KR100315231B1 - Vacuum fluorescent display - Google Patents

Abstract

The present invention relates to a fluorescent display tube that simplifies the wiring structure for applying a voltage to a conductive partition wall that buffers the influence of electrons from external static electricity and reduces the vertical vibration range of the filament support. A pair of substrates facing each other and a side glass positioned between the substrates to form a closed space; A filament for emitting hot electrons when the power is applied; Support means for installing and supporting said filament in tension; An anode electrode which receives an external power source from a wiring layer provided on any one of the substrates and forms a predetermined display pattern; A conductive barrier electrically connected to the support means to receive a voltage equal to a voltage applied to the filament and an equipotential voltage and to buffer an influence on the flow of electrons due to static electricity applied from the outside; and an extension of the conductive barrier The end supports the bottom of the lead frame. This eliminates components for applying voltage to the conductive bulkhead, which simplifies the wiring structure, reduces manufacturing costs, reduces assembly labor, and suppresses luminance irregularities due to vibration of the lead frame. Can be.

Description

Fluorescent Display Tube {VACUUM FLUORESCENT DISPLAY}

The present invention relates to a fluorescent display tube that provides a conductive barrier to the outside of the fluorescent layer to buffer an influence on the flow of electrons due to static electricity applied from the outside, and more particularly, to apply a voltage to the conductive barrier. The present invention relates to a fluorescent display tube which can suppress luminance unevenness due to vibration by reducing wiring structure, reducing manufacturing cost, shortening assembly time, and reducing vertical vibration range of the filament support.

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 As it is possible to apply semiconductor parts 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 the fluorescent display tube, the fluorescent display tube having a bipolar tube structure is a vacuum container formed by a pair of substrates 102 and 104 and a side glass 106 interposed between these substrates, as shown in Figs. And an anode electrode 108 provided in the space portion of the vacuum container and receiving and emitting electrons to display a constant signal, and both ends of which are welded and fixed to the supports 110 and 110 'so as to emit hot electrons by receiving power from the outside. Conductive partition wall 114 provided on the outside of the anode electrode 108 to cushion the influence on the flow of electrons due to static electricity applied from the outside through the filament 112, the side glass 106, a mount assembly, etc. It includes.

The rear substrate 104 serves to prevent unnecessary electrical conduction of the wiring except for the wiring layer 116 for electrically connecting the inside of the fluorescent display tube and the conduction hole formed between the wiring layer 116 and the conductive layer. The insulating layer 118 is provided, and the anode electrode 108 is a fluorescent layer 108a in which phosphors are printed and emitted in a predetermined pattern, and a conductor forming a bottom of the fluorescent layer, and through a conduction hole in the wiring layer 116. It consists of the conductive layer 108b which makes an electric current flow through a fluorescent layer.

In addition, the mount assembly includes a lead frame 122 including lead pins 120 and 120 'for applying an external power source to the anode electrode 108 and the conductive partition wall, and a mount on which the filament supports 110 and 110' are installed. The leading ends of the lead pins 120 and 120 'are bent downward for good contact with the wiring layer 116, and the lead pins 120 are electrically connected to the wiring layer 116 through the lead pads 124, respectively.

Accordingly, when a voltage is applied to the filament 112 and the anode electrode 108 through the lead frame 122 and the lead pin 120, respectively, the anode electrode 108 exhibits the characteristics of a circuit anode, and the filament ( The hot electrons emitted while the 112 is heated impinge on the fluorescent layer 108a of the anode electrode 108 to emit the fluorescent layer, and the emitted light is irradiated to the outside through the front substrate 102 to generate a predetermined character. An image such as a b symbol is implemented.

In addition, since the voltage is applied to the conductive partition wall 114 through the lead pins 120 ′ when the fluorescent display tube is driven, static electricity applied from the outside through the side glass 106 is applied to the conductive partition wall 114. Shielded by the electric field formed by it, the flow of hot electrons is minimized by the static electricity.

However, according to the conventional fluorescent display tube configured as described above, in order to apply a voltage to the conductive partition wall, a lead pin and lead pads for electrically connecting the end portions of the lead pins to the wiring layer must be separately provided, thus manufacturing cost and assembly cost There is a problem that is increased.

In addition, in the state where the mount assembly is installed on the substrate, the mount portion is lifted by a predetermined gap from the upper surface (the upper surface of the insulating layer) of the rear substrate as shown in FIG. 1 by the elastic force generated by bending the tip portion of the lead pin. Thus, the filament support and the filament are also lifted off the back substrate.

Therefore, the filament support can vibrate in the vertical direction as much as the gap, and when the external impact is applied to the fluorescent display tube, the filament vibrates in the vertical direction and the hot electrons are not evenly supplied to the anode electrode. Smudges occur.

Accordingly, an object of the present invention is to provide a fluorescent display tube that can reduce the manufacturing cost and shorten the assembly time by simplifying the wiring structure for applying a voltage to the conductive partition wall.

Another object of the present invention is to provide a fluorescent display tube which can suppress luminance unevenness generated by the vibration by reducing the vertical vibration range of the filament support.

1 is a plan view of a fluorescent display tube according to the prior art.

FIG. 2 is a cross-sectional view taken along line II-II of FIG. 1.

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

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

5 is a cross-sectional view of an essential part of a fluorescent display tube according to a modified embodiment of FIG. 3;

6 is a cross-sectional view of an essential part of a fluorescent display tube according to another embodiment of the present invention;

The object of the present invention as described above,

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

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

Support means for installing and supporting said filament in tension;

An anode electrode which receives an external power source from a wiring layer provided on any one of the substrates and forms a predetermined display pattern;

A conductive partition wall connected to the support means to receive a voltage equal to a voltage applied to the filament, and to buffer an influence on the flow of electrons due to static electricity applied from the outside;

It is achieved by a fluorescent display tube comprising a.

According to a preferred feature of the present invention, the fluorescent display tube is provided between the anode electrode and the conductive partition wall, and includes a rib grid for receiving the voltage applied to the anode electrode and the voltage of the equipotential.

The support means includes a fixed support for fixing one end of the filament and a tension support for fixing the other end of the filament to maintain the tension of the filament, wherein the fixed support and the tension support are respectively mounted to the mount portion of the lead frame. The fixed barrier rib is fixed and has an extension portion whose end portion is in contact with a lead frame on either side. In this case, the extension portion supports the bottom surface of the lead frame to which the fixing support is fixed.

According to another preferred feature of the present invention, a pair of substrates facing each other and the side glass positioned between the substrates to form a closed space; A filament for emitting hot electrons when the power is applied; Support means for installing and supporting said filament in tension; An anode electrode which receives an external power source from a wiring layer provided on any one of the substrates and forms a predetermined display pattern; A conductive partition wall that buffers an influence on the flow of electrons due to static electricity applied from the outside through the side glass; And connecting means for electrically connecting the support means and the conductive partition wall in the tube.

In the fluorescent display tube having such a structure, the connecting means may be made of a metal thin film of the same material as a known lead frame.

According to the present invention having such a feature, the necessity of providing a wiring for applying power to the conductive partition wall, a lead pin for applying power to the wiring, and a lead pad for connecting an end of the lead pin to the wiring layer is eliminated. In addition, the wiring structure can be simplified, manufacturing costs can be reduced, and assembly labor can be shortened.

In addition, since the bottom of the lead frame to which the fixed support is fixed is supported by the extension portion of the conductive partition wall or the conductive metal thin film, the vertical vibration range of the support frame and the lead frame to which the support is fixed can be reduced to suppress luminance unevenness.

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

As shown, the fluorescent display tube includes a front substrate 4 and a rear substrate 6 bonded by the side glass 2, and a filament support 8, 8 'to cross the inside of the container formed by these substrates. A plurality of filaments 10 fixed at both ends thereof, an anode 12 formed of a fluorescent layer 12a and a conductive layer 12b to form a predetermined display pattern, and hot electrons due to static electricity applied from the outside Conductive barrier rib 14a for reducing the disturbance of the flow of the wires, wiring layer 16 for applying external power to the anode electrode 12, and insulating layer 18 that serves to prevent unnecessary electrical conduction of the wiring. And mount assemblies and the like.

Lead frames 20 including mounts are spaced apart from both sides of the rear substrate 6, and fixed supports 8 and tension supports 8 ′ are welded and fixed to mounts of the lead frames 20, respectively. In addition, an end portion of the lead pin 22 for applying external power to the anode electrode 12 is connected to the wiring layer 16 by the lead pad 24, and the conductive partition wall 14a provided at the outer side of the anode electrode 12 is provided. ) Is provided with an extension portion 14b.

The extension part 14b has a lead frame (with a predetermined gap lifted from the upper surface of the rear substrate 6 by a mount force of the lead frame 20 due to the elastic force generated by bending the tip end of the lead pin 22). In order to prevent the 20 from being vibrated in the up and down direction, and to apply the voltage applied to the filament 10 through the lead frame 20 to the conductive partition wall 14a, in this embodiment, the lead frame and the rear surface are It is formed extending to the fixed support 8 side to support the bottom of the lead frame 20 between the substrate.

Accordingly, when voltage is applied to the filament 10 and the anode electrode 12 through the lead frame 20 and the lead pins 22, the hot electrons emitted from the filament 10 are the fluorescent layer of the anode electrode 12. The fluorescent layer 12a emits light when the fluorescent layer 12a is driven, and when the fluorescent display tube is driven, the fluorescent barrier 12a is applied to the filament 10 through the extension part 14b in contact with the lead frame 20. Since the voltage of the voltage and the equipotential is applied, the static electricity applied from the outside is shielded by the conductive partition wall 14a so that the flow of hot electrons is made good.

In addition, since the bottom surface of the lead frame 20 is supported by the extension portion 14b of the conductive partition wall, it is possible to suppress the filament support 8 from vibrating in the vertical direction due to external impact or the like, resulting in uneven luminance due to the vibration. Can be prevented.

On the other hand, the present invention, as shown in Figure 5, a triode structure in which a conductive rib grid 26 for accelerating, diffusing or blocking hot electrons is formed in a space between the anode electrode 12 and the conductive partition wall 14a. It is also applicable to the fluorescent display tube of the present invention, and as shown in Fig. 6, instead of forming the extension portion in the conductive partition wall, the same material as that of the known lead frame 20 (for example, Korean Patent Publication No. 85-A). The lead frame 20 and the conductive partition wall 14a may be electrically connected to each other using a metal thin film 14c of a lead frame disclosed in 7529).

The fluorescent display tube having such a structure has a conductive partition wall when driving the fluorescent display tube in which hot electrons emitted while the filament 10 is heated collide with the fluorescent layer of the anode electrode 12 to emit the fluorescent layer 12a. Since the voltage applied to the filament and the voltage of the equipotential are applied through the lead frame 20 in 14a), the flow of hot electrons emitted from the filament is minimized by the static electricity applied from the outside.

Since the bottom surface of the lead frame 20 is supported by the extension portion 14b of the conductive partition wall or the metal thin film 14c, the filament support 8 can be suppressed from vibrating in the vertical direction due to external impact or the like. .

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. It is natural to fall within the range of

As described above, according to the fluorescent display tube of the present invention, a wiring for applying a voltage applied to the filament and an equipotential voltage to the conductive partition wall, and a lead pin and an end portion of the lead pin for applying power to the wiring are connected to the wiring layer. Since the necessity of providing lead pads for connection is eliminated, the wiring structure can be simplified, manufacturing costs can be reduced, and assembly man-hours can be shortened.

In addition, since the bottom surface of the lead frame to which the fixed support is fixed is supported by the extension portion of the conductive partition wall or the metal thin film, the vertical vibration range of the support frame and the lead frame to which the support is fixed can be reduced to suppress luminance unevenness.

Claims (8)

A pair of substrates facing each other and a side glass positioned between the substrates to form a closed space; A filament for emitting hot electrons when the power is applied; Support means for installing and supporting said filament in tension; An anode electrode which receives an external power source from a wiring layer provided on any one of the substrates and forms a predetermined display pattern; A conductive partition wall electrically connected to the support means to receive a voltage equal to a voltage applied to the filament and to buffer an influence on the flow of electrons due to static electricity applied from the outside; Fluorescent display tube comprising a. The fluorescent display tube of claim 1, further comprising a rib grid provided between the anode electrode and the conductive partition wall to receive a voltage of an equipotential and a voltage applied to the anode electrode. According to claim 1 or 2, wherein the support means, consisting of a fixed support for fixing one end of the filament, and a tension support for fixing the other end of the filament to maintain the tension state of the filament, the fixed support and tension The support is a fluorescent display tube is fixed to the mount of the lead frame, respectively. 4. The fluorescent display tube according to claim 3, wherein the conductive partition wall has an extension portion whose end portion is in contact with a lead frame on either side. The fluorescent display tube of claim 4, wherein the extension part contacts a bottom surface of the lead frame to which the fixing support is fixed to support the bottom surface of the lead frame. A pair of substrates facing each other and a side glass positioned between the substrates to form a closed space; A filament for emitting hot electrons when the power is applied; Support means for installing and supporting said filament in tension; An anode electrode which receives an external power source from a wiring layer provided on any one of the substrates and forms a predetermined display pattern; A conductive partition wall that buffers an influence on the flow of electrons due to static electricity applied from the outside through the side glass; Connecting means for electrically connecting the support means and the conductive partition wall inside the tube; Fluorescent display tube comprising a. (delete) (delete)