AT2754U1 - DISPLAY CELL OF THE MATRIX SCREEN - Google Patents

Abstract

A display cell of a matrix screen that contains a support frame for at least one display cell, a magnetic plate with two different colors rotatably mounted on the support frame by about 180o, two ferromagnetic rods mounted under the plate on the support frame, a solenoid and two supply lines for mastering the position of the Includes magnetic plate and an active radiator, the magnetic plate (2) being mounted on projections (4) which are arranged diagonally in the opposite corner parts of the support frame (3), whereas the ferromagnetic rods (7) in the openings in the bottom of the support frame ( 2) are mounted in the plane perpendicular to the axis of rotation (11) of the magnetic plate (2), in which at least one cavity (12) is formed, which is assigned to the position of the ferromagnetic rods (7), and in the case of a ferromagnetic rod (7) in the outer circumference of the magnetic plate (2) outside the supporting frame (3) the active one in the room via the magnetic plate (2) in both its functional positions oriented radiator (15) is mounted.

Description

AT 002 754 Ul

Technical field

The technical solution relates to the display cell of the matrix screen, which has a support frame for at least one display cell, a magnetic plate with two different colors rotatably mounted on the support frame by approximately 180 °, two ferromagnetic rods mounted under the plate on the support frame, a solenoid for actuating the Includes magnetic plate and an active radiator.

Current state of technology

Three types of matrix screen designs of the type under consideration are currently known. The first type of matrix screens uses active light sources, e.g. Incandescent lamp systems or light emitting diodes (LED), the advantages of which are fully exploited when the ambient lighting is low (twilight, darkness). With the increasing intensity, this advantage turns into a fundamental disadvantage, i.e. almost 100% illegibility in direct sunshine. This disadvantage can practically not be remedied.

The known conventional matrix screens of the second type are based on a passive display type, where the two-tone magnetic disk system of various shapes or other spatial structures, such as cylinders, spheres, cubes etc., are designed as rotors, which are rotated by the action of magnetic forces of the stator and subsequently in the first or the second or when carrying out the magnetic disks in other positions depending on the use, the visible side formed by an overall reflection surface of any color reflecting the incident ambient light back to the observer of such a screen. These screens are the cheapest screens when the ambient lighting is maximum. In low lighting or in the dark, subsequent total lighting by an independent active light source is necessary, which is not always possible. 2 AT 002 754 Ul

The disadvantage of the described matrix screens is eliminated to a considerable extent in the third type of matrix screens, where in a common cell both the active radiator (incandescent lamp, LED, fiber optic cable) and the rotatable magnetic plate reflecting the incident light are applied, which are used by the active ones Covering the spotlight in the first stable position thanks to an opening or a cutout, and so they act together on the observer and covers the active spotlight in the second stable position.

The previously known solutions of matrix screens of the third type still have some disadvantages. Above all, the optimal shape of the magnetic plate (circle, oval, regular polygon) is disturbed by the opening or cut-out for the active spotlight, which reduces the reflective surface of the magnetic plate. The disruption of the optimal shape of the magnetic disk deteriorates the legibility of selectively displayed structures (numbers, letters, pictograms) in cases where the light reflection from the reflection side of the magnetic disk is predominantly claimed. This is particularly noticeable with the intention of using active lamps with larger masses and thus improving readability in the dark or at dusk.

When using an intensively shining active radiator, the undesired visible underexposure of the magnetic plate in the second stable position of the concealed activated radiator is evident, which in the matrix area of such cells deteriorates the legibility of selectively displayed structures.

When using a light other than the light of the active radiator, e.g. B. when guiding the main axis of the active radiator, which is inclined approximately 90 ° from the plane of the magnetic plate, d. H. If the active radiator acts on the reflection surface of the magnetic plate, from which its light to the observer of the matrix screen of the third type is only subsequently reflected, a markedly lower energy yield becomes noticeable and the illumination of the magnetic plate is then insufficient and uneven.

Technological complications in the production of cells or a group of cells for the screens cannot be avoided with these matrix screens, because it is necessary to integrate the magnetic plate, its stator excitation and the active radiator into the individual cell. 3 AT 002 754 Ul

Essence of technical solution

The deficiencies cited largely eliminate the display cell of the matrix screen, which has a support frame for at least one display cell, a magnetic plate with two different colors rotatably mounted on the support frame by approximately 180 °, two ferromagnetic rods arranged under the plate on the support frame, and a solenoid for the mastery of the position of the magnetic plate and an active emitter includes, according to this technical solution, the essence of which is mainly based on the fact that the magnetic plate is mounted on the projections arranged diagonally in the opposite corner parts of the support frame, while the ferromagnetic rods in the bottom openings of the support frame are mounted in the plane perpendicular to the axis of rotation of the magnetic disk, in which at least one cavity is formed which is assigned to the position of the ferromagnetic rods, whereby on the support frame in the case of a ferromagnetic rod at the outer circumference of the magnetic disk outside of the support frame, the active reflector is mounted, which is oriented in the space above the magnetic disk in its two functional positions.

From a technological point of view, it is advantageous that the frame is provided with cavities for the arrangement of the active radiator from the outside in the locations corresponding to the cell corners.

With regard to different possibilities of colored selective display, it is advantageous if the active spotlight is multicolored and z. B. is formed by two single-color chips with three versions, one of which is common to the two chips.

In view of the simple arrangement, it is advantageous if the active radiator is arranged in the cavity by means of a post connected to a spacer.

In view of the possibilities of different colored, selective displays, it is advantageous if the active radiator is connected to the control unit separately from the solenoid.

So that an optimal facial sensation is achieved and the unwanted reflections are eliminated, it is advantageous if the active spotlight with a matting varnish with different effects of the light transition into and out of the active spotlight. With regard to the display option, it is advantageous if the active radiator and the solenoid for 4 AT 002 754 Ul

Control unit are connected, which is independent for each cell and when all control units are connected to a common processor unit.

Further advantages of the technical solution are evident from the description of exemplary embodiments. Overview of the pictures on the drawing

The technical solution is explained in more detail with the aid of a drawing, on which the Fig. 1 individual display cell of the matrix screen after the technical solution in axonometric view, Fig. 2 axonometric view on two display cells with magnetic plates with a cutout, Fig. 3 axonometric view on an alternative design of two display cells with magnetic plates with two cutouts, the Fig. 4 electrical circuit of the display cell and Figs. 5, 6 and 7 shows the top view of the design of display cells in the matrix screen.

Examples of the execution of the technical solution

The individual display cell 1 of the matrix screen, according to Fig. 1, includes the magnetic plate 2, which is provided in a known manner with a permanent magnet, not shown. The magnetic plate 2 is rotatably mounted on two projections 4 which are arranged diagonally in the opposite corner parts of the support frame 3 and which form its inseparable part. Both sides 5, 6. of the magnetic plate 2 are covered with a reflection or retroreflective sheeting or paint, the suitable contrasts of one side 5 compared to the other side 6 with selective display, for. B. with the combination of the colors yellow-red, white-black and the like. can be achieved. The magnetic disk 2 rotates like a rotor in the stator field of the ferromagnetic rods 7, the bistable magnetic field of which is changed as a function of the control pulses via the solenoid 8, which on the ferromagnetic rods 7 in a known manner from the bottom 5 AT 002 754 Ul des Support frame 3 is attached. The ferromagnetic rods 7 are connected to a bridge 9 and are mounted in the openings (not shown) in the bottom of the support frame 3 in the perpendicular to the axis of rotation of the magnetic plate 2, below their outer edge. The magnetic plate 2 is advantageously formed flat approximately in a round shape. However, it can also have an oval shape or the shape of a regular polygon. So that the rotation about 180 ° around the axis 11 is made possible, the magnetic plate 2 with a hollow 12th according to Fig. 2 when turning back or with two hollows 12th, in an alternative embodiment according to Fig. 3, with the possibility of Provide turning in a sense. The cavity 12 is formed in the edge of the magnetic plate 2 and is assigned to the position of ferromagnetic rods 7. The display cell 1. is mechanically and thus also electrically attached to the plate of the flat connection (not shown) with the aid of the first feed line 13 and the second feed line 14, which are mechanically fastened in the support frame 3 from the underside in a known manner not shown and which are known are not electrically connected with the solenoid 8. From the outside of the frame 3 in its corner part at one of the ferromagnetic rods 7, the active radiator 15 is mounted on the outer circumference of the magnetic plate 2, which is oriented in the space above the magnetic plate 2 in both its functional positions, i.e. before and after turning around 180 °. For this purpose, the cavities 10 are formed in the corner parts of the support frame 3 from which the active radiator 15 is mounted on a spacer 17 by means of a post 16. The storage of the active radiator 15, which is fixed in a self-locking manner with the aid of a post 16 on the spacer 17, in the cavity 10 is carried out when changing the assembly on the plate of the flat connection, not shown. The color of the post 16 and the spacer 17 corresponds to the support frame 3 and one side of the magnetic plate 2. The color of the base frame 3 depends on the color of the sides 5 and 6 of the magnetic plate 2 so that the required visual effect of the entire screen black and white color are considered typical. The active radiator .15 can e.g. B. form an incandescent lamp or an incandescent lamp which shines through the optical waveguide. Preferably, however, a multi-color LED, see Fig. 4, is considered, which consists of two single-color chips .18 and .19, and three versions 2J), 21, 22. and which enables several color combinations of the selective representations. Example with the matrix screen when rotating the magnetic disks 2. In the position in which the visible sides 5 e.g. 6 AT 002 754 Ul are covered with a yellow-green reflective film or color, the selective representation is formed by a single-color chip 18 of the active radiator 15, which, for. B. glows yellow-green or by the second monochrome chip 19th of the active radiator 15, which e.g. lights up red or through both single-color chips 18, 19 of the active radiator 15, where the color is created by mixing - e.g. orange, and also when turning the magnetic plates 2 in the position in which the visible sides 6. z. B. are covered with a red reflective film or color. The visual effect of the entire magnetic screen also depends on the basic color of the active radiator 15, which with regard to possible unwanted reflections with a special matting varnish 23 with different effects of the light transition into the active radiator 15 (incident light) or out of it active radiator 15 (emitting light) is covered and which in the switched-off position of the active radiator 15 tones the active radiator in the tone required for the entire screen, and in the switched-on position when the active radiator 15 emits the light does not restrict its passage .

The active radiator 15 and the solenoid 8 are connected to the control unit 24, which is connected to the processor unit 25. In the design of the active radiator 15, which is formed by two monochrome chips 18, 19 with three designs 20 .. 21, 22 according to FIG. 4, the control unit 24 controls with its first control input 26 via the first switch 27 the first feed line 13. of the solenoid 8. and with the second control input 2JJ it controls the second feed line 14 of the solenoid 8 via the second switch 23 and thus the reversal of the magnetic plate 2 either with its visible first side 5 or its second side £. The third control input 30 of the control unit 24 controls the first single-color chip 18 via the third switch 31 and the versions 2.0 and 21, while its fourth control input 32th controls the fourth switch 33 and the versions 22 and 21 control the second monochrome chip .19, and so the switching off of the active radiator 15. or switching on the active radiator 15 and in this position controls the color of the active radiator 15 with the help of the mutual ratio of the glow of the monochrome chips 18 and 19. The coupling of the third or fourth switch 31., .33. can also be done individually. Then only the single-color chip 18 or 1_9 lights up, whose switch 3_1 or 33th is coupled. The design 21 is for both single-color chips 18, 19. together. When using another type of active radiator, for example an incandescent lamp or single-color LED, only the versions 20 and 21 are switched on and the fourth switch 33 is not used. The 7 AT 002 754 Ul

Control unit 24 is formed as an integrated unit, which is independent for each display cell 1. The control units 24 of individual display cells 1 of the matrix screen are connected via the control inputs 26, 28, 30 and 32 to a common processor unit 25_.

The matrix screen for the display of information is formed by a large number of display cells 1, which are arranged in the area next to one another with an equally inclined axis of rotation .11 of the magnetic disks 2, as is evident from FIGS. 5, 6 and 7.

The support frame 3 is therefore common with a view to simplifying production and assembly for a plurality of display cells 1, generally 5 or 7, which are arranged next to one another in the row. In this case, see Fig. 2 or 3, the common partition is: 34. of the support frame 3, which separates the two adjacent display cells 1., is provided with two bearing projections 4 for the storage of magnetic disks 2. The cavities 10 for the active radiators 15 are also in the location of the partition wall. The end partition walls 35 of the support frame 3 are formed similarly to the support frame 3 for a display cell 1. The support frame 3 for one or more display cells 1 are shaped as it is apparent from Figs. 1, 2, 3 that they are arranged in the matrix screen as it is apparent from Figs. 5, 6, 7, and fit tightly active radiators 15 are tightly stored in the cavities 10 between four adjacent cells 1.

The matrix screen described works in three basic regimes.

In the first regime according to Fig. 5, the active emitters 15 are switched off after the execution with the help of the switches 3_1 or 33. and the display is only made by rotating the corresponding magnetic plates 2 by approximately 180 ° with the aid of the first and the second Switch 27. » 29th performed.

In the second mode according to Fig. 6, with the help of the first and the second switch 27th / 29th, all magnetic disks 2nd are rotated into an identical position, in which only side 5th or side 6 can be seen and the illustration with With the help of active radiators 15. Which are controlled with the aid of the third switch 31 and the fourth switch 33. The rotated side 5 or 6. forms the colored background of the active spotlights 15 ..

In the third regime according to Fig. 7, both the magnetic disks 2 and the active radiators 15 are active. In this regime, one of the visible pages corresponds to 5th or 6th, e.g. the side 5 of the magnetic plate 2, the switching on of the active radiator 15 and the side 6 of the magnetic plate 2, the switching off of the active radiator 15 corresponds to this state of the orientation of the magnetic plate 2 and the active radiator 15 is 8 AT 002 754 Ul the function of the display cell 1 so that by the passage of control pulses on the first control input 2.6 and on the second control input 28 with the help of the switches 2_7, 29, the magnetic plate 2 rotates about 180 ° into the position in which the first Side 5 of the magnetic disk 2 is visible, and subsequently the passage of control pulses in the third control input 30 with the help of the third switch 31 and the passage of control pulses in the fourth control input 32. With the help of the fourth switch 33, the active radiator 15 becomes active active, which is hereby switched on. In the reverse process, the active radiator 15 is first switched off with the aid of the third switch 31 and the fourth switch 33. The magnetic disk 2 is then switched off by the passage of control pulses on the first control input 26. And on the second control input 28 Switch 27, 29 rotated back into the position in which the second side 6 can be seen.

The use of independent control units 24 for each display cell .1, which are controlled by a common processor unit 25, enables the matrix screen to work simultaneously in different regimes. For example, one of its parts in the first regime, the other part in the second regime and the rest in the third regime. Static, movable or flickering structures can be formed according to the choice.

Industrial exploitability

The technical solution is for advertising panels, signaling, orientation panels and. Ä. determines where increased demands are made on the presentation options. 9

Claims (7)

AT 002 754 Ul CLAIMS 1. The display cell of the matrix screen, the support frame for at least one display cell, a magnetic plate rotatably mounted about 180 ° on the support frame with two different colors, two ferromagnetic rods mounted under the plate on the support frame, a solenoid and includes two leads for controlling the position of the magnetic plate and an active radiator, characterized in that the magnetic plate (2) is mounted on projections (4) which are arranged diagonally in the opposite corner parts of the support frame (3), while the ferromagnetic rods (7) are mounted in the openings of the base of the support frame (2) in the plane perpendicular to the axis of rotation (11) of the magnetic plate (2), in which at least one cavity (12) is formed which corresponds to the position of the ferromagnetic rods (7) is assigned, with a ferromagnetic rod (7) on the outer circumference of the magnetic plate (2) outside the supporting frame s (3) the active radiator (15) is mounted in the room via the magnetic plate (2) in both its functional positions. 2. The display cell according to claim 1, characterized in that the support frame (3) from the outside in the corner parts of the cell (1) corresponding locations with cavities (10) for the storage of the active radiator (15) is provided. 3. The display cell according to claim 1 or 2, characterized in that the radiator (15) is multi-colored and is formed with two single-color chips (18, 19) with three versions (20, 21, 22), one for both Chips (18, 19) is common. 4. The display cell according to claim 1 or 2 or 3, characterized in that the active radiator (15) is mounted in the cavity by means of a post (16) connected to the spacer (17). 10 AT 002 754 Ul 5. The display cell according to claim 1, characterized in that the active radiator (15) to the control unit (24) is connected separately from the solenoid (8). 6. The display cell according to claim 1 or 3 or 5, characterized in that the active radiator (15) with a matting lacquer (23) with different effects of the light transition into the active radiator (15) and out of the active radiator (15th ) is covered. 7. The display cell according to claim 5, characterized in that the active radiator (15) with the solenoid (8) is connected to the control unit (24), which is independent for each cell (1), and all control units (24) a common processor unit (25) are connected. 11