JPH09199082A - Discharge lamp for display and manufacture thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a discharge lamp for display and a manufacturing method for the lamp by which assembly work of the discharge lamp for display is carried out efficiently without deteriorating the luminance of a light emitting part by simplifying the structure. SOLUTION: A discharge lamp for display is provided with a U-shaped glass bulb 2 having a first and a second liner tubular parts 2a, 2b with different length, a light emitting layer 3 formed in the inner face of the glass bulb 2 and consisting of one or a plurality of phosphor bodies, a first and a second electrodes 4, 5 installed in the respective end parts of the glass bulb 2, and a rare gas sealed in the interior of the glass bulb 2 and manufacturing work of the discharge lamp for display is made easy by staggering the edge portions of the first and the second liner tubular parts 2a, 2b each other and the assembly work of the lamp is carried out efficiently.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display discharge lamp and a method for manufacturing the same, and more particularly to an improvement in a display discharge lamp used as a display element for a large color display device and a method for manufacturing the same.

[0002]

2. Description of the Related Art Conventionally, this type of display discharge lamp is constructed, for example, as shown in FIGS.
105454). In the figure, A is a first envelope, which is composed of, for example, a cylindrical envelope body B made of ceramics and a transparent glass plate,
And a Y-shaped partition member D that integrally extends from the envelope body B and divides the internal space into three independent spaces. Each of the three partitioned spaces of the first envelope A has three first spaces.
The electrodes Ea, Eb, Ec of are arranged. A light emitting layer that emits light in the blue region, the green region, and the red region is formed on the inner surface of the envelope body B corresponding to the three partitioned spaces. A second envelope F made of glass is hermetically sealed in the central portion on the back side of the envelope body B. The second envelope F has a second electrode G formed of a hot cathode built therein, and the first electrodes Ea, E
A discharge path is formed between b and Ec through openings Ba, Bb, and Bc formed in the central portion of the envelope body B.

Thousands and tens of thousands of the display discharge lamps are arranged in alignment on a display board such as a baseball field or an advertising tower, and the second electrode G and the first electrodes Ea, Eb, Ec are arranged. A discharge is selectively generated between the two. As a result, the light emitting layer in the space where the discharge is generated emits light, and the sealing member C emits light of a predetermined color. Therefore, by creating a discharge between each electrode depending on the display content,
The desired display can be realized.

By the way, this display discharge lamp is relatively bright and high in brightness because it is a mixture gas of an inert gas such as argon and mercury vapor as a discharge gas. Even when applied to display devices,
Although it has a feature that good visibility can be obtained, the image quality of the display surface tends to be deteriorated when the apparatus is started up because the brightness and the brightness are easily changed depending on the outside air temperature. In addition, the second envelope F on the back side of the first envelope A
However, there is a problem in that the structure is complicated because it is hermetically sealed.

[0005]

Therefore, the applicant of the present invention is
In view of such a point, the display discharge lamp shown in FIG. 12 was previously proposed. This display discharge lamp is configured as follows. That is, in the figure, H is an envelope, and is composed of a cylindrical envelope body HA made of, for example, a glass member or a ceramic member, and a glass member sealed at one end of the envelope body HA. First sealing member HB as a light emitting portion
And a second sealing member HC made of a glass member or a ceramic member, which is sealed to the other end of the envelope body HA. In particular, the second sealing member HC has a stepped portion HCa at the upper edge thereof, first and second lead insertion holes HCb and HCc spaced apart by a predetermined distance from the upper surface portion, and a second lead member. The recess HCd is formed on the upper edge of the insertion hole HCc.
The exhaust pipe HCe is provided between the second lead insertion holes HCb and HCc.
Are formed and arranged respectively. The enclosure body HA
Sealing of the first and second sealing members HB and HC to the open ends of is performed using a sealing member such as low melting point glass. Then, on the inner surface of the envelope body HA, a light reflecting layer J of silver, aluminum or the like and a light emitting layer K formed by mixing a single or a plurality of phosphors are sequentially laminated.

On the other hand, the first and second sealing members HC are
Electrodes L and M are arranged at a fixed distance from each other, and leads La and Ma extending from the electrodes are inserted into the first and second lead insertion holes HCb and HCc and then the sealing member. It is sealed by using such as. The first and second electrodes L and M
Is configured as a cold cathode. Further, the lower end of a cylindrical partition member N made of, for example, a glass member is inserted into the recess HCd of the second sealing member HC so as to be substantially perpendicular to the first sealing member HB. It is sealed by using such as. A light emitting layer K is formed on the inner surface of the partition member N. In particular, a predetermined amount of rare gas containing xenon gas is enclosed inside the envelope H. However, metal vapor such as mercury is not enclosed.

According to this proposal, the main portion of the discharge path formed between the electrodes L and M is substantially perpendicular to the first sealing member HB as the light emitting portion due to the presence of the cylindrical partition member. Since the light is generated in the direction, the light generated by the discharge is densified in the envelope body and the partition member, and the brightness on the first sealing member side is formed on the inner surface of the envelope body. In combination with the light reflecting action of the light reflecting layer, it can be effectively increased.

Moreover, since the envelope H contains no metal vapor such as mercury in addition to the rare gas, the brightness and the luminance are not easily influenced by the outside air temperature and are relatively stable. Light is obtained, and when it is applied to, for example, a large-sized color display device, an excellent effect such as improvement of image quality of a display screen can be achieved.

However, although this display discharge lamp has a simplified structure, it has a large number of parts and
The first sealing member HB is sealed to the enclosure main body HA, and the envelope main body HA and the pair of electrodes L and M are attached to the second sealing member HC.
In addition, since the partition member N must be sealed, the manufacturing work becomes complicated, and there are many technical problems to be overcome in mass production.

Therefore, an object of the present invention is to provide a display discharge lamp capable of efficiently performing an assembly work of a display discharge lamp device by simplifying the structure without impairing the brightness of a light emitting portion, and a manufacturing method thereof. To provide.

[0011]

Therefore, in order to achieve the above object, the present invention provides a U-shaped glass bulb having first and second straight pipe portions having different lengths, and a glass bulb of the glass bulb. A light emitting layer made of one or more phosphors formed on the inner surface, first and second electrodes arranged at respective ends of the glass bulb, and a rare gas sealed inside the glass bulb, A second invention of the present invention is configured such that the ends of the first and second straight pipe portions are staggered from each other, and the electrode is configured of a cold cathode type. Is characterized in that the rare gas contains xenon gas as a main component.

A fourth invention of the present invention is a step of disposing the first electrode in a straight tubular glass bulb having a light emitting layer on a predetermined portion of the inner surface thereof and temporarily fixing it to the glass bulb; A step of heating the portion to be bent and bending it so that the first and second straight pipe portions having different lengths are formed, and a step of filling a rare gas into the glass bulb after exhaustion, And a step of sealing the temporarily fixed portion of the first electrode after sealing the gas. The fifth invention is characterized in that, prior to temporarily fixing the first electrode to the glass bulb, The sixth invention is characterized in that the second electrode is arranged and sealed at the end portion, and the sixth invention is that the second electrode is arranged at the end portion of the glass bulb after the first electrode is temporarily fixed to the glass bulb. It is characterized by being sealed.

Further, according to a seventh aspect of the present invention, the second electrode is arranged and sealed at one end of a straight tubular glass bulb having a light emitting layer on a predetermined portion of the inner surface thereof, and at the same time, the second electrode is sealed. The step of placing the first electrode in the glass bulb separated from the electrode by a predetermined distance and temporarily fixing it to the glass bulb, and heating the bent portion of the glass bulb to change the length of the first and second electrodes.
A step of bending so as to form a second straight pipe part, and a step of filling a rare gas in the glass bulb after the evacuation is completed,
A step of sealing the other end of the glass bulb, and a step of sealing the temporarily fixed portion of the first electrode and fusing and removing an unnecessary portion of the glass bulb after the sealing. To do.

[0014]

BEST MODE FOR CARRYING OUT THE INVENTION Next, one embodiment of the present invention will be described with reference to FIG. In the figure, 1 is a display discharge lamp, for example, lead glass including low lead glass,
It consists of Douglas, boro / silicate glass, hard glass, etc.,
And the glass bulb 2 having the first and second straight pipe portions 2a, 2b having different lengths and the bent portion 2c connecting the straight pipe portions 2a, 2b, and the inner surface of the glass bulb 2, for example, a blue region, A light emitting layer 3 formed by appropriately mixing single or a plurality of phosphors that emit light in a green region and a red region, and first and second electrodes 4, 5 arranged at the end of the glass bulb 2.
And the xenon (X
e), krypton (Kr), helium (He), neon (Ne), argon (Ar), or a rare gas mixed appropriately.

The above-mentioned first and second electrodes 4 and 5 are of a cold cathode type and are made of metal wires such as nickel.
It is constructed by welding a metal sleeve such as nickel to the lead, welding it, winding a nickel ribbon in a spiral shape, or forming and sintering a metal powder into a columnar shape. ing. Lead-out leads 4a and 5a are extended from the first and second electrodes 4 and 5, and glass beads 4b and 5b are sealed at the portions to be sealed.
The glass beads 4b and 5b are used to hermetically seal the glass bulb 2. The ends of the first and second straight pipe portions 2a and 2b are staggered from each other.

The discharge lamp 1 is manufactured, for example, as shown in FIG. First, as shown in FIGS. 1A and 1B, a second electrode 5 is arranged at one end of a straight tubular glass bulb 2 having a light emitting layer 3 on a predetermined portion of the inner surface thereof, and the glass bulb 2 and the glass bead 5b are connected to each other. Seal by heating. Then, the first electrode 4 is inserted and arranged at a predetermined portion in the glass bulb, and the glass bulb 2 corresponding to the glass bead 4b is formed.
By heating a part 2A of the glass beads 4b
And the glass bulb 2 are partially fused. As a result, the first electrode 4 is temporarily fixed to the glass bulb 2. Next, as shown in FIG. 6C, after heating and softening the glass bulb portion of the planned bending portion (2c) between the first and second electrodes 4 and 5, the glass bulb 2 is bent into a U shape. To achieve. As a result, the length of the first straight pipe portion 2a from the glass bead 4b to the curved portion 2c is longer than the length of the second straight pipe portion 2b from the glass bead 5b to the curved portion 2c. . Then, the other end of the bending valve 2 (on the side of the first electrode 4) is connected to the exhaust device EX. Then, after performing a predetermined exhaust treatment, an electrode activation treatment, and the like, a predetermined amount of a rare gas such as xenon gas is sealed in the glass bulb. Next, as shown in FIG. 3D, the glass bulb 2 portion near the exhaust device EX is chipped off. Then, as shown in FIG. 7e, the temporary fixing portion (2A) is heated to hermetically seal the glass bulb 2 to the glass bead 4b, and the unnecessary glass bulb is melted and cut. The manufacture of the display discharge lamp 1 is completed.

The display discharge lamp 1 is used as a display discharge lamp device by being housed in an envelope 6 as shown in FIG. 3, for example. Here, the envelope 6 is a tubular outer member formed of, for example, a resin member such as an acrylic resin or a polycarbonate resin, a ceramic member, a glass member such as boro-silicate glass, hard glass, or soda glass. The enclosure main body 7 and the sealing member 8 as a light emitting portion made of a resin member or a glass member integrated with one opening of the envelope main body 7 are configured. A light-reflecting layer 9 made of silver, aluminum, or the like is formed on the inner surface of the envelope 6, particularly the inner surface of the envelope body 7. The U-shaped discharge lamp 1 is housed and arranged inside the envelope 6 so that the main part of the discharge path is substantially perpendicular to the sealing member 8 as the light emitting portion. , And is supported by a supporting means 10 made of an insulating member such as silicone resin. Particularly, the supporting means 10 is filled in the opening 6a of the envelope 6 so as to close the opening, whereby the discharge lamp 1 is fixed to the envelope body 7 via the supporting means 10. It A hole 11 for absorbing the pressure fluctuation in the envelope is formed in a part of the supporting means 10, but it can be omitted if the pressure fluctuation is small. The supporting means 10 is preferably an adhesive member such as hot melt, but any insulating member can be used as long as it has a function of supporting the discharge lamp 1.

According to this embodiment, the ends of the discharge lamp 1 are staggered, so that when the first electrode 4 side is sealed, the burner flame is exposed to the first flame. 2 does not hit the end of the glass bulb on the electrode 5 side. Therefore, the glass crack defect at the glass bulb end portion on the second electrode 5 side due to the sealing on the first electrode 4 side can be completely eliminated.

Moreover, since the discharge lamp 5 contains no metal vapor such as mercury other than the rare gas, the brightness and the luminance are hardly affected by the outside air temperature, and a relatively stable light is emitted. discharge. Therefore, when it is applied to, for example, a large color display device, the image quality of the display screen can be improved.

Further, the discharge lamp 1 is formed in a U-shape and is miniaturized. Therefore, the main portion of the discharge path inside the envelope 6 is in a direction substantially perpendicular to the light emitting portion (8). Therefore, the display discharge lamp device can be assembled by a simple operation of simply storing the display discharge lamp device. Therefore, the manufacturing work is simplified and the application to the mass production line becomes easy.

In particular, since the U-shaped discharge lamp 1 is housed inside the envelope 6 so that the main part of the discharge path is substantially perpendicular to the light emitting portion (8), it is made of glass. The light densified in the straight tube portion of the bulb is further densified together with the light reflecting action of the light reflecting layer 9 and is emitted from the light emitting portion to the outside. Therefore, the brightness in the light emitting portion can be increased.

Moreover, since the discharge lamp 1 is fixed by the supporting means 10 inside the envelope, it is possible to prevent damage due to collision with the inner wall of the envelope 6 even if vibration or the like is applied. Therefore, it can be applied to, for example, a large color display device.

Furthermore, since the opening 6a of the envelope 6 is sealed by the supporting means 10 such as an insulating member, the inside of the envelope can be reduced in pollution. Therefore, it is possible to prevent a decrease in brightness due to contamination. However, since the support means 10 has a small hole 11,
Even if a pressure fluctuation occurs in the envelope, it is automatically adjusted through the hole 11 and the envelope and the discharge lamp are not damaged.

FIG. 4 shows a second application example of the discharge lamp 1 according to the present invention to a display discharge lamp device, which is basically the same as the display discharge lamp device shown in FIG. is there. The different point is that a sealing member as a light emitting portion that closes one opening of the envelope body 7 is provided with a lens body 8A having a light collecting function.
It has been changed to. According to this embodiment, since the light is condensed by the lens body 8A, the brightness can be dramatically increased.

FIG. 5 shows a third application example of the discharge lamp 1 according to the present invention to a display discharge lamp device, which is basically the same as the display discharge lamp device shown in FIG. is there. The difference is that the sealing member 8B as the light emitting portion is different from the enclosure body 7
And a disk-shaped component that is a separate component, and is fixed to the opening of the envelope body 7. In particular, when the envelope body 7 and the sealing member 8B are made of glass members, they are sealed with a low-melting glass, and when they are made of resin members, they are sealed with an adhesive or the like. To be done.

FIG. 6 shows a fourth application example of the discharge lamp 1 according to the present invention to a display discharge lamp device, which is basically the same as the display discharge lamp device shown in FIG. is there. The different point is that the sealing member as the light emitting portion is constituted by the lens body 8C which is a separate component from the envelope body 7, and is fixed to the opening portion of the envelope body 7. In particular, the enclosure body 7
When the sealing member 8C is made of a glass member, it is sealed with a low melting point glass or the like, and when it is made of a resin member, it is sealed with an adhesive or the like. According to this embodiment, it is possible to deal with the design change of only the lens body 8C according to the required light emission direction and brightness, so that the facility cost can be reduced.

FIG. 7 shows a fifth application example of the discharge lamp 1 according to the present invention to a display discharge lamp device, which is basically the same as the display discharge lamp device shown in FIG. is there. The different point is that the lens body 8C is attached to the outer surface of the sealing member 8. According to this embodiment, it suffices to mount the lens body 8C according to the required light emission direction and brightness,
A quick response is possible.

FIG. 8 shows a sixth application example of the discharge lamp 1 according to the present invention to a display discharge lamp device, which is basically the same as the display discharge lamp device shown in FIG. is there. The difference is that the lens body 8D having a plurality of convex lens groups is closely attached to the outer surface side of the sealing member 8. According to this embodiment, the same effect as that of the fifth application example can be expected.

FIG. 9 shows a seventh application example of the discharge lamp 1 according to the present invention to a display discharge lamp device, which is basically the same as the display discharge lamp device shown in FIG. is there. The different point is that a parabolic light reflection layer (reflection plate) 12 is arranged on the opening 6a side of the envelope 6 and on the end side of the discharge lamp 1. According to this embodiment, the light emitted from the discharge lamp 1 can be more effectively emitted from the light emitting portion (8), and the brightness can be further improved.

The present invention is not limited to the above-mentioned embodiment at all. For example, the sealing of the first and second electrodes to the glass bulb is performed by interposing a glass bead provided on the lead. The glass bulb can be directly sealed to the lead or the lead for sealing can be used.
Further, the second electrode can be sealed at the end of the glass bulb after temporarily fixing the first electrode to the glass bulb. Further, in the application example to the display discharge lamp device, the shape of the envelope may be a cylindrical shape, a square tube shape, a triangular shape or the like, and a light reflection layer may be formed on the outer surface thereof. Alternatively, the light reflecting layer on the inner surface or the outer surface may be omitted.
Furthermore, the structures and materials of the respective embodiments can be appropriately replaced or combined.

[0031]

Next, an experimental example will be described. First, a sealing member made of soda glass having an outer diameter of 6 mm and a plate thickness of 1 mm was attached to a frit glass (sealing member) at one end opening of an envelope body made of soda glass having an outer diameter of 6 mm and a length of 19 mm. ), And aluminum is vapor-deposited on the inner surface of the envelope body to form a light-reflecting layer. On the other hand, the outer diameter is 2 mm,
A terbium-activated yttrium silicate phosphor (Y ₂ which emits light in the green region) on a predetermined inner surface of a glass bulb made of lead glass having a length of 80 mm. SiO ₅ : Tb) to form a light emitting layer. Hereinafter, a U-shaped discharge lamp is manufactured according to the method shown in FIG. In this discharge lamp, the straight pipe portions are bent alternately, the length of the first straight pipe portion is 18 mm, the bending width is 5 mm, and the filling pressure of xenon gas is 90 Torr. Is. After that,
The discharge lamp is housed in the envelope so that the first and second straight pipe parts (the main part of the discharge path) are substantially perpendicular to the light emitting part, and the opening is made of silicon hot melt. (Supporting means)
The discharge lamp device for display shown in FIG. 3 is completed by sealing at.

Between the electrodes of this discharge lamp, 1000
When a DC voltage of V was applied and the luminance on the sealing member (light emitting portion) side was measured, it was 6000 cd / m ² . This is almost the same as the discharge lamp device shown in FIG. 12 having substantially the same size. Further, when the lens body shown in FIG. 6 was brought into close contact with the sealing member, the front surface brightness was tripled.

When the discharge lamp device was placed in a constant temperature bath and the ambient temperature was changed in the range of 0 to 30 ° C. and the change in luminance was measured, no large change was found.

[0034]

As described above, according to the present invention, the first straight pipe portion is set to be longer than the second straight pipe portion, and the respective end portions are formed in a staggered shape. When sealing the first electrode side, the flame of the burner does not hit the end of the glass bulb on the second electrode side. Therefore, the glass crack defect at the end of the glass bulb on the second electrode side due to the sealing on the first electrode side can be completely eliminated, and the manufacturing operation becomes easy.

In addition, since this discharge lamp contains no metal vapor such as mercury at all, other than rare gas, the brightness and luminance are hardly affected by the outside temperature, and relatively stable light is emitted. To do. Therefore, when it is applied to, for example, a large color display device, the image quality of the display screen can be improved.

Further, since this discharge lamp is formed in a U shape and is miniaturized, the main part of the discharge path is merely inside the envelope so as to be substantially perpendicular to the light emitting portion. The display discharge lamp device can be assembled by a simple operation of storing it. Therefore, the manufacturing work is simplified and the application to the mass production line becomes easy.

Moreover, since the discharge lamp is housed inside the envelope so that the main part of the discharge path is in a direction substantially perpendicular to the light emitting part, a high density is achieved in the straight tube part of the glass bulb. The converted light is further densified together with the light reflecting action of the light reflecting layer and is emitted from the light emitting portion to the outside. Therefore, the brightness in the light emitting portion can be increased.

[Brief description of drawings]

FIG. 1 is a side sectional view showing an embodiment of the present invention.

2A and 2B are views for explaining the method of manufacturing the discharge lamp shown in FIG. 1, in which FIG. 2A is a side sectional view in a temporarily sealed state, and FIG. 2B is a horizontal sectional view in FIG. (C) is a side sectional view in a state in which it is bent into a U shape and then connected to an exhaust device, (d) is a side sectional view in a state in which the exhaust device side of the glass bulb is sealed,
(E) is a sectional side view showing a completed state.

FIG. 3 is a side sectional view showing a first application example of the discharge lamp of the present invention to a display discharge lamp device.

FIG. 4 is a side sectional view showing a second application example of the discharge lamp of the present invention to a display discharge lamp device.

FIG. 5 is a side sectional view showing a third application example of the discharge lamp of the present invention to a display discharge lamp device.

FIG. 6 is a side sectional view showing a fourth application example of the discharge lamp of the present invention to a display discharge lamp device.

FIG. 7 is a side sectional view showing a fifth application example of the discharge lamp of the present invention to a display discharge lamp device.

FIG. 8 is a partially cutaway side view showing a sixth application example of the discharge lamp of the present invention to a display discharge lamp device.

FIG. 9 is a side sectional view showing a seventh application example of the discharge lamp of the present invention to a display discharge lamp device.

FIG. 10 is a cross-sectional view of a conventional example.

11 is a sectional view taken along line XX of FIG.

FIG. 12 is a side sectional view showing another conventional example.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 discharge lamp 2 glass bulb 2a 1st straight pipe part 2b 2nd straight pipe part 2c curved part 3 light emitting layer 4,5 1st, 2nd electrode 4a, 5a lead 4b, 5b glass bead 6 Envelope 7 Envelope body 8, 8A, 8B, 8C, 8D Sealing member (light emitting part) 9, 12 Light reflection layer 10 Supporting means 11 hole

Claims (7)

[Claims] 1. A U-shaped glass bulb having first and second straight tube portions having different lengths, a light emitting layer made of one or a plurality of phosphors formed on the inner surface of the glass bulb, and a glass bulb. First and second electrodes arranged at the respective ends of
A discharge lamp for display, comprising: a rare gas sealed inside a glass bulb, wherein the ends of the first and second straight pipe portions are staggered from each other. 2. The display discharge lamp according to claim 1, wherein the electrode is of a cold cathode type. 3. The display discharge lamp according to claim 1, wherein the rare gas contains xenon gas as a main component. 4. A step of disposing the first electrode in a straight glass bulb having a light emitting layer on a predetermined portion of the inner surface thereof, and temporarily fixing the first electrode to the glass bulb, and heating a bent portion of the glass bulb for a long time. Of the first and second straight pipe portions having different heights, a step of filling a rare gas in the glass bulb after exhaustion, and a step of forming the first electrode after filling the rare gas. And a step of sealing the temporarily fixed part of the display discharge lamp. 5. The display discharge lamp according to claim 4, wherein a second electrode is arranged and sealed at an end portion of the glass bulb before the first electrode is temporarily fixed to the glass bulb. Manufacturing method. 6. The display discharge lamp according to claim 4, wherein after temporarily fixing the first electrode to the glass bulb, a second electrode is arranged and sealed at an end portion of the glass bulb. Production method. 7. A glass which has a second electrode arranged and sealed at one end of a straight tube-shaped glass bulb having a light emitting layer on a predetermined portion of the inner surface thereof, and which is separated from the second electrode by a predetermined distance. A step of disposing the first electrode in the bulb and temporarily fixing it to the glass bulb, and heating the bent portion of the glass bulb so that the first and second straight pipe portions having different lengths are formed. The bending step, the step of sealing the rare gas in the glass bulb after the evacuation is finished, the step of sealing the other end of the glass bulb, and the temporary fixing portion of the first electrode after the sealing. And a step of melting and removing an unnecessary portion of the glass bulb together with sealing.