KR20010003558A - Vacuum fluorescent display - Google Patents

Abstract

PURPOSE: A fluorescent display tube is provided to reduce the noise generated when a lead frame, which is layed in a board glass, vibrates by the driving voltage. CONSTITUTION: A fluorescent display tube(10) includes a front glass(12), a board glass(14), a side glass(16), a wiring layer(18), an isolating layer(20), an anode, a cathode(22), a grid. a board glass(14) and a lead frame(24). The wiring layer(18) connects the inside of the fluorescent display tube(10) electrically. The isolating layer(20) prevents flowing of the electric current in unnecessary wiring. The anode contains the conductive layer and the fluorescent layer and the cathode emits the thermion and the grid is installed between the anode and the cathode(22). The lead line supplies the outer power to the anode and the grid through the wiring layer(18). The lead frame(24) supplies the outer power to the filament of the cathode(22) and is formed in the board glass(14).

Description

Fluorescent Display Tube {VACUUM FLUORESCENT DISPLAY}

The present invention relates to a fluorescent display tube that can reduce noise generated when a lead frame mounted on a substrate glass is vibrated by a driving voltage.

In general, the fluorescent display tube (VFD) is a self-luminous display device that emits electrons emitted from the filament by selectively colliding with the fluorescent layer under the control of the grid electrode and the anode electrode, and is excellent in visibility, wide viewing angle, and low voltage driving. As it is possible to apply semiconductor parts easily and have high reliability, it 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 having a filament, an anode electrode, and a grid electrode is widely used.

As shown in FIGS. 1 to 3, the fluorescent display tube may include the front glass 102, the substrate glass 104, the side glass 106, and the interior of the fluorescent display tube 100, which form a vacuum container. Insulation layer which serves to prevent unnecessary electric conduction of the wiring except for a wiring layer 108 for electrically connecting and a through hole formed between the wiring layer 108 and the conductive layer 110 ( 112 and a conductive layer which forms a bottom of the fluorescent layer 114 and a fluorescent layer printed by emitting a phosphor in a predetermined pattern, and a conductive layer which allows current to flow through the through hole in the wiring layer 108 through the through hole ( An anode 116 including a 110, a cathode 118 including a filament for emitting hot electrons and provided at a predetermined distance from the anode 116 toward the front glass 102, and at the cathode 118 Accelerated diffusion of emitted hot electrons, It made of a single metal mesh (mesh) that is composed of the grid electrode 120 is provided at the cathodes with a predetermined interval to the lower side of the cathode 118.

The substrate glass 104 includes a lead wire 122 for supplying external power to the anode electrode 116 and the grid electrode 120 through the wiring layer 108, and a lead frame 124 for supplying external power to the filament. ) Is mounted on the substrate glass through the side glass 106 and the substrate glass 104, and the filament support 126 for supporting the filament in a predetermined tension state is welded to the mount portion of the lead frame 124. .

Here, the filament support 126 may be integrally formed with the mount portion of the lead frame 124.

Accordingly, when voltage is applied to the grid electrode 120, the anode electrode 116, and the cathode 118 through the lead wire 122 and the lead frame 124, the anode electrode 116 may exhibit the characteristics of a circuit anode. The hot filaments of the cathode 118 are heated to emit hot electrons, and the hot electrons are accelerated and diffused by the grid electrode 120 to collide with the fluorescent layer 114 of the anode electrode 116 to emit light. When the emitted light is irradiated to the outside through the front glass 102, an image such as a predetermined character or symbol is realized.

On the other hand, when a negative voltage is applied to the grid electrode 120, the hot electrons emitted from the filament is blocked to flow to the fluorescent layer of the anode electrode 116 to prevent the fluorescent layer from emitting light, the grid electrode 120 and the anode When a negative voltage is applied to the electrode 116, hot electrons emitted from the filament collide with the fluorescent layer, but a negative voltage is applied to the fluorescent layer of the anode electrode, thereby preventing the corresponding fluorescent layer from emitting light.

As described above, the plurality of fluorescent layers constituting the dot or segment format are individually driven according to voltages applied to the anode electrode and the grid electrode to express specific letters or numbers.

However, the conventional fluorescent display tube constructed as described above has the following problems.

In the state where the lead frame is mounted on the substrate glass, a minute gap is formed between the lead frame and the substrate glass.

Therefore, when a voltage is applied through the lead wires and the lead frame to emit the fluorescent layer, an electric field is formed with the positive voltage and the negative lead voltage due to the relative potential difference. This causes the lead frame to deform to the substrate glass side.

If no power is applied, no electric field is formed, and the lead frame is restored to its original form.

As described above, when deformation and restoration of the lead frame are repeated according to the above action, vibration is induced in the lead frame in the vertical direction, and the vertical vibration of the lead frame is transmitted to the front glass through the substrate glass and the side glass, When the vibration is transmitted, the front glass acts as a ring plate, so that sound waves are generated to the outside, thereby generating noise due to the vibration.

An object of the present invention is to provide a fluorescent display tube that can reduce noise generated when a lead frame mounted on a substrate glass is vibrated by a driving voltage.

1 is an exploded perspective view of a fluorescent display tube according to the prior art.

FIG. 2 is a sectional view taken along the line "II-II" of FIG. 1; FIG.

3 is a sectional view taken along line "III-III" in FIG.

4 is a cross-sectional view of a fluorescent display tube according to an embodiment of the present invention.

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

The fluorescent display tube of the present invention for achieving the above object,

A pair of substrates facing each other and a side glass positioned between the substrates to form a closed space;

An anode electrode to which a current is applied from a wiring layer provided on any one of the substrates, and a phosphor coated on a surface of the electrode;

Hot electron emitting means for emitting hot electrons upon application of power;

A grid electrode which accelerates hot electrons emitted from said hot electron emitting means and impinges on said phosphor;

A lead frame installed on one of the substrates to apply a driving voltage to the hot electron emission means;

The lead frame includes an electric field attenuation part.

According to a preferred feature of the invention, the electric field attenuation portion comprises a structure for increasing the distance between the substrate and the lead frame.

According to another preferred feature of the present invention, the electric field damping portion is composed of a bending portion formed by bending the lead frame away from the substrate side, and the bending portion is supported by any one of the substrates by a glass post.

According to the fluorescent display tube of the present invention having the above characteristics, when the electric field is formed between the wiring layer and the lead frame as the driving voltage is applied, the electric field in the bending portion is weakly formed in inverse proportion to the increase in the gap.

Therefore, in the bending part, since the vertical vibration (deformation and restoration action) due to the electric field is weakly generated, the noise due to the vibration is reduced.

In addition, when the bending portion of the lead frame is supported by the glass post, vertical vibration due to the electric field may be further suppressed, and noise due to the vibration may be further reduced.

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.

4 illustrates a cross-sectional view of a fluorescent display tube according to an embodiment of the present invention.

As illustrated, the fluorescent display tube 10 includes a front glass 12, a substrate glass 14, a side glass 16, and a wiring layer electrically connecting the interior of the fluorescent display tube 10 to form a vacuum container. 18), an insulating layer 20 which serves to prevent unnecessary electrical conduction of wiring, an anode electrode (not shown) including a conductive layer and a fluorescent layer, a cathode 22 emitting hot electrons, and an anode electrode And a grid electrode (not shown) provided between the cathode and the cathode 22.

The substrate glass 14 includes a lead wire (not shown) for supplying external power to the anode electrode and the grid electrode through the wiring layer 18, and a lead frame 24 for supplying external power to the filament of the cathode 22. The glass is mounted on the substrate glass 14 through a space between the side glass 16 and the substrate glass 14.

Here, reference numeral 26 is a filament support that is installed in the mount portion of the lead frame to support the filament in a predetermined tension state, the filament support may be formed integrally with the mount portion of the lead frame.

In the fluorescent display tube formed as described above, the lead frame 24 of the present invention is provided with a bending part 24 ′, and the bending part 24 ′ is disposed between the lead frame 24 and the substrate glass 14. In order to weaken the electric field formed between the wiring layer and the lead frame by increasing the gap of the lead frame, all or part of the lead frame 24 located inside the vacuum vessel is bent upward.

Accordingly, when a voltage is applied through the lead wire and the lead frame, an electric field is formed with the positive voltage and the lead frame 24 with the negative voltage due to the relative potential difference. The frame 24 is deformed to the substrate glass 14 side, and if no power is applied, no electric field is formed, and the lead frame is restored to its original shape.

As described above, when deformation and restoration of the lead frame 24 are repeated according to the above action, vibration is caused in the lead frame in the vertical direction, and the vertical vibration of the lead frame is carried out through the substrate glass 14 and the side glass 16. The front glass 12 is transmitted to generate noise due to vibration.

In the noise generation process as described above, since the strength of the electric field formed between the wiring layer 18 and the lead frame 24 is inversely proportional to the distance between the wiring layer and the lead frame, the bending part 24 ′ of the lead frame except for the bending part is different. Weak electric field is formed compared to the part.

Therefore, the amount of deformation of the lead frame 24 including the bending part 24 ′ is reduced compared to the prior art, thereby reducing noise due to vibration of the lead frame.

In addition, the noise reduction effect is more effective as the length L of the bending part 24 ′ and the gap H increase.

5 is a cross-sectional view illustrating a fluorescent display tube according to another exemplary embodiment of the present invention. As shown in the drawing, the lead frame 24 includes a lead to increase a gap between the lead frame 24 and the substrate glass 14. A bending part 24 'is formed to bend all or a part of the frame 24 located inside the vacuum container upwardly, and one end of the bending part 24' is fixed to the front glass 12. The other end of the glass post 28 is fixed, and the other configuration is the same as that of the embodiment of FIG.

Here, when the glass post 28 is fixed to the front glass, its installation position is set to the space between the filaments, and when the glass post is fixed to the substrate glass, its installation position is set to the inner space of the bending part.

Accordingly, when the lead frame 24 including the bending part 24 ′ is deformed and restored by an electric field formed between the wiring layer 18 and the lead frame 24 and vibrates up and down, the lead frame ( Since the bending part 24 'of 24 is supported by the glass post 28 whose one end was fixed to the inner surface of the front glass 12, the vertical vibration of the bending part 24' is suppressed.

Therefore, the vertical vibration of the lead frame 24 due to the electric field formed between the wiring layer 18 and the lead frame 24 can be further suppressed, so that the noise caused by the vibration can be more effectively reduced.

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, when the electric field is formed between the wiring layer and the lead frame as the driving voltage is applied, the electric field in the bending part is weakly formed in inverse proportion to the increase in the gap, and thus includes the bending part. Vertical vibration (deformation and restoration action) of the lead frame is weaker than in the prior art, and noise due to vibration is reduced.

In addition, when the bending portion of the lead frame is supported by the glass post, it is possible to further suppress the vertical vibration caused by the electric field formation, thereby reducing the noise caused by the vibration more effectively.

Claims (4)

A pair of substrates facing each other and a side glass positioned between the substrates to form a closed space; An anode electrode to which a current is applied from a wiring layer provided on any one of the substrates, and a phosphor coated on a surface of the electrode; Hot electron emitting means for emitting hot electrons upon application of power; A grid electrode which accelerates hot electrons emitted from said hot electron emitting means and impinges on said phosphor; A lead frame installed on one of the substrates to apply a driving voltage to the hot electron emission means; And the lead frame includes an electric field attenuation unit. The fluorescent display tube of claim 1, wherein the electric field attenuator comprises a structure for increasing a distance between the substrate and the lead frame. 2. The fluorescent display tube according to claim 1, wherein the electric field attenuation portion is a bending portion formed by bending the lead frame away from the substrate side. The fluorescent display tube of claim 3, wherein the bending part is supported by any one of the substrates by a glass post.