JP2002072902A - Light emitting panel forming system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a light emitting panel forming system which permits the simulation of a light emitting screen. SOLUTION: This light emitting panel forming system is composed of printers or cutting plotters 11, 12, a monitor 28 and a computer 13 having a computer program which has a function of displaying a design on the screen of the monitor 28, a function of displaying a light emitting region and the design so as to overlap to each other on the screen of the monitor 28 and displaying a virtual light emitting screen of the real light emitting panel, a function of forming the light emitting region on a light emitting substrate with the printer or the cutting plotter 11, a function of drawing out the design on a transparent sheet with the printer 12 and a function of writing an emission control data into a controller.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a thermal transfer member for transferring ink using a thermal head or the like, or transferring ink using a transfer sheet cut using a cutting plotter or the like. The present invention relates to a thermal transfer member for forming an EL panel by forming a dielectric layer and a light emitting layer on a substrate having a large number of pairs of electrodes that can be electrically connected to each other on the surface.

[0002]

2. Description of the Related Art Conventionally, as an EL panel, FIG.
The following are known. In the EL panel 70, a transparent electrode 72 is formed on a transparent substrate 71, and the transparent electrode 72
A light emitting layer 73 and a dielectric layer 74 are formed on the substrate, and a back electrode 75 made of an aluminum sheet is provided on the dielectric layer 74 and covered with a protective film.

In the EL panel 70, as shown in FIG. 16, pictures P1, P2 and characters M1 to P1 drawn on a transparent substrate 71 are formed.
If only M3 is to be illuminated, pictures P1, P2 and characters M1
The dielectric layer 74 and the light emitting layer 75 conforming to the shape of M3 to M3 are formed on a back electrode
5.

[0004]

However, in such an EL panel 70, it is necessary to make a plate for silk printing, especially when changing the luminescent color for each of the patterns P1, P2 and the characters M1 to M3. , Each pattern P1, P2 and character M1 ~
The number of editions corresponding to M3 must be created. Also, the aluminum sheet of the back electrode has to be cut out and arranged in accordance with the pattern and the character, and the wiring process must be performed for each. For this reason, many steps are required, and there has been a problem that the cost is increased.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and has as its object to provide a light-emitting panel creation system that enables ordinary persons who are not familiar with plate making and the like to easily edit and create screens. .

[0006]

In order to achieve the above object, a light emitting panel producing system according to the first aspect of the present invention provides a substrate for forming a dielectric layer and a light emitting layer on a pair of electrodes, or A light emitting substrate for forming the dielectric layer and the light emitting layer between a pair of electrode parts, and forming the dielectric layer and the light emitting layer on the light emitting substrate simultaneously or sequentially A dielectric light emitting layer forming means, a pattern drawing means for drawing a pattern on a light transmitting sheet disposed on the light emitting layer of the light emitting substrate, and the electrodes, a dielectric layer, a light emitting layer, and a light transmitting sheet. A controller for controlling blinking of the light emitting panel, a function of controlling the dielectric light emitting layer forming means, the picture drawing means, and a monitor, and displaying the screen of the light emitting substrate on the screen of the monitor; A function of displaying the light emitting area composed of the dielectric layer and the light emitting layer in an editable manner, a function of displaying the picture on the monitor screen in an editable manner, and the light emitting area and the picture on the monitor screen. A function of displaying a virtual light-emitting screen of an actual light-emitting panel by displaying in a superimposed manner, a function of forming the light-emitting region on the substrate by the dielectric light-emitting layer forming means, and a function of forming the picture by the picture drawing means. And a computer having a function of drawing on the translucent sheet and a function of writing blinking control data in the controller.

According to a second aspect of the present invention, in the light emitting panel producing system according to the first aspect, the computer has a function of simulating a light emitting state of the light emitting area in a screen of the monitor. Features.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a light emitting panel producing system according to an embodiment of the present invention will be described with reference to the drawings.

FIG. 1 shows a light emitting panel producing system according to a first embodiment. This light-emitting panel creation system
Light-emitting substrate 10 and controller 5 as blinking control mechanism
0, a thermal transfer printer or cutting plotter 11 as a dielectric light emitting layer forming means, a printer 12 as a picture drawing means, and a personal computer 13, and a hard disk of the personal computer 13 has image processing for creating a light emitting screen. The program 14A is installed. <Light-Emitting Substrate> As shown in FIGS. 2 and 3, the light-emitting substrate 10 has a pair of comb-shaped electrodes 16 on a polyester resin plate 15.
Are formed in a matrix, a honeycomb, or an irregular shape. Each of the segments 17 can be independently controlled to be energized.

In the present invention, the light-emitting substrate refers to a plate-like or sheet-like resin on which an electrode portion is formed, and in the embodiment, a polyester resin plate 15 on which a segment 17 is formed is shown.

On the segment 17 of the polyester resin plate 15, a dielectric layer 18 and a light emitting layer 19 are formed. On the light emitting layer 19, a transparent sheet 20 having a pattern printed thereon and a protective sheet are mounted. ing.

Note that, instead of the light emitting substrate 10, FIG.
As shown in FIG. 3, a light emitting substrate 23 having a back electrode 22 formed on a support sheet 21 is used. A dielectric layer 24 and a light emitting layer 25 are formed on the back electrode 22 to form a transparent electrode 26 (ITO).
The film and the back electrode 22 may be arranged facing each other, and a transparent sheet 27 may be arranged on the transparent electrode 26. <Dielectric Light Emitting Layer Forming Means> The dielectric light emitting layer forming means includes a printer or cutting plotter 11 and a thermal transfer ribbon and a thermal transfer sheet (not shown) incorporated in the printer or cutting plotter 11. The light emitting substrate to be printed is the light emitting substrate 10 made of the polyester resin plate 15 on which the electrode portions 16 and 16 are formed, or the light emitting substrate 23 made of the support sheet 21 on which the back electrode 22 is formed.

The polyester resin plate 15 or the support sheet 21 to be printed has the electrode portions 16, 16 or the back electrode 22 formed of the polyester resin plate 15 or the support sheet 21.
, The dielectric layer and the light emitting layer can be sufficiently transferred by the printer 11, but once the light emitting layer 19 and the dielectric layer 18 are once transferred to a sheet for indirect transfer, the indirect transfer is performed. Light-emitting layer 19 and dielectric layer 18 of transfer sheet
May be indirectly transferred to the light emitting substrate 10. The same applies to the case of indirect transfer to the support sheet 21.
Further, indirect transfer may be performed from a thermal transfer sheet cut by a cutting plotter.

Printer or cutting plotter 1
The thermal transfer ribbon and the thermal transfer sheet used in 1 are formed by forming a release layer, a light emitting layer 19, and a dielectric layer 18 on a base material made of a plastic sheet or a plastic film, and transferring the dielectric layer 18 to the light emitting substrate 10 side. It has a possible layer configuration. The light emitting layer 19 is made of a heat transferable light emitting body, and the dielectric layer 18 is made of a heat transferable dielectric.

The thermal transfer ribbon and the thermal transfer sheet are formed by sequentially forming a thermal transferable luminous body and a thermal transferable dielectric on the surface of a substrate by coating or the like.

The thermal transferable dielectric is obtained by mixing a dielectric such as barium oxide titanium and a binder such as polyester resin with an ethylene-based organic solvent.

The heat transferable luminescent material is, for example, silicon oxide zinc +
It is a mixture of a luminescent substance such as manganese and a binder such as a polyester resin with an ethylenic organic solvent.

The thermal transfer ribbon and the thermal transfer sheet are
Although the light emitting layer 19 and the dielectric layer 18 are formed in two layers on the release layer of the base material, only the light emitting layer 19 is formed on the release layer of the base material, and on the release layer of another base material. Alternatively, only the dielectric layer 18 may be formed.

These thermal transfer ribbons and thermal transfer sheets are obtained by forming the light emitting layer 19 and the dielectric layer 18 on one base material, or by forming the light emitting layer 19 on the base material, or by using the base material. The light emitting layer 19 and the dielectric layer 18 are once transferred to another indirect transfer sheet or an indirect transfer film or the like by using only the dielectric layer 18 formed thereon,
Next, what is transferred to the indirect transfer sheet or the indirect transfer film may be transferred to the light emitting substrate 10 or the light emitting substrate 23.

Even in the case of indirect transfer, the dielectric layers 18 and 24 are finally formed on the segments 17 of the light emitting substrates 10 and 23 or the electrode portions 22, and the light emitting layers 19 and 24 are formed on the dielectric layers 18 and 24. It goes without saying that 26 is formed. In such an indirect transfer method, the substrate is finally heated and pressurized and transferred by a heat roller. Therefore, when the electrode portions 16 or 22 of the substrate have large irregularities, the thermal head, the transfer sheet, or the transfer ribbon is required. There is no fear of causing a transfer failure such as damage or missing transfer. A flexible plastic sheet or the like having thermal conductivity may be interposed between the heat transfer roller and the indirect transfer film. It is needless to say that the dielectric layer and the light emitting layer are substantially the same in shape and are transferred to the same position on the substrate.

According to this thermal transfer ribbon, the light emitting substrate 1
By controlling the heat generation of the thermal head while relatively moving the thermal transfer ribbon and the thermal transfer ribbon with the thermal transfer ribbons, the dielectric layers 18 and 24 and the light emitting layers 19 and 26 are transferred onto the light emitting substrates 10 and 23. <Picture Depth Means> The pattern depiction means is configured by the printer 12 which performs color printing on the transparent sheets 20 and 27 such as the sheet for an electric signboard. As the printer 12, a commercially available color printer such as a thermal transfer type or an ink jet type capable of printing on the translucent sheets 20 and 27 such as an electric signboard sheet can be used. You may use the cutting printer which cuts by cutting. <Computer> The computer is composed of a personal computer 13, but any other computer capable of forming images, for example, a printer, a word processor capable of drawing, a hand-held computer, a UNI, etc.
An X computer may be used.

In this embodiment, a personal computer 13 is used, and a monitor 28, a printer 11,
12 is controllably connected. <Light-emitting panel creation program> The light-emitting panel creation program runs on the OS of the personal computer 13 and is stored in a hard disk (hereinafter, HDD) as an external storage device of the personal computer 13.

The light-emitting panel creation program is composed of an image processing program 14A described in, for example, C language, C ++ language, Java language or the like, and an image control program 14B.

The image processing program 14A can display a plurality of layers on the screen of the monitor 28 in a superimposed manner.
Printing can be performed for each predetermined layer, and the screens of all layers can be printed collectively, so that a picture can be edited for each layer. In the image processing program,
At least three layers are used.

FIGS. 5 to 8 show screens shown in these at least three layers. 5 to 8, buttons for various operations such as file operation, editing, display, and printing of the image processing program are omitted.

FIG. 5 shows a screen of the first layer 40 displayed on the lowermost layer. In this first layer 40,
The light emitting substrates 10 and 23 to be created (hereinafter, the light emitting substrate 10 will be described, and since the light emitting substrate 23 is the same,
Invite explanation. The board image 41 showing the contour shape and the segment 17) is displayed.

The board image 41 can be displayed in a state where the size of the light emitting board 10 to be actually created in the vertical and horizontal directions is equal to, enlarged, or reduced. In the board image 41, the individual segments are arranged based on, for example, XY orthogonal coordinates and can be specified.

The board image 41 is created by operating the mouse 30 or the keyboard 31 (see FIG. 1) and
Image data stored in D, FDD, a memory card, or the like is called and edited, or newly created.

FIG. 6 shows a second layer 42 displayed on the first layer 41. In this second layer 42,
The light emitting areas 43A to 43J composed of the dielectric layer and the light emitting layer are displayed. The light emitting areas 43A to 43H are operated by operating the mouse 30 or the keyboard 31 to call and edit image data that has already been created, or are newly created.

The scale of each of the light emitting units 43A to 43H is the same as that of the substrate screen 41 of FIG. 5, and the scale of the first layer 40 and the scale of the second layer 42 are linked.

FIG. 7 shows the third layer 44. This third
The layer 44 is displayed on the second layer 42, and the patterns 45A to 45H are called and displayed on the light emitting areas 43A to 43H, or are newly created.

FIG. 8 shows a state where the third layer 43 is displayed in a superimposed manner on the first layer 41 and the second layer 42, and the picture 45A is displayed on the monitor 28.
The screen of the light-emitting panel displaying ~ 45H can be seen.

In the monitor 28, the scale ratios of the first layer 40 and the second layer 42 are linked,
A to 45H are the same as the light emitting units 43A to 43H and the substrate screen 41 of FIG. 5, and the first layer 40, the second layer 42, and the third layer 44 are linked in scale.

In the image processing program 14A, the second
The light-emitting areas 43A to 43H of the layer 42 are cut or printed or sheet-cut by a printer or a cutting plotter in accordance with the scale of the light-emitting substrate 41 of the first layer 40 and separated from the first layer 40 and the third layer 44. You.

In the image processing program 14A, the patterns 45A to 45H of the third layer 44 are transmitted from the first layer 40 and the second layer 42 in accordance with the scale of the light emitting substrate 41 of the first layer 40. The printed image is separated by the printer 12.

Thus, the dielectric layer 18 is formed on the light emitting substrate 10.
And the light emitting layer 19 can be formed. Also, picture 4
5A to 45H are printed on the transparent sheet 20. <Light Emission Sequence> Next, the light emission panel creation program has a light emission panel emission sequence simulation program 14B based on the image file created by the image processing program 14A.

As an example, the light-emitting panel simulation program 14B individually creates control data for changing the light-emitting state of the light-emitting panel and stores it in an external storage device such as an HDD or a memory of a computer.
These control data are called out in a predetermined order and at a predetermined time and output to the monitor 28.

Of course, the individual patterns 45A to 45H can be
File or data in JPEG or BMP format, store it in a predetermined folder such as an HDD, and display the light-emitting panel screen as an HTML file or XML.
HTML file of this light-emitting panel screen
In a predetermined area of the file or XML file, a picture 45
The file data of A to 45H may be called and output.

As described above, in the method of creating and editing the control data while confirming the change of the light emitting state of the light emitting panel on the monitor screen, the display order, the display time, and the blinking state of the pictures 45A to 45H can be freely changed by changing the parameters. To
The desired sequence can be obtained. <Storing of Light Emitting Sequence> Next, the light emitting sequence of the light emitting panel thus created is stored in an actual light emitting panel controller 50 (microcomputer and peripheral unit, see FIG. 2). According to the stored sequence, power supply control to the segment to emit light is performed.

In the case of the light emitting substrate 10 as shown in FIG.
Power is supplied to the segment 17 composed of the pair of comb blade electrodes 16 from the output terminal of the control device 50 via the connector C. In the light emitting substrate 10 of FIG.
Are formed in a total of eight places, so that the terminals of the control device 50 supply power to each segment 17 in a predetermined order and for a predetermined time. The sequence program at this time is created by a compiler such as an assembler language of the control device 50 or a C language operable by the microcomputer. The output order and the output time are determined by the emission state control data of the above-described emission panel creation program. To the sequence of <Matrix-Type Light-Emitting Substrate> FIGS. 9 to 13 show a light-emitting substrate 10 in which segments 17 are arranged in a matrix.
23 are shown below.

In the case of the matrix type light emitting substrate 10,
A substrate screen 61 of the light emitting substrate 10 is displayed on the first layer 60. The substrate screen 61 is used for the light emitting substrate 10 to be transferred.
Scanner data or board data created to correspond to the light emitting board 10 can be displayed. This substrate screen 61 is composed of an actual light emitting substrate 10 and a dielectric layer to be transferred.
The display is performed so that the positions and the sizes of the light emitting layer and the pattern or the like match.

FIG. 10 shows the second layer 62. The second layer 62 is displayed according to the position and size of the substrate screen 61, and includes the formation regions 63A to 63A to where the dielectric layer 18 and the light emitting layer 19 are formed.
63J is displayed so that it can be created and edited. This formation area 6
3A to 63J can be newly created, and can also read and edit and process existing image data. The display screen of the second layer 62 is transferred onto the light emitting substrate 10 by the printer 11 using a transfer ribbon.

FIG. 11 shows the substrate screen 6 of the first layer 60.
1, the dielectric layer 18 of the second layer 62 and the light emitting layer 1
9 shows a screen in which nine forming regions 63A to 63J are displayed in a superimposed manner. Thereby, the segment 17 located under the formation regions 63A to 63J of the dielectric layer 18 and the light emitting layer 19 can be specified.

FIG. 12 shows the third layer 64. The third layer 64 includes a substrate screen 61 and formation areas 63A to 63A.
The picture 65A-65J can be newly created on the formation area 63A-63J, and the existing image data can be read out and edited / processed. Patterns 65A-6 of third layer 64
5J is color-printed on the transparent sheet 20 by the printer 12.

FIG. 13 shows the first to third layers 60 and 6.
2 shows a screen on which 2, 64 is superimposed. With this screen, the formation areas 63A to 63J or the patterns 65A to 65J
Can be confirmed and the color or brightness can be confirmed. When a change is required, the process returns to the respective layers and the editing process is performed. <Emission simulation screen of matrix-like substrate> A program for creating a light-emitting panel of a matrix-like substrate is shown in FIG.
As in the case of the creation of the light emitting substrate 10, a simulation program 14B of the light emission sequence of the light emitting panel is provided based on the image file created by the image processing program 14A.

As an example, the light-emitting panel simulation program 14B individually creates screen files for changing the light-emitting state of the light-emitting panel, stores them in a folder of an external storage device such as an HDD, and calls these screen files. Output to the monitor 28.

Of course, individual pictures 65A to 65J can be
File or data in JPEG or BMP format, store it in a predetermined folder such as an HDD, and display the light-emitting panel screen as an HTML file or XML.
HTML file of this light-emitting panel screen
In a predetermined area of the file or the XML file, a picture 65
A to 6J file data may be called and output.

As described above, in the method of creating and editing the control data while confirming the change of the light emitting state of the light emitting panel on the monitor screen, the display order, the display time, and the blinking state of the pictures 65A to 65J can be freely changed by changing the parameters. To
The desired sequence can be obtained. <Creation of light emission sequence for matrix type substrate>
The light emission sequence of the matrix type substrate will be described.

First, as shown in FIG. 14, a matrix type light emitting substrate 70 has a surface on which segments 72 each comprising a pair of electrode portions 71 are formed in a matrix, and each segment is arranged in the XY direction or an arbitrary direction. Are individually controllably connected by terminals.

Accordingly, the segments of the light emitting substrate 70 located below the light emitting units 63A to 63J are divided into the light emitting units 63A to 63J.
Group according to.

For example, as shown in FIG.
The segments located below A are grouped into one control unit data, and similarly, the light emitting units 63B to 63J
Are segmented into control unit data as another group.

The segment control unit data of each of the light emitting units 63A to 63J is converted into actual position information of the segment of the light emitting panel. For example, as shown in FIG.
The segment control unit data of 3A is from the terminal “00000100” to the terminal “000011111” in the X-axis direction.
And the terminal “0” from the terminal “00000110” in the Y-axis direction.
0001100 ". Therefore, the light emitting unit 63A
Can be managed as a set of position information of these segments.

In the image processing program, if the light emitting units 63A to 63J are converted into bitmap data corresponding to the segments of the light emitting substrate, the bitmap data can be converted into segment data.

The control unit data of the segment is stored in each light emitting unit 6.
Since these data correspond to 3A to 63J, these data are stored in a memory (EEPROM or the like) of the actual light emitting panel control device 50 (a 16-bit microcomputer or an 8-bit microcomputer may be used).

The light emitting sequence of the light emitting panel is as follows.
The segment control unit data of 3A to 63J is called from the light emitting panel 50 in a predetermined order and for a predetermined time and controlled. <Process of Producing Light Emitting Panel> Next, the process of producing a light emitting panel will be described. First, the segments 17 are formed on the surface of the light emitting substrate 10, and then the dielectric layer 18 and the light emitting layer 19 are formed on the surface by the thermal transfer printer 11. Further, the printer 63 performs color printing of the patterns 63A to 63J on the transparent sheet 20,
Finally, a transparent sheet 20 is stuck on the light emitting layer 19.

As described above, the dielectric layer 18 and the light emitting layer 19 are formed by the thermal transfer printer 11 and the thermal transfer ribbon, and the pattern 12A is formed on the transparent sheet 20 by the printer 12.
~ 65J, and can be formed very easily in a short time. That is, plate making becomes unnecessary, and an inexpensive light-emitting panel can be manufactured in a small number of steps.

In the light emitting panel prepared as described above, when an AC voltage is applied to the segment 17, the dielectric layer 18 is insulated by the AC current, and the light emitting layer 19 emits light.

By controlling the AC voltage applied to each segment 17, the light emitting layer 64 of each of the pictures 65 A to 65 J is controlled.
A to 64J can emit light independently of each other.
That is, light can be emitted independently for each of the patterns 65A to 65J, and light can be emitted in a free light emission pattern.

[0059]

As described above, according to the light emitting panel producing system of the first aspect of the present invention, a light emitting screen corresponding to an actual light emitting panel can be freely created and edited on a monitor screen. After the light emitting area and the pattern are determined, the light emitting area can be printed on the light emitting substrate by setting the substrate on the dielectric light emitting layer forming means. When drawing a picture, the translucent sheet can be set on the picture drawing means and the picture can be drawn by the picture drawing function. At this time, the brightness of the light-emitting area and the shape and color of the picture (including characters) can be freely changed, so that the light-emitting panel can be easily manufactured without a light-emitting panel expert.

According to the light emitting panel production system of the second aspect of the present invention, after setting the light emitting area and the pattern of the light emitting panel as in the first aspect, the light emitting area, the light emitting time, the blinking, and the brightness of the light emitting area are further set. Set the light emission control information such as
Simulation of the actual light emitting state of the light emitting panel can be performed.

In the light emitting panel production system according to the first and second aspects, the dielectric light emitting layer forming means is provided on the substrate by using a heat transfer ribbon or a heat transfer sheet formed of a dielectric layer, a light emitting layer and a plurality of layers on a base material. A direct transfer printer is used at a time, but a dielectric layer thermal transfer ribbon or thermal transfer sheet with only a dielectric layer formed on the substrate is transferred and formed on the substrate by a printer, and then the substrate is transferred onto the substrate. The thermal transfer ribbon or thermal transfer sheet for the dielectric layer having only the light emitting layer formed thereon may be formed by transferring the light emitting layer region onto the dielectric layer region by a printer.

Further, in these transfer steps, transfer may be performed by indirect transfer instead of direct transfer onto the substrate. In this case, a light emitting layer and a dielectric layer are formed by primary transfer on a substrate sheet for indirect transfer, and the dielectric layer is formed on an electrode portion of the substrate during secondary transfer. If a thermal head is used for the primary transfer and a heat roller is used for the secondary transfer on the substrate, the transfer can be performed favorably even if the unevenness of the electrode portion matches the light emitting panel substrate. Further, a dielectric layer and a light emitting layer may be formed on a substrate by indirect transfer from a thermal transfer sheet cut by a cutting plotter.

[Brief description of the drawings]

FIG. 1 is a schematic diagram of a light emitting panel creation system according to an embodiment of the present invention.

FIG. 2 is an enlarged view of a light emitting substrate used in the production system of FIG.

FIG. 3 is an enlarged sectional view of the light emitting substrate of FIG. 2;

FIG. 4 is an enlarged cross-sectional view of a light-emitting substrate in which a dielectric layer and a light-emitting layer are formed between a pair of electrodes.

FIG. 5 is a first view of a monitor screen according to an image processing program.
The figure of the board screen displayed on the layer of.

FIG. 6 shows a second example of a monitor screen according to the image processing program.
Of the formation area of the dielectric layer and light emitting layer displayed on the layer of

FIG. 7 shows a third screen on the monitor screen according to the image processing program.
Of the picture screen displayed on the layer of

FIG. 8 shows a first example of a monitor screen according to an image processing program.
The figure which superimposedly displayed the image displayed on the 3rd layer.

FIG. 9 is a monitor display screen of a matrix-type light-emitting substrate displayed on a first layer of the image processing program.

FIG. 10 is a monitor display screen of a light emitting unit displayed on a second layer of the image processing program.

FIG. 11 is a monitor screen in which the light emitting units of the second layer are displayed in a superimposed manner on the matrix type light emitting substrate screen of the first layer.

FIG. 12 is a monitor screen of a picture in a third layer.

FIG. 13 is a monitor screen on which a light emitting substrate screen of a first layer, a light emitting unit display screen of a second layer, and a picture screen of a third layer are displayed in a superimposed manner.

FIG. 14 is an enlarged plan view of a matrix-type light-emitting substrate, and is an explanatory diagram for specifying a segment below a formation region of a dielectric layer and a light-emitting layer.

FIG. 15 is a cross-sectional view of a conventional EL panel.

FIG. 16 is a schematic diagram of a light emitting state of a conventional EL panel.

[Explanation of symbols]

 Reference Signs List 10 light emitting substrate 16 electrode 17 segment 40 first layer 41 light emitting substrate on screen 42 second layer 43A to 43H light emitting unit on screen 44 third layer 45A to 45H picture on screen

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 2C065 AF02 DA36 3K007 BA06 CA01 CB01 DB03 5B049 BB07 DD01 DD04 DD05 EE07 EE28 EE41 FF02 FF03 FF04 FF08 FF09 5G435 AA00 AA17 BB05 CC09 EE12 KK00 KK05 KK10

Claims (2)

[Claims] 1. A substrate for forming a dielectric layer and a light emitting layer on a pair of electrode portions, or a substrate for forming the dielectric layer and the light emitting layer between the pair of electrode portions. A light-emitting substrate; a dielectric light-emitting layer forming means for simultaneously or sequentially forming the dielectric layer and the light-emitting layer on the light-emitting substrate; and a light-transmitting sheet disposed on the light-emitting layer of the light-emitting substrate. A pattern drawing means for drawing a pattern, a controller for controlling the flashing of light emission of the light emitting substrate, a dielectric light emitting layer forming means, the pattern drawing means and a monitor for controlling the light emitting substrate on the monitor screen. A function of displaying a screen, a function of displaying the light emitting region composed of the dielectric layer and the light emitting layer on the monitor screen in an editable manner, and a function of displaying the picture on the monitor screen in an editable manner, A function of displaying the light-emitting area and the pattern in a superimposed manner on the screen of the monitor to display a virtual light-emitting screen of an actual light-emitting panel; And a computer having a function of forming the image on the translucent sheet by the image drawing means and a function of writing blinking control data in the controller. Light emitting panel creation system. 2. The light-emitting panel creation system according to claim 1, wherein the computer has a function of simulating a light-emitting state of the light-emitting area in a screen of the monitor.