Display panel and display device to which the display panel is applied

BACKGROUND OF THE INVENTION AND RELATED ART STATEMENT

The present invention relates to a display panel and a display device to which the display panel is applied. More specifically, it relates to a display panel having a fluorescence layer which is excited by electrons from a vacuum space to emit light, and a display device into which the display panel is incorporated.

Various flat type (flat panel type) displays are being studied as image display devices which are to replace currently main-stream cathode ray tubes (CRT). The flat type displays include a liquid crystal display (LCD), an electroluminescence display device (ELD) and a plasma display panel (PDP). Further, there is also proposed a cold cathode field emission display device, a so-called field emission device (FED), which is capable of emitting electrons into vacuum from a solid without relying on thermal excitation, and it attracts attention from the viewpoint of a brightness on a screen and a low power consumption.

FIG. 24

shows a typical configuration of FED, in which a display panel

500

and a rear panel

400

are placed to be opposed to each other. These panels

400

and

500

are bonded to each other in circumferential end portions through a frame (not shown), so that vacuum space VAC is formed in a closed space between these two panels. The rear panel

400

has cold cathode field emission devices (to be referred to as “field emission devices” hereinafter) as electron emitting members. In

FIG. 24

, there is shown a so-called Spindt type field emission device having a conical electron emitting portion

45

as an example of the field emission device. The Spindt type field emission device comprises a cathode electrode

41

formed on a supporting member

40

, an insulating interlayer

42

formed on the cathode electrode

41

and the supporting member

40

, a gate electrodes

44

formed on the insulating interlayer

42

, and the conical electron emitting portion

45

formed in opening portions

43

provided in the gate electrodes

44

and the insulating interlayer

42

. Generally, a predetermined number of the electron emitting portions

45

having a predetermined alignment are so arranged as to correspond to one fluorescence layer

51

to be explained later. A relatively negative voltage (video signal) is applied to the electron emitting portion

45

from a cathode electrode driving circuit

46

through the cathode electrode

41

, and a relatively positive voltage (scanning signal) is applied to the gate electrode

44

from a gate electrode driving circuit

47

. Electrons are emitted from the top of the electron emitting portion

45

depending upon an electric field generated by the application of these voltages. The electron emitting member is not limited to the above Spindt type field emission device. A so-called edge type field emission device is used in some cases, and other types such as a flat type field emission device, a crown type field emission device and the like are also used in some cases. Further, sometimes the above is the other way round, that is, a scanning signal is inputted to the cathode electrode

41

, and a video signal is inputted to the gate electrode

44

.

The display panel

500

has a plurality of fluorescence layers

51

formed on a transparent substrate

50

composed of glass or the like, and a conductive reflective film

52

. The fluorescence layer

51

is formed in the form of a matrix or stripes, and the conductive reflective film

52

is formed on the fluorescence layer

51

and the transparent substrate

50

. A positive voltage higher than the positive voltage applied to the gate electrode

44

is applied to the conductive reflective film

52

from an acceleration power source (anode electrode driving circuit)

53

, and the conductive reflective film

52

works to direct electrons emitted into the vacuum space VAC from the electron emitting portion

45

toward the fluorescence layer

51

. Further, the conductive reflective film

52

has the following functions. It protects fluorescence particles constituting the fluorescence layer

51

from the sputtering by particles such as ions, it reflects light emitted by the fluorescence layer

51

due to electron excitation toward the transparent substrate

50

to improve the brightness of a display screen viewed from outside the transparent substrate

50

, and it also prevents an excess charge to stabilize the potential of the display panel

500

. That is, the conductive reflective film

52

has both the function of an anode electrode and the function of a member known as a metal-back layer in the field of cathode ray tubes (CRT). The conductive reflective film

52

is generally composed of an aluminum thin film.

FIG. 25A

shows a schematic plan view of a display panel in which the fluorescence layers

51

R,

51

G and

51

B are formed in a matrix form, and

FIG. 25B

shows a schematic partial cross-sectional view taken along an X—X line in

FIG. 25A. A

region where the fluorescence layers

51

R,

51

G and

51

B are arranged is an effective region which practically works as a display device, and an anode electrode forming region corresponds nearly to the above effective region. For clarification, the anode electrode forming region is indicated by slanting lines in

FIG. 25A. A

circumferential region of the effective region is an idle region which supports functions of the effective region such as the housing of peripheral circuits and the mechanical support of a display screen. A lead portion

54

used for connecting the anode electrode to the acceleration power source (see acceleration power source

53

in

FIG. 24

) which supplies a power, for example of 5 kV is formed on an edge portion of the transparent substrate

50

. Between the acceleration power source and the anode electrode is generally provided a resistance member (a resistance value of 100 MΩ in a shown example) for preventing an over-current and discharging. The resistance member is provided outside the substrate.

The anode electrode in an FED is not so necessarily required to be composed of the conductive reflective film

52

as described above. As is shown in a schematic partial cross-sectional view of

FIG. 25C

taken along an X—X line in

FIG. 25A

, there may be employed a constitution in which a transparent conductive film

55

formed on the transparent substrate

50

has the function of the anode electrode. The region where the conductive reflective film

52

or the transparent conductive film

55

which works as an anode electrode is formed covers nearly the entire area of the effective region on the transparent substrate

50

.

FIG. 26A

shows a schematic plan view of a display panel in which the fluorescence layers are formed in a stripe form, and

FIGS. 26B and 26C

show schematic partial cross-sectional views taken along an X—X line in FIG.

26

A. Some members in

FIGS. 26A

to

26

C are the same as those in

FIGS. 25A

to

25

c

and indicated by the same reference numerals, and detailed explanations thereof are omitted.

FIG. 26B

shows a configuration in which the anode electrode is composed of a conductive reflective film

52

.

FIG. 26C

shows a configuration in which the anode electrode is composed of a transparent conductive film

55

. The region where the conductive reflective film

52

or the transparent conductive film

55

which works as an anode electrode is formed covers nearly the entire area of the effective region of the display panel.

Meanwhile, an FED which is a flat type display device has a far smaller flying distance of electrons than a cathode ray tube, so that the electron acceleration voltage cannot be so increased as a cathode ray tube. That is, when the electron acceleration voltage is too high in the FED, a spark discharge is liable to take place very easily between the electron emitting portion on the rear panel and the film which works as an anode electrode, which may highly possibly downgrade the image quality to a large extent. In the discharge generating mechanism in a vacuum space, presumably, a small discharge is first triggered by the release of electrons and ions from electron emitting portions under a strong electric field, and the anode electrode is supplied with energy to increase a local temperature of the anode electrode, or an occlusion gas inside the anode electrode is released or an anode-electrode-forming material itself is vaporized, so that a small discharge grows to be a spark discharge. Beside the acceleration power source, energy stored or accumulated in an electrostatic capacitance between the anode electrode and the electron emitting portion or between the anode electrode and the cathode electrode may possibly become an energy source which promotes the growth to a spark discharge. For inhibiting the spark discharge, it is effective to control the emission of electrons and ions which trigger the discharge, while it is required to control the particles extremely strictly therefor. In a general production process of display panels or display devices using the display panels, practicing the above control involves great technical difficulties.

The FED for which a low acceleration voltage of electrons is inevitably selected causes characteristic problems which are not found in a cathode ray tube. In a cathode ray tube in which high-voltage acceleration is carried out, the penetration depth of electrons into a fluorescence layer is large, so that the energy of the electrons is received in a relatively large region inside the fluorescence layer. A relatively large number of fluorescence particles in the above large region can be therefore simultaneously excited to achieve a high brightness. In contrast, in the FED, the penetration depth of electrons into the fluorescence layer is small, so that the energy of electrons can be received only in a narrow region. For attaining a practically satisfactory brightness, it is required to increase the density of electrons emitted from the field emission device (i.e., to increase a current density) or to irradiate the fluorescence layer with the electrons for a longer time period than in the cathode ray tube. When the anode electrode is formed on the fluorescence layer, the number of electrons which can transmit the anode electrode is increased by limiting the thickness of the anode electrode to approximately 0.07 μm, so that the anode electrode cannot be expected to has such an effect that the metal-back layer (generally having a thickness of approximately 0.2 μm) of the cathode ray tube has on preventing an antistatic charge. It can be therefore said that the fluorescence layer of the field emission device is situated in an environment where it easily degraded due to the long time irradiation of electrons and charging. When the fluorescence layer is composed of a sulfide-containing fluorescence particles, the above degradation appears as a phenomenon in which sulfur as a component thereof is dissociated in the form of a simple substance, sulfur monoxide (SO) or sulfur dioxide (SO

2

), and the sulfide-containing fluorescence layer changes in composition or is physically disintegrated. The above degradation of the fluorescence layer leads to a variance in the color of emitted light or light emission efficiency and contamination of components inside the FED and finally to a decrease in the reliability and lifetime characteristic of the FED.

Further, the conventional FED has another problem that the brightness of a display screen varies depending upon pixels or sub-pixels selected on the rear panel

400

side.

FIGS. 27A and 27B

show schematic configurations of the real panel

400

. In these Figures, for clarification, a cathode electrodes

41

in a non-selected state (to which a voltage of +50 volts is applied from the cathode electrode driving circuit

46

) is indicated by a less dense hatching, and a cathode electrodes

41

in a selected state (to which a voltage of 0 volt is applied from the cathode electrode driving circuit

46

) is indicated by a dense hatching. A video signal applied to the cathode electrode

41

in a selected state can have a value of from 0 volt (inclusive) to less than +50 volts depending upon tones, while it is assumed to be 0 volt for simplification. A gate electrodes

44

in a non-selected state (to which a voltage of 0 volt is applied from the gate electrode driving circuit

47

) is indicated by a blank, and a gate electrodes

44

in a selected state (to which a voltage of +50 volts is applied from the gate electrode driving circuit

47

) is indicated by hatching. A portion where projection images of the cathode electrode

41

and the gate electrode

44

overlap (to be referred to as “overlap region” hereinafter) corresponds to one pixel in a monochromatic display device, or to one sub-pixel in a color display device, and generally, a plurality of field emission devices are arranged per overlap region. An overlap region of the selected cathode electrode

41

and the selected gate electrode

44

is a selected pixel (or a selected sub-pixel), and it is shown by a blank circle in Figure. The gate electrodes

44

will be referred to as a first column, . . . , m-th column, . . . from top to bottom, and the cathode electrodes

41

are referred to as a first row, . . . , n-th row, . . . from left to right.

When it is assumed that the gate electrode

44

on the first column and the cathode electrode

41

on the first row are selected as shown in

FIG. 27A

, electrons are emitted from the field emission devices arranged in the overlap region positioned on the first column and the first row, and the opposing fluorescence layer

51

emits light. In this case, if it is assumed that a current of 1 μA flows from the display panel

500

toward the rear panel

400

, a voltage drop of 1 μA×100 MΩ=0.1 kilovolt occurs. That is, an acceleration voltage of 5−0.1=4.9 kilovolts is applied between the rear panel

400

and the display panel

500

. When it is assumed that the gate electrode

44

on the 2nd column is selected and, for example, that five cathode electrodes

41

such as those on the 2nd, 6th, 9th, 11th and 14th rows are selected as shown in

FIG. 27B

, however, a current which flows from the display panel

500

toward the rear panel

400

has a total value of 5 μA, and a voltage drop of 0.5 kilovolt takes place, so that the acceleration voltage between the rear panel

400

and the display panel

500

decreases to 5.0−0.5=4.5 kilovolts. This means a decrease in the energy of electrons which are to collide with the fluorescence layer

52

and a subsequent decrease in the brightness of a display screen. That is, the brightness of the display screen varies depending upon the number of the cathode electrodes

41

to be selected per column of the gate electrodes

44

.

OBJECT AND SUMMARY OF THE INVENTION

It is therefore a first object of the present invention to provide a display panel in which the deterioration of its fluorescence layer caused by a charge can be prevented, and a display device having a long lifetime due to the use of the above display panel.

It is a second object of the present invention to provide a display panel in which a spark discharge can be prevented, and a display device having a long lifetime and high reliability due to the use of the above display panel.

Further, it is a third object of the present invention to provide a display device which exhibits a stabilized brightness on a display screen by keeping a voltage drop in a constant range without regard to the number of selected electrodes to which video signals are inputted on the rear panel side.

The display panel according to a first aspect of the present invention for achieving the above first object is a display panel comprising a substrate, a fluorescence layer which is to be caused to emit light by electrons from a vacuum space, and an anode electrode which is to direct the electrons toward the fluorescence layer,

wherein the anode electrode comprises a lower electrode and an upper electrode.

In the display panel according to the first aspect of the present invention, the anode electrode has a two-layered structure comprising a lower electrode and an upper electrode, and charge is removed through both the lower electrode and the upper electrode, so that the deterioration of the fluorescence layer caused by an excess charge can be prevented.

The display device according a first aspect of the present invention for achieving the above first object is a display device comprising the display panel according to the first aspect of the present invention,

wherein the display panel and a rear panel having a plurality of electron emitting members are arranged to be opposed to each other through a vacuum space,

the display panel comprises a substrate, a fluorescence layer which is to be caused to emit light by electrons emitted from the electron emitting members into the vacuum space, and an anode electrode which is to direct the electrons toward the fluorescence layer, and

the anode electrode comprises a lower electrode and an upper electrode.

In the display panel and the display device according to the first aspect of the present invention, structurally, there can be two cases, such as

(i) a case where the lower electrode is formed on the substrate, the fluorescence layer is formed on the lower electrode and the upper electrode is formed on the fluorescence layer, and

(ii) a case where the fluorescence layer is formed on the substrate, the lower electrode is formed on the fluorescence layer and the upper electrode is formed on the lower electrode.

In both the cases (i) and (ii), the fluorescence layer may be composed of monochromatic fluorescence particles, or it may be composed of fluorescence particles of three primary colors. Further, concerning the alignment configuration of the fluorescence layers, the fluorescence layers may be aligned in the form of a dot matrix, or in the form of stripes. In the alignment configurations of a dot matrix and stripes, gaps between adjacent fluorescence layers may be filled with a black-matrix layer for improving a contrast. When the above black-matrix layer is formed in the case (i), the fluorescence layers and the black-matrix layer are formed on the lower electrode, and the upper electrode is formed on the fluorescence layers and the black-matrix layer. When the above black-matrix layer is formed in the case (ii), the fluorescence layers and the black-matrix layer are formed on the substrate, and the lower electrode is formed on the fluorescence layers and the black-matrix layer. In both the cases, the lower electrode and the upper electrode are electrically connected and have potentials at the same level when the display device is operated.

In each of these cases (i) and (ii), it is determined depending upon which material is used for the lower electrode and the upper electrode, a transparent material or a non-transparent material, whether the material constituting the substrate is transparent or non-transparent. As a consequence, it is determined whether the display device is a transmission type or a reflection type when the display panel is incorporated into the display device. The above transmission type refers to a system in which an image is viewed through the substrate of the display panel, and not only the substrate is required to be transparent, but all the layers interposed between the fluorescence layer and the substrate are also required to be transparent. The above reflection type refers to a system in which an image is viewed through the rear panel placed to be opposed to the display panel, and not only all the components of the rear panel present in the effective region are required to be transparent, but all the layers that are nearer to the rear panel side than the fluorescence layer on the display panel side are also required to be transparent.

In view of the above conditions, the case (i) can be further classified into follows. “TP” stands for “transparent”, “N-TP” stands for “non-transparent”, “TR” stands for “transmission type display device”, and “RF” stands for “reflection type display device”.

Type of

Upper

Lower

display

Case

electrode

electrode

Substrate

device

(i-1)

N-TP

TP

TP

TR

(i-2)

TP

N-TP

TP or

RF

N-TP

(i-3)

TP

TP

TP

TR or

RF

(i-4)

TR

TP

N-TP

RF

In view of the above conditions, the case (ii) is further classified into follows.

Type of

Upper

Lower

display

Case

electrode

electrode

Substrate

device

(ii-1)

N-TP

TP

TP

TR

(ii-2)

TP or

N-TP

TP

TR

N-TP

(ii-3)

TP

TP

TP

TR or

RF

(ii-4)

TP

TP

N-TP

RF

There may be employed any one of a structure in which both the lower electrode and the upper electrode are so formed as to extend on the entire effective region, a structure in which one is divided into a plurality of independent regions and the other is so formed as to extend on the entire effective region, and a structure in which each of the lower electrode and the upper electrode is divided into a plurality of independent regions. Further, when each of the lower electrode and the upper electrode is divided into a plurality of independent regions, the number of the independent regions of one may be the same, or different from, the number of the independent regions of the other. Particularly, when at least the upper electrode is divided into a plurality of independent regions in the case (i), or when each of the lower electrode and the upper electrode is divided into a plurality of independent regions in the case (ii), the electrostatic capacitance between the anode electrode and the cathode electrode can be decreased due to a decrease in the area of the anode electrode, and the spark discharge can be effectively prevented. A plurality of the independent regions are practically preferably correspondent to a predetermined number of the unit fluorescence layers, and this point will be discussed with regard to a second aspect of the present invention.

The display panel according to a second aspect of the present invention for achieving the above second object is a display panel comprising a substrate, a plurality of unit fluorescence layers which are to be caused to emit light by electrons from a vacuum space, an anode electrode which is to direct the electrons toward the unit fluorescence layers, and a power supply line,

wherein the anode electrode comprises a plurality of independent electrodes so formed as to correspond to a predetermined number of the unit fluorescence layers, and

each independent electrode is connected to an anode electrode driving circuit through the power supply line.

The display device according the second aspect of the present invention for achieving the above second object is a display device using the display panel according to the second aspect of the present invention,

wherein the display panel and a rear panel having a plurality of electron emitting members are arranged to be opposed to each other through a vacuum space,

the display device comprises a substrate, a plurality of unit fluorescence layers which are to be caused to emit light by electrons emitted from the electron emitting members into the vacuum space, an anode electrode which is to direct the electrons toward the unit fluorescence layers, and a power supply line,

the anode electrode comprises a plurality of independent electrodes so formed as to correspond to a predetermined number of the unit fluorescence layers, and

each independent electrode is connected to an anode electrode driving circuit through the power supply line.

The display panel and the display device according to the second aspect of the present invention are based on a basic thought that, instead of preventing the trigger to a discharge, an energy to be stored or accumulated, for example, between the anode electrode and the cathode electrode is controlled to be at a level at which it is not promoted to grow to a spark discharge, so that a discharge of a small scale, if any, is not grown to a spark discharge. Since the anode electrode is formed to have a form of divided independent electrodes having a smaller area each, instead of being so formed as to extend on the entire effective region, the electrostatic capacitance, for example, between the anode electrode and the cathode electrode can be decreased, so that a stored or accumulated energy can be decreased.

The above unit fluorescence layer is defined to a fluorescence layer which generates one bright point on the display panel. In the industrial field of display devices such as a color cathode ray tube, etc., a combination of three fluorescence layers such as a red fluorescence layer, a green fluorescence layer and a blue fluorescence layer corresponding to the three primary colors of R (red), G (green) and B (blue) is called “pixel”, and it is often used as a technical unit for a screen fineness. However, the unit fluorescence layer in the present invention differs from the above pixel. The above definition applies to display panels according to all the aspects of the present invention excluding the first aspect of the present invention and also applies to display devices according to all the aspects of the present invention excluding the first aspect of the present invention.

The power supply line may comprise a plurality of unit power supply lines and each unit power supply line is connected to each independent electrode. That is, each unit power supply line is so formed as to correspond to each independent electrode. Such a constitution will be referred to as “second-A constitution”. Each unit power supply line can be connected to the anode electrode driving circuit by extending each unit power supply line on an idle region to a connecting terminal provided, for example, on one portion of a peripheral area of the display panel and by providing a line from the connecting terminal to the anode electrode driving circuit.

Further, a resistance member may be inserted somewhere in, for example, the middle of each unit power supply line. Such a constitution will be referred to as “second-B constitution”. When a discharge takes place, the supply of energy from the anode electrode driving circuit can be temporarily discontinued by providing the resistance member. In the second-B constitution, for example, a chip resistor may be inserted, or a resistance film may be formed, as a resistance member somewhere in the middle of each unit power supply line on the idle region. The resistance value of the resistance member is set at a value which is small to such an extent that a voltage drop caused by an anode current during general display operation has almost no effect on the display brightness and which is large to such an extent that the supply of an energy to the anode electrode from the anode electrode driving circuit through the unit power supply line can be virtually shut off when a discharge of a small scale takes place. The above basic thought of dividing the anode electrode and using the resistance member applies also to a display panel and a display device according to a third aspect of the present invention which will be discussed later.

The display panel and the display device according to the second aspect of the present invention may have a constitution in which the independent electrodes are so arranged in a matrix form as to correspond to fluorescence layer groups consisting of a predetermined number of the unit fluorescence layers each, the power supply line has a main line and a plurality of branch lines branching from the main line, and all the independent electrodes included in columns or rows of the matrix are connected to the branch lines common to the columns or rows through resistance films. The above constitution will be referred to as “second-C constitution” hereinafter. The plane form of each independent electrode is not specially limited, while the plane form is preferably such that gaps between adjacent independent electrodes have no irregular sizes, in view of achieving a uniform brightness distribution in the effective region. The number of the branch lines branching from the main line and the branching direction thereof are not specially limited, either. However, the branch lines preferably have lengths which are as uniform as possible and uniform wiring resistances, in view of achieving a uniform brightness distribution in the effective region. Each branch line may further have a plurality of branch lines being branched therefrom.

In the second-C constitution, the number of the unit fluorescence layers constituting the fluorescence layer group corresponding to one independent electrode is not specially limited. From the viewpoint of a pixel unit of a color display device, one fluorescence layer group may contain the unit fluorescence layers to such a number that a plurality of the pixels can be constituted, or one fluorescence layer group may contain three unit fluorescence layers that can constitute one pixel. Further, one fluorescence layer group may contain one unit fluorescence layer. When one fluorescence layer group contains one unit fluorescence layer, there can be provided a constitution in which the electrostatic capacitance can be minimized in the display panel having an effective region of some finite size. In the display panel having the second-C constitution, preferably, the unit fluorescence layers are arranged in the form of a so-called dot matrix. The above description can also apply to a display panel having a third-A constitution according to a third aspect of the present invention.

In the display panel and the display device according to the second aspect of the present invention, the independent electrodes can be so arranged in the form of stripes as to correspond to the fluorescence layer group consisting of a plurality of the unit fluorescence layers. The above constitution will be referred to as “second-D constitution” hereinafter. The stripes may be extended in a length direction or a width direction when it is assumed that the effective region has a rectangular form. In the second-D constitution, preferably, the unit fluorescence layers are also arranged in the form of stripes. That is, in this constitution, the unit fluorescence layers for red (R) are arranged in one row to form a red fluorescence layer group, the unit fluorescence layers for green (G) are arranged in one row to form a green layer group, and the unit fluorescence layers for blue (B) are arranged in one row to form a blue fluorescence layer group. One independent electrode may correspond to one row of the fluorescence layer groups of one color, may correspond to a combination of three rows of the fluorescence layer groups of three primary colors, or may correspond to a plurality of combinations of three rows of the fluorescence layer groups of three primary colors. The above description can also apply to a display panel having a third-B constitution according to a third aspect of the present invention.

In the display panel and the display device according to the second aspect of the present invention, the independent electrodes and the power supply line can be composed of a common conductive material layer on the substrate. For example, a conductive material layer composed of a conductive material is formed on the substrate, and the conductive material layer is patterned, whereby the independent electrodes and the power supply line can be simultaneously formed. Otherwise, a conductive material is deposited or screen-printed through a mask or a screen having a pattern of the independent electrodes and the power supply line, whereby the independent electrodes and the power supply line can be simultaneously formed on the substrate. In the display panel having the second-C or second-D constitution, the resistance film can be also formed in the same manner as above. That is, a resistance film composed of a resistance material may be formed on the substrate and patterned to form the resistance member, or a resistance material may be deposited or printed through a mask or a screen having a resistance member pattern, to form the resistance film.

Even in a case where neither the resistance member nor the resistance film is formed on the display panel side, the resistance member(s) may be provided in the anode electrode driving circuit, and the power supply line can be connected to such an anode electrode driving circuit. When a discharge of a small scale takes place between the rear panel and the display panel, therefore, the supply of energy from the anode electrode driving circuit to the anode electrodes through the power supply line can be temporarily shut off to prevent the occurrence of a spark discharge.

The above second-A to second-D constitutions are based on the classification made, in a sense, in view of arrangements of the power supply line and the resistance member or the resistance film and of the formation pattern of the independent electrodes. The display panel and the display device according to the second aspect of the present invention can structurally include the following five cases (1) to (5). That is,

(1) a case where the unit fluorescence layers are formed on the substrate and the independent electrodes are formed on the unit fluorescence layers,

(2) a case where the independent electrodes are formed on the substrate and the unit fluorescence layers are formed on the independent electrodes,

(3) a case where each of the independent electrodes comprises a lower electrode and an upper electrode, the lower electrode is formed on the substrate, the unit fluorescence layer is formed on the lower electrode, and the upper electrode is formed on the unit fluorescence layer and the lower electrode,

(4) a case where each of the independent electrodes comprises a lower electrode and an upper electrode, the unit fluorescence layer is formed on the substrate, the lower electrode is formed on the unit fluorescence layer, and the upper electrode is formed on the lower electrodes, and

(5) a case where the independent electrodes are formed on the substrate, the resistance film extends over onto the independent electrode, and the unit fluorescence layer(s) is (are) formed on the resistance film.

In the case (5), further, an adhesive layer may be formed between the resistance film and the independent electrode and/or between the resistance film and the unit fluorescence layer. In the cases (3) and (4) in which the independent electrodes comprise the upper electrodes and the lower electrodes, not only the second object of the present invention but also the first object of the present invention can be achieved.

In each of these cases (1) to (5), it is determined depending upon which material is used for forming the independent electrodes and the resistance member, a transparent material or non-transparent (reflective) material, whether the material constituting the substrate is transparent or non-transparent. As a consequence, it is determined whether the display device is a transmission type or a reflection type when the display panel is incorporated into the display device.

In view of the above conditions, the case (1) can be further classified into follows. Of these, the case (1-1) is the most excellent in the compatibility with an existing production process for the production of a display panel. That is, the independent electrodes and the power supply line can be constituted by utilizing a conventional conductive material layer used as a conductive reflective layer (corresponding to the metal-back layer of a cathode ray tube).

independent

Type of

Case

electrode

substrate

display device

(1-1)

N-TP

TP

TR

(1-2)

TP

TP

TR or RF

(1-3)

TP

N-TP

RF

In view of the above conditions, the case (2) can be further classified into follows. Of these cases, the case (2-2) is the most excellent in the compatibility with an existing production process for the production of a display panel. That is, the independent electrodes and the power supply line can be constituted by utilizing a conventional layer used as a transparent conductive layer.

independent

Type of

Case

electrode

substrate

display device

(2-1)

N-TP

TP or N-TP

RF

(2-2)

TP

TP

TR or RF

(2-3)

TP

N-TP

RF

The case (3) can be classified into (i-1) to (i-4) explained in the first aspect of the present nvention. Further, the case (4) can be classified into (ii-1) to (ii-4) explained in the first aspect of the present invention.

In view of the above conditions, the case (5) can be further classified into follows.

resistance

independent

Type of

Case

film

electrode

substrate

display device

(5-1)

N-TP

TP or N-TP

TP or N-TP

RF

(5-2)

TP

N-TP

TP or N-TP

RF

(5-3)

TP

TP

N-TP

RF

(5-4)

TP

TP

TP

TR or RF

When the adhesive layer is formed between the resistance film and the independent electrode and/or between the resistance film and the fluorescence layer, there can be further many cases depending upon whether the adhesive layer is transparent or non-transparent. In these cases, however, the above discussion can apply to whether the display device is a transmission type or a reflection type. That is, when a transmission type display device is constituted, not only the substrate is required to be transparent, but also all the layers present between the fluorescence layer and the substrate are required to be transparent. When a reflection type display device is constituted, all the components for the rear panel present in the effective region are required to be transparent.

The display panel according to a third aspect of the present invention for achieving the above second object is a display panel comprising a substrate, a plurality of unit fluorescence layers which are to be caused to emit light by electrons from a vacuum space, and an anode electrode which is to direct the electrons toward the unit fluorescence layers,

wherein the anode electrode comprises a plurality of independent electrodes so formed as to correspond to a predetermined number of the unit fluorescence layers,

the display panel has a power supply layer formed on the substrate, an insulating layer formed on the power supply layer, the unit fluorescence layers formed on the power supply layer or the insulating layer, the independent electrodes formed on the unit fluorescence layers and the insulating layer, holes formed in the insulating layer, and resistance layers buried in the holes, and

the independent electrode is connected to the power supply layer with the resistance layer.

The display device according to a third aspect of the present invention for achieving the above second object is a display device in which the display panel according to the third aspect of the present invention is used,

wherein the display panel and a rear panel having a plurality of electron emitting members are arranged to be opposed to each other through a vacuum space,

the display panel comprises a substrate, a plurality of unit fluorescence layers which are to be caused to emit light by electrons emitted from the electron emitting members into the vacuum space, and an anode electrode which is to direct the electrons toward the unit fluorescence layers,

the anode electrode comprises a plurality of independent electrodes so formed as to correspond to a predetermined number of the unit fluorescence layers,

the display panel has a power supply layer formed on the substrate, an insulating layer formed on the power supply layer, the unit fluorescence layers formed on the power supply layer or the insulating layer, the independent electrodes formed on the unit fluorescence layers and the insulating layer, holes formed in the insulating layer, and resistance layers buried in the holes, and

the independent electrode is connected to the power supply layer with the resistance layer.

In the display panel and the display device according to the third aspect of the present invention, the power supply means for supplying a positive voltage to the independent electrodes from the anode electrode driving circuit is not a power supply “line” but a power supply “layer”. In the display panel and the display device according to the third aspect of the present invention, the power supply means and the independent electrodes are three-dimensionally arranged through the insulating layer. Unlike the display panel and the display device according to the second aspect of the present invention, therefore, it is no longer necessary to figure out a layout of the power supply means and the independent electrodes in one plane, and the power supply means can be formed on the entire surface of the effective region. However, the power supply layer can have any predetermined pattern without any problem. In the display panel and the display device according to the third aspect of the present invention, a charge is removed from the unit fluorescence layers through both the power supply layer and the independent electrodes, so that the first object of the present invention can be also achieved.

In the display panel and the display device according to the third aspect of the present invention, when a plurality of the unit fluorescence layers are formed on the power supply layer, the unit fluorescence layers are in contact with both the power supply layer and the independent electrodes and are therefore required to have good insulating properties, while the display panel is advantageously decreased in thickness since the unit fluorescence layers and the insulating layer are formed nearly in the same plane. When a plurality of the unit fluorescence layers are formed on the insulating layer, it is not critical whether or not the unit fluorescence layers have good insulating properties.

In the display panel and the display device according to the third aspect of the present invention, there may be employed a constitution in which the independent electrodes are so arranged in a matrix form as to correspond to fluorescence layer groups consisting of a predetermined number of the unit fluorescence layers. The above constitution will be referred to as “third-A constitution” hereinafter. The number of the unit fluorescence layers constituting the unit fluorescence layer group corresponding to one independent electrode is not specially limited, and it may be one. In the display panel and the display device according to the third aspect of the present invention, there may be employed a constitution in which the independent electrodes are so arranged in the form of stripes as to correspond to fluorescence layer groups consisting of a plurality of the unit fluorescence layers. The above constitution will be referred to as “third-B constitution” hereinafter.

In the display panel according to the third aspect of the present invention, it is also determined depending upon which material is used for forming the independent electrodes, a transparent material or non-transparent (reflective) material, whether the material constituting the substrate is transparent or non-transparent. As a consequence, it is determined whether the display device is a transmission type or a reflection type when the display panel is incorporated into the display device. That is, when a plurality of the unit fluorescence layers are formed on the power supply layer, the same discussion as the discussion of the cases (i-1) to (i-4) can be made by replacing the upper electrode in the previous case (i) with the independent electrode and replacing the lower electrode in the previous case (i) with the power supply layer. When a plurality of the unit fluorescence layers are formed on the insulating layer, it is further required to consider whether the insulating layer is transparent or non-transparent. That is, when the independent electrodes are non-transparent, the substrate and all the layers present between the unit fluorescence layers and the substrate are required to be transparent, and a transmission type display panel can be constituted. When the independent electrodes are transparent, transmission type and reflection type display panels can be constituted if all of the substrate, the power supply layer and the insulating layer are transparent, and a reflection type display panel can be constituted if at least one of the above layers is non-transparent.

In the display device according to each of the first to third aspects of the present invention, a cold cathode field emission device (to be referred to as “field emission device” hereinafter) is preferred as an electron emitting member. The type of the field emission device is not specially limited, and it can be any one of a Spindt type field emission device, an edge type field emission device, a flat type field emission device, a low-profile type field emission device and a crown type field emission device. Generally, the electron emitting member(s) is arranged in a region where each of projection images of a first electrode group extending in one direction in which scanning signals are inputted and a second electrode group extending in the other direction in which video signals are inputted overlaps each other. In the display device according to each of the second and third aspects of the present invention, preferably, the independent electrodes are arranged in the form of stripes and extend in a direction nearly in parallel with the direction of the second electrode group for achieving the third object of the present invention to prevent a variability of brightness in a display screen caused depending upon the number of selected electrodes of the second electrode group. When the first electrode group comprises gate electrodes, the second electrode group comprises cathode electrodes. When the first electrode group comprises cathode electrodes, the second electrode group comprises gate electrodes.

As a field emission device, a device called a surface conductive type electron emission device is also known in addition to the above types and can be applied to the display device according to any one of the first to third aspects of the present invention. The surface conductive type electron emission device has a constitution in which thin layers of tin oxide (SnO

2

), gold (Au), indium oxide (In

2

O

3

)/tin oxide (SnO

2

) or palladium oxide (PdO) having a very small area are formed on a substrate composed, for example, of glass and in the form of a matrix, each thin layer comprises two thin layer pieces, a column-direction wiring is connected to one thin layer piece and a row-direction wiring is connected to the other thin layer piece. There is provided a gap of several nano meter between one thin layer piece and the other thin layer piece. The thin layer selected with the column-direction wiring and the row-direction wiring emits electrons through the gap. When the first electrode group comprises the column-direction wirings, the second electrode group comprises the row-direction wirings. When the first electrode group comprises the row-direction wirings, the second electrode group comprises the column-direction wirings.

In the display panel and the display device according to all the aspects of the present invention, the substrate can be any substrate so long as the surface thereof comprises an insulation member. The substrate includes a glass substrate, a glass substrate having a surface on which an insulating film is formed, a quartz substrate, a quartz substrate having a surface on which an insulating film is formed and a semiconductor substrate having a surface on which an insulating film is formed. The substrate is not necessarily required to be transparent when it is used for constituting a reflection type display panel and a reflection type display device. Each of the above substrates may be used for constituting a supporting member for the rear panel.

Examples of materials for constituting the independent electrode, the power supply line, the power supply layer, the lower electrode, the upper electrode, the first electrode group and the second electrode group include metals such as tungsten (W), niobium (Nb), tantalum (Ta), molybdenum (Mo), chromium (Cr), aluminum (Al), copper (Cu), gold (Au), silver (Ag), titanium (Ti) and nickel (Ni), alloys or compounds of these metal elements (e.g., nitrides such as TiN and silicides such as WSi

2

, MoSi

2

, TiSi

2

and TaSi

2

), conductive metal oxides such as ITO (indium-tin oxide), indium oxide and zinc oxide, and semiconductor such as silicon. When the above members are formed, a thin layer of the above material is formed on a substratum by a known thin film forming method such as a chemical vapor deposition method, a sputtering method, a vapor deposition method, an ion plating method, an electroplating method, an electroless plating method, a screen-printing method, a laser abrasion method or a sol-gel method. When the thin film is formed on the entire surface of a substratum, the thin film is patterned by a known patterning method to form each member. Each member can be formed by a lift-off method by forming a resist pattern on the substratum prior to the formation of the thin film. Further, the patterning after the formation of the layer is not required if the vapor deposition is carried out with a mask having openings corresponding to the form of the independent electrode or the power supply line or screen-printing is carried out through a screen having the above openings.

Typical examples of the material for constituting the resistance film or the resistance layer include carbon-containing materials, semiconductor materials such as amorphous silicon and refractory metal oxides such as tantalum oxide. The resistance film can be formed by the same method as the method of forming the above members such as the independent electrode and the power supply line. The pattern width and thickness of the resistance film are determined such that the resistance value is small to such an extent that a voltage drop caused by an current flowing from the display panel toward the rear panel during general display operation has almost no effect on the display brightness and that the resistance value is large to such an extent that the supply of energy to the anode electrode from the anode electrode driving circuit through the power supply line or the power supply layer can be virtually shut off when a discharge of a small scale takes place. The resistance value can be set between several tens kΩ and several hundreds MΩ. This resistance value can also apply to the resistance member such as a chip resistor. As a typical material for constituting the adhesive layer, titanium (Ti) can be used.

In the display panel and the display device according to the third aspect of the present invention, the material for constituting the insulating layer includes SiO

2

, SiN, SiON, SOG (spin on glass) and a glass paste cured product. These materials can be used alone or in combination. The insulating layer can be formed by a known method such as a chemical vapor deposition method, an application method, a sputtering method or a screen-printing method. The above materials and the above method can be applied to the formation of the insulating interlayer which is a component of the cold cathode field emission device.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will be explained hereinafter with reference to Examples by referring to drawings.

FIGS. 1A

,

1

B and

1

C are schematic partial cross-sectional views of display panels having an anode electrode having a two-layered structure in Example 1.

FIGS. 2A

,

2

B and

2

C are schematic partial cross-sectional views of other display panels having an anode electrode having a two-layered structure in Example 1.

FIG. 3

shows a conceptual view of the display device of Example 1.

FIGS. 4A and 4B

are graphs showing brightness lifetime characteristics of the display devices of Example 1.

FIG. 5A

is a schematic partial plan view and

FIGS. 5B

,

5

C,

5

D and

5

E are schematic partial cross-sectional views of display panels of Example 2 in which independent electrodes are arranged in a matrix form.

FIGS. 6A

,

6

B,

6

C and

6

D are schematic partial cross-sectional views of other display panels taken along X—X line in FIG.

5

A.

FIG. 7

is a conceptual view of the display device of Example 2.

FIGS. 8A

,

8

B and

8

C are schematic partial cross-sectional views showing combinations of materials constituting an independent electrode and a substrate.

FIGS. 9A

,

9

B,

9

C and

9

D are schematic partial cross-sectional views showing other combinations of materials constituting an independent electrode and a substrate.

FIGS. 10A

,

10

B,

10

C,

10

D and

10

E are schematic partial cross-sectional views showing other combinations of materials constituting an independent electrode and a substrate.

FIGS. 11A

,

11

B,

11

C and

11

D are schematic partial cross-sectional views showing other combinations of materials constituting a resistance film, an independent electrode and a substrate.

FIG. 12A

is a schematic partial plan view and

FIGS. 12B

,

12

C,

12

D and

12

E are schematic partial cross-sectional views of display panels of Example 3 in which independent electrodes are arranged in the form of a matrix.

FIGS. 13A and 13B

are schematic plan views of display panels of Example 4 in which independent electrodes are arranged in the form of stripes.

FIGS. 14A

,

14

B,

14

C and

14

D are partial cross-sectional views of other display panels taken along X—X line in FIG.

13

B.

FIG. 15A

is a schematic plan view of a display panel of Example 5 in which unit power supply lines are provided and independent electrodes are arranged nearly in parallel with cathode electrodes, and

FIG. 15B

is a schematic plan view of a rear panel which is arranged to be opposed to the display panel.

FIGS. 16A and 16B

are schematic plan views of other configuration examples of the display panel of Example 5.

FIGS. 17A and 17B

are schematic plan views of a display panel of Example 6 in which independent electrodes are arranged in the form of a matrix.

FIGS. 18A and 18B

are partial cross-sectional views of display panels taken along an X—X line in FIG.

17

A.

FIGS. 19A and 19B

are schematic plan views of a display panel of Example 7 in which independent electrodes are arranged in the form of a matrix.

FIGS. 20A and 20B

are partial cross-sectional views of display panels taken along an X—X line in FIG.

19

A.

FIG. 21A

is a schematic partial plan view and

FIGS. 21B and 21C

are schematic partial cross-sectional views of display panels of Example 8 in which independent electrodes are arranged in the form of stripes.

FIGS. 22A

,

22

B and

23

C are schematic partial cross-sectional views of edge type cold cathode field emission devices.

FIG. 23A

is a schematic partial cross-sectional view of a flat type cold cathode field emission device,

FIG. 23B

is a schematic partial cross-sectional view of a low-profile type cold cathode field emission device, and

FIG. 23C

is a schematic partial cross-sectional view of a crown type cold cathode field emission device.

FIG. 24

is a conceptual view of a conventional display device having field emission devices.

FIG. 25A

is a schematic partial plan view and

FIGS. 25B and 25C

are schematic partial cross-sectional views of conventional display panels in which fluorescence layers are arranged in the form of a matrix.

FIG. 26A

is a schematic partial plan view and

FIGS. 26B and 26C

are schematic partial cross-sectional views of conventional display panels in which fluorescence layers are arranged in the form of stripes.

FIGS. 27A and 27B

are schematic plan views of a rear panel for explaining a variance of acceleration voltage caused by a difference in the selected number of cathode electrodes.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

EXAMPLE 1

Example 1 is concerned with a display panel and a display device according to the first aspect of the present invention.

FIGS. 1A

to

1

C show schematic partial cross-sectional views of the display panels of the case (i),

FIGS. 2A

to

2

C show schematic partial cross-sectional views of the display panels of the case (ii),

FIG. 3

shows a conceptual view of the display device, and

FIGS. 4A and 4B

show brightness lifetime characteristics of the display devices.

FIGS. 1A

to

1

C show configuration examples of three types of the display panels belonging to the case (i). An anode electrode

4

comprises a lower electrode

2

and an upper electrode

3

, the lower electrode

2

is formed on a substrate

1

, a fluorescence layer

5

is formed on the lower electrode

2

, and the upper electrode

3

is formed on the fluorescence layer

5

. The display panel shown in

FIG. 1A

is intended to be a display panel for monochromatic displaying, and the fluorescence layer for emitting light, for example, of green (G) is formed on the entire surface of an effective region. The lower electrode

2

and the upper electrode

3

are electrically connected to each other on a region (not shown), for example, in a peripheral portion of the effective region. The display panel shown in

FIG. 1B

is intended to be a display panel for full color displaying, and the fluorescence layers

5

for emitting light of red (R), green (G) and blue (B), respectively, are formed in a predetermined pattern. The upper electrode

3

is so formed on the fluorescence layers

5

as to reach the surface of the lower electrode

2

.

FIG. 1C

shows a display panel formed by modifying the display panel shown in

FIG. 1B

by filling gaps between the fluorescence layer

5

and the fluorescence layer

5

with a black-matrix layer

6

. The upper electrode

3

is formed on the fluorescence layers

5

and the black-matrix layer

6

. The lower electrode

2

and the upper electrode

3

are electrically connected to each other on a region (not shown), for example, in a peripheral portion of the effective region. In the display panel for monochromatic displaying, the fluorescence layer

5

may be formed in a predetermined pattern, or further, gaps between the fluorescence layer

5

and the fluorescence layer

5

may be filled with a black-matrix layer

6

.

The display panel shown in

FIG. 1A

is manufactured as follows. First, the lower electrode

2

of ITO having a thickness of approximately 0.01 to 0.5 μm, preferably, approximately 0.05 to 0.2 μm (typically, approximately 0.05 μm) is formed on the entire surface of the effective region on the substrate

1

composed, for example, of glass, by a sputtering method or a sol-gel method. Then, the fluorescence layer

5

is formed on the lower electrode

2

by a screen-printing method or a slurry method. When the screen-printing method is used, a fluorescence composition containing fluorescence particles is screen-printed on the lower electrode

2

, followed by drying and sintering, whereby the fluorescence layer

5

can be formed. When the slurry method is used, a slurry containing fluorescence particles and a photo-sensitive polymer is applied onto the lower electrode

2

to form a coating, and the photo-sensitive polymer is insolubizied to a developer solution by exposure, whereby the fluorescence layer

5

can be formed. Then, the upper electrode

3

of aluminum (Al) is formed as a layer having a thickness of approximately 0.01 to 0.5 μm, preferably, approximately 0.05 to 0.1 μm (typically, approximately 0.1 μm), for example, by a sputtering method. As a material for the upper electrode

3

, the aluminum may be replaced with nickel (Ni) or silver (Ag). When the display panel shown in

FIG. 1B

is manufactured, the fluorescence layer can be formed by a screen-printing method or a slurry method which consecutively uses three fluorescence compositions or slurries containing Y

2

O

2

S:Eu as fluorescence particles for emitting red light, ZnS:Cu,Al as fluorescence particles for emitting green light and ZnS:Ag,Al or ZnS:Ag,Cl as fluorescence particles for emitting blue light. Further, when the display panel shown in

FIG. 1C

is manufactured, the black-matrix layer

6

is formed on the lower electrode

2

, and then the fluorescence layer

5

can be formed by a screen-printing method or a slurry method consecutively using the three fluorescence compositions or slurries.

FIGS. 2A

to

2

C show configuration examples of three types of the display panels belonging to the case (ii). An anode electrode

4

comprises a lower electrode

2

and an upper electrode

3

, a fluorescence layer

5

is formed on a substrate

1

, the lower electrode

2

is formed on the fluorescence layer

5

, and the upper electrode is formed on the lower electrode

2

. The display panel shown in

FIG. 2A

is intended to be a display panel for monochromatic displaying, and the fluorescence layer

5

for emitting light, for example, of green (G) is formed on the entire surface of an effective region. The display panel shown in

FIG. 2B

is intended to be a display panel for full color displaying, and the fluorescence layers

5

for emitting light of red (R), green (G) and blue (B), respectively, are formed in a predetermined pattern. The lower electrode

2

is so formed on the fluorescence layers

5

as to reach the surface of the substrate

1

.

FIG. 2C

shows the display panel formed by modifying the display panel shown in

FIG. 2B

by filling gaps between the fluorescence layer

5

and the fluorescence layer

5

with a black-matrix layer

6

. The lower electrode

2

is formed on the fluorescence layers

5

and the black-matrix layer

6

. In the display panel for monochromatic displaying, the fluorescence layer

5

may be formed in a predetermined pattern, or further, gaps between the fluorescence layer

5

and the fluorescence layer

5

may be filled with a black-matrix layer

6

.

The display panel shown in

FIG. 2A

can be manufactured as follows. First, the fluorescence layer is formed on the entire surface of an effective region on the substrate

1

composed, for example, of glass, by a screen-printing method or a slurry method. Then, the lower electrode

2

of ITO having a thickness of approximately 0.05 μm is formed on the fluorescence layer

5

by a sputtering method or a sol-gel method. Then, the upper electrode

3

, for example, of aluminum having a thickness of approximately 0.1 μm is formed on the lower electrode

2

by a sputtering method. When the display panel shown in

FIG. 2B

is manufactured, the fluorescence layers

5

can be formed by a screen-printing method or a slurry method consecutively using three fluorescence compositions or three slurries corresponding to three primary colors. When the display panel shown in

FIG. 2C

is manufactured, the black-matrix layer

6

is formed on the substrate

1

, and then the fluorescence layers

5

can be formed by a screen-printing method or a slurry method consecutively using the three fluorescence compositions or slurries.

FIG. 3

shows a configuration example of the display device using the display panel shown in FIG.

1

B. In the display device, the display panel

7

and a rear panel

300

are arranged to be opposed to each other, and these panels

7

and

300

are bonded to each other in circumferential end portions through a frame (not shown) to form a closed space between the panels

7

and

300

as a vacuum space VAC. The rear panel

300

has cold cathode field emission devices (to be referred to as “field emission devices” hereinafter) as electron emitting members. In

FIG. 3

, so-called Spindt type field emission devices having conical electron emitting portions

35

are shown as an example of the field emission device. Each Spindt type field emission device comprises a cathode electrode

31

formed on a supporting member

30

, an insulating interlayer

32

formed on the cathode electrode

31

and the supporting member

30

, a gate electrode

34

formed on the insulating interlayer

32

, and the conical electron emitting portion

35

formed in an opening portion

33

formed in the gate electrode

34

and the insulating interlayer

32

. In

FIG. 3

, a plurality of the electron emitting portions

35

correspond to one unit fluorescence layer

5

. The electron emitting portions

35

have a very small structure, and in some actual cases, several hundreds to several thousands electron emitting portions

35

are provided per pixel. A relatively negative voltage (video signal) is applied to the electron emitting portions

35

from a cathode electrode driving circuit

36

through the cathode electrode

31

, and a relatively positive voltage (scanning signal) is applied to the gate electrode

34

from a gate electrode driving circuit

37

. Electrons are emitted from the tips of the electron emitting portions

35

depending upon an electric field generated by the application of the above voltages. A positive voltage higher than the positive voltage applied to the gate electrode

34

is applied to the lower electrode

2

of the display panel

7

from an anode electrode driving circuit

8

, so that the electrons emitted from the electron emitting portions

35

are directed toward the fluorescence layer

5

. The electron emitting member is not limited to the above Spindt type field emission device, and it can be also selected from field emission devices of other types such as a so-called edge type field emission device, a flat type field emission device, a low-profile type field emission device and a crown type field emission device.

The display panels shown in

FIGS. 1A and 1C

and

FIGS. 2A

to

2

C can be also used for constituting display devices. Further, in the explanations, the lower electrode

2

is composed of transparent ITO, the upper electrode

3

is composed of non-transparent (reflective) aluminum, and the substrate

1

is composed of glass, so that the display device is constituted as a transmission type. However, a reflection type display device or transmission type display device can be constituted depending upon some materials for constituting the above members. Configuration examples thereof will be explained later in Example 2.

FIGS. 4A and 4B

show brightness lifetime characteristics of the above display devices.

FIG. 4A

shows brightness lifetime characteristics of the display device into which the display panel of the case (i) shown in

FIG. 1B

is incorporated and a display device into which the same display panel manufactured in the same manner as above except for the formation of the lower electrode

2

is incorporated.

FIG. 4B

shows brightness lifetime characteristics of the display device into which the display panel of the case (ii) shown in

FIG. 2B

is incorporated and a display device into which the same display panel manufactured in the same manner as above except for the formation of the lower electrode

2

is incorporated. The above display devices are measured under conditions of 6 kilovolts of acceleration voltage and 10 μA/cm

2

of a current density. When no lower electrode

2

is formed, the brightness sharply decreases near to a finally stabilized level in the first 500 hours after initiation of the measurement, and the finally stabilized level decreases to less than 40% of the value found immediately after initiation of the measurement. When the lower electrode

2

is formed, both the display devices into which the display panels of the cases (i) and (ii) are incorporated show a moderate decrease in the brightness, and even after 1300 hours after initiation of the measurement, clearly, the display devices keep approximately 80% of the brightness value found immediately after initiation of the measurement.

EXAMPLE 2

Example 2 is concerned with a display panel according to the second-C constitution and a display device according to the second aspect of the present invention.

FIG. 5A

is a schematic partial plan view and

FIGS. 5B

to

5

E and

FIGS. 6A

to

6

D are schematic partial cross-sectional views of the display panels of Example 2.

FIG. 7

shows a conceptual view of the display device.

FIGS. 8A

to

8

C,

FIGS. 9A

to

9

D,

FIGS. 10A

to

10

E and

FIGS. 11A

to

11

D show patterns of combinations of an independent electrode and a substrate.

In a display panel

100

of Example 2, an anode electrode comprises a plurality of independent electrodes

13

so formed as to correspond to a predetermined number of unit fluorescence layers as shown in

FIG. 5A. A

plurality of these independent electrodes

13

are arranged as a whole to nearly cover the effective region. A power supply line is formed on a rectangular substrate

10

composed, for example, of glass, and the power supply line comprises one main line

14

extending in the width direction of the substrate

10

and a plurality of branch lines

24

extending in parallel with the length direction of the rectangular substrate

10

(column direction). Each independent electrode

13

is connected to the power supply line through a resistance film

11

. More specifically, the independent electrodes

13

forming one column are connected to one common branch line

24

extending in the column direction, and the independent electrodes

13

forming another column are connected to another common branch line

24

. The main line

14

is connected to a connecting terminal (not shown) through a lead portion

15

, and the connecting terminal is connected to an anode electrode driving circuit. In

FIG. 5A

, the anode electrode driving circuit is shown by a symbol of a power source (5 kV) for simplification. Each independent electrode

13

has a rectangular form as an example, and each independent electrode

13

is so formed as to correspond to a fluorescence layer group Gr consisting of three unit fluorescence layers

12

R,

12

G and

12

B. The unit fluorescence layer

12

R emits red light, the unit fluorescence layer

12

G emits green light, and the unit fluorescence layer

12

B emits blue light, so that the above fluorescence layer group Gr corresponds to one pixel of a general full color display device. The number of the unit fluorescence layers constituting the fluorescence layer group Gr shall not be limited to 3.

The display panel

100

shown in

FIG. 5A

includes eight structural cases shown in

FIGS. 5B

to

5

E and

FIGS. 6A

to

6

D depending upon constitutions of the independent electrodes.

FIGS. 5B

to

5

E and

FIGS. 6A

to

6

D shows partial cross-sectional views taken along an X—X line in FIG.

5

A. The constitution shown in

FIG. 5B

corresponds to the case (1) where the unit fluorescence layers

12

R,

12

G and

12

B are formed on the substrate

10

and an independent electrode

13

A is formed on the unit fluorescence layers

12

R,

12

G and

12

B. The case (1) is the most highly consistent with an existing production process when only a conductive reflective layer typified by a metal-back layer is used for constituting the independent electrode

13

A. The constitution shown in

FIG. 5C

corresponds to the case (2) where an independent electrode

13

B is formed on the substrate

10

and the unit fluorescence layers

12

R,

12

G and

12

B are formed on the independent electrode

13

B. The case (2) is the most highly consistent with an existing production process when a transparent conductive layer typified by an ITO layer is used for constituting the independent electrode

13

B. The constitution shown in

FIG. 5D

corresponds to the case (3) where an independent electrode

13

C comprises a lower electrode

131

and an upper electrode

132

, the lower electrode

131

is formed on the substrate

10

, the unit fluorescence layers

12

R,

12

G and

12

B are formed on the lower electrode

131

, and the upper electrode

132

is formed on the unit fluorescence layers

12

R,

12

G and

12

B and the lower electrode

131

. The case (3) corresponds to the constitution where the anode electrode is divided into a plurality of independent regions in the case (i) in the first aspect of the present invention.

FIG. 5E

corresponds to the case (4) where an independent electrode

13

D comprises a lower electrode

131

and an upper electrode

132

, the unit fluorescence layers

12

R,

12

G and

12

B are formed on the substrate

10

, the lower electrode

131

is formed on the unit fluorescence layers

12

R,

12

G and

12

B, and the upper electrode

132

is formed on the lower electrode

131

. The case (4) corresponds to the constitution in which the anode electrode is divided into a plurality of independent regions in the case (ii) in the first aspect of the present invention.

The constitution shown in

FIG. 6A

corresponds to the case (5) where an independent electrode

13

B is formed on the substrate

10

, a resistance film

11

is extended onto the independent electrode

13

B, and the unit fluorescence layers

12

R,

12

G and

12

B are formed on the resistance film

11

.

FIG. 6B

shows an embodiment in which an adhesive layer

16

is formed between the resistance film

11

and the independent electrode

13

B in the case (5).

FIG. 6C

shows an embodiment in which an adhesive layer

16

is formed between the resistance film

11

and the unit fluorescence layers

12

R,

12

G and

12

B in the case (5) Further,

FIG. 6D

shows an embodiment in which an adhesive layer is formed between the resistance film

11

and the independent electrode

13

B and an adhesive layer is formed between the resistance film

11

and the unit fluorescence layers

12

R,

12

G and

12

B in the case (5).

In the constitutions shown in

FIGS. 5B

,

5

D and

5

E, when a conductive reflective layer composed of a metal such as aluminum is used for forming the independent electrode

13

A and the upper electrode

132

, typically, the independent electrode

13

A and the upper electrode

132

can be formed by a vapor deposition method using a metal mask. In the constitutions shown in

FIGS. 5C

to

5

E and

FIGS. 6A

to

6

D, when a transparent conductive layer is used for forming the independent electrode

13

B and the lower electrode

131

, typically, the independent electrode

13

B and the lower electrode

131

can be formed by forming a layer of a transparent conductive material on the entire surface and patterning the layer.

Meanwhile, in

FIG. 5B

, a branch line

24

A and the independent electrode

13

A are composed of the same conductive material layer. In FIG.

5

C and

FIGS. 6A

to

6

D, further, a branch line

24

B and the independent electrode

13

B are composed of the same conductive material layer. Further, in

FIGS. 5D and 5E

, the lower electrode

141

constituting branch lines

24

C and

24

D and the lower electrode

131

constituting independent electrode

13

C and

13

D are composed of the same conductive material layer, and the upper electrode

142

constituting the branch lines

24

C and

24

D and the upper electrode

132

constituting the independent electrodes

13

C and

13

D are composed of the same conductive material layer. Further, the main line

14

and the lead portion can be composed of the same conductive material layer as that of the independent electrodes

13

A,

13

B,

13

C and

13

D in these cases. That is, the independent electrode, the power supply line and the lead portion can be simultaneously formed.

In the constitutions shown in

FIGS. 5B

to

5

E, the resistance film

11

is formed on the substrate

10

first, and then the independent electrode

13

A or

13

B or the lower electrode

131

is formed. The order of the formation of these members may be reversed. That is, after the independent electrode and the power supply line are formed, the resistance film

11

may be so formed as to connect the branch line of the power supply line and the independent electrode. Further, in the constitutions shown in

FIGS. 5D and 5E

, the resistance film

11

may be formed after the upper electrode

132

is formed, or it may be formed after the lower electrode

131

or

141

is formed and before the upper electrode

132

or

142

is formed.

FIG. 7

shows a configuration of the display panel using the display panel

100

of

FIG. 5D

as an example. In the display device, the display panel

100

and the rear panel

300

are arranged to be opposed to each other, and these two panels

100

and

300

are bonded to each other in circumferential end portions through a frame (not shown) to form a closed space between these panels

100

and

300

as a vacuum space VAC. The rear panel

300

has the field emission devices. In

FIG. 7

, the Spindt type field emission devices having conical electron emitting portions

35

are shown as field emission devices. The electron emitting member is not limited to the above Spindt type field emission device, and it can be also selected from field emission devices of other types such as a so-called edge type field emission device, a flat type field emission device, a low-profile type field emission device and a crown type field emission device. Further, a different type field emission device such as a surface conductive type electron emitting device is used in some cases.

The constitution of the display device of Example 2 corresponds to a constitution in which the anode electrode is formed as divided portions instead of being formed on the entire surface of the effective region and each anode electrode is decreased in area. As a result, the electrostatic capacitance between the anode electrode (independent electrode

13

in Example 2) and the rear panel

300

is decreased, and energy stored or accumulated in the electrostatic capacitance can be no longer any energy which causes a discharge or causes it to continue. Further, each independent electrode

13

is connected to the anode electrode driving circuit not directly but through the resistance element

11

, so that the growth of a discharge of a small scale, if any, to a spark discharge can be prevented. In a low voltage type display device in which the gap between the display panel and the rear panel is relatively small, therefore, a high voltage can be applied to the anode electrode stably, so that the low brightness which is a disadvantage of the low voltage type can be overcome with retaining other inherent advantages of the low voltage type.

In the display panels

100

shown in

FIGS. 5B

to

5

E and

FIG. 6A

, the transmission or reflection type of the display device is finally obtained depending upon the combinations of transparent and/or non-transparent (reflective) materials used for constituting the independent electrode

13

A,

13

B,

13

C or

13

D, the resistance film

11

and the substrate

10

. The above combinations will be explained with reference to

FIGS. 8A

to

8

C,

FIGS. 9A

to

9

D,

FIGS. 10A

to

10

E and

FIGS. 11A

to

11

D.

FIGS. 8A

to

8

C show the combinations in the display panel shown in

FIG. 5B

,

FIGS. 9A

to

9

D show the combinations in the display panel shown in

FIG. 5C

,

FIGS. 10A

to

10

E show the combinations in the display panel shown in

FIG. 5D

, and

FIGS. 11A

to

11

D show the combinations in the display panel shown in FIG.

6

A. In

FIGS. 8A

to

11

D, the unit fluorescence layer

12

R alone is shown and showing of the unit fluorescence layers

12

G and

12

B are omitted for simplification.

The combination shown in

FIG. 8A

corresponds to the case (1) in which the independent electrode

13

A formed on the unit fluorescence layer

12

R is composed of a non-transparent material such as a conductive reflective layer. In this case, the display panel

100

can be obtained only when the substrate

10

is transparent, and a display device using the display panel shown in

FIG. 8A

is inevitably a transmission type. In contrast, when the independent electrode

13

A is composed of a transparent conductive layer such as an ITO layer, the substrate

10

can be transparent or can be non-transparent. That is, when the substrate

10

is transparent as shown in

FIG. 8B

, a transmission or reflection type display panel is constituted, and when the substrate

10

is non-transparent as shown in

FIG. 8C

, a reflection type display device is constituted.

The combinations shown in

FIGS. 9A and 9B

correspond to the case (2) in which the independent electrode

13

B formed between the substrate

10

and the unit fluorescence layer

12

R is composed of a non-transparent material such as a conductive reflective layer. In these cases, a reflection type display device is constituted regardless of whether the substrate

10

is transparent as shown in

FIG. 9A

or is non-transparent as shown in FIG.

9

B. FIG.

9

C and

FIG. 9D

show the constitutions in which the independent electrode

13

B is composed of a transparent material such as ITO. In these cases, when the substrate

10

is transparent as shown in

FIG. 9C

, a transmission or reflection type display device can be constituted, and when the substrate

10

is non-transparent as shown in

FIG. 9D

, a reflection type display device can be constituted.

The constitution shown in

FIG. 10A

corresponds to the case (3) in which the upper electrode

132

formed on the unit fluorescence layer

12

R is composed of a non-transparent material such as a conductive reflective layer. In this case, the display panel

100

can be obtained only when both the upper electrode

131

and the substrate

10

are transparent, and the display device using the display panel shown in

FIG. 10A

is inevitably a transmission type.

FIGS. 10B and 10C

show the constitutions in which the lower electrode

131

formed between the substrate

10

and the unit fluorescence layer

12

R is composed of a non-transparent material such as a conductive reflective layer. In these cases, a reflection type display device is constituted regardless of whether the substrate

10

is transparent as shown in

FIG. 10B

or is non-transparent as shown in FIG.

10

C. Further,

FIGS. 10D and 10E

show the constitutions in which both the lower electrode

131

and the upper electrode

132

are transparent. In these cases, when the substrate

10

is transparent as shown in

FIG. 10D

, a transmission or reflection type display device can be constituted, and when the substrate

10

is non-transparent as shown in

FIG. 10E

, a reflection type display device can be constituted. The combinations shown in

FIGS. 10A

to

10

E can similarly apply to the case (i) in the first aspect of the present invention.

The independent electrode

13

D comprising the lower electrode

131

and the upper electrode

132

in the case (4) corresponds to a constitution in which each of the lower electrode and the upper electrode in the case (ii) in the first aspect of the present invention is divided into a plurality of independent regions. When the upper electrode

132

of the independent electrode

13

D is composed of a non-transparent material such as a conductive reflective layer, the display panel can be constituted only when both the lower electrode

131

and the substrate

10

are transparent, and a transmission type display panel is inevitably constituted. Showing such a constitution is omitted. In contrast, when the upper electrode

132

is composed of a transparent material such as ITO and the lower electrode

131

is non-transparent, a reflection type display device is constituted regardless of whether the substrate

10

is transparent or non-transparent. Further, when both the upper electrode

132

and the lower electrode

131

are transparent and the substrate

10

is transparent, a reflection or transmission type display device is constituted. When both the upper electrode

132

and the lower electrode

131

are transparent and the substrate

10

is non-transparent, a reflection type display device is constituted.

The constitution shown in

FIG. 11A

corresponds to the case (5) in which the resistance film

11

extending onto the independent electrode

13

is composed of a non-transparent material such as conductive reflective layer. In this case, a reflection type display device is constituted regardless of whether the independent electrode

13

B is transparent or non-transparent and whether the substrate

10

is transparent or non-transparent. When the resistance film

11

is composed of a transparent material such as tantalum oxide and the independent electrode

13

B is non-transparent as shown in

FIG. 11B

, a reflection type display device can be constituted regardless of whether the substrate

10

is transparent or non-transparent. When the resistance film

11

is composed of a transparent material such as tantalum oxide, and when the independent electrode

13

B is transparent as shown in FIG.

11

C and the substrate

10

is non-transparent, a reflection type display device can be constituted. Further, when all of the resistance film

11

, the independent electrode

13

B and the substrate

10

are transparent, a transmission or reflection type display device as shown in

FIG. 11D

can be constituted.

Table 1 shows the constitutions of the display devices that can be constituted when the adhesive layer is formed between the resistance film and the independent electrode. Table 2 shows the constitutions of the display devices that can be constituted when the adhesive layer is formed between the resistance film and the unit fluorescence layer. Further, Table 3 shows the constitutions of the display devices that can be constituted when the adhesive layer is formed between the resistance film and the independent electrode and between the resistance film and the unit fluorescence layer. In these Tables, “TP” stands for “transparent”, “N-TP” stands for “non-transparent”, “TR” stands for “transmission type display device”, and “RF” stands for “reflection type display device”.

TABLE 1

Resistance film

N-TP

TP

TP

TP

TP

Adhesive layer

TP or N-TP

N-TP

TP

TP

TP

Independent

TP or

TP or

N-TP

TP

TP

electrode

N-TP

N-TP

Substrate

TP or

TP or

TP or

N-TP

TP

N-TP

N-TP

N-TP

Type of

RF

RF

RF

RF

TR or

display device

RF

TABLE 2

Adhesive layer

N-TP

TP

TP

TP

TP

Resistance film

TP or N-TP

N-TP

TP

TP

TP

Independent

TP or

TP or

N-TP

TP

TP

electrode

N-TP

N-TP

Substrate

TP or

TP or

TP or

N-TP

TP

N-TP

N-TP

N-TP

Type of

RF

RF

RF

RF

TR or

display device

RF

TABLE 3

Adhesive layer

N-TP

TP

TP

TP

TP

TP

Resistance film

TP or N-TP

N-TP

TP

TP

TP

TP

Adhesive layer

TP or

TP or

N-TP

TP

TP

TP

N-TP

N-TP

Independent

TP or

TP or

TP or

N-TP

TP

TP

electrode

N-TP

N-TP

N-TP

Substrate

TP or

TP or

TP or

TP or

N-TP

TP

N-TP

N-TP

N-TP

N-TP

Type of

RF

RF

RF

RF

RF

TR or

display device

RF

EXAMPLE 3

Example 3 is concerned with a display panel as other examples of the display panel of the second-C constitution, in which the independent electrodes are formed such that one independent electrode corresponds to one unit fluorescence layer.

FIG. 12A

shows a schematic plan view of the display panel of Example 3. As shown in

FIG. 12A

, the anode electrode of the display panel

101

comprises a plurality of independent electrodes

113

which are formed in the form of a matrix such that the independent electrodes are so formed as to correspond to the unit fluorescence layers

112

R,

112

G, . . . respectively. A plurality of these independent electrodes

113

as a whole are arranged to nearly cover the effective region. The power supply line is formed on the rectangular substrate

110

composed, for example, of glass, and it comprises one main line

114

extending in the width direction of the rectangular substrate

110

and a plurality of branch lines

124

extending from the main line

114

and in the column direction, i.e., in the direction in parallel with the length direction of the rectangular substrate

110

. Each independent electrode

113

is connected to the power supply line through a resistance film

111

, and more specifically, the independent electrodes

113

in a column are connected to one common branch line

124

, and the independent electrodes

113

in another column are connected to another common branch line

124

. The main line

114

is connected to a connecting terminal (not shown) through a lead portion

115

, and the connecting terminal is connected to an anode electrode driving circuit. In

FIG. 12A

, the anode electrode driving circuit is shown by a symbol of a power source (5 kV) for simplification. Each independent electrode

113

has a rectangular form as an example, and the independent electrodes

113

are so formed as to correspond to the unit fluorescence layers

112

R (red) and

112

G (green), respectively. Although not shown in

FIGS. 12A

to

12

E due to limited space, an independent electrode

113

is formed on a unit fluorescence layer for blue as well.

The display panel

101

shown in

FIG. 12A

includes some structural cases depending upon constitutions of the independent electrodes

113

.

FIGS. 12B

to

12

E show examples thereof.

FIGS. 12B

to

12

E are partial cross-sectional views taken along an X—X line in FIG.

12

A. The constitution shown in

FIG. 12B

corresponds to the case (1) in which the unit fluorescence layers

112

R and

112

G are formed on the substrate

110

and the independent electrodes

113

A are formed on the unit fluorescence layers

112

R and

112

G, and the above case (1) is the mostly highly consistent with an existing production process when a conductive reflective layer typified by a metal-back layer is used for constituting the independent electrodes

113

A. The constitution shown in

FIG. 12C

corresponds to the case (2) in which the independent electrodes

113

B are formed on the substrate

110

, and the unit fluorescence layers

112

R and

112

G are formed on the independent electrodes

113

B. The above case (2) is the most highly consistent with an existing production process when a transparent conductive layer typified by an ITO layer is used for constituting the independent electrodes

113

B. The constitution shown in

FIG. 12D

corresponds to the case (3) in which each independent electrode

113

C comprises a lower electrode

231

and an upper electrode

232

, the lower electrode

231

is formed on the substrate

110

, the unit fluorescence layers

112

R and

112

G are formed on the lower electrode

231

, and the upper electrode

232

is formed on the unit fluorescence layers

112

R and

112

G and the lower electrode

231

. The above case (3) corresponds to a constitution in which the anode electrode in the case (i) of the first aspect of the present invention is divided into a plurality of independent regions.

Further, the constitution shown in

FIG. 12E

corresponds to the case (4) in which each independent electrode

113

D comprises a lower electrode

231

and an upper electrode

232

, the unit fluorescence layers

112

R and

112

G are formed on the substrate

110

, the lower electrode

231

is formed on the unit fluorescence layers

112

R and

112

G, and the upper electrode

232

is formed on the lower electrode

231

. The above case (4) corresponds to a constitution in which the anode electrode in the case (ii) in the first aspect of the present invention is divided into a plurality of independent regions. In addition to these, the display panel shown in

FIG. 12C

also includes a constitution in which the resistance film

111

extends onto the independent electrode

113

B. The branch lines

124

A,

124

B,

124

C and

124

D are composed of the same conductive material layer as that used for forming the independent electrodes

113

A,

113

B,

113

C and

113

D. That is, the lower electrode

241

constituting the branch line

124

A,

124

B,

124

C or

124

D and the lower electrode

231

constituting the independent electrode

113

A,

113

B,

113

C or

113

D are composed of the same conductive material layer, and the upper electrode

242

constituting the branch line

124

A,

124

B,

124

C or

124

D and the upper electrode

232

constituting the independent electrode

113

A,

113

B,

113

C or

113

D are composed of the same conductive material layer.

The independent electrodes

113

A,

113

B,

113

C and

113

D of the display panel

101

of Example 3 can be formed in the same manner as in the formation of the independent electrodes

13

A,

13

B,

13

C and

13

D of the display panel

100

of Example 2. The resistance film

111

of the display panel

101

of Example 3 can be formed in the same manner as in the formation of the resistance film

11

of the display panel

100

of Example 2. The main line

114

, the branch lines

124

A,

124

B,

124

C and

124

D and the lead portion

115

of the display panel

101

of Example 3 can be formed in the same manner as in the formation of the main line

14

, the branch lines

24

A,

24

B,

24

C and

24

D and the lead portion

15

of the display panel

100

of Example 2. Those constitutions explained with reference to

FIGS. 8A

to

11

D also apply to the display panel

101

of Example 3.

Further, the display panel

101

of Example 3 can be incorporated into a display device like the display panel

100

of Example 2. In the display device using the display panel

101

of Example 3, the electrostatic capacitance is further decreased to a greater extent than in the display device using the display panel

100

of Example 2.

EXAMPLE 4

Example 4 is concerned with a display panel of the second-D constitution of the present invention in which independent electrodes are arranged in the form of stripes.

FIGS. 13A and 13B

show schematic plan views of the display panels of Example 4, and

FIGS. 14A

to

14

D show partial cross-sectional views taken along an X—X line in FIG.

13

B. In the display panel

102

, as shown in

FIG. 13A

, the anode electrode comprises a plurality of independent electrodes

213

which are so formed in the form of strips as to correspond to a fluorescence layer group Gr

1

consisting of a predetermined number of unit fluorescence layers. The fluorescence layer group Gr

1

refers to a set of three fluorescence layer unit groups, each of which consists of a plurality of the unit fluorescence layers emitting one of three primary colors and is arranged in the form of a stripe along the width direction of a substrate

210

. That is, in the display panel

102

, each independent electrode

213

is so formed as to correspond, for example, to a plurality of pixels. A plurality of these independent electrodes

213

are arranged as a whole to cover the effective region. In

FIG. 13A

, the stripes extend in the row direction, i.e., in the width direction of the rectangular substrate

210

, while they may extend in the length direction. On the substrate

210

, one power supply line

214

is formed along a major side of the substrate

210

and in parallel with the major side, and each independent electrode

213

is connected to the power supply line

214

through a resistance film

211

. Each independent electrode

213

has the form of a stripe as an example.

In a display panel

103

shown in

FIG. 13B

, an electrode corresponding to the independent electrode

213

of the display panel

102

is further divided to correspond to each of three primary colors. That is, one independent electrode

313

is so formed as to correspond to one fluorescence layer group Gr

2

, and another independent electrode is so formed as to correspond to another fluorescence layer group Gr

2

. Each fluorescence layer group Gr

2

refers to a set of a plurality of the unit fluorescence layers emitting one of three primary colors and is arranged in the form of a stripe. On a substrate

310

, one power supply line

314

is formed along a major side of the substrate

310

and in parallel with the major side, and each independent electrode

313

is connected to the power supply line

314

through a resistance film

311

. The power supply line

214

or

314

is connected to a connecting terminal (not shown) provided in a peripheral portion of the display panel

102

or

103

, and the connecting terminal is connected to an anode electrode driving circuit. In

FIGS. 13A and 13B

, the anode electrode driving circuit is shown by a symbol of a power source (5 kV) for simplification.

The display panel

102

shown in FIG.

13

A and the display panel

103

shown in

FIG. 13B

include some structural cases depending upon constitutions of the independent electrodes

213

and

313

.

FIGS. 14A

to

14

D show some of the structural cases of the display panel

103

as examples. The display panel

102

also has such similar structural cases.

FIGS. 14A

to

14

D show partial cross-sectional views taken along an X—X line in FIG.

13

B. In

FIGS. 14A

to

14

D, a fluorescence layer group Gr

2

of red (R) color is shown as a typical example. The constitution shown in

FIG. 14A

corresponds to the case (1) in which the fluorescence layer group Gr

2

is formed on a substrate

310

and an independent electrode

313

A is formed on the fluorescence layer group Gr

2

. The above case (1) is the most highly consistent with an existing production process when only a conductive reflective layer typified by a metal-back layer is used for constituting the independent electrode

313

A. The constitution shown in

FIG. 14B

corresponds to the case (2) in which an independent electrode

313

B is formed on the substrate

310

and the fluorescence layer group Gr

2

is formed on the independent electrode

313

B. The above case (2) is the most highly consistent with an existing production process when a transparent conductive layer typified by an ITO layer is used for constituting the independent electrode

313

B. The constitution shown in

FIG. 14C

corresponds to the case (3) in which an independent electrode

313

C comprises a lower electrode

331

and an upper electrode

332

, the lower electrode

331

is formed on the substrate

310

, the fluorescence layer group Gr

2

is formed on the lower electrode

331

, and the upper electrode

332

is formed on the fluorescence layer group Gr

2

and the lower electrode

331

. The above case (3) corresponds to a constitution in which the anode electrode in the case (i) in the first aspect of the present invention is divided into a plurality of independent regions. The constitution shown in

FIG. 14D

corresponds to the case (4) in which an independent electrode

313

comprises a lower electrode

331

and an upper electrode

332

, the fluorescence layer group Gr

2

is formed on the substrate

310

, the lower electrode

331

is formed on the fluorescence layer group Gr

2

, and the upper electrode

332

is formed on the lower electrode

331

. The above case (4) corresponds to a constitution in which the anode electrode in the case (ii) in the first aspect of the present invention is divided into a plurality of independent regions. Further, the display panel shown in

FIG. 14B

includes the case (5) in which the resistance film

311

extends onto the independent electrode

313

B. The power supply lines

314

A,

314

B,

314

C or

314

D and the independent electrodes

313

A,

313

B,

313

C or

313

D are composed of the same conductive material layer. That is, the lower electrode

341

constituting the power supply line

314

A,

314

B,

314

C or

314

D and the lower electrode

331

constituting the independent electrode

313

A,

313

B,

313

C or

313

D are composed of the same conductive material layer, and the upper electrode

342

constituting the power supply line

314

A,

314

B,

314

C or

314

D and the upper electrode

331

constituting the independent electrode

313

A,

313

B,

313

C or

313

D are composed of the same conductive material layer.

The independent electrode

213

of the display panel

102

and the independent electrodes

313

,

313

A,

313

B,

313

C and

313

D of the display panel

103

in Example 4 can be formed in the same manner as in the formation of the independent electrodes

13

A,

13

B,

13

C and

13

D of the display panel

100

of Example 2. The resistance film

211

of the display panel

102

and the resistance film

311

of the display panel

103

in Example 4 can be formed in the same manner as in the formation of the resistance film

11

of the display panel

100

of Example 2. The power supply line

214

of the display panel

102

and the power supply line

314

of the display panel

103

in Example 4 can be formed in the same manner as in the formation of the power supply line of the display panel

100

of Example 2. Those constitutions explained with reference to

FIGS. 8A

to

FIG. 11D

also apply to the display panels

102

and

103

in Example 4.

Each of the display panels

102

and

103

of Example 4 can be incorporated into a display device like the display panel

100

of Example 2. In a display device having the above fluorescence layer group shaped in the form of stripes, generally, so-called line sequential display is performed. For example, in the display panel

102

shown in

FIG. 13A

, only a current of approximately several μA flows per independent electrode

213

, so that a voltage drop caused by the above resistance film

211

is approximately several volts to several tens volts. Such a voltage drop is at a level that is negligible as compared with an anode voltage which is generally the order of several kilovolts. In the display devices using the display panels

102

and

103

of Example 4, therefore, no substantial decrease in brightness is caused, and a high voltage can be stably applied to the anode electrode (i.e., independent electrodes

213

and

313

).

EXAMPLE 5

Example 5 is concerned with display panels of the second-A constitution and the second-B constitution of the present invention.

FIG. 15A

shows a schematic plan view of a display panel

103

A of the second-A constitution. In the display panel

103

A, independent electrodes

313

are so arranged in the form of stripes as to correspond to fluorescence layer groups each of which consists of a plurality of unit fluorescence layers. A power supply line comprises a plurality of unit power supply lines

315

, and each unit power supply lines

315

is connected to each independent electrode

313

. That is, each of the unit power supply lines

315

is so provided as to correspond to each of the independent electrodes

313

. In

FIG. 15A

, the independent electrodes

313

are indicated by hatching for clarification. In

FIG. 15A

, the number of the independent electrodes

313

is

16

, which is just for showing as an example. On a peripheral portion of the display panel

103

A, a terminal of each unit power supply line

315

is provided with a connecting terminal (not shown), and each unit power supply line is connected to an anode electrode driving circuit

317

A through the connecting terminal. In a constitution in which only the anode electrode is divided as described above, the effect of decreasing the electrostatic capacitance can be produced. In Example 5, further, resistance members corresponding are provided to the unit power supply lines

315

for temporarily discontinuing the supply of energy to the independent electrodes

313

when a discharge takes place and for stabilizing a brightness. In the display panel shown in

FIG. 15A

, resistance members

316

having a resistance, for example, of 100 MΩ are inserted somewhere in lines connected to each unit power supply line

315

in the anode electrode driving circuit

317

A, and each line is connected to a common power source line. A positive voltage, for example, of a 5 kilovolts is applied to each independent electrode

313

from a built-in power source of the anode electrode driving circuit through the above power source line.

FIG. 15A

shows an equivalent circuit, and in a practical constitution, the unit power supply lines

315

are extended to an idle region of the display panel

103

A, collected on one place in a peripheral portion of the display panel

103

A and connected to the anode electrode driving circuit

317

A provided with the resistance members through a connecting means

318

as shown in FIG.

16

A. The independent electrode

313

may has any constitution of the cases (1) to (4). The connecting means

318

includes a flexible printed wiring board and a bonding wire. When the connecting means

318

is a flexible printed wiring board, a resistance member is inserted somewhere in each of the lines connecting the independent electrodes

313

and the corresponding connecting terminals of the anode electrode driving circuit

317

A. When the connecting member

318

is a bonding wire, there can be used a bonding wire having a desired resistance value.

FIG. 15B

shows a schematic plan view of a rear panel

300

having a plurality of electron emitting members, which rear panel

300

is arranged to be opposed to the above display panel

103

A through a vacuum space. The electron emitting members are disposed in regions (i.e., overlap regions) where projection images of a first electrode group (specifically, a plurality of gate electrodes

34

) which extend in one direction and to which scanning signals are inputted and a second electrode group (specifically, a plurality of cathode electrodes

31

) which extend in the other direction and to which video signals are inputted overlap each other. The scanning signals are inputted from a gate electrode driving circuit

37

, and the video signals are inputted from a cathode electrode driving circuit

36

. The independent electrodes

313

shown in

FIG. 15A

extend in the direction nearly in parallel with the second electrode group, i.e., a plurality of the cathode electrodes

31

. In this Example, the number of the independent electrodes

313

and the number of the cathode electrodes

31

are the same, while there may be employed a constitution in which a plurality of the cathode electrodes

31

correspond to one independent electrode

313

. In the above constitution, electrons are substantially simultaneously emitted from desired overlap regions among the overlap regions positioned on the electrodes constituting the first electrode group.

In

FIG. 15B

, for clarification, the cathode electrodes

31

in a non-selected state (to which a voltage of +50 volts is applied from the cathode electrode driving circuit

36

) are indicated by less dense hatchings, and the cathode electrodes

31

in a selected state (to which a voltage of 0 volt is applied from the cathode electrode driving circuit

36

) are indicated by dense hatchings. Video signals applied to the cathode electrodes

31

in a selected state can have a value (intermediate tones) of from 0 volt or more to leas than +50 volts depending upon tones, while they are assumed to have 0 volt at which a maximum brightness (full tone) can be obtained, for simplification. Concerning the gate electrodes

34

, a non-selected state (a voltage of 0 volt is applied from the gate electrode driving circuit

37

) is indicated by a blank, and a selected state (a voltage of +50 volts is applied from the gate electrode driving circuit

37

) is indicated by hatchings. A region (overlap region) where projection images of the cathode electrode

31

and the gate electrode

34

overlap each other corresponds to one pixel in a monochromatic display device or one sub-pixel in a full color display, and generally, a plurality of the field emission devices are arranged per overlap region. The overlap regions of the selected cathode electrodes

31

and the selected gate electrodes

34

are the selected pixels (or selected sub-pixels), and are indicated by blank circles. The gate electrodes

34

are referred to as m-th column from top to bottom, and the cathode electrodes

31

are referred to as n-th row from left to right.

For example, it is assumed as follows. When the gate electrode

34

on the 2nd column is selected, five cathode electrodes

31

such as the cathode electrodes on the 2nd, 6th, 9th, 11th and 14th rows are selected as shown in

FIG. 15B

, and when a current of 1 μA flows from each of the five independent electrodes

313

on the 2nd, 6th, 9th, 11th and 14th rows which face the cathode electrode

31

, during a full tone. In this case, a voltage drop comes to be 1 μA×100 MΩ=0.1 kilovolt. That is, between a cathode electrode

31

on any row and any independent electrode

313

, an acceleration voltage comes to be 5−0.1=4.9 kilovolts. A current of smaller than 1 μA flows during an intermediate tone, so that a voltage drop comes to be smaller than 0.1 kilovolt. In any case, since the anode electrode is divided into a plurality of the independent electrodes

313

, a voltage drop takes place only in a constant range (0.1 kilovolt in the above example) without regard to the number of the cathode electrodes

31

selected, whereby the brightness on a display screen is stabilized. When scanning signals are inputted to the cathode electrodes

31

and video signals are inputted to the gate electrodes

34

unlike the above-explained example, it is sufficient to arrange the independent electrodes

313

nearly in parallel with the gate electrodes

34

.

FIG. 16B

shows a schematic plan view of a display panel

103

B of the second-B constitution. In the display panel

103

B, the constitution of independent electrodes

313

is the same as that in the display panel

103

A, while resistance members

316

are inserted somewhere in the unit power supply lines

315

. The resistance member

316

can be selected from chip resistors or resistance films.

FIG. 16B

also shows an equivalent circuit, and in a practical constitution, there may be employed a constitution as shown in

FIG. 16A

in which the unit power supply lines

315

are collected on one place in a peripheral portion of the display panel

103

B and connected to an anode electrode driving circuit

317

B having no resistance member with a similar connecting means

318

.

EXAMPLE 6

Example 6 is concerned with a display panel of the third-A constitution.

FIG. 17A

shows a schematic plan view of the display panel of Example 6, and

FIG. 17B

shows an enlarged view of vicinities of an independent electrode.

FIGS. 18A and 18B

show schematic partial cross-sectional views taken along an X—X line in FIG.

17

A and show two structural cases based on constitutions of the independent electrode.

In the display panel

104

of Example 6, as shown in these Figures, the anode electrode comprises a plurality of independent electrodes

413

so as to correspond to a plurality of unit fluorescence layers

412

R,

412

G and

412

B. The display panel

104

has a power supply layer

414

formed on a substrate

410

, an insulating layer

417

formed on the power supply layer

414

, the unit fluorescence layers

412

R,

412

G and

412

B formed on the power supply layer

414

or the insulating layer

417

, the independent electrodes

413

formed on the unit fluorescence layers

412

R,

412

G and

412

B so as to reach the insulating layer

417

, holes

416

formed in the insulating layer

417

and resistance layers

411

filled in the holes

416

. The independent electrode

413

is connected to the power supply layer

414

with the resistance layer

411

. The power supply layer

414

is formed on the substrate

410

to nearly cover the effective region, and the independent electrodes

413

as a whole are also arranged to nearly cover the effective region. The power supply layer

414

may be formed as desired. Each independent electrode

413

is so formed as to correspond to a fluorescence layer group Gr consisting of the unit fluorescence layers

412

R,

412

G and

412

B as shown in an enlarged view of FIG.

17

B. The layout of the unit fluorescence layers

412

R,

412

G and

412

B in

FIG. 17B

is given for consistency with partial cross-sectional views of

FIGS. 18A and 18B

for convenience, and the layout thereof shall not be limited to the layout shown in FIG.

17

B.

The display panel

104

shown in

FIG. 17A

includes two kinds of constitutions shown in

FIGS. 18A and 18B

depending upon constitutions of the independent electrodes

413

.

FIG. 18A

shows a constitution in which the unit fluorescence layers

412

R,

412

G and

412

B are formed on the power supply layer

414

, and

FIG. 18B

shows a constitution in which the unit fluorescence layers

412

R,

412

G and

412

G are formed on the insulating layer

417

. The constitution shown in

FIG. 18A

is feasible when the unit fluorescence layers

412

R,

412

G and

412

G have a sufficiently high resistivity, and it is advantageous for flattening the display panel and is consequently advantageous for decreasing the thickness of a display device using the display panel. The constitution shown in

FIG. 18B

is suitable when the unit fluorescence layers

412

R,

412

G and

412

G have an insufficient resistivity. Like the case (ii) according to the first aspect of the present invention, the independent electrodes

413

A and

413

B may have a two-layered structure comprising a lower electrode and an upper electrode formed thereon.

In the constitution shown in

FIG. 18A

, a type difference of a display device finally constituted, whether it is a transmission type or a reflection type, is caused depending upon the combinations of materials used for constituting the substrate

410

, the power supply layer

414

and the independent electrode

413

A.

The above difference is substantially the same as that in examples explained with reference to

FIGS. 10A

to

10

E. The constitution shown in

FIG. 18B

includes a diversity of the combinations since the insulating layer

417

is added to these layers. However, a reflection type display device can be constituted when one non-transparent layer is present nearer to the substrate

410

side than the unit fluorescence layers

412

R,

412

G and

412

B, a transmission type display device can be constituted when the independent electrode

413

B is non-transparent, and any one of a transmission type display device and a reflection type display device can be constituted when all the layers and the substrate are transparent. The above basic thought is applicable to any case. For example, the power supply layer

414

can be constituted of a transparent conductive layer typified by an ITO layer and the independent electrodes

413

A and

413

B can be constituted of a conductive reflective layer typified by a metal-back layer. In this case, a transmission type display device is constituted.

In the display panel

104

of Example 6, it is no longer necessary to form the power supply line on a surface flush with the surface of the independent electrodes

413

A and

413

B, so that the configuration of the unit fluorescence layers can be increased in density. In a display device into which the above display device

104

is incorporated, screen display having a higher fineness can be achieved.

EXAMPLE 7

Example 7 is concerned with another example of the display panel of the third-A constitution, i.e., a display panel in which one independent electrode is so formed as to correspond to one unit fluorescence layer.

FIG. 19A

shows a schematic plan view of the display panel of Example 7, and

FIG. 19B

shows an enlarged view of vicinities of an independent electrode.

FIGS. 20A and 20B

show schematic partial cross-sectional views taken along an X—X line in FIG.

19

A and show two kinds of structural cases based on the constitution of the independent electrode.

In the display panel

105

of Example 7, the anode electrode comprises a plurality of independent electrodes

513

, each of which is so formed as to correspond to each of the unit fluorescence layers

512

R,

512

G and

512

B. The display panel

105

has a power supply layer

514

formed on a substrate

510

, an insulating layer

517

formed on the power supply layer

514

, the unit fluorescence layers

512

R,

512

G and

512

B formed on the power supply layer

514

or the insulating layer

517

, the independent electrodes

513

formed on the unit fluorescence layers

512

R,

512

G and

512

B to reach the surface of the insulating layer

517

, holes

516

formed in the insulating layer

517

and resistance layers

511

filled in the holes

516

. The independent electrode

513

is connected to the power supply layer

514

with the resistance layer

511

. The power supply layer

514

is so formed on the substrate

510

as to nearly cover an effective region, and the independent electrodes

513

are arranged as a whole to nearly cover the effective region. The power supply layer

514

may be formed to have the same pattern as that of the independent electrodes

513

.

FIGS. 20A and 20B

show two kinds of constitution of the display panel

105

shown in FIG.

19

A.

FIG. 20A

shows a constitution in which the unit fluorescence layers

512

R,

512

G and

512

B are formed on the power supply layer

514

, and

FIG. 20B

shows a constitution in which the unit fluorescence layers

512

R,

512

G and

512

B are formed on the insulating layer

517

. In

FIGS. 19A

,

19

B,

20

A and

20

B, the same members as those in

FIGS. 17A

to

18

B are shown by the same reference numerals except that the first digit

4

is replaced with

5

, and explanations of the same members are omitted.

Like the display panel

100

of Example 2, the display panel

105

of Example 7 can be incorporated into a display device. When one independent electrodes

513

is so formed as to correspond to one unit fluorescence layer

512

R,

512

G or

512

B, as shown in the display panel

105

of Example 7, a great number of the independent electrodes

513

are constituted. Since, however, the power supply layer

514

and the independent electrodes

513

are three-dimensionally arranged through the insulating layer

517

, excellent fineness on a screen can be achieved.

EXAMPLE 8

Example 8 is concerned with a display panel

106

of the third-B constitution of the present invention in which independent electrodes are formed in the form of stripes.

FIG. 21A

shows a schematic plan view of the display panel

106

, and

FIGS. 21B and 21C

show schematic partial cross-sectional views taken along an X—X line in FIG.

21

A. In

FIGS. 21A and 21B

, the same members as those in

FIGS. 19A

to

20

B are shown by the same reference numerals except that the first digit

5

is replaced with

6

. The display panel

106

of Example 8 is a display panel structured by replacing the unit fluorescence layers

512

R of the display panel

105

of Example 7 with a fluorescence layer group Gr extending in the form of stripes, and detailed explanations thereof are omitted. Like the display panel

100

of Example 2, the display panel

106

of Example 8 can be incorporated into a display device.

The present invention has been explained with reference to Example, while the present invention shall not be limited thereto. Particulars of structures of the display panels and particulars of structures of the display devices to which the display panels are applied have been described as examples, and they can be altered, selected and combined as required. Further, the materials and methods used for constituting the display panels can be also altered, selected and combined as required.

The field emission device is not specially limited to the Spindt type field emission device, and it can be any one of an edge type field emission device, a flat type field emission device, a low-profile type field emission device and a crown type field emission device.

As

FIG. 22A

shows a schematic partial cross-sectional view, an edge type field emission device comprises an electron emitting layer

701

formed on a supporting member (supporting substrate)

700

, an insulating interlayer

702

formed on the supporting member

700

and the electron emitting layer

701

, and a gate electrode

703

formed on the insulating interlayer

702

. An opening portion

704

is formed in the gate electrode

703

and the insulating interlayer

702

, and has a bottom portion where an edge portion

701

A of the electron emitting layer

701

is exposed. Electrons are emitted from the edge portion

701

A of the electron emitting layer

701

by properly applying voltages to the electron emitting layer

701

and the gate electrode

703

. As is shown in

FIG. 22B

, a recess

705

may be formed in the supporting member

700

under the electron emitting layer

701

in the opening portion

704

. Further, as

FIG. 22C

shows a schematic partial cross-sectional view, an edge type field emission device comprises a first gate electrode

703

A formed on a supporting member (supporting substrate)

700

, a first insulating interlayer

702

A formed on the supporting member

700

and the first gate electrode

703

A, an electron emitting layer

701

formed on the first insulating interlayer

702

A, a second insulating interlayer

702

B formed on the electron emitting layer

701

and the first insulating interlayer

702

A, and a second gate electrode

703

B formed on the second insulating interlayer

702

B. An opening portion

704

is formed in the second gate electrode

703

B, the second insulating interlayer

702

B, the electron emitting layer

701

and the first insulating interlayer

702

A, and has a bottom portion where the first gate electrode

703

A is exposed. An edge portion

701

B is exposed on a side wall of the opening portion

704

. Electrons are emitted from the edge portion

701

B of the electron emitting layer

701

by properly applying voltages to the electron emitting layer

701

and the first and second gate electrode

703

A and

703

B.

As

FIG. 23A

shows a schematic partial cross-sectional view, a flat type field emission device comprises a cathode electrode

711

formed on a supporting member (supporting substrate)

700

, an insulating interlayer

702

formed on the supporting member

700

and the cathode electrode

711

, and a gate electrode

703

formed on the insulating interlayer

702

. An opening portion

704

is formed in the gate electrode

703

and the insulating interlayer

702

, and has a bottom portion where the cathode electrode

711

is exposed. Electrons are emitted from an exposed portion

711

A of the cathode electrode

711

by properly applying voltages to the cathode electrode

711

and the gate electrode

703

.

As

FIG. 23B

shows a schematic partial cross-sectional view, a low-profile type field emission device comprises a cathode electrode

711

formed on a supporting member (supporting substrate)

700

, an insulating interlayer

702

formed on the supporting member

700

and the cathode electrode

711

, and a gate electrode

703

formed on the insulating interlayer

702

. An opening portion

704

is formed in the gate electrode

703

and the insulating interlayer

702

, and has a bottom portion where an electron emitting portion

721

which is formed on the cathode electrode

711

and has a flat form is exposed. Electrons are emitted from the electron emitting portion

721

by properly applying voltages to the cathode electrode

711

and the gate electrode

703

. The electron emitting portion

721

is composed of a material which has an electron emission efficiency higher than a refractory metal has. As is shown in

FIG. 23C

, a crown type field emission device can be obtained by replacing the electron emitting portion

721

with a electron emitting portion

722

having a crown form.

As is clear from the above explanations, in the display panel and the display device according to the first aspect of the present invention, the anode electrode has a two-layered structure comprising the lower electrode and the upper electrode, and a charge is removed through both the lower electrode and the upper electrode, so that the deterioration of the fluorescence layer is prevented and that a long lifetime of display panel is achieved. As a consequence, a long lifetime of the display device can be achieved. Therefore, the first object of the present invention is achieved.

In the display panel and the display device according to the second aspect of the present invention, instead of preventing a discharge phenomenon which is to trigger a spark discharge, the electrostatic capacitance, for example, between the anode electrode and the cathode electrode is decreased to such an extent that there is supplied no energy sufficient for promoting a discharge of a small scale, if any, to grow to a spark discharge, whereby the spark discharge can be effectively prevented. In a so-called low voltage type display device in which the gap between the display panel and the rear panel is relatively small, therefore, a high voltage can be applied to the anode electrode as well, and there can be achieved the second object of the present invention that there is provided a display device which can overcome conventional disadvantages with retaining the advantages of the low voltage type display device such as a simple panel structure and a low cost and which permits stabilized high-brightness displaying with a low power consumption. In some layout modes of the independent electrodes, a voltage drop can be always controlled to be in a constant range regardless of the number of selected electrodes to which video signals are inputted on the rear panel side, whereby not only the second object of the present invention is achieved but also there is achieved the third object of the present invention to obtain a display device in which the brightness on a display screen is stabilized.

In the display panel and the display device according to the third aspect of the present invention, the screen fineness can be further improved while achieving effects similar to the effects of the display panel and the display device according to the first and second aspects of the present invention, i.e., while achieving the first and second objects of the present invention.

Number	Date	Country	Kind
P11-058957	Mar 1999	JP
P11-361805	Dec 1999	JP

Number	Name	Date	Kind
4855190	Bezner	Aug 1989	A
5557296	Lambert et al.	Sep 1996	A
5592056	Peyre et al.	Jan 1997	A
5644327	Onyskevych et al.	Jul 1997	A
5742266	Onozuka	Apr 1998	A
5796375	Holloman	Aug 1998	A
5844531	Betsui	Dec 1998	A
6117529	Leising et al.	Sep 2000	A
6317106	Beeteson et al.	Nov 2001	B1

Display panel and display device to which the display panel is applied

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Abstract

Description

Claims

Priority Claims (2)

US Referenced Citations (9)