RU83649U1 - DISPLAY MODULE FOR CONFIGURABLE TRANSPARENT COMBINED VIDEO DISPLAY WITH LARGE SCREEN - Google Patents

Abstract

1. Display module for a transparent video display with a large screen, containing elementary panels with light-emitting elements and through windows, a data distribution circuit and inputs for data and power, characterized in that it is equipped with a control unit installed on the display module without impairing the transparency of the latter, and said data distribution scheme is installed inside said control unit. ! 2. A display module according to claim 1, provided with receiving connection parts for said data and power inputs located in a central region of said elementary panels. ! 3. The display module of claim 2, wherein said data and power inputs are provided with multicore cables soldered directly to said receiving connection portions on the elementary panels. ! 4. The display module of claim 2, wherein said data and power inputs are provided with multicore cables connected to said receiving connection portions by means of quick disconnect connectors on elementary panels. ! 5. The display module of claim 1, wherein the topology of interconnecting the light emitting elements forms a boustrophedon. ! 6. The display module of claim 1, wherein each elementary panel is a monolithic printed circuit board. ! 7. The display module of claim 6, wherein the light emitting elements are located on one side of the printed circuit board and the drivers are located on the opposite side. ! 8. The display module of claim 6, wherein the elementary panel is provided with a protective coating applied to the surface of the printed circuit board. ! 9. Display module according to claim 1, comprising four elementary panels and a

Description

The proposed utility model relates to image display, and / or visual presentation of information, in particular, to a display module for a configurable large-screen transparent assembled display. The proposed display module can find application as an element of stage decoration or decoration of an architectural structure.

Large-screen prefabricated video displays are widely used to display images and information at stadiums, sports grounds, in advertising, to decorate various events and shows. On such prefabricated video displays for entertainment or advertising purposes, static and animated images, texts, as well as video films are displayed for large audiences.

An example of such a large-screen precast video display is described in US Pat. No. 6,690,341. The aforementioned patent discloses a dot-raster display device comprising a plurality of linear elements intersecting each other with an interval exceeding the width of each of said linear elements, a plurality of light-emitting elements located at the intersection points of the linear elements, wherein each of said light-emitting elements is shaped without deteriorating the transparency of the structure formed by intersecting linear elements, while each of the light-emitting elements is located them that its optical axis is oriented substantially perpendicular to the surface of the structure formed by the intersecting line elements,

as well as controls for light-emitting elements, wherein said controls are distributed over linear elements.

The module of such a large screen video display comprises a panel with eight linear elements forming a lattice structure. Each panel has 16 electrical and mechanical connections, and a prefabricated video display requires a large number of electrical and mechanical connections for its operation. Therefore, changing the installation parameters of such a prefabricated video display in relation to real conditions is not an easy task. A huge number of electrical and mechanical connections reduces the reliability of such a prefabricated video display, which is subjected to multiple installation and dismantling. The use of such a prefabricated video display, for example, as parts of stage equipment, when the installation conditions are different each time, is fraught with great difficulties. It takes a lot of time to install it, which makes it inapplicable for events with an unstable venue.

Another disadvantage of the known display modules is their limited permeability to air and light. The use of linear elements combined in longitudinal and transverse sets reduces the transparency and wind resistance of these display modules.

The purpose of the proposed utility model is to create a display module with increased transparency, wind and sound permeability.

The proposed display module is made of several, preferably four, elementary panels. Each elementary panel is created on the basis of a monolithic printed circuit board.

The one-piece PCB sheet is made of fiberglass or other suitable material. The window has through windows.

The circuit board is provided with a protective coating deposited on the side on which the light-emitting elements are located.

Said light-emitting elements are located on one side of the printed circuit board, and the control devices (drivers) of these light-emitting elements are located on its opposite side. Each elementary panel is mounted on a support frame with sufficiently narrow lamellas so that the transparency of the elementary panel does not deteriorate.

The mechanical strength of this design allows you to cut windows in the form of elongated, in the vertical or horizontal direction, rectangles. At the same time, an increase in transparency, wind and sound permeability is provided in comparison with the known display modules. In a preferred embodiment of the idea of the proposed utility model, an increase in transparency, wind and sound permeability of 25-30% is provided.

Another purpose of the proposed utility model is the creation of a display module that provides increased reliability of a transparent prefabricated video display with a large screen, composed of such display modules.

Each display module is equipped with a local control unit containing a data distribution circuit. Unlike the known display modules, in the proposed display module, a control unit containing a data distribution circuit is installed directly in the display module without compromising the transparency of the latter. For this, the control unit is made no wider than the lamella of the support frame. During assembly and disassembly

prefabricated video display with a large screen, there is no need to connect and disconnect numerous electrical contacts, as is the case in the prior art. This improves the reliability of the large screen prefabricated video display.

Another purpose of the proposed utility model is the creation of a display module that provides ease of implementation of multiple assembly and disassembly cycles of a transparent assembled video display, composable from such easily replaceable display modules.

The local control unit is connected to each elementary panel via a cable that is soldered directly to the printed circuit board, preferably to its central region, so that all elementary panels in the assembled video display as a whole are fully replaceable. The design of the display modules with support frames, soldered cables (without pin electrical contacts) makes it easy to assemble a large-screen prefabricated video display and its high performance: in case of problems with any elementary panel in a prefabricated video display, it can be quickly replaced with a spare one without disassembling the entire design of the prefabricated video display.

Thus, when assembling a video display with a large screen, it is easy and convenient to install the proposed display module and support it as part of the entire design, as well as dismantling, which is a special advantage in cases where you often need to change the venue of the event, which is associated with multiple cycles assembly / disassembly of a large screen prefabricated video display.

Other features and advantages of the proposed utility model will become apparent to the average person from the following detailed description with reference to the accompanying drawings.

For a better understanding of the essence of the proposed utility model, its further detailed description will be based on an example of a preferred embodiment of its idea. This example serves purely illustrative purposes, and in no way limits the scope of the proposed utility model. A detailed description of the proposed utility model is carried out with reference to the accompanying drawings.

On figa the proposed display module is shown in a perspective view from the front side.

On fig.1b the proposed display module is shown in a perspective view from the back.

Figure 2 shows a functional diagram of the proposed display module.

On figa shown in perspective view from the lower left side of the control unit of the proposed display module.

On fig.3b the control unit of the proposed display module is shown in a perspective view from the lower right side.

4 illustrates the electrical connections of the display modules.

On figa in a perspective view from the front side shows the elementary panel of the proposed display module.

On fig.5b the elementary panel of the proposed display module is shown in a perspective view from the back.

On figs elementary panel of the proposed display module is shown in a perspective view from the front side with a spatial diversity of parts.

On figa in a perspective view from the front side shows a printed circuit board related to the proposed display module.

On fig.6b printed circuit board related to the proposed display module is shown in a perspective view from the back.

Fig. 7 is a perspective view from the front of the protective coating related to the printed circuit board.

On figa in an enlarged view in a perspective view from the back with spatial diversity of parts shows a fragment of the elementary panel of the proposed display module.

On fig.8b fragment (left corner) of the elementary panel of the proposed display module is shown in enlarged view in a perspective view with spatial diversity of parts from the front side.

Figure 9 schematically shows a system of control devices (drivers) of light-emitting elements.

On figa shows the supporting frame of the proposed display module.

10b illustrates the construction of a central region of a display module of the invention.

11, the proposed display module is shown in front view.

On Fig illustrated the layout of the power, information and lighting electrical cables.

13, an enlarged view illustrates the mechanical connection of the display modules.

On Fig shows a prefabricated video display with a large screen assembled from display modules according to the proposed utility model.

The display module 1 in FIG. 1 a comprises a support frame 2 on which a control unit 3 and four elementary panels 4 are mounted.

The elementary panel 4 in Fig. 1b is connected to the control unit 3 of the display module 1 by means of cable 5. The cable 5 includes several conductors that supply power with a voltage of 5V DC, and serial modulated information signals for the elementary panel 4.

Functional diagram of the display module 1 is shown in figure 2.

The control unit 3 comprises a power input 6, a power output 7, an input 8 for serial data, an output 9 for serial data, an input 10 for lighting control data, an output 11 for lighting control data, and a data distribution circuit 12.

The power input 6 is electrically connected to a voltage converter 13, which converts the direct voltage 48V to a constant voltage 5V, required for the operation of the data distribution circuit 12 and elementary panels 4. The power output 7 is a jumper for transmitting electrical energy to an adjacent display module.

Input 8 for serial data receives control signals and displayed image data, which contain, for example, the pixel address and fractions of the red, green, and blue color components of the pixel, parameters of horizontal and vertical blanking intervals, and frequency

following pixels. However, such consistent data may carry a variety of other characteristics and standards for specifying color, as is well known to those skilled in the art. The output 9 for serial data is used to transmit image pixel data to an adjacent display module.

The input 10 for the lighting control data is a digital serial input, for example, organized by the well-known specialists in the DMX protocol, which controls lighting effects, such as blinking, dimming and fading. It is also possible to use other communication protocols, including the usual protocols used in the field of lighting.

The output 11 for lighting control data is a jumper for transmitting lighting control data to an adjacent display module.

The data distribution circuit 12 provides power control, image data processing, and control data processing, which is necessary for the normal operation of the display module. The data distribution circuit 12 contains output connectors 14. These output connectors 14 are used to supply power (DC voltage 5V) and serial modulated information signals to the elementary panel 4 via cable 5. In addition, the data distribution circuit 12 contains standard electronic components necessary for normal the operation of the display module 1, for example, a programmable matrix of logic elements, linear drivers with three states, a storage device and electronic filter components you, such as resistors and capacitors.

Input 8 for serial data and output 9 for serial data are connected to the communication unit 15, which is part of the data distribution circuit 12. The communication unit 15 receives control signals and image pixel data and transmits them for subsequent processing by the data distribution circuit 12. In addition, the communication unit 15 also functions as a data repeater and relays control signals and image pixel data to an adjacent display module.

An input 10 for lighting control data and an output 11 for lighting control data are connected to the lighting control unit 16, which is part of the data distribution circuit 12. The lighting control unit 16 receives data related to the lighting control and transmits them for subsequent processing by the data distribution circuit 12.

On figa and fig.3b in different views shows the control unit 3. It is attached to the supporting frame 2 of the display module 1 with screws 17, which makes it possible to quickly and easily replace the control unit 3 in case of failure or abnormal operation . This is often necessary if the business is related to equipment rental.

4 illustrates the electrical connections of the display module 1. Power can be supplied from an external power source 18, data related to lighting can be supplied from any standard lighting controller 19, and a serial data source can be, for example, a display controller 20. How can see in FIG. 4, power, lighting related data, and serial data can be transmitted from the outputs of one display module to the inputs of another display module. This allows you to connect the display modules with a daisy chain and reduce

the number of cables required when arranging a large screen modular display.

The elementary panel 4 is shown in different views in figa, fig.5b and figs. It contains a printed circuit board 21, a protective coating 25, a cable 5, screws 25 and nuts 27. Screws 25 and nuts 27 are used to connect the elementary panel 4 to the support frame 2.

The printed circuit board 21 is shown in different views in figa and fig.6b. It is made on the basis of a single sheet consisting of a dielectric material. Through holes 24 are cut out in the printed circuit board 21. Light emitting diodes 22 are located on the front side of the printed circuit board 21. Drivers 23 are located on its rear side, cable 5 is also located there. A receiving part 5b is made in the central part of the board for connecting to power inputs and data.

The protective coating 25 is shown in Fig.7. It is made of a single sheet of PCB or plastic. To enhance the contrast of the transparent display, the protective coating 25 may be provided with a matte black finish.

The thickness of the protective coating 25 is equal to the thickness of the light emitting diodes 22, so that the angle of emission of these light emitting diodes is not reduced, but they are protected from mechanical damage. Through-holes 24a and openings 28 are made in the protective coating 25. The through-holes 24a are the same in size and location as the through-holes 24 made in the printed circuit board 21. The light-emitting diodes 22 are placed in the openings 28 made in the protective cover 25.

The elementary panel 4 of the display module 1 is illustrated in FIG. 8a and FIG. 8b. These figures show in detail the light emitting diodes 22 located on the printed circuit board 21, the drivers 23, the protective coating 25, the screws 26, the nuts 27 and the holes 28.

Fig. 9 schematically shows a system of drivers 23. The topology for connecting drivers 23 to each other is of the “boostrofedon” type (originally called the writing method in which the direction of the letter alternates depending on the parity of the line, that is, if the first line is written to the right to the left, then the second - from left to right, the third - again from right to left, etc.). In the central region of the printed circuit board 21, a connection is made with a cable 5, which can be directly soldered, or connected via a quick-disconnect connector. The printed circuit board 21 has a copper track 5a for transmitting modulated information signals from the central region of the printed circuit board 21 to its upper right corner, to the first driver in the system 23. This arrangement of the driver system ensures full interchangeability of all elementary panels 4 as part of a large-screen modular video display.

Drivers 23 are preferably standard integrated DC LED drivers, such as a DM412 manufactured by Silicon Touch Technology Inc., Taiwan.

Light emitting diodes 22 are preferably light-emitting diode type KZS (red, green, blue), implemented, for example, in the form of a product NSSM016A manufactured by Nitia, Japan.

The support frame 2 is illustrated in FIG. 10a and FIG. 10b. It contains metal tubes 29, 32, 33, which are mechanically interconnected to form a solid and stable structure. On the lower ends of the vertical tubes 29, fixing sockets 30 are made, and on the upper ends of the vertical tubes 29, fixing lugs 31 are made and safety cables 36 are attached. Vertical tubes 29 are used to increase the mechanical stability of the structure of the support frame 2 as a whole to hold the elementary panels 4 (see figa) and cables 5 (see fig.10b). Horizontal tubes 33 are mechanically connected to the vertical tubes 29, 32 at the points 34. The tube 33, located on top of the support frame 2, has two cable holders 35.

The cable holders 35 are illustrated in FIG. With their help, the power, lighting and information cables are held in a horizontal position behind the upper horizontal tube 33 of the support frame 2. Due to this solution, the cables remain invisible to the observer located on the front side of the modular display 1, and the transparency of the display module 1 due to the presence of cables not getting worse.

On Fig shows the mechanical connection between adjacent display modules 1. This connection between adjacent display modules 1, located one above the other, is carried out using the locking sockets 30 and the locking protrusions 31. Using the safety wires 36, the display modules 1 are connected in accordance with safety standards for stage equipment. This figure also shows on an enlarged scale part of the vertical tube 29 and cable holder 35.

A prefabricated video display 37 with a large screen assembled from display modules according to the proposed utility model is shown in Fig. 14. The video display 37 is shown ready for use, it is suspended on the farm 38. The video display 37 is assembled from a set of display modules 1.

The display modules 1 constituting the video display 37 preferably form a 2 × 2 matrix. However, the specialist should be clear that they can be connected and with the formation of other configurations. In some applications, even a single modular display 1 can be dispensed with.

In the process of assembling a large-screen video display 37, the first row of display modules 1 is suspended from a horizontal support of a known type, for example, truss 38. The control units 3 are connected to each other, as well as to an external power source 18, a lighting controller 19 and a display controller 20, while a garland is created from the display modules 1.

The truss 38 is then raised to a height sufficient to suspend the second row of modular displays 1. This second row is suspended from the first row. The connection process is reduced to the creation of conventional cable connections and does not require multiple pin connections, as is the case in the prior art. This also facilitates the dismantling of the prefabricated video display. Thus, the proposed utility model provides simplicity and ease of implementation of assembly and disassembly cycles of a prefabricated video display.

The sizes of the proposed display module 1 can be different and are selected for reasons of weight and ease of transportation and assembly / disassembly of the video assembly. Preferably, the proposed display module 1 has the following dimensions and weight: width 940 mm, height 960 mm,

weight is 10 kg. The distance between the centers of the light emitting diodes 22 is 40 mm. Any changes in the size and weight of the display module 1 does not go beyond the scope of the proposed utility model.

What is located behind the video display is visible to the public, the video display can be backlit, which creates the possibility of obtaining unusual stage effects in addition to the on-screen video. Behind the video display, for example, stage lasers, or a scoreboard with a running line, can be placed.

During operation, image pixel data 1 is input to serial data of display module 1, data related to lighting is received to input 10 for lighting control data, and power is supplied to power input 6. The incoming image pixel data is processed by the data processing circuit 12, which takes all the necessary data related to the images from the image pixel data stream in accordance with the coordinates, processes the data related to the images, and generates sequential modulated information signals, which are then sent to each elementary panel 4 via cables 5. Modulated information signals are sent to the driver system 23. Each of the drivers 23 using pulse width modulation includes either Turns off the light emitting diode 22, so that it becomes possible to implement a static or dynamic color image.

Claims (10)

1. The display module for a transparent video display with a large screen containing elementary panels with light-emitting elements and through windows, a data distribution circuit and inputs for data and power, characterized in that it is equipped with a control unit mounted on the display module without compromising the transparency of the latter, and said data distribution scheme is installed inside said control unit. 2. The display module according to claim 1, provided with receiving portions of the connection for said inputs for data and power, located in the central zone of said elementary panels. 3. The display module according to claim 2, in which said inputs for data and power are provided with multi-core cables soldered directly to said receiving parts of the connection on elementary panels. 4. The display module according to claim 2, in which said inputs for data and power are provided with multi-core cables connected to said receiving parts of the connection by means of quick-disconnect connectors on elementary panels. 5. The display module according to claim 1, in which the topology of the connection of the light-emitting elements to each other forms boostrophedon. 6. The display module according to claim 1, in which each elementary panel is made in the form of a monolithic printed circuit board. 7. The display module according to claim 6, in which the light emitting elements are located on one side of the printed circuit board, and the drivers on its opposite side. 8. The display module according to claim 6, in which the elementary panel is provided with a protective coating applied to the surface of the printed circuit board. 9. The display module according to claim 1, containing four elementary panels and forming a square. 10. The display module according to claim 1, in which the elementary panels are mounted on a support frame.