the discharge electrode side of the tube end encapsulation part has a disk shape larger than the thickness of the main body part of the tube end encapsulation part. The method according to claim 6 or 7, And the portion facing the discharge electrode side of the tube end encapsulation part has a disk shape having substantially the same size as that of the inner longitudinal section of the glass tube. The method according to any one of claims 6 to 9, The shape of the portion toward the discharge electrode side of the tube end encapsulation portion of the glass tube is formed in a conical or dome shape or a plurality of irregularities formed on the surface thereof so that its axis substantially coincides with the tube axis of the glass tube, Fluorescent lamp, characterized in that the projection is formed. The method according to claim 6 or 7, And a portion of the tube end encapsulation portion directed toward the discharge electrode forms a disk shape having a size smaller than that of the inner longitudinal section of the glass tube.