KR20070104248A - Cold cathode discharge lamp - Google Patents

Abstract

A cold cathode discharge lamp is provided to form a current conducting layer on external circumferences and sectional surfaces of both ends of a lamp glass tube by using a solder dipping method. A discharge medium is inserted into an internal discharge space of a lamp glass tube(1). Electrodes(2) are installed at both ends of the lamp glass tube. One end of a feeding lead line(3) is connected to the electrodes. The other end of the feeding lead line is protruded from each of the ends of the lamp glass tube. A current conducting layer(6) is formed on external circumferences and sectional surfaces of both ends of the lamp glass tube by using a solder dipping method. The feeding lead line protruded from each of the ends of the lamp glass tube is bent along the sectional surface of the lamp glass tube.

Description

Cold Cathode Discharge Lamp {COLD CATHODE DISCHARGE LAMP}

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a partial front view of the vicinity of a lamp shaft end of a cold cathode discharge lamp of a first embodiment of the present invention.

Fig. 2 is a partial front view of the vicinity of the lamp shaft end of the cold cathode discharge lamp of the second embodiment of the present invention.

3 is a partial front view near the lamp shaft end of the conventional cold cathode discharge lamp.

<Explanation of symbols for main parts of the drawings>

1: lamp glass tube

2: electrode

3, 3A: Lead wire for power supply

6: current conductor layer

[Document 1] Japanese Unexamined Patent Application Publication No. 9-17329

The present invention relates to a cold cathode discharge lamp.

Conventionally, a cold cathode discharge lamp is widely adopted as a light source of a backlight device of a liquid crystal display device. In this cold cathode discharge lamp, a phosphor layer is generally formed on an inner wall of a lamp glass tube, a discharge medium is sealed in an internal discharge space, and electrodes are provided inside both ends of the lamp glass tube, and one end is connected to each electrode. The other end of the lead wire for power supply is configured to be led out from each end of the lamp glass tube.

As a structure of the power supply part of such a cold cathode discharge lamp, the thing of the structure described in Unexamined-Japanese-Patent No. 9-17329 (patent document 1) is known. In this conventional cold cathode discharge lamp, as shown in Fig. 3, electrodes 2 are provided inside both ends of a lamp glass tube 1 in which a discharge medium is sealed in an internal discharge space, and the electrodes 2 The other end of the lead wire for power supply 3 to which one end is connected is led outward from the end of the lamp glass tube 1. Then, a conductor cap or an inlet member 4 is mounted on the outer surface of the end portion of the lamp glass tube 1, and the inlet member 4 is electrically connected to the outer end of the lead wire 3 for feeding and the solder 5. You are connected. This cap or inlet member 5 is provided for connecting the lead wire from the inverter on the backlight unit side when the cold cathode discharge lamp is mounted on the backlight unit and turned on.

By the way, in the conventional cold cathode discharge lamp, as mentioned above, in order to supply electric power from an inverter power supply, the cap or inlet member 5 is provided in the edge part of the lamp glass tube 1, and therefore, in the manufacturing process, the lamp The process of manufacturing a cap or inlet member 5 as a member separate from a glass tube, and attaching it to the edge part of the lamp glass tube 1 is required, and manufacturing cost of the cap or inlet member 5 is expensive. As a result, there is a problem that the manufacturing cost of the cold cathode discharge lamp also increases.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems of the prior art, and can form a current conductor layer at the end of a lamp glass tube at a low cost, and furthermore, a cold cathode discharge capable of reducing the manufacturing cost of a lamp. It is an object to provide a lamp.

According to the present invention, a discharge medium is sealed in an internal discharge space of a lamp glass tube, electrodes are provided inside both ends of the lamp glass tube, and the other end of the feeder lead wire having one end connected to each of the electrodes is connected to the lamp glass tube. It is a cold-cathode discharge lamp guide | induced to the outside from each edge part of it, It is characterized by the current conductor layer by solder dipping being formed in the outer peripheral surface and end surface of the both ends of the said lamp glass tube.

Further, in the present invention, the lead wire for feeding guided out from the end of the lamp glass tube is bent along the end surface of the lamp glass tube.

Moreover, in this invention, the dimension of the bending part of the said lead wire for power supply is characterized by being within the radius of the said end surface of the lamp glass tube.

The solder for forming the current conductor layer is formed by adding any one of tin, an alloy of tin and indium, and an alloy of tin and bismuth as a main component, and adding at least one kind of antimony, zinc, and aluminum. .

The front end portions of the pair of electrodes provided on both ends of the lamp glass tube facing each other are arranged so as to be positioned at the lamp center side rather than the position of the lamp center side tip portion of the current conductor layer.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described in detail based on drawing.

(1st embodiment)

1 shows a cold cathode discharge lamp according to a first embodiment of the present invention, in which a discharge medium is sealed in an internal discharge space of a lamp glass tube 1, and an electrode ( 2) is provided, and the other end of the lead wire for power supply 3, one end of which is connected to each of the electrodes 2, is led out from the end of the lamp glass tube 1 to the outside. Then, the current conductor layer 6 is formed on the outer peripheral surface and the end surface of the lamp glass tube 1 by the solder dipping on the outer exposed end of the lead wire 3 for power supply. In addition, although the phosphor layer and the protective layer are formed in the inner wall surface of the lamp glass tube 1, it is not shown in figure.

The solder of the current conductor layer 6 is made of any one of tin, an alloy of tin and indium, and an alloy of tin and bismuth, and at least one of antimony, zinc, and aluminum is added.

In the cold cathode discharge lamp having the above-described configuration, the tips of the opposite sides of each of the electrodes 2 are set to a position which is directed toward the lamp center rather than the position of the tips of the current conductor layer 6. This is to avoid the discharge delay between the electrodes 2.

The cold cathode discharge lamp of this embodiment is used as a light source of a backlight unit. When used in a backlight unit, the current conductor layers 6 at both ends of the cold cathode discharge lamp are mounted in a socket for power supply or a clip for power supply on the backlight unit side to discharge the AC power by supplying AC power from the inverter power source. . In this case, it is preferable to feed a high frequency alternating current of 100 kW or less from the inverter power supply.

According to the cold cathode discharge lamp of the present embodiment, since the current conductor layer 6 is formed on the outer surface and both end surfaces of the lamp glass tube 1 by solder dipping, the current conductor layer 6 is Forming cost can be reduced significantly compared with the case where a cap or an inlet member is manufactured as a separate component, and it attaches to the edge part of the lamp glass tube 1, and also the reduction of manufacturing cost of a lamp can be aimed at.

(2nd embodiment)

Fig. 2 shows a cold cathode discharge lamp of a second embodiment of the present invention, in which a discharge medium is sealed in an internal discharge space of a lamp glass tube 1, and an electrode ( 2) is provided, and the other end of the lead wire for power supply 3A having one end connected to each of the electrodes 2 is led out from the end of the lamp glass tube 1 to the outside. The outer exposed end of the lead wire 3A for power feeding is bent in parallel with the end face of the lamp glass tube 1. However, the dimension of the bent portion of the lead wire 3A for power feeding is equal to or smaller than the radius R of the lamp end surface. The current conductor layer 6 is formed by solder dipping on the outer circumferential surface and the end surface of both end portions of the lamp glass tube 1 and the outer exposed curved end of the lead wire 3A for power supply.

Moreover, also in this embodiment, although the phosphor layer and the protective layer are formed in the inner wall surface of the lamp glass tube 1, it is not shown in figure. Also in the present embodiment, the solder of the current conductor layer 6 is composed of any one of tin, an alloy of tin and indium, and an alloy of tin and bismuth, and at least one of antimony, zinc, and aluminum. It is added.

Also in the cold cathode discharge lamp of this embodiment, each tip portion of both electrodes 2 facing each other is set to a position which is directed toward the lamp center side rather than the position of the tip portion of the current conductor layer 6. By configuring in this way, discharge delay can be prevented. That is, when the cold cathode discharge lamp is turned on, electrons due to photoelectrons or the like present in the vicinity of the electrodes become the type of discharge initiation, and when the high frequency voltage is applied between the both electrodes, they are instantaneously discharged between the two electrodes. The furnace is formed. As the seed electron of such discharge start, the electron beam coming to the discharge lamp from the outside (space) of the cold cathode discharge lamp can also be a seed electron, so that the front end of the internal electrode is exposed from the current conductor layer 6. By doing so, the seed electrons can be reached in the vicinity of the electrode, so that the discharge can be started quickly.

The cold cathode discharge lamp of this embodiment is also used as a light source of the backlight unit. Thus, when used in the backlight unit, the electric current conductor layer 6 at both ends of the cold cathode discharge lamp is mounted in the socket for power supply or the clip for power supply on the backlight unit side, and the electric power is supplied from the inverter power supply to discharge the discharge. Let's do it. Also in this case, it is preferable to feed a high frequency alternating current of 100 kW or less from the inverter power supply.

According to the cold cathode discharge lamp of the present embodiment, since the current conductor layer 6 is formed on the outer surface and both end surfaces of the lamp glass tube 1 by solder dipping, the manufacturing cost of the lamp is the same as in the first embodiment. Reduction can be aimed at. In the present embodiment, the outer exposed end of the lead wire 3A for the internal electrode 2 is bent, and the current conductor layer 6 is also formed by solder dipping on the outer exposed end. The current path from the conductor layer 6 to the electrode 2 inside the lamp glass tube 1 can be strengthened and widened, which greatly reduces the possibility of poor contact when mounted on the backlight unit. Can be lowered. In addition, by setting the tip portion of the bent portion of the feeder lead wire 3A to a dimension that does not protrude outward from the outer periphery of the lamp, the tip portion is not disturbed when attached to the socket for the feeder or the feeder clip on the backlight unit side, There is an advantage that the mounting operation can be performed smoothly.

According to the present invention, since the current conductor layer is formed at the end of the lamp glass tube by solder dipping, the cost of forming the current conductor layer is a separate component, and a cap or inlet member is manufactured and attached to the end of the lamp glass tube. Compared with the above, it is possible to considerably reduce, and furthermore, the manufacturing cost of the lamp can be reduced.

Claims (8)

A discharge medium is enclosed in an internal discharge space of the lamp glass tube, electrodes are provided inside both ends of the lamp glass tube, and the other ends of the power supply lead wires having one end connected to each of the electrodes from each end of the lamp glass tube. A cold cathode discharge lamp which has been led to the outside, wherein a current conductor layer by solder dipping is formed on the outer circumferential surface and the end surface of both ends of the lamp glass tube. The cold cathode discharge lamp according to claim 1, wherein the lead wire for feeding drawn out from the end of the lamp glass tube is bent along an end surface of the lamp glass tube. The cold cathode discharge lamp of claim 2, wherein a dimension of a bent portion of the lead wire for feeding is within a radius of an end surface of the lamp glass tube. The solder for forming the current conductor layer comprises any one of tin, an alloy of tin and indium, and an alloy of tin and bismuth as a main component. A cold cathode discharge lamp comprising at least one of antimony, zinc, and aluminum. The front end portion of the pair of electrodes provided on both ends of the lamp glass tube facing each other is disposed so as to be positioned at the lamp center side rather than the position of the lamp center side tip portion of the current conductor layer. Cold cathode discharge lamp, characterized in that. 7. The cold cathode discharge lamp according to claim 6, wherein the lead wire for feeding drawn out from the end of the lamp glass tube is bent along an end surface of the lamp glass tube. The cold cathode discharge lamp according to claim 6, wherein a dimension of the bent portion of the lead wire for feeding is within a radius of the end face of the lamp glass tube. The solder for forming the current conductor layer is made of any one of tin, an alloy of tin and indium, and an alloy of tin and bismuth, and at least one of antimony, zinc, and aluminum. A cold cathode discharge lamp comprising one type added thereto.

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