JPH0542108B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial Application Field) The present invention relates to a fluorescent lamp for display, and is a single tube multi-tube lamp suitable for use as a display element in, for example, a guide display device, an electronic display device, or a display. Related to color emitting lamps.

(Prior art) Conventional guidance displays that display text and images outdoors;
As a display element used in an electronic display device, a display, etc., for example, as described in Japanese Utility Model Publication No. 39-22214 and Japanese Utility Model Publication No. 39-22215, the display surface of one tube is divided into three, 2. Description of the Related Art Arc tubes are known that emit three colors of light, red, green, and blue, using the display surface of the same tube. This conventional arc tube has a target having red, green, and blue luminescent material layers in an integrated outer tube, and causes the target to emit light using an electron beam.
It is a CRT.

Furthermore, as described in Japanese Patent Application Laid-open No. 57-1214832, a fluorescent film exhibiting red, green, and blue display colors is formed on the front surface of one tube, which becomes the display surface. A display element is known that has a structure in which counter electrodes for each color are formed on the inner circumferential surface, and a common electrode of an aluminum strip plate that performs electric discharge is formed radially from the center of the counter electrodes for each color.

Furthermore, as described in Japanese Patent Application Laid-Open No. 57-119453, a common cathode of cold cathodes is arranged in the center of the envelope, and a gap extending from the part where this cold cathode is arranged to the entire length in the height direction is provided. A lamp is known in which a light emitting chamber is formed in communication with a light emitting chamber.

(Problems to be Solved by the Invention) In the conventional display elements described in the above-mentioned conventional Japanese Utility Model Publication No. 39-22214 and Japanese Utility Model Publication No. 39-22215, the target cannot be irradiated from the viewpoint of thermal deterioration of the luminescent material. There is a limit to the intensity of the electron beam that can be produced, and as a result, the brightness is about 50% lower than that of a fluorescent discharge lamp using a rare earth phosphor film.Furthermore, a high voltage is required to accelerate the electron beam. This makes the socket larger and more complex, and this socket makes it impossible to place the tube bodies closely together when installing it in a display device, making it difficult to widen the effective light emitting area of the display device. There was a problem that I couldn't solve.

In addition, the display element described in JP-A No. 57-124832 uses electrodes made of aluminum band plates formed in a radial pattern, so if the electrodes were to be constantly preheated, the power consumption would be large due to the large size of the electrodes. This poses a problem that makes it unsuitable for practical use.

Furthermore, the inventors considered using a filament with good startability due to preheating in place of the cold cathode common electrode of the lamp having the structure described in JP-A No. 57-119453, but the area near the filament Because glow discharge occurs, ultraviolet rays leak into the unlit light-emitting chamber due to the spread of the filament glow, which excites the phosphor in the unlit light-emitting chamber, causing undesired light emission. When viewed, a problem arises in that the glow occupies a large area on the display surface.

The present invention has been made in view of the above problems.
By integrating colored fluorescent lamps and reducing the number of lamp sockets, it is possible to improve the mounting density in the display device, and the number of electrodes can also be reduced.Also, while a filament electrode is used as a common electrode, undesired light emission due to filament glow occurs. When looking at the display surface, the ratio of the glow discharge of the common filament electrode to the display surface can be reduced by the electrode chamber, the color display area ratio to the display surface can be widened, and the number of bases and sockets can be reduced. Simplify the structure of
The present invention provides a display fluorescent lamp that is inexpensive to manufacture and easy to install.

(Means for Solving the Problems) The display fluorescent lamp of the present invention includes an envelope in which mercury and an inert gas are sealed and whose front part is a display surface, and this envelope has the following features: A bottomed cylindrical hole is formed on the display surface side of the envelope with an interval sufficient to form an electric discharge between the display surface and the display surface, and extends perpendicularly to the display surface and backward. a common filament electrode having an electrode chamber and housed in the electrode chamber at a predetermined distance from the opening so that a common discharge path is formed in the electrode chamber; A plurality of counter electrodes are disposed around the aperture outside the electrode chamber on the back side and form individual discharges between the common filament electrode and the aperture, and each of the apertures is arranged in the envelope. A plate-shaped partition wall partitions the opposing electrodes perpendicularly to the display surface, and a partition wall is provided for each section of the inner surface of the envelope partitioned by the partition wall, and a partition wall is provided for each portion of the inner surface of the envelope that is partitioned by the partition wall, and is provided to protect against ultraviolet rays generated by the individual discharges. red, green, and blue, which are excited and output colored light to the outside of the display screen.
The device is equipped with a fluorescent film that exhibits different display colors.

(Function) In the display fluorescent lamp of the present invention, when electric power is selectively supplied between the common filament electrode and the counter electrode, discharge occurs between the common filament electrode and the counter electrode individually through the apertures, The display surface faces the fluorescent film and emits red, green, and blue monochrome or mixed colors.

At this time, the common filament electrode produces a filament glow, but the spread of the filament glow of the common filament electrode is regulated by the electrode chamber and the opening, and the filament glow of the common filament electrode can be reduced when looking at the display surface. .

Furthermore, since the common filament electrode is disposed within the electrode chamber at a distance from the opening, a discharge path common to each opposing electrode is formed between the common filament electrode and the opening. Due to the discharge formed in this common discharge path, the atmospheric gas between the common filament electrode and the opening is activated when it is discharged between any opposing electrode and the common filament electrode, and in this state, other opposing electrodes are activated. When transitioning to a discharge between the electrode and the common filament electrode, the discharge starting voltage between the other opposing electrode and the common filament electrode can be lowered.

(Example) The configuration of an example of the present invention will be described with reference to the drawings.

In FIGS. 1 to 4, 1 is a fluorescent lamp, and an envelope 2 is, for example, a cylindrical lower part made of transparent glass and has a stem portion 3 with one end open and the other end closed. The tube part 4 and the upper outer tube part 5 having a flat U-shaped cross section made of transparent glass seal the open end surface of the lower outer tube part 4 and form the display surface 7 on the front part. It is formed from a single cylindrical tube body. The envelope 2 is filled with mercury at a pressure of 0.005 to 0.006 mmHg and an inert gas such as argon gas at a pressure of several mmHg.

Further, in the envelope 2, a bottomed cylindrical electrode chamber 8 having an opening 9 facing the display surface 7 is provided at the center of the outer tube portion 4 on the outer peripheral surface of the lower outer tube portion 4. It is formed by a cylindrical portion 8a provided concentrically with the cylindrical portion 8a.
radially from the outside of the cylindrical portion 8a forming the electrode chamber 8 to the inner peripheral surface of the lower outer tube portion 4 of the envelope 3.
A plate-shaped partition wall 8b is provided to form light emitting chambers 6, 6, 6 which are partitioned vertically to the display surface 7 in a direction forming an angle of 120°. are formed into three sector shapes separated from each other by plate-shaped partition walls 8b.
The cylindrical portion 8a forming the electrode chamber 8 is formed to have a slightly lower height than the plate-shaped partition wall 8b forming the light emitting chambers 6, 6, 6, and the upper end of this plate-shaped partition wall 8b. The rim is formed at a height slightly below the opening edge of the lower outer tube section 4, and the upper end of this cylindrical section 8a is open, allowing each of the light emitting chambers 6 and the electrode chambers 8 to be opened.
The opening 9 is formed to allow communication between the two.

On the inner surface of the upper outer tube part 5 of the envelope 2, red, green, and blue fluorescent films 6 are provided for each light emitting chamber.
R, 6G, and 6B are formed radially from the center of the upper tube portion 5 with equal areas at intervals of 120°. These fluorescent films 6R, 6G, and 6B are preferably made of high-luminance rare earth phosphors, and the fluorescent film 6R exhibiting red color is, for example,
(Y, Eu) ₂ O ₃ , the green fluorescent film 6R is, for example, (Y, Ce, Tb) ₂ SiO ₂ , and the blue fluorescent film 6B is, for example, (Sr, Ca, Eu) ₁₀
(PO4) ₆ C ₂ is used.

In addition, two wells 1 are provided in the electrode chamber 8.
A triangular common filament electrode 1 is connected to 0 and supported by two insulating poles 11.
2 are housed at a predetermined distance from the opening 9 so that a common discharge path is formed.

Further, two wires are provided in the envelope 2, located outside the electrode chamber 8, and arranged in a straight line in each of the light emitting chambers 6, 6, 6, facing each side of the common filament electrode 12. A plurality of opposing electrodes 13, 1 made of filaments are connected and supported by the wells 10.
4, 15 are provided, and each of these opposing electrodes 13, 1
4 and 15 and the common filament electrode 12 through the openings 9, respectively. Further, each of the wells 10 is inserted into the thick portion of the stem portion 3 in an airtight manner and led out.

Next, the electrical connection of the display fluorescent lamp 1 will be explained based on FIG. 5.

The common filament electrode 12 is connected to the common AC power source 2
1, and each opposing electrode 13, 1
4 and 15 are connected to the other pole of the AC power supply 21 via dimmers 22, 23, and 24, respectively. Each of these dimmers 22, 23, 24 adjusts the ballast circuit based on the dimming signal input to the terminals a, b, c, and adjusts the ballast circuit between the common filament electrode 12 and each opposing electrode 13, 14, 15. control the power supplied to the

The common filament electrode 12 and the opposing electrodes 13, 14, 15 are connected to filament transformers 25, 26, respectively, and are preheated.

Next, a method of manufacturing the fluorescent lamp of this embodiment will be explained.

a lower outer tube section 4 having a stem section 3 and a partition wall 8b;
The electrode chamber 8 and the electrode chamber 8 are integrally molded from transparent glass, and two wells 10 are provided at positions corresponding to each of the light emitting chambers 6 and the electrode chambers 8, which are partitioned by the partition wall 8b and the cylindrical portion 8a of the stem portion 3. Two insulating poles 11 are also fixed in the electrode chamber 8 constituted by the cylindrical portion 8a.

Then, both ends of the opposing electrodes 13, 14, 15 of the filament are connected between the tips of the two wells 10 provided in each of the light emitting chambers 6, 6, 6, and the two ends of the two wells 10 provided in the electrode chamber 8 are connected. A triangular common filament electrode 12 supported by an insulating pole 11 between the tips of the wells 10 is connected to both ends thereof.

In addition, red, green, and blue phosphors divided radially into three parts are coated on the inner surface of the display surface 7 of the upper outer tube part 5 formed of transparent glass, and the fluorescent films 6A, 6B, 6
form C.

Next, the upper outer tube part 5 is hermetically welded to the opening edge of the lower outer tube part 4 to form the envelope 2.

Furthermore, after exhausting the air inside the envelope 2 from an exhaust pipe (not shown) provided in the lower outer tube part 4,
Fill with mercury and argon gas and close the exhaust pipe.

Next, the operation of this embodiment will be explained.

Common filament electrode 12 and counter electrode 13,1
For example, when power is selectively supplied between the common filament electrode 12 and the counter electrodes 13, 14, 15 through the aperture 9, the display surface 7 becomes the fluorescent film 6R. , 6G, and 6B, selectively emit light in red, green, and blue. The brightness of these three colors is changed by changing the dimming signals output from terminals a, b, and c, and by adjusting these dimming signals, the luminance of the display fluorescent lamp 1, which becomes one pixel, is changed. You can change the color.

Further, in the structure of this embodiment, the fluorescent films 6R, 6
By employing a fluorescent discharge method in which G and 6B are formed and using rare earth phosphors, the brightness can be improved to about twice as much as, for example, compared to the conventional single-tube three-color CRT method.

Furthermore, since the fluorescent lamp 1 is a single tube, compared to a configuration using three types of display elements for each color, the mounting density on the display device can be increased, the effective light emitting area of the front panel can be widened, and the display The average brightness of the device's panel surface can be increased. Furthermore, since the aperture is located at the center of the display surface when looking at the display surface, it is easier to equalize the discharge length for each color, which improves white balance compared to when the discharge length for each color is different. becomes simple hydrogen.

Furthermore, in this embodiment, since the common filament electrode 12 and the counter electrodes 13, 14, 15 are provided on the stem portion 3 formed on the other end surface of the tube body 2, the base can be integrally formed, and the base can be attached to the display device side. The provided socket can also be formed integrally, allowing the fluorescent lamp 1 and the socket to be miniaturized.

Furthermore, three pairs of electrodes are connected to three opposing electrodes 13, 1.
4 and 15 and one common filament electrode 12, the number of electrodes that would normally be required is reduced to four, and 8 wells 10 are sufficient instead of 12. The base should also be 8 pins,
The structure of the cap and socket can be simplified, manufacturing and assembly work can be facilitated, and manufacturing costs can be reduced.

Further, a discharge path is formed between the electrode chamber 8 and each light emitting chamber 6 in an inverted L shape by the opening 9, and even if the total length of the tube body 2 is short, the discharge path length required for the required brightness can be maintained. Obtainable.

Further, the partition wall 8b of the lower outer tube portion 4, the electrode chamber 8
Since the height of the lower outer tube portion 4 is formed to be lower than the opening edge of the lower outer tube portion 4, damage to the partition wall 8b and the electrode chamber 8 during the manufacturing process is prevented.

Furthermore, since the upper outer tube section 5 and the lower outer tube section 4, which form the display surface that requires translucency, are constructed separately, the lower outer tube section 4 can be made non-transparent.

Next, specific dimensions of this fluorescent lamp 1 will be explained.

The diameter R of the envelope 2 is 45 mm, and the height h ₂ of the envelope 2 is
45 mm, and the height h ₁ of the partition wall 8b that partitions each light emitting chamber 6 is 40
mm, and the height _h3 of the cylindrical portion 8a forming the electrode chamber 8 is 35 mm.
It is becoming.

In the above embodiments, the envelope is formed into a substantially cylindrical shape, but it can also be formed into a rectangular tube shape.

Further, the outer surface of the upper outer tube portion may be provided with red, green, and blue colored coatings corresponding to the red, green, and blue display surfaces.

In addition, although the lower outer tube part has a structure in which the electrode chamber is integrally formed, the lower outer tube part and the stem part provided with the electrode chamber are formed separately, and then the stem part and the lower outer tube part are welded together. You can also.

[Effects of the Invention] According to the present invention, since the common electrode is a filament electrode, filament glow occurs, but since there is an electrode chamber and an opening for accommodating the filament electrode, when looking at the display surface, the filament glow is caused by the filament glow. It can be made smaller, and the display area that occupies the display surface can be enlarged.
Moreover, since multiple colors can be displayed with one lamp, the mounting density on the display device can be improved, and the effective light emitting area contributing to the color display of the display device can be increased.

Furthermore, since the common filament electrode is disposed within the electrode chamber at a distance from the opening, a discharge path common to each opposing electrode is formed between the common filament electrode and the opening. Due to the discharge formed in this common discharge path portion, the atmospheric gas between the common filament electrode and the opening is activated when a discharge is formed between any opposing electrode and the common filament electrode, and in this state, other When transitioning to a discharge between the opposing electrode and the common filament electrode, the discharge starting voltage between the opposing electrode and the common filament electrode can be lowered.

[Brief explanation of the drawing]

FIG. 1 is a cross-sectional plan view of a display fluorescent lamp showing an embodiment of the present invention, FIG. 2 is a vertical cross-sectional view of the negative part in FIG. 1, and FIG. 3 is a vertical cross-sectional view of the negative part in FIG. 4 is a plan view of the same, and FIG. 5 is an electric circuit diagram showing the connection of the display fluorescent lamp. 1... Fluorescent lamp, 6R, 6G, 6B... Fluorescent film, 6... Light emitting chamber, 7... Display surface, 8... Electrode chamber, 8b... Partition wall, 9... Opening, 12... Common filament Electrodes, 13, 14, 15... counter electrodes.

Claims (1)

[Scope of Claims] 1. The device is equipped with an envelope in which mercury and inert gas are sealed and whose front part is a display surface, and the envelope has the above-mentioned display on the display surface side of the envelope. It has a cylindrical electrode chamber with a bottom that extends perpendicularly and backwards to the display surface and has openings with sufficient spacing to form a discharge between the display surface and the common discharge inside the electrode chamber. a common filament electrode housed in the electrode chamber at a predetermined distance from the aperture so as to form a path; and a periphery of the aperture outside the electrode chamber on the back side of the display surface in the envelope. a plurality of opposing electrodes arranged between the common filament electrode and each forming an individual discharge through the openings; A partition wall is provided in each section of the inner surface of the envelope that is partitioned by the partition wall, and is excited by the ultraviolet rays generated by the individual discharges and outputs colored light to the outside of the display surface. 1. A display fluorescent lamp characterized by comprising a fluorescent film exhibiting three different display colors of red, green, and blue.