The present invention relates to a display device which utilizes an emission of electrons into a vacuum, and more particularly, to a display device which can enhance the display characteristics by enabling the stable control of an electron emission quantity by forming a gap between electron emitting sources and control electrodes which control the electron emission quantity from the electron emitting sources with high accuracy.
As a display device which exhibits the high brightness and the high definition, color cathode ray tubes have been widely used conventionally. However, along with the recent request for the higher quality of images of information processing equipment or television broadcasting, the demand for planar displays (panel displays) which are light in weight and require a small space while exhibiting the high brightness and the high definition has been increasing.
As typical examples, liquid crystal display devices, plasma display devices and the like have been put into practice. Further, particularly, as display devices which realize the higher brightness, it is expected that various kinds of panel-type display devices including a display device which utilizes an emission of electrons from electron emitting sources into a vacuum (hereinafter, referred to as “an electron emission type display device” or “a field emission type display device”) and an organic EL display which is characterized by low power consumption will be commercialized.
Among such panel type display devices, as the above-mentioned field emission type display device, a display device having an electron emission structure which was invented by C. A. Spindt et al (for example, see U.S. Pat. No. 3,453,478, Japanese Laid-open Patent Publication 21305/2000), a display device having an electron emission structure of a metal-insulator-metal (MIM) type, a display device having an electron emission structure which utilizes an electron emission phenomenon based on a quantum theory tunneling effect (also referred to as “surface conduction type electron emitting source, see Japanese Laid-open Patent Publication 21305/2000), and a display device which utilizes an electron emission phenomenon having a diamond film, a graphite film and carbon nanotubes and the like have been known.
The rear panel 100 includes cathode wires 2 which have electron emitting sources 2a and the control electrodes 4 which are formed such that the control electrodes 4 cross the cathode wires 2 by way of an insulation layer 3 on the rear substrate 1 preferably made of glass or alumina or the like. Then, an electron emission quantity (including turning on or off of emission) from the electron emitting sources 2a are controlled in response to the potential difference between the cathode wires 2 and the control electrodes 4.
Further, the face panel 200 includes the anodes 7 and the fluorescent material layers 6 on a face substrate 5 formed of light-transmitting material such as glass. The sealing frame 300 is fixedly secured to the inner peripheries of the rear panel 100 and the face panel 200 using an adhesive agent such as frit glass. The inside defined by the rear panel 100, the face panel 200 and the sealing frame 300 is evacuated to a vacuum of 10−5 to 10−7 Torr, for example.
With respect to this type of display device whose inside is evacuated, to hold a gap between the rear panel 100 and the face panel 200, that is, a gap between the cathode wires 2 (electron emitting sources 2a) and the anodes 7 at a predetermined value, it is necessary to provide gap holding members 9 at portions except for a pixel region.
The insulation layer 3 is interposed between the cathode wires 2 formed on the rear panel 100 and the control electrodes 4 which cross the cathode wires 2 and an hole (grid hole) 4a is formed at each crossing portion of the cathode wire 2 and the control electrode 4. The hole 4a allows electrons emitted from the electron emitting source 2a to pass therethrough toward the anode 7 side. On the other hand, the electron emitting source 2a is formed on the above-mentioned crossing portion of the cathode wire 2 and the control electrode 4 and the insulation layer 3 is eliminated at a portion which corresponds to the hole 4a of the control electrode 4. The above-mentioned electron emitting sources 2a are constituted of carbon nanotubes (CNT), diamond-like carbon (DLC) or other field emission cathode, for example.
Here, as the electron emitting sources 2a, electron emitting sources which use carbon nanotubes are illustrated. As shown in FIG. 39A and
FIG. 40A and
Electrons emitted from the rear panel 100 impinge on the fluorescent material layer 6 of the opposing face panel 200. Light which corresponds to the emitting characteristics of the fluorescent material layer 6 is irradiated to the outside of the face panel 200 so that a display device performs the function thereof.
As literatures which disclose the conventional technique related to this type of display device, for example, Japanese Laid-open Patent Publication 144652/1999, Japanese Laid-open Patent Publication 323078/2000 and the like are named.
Since the insulation layer 3 is formed by coating resin material using a screen printing method, it is difficult to make a thickness of the insulation layer 3 uniform. Accordingly, it is impossible to obtain the uniform thickness with no irregularities over the entire surface of the display region. Since the control electrodes 4 are formed along the surface contour of the insulation layer 3, as emphasized in conjunction with
Further, since the insulation layer 3 is disposed between the crossing portions of the cathode wires 2 and the control electrodes 4, the capacitance is generated. The irregularities of the thickness of the insulation layer 3 lead to the irregularities of the capacitance and when the thickness of the insulation layer 3 is increased, this obstructs the high-frequency driving. Accordingly, the thinner the thickness of the insulation layer 3, the high-frequency driving is improved and hence, it is ultimately desirable to have the constitution which can eliminate the insulation layer 3.
Then, in this type of display device, as has been explained in conjunction with
Accordingly, it is an object of the present invention to provide a display device exhibiting high reliability which can solve the above-mentioned various problems of the conventional techniques and can realize the electron emission characteristics and the high-frequency driving of high performance by adopting a constitution in which a gap formed between cathode wires 2 (electron emitting sources 2a) and control electrodes 4 can be made uniform and a gap formed between a rear panel 100 and a face panel 200 can be held at a predetermined value with high accuracy.
To achieve the above-mentioned object, a display device according to the present invention uses plate-like members as control electrodes and also arranges gap holding members right above the control electrodes.
Further, to achieve the above-mentioned object, the display device according to the present invention constitutes the control electrodes by forming holes in plate-like members and a gap formed between cathode wires and the control electrodes is regulated by a plate-thickness direction size of the holes.
Further, in the present invention, by interposing the gap holding members having an approximately plate-like shape between the rear panel and the face panel with high reliability, the gap can be held at a predetermined value with high accuracy.
Further, in the present invention, the capacitance can be reduced by removing or minimizing an insulation layer interposed between the control electrodes and the cathode wires. Further, at the cathode-wire sides of the control electrodes including hole forming portions or portions except for the hole forming portions, that is, an hole forming region, large-diameter openings (recessed portions) which regulate the gap between the holes and the cathode wires are formed by etching or the like, or the gap between the holes through which a flow of electrons pass and the cathode wires is controlled. To list the fundamental constitutions of the present invention, they are as follows.
(1) In a display device comprising a rear panel having a plurality of cathode wires having electron emitting sources, a plurality of control electrodes which cross the cathode wires and control an emission quantity of electrons from the electron emitting sources in response to the potential difference between the cathode wires and the control electrodes and a rear substrate, and a face panel having anodes and fluorescent materials, the control electrodes are formed of plate-like members, the control electrodes have holes which allow the electrons emitted from the electron emitting sources to pass therethrough toward the face panel side in pixel regions where the control electrodes cross the cathode wires, the control electrodes include contact portions which are projected toward the rear panel side between the neighboring cathode wires and support the control electrodes and gap holding members hold a gap formed between the face panel and the rear panel to a predetermined value right above the contact portions of the control electrodes and at the face panel side.
(2) In the constitution (1), the contact portions include first contact portions and second contact portions and the gap holding members are provided right above the first contact portions of the control electrodes and at the face panel side.
(3) In the constitution (1) or (2), the control electrodes include grooves into which ends of the gap holding members are fitted right above the contact portions of the control electrodes and at the face panel side.
(4) In any one of the constitutions (1) to (3), the cathode wires are divided in two or more in the pixel region, the control electrodes have third contact portions which are projected to the rear panel side and support the control electrodes, and the third contact portions are arranged between the divided cathode wires.
(5) In any one of the constitutions (1) to (3), the cathode wires have an opening in the pixel region, the control electrodes have third contact portions which are projected to the rear panel side and support the control electrodes, and the third contact portions are arranged in the opening formed in the cathode wires.
(6) In any one of the constitutions (1) to (5), the control electrodes and the gap holding members are fixed to each other by an adhesive agent or an anodic bonding.
(7) In any one of the constitutions (1) to (6), at least portions of respective contact portions of the control electrodes are fixed to the rear panel by an adhesive agent or an anodic bonding.
(8) In any one of the constitutions (1) to (7), the gap holding members are supported at a given interval from each other by a support member which crosses the cathode wires.
(9) In the constitution (8), the support member has cuts into which side peripheries of the gap holding members extending in the gap holding direction are fitted.
(10) In the constitution (8), the support member is arranged between the control electrodes and at positions where the control electrodes cross the gap holding members and have cuts into which side peripheries of the gap holding members at the cathode-wire side are fitted.
(11) In any one of the constitutions (1) to (10), the each gap holding member has plate-like portions which are arranged parallel to the cathode wires and the control electrodes respectively among neighboring pixel regions and has an approximately cruciform cross section on a plane of a direction parallel to the cathode wires and the control electrodes.
(12) In any one of the constitutions (1) to (11), the contact portions are brought into contact with the rear substrate.
(13) In any one of the constitutions (1) to (11), an insulation layer is interposed between the contact portions and the rear substrate.
(14) In any one of the constitutions (1) to (13), recessed portions are formed in the cathode wire sides of the control electrodes including hole forming regions.
(15) In the constitution (14), a width of the recessed portions is set smaller than a width of the control electrodes and an insulation layer is interposed between portions of the control electrodes other than the recessed portions and the cathode wires.
(16) In any one of the constitutions (1) to (15), a tension is applied to the control electrodes in the longitudinal direction of the control electrodes.
Due to the above-mentioned respective constitutions, the contact portions of the control electrodes made of plate-like members which are projected toward the rear panel side are brought into pressure contact with the rear substrate so that the gap formed between the cathode wires and the control electrodes is regulated to a given value and the control electrodes can effectively cope with an air pressure applied from both sides of the rear panel and the face panel.
Further, since the gap holding members are arranged right above the control electrodes made of the plate-like members, the control electrodes made of the plate-like members can be firmly fixed. It is preferable to position the control electrodes right above the contact portions.
Further, by increasing the contact portions or by fixing the control electrodes using an adhesive agent, the control electrodes can further effectively cope with an air pressure applied from both sides of the rear panel and the face panel and, at the same time, can enhance the reliability thereof.
Further, by interposing an adhesive agent between the contact surfaces or by fitting the gap holding members into the grooves formed in the control electrodes and fixing the peripheries of the grooves using an adhesive agent, they can be fixed to each other more reliably and firmly so that the machining irregularities of the gap holding members and the control electrodes can be absorbed and the gap holding members can be fixed firmly whereby the reliability can be enhanced and, at the same time, the change of the electron emission ability can be eliminated thus enabling the acquisition of the image display of high quality.
The gap holding member having an approximately cruciform cross section per se has the self standing ability so that by mounting the gap holding member to given portions in the pixel region, it is possible to hold the gap formed between the face panel and the rear panel at a predetermined value.
Further, by fixing the gap holding member using the support member, it is possible to surely make the gap holding member stand in an erected manner and it is also possible to surely hold the gap formed between the face panel and the rear panel at a predetermined value.
Further, by providing large-diameter openings (recessed portions) which regulate the gap between the holes and the cathode wires at the cathode wire side of the control electrode including the hole forming region, the gap between the holes of the control electrodes and the cathode wires can be adjusted based on a depth of the large-diameter openings so that the gap can be accurately set.
Further, by assembling the control electrodes to the rear panel while applying a tension to the control electrodes in the longitudinal direction of the control electrodes, the flatness of the control electrodes can be guaranteed and the gap formed between the holes and the cathode wires can be uniformly set.
In the above-mentioned explanation and the description of embodiments which will be explained later, unless otherwise specified, the cathode wires include electron emitting sources. Further, the gap formed between the control electrodes and the cathode wires means the gap formed between the holes of the control electrodes and the cathode wires (electron emitting sources).
Further, it is needless to say that the present invention is not limited to the above-mentioned constitutions and constitutions which will be described later and various modifications are conceivable without departing from the technical concept of the present invention.
FIG. 3A and
FIG. 8A and
FIG. 9A and
FIG. 39A and
FIG. 40A and
Preferred embodiments of the present invention are explained in detail hereinafter in conjunction with drawings which show these embodiments.
That is, as shown in
On an inner surface of the rear substrate 1 which constitutes the rear panel 100, a plurality of cathode wires 2 and a plurality of control electrodes 4 are formed in an crossing manner and one pixel is formed at each crossing portion. The control electrode 4 has a plurality of holes 4a per one pixel and has first contact portions 10 and second contact portions 11 having a projection shape at the rear substrate 1 side at portions thereof which are brought into contact with the rear substrate 1.
The first contact portions 10 and the second contact portions 11 are fixed to the rear substrate 1 directly or using a second adhesive agent 15 which will be explained later. Further, to a side of the control electrode 4 opposite to the first contact portions 10, gap holding members 9 are fixed directly or using a first adhesive agent 14 which will be explained later. The first contact portion 10 and the second contact portion 11 are formed between a plurality of cathode wires 2 and the second contact portion 11 is formed at a portion where the gap holding member 9 is not present. With respect to the number of mounting of the gap holding members 9, since the gap holding members 9 are mounted among whole pixels or between arbitrary pixels, the number depends on the size and the like of the display device.
The rear substrate 1 may be formed of a metal plate which has a surface thereof covered with inorganic insulation material, glass, quartz or insulation material or the like. Although it is preferable to set a plate thickness of the rear substrate 1 to approximately 0.5 mm to 3 mm, the plate thickness is not limited to such a value.
Although anodes 7 and fluorescent materials 6 are formed on an inner surface of the face panel 200, they are omitted from the drawing. The gap holding members 9 which define a gap formed between the face panel 200 and the rear panel 100 which face each other in an opposed manner are formed of a metal plate which has a surface thereof covered with inorganic insulation material, glass, quartz or insulation material or the like.
Although the gap holding members 9 are formed of simple plate-like members which are referred to a so-called rib structure in this embodiment, members having various shapes such as members having a so-called cross-structure which is also provided with ribs in the different direction in a plan view can be used as will be explained later.
The spatial positional relationship between the control electrodes 4 and the cathode wires 2 which largely influences the driving characteristics of a display device of this kind can be realized by performing a precision machining of the control electrodes 4. When the control electrodes 4 are constituted of metal plates, holes 4a may be machined accurately by adopting etching based on a photolithography technique which uses a photosensitive resist.
The control electrodes 4 have portions of lower surfaces thereof brought into contact with the rear substrate 1 directly or by way of an adhesive agent and have portion of upper surfaces thereof brought into contact with the gap holding members 9 directly or by way of an adhesive agent. Here, it is possible to hold the gap holding members 9 on the control electrodes 4 by forming grooves 13 in the control electrodes 4 and fitting the gap holding members 9 in these grooves 13. As shown in
The gap holding members 9 have upper portions thereof brought into contact with the face substrate 5 directly or by way of an adhesive agent so that the gap holding members 9 can firmly support the rear panel 100 and the face panel 200 whereby the gap defined between the rear panel 100 and the face panel 200 which face each other in an opposed manner can be held at a given value with high accuracy against an atmospheric pressure applied to an external surface of the display device.
In the display device of this embodiment, since no insulation layer 3 is interposed in a space defined between the cathode wires 2 and the control electrodes 4 and the space is evacuated, the capacitance between both electrodes is minimized. As a result, it is possible to input high-frequency control signals so that a display device having a large screen and a high definition can be easily realized.
Further, since the rear substrate 1 and the control electrodes 4 can be machined as separates parts, they can be assembled after fabricating them using optimum machining methods respectively whereby the productivity can be enhanced. For example, the control electrodes 4 are separately formed by etching or by laminating two or more members. The details of portion A and portion B shown in
By forming the holes 4a in a circular shape in the same manner as
In this embodiment, cathode wires 2 in one pixel are divided in halves, that is, a cathode wire 2-1 and a cathode wire 2—2 in the longitudinal direction and a third contact portion 12 of a control electrode 4 is positioned between the cathode wires 2-1, 2—2. Holes 4a formed in the control electrode 4 are formed such that they belong to pixel ranges of the respective cathode wires 2-1, 2—2 formed in halves.
In this embodiment, by bringing the control electrode 4 into contact with the rear substrate 1 at three contact portions, that is, the first, the second and the third contact portions, a gap formed between both electrodes can be held with high accuracy. Here, although gap holding members 9 are provided at positions corresponding to both ends of the pixel, it is not always necessary to provide the gap holding members 9 for each pixel and, as mentioned previously, the gap holding members 9 may be provided for every several other pixels.
FIG. 9A and
The electron emitting source 2a has a function of emitting electrons when an electric field is applied thereto. Holes 4a formed in the control electrode 4 fall within an area of the electron emitting source 2a. In this manner, by separately forming and laminating the cathode wire 2 and the electron emitting source 2a to each other, it is possible to select and use optimum materials to the cathode wire 2 and the electron emitting source 2a respectively.
To be more specific, by narrowing a size “b” of the electron emitting source 2a than a size “a” of the holes 4a in
The gap holding member 9 has a function of holding a gap between a face panel 200 and a rear panel 100 to a predetermined value as well as a function of firmly holding the control electrode 4 to the rear substrate 1 by bringing the control electrode 4 into contact with the rear substrate 1 using an atmospheric pressure applied downwardly from an upper portion of the drawing (face panel 200 side). Particularly, by fitting the lower end of the gap holding member 9 into the groove 13 formed in the control electrode 4, the positional displacement can be eliminated so that the gap holding member 9 can be accurately arranged.
Then, the control electrode 4 and the rear substrate 1 are fixed to each other by means of a second adhesive agent 15. In this manner, the control electrode 4 and the rear substrate 1 are brought into direct contact with each other and are firmly fixed to each other by the adhesive agent 15 and hence, the rear substrate 1 and the control electrode 4 and eventually the gap holding member 9 are positioned with high precision and these positions can be held.
Then, the control electrode 4 and the rear substrate 1 are fixed to each other by means of the second adhesive agent 15. In this manner, the control electrode 4 is firmly fixed to the rear substrate 1 by the adhesive agent 15 which is infiltrated between the rear substrate 1 and the first contact portion 10 and hence, even when the irregularities exist with respect to the gap between the rear substrate 1 and a plurality of first contact portions 10, the adhesive agent can absorb the irregularities and hence, the rear substrate 1 and the control electrodes 4 and, eventually, the gap holding members 9 are positioned with high precision and these positions can be held.
Subsequently, examples of other constitutions of gap holding members 9 are further explained. In the following explanation, since the constitutions of cathode wires 2 and control electrodes 4 mounted on a rear substrate 1 are similar to those of the above-mentioned embodiments, the repeated explanation is obviated unless otherwise specified.
As shown in
Further, by forming the cuts 16a into which the side peripheries of the gap holding members 9 extending in the gap holding direction are fitted in the support member 16 and by fitting the gap holding members 9 into the cuts 16a, the positional relationship between the gap holding members 9 can be set with accuracy.
Further, by fitting lower ends of the gap holding members 9 into the cuts 17a, the positional relationship between the gap holding members 9 is determined and the gap holding members 9 are supported with a given gap therebetween by the auxiliary support member 17 which intersects the cathode wires 2.
Such a constitution can restrict the positional relationship between the gap holding members 9 and can effectively resist an atmospheric pressure applied from both sides of a rear panel 100 and a face panel 200 and hence, a gap formed between the rear panel 100 and the face panel 200 can be set to a given value.
The auxiliary support member 17 can be mounted not only on the periphery of a display device but also in the inside of a display region. Accordingly, by efficiently arranging the gap holding members 9 over the whole display device, the gap can be set more effectively.
Further, the support member 16 or the auxiliary support member 17 in the above-mentioned fourth embodiment and fifth embodiment can be made of inorganic material, metal having an insulation treatment on a surface thereof, glass, quartz or the like. Further, mica has the heat resistance, can be machined easily and has the resiliency and hence, mica can be also used as the material of the support member 16 or the auxiliary support member 17. Further, the cut portions 16a, 17a of the support member 16 or the auxiliary support member 17 can be also fixed using a proper adhesive agent.
In this embodiment, out of two plate-like members having the cross structure of the gap holding member 9, one plate-like member is arranged between the control electrodes 4 and the other is arranged right above the first contact portions 10 of the control electrodes 4.
The gap holding member 9 having such a shape per se has a self-standing function with respect to a surface of a substrate and the gap defined between a face panel 200 and a rear panel 100 can be held at a predetermined value by mounting the gap holding member 9 at the given portion among the pixel regions.
Between the plate-like member of the gap holding member 9 which intersects the cathode wires 2 and the rear substrate 1 and the cathode wires 2, a second adhesive agent 15 is filled. By fixing the gap holding members 9 using such a second adhesive agent 15, the gap holding members 9 can be surely mounted on the rear substrate 1 in an erected manner and the gap defined between the face panel 200 and the rear panel 100 can be also held at a predetermined value.
Then, all plate-like members of the gap holding member 9 which cross cathode wires 2 are positioned above the control electrodes 4. As shown in
Further, between the plate-like member of the gap holding member 9 which are arranged parallel to the cathode wires 2 and the rear substrate 1, a second adhesive agent 15 is filled. By fixing the gap holding members 9 using such a second adhesive agent 15, the gap holding members 9 can be mounted on the rear substrate 1 surely and in a reliable manner.
Each control electrode 4 has recessed portions 4c in a cathode wire 2 side including a pixel region which forms holes 4a therein, wherein the recessed portions 4c form a gap between the holes 4a and cathode wires 2. The recessed portions 4c are formed such that the recessed portions 4c are extended over the width of the cathode wires 2. The gap between the holes 4a of the control electrodes 4 and the cathode wires 2 can be adjusted based on a depth of the recessed portions 4c so that the gap can be determined more accurately.
In this embodiment, since the recessed portions 4c are formed smaller than the width of the control electrode 4, the control electrode 4 has projecting portions also at peripheral portions thereof along the extending direction of the control electrode 4. Further, an insulation layer 3 is formed between the projecting portions and the cathode wires 2. Although capacitance is generated due to the insulation layer 3, such a region is small so that the high frequency driving is possible. Here, insulation layers 3 are also formed between a first contact portion 10 of the control electrode 4 and a rear substrate 1 as well as between a second contact portion 11 and the rear substrate 1.
It is preferable to fix the control electrode 4 in the state that a tension is applied to the control electrode 4 in a longitudinal direction. At the time of assembling the control electrode 4 to the substrate 1 of the rear panel, end portions of the control electrode 4 are fixed to the substrate 1 using an adhesive agent while applying the tension to the control electrode 4 in the longitudinal direction of the control electrode 4. Due to such a constitution, the flatness of the control electrode 4 is guaranteed so that a gap defined between the holes 4a and the cathode wires 2 can be set uniform. The same goes for other embodiments.
The recessed portions 4c which have been explained in conjunction with the ninth embodiment and the tenth embodiment may be combined with the constitutions of other embodiments.
As shown in
The ninth embodiment, the tenth embodiment and the eleventh embodiment which have been explained above may be selected depending on the strength and size of the plate-like bodies of the control electrodes 4 and the screen size of the display device. Further, with respect to the gap holding member 9, any gap holding member of any one of the above-mentioned embodiments can be adopted.
Here, the illustration of the gap holding member 9 is omitted from
By setting the thermal expansion coefficient of the control electrodes 4 to a value larger than the thermal expansion coefficient of the rear substrate 1, in conveying the control electrodes 4 through a heating process (for example, process in which the control electrodes 4 are heated at a temperature of equal to or more than 300 degrees centigrade) in a fabrication process, the control electrodes 4 are fixed to the rear substrate 1 at a temperature higher than a room temperature and, thereafter, the control electrodes 4 are cooled down to a room temperature so that a tensile stress is generated in the control electrodes 4. Accordingly, the control electrodes 4 can always hold the flatness and can hold the gap between the control electrodes 4 and the cathode wires 2 with high accuracy.
On a periphery of a rear panel which constitutes the display device, a scanning circuit 40 and a video signal circuit 20 are arranged. Respective control electrodes 4 are connected to the scanning circuit 40 at control electrode terminals 41 (Y1, Y2, . . . Ym) and respective cathode wires 2 are connected to the video signal circuit 20 at cathode terminals 21 (X1, X2, . . . Xn).
The electron emitting source 2a which has been explained in the above-mentioned embodiments is provided to each one of pixels arranged in a matrix array. R, G, B in the drawing respectively correspond to the pixels of red, green and blue, and lights which correspond to respective colors are made to be emitted from fluorescent materials.
Synchronous signals 42 are inputted to the scanning circuit 40. The scanning circuit 40 is connected to the control electrodes 41 through the control electrode terminals 41 and applies a scanning signal voltage to the control electrodes 4 by selecting the row of the matrix.
On the other hand, video signals 22 are inputted to the video signal circuit 20. The video signal circuit 20 is connected to the cathode wires 2 through the cathode terminals 21 (X1, X2, . . . Xn) and applies voltages to the cathode wires 2 by selecting rows of the matrix in response to the video signals 22. Accordingly, given pixels which are sequentially selected by the control electrodes 4 and the cathode wires 2 emit light with given colors thus displaying two-dimensional images. Due to the display device having the constitutional example of the present invention, a flat panel type display device which can be driven at a relatively low voltage and exhibits high efficiency can be realized.
Here, although the first adhesive agent 14 and the second adhesive agent 15 are used in the respective embodiments which have been explained heretofore, it is possible to adopt the anodic bonding technique as a method for fixing the control electrode 4 and the rear substrate 1. It is also possible to adopt the anodic bonding technique similarly for fixing the gap holding member 9 and the control electrode 4.
Further, with respect to respective embodiments which have been explained in conjunction with
As has been explained heretofore, according to the present invention, by forming the control electrodes 4 using plate-like members and by assembling the control electrodes 4 to the rear substrate 1 and, at the same time, by providing the gap holding members 9 between the rear panel 100 and the face panel 200 with high accuracy, the gap can be held to a predetermined value with high accuracy so that the display device with high reliability can be provided.
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2001-138912 | May 2001 | JP | national |
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20020167265 A1 | Nov 2002 | US |