WO2018169445A1

WO2018169445A1 - Method for clamping a light-emitting diode lamella to a supporting surface

Info

Publication number: WO2018169445A1
Application number: PCT/RU2018/000032
Authority: WO
Inventors: Алексей Викторович ШТОРМ
Original assignee: Алексей Викторович ШТОРМ
Priority date: 2017-03-13
Filing date: 2018-02-14
Publication date: 2018-09-20
Also published as: RU2662386C1

Abstract

The invention relates to the field of devices for presenting changing information material and can be used for producing devices for showing an outdoor video commercial. The problem which this invention is aimed at solving is to ensure that light-emitting diode lamellae can be clamped tightly to a segment frame, along the entire length of said lamellae. The light-emitting diode lamella is in the form of a long strip, the front surface of which is covered with light-emitting diodes. The light-emitting diode lamella is manufactured with a slight curve, which straightens out when the lamella is fitted to the segment frame, and the spring force which arises as a result clamps the light-emitting diode lamella reliably to the segment frame, along the entire length of said lamella.

Description

The method of pressing the LED lamella to the bearing surface

The invention relates to the field of devices for presenting changing information material and can be used to create devices for demonstrating outdoor video ads.

An LED screen device is known from the prior art (CN 201859616 U, G09F 9/33, 06/08/2011). The device is a rectangular frame with a control unit with a power source installed in the upper part. LED strips located in iron cases are connected to the control unit. The frame contains transverse bars on which the permanent magnets are placed. These magnets attract the iron casing of LED strips to themselves and hold them on the surface of the frame. The first disadvantage of this device is the low reliability that occurs due to the large number of connecting contacts in the device. And when using such an LED screen in street conditions, you will have to ensure the tightness of the signal connectors of each tape. The second disadvantage of this device is the low image quality due to the large distance between the LED strips and the low density of LEDs per square meter. The device has low contrast. The third disadvantage of this device is the difficulty of maintenance. To gain access to the control unit from the front, you must first dismantle the LED strips. To successfully replace the LED strip at the back, you must have

a sufficiently large gap between the strips, otherwise it will be difficult to install a new LED strip in place of the old one.

The prior art device is known for the LED screen (US 20090251393 A1, G09G 3/32, 04/04/2008). The device contains a group of LED modules connected in series in several

parallel lines. The lines are fixed on the upper guide, and from the bottom are fastened together by a reinforcing lock. The first disadvantage of this device is the lack of a frame. LED modules hang freely from the upper guide, which does not allow to achieve the resistance to wind loads necessary for outdoor conditions and to provide high accuracy of pixel placement relative to each other. Because of this, the image quality of the LED screen is significantly reduced. The second disadvantage of this device is the complexity of the technical

service. If a malfunction occurs in one of the units, it may be necessary to disassemble a significant part of the device. An LED screen device is known from the prior art (CN 201465464 U, G09F 9/33, 06/26/2009). The device contains a group of narrow and long LED modules connected in parallel and forming a single LED surface. The lines are fastened together using transverse aluminum profiles that are screwed to the LED modules with bolts at the rear. The first disadvantage of this device is the lack of a solid frame. Since LED screens are structures that require precise relative positioning of LED modules relative to each other, when placing LED segments on the target surface, an external frame will have to be mounted. Installing an external frame can significantly increase the weight of the structure. The second disadvantage of this device is the complexity of maintenance. This type of LED display provides only rear maintenance, since all mounting elements are located at the rear. If you need to replace the LED module in front, you have to

dismantle the entire segment. Maintenance Difficulty

limits the scope of LED screens of this design.

An LED screen device is known from the prior art (CN 201222330 Y, G09F 9/33, 08/08/2008). The device consists of LED modules located inside round transparent tubes. Pipes are connected in series in a line and suspended from control units,

located at the top of the screen. The exact distance between the pipes is maintained thanks to the positioning elements, which are flat plates with cutouts for LED modules and holes for connection with neighboring similar elements. The first disadvantage of this device is the lack of a solid frame, this limits its use in outdoor conditions (due to high wind loads) and reduces image quality. Screens with this design require the placement of additional positioning elements on the bearing surface to ensure an even image. The second disadvantage of this device is the complexity of maintenance. It may be necessary to dismantle a separate LED module.

dismantle other modules making up the line. To replace the control unit, it is necessary to disassemble all lines suspended from it.

LED modules. Due to the large number of independent elements, the deployment of such screens on a bearing surface is difficult and

expensive. The third disadvantage of this device is the low image quality. The device uses transparent plastic pipes, which many times reduce the contrast of the LED screen in the daytime, and the large distances between the modules allow you to see the facade of the building located at the back of the screen.

Modern LED screens are sophisticated digital devices containing millions of elements and tens of thousands of electrical connections between modules. Due to the complexity of LED screens to ensure reliability and quality, the architecture of engineering and electronic systems of LED screens is of particular importance.

The invention is aimed at solving the problems of creating a new type

LED video screens for the advertising industry, consisting of a set of long (up to 10 meters) LED slats. LED lamella is a narrow and long strip, the front surface of which is covered with LEDs. These screens will have low weight, ease of assembly and maintenance. Lamellar LED screens will be used for the deployment of large digital advertising networks, which require standard-sized LED screens with high operational

characteristics.

To date, long and narrow LED modules have been used in media facades, where a separate LED module contained one line of LEDs, and the length of the module was limited to 2 meters. Media facades have a number of design flaws: a large number of external connections leads to a decrease in reliability and an increase in the cost of the media facade; due to the design features of the media facade, it is difficult to ensure a high density of LEDs per square meter and high image quality. So, in media facades, an increase in resolution leads to an increase in the number of individual LED modules and a decrease in the reliability of the entire screen, and because of the large distance between the LED modules, the media facades have low contrast

Images.

In the lamellar LED screen, unlike media facades, the length of the lamella is equal to the height of the screen and can reach 10 meters. In addition, each LED lamella can contain dozens of LED lines, and the LED lines can be located at a distance of only 2 mm from each other, which will provide a high density of LEDs per square meter.

The tasks to which this invention is directed are: ensuring tight pressing LED lamellas along their entire length to the bearing surface.

The tasks are solved as follows

Lamella LED screen consists of several LED

segments connected in a single LED surface. Each LED segment includes: a segment frame (3), several LED slats (1) and one or more control units (2).

At one end of the frame of the segment (3) there are lamella guides (11, 12) blocking the movement of the LED lamellas along two axes,

perpendicular to the longitudinal axis of the segment frame. Guides

LED lamellas can be realized in the form of holes in the frame of a segment (11), into which rods are placed at the ends of LED lamellas (19). The guides of the LED lamellas can also be implemented in the form of rods mounted on the frame of the segment (12), which are inserted into the holes located at the ends of the LED lamellas (18).

Transverse crossbars (5) are located along the entire length of the segment frame (3), which are sheets with cutouts for inserting LED slats. Using these crossbars (5), the position of the LED lamellas (1) is precisely positioned along the entire length of the segment frame (3), and the lateral displacement of the LED lamellas (1) is also blocked.

From the other end of the frame of the segment (3), the LED lamellas (1) are blocked by the fixing device of the LED lamellas. This device consists of several magnetic clips (8) and a fixing strip (b).

The locking bar (6) is a corner made of ferromagnetic materialb, on one side of which there are holes (7) for inserting the rods of the magnetic clamps (8). On the other side of the corner are cutouts (16) for electrical contacts in the form of rods (14) and signal connectors (17) connecting the control unit (2) with

LED slats (1). Under the holes (7) located on the fixing strip at the lower ends of the LED slats, there are holes (7) for inserting the rods of the magnetic clips (8).

Ensuring reliable pressing of the LED lamella (1) to the segment frame is as follows. During production, a small radial bend of the central parts of the LED lamella (1) back relative to the ends of the LED lamella. When installing the LED lamella on the supporting surface, the ends of the LED lamella are firmly pressed against the segment frame, and

the LED lamella (1) is straightened, due to reverse deformation in the LED lamella (1) there is an elastic force directed to

restoration of the original form, this force presses the LED lamella (1) along its entire length to the segment frame.

The movement of the LED screen elements on the frame of the segment is blocked using magnetic clips (8). The magnetic lock (8) is a rod with a thickening on one side of the rod, which is made using ferromagnetic material in the structure. The magnetic lock can be made in the form of a rod with a thickening at the end, on which a ferromagnetic ring (8) is worn, pressed against the thickening of the rod. The magnetic lock (8) is held in place by magnetic forces between the ferromagnetic element of the magnetic lock (8) and the ferromagnetic element of the segment frame. The longitudinal movement of the element of the LED screen is fixed due to the fact that the magnetic lock incorporates a rod that passes through the holes (7) in the element of the LED screen and the segment frame. When the element of the LED screen is shifted relative to the frame of the segment, the walls of the holes abut against the edges of the rod, thus blocking the movement of the elements of the LED screen relative to the bearing surface.

Fixation of LED lamellas is carried out as follows: first, LED lamellas (1) are inserted into the guide lamellas (11, 12) at a small angle to the surface of the segment frame; after insertion, the LED lamella (1) is installed parallel to the surface of the segment frame and moves in the opposite direction; After being set to a predetermined position, the movement of the LED lamella (1) is blocked by the longitudinal movement lock (8).

The fixing of the control unit (2) is carried out as follows: the control unit (2) is moved along the guides of the control unit (13);

guides of the control unit (13) block its movement along two axes perpendicular to the longitudinal axis of the segment frame; after installation in a predetermined position of the control unit (2), its movement is blocked with the help of longitudinal movement clamps (8). The latches of longitudinal movement (8) can be in blocking and non-blocking longitudinal movement states. The installation operations of the LED slats (1) and the control unit (2) can be performed independently of each other and in random order. As an alternative to magnetic locks, threaded locks can also be used. In this case, to install the clamps on the frame elements or elements of the LED screen, a thread is cut, and the lock is screwed into this thread.

The control unit (2) and LED slats (1) contain electrical contacts (14, 15) and signal connectors (17) located on the sides. After installing the LED lamellas (1) and control units (2) in a predetermined position, the electrical contacts (14, 15) of the control unit (2) and the LED lamellas (1) touch each other, this allows you to transfer electrical power and signals from the control unit ( 2) to LED slats (1). Electrical contacts can be implemented as a set of conductive rods (14) that exit the control unit (2) and enter the holes (15) of the LED slats (1) with

electrical contacts inside. Also, electrical contacts can be implemented as a set of conductive rods (14) that extend from the ends of the LED slats (1) and enter the holes (15) in the control unit (2) with electrical contacts inside. To transmit a large number of control signals, special signal connectors (17) can be used, where a flat printed circuit board, with many contacts located on the surface layers of the printed circuit board, is used in place of the rod.

Brief Description of the Drawings

In the figures (1-8) the lamella screen device is shown.

The figure (9) shows the steps for installing the LED lamella on the segment frame: (9 A) Starting position - there is no LED lamella; (9 B) Position of the LED lamella before insertion into the hole of the guide lamella; (9 V) The LED lamella is pushed into the guide hole to the end; (9 G) The LED lamella is moved back and in the set position, the LED lamella is fixed with a magnetic lock.

The figure (10) shows the steps for installing the control unit on the segment frame: (10 A) Starting position - there is no control unit; (10 B) The control unit is half-moved; (10 V) The control unit is pushed to end and is in a predetermined position; (10 G) The control unit is fixed with magnetic clips.

The figure (11) shows a method that provides reliable pressing of the LED lamella along the entire length to the bearing surface. (11 A)

LED lamella, side view; (11 B) LED lamella with a bend, side view; (11 V) LED lamella with a bend before installation on a bearing surface, side view; (11 G) LED lamella with a bend after pressing the ends to the bearing surface and securing the ends with clamps, side view.

The figures (12-16) depict one of the possible options for the industrial implementation of the lamella screen.

List of Shapes

1. LED screen.

2. LED segment, complete.

3. LED segment, exploded view.

4. Slat guides, in the form of holes.

5. Guide rails, in the form of rods.

6. Control unit with external contacts.

7. Control unit with internal contacts.

8. Magnetic lock longitudinal movement.

9. Installation of LED slats.

10. Installing the control unit.

I. Installation of LED sipes with deflection.

12. LED segment.

13. LED segment, exploded view.

14. The frame of the segment. 15. LED lamella.

16. The control unit.

List of items depicted in the figures

1. LED lamella.

2. The control unit.

3. The frame of the segment.

4. Aluminum profile frame segment.

5. The crossbeam.

6. The fixing strip.

7. Hole for longitudinal locking.

8. Magnetic lock longitudinal movement.

9. The ferromagnetic ring.

10. The fan.

11. Guide lamellas in the form of holes.

12. The guide lamellas in the form of a rod.

13. Guide of the control unit.

14. A rod-shaped electrical contact.

15. Electrical contact in the form of a hole.

16. Cutout in the retaining plate for electrical contacts.

17. Signal connector.

18. Hole in the LED strip for the guide.

19. The rod of the LED lamella for the guide.

20. LED surface. Device

Lamella LED screen consists of several LED

segments connected in a single LED surface. Each LED segment includes: a segment frame (3), several

LED slats (1) and one or more control units (2).

At one end of the frame of the segment (3) there are lamella guides (11, 12) blocking the movement of LED lamellas along two axes,

perpendicular to the longitudinal axis of the segment frame. Guides

From the other end of the frame of the segment (3), the LED lamellas (1) are blocked by the fixing device of the LED lamellas. This device consists of several magnetic locks (8) and a fixing strip (6).

The movement of the LED screen elements on the frame of the segment is blocked using magnetic clips (8). The magnetic lock (8) is a rod with a thickening on one side of the rod, which is made using ferromagnetic material in the structure. The magnetic lock can be made in the form of a rod with a thickening on the end, on which a ferromagnetic ring (8) is worn, pressed against the thickening of the rod. As an alternative to magnetic locks, threaded locks can also be used. In this case, to install the clamps on the frame elements or elements of the LED screen, a thread is cut, and the lock is screwed into this thread.

The device is manufactured as follows:

The LED lamella (1) consists of a housing, LED modules and plastic covers. The housing of the LED lamella (1) is an aluminum profile made by extrusion of aluminum.

LED modules are printed circuit boards with front-mounted LEDs and other electronic elements located at the back. LED modules are manufactured using standard industrial electronics assembly methods. Plastic caps

made using injection molding of plastic.

The LED lamella (1) is assembled from individual elements into a finished product.

The control unit housing (2) is made of plastic by injection molding. The control unit (2) contains power modules, the output contacts of which are connected to the output contacts (14, 15) of the control unit (2). The control unit (2) also contains a segment controller, which

transmits control signals to LED slats (1) through signal connectors (17) located next to the power contacts (14, 15). At the back of the control unit (2) are aluminum radiators,

made by extrusion of aluminum, which are used to cool the power modules.

The frame of segment (3) contains two aluminum profiles made by extrusion of aluminum. Aluminum profiles are interconnected by transverse beams (5). Cross bars (5) are sheets cut from solid composite panels on a milling machine and bent into boxes. The crossbars can also be made of sheet metal using laser cutting and bending. The rails are attached to the flanges of aluminum profiles with rivets. Next, cooling fans (10) are installed on the segment frame and the supply wires are attached.

A fixing strip (6) is also mounted on the frame of the segment (3), which is made of a solid steel sheet using laser cutting and metal bending. The latches (8) can be made on a lathe from a ferromagnetic magnetic hard material with subsequent

magnetization. Magnetic clamps (8) can also be made of plastic or soft magnetic metal, in which case they are mounted ferromagnetic from a magnetically hard ring (9).

The segment of the LED screen is assembled as follows: LED lamellas (1) are installed on the frame of the segment (3), the position of which is fixed using magnetic clips (8). After insertion

LED lamellas (1) on the frame of the segment (3), a control unit (2) is installed, which is also fixed using magnetic clips (8).

Deployment of the screen on the supporting structure is as follows: the assembled LED segments are suspended on the supporting structure, and their segments are bolted together. After the screen is assembled, power and signal wires are connected to the control units (2).

The operation of the device is as follows:

When applying voltage from the network to the control unit (2), the power modules included in its composition reduce it to 5 volts. This voltage is transmitted to the LED slats (1) through the power contacts (14, 15). To controller segment of the control unit (2) receives a data stream from the screen controller, this data stream is converted and transmitted through the signal connectors (17) to the LED slats. Each LED module contains LED drivers that receive a control signal from the segment controller and supply current to the LEDs in accordance with this signal. With the passage of electric current through the LEDs, they begin to emit light. Thus, on the surface (20) of the LED slats (1)

an image is formed.

When light is emitted by LEDs, a significant part of the energy is released in the form of heat, this heat is dissipated by the aluminum profiles of the LED lamellas (1) using air convection. If the ambient temperature does not allow heat to be removed by means of natural convection, then for cooling in the LED segments fans (10) located along the entire length of the segment frame (3) are switched on. These fans (10) pump air behind the LED segment, cooling the LED slats (1). For forced cooling of the control unit (2)

LED segment uses fans (10), located on the frame of the segment (3) behind the control units (2). The air flow of these fans (10) is directed directly to the radiators of the control units (2) located on the rear side of the control units (2). This solution allows for intensive cooling of the power supply modules of the control unit (2) through radiators.

Claims

Formula

1. The method of ensuring reliable pressing of the LED lamella to the bearing surface is characterized by the fact that during production along the entire length of the LED lamella, a small radial bend of the central part of the LED lamella is formed back relative to the ends of the LED lamella, when the LED lamella is installed on the bearing surface, the ends

LED lamellas are firmly pressed against the bearing surface, and the LED lamella itself is straightened, due to reverse deformation, an elastic force arises in the LED lamella aimed at

restoration of the original form, this force presses the LED lamella along its entire length to the bearing surface.