RU2254619C2 - Plasma panel of indication screen - Google Patents

Abstract

FIELD: indication equipment engineering.

SUBSTANCE: device has back dielectric plates on back side, adjacent along horizontal line, in amount of n≥2... and back dielectric plates, adjacent along vertical line, in amount of m≥2..., which allowed to separate electrodes of anodes of panel on groups with their own electrodes outputs, and to increase duration time of charge burning with less scanning of cathodes.

EFFECT: increased brightness of display elements of plasma panel, removed image mosaicism, higher quality of displayed data.

4 cl, 10 dwg

Description

The invention relates to the field of display technology and can be used to build typesetting color television screens for collective use on flame panels.

Known plasma panel dial screen containing the front and back dielectric plates, a system of spatially perpendicular electrodes of the anodes and cathodes with leads on the ends of the dielectric plates, the dielectric matrix forms the display elements [1]. The reason that impedes the achievement of the required technical result when using the known device is that it is impossible to display television information in the known plasma panel, since there are no phosphors in the display elements.

A known plasma panel for a typeset screen containing the front and back dielectric plates, a system of spatial mutually perpendicular electrodes of the anodes and cathodes made of wires that use the matrix to form the display elements, on the surface of the back dielectric plate in the display elements there is a phosphor [2]. The reasons that impede the achievement of the required technical result when using the known device include the fact that in the known plasma panel the formation of protrusions with a trapezoidal cross-section and dielectric barriers in accordance with the proposed relations do not allow the phosphor to be used on the face plate due to increased ultraviolet radiation through the gap trapezoidal shape between the protrusions relative to the front plate. The absence of a phosphor on the front plate reduces the brightness by 20% -30%. In addition, the serial technological process of manufacturing panels is complicated in compliance with the proposed ratios, because additional equipment with high accuracy is required, which increases the cost of the panel.

Known plasma panel for a dial screen containing the front and back dielectric plates, a system of spatial mutually perpendicular electrodes of the anodes and cathodes made of wires that form the display elements using a matrix, and a phosphor is located on the surface of the back dielectric plate in the display elements, and the thickness of the dielectric plates and wire diameters are selected from the proposed ratio [3]. The reasons that impede the achievement of the required technical result when using the known device include the fact that in the known plasma panel the proposed ratio between the thickness of the dielectric plate and the diameter of the wires from the lower boundary does not function, therefore, it cannot be used as a criterion for choosing the plate thickness and wire diameters electrodes.

The closest device of the same purpose to the claimed device is a type-plate plasma panel containing a front and back dielectric plates connected along the perimeter by a sealing seam, and a front black matrix with a phosphor is formed on the inner surface of the front dielectric plate. On the rear dielectric plate there is a gas evacuation and filling pad, in each row of the panel the display elements are formed by dielectric matrix barriers, and protrusions are placed on the surface of the dielectric barriers of the matrix along the length of the display elements, which are spaced apart from the dielectric barriers of the width of the display elements. The anodes and cathodes in the display elements are made of conductors in the form of a wire and are arranged orthogonally with each other, while the anodes are vertical to the screen, and the cathodes are parallel to the lines, the conclusions of the anodes and cathodes are output through the ends of the back plate, the color of the glow of each display element is determined by the phosphor [ 4]. The reason that impedes the achievement of the required technical result when using the known color plasma panel adopted as a prototype is that there are no conditions in this panel for increasing the brightness of the glow of the display elements.

The claimed group of inventions solves the problem of improving the quality of the displayed information on a screen typed from plasma panels. When implementing the group of inventions, a unified technical result will be obtained, namely, increasing the brightness of the luminescence of the display elements of the plasma panel and the quality of the displayed information by introducing n≥1 back dielectric plates on the back side, horizontally adjacent and from m≥2 back dielectric plates vertically, relative to the front plate, which allowed the electrodes of the anodes of the panel to be divided into groups with their electrode leads to increase the duration of the discharge burning time, as well as to remove l mosaic in the panel with increased dimensions.

The specified technical result in the implementation of the group of inventions is achieved in that in the first embodiment of the invention, a front black matrix with a phosphor is formed on the inner surface of the front dielectric plate in the well-known plasma panel of a type-plate containing front and back dielectric plates connected along the perimeter by a sealing seam. On the back dielectric plate there is a gas evacuation and gas filling plug, in each row of the panel display elements are formed by dielectric matrix barriers. On the surface of the dielectric barriers of the matrix along the length of the display elements are projections that are spaced relative to the dielectric barriers of the width of the display elements. In the display elements, the anodes and cathodes are made of conductors in the form of a wire and are arranged orthogonally with each other. In this case, the anodes are vertical to the screen, and the cathodes are parallel to the rows, the conclusions of the anodes and cathodes are output through the ends of the back plate. The color of the glow of each display element is determined by the phosphor, while on the back side the panel is made of n≥2 back dielectric plates adjacent horizontally, and m≥2 back dielectric plates adjacent vertically, with a back black formed on each plate on the surface a matrix in the form of mutually perpendicular dielectric strips. A phosphor is deposited between the dielectric strips, on the surface of which anode wires are located, sealed on the surface of the dielectric strips that determine the width of the display element of the back black matrix, the first layers of the dielectric barriers of the matrix, and the second layers of the dielectric barriers of the matrix are sealed with cathodes. The second layers of the dielectric barriers of the matrix are projected with a height equal to the distance of the mean free path of ionizing electrons at a selected pressure of the gas mixture. The conclusions of the wires of the anodes and cathodes pass through the ends of these plates, while on the edges of the outer part of each back dielectric plate, bevels of the sealing and laying of wires are made, and at the ends with the ends of the anodes grooves are cut for laying the anodes, while in the dielectric plates on adjacent sides of the grooves for laying anodes, they are located asymmetrically on one edge with respect to the other edge. In the rear dielectric plates located around the perimeter of the panel, the grooves are made only on adjacent sides. In the back plates with adjacent sides in the display elements located on the edges of adjacent sides, from one edge the extreme dielectric barrier of the matrix along the row of display elements or along the length of the display elements vertically is not formed. Chamfers are made on the front dielectric plate along the edges of the ends from the inner surface. Chamfers are made on the front dielectric plate along the edges of the ends from the outer and inner surfaces of the sides. The band width of the back black matrix is selected from the relation: a = (1.1 ÷ 1.4) b, where a is the band width of the black matrix, b is the width of the dielectric barrier of the matrix. The width of the stripes on the front black matrix is the vertical width of the projections, and the horizontal width of the screen is equal to the width of the dielectric barriers of the matrix, which determine the width of the display elements. A gas evacuation and gas filling plug 9 is located on each back dielectric plate. A gas evacuation and gas filling plug is located on every second back dielectric plate or at the boundary of adjacent dielectric plates. The width of the protrusions is determined from the relation: b1 = (0.5 ÷ 1.0) b, where b is the width of the dielectric barrier of the display element, b1 is the width of the protrusion, and the length of the gap between the protrusions is determined from the relation: L = (0.8 ÷ 1 , 2) b, where b is the width of the dielectric barrier of the display elements, L is the length of the gap. The protrusions are made of transparent dielectric material. The width and depth of the groove for laying the anode is selected according to the relations: 2.0d≤c≤0.3S and 1.5d≤е≤0.2b, where b is the width of the dielectric barrier of the display element, d is the diameter of the wire, s is the width of the groove, e - groove depth, S - width of the display element. After sealing the panel on each back dielectric plate, a printed circuit board is installed for wiring the conclusions of the anodes and cathodes for connection to a control circuit or to part of the elements of a control circuit. On the back side, the panel is made of m≥2 back dielectric plates adjacent vertically and contains one gas evacuation and filling plug located on one of the back dielectric plates or at the boundary of adjacent back dielectric plates. In the second embodiment of the invention, with m = 2 back dielectric plates adjacent vertically and n≥1 back dielectric horizontal plates, a back black matrix is formed on the surface of the back plate, and a phosphor is deposited between the dielectric strips, on the surface of which the wires of the anodes of each element are laid display lines, the wires of the anodes are sealed on the surface of the dielectric strips of the back black matrix by the first layers of the dielectric barriers of the matrix, and in the middle of the back plate on the surface of the die of the electric strip of the back black matrix, the anode wires are sealed with two barriers with a gap between each other, in which the anode wires are cut and insulated by a dielectric. The cathode wires are sealed with second layers of dielectric matrix barriers, on which protrusions are deposited with a height equal to the distance of the free path of ionizing electrons at a selected gas mixture pressure.

In the third embodiment of the invention, recesses are formed on the front dielectric plate between the dielectric strips of the black matrix along the length of each display element, on the surface of which a phosphor is applied. On the front dielectric plate of the panel, for each color of the phosphor, between the dielectric stripes of the black matrix, vertical notches are formed along the vertical of the panel with a length equal to the length of the anode.

In a fourth embodiment of the invention, the typesetting plasma panel comprises a front and a back dielectric plate connected along the perimeter by a sealing seam, and a front black matrix with a phosphor is formed on the inner surface of the front dielectric plate. On the back dielectric plate, the matrix barriers from the dielectric form display elements containing the wires of the anodes and the cathode wires perpendicular to them. The thickness of the front and back dielectric plates Tm and the height h of the location of the cathode wires on the barriers of the dielectric matrix relative to the surface of the back plate are selected from the relation: 12≥Tpl / h≥1, while the wires of the anodes and cathodes with a diameter of (0.1 ÷ 0 , 25) mm. The execution on the rear side of the panel of n≥2 ... back dielectric plates adjacent horizontally, and from m≥2 ... back dielectric plates adjacent vertically, with a different number of rams for pumping and filling with a gas mixture and various options for their location makes it possible to divide the anodes into two groups with their own conclusions and have independent scan scans along the cathodes when entering and displaying information. This increases the duration of the discharge burning, which increases the brightness of the panel by 1.8-1.9 times, with the formation of the phosphor on the surfaces of the front and back plates. The application of protrusions with the proposed location and size eliminates the statistical delay in the occurrence of the discharge, which ensures reliable operation of the panel, and also forms a black mask on the front plate with optimal strip sizes, which increases the contrast of the displayed information and, accordingly, the image quality. The introduction of grooves with the proposed dimensions on the edges of the adjacent sides of the back dielectric plates ensures that the plates are positioned without a gap, which, together with the absence of dielectric barriers of the width of the display element located on the adjacent side of the display back from the edges of the back plate, makes it possible to produce a panel with the same element sizes display in all lines throughout the display field, which removes the "mosaic" image on the panel. Installing on each back plate options for a printed circuit board wiring the conclusions of the anodes and cathodes allows you to choose the best way to connect the panel to the control circuit. During internal cutting of the indication electrodes between two barriers, the panel has increased sealing reliability. The implementation of the panel with the front plate, where the phosphor of the display element is located in the recesses with different options for their implementation, increases the brightness of the panel. The proposed relationship between the thickness of the dielectric panel and the height of the winding of the cathode wires allows eliminating the deformation of the plate at a selected size of the display element, which ensures uniformity in size along the height of the display elements over the entire display area of the panel, allows you to create stacked screens having minimal dimensions of the joint seams between the panels, and increases quality of information displayed. To check the compliance of each of the variants of the claimed group of inventions with the requirement of inventive step, an additional search was carried out for known solutions in order to identify features that match the distinctive features of the prototype of the claimed invention, the results of which show that the claimed invention does not explicitly follow from the prior art. Since technical solutions are not known in which an increase in the brightness of the luminescence of a panel of a typeset screen would be achieved by making a back dielectric plate from n≥2 ... back dielectric plates adjacent horizontally and from m≥2 ... back dielectric plates vertically, on which black masks are formed with a phosphor and barriers of the dielectric matrix of the display elements and the wires of the anodes and cathodes are wound. Recesses are located on the front dielectric plate, and grooves are made for the conclusions of the anodes at the ends along the edges of the adjacent sides of the back plates, and the grooves of one plate are offset relative to the other plate to insulate the separated anodes and form display elements with the same dimensions in all rows of the panel, including number in a row located at the junction of the rear dielectric plates. The protrusions on the dielectric barriers are applied with certain sizes, relative to which the bands of the black matrix are formed on the front plate. Various options for the location on the back plate of the evacuation plug and gas filling with the gas mixture allow for a more optimal design of the control circuit, and the use of several evacuation and gas mixture filling panels in the panel increases the life of the panel.

The proposed plasma panel of the dial screen is represented by the drawings:

Figure 1 schematically shows the plasma panel of a typeset screen.

Figure 2 is a schematic vertical sectional view of the plasma panel of the first embodiment.

Figure 3 is a schematic sectional view along a line of a plasma panel.

Figure 4 schematically shows a part of the dielectric plate of the back side of the panel.

Figure 5 schematically shows the dielectric plate of the back side with grooves at the ends of adjacent sides.

Figure 6 schematically shows the end face of the dielectric plate of the back side of the panel.

7 schematically shows another panel of the first embodiment.

Fig. 8 is a schematic vertical sectional view of a plasma panel of the second embodiment.

Figure 9 is a schematic sectional view along the line of the plasma panel of the third embodiment.

Figure 10 is a schematic sectional view along the line of the plasma panel of the fourth embodiment.

In the plasma panel 1 of the dial screen (Fig. 1), each row 2 contains display elements 3, which are visually separated from each other by strips of a black matrix 4 formed on the inner surface of the front dielectric plate 5. On the back side, the panel has two dielectric plates 6m1, 6m2 vertically and two dielectric plates 6n1, 6n2 horizontally. In each back dielectric plate, on one side, the ends of the wires of the anodes 7 pass through the ends, on the other side, the ends of the wires of the cathodes pass through the ends 8. The panel 1 can have a gas evacuation and filling plug 9 on only one plate 6, or on each plate shown with a dashed line ( figure 1). In the section of the panel along the line on the surface of each back plate 6 (Fig. 2), a black matrix is formed with dielectric strips 10, the width of which is selected from the relation a = (1.1 ÷ 1.4) b, where a is the bandwidth of the black matrix, b is the width of the dielectric barrier of the matrix. Between the dielectric strips 10, in the display elements 3 on the surface of the back plate 6 there is a phosphor 11, on the surface of which the wires of the anodes 7 are laid. The wires of the anodes 7 are sealed with the first layers of the dielectric barriers 12 of the matrix, which is formed on the surface of the dielectric strips 10 of the black matrix. The wires of the cathodes 8 in the display elements are sealed with second layers of dielectric barriers 13 of the matrix. The front dielectric plate 5 and the rear dielectric plates 6 of the panel 1 are sealed around the perimeter and between the adjacent rear dielectric plates 6n, 6m by the seam 15 (Fig.2). The front and back dielectric plates 5, 6 at the edges have chamfers 16, which increase the reliability of sealing, and the back plates with chamfers make it possible to more optimally lay the wires of the anodes 7 with a smaller bending angle along the end of the plates through the grooves 17. On the surface 18 of the dielectric barriers 13 are applied protrusions 14 (Figs. 3, 4), the width of which is determined from the relation: b1 = (0.2 ÷ 1.0) b, where b is the width of the dielectric barrier of the display element, b1 is the width of the protrusion, and the length of the gap between the protrusions 14 is determined from the relation: L = (0.8 ÷ 1.2) b, where b is the width and the dielectric barrier 12, 13 of the matrix display of elements, L - the length of the gap. The height k of the protrusions is not less than the mean free path of ionizing electrons at a selected pressure of the gas mixture. At a gas pressure of about 100 Top, the mean free path of ionizing electrons is 10 ^-2 -10 ^-3 cm. On the front dielectric plate 5 of the panel (Fig. 3), the width of the stripes of the black matrix 4 in each display element 3 can be vertically equal to or greater than the width protrusions 14 on the surface 18 of the dielectric barriers 12, 13 of the matrix of the display elements 3. The protrusions 14 with a width of "b1" are located on the surface 18 of the dielectric barriers 12, 13 of the matrix with a width of "b" along the length of the display element and at a distance of "L" with each other given the width "b" of the barriers 1 2, 13 (Fig. 4). An embodiment of the protrusions 14a (FIG. 1), where the beginning of the protrusions in the extreme display elements is aligned with the extreme dielectric barriers of the matrix, which determine the width of the display element. On the back side of the dielectric plates (FIG. 5), grooves 17 are shown on the back plate 6n and on the back plate 6m. The width of the groove "c" is selected taking into account the diameter of the wire "d" and the width "S" of the display element, and the depth "e" of the groove is determined taking into account the diameter of the wire and the width of the dielectric barrier of the matrix of the display element. In adjacent rear plates 6 relative to each other, the offset of the grooves 17 is selected by the value of "Lcm", taking into account the diameter of the wires. To reduce the likelihood of a circuit, when laying the wires of the anodes in adjacent back plates, the grooves are made with an inclination at each end, as shown in Fig.6. The slope of the grooves at each adjacent end of the back plate is performed in different directions. In the panel (Fig. 7), on one adjacent back plate 6m, in the display elements located on the edges of adjacent sides, the extreme dielectric matrix barrier along the line of display elements is not formed on one edge. In the second embodiment of the panel design of the dial screen (Fig. 8), the wires of the anodes are cut in the middle of the panel between the dielectric barriers of the matrices of adjacent rear dielectric plates 6n and 6m. Fig. 9 shows a sectional view of the plasma panel of the type-setting screen of the third embodiment, in which recesses 19 are formed on the front dielectric plate 5, onto the surface of which a phosphor 11 is applied. FIG. 10 shows a panel of the fourth embodiment, in which the thickness Tm of the front and back dielectric plates and the height h of the cathode wires on the barriers of the dielectric matrix relative to the surface of the back plate are selected from the ratio: 12≥T / h≥2, while the wires of the anodes and cathodes have a diameter ( 0.1-0.25) mm.

The operation of the plasma panel of the dialer is as follows. When displaying information with a repetition period of the occurrence of discharge T in the selected display elements 3 of each row 2 along which the cathodes 8 are located, a voltage with an amplitude higher than the voltage of the occurrence of the discharge in the selected display element is applied between the selected anode 7 and the cathode 8 of the selected row 2, in which breakdown of the gas gap between the anode and cathode occurs, after which the voltage decreases to the voltage of the combustion discharge. The ultraviolet radiation of this discharge excites the phosphor 11, providing its glow in the selected display element. Since the repetition period of the discharge and its duration in the display element depends on the number of lines, the brightness of the glow of the display element increases with a reduced number of lines. The proposed design is implemented in a panel 400 × 400 mm in size, with a color pixel size of 6 × 6 mm, and a 6 × 2 mm display element for a typeset screen has n = 2 back plates horizontally and m = 4 back plates vertically. Compared with the known panels, the brightness is increased by 1.8 -1.9 times. If in the prototype the panel has a brightness (120-140) cd / m ² , then in the proposed invention, the panel has a brightness (220-250) cd / m ² .

Thus, the above information indicates the fulfillment of the following set of conditions when using the claimed group of inventions:

- a tool embodying the claimed group of inventions in its implementation, intended for use in a display system made in the form of a dial screen from modules based on plasma panels for displaying color video information;

- for the claimed group of inventions, as described in the independent claims, the possibility of its implementation using the means and methods described above or known prior to the priority date is confirmed;

- a tool that embodies the claimed group of inventions in its implementation, is able to ensure the achievement of the perceived by the applicant technical result.

Sources of information

1. Patent EP 0696047, cl. H 01 J 17/04 of 02/07/1996

2. Patent RU 2188461, cl. G 01 F 9/313 dated 08/27/2002

3. Patent RU 2186641, cl. G 01 F 9/313 dated 07/20/2002

4. Patent RU 2076382, cl. H 01 J 17/49 dated 03/27/1997

Claims (20)

1. Plasma screen panel containing the front and back dielectric plates connected along the perimeter by a sealing seam, a front black matrix with a phosphor is formed on the inner surface of the front dielectric plate, a pumping and filling gas bar is located on the back dielectric plate, and display elements in each row of the panel matrices are formed by dielectric barriers and protrusions are applied to the surface of the matrix of dielectric barriers along the length of the display elements, which located at intervals relative to the width of the dielectric barriers of the display elements, the anodes and cathodes in the display elements are made of conductors in the form of wires and are arranged orthogonally with each other, while the anodes are vertical to the screen, and the cathodes are parallel to the lines, the conclusions of the anodes and cathodes are output through the ends of the back plate, the color of the glow of each display element is determined by the phosphor, while on the back side the panel is made of n≥2 ... back dielectric plates adjacent horizontally and from m≥2 ... back dielectric plates adjacent vertically, while in each plate on the surface a back black matrix is formed in the form of mutually perpendicular dielectric strips, a phosphor is deposited between the dielectric strips, on the surface of which there are anode wires that are sealed on the surface of the dielectric strips that determine the width of the display element the back black matrix with the first layers of the dielectric barriers of the matrix, and the second layers of the dielectric barriers of the matrix are sealed cat Odes and protrusions with a height equal to the mean free path of ionizing electrons are deposited on the second layers of the dielectric barriers of the matrix, at the selected pressure of the gas mixture, the leads of the wires of the anodes and cathodes pass through the ends of these plates, and chamfers are made on the edges of the outer part of each back dielectric plate and laying of wires, at the ends with the terminals of the anodes, grooves are cut for laying anodes, while in the dielectric plates on adjacent sides of the grooves for laying anodes on one edge are asymmetric en- respect to the other edge. 2. The plasma panel of the dial screen according to claim 1, characterized in that in the rear dielectric plates located around the perimeter of the panel, the grooves are made only on adjacent sides. 3. The plasma panel of the dial screen according to claim 1, characterized in that in the back plates with adjacent sides in the display elements located on the edges of adjacent sides, the extreme dielectric barrier of the matrix along one row of the display elements or along the length of the vertical display elements is not on one edge formed. 4. The plasma panel of the dial screen according to claim 1, characterized in that chamfers are made on the front dielectric plate along the edges of the ends from the inner surface. 5. The plasma panel of the dial screen according to claim 4, characterized in that chamfers are made on the front dielectric plate along the edges of the ends from the outer and inner surfaces of the side. 6. The plasma panel of the dial screen according to claim 1, characterized in that the width of the back of the black matrix is selected from the relation a = (1.1 ÷ 1.4) b, where a is the width of the strip of the black matrix, b is the width of the dielectric barrier of the matrix . 7. The plasma panel of the dial screen according to claim 1, characterized in that the width of the stripes on the front black matrix is equal to the width of the protrusions along the vertical of the screen and horizontally equal to the width of the dielectric barriers of the matrix, which determine the width of the display elements. 8. The plasma panel of the dial screen according to claim 1, characterized in that on each back dielectric plate there is a plug for pumping and filling gas. 9. The plasma panel of the dial screen according to claim 1, characterized in that the gas evacuation and gas filling plug is located on every second back dielectric plate or at the border of adjacent dielectric plates. 10. The plasma panel of the dial screen according to claim 1, characterized in that the width of the protrusions is determined from the relation b1 = (0.2 ÷ 1.0) b, where b is the width of the dielectric barrier of the display element, b1 is the width of the protrusion, and the gap length between the protrusions is determined from the relation L = (0.8 ÷ 1.2) b, where b is the width of the dielectric barrier of the display elements, L is the length of the gap. 11. The plasma panel of the dial screen according to claim 1, characterized in that the location of the beginning of the protrusions in the extreme display elements is aligned with the extreme dielectric barriers of the matrix, which determine the width of the display element. 12. The plasma panel of the dial screen according to claim 1, characterized in that the protrusions are made of transparent dielectric material. 13. The plasma panel of the dial screen according to claim 1, characterized in that the width and depth of the groove for laying the anode are selected according to the ratios 2.0d≤c≤0.3S and 1.5d≤e≤0.1b, where b is the width of the dielectric barrier display element, d — wire diameter, c — groove width, e — groove depth, S — display element width. 14. The plasma panel of the dial screen according to claim 1, characterized in that the displacement of the grooves at the ends of the adjacent rear dielectric plates is determined from the relation Lcm = (1.0 ÷ 2.5) d, where Lcm is the offset of the grooves, d is the diameter of the wire . 15. The plasma panel of the dial screen according to claim 1, characterized in that after sealing the panel on each rear dielectric plate, a printed circuit board is installed for wiring the leads of the anodes and cathodes for connection to a control circuit or to part of the elements of a control circuit. 16. The plasma panel of the dial screen according to claim 1, characterized in that on the back side the panel is made of m≥2 ... back dielectric plates adjacent vertically and contains one gas evacuation and filling pad located on one of the back dielectric plates or at the border of adjacent rear dielectric plates. 17. Plasma screen panel containing front and back dielectric plates connected along the perimeter by a sealing seam, a front black matrix with a phosphor is formed on the inner surface of the front dielectric plate, a gas evacuation and filling pad is located on the back dielectric plate, and display elements in each row of the panel formed by dielectric matrix barriers, protrusions are applied to the surface of the dielectric barrier of the matrix along the length of the display elements, The anodes and cathodes laid at intervals relative to the width of the dielectric barriers of the display elements are made of conductors in the form of a wire and are arranged orthogonally with each other, the anodes are vertical in the screen, and the cathodes are parallel to the lines, the conclusions of the anodes and cathodes are led out through the ends of the back plate, color the luminescence of each display element is determined by the phosphor, with m = 2 back dielectric plates adjacent vertically and n≥2 back dielectric horizontal plates on the surface On the back of the back plate, a back black matrix is formed, a phosphor is deposited between the dielectric strips, on the surface of which the wires of the anodes of each line display element are laid, the wires of the anodes are sealed on the surface of the dielectric strips of the back black matrix with the first layers of the dielectric barriers of the matrix, and in the middle of the back plate on the surface of the dielectric strip the back of the black matrix, the anode wires are sealed with two barriers with a gap between each other, in which the anode wires are cut and insulated s insulator wire cathodes sealed second layers of dielectric matrix barriers which bear projections having a height equal to the distance of run lengths of ionizing electrons at the selected pressure gas mixture. 18. The plasma panel of the dial screen, containing the front and back dielectric plates connected along the perimeter by a sealing seam, a front black matrix with a phosphor is formed on the inner surface of the front dielectric plate, and a gas evacuation and filling pad is located on the back dielectric plate, in each row of the panel there are elements mappings are formed by dielectric barriers of the matrix and protrusions are applied to the surface of the dielectric barriers of the matrix along the length of the display elements laid at intervals relative to the width of the dielectric barriers of the display elements, the anodes and cathodes in the display elements are made of conductors in the form of wires and are arranged orthogonally with each other, the anodes are vertical in the panel, and the cathodes are parallel to the lines, the conclusions of the anodes and cathodes are output through the ends of the back plate, color the luminescence of each display element is determined by the phosphor, while on the front dielectric plate between the dielectric stripes of the black matrix along the length of each element is displayed I have recesses formed on the surface of which a phosphor is applied. 19. The plasma panel of the dial screen according to claim 16, characterized in that on the front dielectric plate of the panel, for each color of the phosphor between the dielectric strips of the black matrix, vertical recesses are formed along the panel vertical with a length equal to the length of the anode. 20. The plasma panel of the dial screen containing the front and back dielectric plates connected along the perimeter by a sealing seam, a front black matrix with a phosphor is formed on the inner surface of the front dielectric plate, and on the back dielectric plate, display elements containing anode wires and perpendicular to the cathode wires, the thickness Tm of the front and back dielectric plates and the height h of the location of the cathode wires at the barriers Ritsa relative to the surface of the dielectric plate back are selected from 12≥Tpl / h≥2 ratio, the wire diameter of the anodes and cathodes (0,1 ÷ 0,25) mm.

Images