KR100338028B1 - Vacuum fluorescent display - Google Patents

Abstract

The present invention provides a fluorescent display tube in which a conductive layer printed around a fluorescent layer acts as a grid electrode, employing multiple grid electrodes, and forming a grid electrode adjacent to the fluorescent layer lower than an outer grid electrode to diffuse electrons. A fluorescent display tube in which a viewing angle of a display pattern portion is enlarged while performing a good function, comprising: a pair of substrates constituting a vacuum container by side glass; An anode electrode which forms a predetermined display pattern by emitting light by receiving an external power from a wiring layer provided on one of the substrates; A filament for emitting hot electrons when the power is applied; Comprising a main control electrode provided around the anode electrode and at least one auxiliary control electrode provided outside the main control electrode to accelerate or block the hot electrons emitted from the filament when the power is applied, the main control electrode is the A grid electrode formed lower than the auxiliary control electrode so as to enlarge a viewing angle of an anode electrode; And a wiring layer applying power to the anode electrode and the grid electrode. Thereby, the viewing angle of the pattern display portion can be enlarged while performing the electron diffusion effect satisfactorily.

Description

Fluorescent Display Tube {VACUUM FLUORESCENT DISPLAY}

The present invention provides a fluorescent display tube in which a conductive layer printed around a fluorescent layer acts as a grid electrode, employing multiple grid electrodes, and forming a grid electrode adjacent to the fluorescent layer lower than an outer grid electrode to diffuse electrons. The present invention relates to a fluorescent display tube in which the viewing angle of the display pattern portion is enlarged while the operation is performed well.

In general, a fluorescent display tube (VFD) is a self-luminous display device that emits hot electrons emitted from a filament by selectively colliding with a fluorescent layer under control of a grid electrode and an anode electrode, and has excellent visibility, a wide viewing angle, and low voltage driving. It is easy to apply the semiconductor parts and it has high reliability and is used for various purposes in various fields.

Such fluorescent display tubes are classified into dipoles, triodes, and quadrupoles according to their structure. In general, a triode structure including a filament, an anode electrode, and a grid electrode is widely used.

As shown in FIG. 1, the fluorescent display tube is configured to electrically connect the front substrate 102, the rear substrate 104, the side glass 106, and the inside of the fluorescent display tube to form a vacuum container. Except for the wiring layer 108, the conductive hole formed between the wiring layer 108 and the conductive layer, the insulating layer 110, which serves to prevent unnecessary electrical conduction of the wiring, and the phosphor is printed and emitted in a predetermined pattern. An anode comprising a fluorescent layer 112 to be formed and a conductor forming a bottom of the fluorescent layer, the anode including a conductive layer 114 for flowing a current through the conducting hole in the wiring layer 108 and a current through the conducting hole; The filament 116 emits hot electrons, and the mesh type grid electrode 118 accelerates diffusion or blocks hot electrons emitted from the filament 116.

Accordingly, when a voltage is applied to the filament 116, the grid electrode 118, and the anode electrode through the lead wire 120, the anode electrode emits thermal electrons while the filament 116 is heated. The emitted hot electrons are accelerated and diffused by the grid electrode 118 to collide with the fluorescent layer 112 of the anode to emit the fluorescent layer, and the emitted light is irradiated to the outside through the front substrate 102. By this, an image such as a predetermined character or symbol is realized.

On the other hand, in recent years, the grid structure of the mesh type, which is very disadvantageous in cost structure, is removed, and an insulating partition wall is formed around the anode electrode as a corresponding component, and then a conductive layer is printed on the partition wall, or a conductive partition wall is formed to form a grid electrode. Fluorescent displays have been proposed to function.

FIG. 2 is a cross-sectional view of a fluorescent display tube according to the related art, which is configured as described above, and has an insulating layer on the surface of the rear substrate 104 disposed in parallel with the front substrate 102 by the side glass 106. 110 is provided, and an anode electrode forming a display pattern portion and a control electrode 118 'for accelerating or blocking hot electrons emitted from the filament 116 are provided on the surface of the insulating layer 110.

The anode electrode is printed on the surface of the insulating layer 110, the conductive layer 114 receives power from the wiring layer 108, and the light emitted by the hot electrons printed on the surface of the conductive layer 114 emitted from the filament 116 The control electrode 118 'is formed of a conductive partition wall having a predetermined height, and the conductive partition wall is configured to receive an external power source through the wiring layer 108'.

However, according to the conventional fluorescent display tube configured as described above, since the control electrode which acts to accelerate, diffuse, or block hot electrons must be formed at a predetermined height or more around the anode electrode in order to perform the above-mentioned function, When viewed from above the display tube, there was a problem in that the viewing angle at the time of emitting the display pattern portion was narrow.

Therefore, in the fluorescent display tube having the above structure, the multi-grid electrode is employed, and the grid electrode adjacent to the fluorescent layer is formed lower than that of the outer grid electrode, so that the electron diffusing action is performed well and the viewing angle of the display pattern portion is improved. It is an object to provide an enlarged fluorescent display tube.

1 is a cross-sectional view of a typical fluorescent display tube.

2 is a cross-sectional view of a fluorescent display tube according to the prior art.

3 is a plan sectional view of a fluorescent display tube according to the present invention;

4 is a cross-sectional view taken along line IV-IV of FIG. 3.

5 is a cross-sectional view illustrating main parts of a fluorescent display tube according to another exemplary embodiment of the present invention.

The object of the present invention as described above,

A pair of substrates constituting the vacuum container by the side glass;

An anode electrode which forms a predetermined display pattern by emitting light by receiving an external power from a wiring layer provided on one of the substrates;

A filament for emitting hot electrons when the power is applied;

Comprising a main control electrode provided around the anode electrode and at least one auxiliary control electrode provided outside the main control electrode to accelerate or block the hot electrons emitted from the filament when the power is applied, the main control electrode is the A grid electrode formed lower than the auxiliary control electrode so as to enlarge a viewing angle of an anode electrode;

A wiring layer applying power to the anode electrode and the grid electrode;

It is achieved by a fluorescent display tube comprising a.

According to a preferred feature of the invention, the main control electrode is composed of an insulating partition printed at a predetermined height and a conductive layer provided on the surface of the insulating partition, and the auxiliary control electrode is formed by alternately stacking the insulating partition and the conductive layer. do.

According to the present invention having the above characteristics, since the grid electrode is constituted by multiple control electrodes, the electron diffusion action can be performed well, and the main control electrode around the anode is formed lower than the auxiliary control electrode on the outside. Therefore, the viewing angle at the time of emitting the anode electrode can be enlarged.

According to another preferred feature of the present invention, the main control electrode and the auxiliary control electrode are each made of conductive partition walls printed at a predetermined height.

If the control electrode is configured as described above, the wiring structure can be simplified.

Hereinafter, a fluorescent display tube according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

3 is a plan sectional view showing a fluorescent display tube according to the present invention, and FIG. 4 is a sectional view taken along the line 'IV-IV' of FIG.

As shown, the fluorescent display tube is formed by the filament support 6 so as to cross the inside of the container formed by the front substrate (not shown) and the rear substrate 4 bonded by the side glass 2. A plurality of filaments 8 fixed at both ends, an anode electrode 10 formed on the surface of the rear substrate 4 to form a predetermined display pattern, and a filament provided around the anode electrode 10 when the power is applied Insulation that serves to prevent unnecessary electric wiring of the grid electrode 22, the wiring layer 16 for applying an external power source to the anode electrode 10, and the unnecessary wiring. Layer 18.

The anode electrode 10 is printed on the surface of the insulating layer 18 and is printed on the surface of the conductive layer 10a to which power is applied from the wiring layer 16 and emitted from the filament 8. It consists of the fluorescent layer 10b which light-emits by the hot electron.

Here, reference numeral 20 is a lead wire for applying an external power source to the anode electrode, the grid electrode and the filament.

In the present invention, the grid electrode 22 is provided to the main control electrode 12 provided on the side of the anode electrode 10, and the auxiliary control provided at a position spaced apart by a predetermined interval to the outside of the main control electrode 12 It consists of an electrode 14.

As shown in Fig. 4, the main control electrode 12 is composed of an insulating partition 12a printed on the surface of the insulating layer 18 and a conductive layer 12b printed on the surface of the insulating partition 12a. In addition, the auxiliary control electrode 14 is provided on the insulating partition 14a and the surface of the insulating partition 14a to accelerate diffusion or blocking hot electrons emitted from the filament 8 when the power is applied to the fluorescent layer of the anode electrode 10. The conductive layers 14b are alternately stacked, and the main control electrode 12 is formed lower than the auxiliary control electrode 14 so as to enlarge the viewing angle of the anode electrode.

Thus, when an external power source is applied to the filament 8, the anode electrode 10, the main control electrode 12 and the auxiliary control electrode 14 through the lead wire 20, the fluorescent layer 10b of the anode electrode 10 It receives the hot electrons emitted from the filament 8 and emits light.

5 illustrates a cross-sectional view of main parts of a fluorescent display tube according to another exemplary embodiment, wherein an insulating layer 18 is provided on a surface of the rear substrate 4, and a display pattern is provided on the surface of the insulating layer 18. An anode electrode 10 forming a portion and a main control electrode 12 ', 14' as a grid electrode 22 'for accelerating or blocking hot electrons emitted from the filament 8 are provided.

The main control electrode 12 'and the auxiliary control electrode 14' are formed of conductive barrier ribs printed by a predetermined height on an upper side of the insulating layer 18 provided on the surface of the rear substrate, and the auxiliary control electrode 14 ' ) Is provided at a position spaced apart from the main control electrode 12 'by a predetermined distance, and the main control electrode 12' is provided to the auxiliary control electrode 14 'in order to enlarge the viewing angle during light emission of the display pattern portion. It is formed lower than, and the anode electrode, the main control electrode and the auxiliary control electrode is configured to receive an external power source through separate wiring layers 16 and 16 ', respectively.

Therefore, when power is applied to each electrode, hot electrons emitted from the filament 8 are accelerated and diffused by the main control electrode 12 'and the auxiliary control electrode 14', and the corresponding fluorescent layer of the anode electrode 10 emits light. .

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications and changes can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. Naturally, it belongs to the range of.

As described above, according to the fluorescent display tube of the present invention, since the grid electrode is composed of multiple control electrodes, the electron diffusion effect can be satisfactorily performed, and the main control electrode around the anode electrode is connected to the auxiliary control electrode on the outer side. Since it is formed lower than that, the viewing angle can be increased when the anode electrode emits light, and the wiring structure can be simplified by forming the main control electrode and the auxiliary control electrode as conductive partition walls.

Claims (4)

A pair of substrates constituting the vacuum container by the side glass; An anode electrode which forms a predetermined display pattern by emitting light by receiving an external power from a wiring layer provided on one of the substrates; A filament for emitting hot electrons when the power is applied; Comprising a main control electrode provided around the anode electrode and at least one auxiliary control electrode provided outside the main control electrode to accelerate or block the hot electrons emitted from the filament when the power is applied, the main control electrode is the A grid electrode formed lower than the auxiliary control electrode so as to enlarge a viewing angle of an anode electrode; A wiring layer applying power to the anode electrode and the grid electrode; Fluorescent display tube comprising a. The fluorescent display tube according to claim 1, wherein the main control electrode comprises an insulating barrier rib and a conductive layer provided on a surface of the insulating barrier rib. The fluorescent display tube of claim 1, wherein the auxiliary control electrode is laminated alternately between an insulating barrier and a conductive layer. The fluorescent display tube according to claim 1, wherein the main control electrode and the auxiliary control electrode are each formed of a conductive partition wall.