SK500322015A3 - Variable display for displaying traffic signs or advertisements - Google Patents

Abstract

The display device comprises a worm gear (6) coupled to a respective one prism (3) of the variable display device (1), provided with one sensor for sensing the position of all prisms (3). Each worm gear (6) includes a screw cage (28) which is provided with sliding sleeves (27) for rotating the screw (12) and defining the position of the screw (12) in the gearbox (6) against the worm wheel (12) and on the one hand, a spacer (29) which locks the axial play of the screw (12) in the cage (28). An electric motor (16) allowing the side surfaces of the prisms (3) to rotate in the order of seconds is electrically connected to the power control unit (4) to process input messages or voltage signals from the control center to control the position of all prisms (3) of the display device ( 1).

Description

Variable display device for displaying traffic signs or advertisements

Technical field

The invention relates to a variable display device for displaying traffic signs or advertisements. The variable display device for displaying traffic signs or advertisements comprises a support box, in the front wall of which prisms with externally visible lateral prism surfaces, preferably with three lateral prismatic surfaces, are arranged in a reversibly rotatable arrangement, preferably with three lateral prismatic surfaces representing the variable active display surface. The support box is equipped with a control unit and a power supply system. Each prism has one end portion of it connected to an associated helical gearbox. All worm gearboxes are mounted with their worms on one common reversible drive shaft. The prism position sensor is electrically connected via a control unit to one electric motor to control the variable display device.

Prior art

EP 1 596 352 B1 to Dambach-Werke GmbH, DE describes a variable display device for traffic signs with a plurality of prisms arranged relative to one another, which rotates by means of a single motor and a drive shaft, so as to make it possible to display a larger number of traffic signs. a reset device which, in the event of a power failure, returns the prisms to a predetermined position by means of a mechanical energy storage device, by connecting the drive shaft, the sprocket and the roller chain, which is connected to the lever means. The prisms usually have three surfaces. The drive shaft and the screws transmit the movement to the prism shaft by means of a helical gear.

The advantage of the device is the reset device, which in the event of a power failure restores the return of the prisms to a predetermined position.

The disadvantage of this solution is that in the event of a power failure, the prisms return to a predetermined one position, so that it may happen that an undesired traffic sign or symbol is set in the event of a power failure.

U.S. Pat. No. 5,694,494 describes a rotating unit and a lighting unit for a 3-sided variable advertising display board. It has a frame formed by a bottom groove and two side hollow tubes and fixed to the support legs by welding. The light tubes are fixed inside the triangular hollow columns with rubber washers screwed onto the upper member. The crosshead shaft has a cross-section fitting at one end through a transverse hole for the gear wheel and at the other end into the helical gear screws. The crosshead shaft passing through the helical wheel screws located inside the lower support member and connected to a rectangular axis at the top of the lower support member is connected to a gear wheel driven by a motor-driven drive wheel, causing the shaft crosshead to move, leading to rotation of triangular hollow columns. The infrared sensor is used to signal the light stop of the movement of the triangular hollow columns, the timer and the rectifier are used to preselect and control the regular movement of the triangular hollow columns. Thus, ads displayed on the three faces of the triangular columns may be displayed as they rotate as a result of the regular movement of the triangular hollow columns.

U.S. Pat. No. 5,694,494 thus discloses an advertising variable device with triangular light prisms, the rotation of which is effected by a crosshead of the shaft, as described above.

Each triangular hollow column has one end portion connected to an associated helical gearbox. All worm gearboxes are mounted with their worms on one common drive shaft. The prism position sensor is electrically connected via a control unit with one electric motor to control the variable display device.

An advantage of the present invention is the possibility of placing the light source inside triangular translucent prisms. The rotating and lighting unit is designed for the interior. The disadvantage is that an infrared sensor or a limit switch is used. The disadvantage of the infrared sensor or the limit switch is that they detect the position of the prism only for information, i. that the prisms are rotated to the display position, but does not indicate which of the three possible sides of the triangular prism is in this position. Another disadvantage is that the prisms move only at regular intervals, and not according to the signals from the superior control system, i.e. according to the immediate need. Furthermore, the infrared sensor is not suitable for outdoor use, e.g. for traffic signs. The design solution does not deal with adjusting or locking the axial play of the screw or defining the screw in the helical gearbox relative to the helical wheel.

EP 978 815 A2 relates to a billboard with longitudinal elements. The billboard consists of a support frame and a plurality of individual longitudinal elements rotatably mounted, in particular suspended, about vertical parallel axes, which are controllable by at least one electric motor arranged on the support frame, so that the individual elements form an image containing the advertisement in at least one alignment. Each individual longitudinal element at at least one of its ends is provided with a permanent magnet. At least one sensor is arranged on the support frame in the range of movement of the permanent magnet, which captures the magnetic field of the permanent magnet and outputs a signal to the control device of the electric motor (s). The advertising board, preferably a billboard, is formed of several vertically suspended longitudinal elements - panels on a common drive shaft, which is connected by means of a helical transmission to an electric motor. The tops of one panel are provided with permanent magnets, which are detected by a sensor. Rotation of vertically suspended panels is performed by a sensor connected to permanent magnets. The elongate panels may be e.g. hollow bodies, cylinders, prismatic bodies, emptied bottles or emptied beverage cans.

The advantage of the solution is structural simplicity. The advantage is also the hanging of different types of panels that can be used for advertising or promotional purposes.

The disadvantage is that this type of billboard is intended for interior and not for exterior traffic signs. An electromagnetic sensor is used as a sensor, which senses the magnetic field of permanent magnets located on one of the panels. This type of sensor is able to detect the position of the panel only if the permanent magnet is in close proximity to the electromagnetic sensor and is unable to provide information on which of the possible exact positions the panel is in.

Both of the above solutions are intended and applicable only for advertising, preferably with regular rotation of advertising, but not for large ones for traffic signs, which must meet high requirements based on the given standards. Although both solutions are structurally undemanding, they can be expected to have lower reliability of rotating elements in a demanding exterior environment.

The essence of the invention

These disadvantages are eliminated or substantially reduced by a variable display device comprising a support box in which a prism with parallel externally visible lateral, preferably three, prismatic surfaces, representing a variable active display surface, are reciprocally rotatably mounted parallel to each other, each prism having a prism. one end portion thereof connected to an associated helical gearbox, which are mounted by their helices on one reversibly rotatable drive shaft, and the prism position sensor is electrically connected via a control unit with one electric motor to control the variable display device. The essence of the present invention is that only one helical gearbox, coupled to the respective one prism of the variable display device, is provided with one sensor for sensing the position of all prisms, each helical gearbox comprising a screw cage which is provided with sliding sleeves for rotating the screw and defines the position of the screw in the gearbox relative to the screw wheel and on the one hand by the spacer which locks the axial play of the screw in the cage. Further, an electric motor allowing the side surfaces of the prisms to be rotated in the order of seconds is electrically connected to a power supply control unit for processing input messages or voltage signals from the control center to control the position of all prisms of the display device.

The main advantage of the present invention is the overall construction of the variable display device, usable for the needs of large boards with variable information for traffic signs. The construction is undemanding to production, service and maintenance while ensuring safe operation, while its individual components are affordable and inexpensive. The rotation of all prisms in the order of seconds is controlled by one electric motor and one common drive shaft. On one helical gearbox coupled to only one prism, an absolute sensor is located to sense the position of all prisms continuously. A common electric motor is controlled via the control unit by means of an absolute sensor. A special screw construction has been developed, intended only for the purposes of the present invention, which allows the axial play of the screw to be adjusted and the position of the screw to be defined. The control unit allows the processing of input messages and signals from the control center and in a matter of seconds to rotate the prisms by means of an electric motor to the desired variable position to display the desired current information.

It is advantageous if the sensor for sensing the position of all prisms is an absolute sensor. In the event of a power failure after restarting the device, the absolute sensor informs the control unit of the position of the prisms, without the need to rotate the prisms.

For trouble-free and tested mounting of the prisms, it is advantageous if each prism is mounted at its ends in housings, one housing of which is firmly connected to the support housing, and one housing of each prism is connected to one associated helical gearbox.

One of the housings may be provided with a spring to secure the prism in the axial direction. The opposite housing is mounted via a bearing on a pin, which is part of the support box, which ensures a simple and reliable fixing of the prism in the entire device.

The optimal location of the absolute sensor for sensing the position of the prisms is on the helical gearbox of the electric motor.

A preferred embodiment is a helical gearbox, comprising a helical gear and a helical gear, which are connected via a spur gear to a drive shaft via an drive spur gear to an electric motor.

It is advantageous if the electric motor has a DC supply due to the fact that the distributions of the device can be low-current. Then it is easier to back up the power supply and the possibility of using power from solar cells.

For easy coupling of the absolute sensor for sensing the position of the prisms, its connection to the helical gearbox is a screw coupling via a fastening mandrel.

In addition, it is advantageous if the electric motor is attached to a holder to which a fork is also attached, and a drive shaft drive wheel is mounted on the fork on the sliding bushes, and the driven wheel is connected to the drive wheel of the electric motor.

In order to perform the movement of the prism coupled to the absolute encoder, it is advantageous if the mounting mandrel for connecting the absolute encoder to the helical gearbox is located on a clamping coupling which is slid onto a shaft shaft mounted in bearings located in the base of the helical gearbox.

Axial displacement of the drive shaft is effectively prevented by at least one caliper threaded on the drive shaft.

When the locking ring is placed on the driven shaft, it is possible to easily remove and reattach the prism in case of replacement or repair of the prism. The compression spring threaded on the locking ring secures its position in the securing position.

A preferred construction is the connection of the coupling to the helical wheel by means of a resilient pin, and then the helical wheel forms a helical gear with a helical wheel, which is housed in sliding bushes and placed in the cage of the helical wheel.

To adjust the play of the screw housed in the sliding bushes pressed into the screw cage, it is advantageous if the screw cage is provided with a spacer.

The screw cage can be provided with guide pins which ensure the coaxiality of the screw with the drive shaft. The screw cage can also be provided with an adjusting screw for adjusting the axial distance of the screw and the screw wheel.

The variable display device can be provided with a backup power supply to ensure its uninterrupted function in the event of a power failure.

Overview of figures in the drawings

The solution is further described in detail in exemplary embodiments and is further elucidated in the accompanying schematic drawings, of which FIG. 1 is an axonometric view of the housing of a variable display device with an active surface formed by prisms, FIG. 2 is an axonometric view of FIG. 1 to the rear of the cabinet, FIG. 3 is a front view of the housing of FIG. 1, FIG. 4 section A-A from FIG. 3, FIG. 5 detail B from FIG. 4, FIG. 6 detail C from FIG. 4, FIG. 7 is an axonometric view of the drive device of the display device, FIG. 8 is an axonometric detailed view of FIG. 7 to a helical gearbox with a mounting mandrel for connecting an absolute sensor, FIG. 9 is a side view of the helical gearbox of FIG. 8 from direction D, FIG. 10 is an axonometric detailed view of FIG. 7 for a helical gearbox without a mounting mandrel for connecting an absolute sensor, FIG. 11 is an axonometric detailed view of the electric motor of FIG. 7, FIG. 12 is a side view of the electric motor of FIG. 11 from direction E, FIG. 13 is a front view of a prism with housings, FIG. 14 is an axonometric view of the prism with the upper housing, FIG. 15 is an axonometric view of a prism with a separate upper housing, FIG. 16 is an axonometric view of a prism with a lower housing and a bearing, and FIG. 17 is an axonometric view of a prism with an exploded lower housing and bearing.

Examples of embodiments of the invention

The variable display device 1 for displaying traffic signs or advertisements is shown schematically in an axonometric view in FIG. 1 in a front view and in FIG. 2 in rear view. The variable display device 1 has a support housing 2, made in an exemplary embodiment of aluminum alloy sheets, or of stainless steel sheet or aluminum profiles. In the support box 2, prisms 3 are arranged on the front side, arranged vertically in parallel one behind the other, and represent an active variable display area of a traffic sign or advertisement. The prisms 3 are made of drawn aluminum profiles. In an exemplary embodiment, each prism 3 is made of one aluminum profile of triangular cross-section. Each prism 3 is a triangular prism on the outside and a variable display surface or motif is placed on its outer prism surfaces. On the rear wall of the exemplary display device 1 there are two cabinets, in one of which the control unit 4 with the power supply of the prism drive 3 is stored, and in the other box the backup 4a of the power supply is stored.

The display device 1 in the front view in FIG. 3 has, in a specific exemplary embodiment, 11 prisms 3, with a length of e.g. 1500 mm. The number of prisms 3 and their length depend on the needs and purpose of the display device 1 and the customer's requirements. Each prism 3 has an upper part connected to one associated helical gearbox 6, as shown in FIG. 7. The helical gearbox 6 has its own special construction, intended only for the purposes of the present invention. In FIG. 3 shows a vertical section A through the sixth prism 3 of the display device 1. The section A through the display device 1 is shown in FIG. 4. The upper part B of this section A is shown in detail in FIG. 5 and the lower part C in FIG. 6. In the exemplary embodiment of the display device 1 shown in FIG. 3, 4, 5 and 6, i.e. only one prism 3, namely the sixth prism 3 is connected to a sensor 8 for sensing the position of the prisms 3. The prism 3 is connected via an upper housing 5 to a helical gearbox 6. The helical gearbox 6, to which connected to the sixth prism 3, is connected by a screw coupling 7 to a position sensor via a mounting mandrel 11 for connecting this sensor to a helical gearbox 6. In this embodiment, an absolute sensor 8, e.g. manufacturer Megatron Electronic GmbH Co.KG, DE. The absolute sensor 8 has a high reliability and a long service life. The absolute sensor 8 for sensing the position of the prisms 3 is housed in a protective cover 9.

In FIG. 7 shows an axonometric view of the drive of the display device 1. Each prism 3 is connected to its helical gearbox 6 via its upper housing 5. A helical gear 12 is part of the helical gearbox 6. A common drive shaft 13 passes through all the screws 12. The common drive shaft 13 passes through a driven spur gear 14 connected to the driving spur gear 15 of the electric motor 16.

In the exemplary embodiment, the drive shaft 13 is provided with a single caliper 17, preventing its axial displacement. The drive shaft 13 can be provided with several calipers 17 as required.

In FIG. 7, in an exemplary embodiment, a sixth prism 3 is shown connected to an absolute sensor 8 for sensing its position. In an exemplary embodiment, one absolute sensor 8 is coupled to one electric motor 16 via a control unit 4.

If higher power of the drive device of the display device 1 is required, several electric motors 16 can be used, each electric motor 16 being coupled to one associated absolute sensor 8. In this case, of course, the drive device is divided into individual units, each unit comprising its own a drive shaft 13 with respective drive and driven wheels 14, 15 and an electric motor 16 coupled to its own associated absolute sensor 8. The mounting of the prism drive 3 of the display device 1 may have a different arrangement. In the case of a vertical arrangement of prisms 3, the drive device of the prisms 3 can also be mounted on the contrary, in the lower part of the support housing 2. In the case of horizontally arranged prisms 3, the drive device can be mounted in the side of the support housing 2.

In FIG. 8 is an axonometric detail view of FIG. 7 to a helical gearbox 6 with a mounting mandrel 11 for connecting an absolute sensor 8. The mounting mandrel 11 for connecting an absolute sensor 8 is located on the upper side of a helical coupling 18 which is connected to a driven shaft 19 of a helical gearbox 6. The driven shaft 19 is mounted in pairs. bearings 20, 21, upper bearing 20 and lower bearing 21. The bearings 20, 21 are located in the base 22 of the helical gearbox 6.

A locking ring 23 is arranged in the lower part of the driven shaft 19 for securing the upper housing 5 of the prism 3 on the driven shaft 19 of the helical gearbox 6. A compression spring 24 is threaded on the locking ring 23 to secure the locking ring 23 in the securing position on the driven shaft 19. Compression spring 24 rests in the upper part on the base 22 of the helical gearbox 6. The screw 12 is provided with a square hole for the drive shaft 13.

The helical gearbox 6 with the mounting mandrel 11 for connecting the absolute sensor 8 is in view D in FIG. 8 shown in FIG. 9. In this illustration, the arrangement of the clutch 18 is better visible. A clamping clutch 18 is slid onto the upper part of the driven shaft 19 shown in dashed lines, on which a helical wheel 25 is mounted. The helical wheel 25 is connected to the clamping clutch 18 by a spring pin 26. The helical wheel 25 forms a gear with a screw 12 housed in sliding bushes 27. The screw 12 is placed in the cage 28 of the screw 12 by means of sliding bushes 27. The cage 28 of the screw 12 is provided with a spacer 29 for adjusting the axial play of the screw 12 in the cage 28. The cage 28 of the screw 12 is placed on the support plate 30. The cage 28 is provided with two guide pins 31 and an adjusting screw 32. The cage 28 is firmly connected to the support plate 30 by a screw connection 33.

In FIG. 10 shows a helical gearbox 6 which is completely identical in construction to the helical gearbox 6 shown in the previous figures 8, 9, with the difference that the clamping coupling 18 does not comprise a mounting mandrel 11 for connecting an absolute sensor 8. Thus, this type of helical gearbox 6 is used for all prisms 3 which are not coupled to the absolute sensor 8, as shown e.g. in FIG. 7.

The electric motor 16 of FIG. 7 is shown in detail in FIG. 11 in an axonometric view. FIG. 12 shows a side view from the direction E of the electric motor 16 of FIG. 11. The electric motor 16 is attached to the holder 34. A fork 35 is attached to the holder 34. The holder 34 and the fork 35 may be integrally connected or formed in one piece. On the fork 35, a sprocket 14 of the driven drive shaft 13 is mounted on the sliding bushes 27. The driven sprocket 14 is connected to the drive wheel 15 of the electric motor 16.

Each prism 3 is housed in a support structure 2 by means of an upper housing 5 and a lower housing 10. Views of any prism 3 with an upper housing 5 and a lower housing 10 are schematically shown in FIG. 13. Axonometric views of the prism 3 with the upper housing 5 are shown in FIG. 14, 15, and the prism 3 with the lower housing 10 in FIG. 16, 17. Figures 14 to 17 show a cross section of a prism 3 in the shape of an equilateral triangle.

In FIG. 14 shows the upper part of the prism 3 with the pressed-in upper housing 5.

In more detail, in FIG. 15 shows the upper part of the prism 3 with the upper housing 5 in an exploded state. The upper housing 5 is provided with a spring 36 for securing the prism 3 in the axial direction.

In FIG. 16 shows the lower part of the prism 3 with the pressed-in lower housing 10.

In more detail, in FIG. 17 shows the lower part of the prism 3 with the lower housing 10 in an exploded state. The lower housing 10 is provided with a bearing 37 and a pin 38. The lower housing 10 of the prism 3 is mounted via a bearing 37 on a pin 38 which is part of the support housing 2.

Display device 1 works as follows:

The variable display device 1 (Figs. 1, 2, 3) with reversibly rotating prisms 3 according to the invention is, for example, a traffic sign which is used for traffic control. The traffic sign allows you to react to current changes in traffic, passability and weather. By means of the display device 1 it is possible, e.g. stop traffic in front of road tunnels and divert it to an alternative route. On each of the side walls of the triangular prisms 3 of the variable display device 1, one of the three possible required traffic information or traffic signs, e.g. change of required speed, change of maximum allowed speed, no entry, change of direction of travel, etc.

The control unit 4 (Figs. 2, 4) of the display device 1 processes input messages or voltage signals from a remote control center (not shown). If necessary, the control unit 4 confirms the reconfiguration of the display device 1 with a message sent to the remote control center. At the same time, the control unit 4 senses the position of the prisms 3 by means of an absolute sensor 8 with an analog or digital output signal. The absolute sensor 8 is resistant to air humidity and water, and in addition can be protected by a cover 9 (Figs. 4, 5, 7). The absolute sensor 8 converts the angular movement of the prism 3 to a voltage output or to a data output, these outputs being fed to a control unit 4. The control unit 4 changes the information displayed by the prisms 3 on the variable active display surface of the display device 1 by an electric motor 16. it does not have to be powered only from the mains, but can be powered from the solar panel by batteries or backed up by batteries.

The holder 34 secures the electric motor to the support housing 2. The fork 35 attached to the holder 34 secures the position of the driven spur gear 14 relative to the drive shaft 13.

When using a DC electric motor, it is not necessary to use any other operating means, such as e.g. transformer or transducer. In this case, the input voltage is used, e.g. 12 V. It is used e.g. DC electric motor 6, with respect to the power supply, with a power of 50 - 300 W depending on the size of the prismatic field.

The electric motor 6 used has a speed which allows the side surfaces of the prisms 3 to rotate within 3 seconds. If the speed is too high, there is a risk of excessive stress on the carrier housing 2 and the mechanical transmission elements. At low speeds, the rotation of the side surfaces of the prisms 3 would not meet the requirement to rotate the side walls of the prisms 3 in the order of seconds. It is possible to use other types of electric motors 16 with a different input voltage, e.g. 24 V, using voltage adjustment means.

The rotation of the prisms 3 to the desired state is performed by means of an electric motor 16, which transmits the torque via the spur gears 14, 15 to the helical gearboxes 6 via the drive shaft 13 of square cross-section (Figs. 7, 8, 10, 11). Thus, the torque of the electric motor 16 is transmitted to the driven spur gear 14 and the driving spur gear 15 of the spur gear to the drive shaft 13; in this case, the screw 12 of the worm gearbox 6 transmits the torque from the drive shaft 13 to the worm wheel 25.

Helical gearboxes 6, one of which is connected to an absolute sensor 8 for sensing the position of all prisms 3, rotate the prisms 3 to one of three possible positions by 120 ° (Figs. 7, 14-17). The safe and suitable location of the absolute sensor is ensured by a mounting mandrel 11 on the upper side of the clamping coupling 18, connected to the driven shaft 19 of the helical gearbox 6 (Figs. 8, 9).

The clamping coupling 18 provides a mechanical connection between the driven shaft 19 and the helical wheel 25. The helix 12, forming a gear with the helical wheel 25, rotates in sliding bushes 27. The helix 12 is placed in a cage 28 by sliding bushes 27, which determines the position of the helix 12 relative to The cage 28 of the screw 12 is provided with a spacer 29 which locks the axial play of the screw 12 in the cage 28. The cage 28 is provided with two guide pins 31 ensuring the perpendicularity of the screw axis 12 to the plane of the prism 3 and an adjusting screw 32 securing the axial distance of the screw. 12 and the helical wheel 25. The cage 28 is firmly connected to the support plate 30 by a screw connection 33, thus forming a solid unit.

The driven shaft 19 is mounted in a pair of bearings 20, 21, an upper bearing 20 and a lower bearing 21 of the base 22 of the helical gearbox 6.

The locking ring 23 in the lower part of the driven shaft 19 secures the upper housing 5 of the prism 3 on the driven shaft 19 of the helical gearbox 6 in order to fall out. The compression spring 24, threaded on the locking ring 23 and resting on the upper part, rests on the base 22 of the helical gearbox 6, securing the locking ring 23 on the driven shaft 19 prevents its displacement and thus the release of the prism 3 from the driven shaft 19. Screw 12 is provided with a square hole for a square drive shaft 13, which is easy to manufacture.

The prisms 3 forming the active display surface are mounted together at one end on the pin 38 via the bearing 37 of the lower housing 10 into the support housing 2, thereby fixing them in the support housing 2. The opposite ends are mounted in the driven shaft 19 via the upper housing 5. of the helical gearbox 6, where they are secured by a locking ring 23 against falling out of the driven shaft 19. The compression spring 24, threaded on the locking ring 23, secures the locking ring 23 against unintentional release from the securing position on the driven shaft 19 (Fig. 8-10, 13- 17).

Each vertically oriented triangular prism 3 is accommodated by means of an upper housing 5 and a lower housing 10 in a support structure 2 allowing the prism 3 to rotate. The upper housing 5 with spring 36 secures the prism 3 in the axial direction and in addition rotates the prism 3. provided with a bearing 37, enabling the prism 3 to be rotatably mounted in the support housing 2 by means of a pin 38.

Industrial applicability

The present invention is particularly useful for traffic signs, advertisements, and wherever large variable information boards are used.

Claims (15)

PATENT CLAIMS Variable display device for displaying traffic signs or advertisements, comprising a support box (2) in which a prism (3) with externally visible lateral prismatic surfaces, preferably with three lateral prismatic surfaces, arranged in a reciprocally rotatable manner, is rotatably mounted in parallel. the variable active display area and the support box (2) is provided with a control unit (4) and a power supply system, each prism (3) having one end portion connected to the associated helical gearbox (6), all helical gearboxes (6) being mounted by their screws (12) on a common reciprocating drive shaft (13), and the prism sensor (3) is electrically connected via a control unit (4) to one electric motor (16) for controlling the variable display device (1), characterized by in that only one helical gearbox (6), coupled to the corresponding one prism (3) of the variable display device (1), is careful provided by one sensor for sensing the position of all prisms (3), each helical gearbox (6) comprises a cage (28) of the screw (12), which is provided on the one hand with sliding bushes (27) for rotating the screw (12) and defines the position of the screw (12) in the gearbox (6) relative to the worm wheel (12) and on the one hand by the spacer (29) which locks the axial play of the screw (12) in the cage (28), the electric motor (16) allowing the side surfaces of the prisms (3) to rotate in the order of seconds is electrically connected to the control unit (4) with power supply for processing input messages or voltage signals from the control center for controlling the position of all prisms (3) of the display device (1). Variable display device according to Claim 1, characterized in that the sensor for sensing the position of all prisms (3) is an absolute sensor (8). Variable display device according to claim 1, characterized in that each prism (3) is housed at its ends in housings (5, 10), one of which housing (5, 10) is fixedly connected to the support housing (2). , and one housing (5,10) of each prism (3) is connected to one associated helical gearbox (6). Variable display device according to claim 3, characterized in that one of the housings (5, 10) is provided with a spring (36) for securing the prism (3) in the axial direction, and the opposite housing (5, 10) is via a bearing ( 37) mounted on a pin (38) which is part of the support box (2). Variable display device according to Claim 1, characterized in that a sensor for sensing the position of the prisms (3) with an analog or digital output is arranged on the helical gearbox (6). Variable display device according to Claim 1, characterized in that the sensor for sensing the position of the prisms (3) is connected to the helical gearbox (6) by a screw coupling (7) via a fastening mandrel (11). Variable display device according to claim 1, characterized in that the helical gearboxes (6), comprising the helix (12) and the helical wheel (25) are connected via a driven spur gear (14) of the drive shaft (13) via driven spur gears wheel (15) with electric motor (16). The variable display device according to claim 1, characterized in that the electric motor (16) is a DC motor. Variable display device according to claim 1, characterized in that the electric motor (16) is attached to a holder (34), to which a fork (35) is also attached, to the fork (35) it is mounted on sliding bushes (27) the driven wheel (14) of the drive shaft (13) and the driven wheel (14) are connected to the drive wheel (15) of the electric motor (16). Variable display device according to Claim 6, characterized in that the mounting mandrel (11) for connecting the absolute sensor (8) to the helical gear unit (6) is arranged on a clamping coupling (18) which is mounted on the driven shaft (19). , housed in bearings (20, 21) which are located in the base (22) of the helical gearbox (6). The variable display device according to claim 1, characterized in that the common drive shaft (13) is provided with at least one caliper (17) preventing its axial displacement. Variable display device according to Claim 1, characterized in that the driven shaft (19) is provided with a locking ring (23) on which a compression spring (24) is threaded. Variable display device according to claim 10, characterized in that the clamping coupling (18) is connected by a resilient pin (26) to the helical wheel (25), and the helical wheel (25) forms a helical gear with a helical wheel (12). Variable display device according to Claim 13, characterized in that the cage (28) of the screw (12) is provided with guide pins (31) and an adjusting screw (32). Variable display device according to claim 1, characterized in that the variable display device (1) is provided with a backup power supply (4a).