RU2555767C1 - Method and device for magnetic attachment of light-emitting diode module to transparent sheet - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: device for magnetic attachment consists of: a ferromagnetic substrate, which can be a perforated sheet of ferromagnetic material or a set of parallel strips of ferromagnetic material; a light-emitting diode (LED) module, which is a printed-circuit board with LEDs soldered on the front surface and ferromagnetic elements mounted on the front or back surface of the printed-circuit board. The LED module is attached to a glass surface using a method which includes: gluing the ferromagnetic substrate to the glass surface; mounting the LED module on the substrate, the module being placed such that LEDs lie opposite openings in the substrate. The LED module is held on the transparent surface by magnetic attractive forces between the ferromagnetic elements of the LED module and the ferromagnetic substrate. Vertical movement of the module is blocked due to that the LEDs in the openings of the ferromagnetic substrate rest on the edge of the openings of the substrate, which prevents movement of the module.

EFFECT: enabling placement of LED screens and LED displays directly on a glass surface or transparent sheets made of other materials without additional fastening elements or a mounting frame; producing LED screens and LED displays with a simple design using as the bearing element thick glass or transparent sheets made of other transparent materials.

25 cl, 11 dwg

Description

The invention relates to the field of outdoor advertising and can be used to create LED advertising video screens and LED displays mounted on the surface of glasses or translucent sheets made of other materials.

The prior art device device LED module with a transparent surface - High-Transparent LED Display Module, July 5, 2012, patent US 20120168789 A1 // Patent search GOOGLE.

URL: httpshttps: //www.google.com/patents/US20120168789 (accessed 05/11/2014). The device has a supporting frame in the form of a metal rectangular pipe; inside the frame is an electronic board that controls the LEDs; a sheet of translucent material is mounted on the frame, on which the LEDs are mounted. The first disadvantage of this design is the low image quality due to the transmission of the frame and other engineering elements at low levels of image brightness. The second disadvantage is the need for a support or suspension for placing such modules on the surface of the translucent sheet. The third disadvantage is the inability to create screens with a high pixel density using such a device, since in this case transparency will be lost. The fourth drawback is that this technical solution is aimed at solving another technical problem - to ensure transparency of the screen.

There is also a method of attaching the transparent LED modules described above to a translucent sheet using translucent threaded fasteners. Fasteners are glued to a translucent sheet, an LED module is screwed to these elements using a bolted connection. The disadvantage of this mounting method is the heterogeneous front surface due to the placement of transparent fasteners in front of the LED module. The inability to create high-quality screens with a high pixel density, since fasteners and bolts should be placed between the LEDs.

Most devices of existing LED modules do not have the ability to mount to the glass surface, as a result of which it is necessary to mount the LED modules on a massive frame. Existing methods of fastening the screen to a translucent sheet do not allow creating high-definition screens for mounting on the glass surface, since due to the large size of the fasteners, the distance between the LEDs cannot be reduced. Existing attachment devices, despite partial transparency, are noticeable, which reduces image quality. The contrast of the known technical solutions is minimal due to the reflection of light from the back surface of the translucent sheet and the use of a transparent design, which also reduces contrast due to reflection of light from the surface of the transparent sheet on which the LEDs are soldered and reflection of light from objects behind the LED module. Replacing the modules of modern screens mounted on translucent sheets is time-consuming due to the complex mounting design. It is also laborious to deploy large screens on the surface of glass or other translucent sheets - due to the fact that very precise positioning of each of the fasteners located at a great distance from each other is required.

The tasks to which this invention is directed are:

easy-to-use and inconspicuous fastening of LED modules on the surface of glass or translucent sheets of other materials without additional fasteners or a support frame; the ability to quickly and easily replace the module in any part of the screen without the use of tools; the ability to quickly deploy large-area screens on the surface of translucent sheets (glass); the ability to make of any glass or translucent sheet of another material a high-quality contrast LED screen without visible joints or visible mounts; the ability to create LED screens and LED displays of a simplified design, using thick translucent sheets as a support element.

The solution of tasks

The LED module (2) is mounted on the surface of the translucent sheet (9) as follows: a ferromagnetic substrate (3, 4, 5) is glued onto the translucent sheet (9), including openings for accommodating the LEDs (1) of the LED module (2); an LED module (2) is installed on the substrate (3, 4, 5), which incorporates one or more ferromagnetic elements (6, 7, 8); the LED module is placed on the surface of the ferromagnetic substrate (3, 4, 5) so that the LEDs (1) are opposite the openings in the substrate (3, 4, 5), and the light emitted by the LEDs (1) passes through these openings unhindered; the LED module (2) is held on the surface of the translucent sheet (9) due to the forces of magnetic attraction arising between the ferromagnetic elements (6, 7, 8) of the LED module (2) and the ferromagnetic substrate (3, 4, 5). There are various options for bonding the substrate (3, 4, 5) to the surface of the translucent sheet: by applying glue to the surface of the substrate (3, 4, 5); by applying glue with ultraviolet hardening on the surface of the substrate (3, 4, 5) with further irradiation with ultraviolet light through a translucent sheet; by applying glue to a translucent sheet; using an adhesive layer deposited on a substrate (3, 4, 5) during the manufacturing process of the substrate (3, 4, 5); with double-sided transparent adhesive film.

The first version of the ferromagnetic substrate (3) is a sheet having ferromagnetic properties, with holes for accommodating the LEDs (1) of the LED module (2). The location of the holes in the ferromagnetic substrate corresponds to the location of the LEDs (1) on the surface of the LED module (2), therefore, the light emitted by the LEDs (1) can freely pass through these holes. In this case, the holes in the substrate (3) can have a different shape in different versions of the substrate, including: round shape, oval shape, rectangular shape, rectangular shape with rounded edges. The holes in various embodiments of the substrate can cover either one (3) LED (1) or several (4) LEDs (1) at once. The substrate (3, 4, 5) can be made of either soft magnetic or hard magnetic material. The substrate (3, 4, 5) has a black surface that absorbs light. Due to the absence of an air gap between the substrate and the translucent sheet, there is no reflection of light from the rear surface of the translucent sheet, which significantly increases the contrast of the image.

The second version of the ferromagnetic substrate (5) is a set of strips with ferromagnetic properties. The strips are placed on the translucent sheet (9) parallel to each other at a distance sufficient to accommodate the LEDs (1) between them. The location of the gaps between the strips corresponds to the location of the LEDs (1) on the surface of the LED module (2), therefore, the light emitted by the LEDs (1) can freely pass through these gaps. The strips can have a different shape in different versions: rectangular strips; strips with protrusions located at the edges, covering the LEDs (1) of the LED module (2); stripes with wave-shaped edges; strips connected by jumpers. Strips can be made of either soft magnetic or hard magnetic material. The stripes of the substrate have a black surface that absorbs light.

The device of the LED module (2) is a printed circuit board with LEDs (1) located on the front surface and installed on the surface of the printed circuit board with one or more ferromagnetic elements (6, 7, 8). Ferromagnetic elements (6, 7, 8) can be mounted both on the front side of the circuit board and on the back. Ferromagnetic elements (6, 7, 8) can have various shapes, including the shape of sheets with holes (6) for LEDs or the shape of strips. Ferromagnetic elements can be mounted on the surface of the board by soldering or gluing. Ferromagnetic elements (6, 7, 8) can be made of either soft magnetic or hard magnetic material. The circuit board has a black surface that absorbs light.

Brief Description of the Drawings

Before installing the LED module (2) on the surface of the translucent sheet (9), a ferromagnetic substrate is glued onto the translucent sheet (9), which may be in the form of a perforated sheet with holes for the LEDs (3). Also, the substrate may be in the form of a perforated sheet with holes spanning several LEDs (4). Also, the substrate can be made in the form of separate parallel flat strips of various shapes (5) or strips with jumpers. After gluing the ferromagnetic substrate onto the translucent sheet (9), an LED module (2) is installed on the ferromagnetic substrate, which is a printed circuit board with LEDs (1) soldered to the front surface. Ferromagnetic elements can have a different shape. The figures show square ferromagnetic elements (7) and round ferromagnetic elements (8). Ferromagnetic elements can be installed both on the rear surface of the LED module and on the front surface. To install ferromagnetic elements on the front surface of the LED module, perforated ferromagnetic elements can be used (6).

List of Shapes

1. Magnetic mounting device for an LED module with a perforated substrate, front view with spaced parts.

2. Device for magnetic fastening of an LED module with a strip-like substrate, front view with spaced parts.

3. The device for magnetic fastening of the LED module with a substrate in the form of strips with protrusions, front view with spaced parts.

4. The device for magnetic fastening of the LED module with a substrate in the form of strips with jumpers, front view with spaced parts.

5. The device for magnetic fastening of the LED module with a perforated substrate and square ferromagnetic elements, rear view with spaced parts.

6. The device for magnetic fastening of the LED module with a substrate in the form of strips and round ferromagnetic elements, rear view with spaced parts.

7. The device for magnetic fastening of the LED module with a substrate in the form of strips and a front mounted magnetic element in the form of a perforated ferromagnetic sheet, front view with spaced parts.

8. Installation of the LED module on a perforated substrate, front view.

9. Installation of the LED module on a perforated substrate with holes covering several LEDs, front view.

10. Installation of the LED module on a substrate of strips, front view.

11. Sectional view of the design of the magnetic mount of the LED module.

List of items depicted in the figures

1. LED.

2. LED module.

3. Perforated ferromagnetic substrate.

4. Perforated ferromagnetic substrate with holes spanning several LEDs.

5. The magnetic substrate in the form of stripes.

6. Perforated ferromagnetic element.

7. Square ferromagnetic element.

8. Round ferromagnetic element.

9. Translucent sheet.

Magnetic mount device for LED module

The device consists of 3 main elements: a translucent sheet (9), on which LED modules (2) will be installed; a ferromagnetic substrate (3, 4, 5) and an LED module (2) with ferromagnetic elements (6, 7, 8) in the composition. The ferromagnetic substrate (3, 4, 5) is glued to the translucent sheet (9). The LED module (2) is fixed on the surface of the translucent sheet (9) due to the forces of magnetic attraction between the ferromagnetic substrate (3, 4, 5) and the ferromagnetic elements (6, 7, 8) mounted on the surface of the module. LEDs (1), falling into the openings of the substrate (3, 4, 5), abut against its edges, which blocks the possibility of vertical movement of the LED module on the surface of the translucent sheet (9). The substrate (3, 4, 5) is made of black light-absorbing material to create a contrasting surface.

The manufacture of magnetic mounting device LED module

The LED module is made as follows: first, the printed circuit board is manufactured by the standard industrial method, then the LEDs and other electronic components are soldered to the printed circuit board. In some embodiments of the device, the ferromagnetic elements are soldered simultaneously with other electronic elements to the surface of the board. After testing the electronic board of the LED module, ferromagnetic elements are glued to its surface from the front or back of the board, depending on the implementation of the device.

The substrate can be made of various materials, for example, from a metal sheet having ferromagnetic properties, or ferromagnetic vinyl. In the manufacture of a substrate of metal, laser cutting or coordinate punching of metal can be used. The metal sheet is first perforated, then painted black. When using ferromagnetic vinyl, the substrate is made by cutting from a single vinyl sheet. Vinyl material may also have an adhesive layer on one side.

The operation of the magnetic mounting device of the LED module is as follows:

a ferromagnetic substrate (3, 4, 5) is glued to the surface of the translucent sheet (9), an LED module (2) with integrated ferromagnetic elements (6, 7, 8) is mounted on the substrate; the module is fixed on the surface of the translucent sheet (9) due to the forces of magnetic attraction between the ferromagnetic substrate (3, 4, 5) and the ferromagnetic elements (6, 7, 8) mounted on the surface of the module; LEDs (1), falling into the openings of the substrate, abut against its edges, which blocks the possibility of vertical movement of the LED module on the surface of the translucent sheet (9); when a signal is applied to the LED module, the LEDs begin to emit light of various intensities, creating an image on the surface. Due to the fact that the substrate (3, 4, 5) has a black surface that absorbs light, and there is no gap between the translucent sheet and the substrate, a high-contrast image is formed.

Claims (25)

1. The method of mounting the LED module on the surface of the translucent sheet using a ferromagnetic substrate is characterized in that a substrate having ferromagnetic properties is adhered to the translucent sheet, including openings for accommodating LEDs of the LED module, an LED module having one or more ferromagnetic elements, the LED module is placed on the surface of the ferromagnetic substrate so that the LEDs are opposite willows of the openings of the ferromagnetic substrate, and the light emitted by the LEDs passed through these openings without hindrance, the LED module is held on the surface of the translucent sheet using the forces of magnetic attraction arising between the ferromagnetic elements included in the LED module and the ferromagnetic substrate. 2. The method of attaching the LED module to a translucent sheet according to claim 1 is characterized in that the substrate is adhered by applying glue to the surface of the substrate. 3. The method of attaching the LED module to a translucent sheet according to claim 1 is characterized in that the substrate is adhered by applying glue to the translucent sheet. 4. The method of attaching the LED module to a translucent sheet according to claim 1 is characterized in that the substrate is adhered using a double-sided transparent adhesive film. 5. The device of the ferromagnetic substrate, consisting of a perforated ferromagnetic sheet, intended for mounting the LED module on the surface of the translucent sheet, is characterized in that the substrate has ferromagnetic properties and includes holes for accommodating the LEDs of the LED module, the location of the holes in the ferromagnetic substrate corresponds to the location of the LEDs on the surface of the LED module, so the light emitted by the LEDs can pass unhindered Res these holes, the ferromagnetic substrate holds the LED module on the translucent surface of the sheet by means of magnetic attraction forces generated between the LED module ferromagnetic elements and ferromagnetic substrate. 6. The device of the ferromagnetic substrate according to claim 5 is characterized in that the holes in the substrate are round in shape. 7. The device of the ferromagnetic substrate according to claim 5 is characterized in that the holes in the substrate are rectangular in shape. 8. The device of the ferromagnetic substrate according to claim 5 is characterized in that one hole covers one LED. 9. The device of the ferromagnetic substrate according to claim 5 is characterized in that one hole covers several LEDs. 10. The device of the ferromagnetic substrate according to claim 5 is characterized in that the substrate is made of soft magnetic material. 11. The device of the ferromagnetic substrate according to claim 5, characterized in that the substrate is made of hard magnetic material. 12. The device of the ferromagnetic substrate according to claim 5, characterized in that the substrate has a black surface that absorbs light. 13. The device of the ferromagnetic substrate, consisting of flat strips having ferromagnetic properties, designed for mounting the LED module on the surface of the translucent sheet, characterized in that the strips are placed on the translucent sheet parallel to each other at a distance sufficient to accommodate the LEDs between them, the location of the gaps between the strips corresponds to the location of the LEDs on the surface of the LED module, so the light emitted by the LEDs can interfere but pass through these gaps, the ferromagnetic substrate holds the LED module on a surface of a translucent sheet by magnetic attraction forces generated between the ferromagnetic element and the LED module substrate ferromagnetic strips. 14. The device of the ferromagnetic substrate according to claim 13 is characterized in that the strips have protrusions located on the sides, covering the LEDs of the LED module. 15. The device of the ferromagnetic substrate according to claim 13, is characterized in that the strips are interconnected by jumpers. 16. The device of the ferromagnetic substrate according to claim 13 is characterized in that the strips are made of hard magnetic material. 17. The device of the ferromagnetic substrate according to claim 13, characterized in that the strips are made of soft magnetic material. 18. The device of the ferromagnetic substrate according to p. 13 is characterized in that the strips of the substrate have a black surface that absorbs light. 19. The device of the LED module, designed for installation on a translucent sheet with a magnetic substrate, containing a printed circuit board with LEDs placed on the front surface, is characterized in that one or more ferromagnetic elements are installed on the surface of the printed circuit board, which, by means of magnetic forces arising between ferromagnetic elements of the LED module and a ferromagnetic substrate, hold the LED module on the surface of the translucent sheet. 20. The device of the LED module according to claim 19 is characterized in that the ferromagnetic elements are mounted on the rear surface of the printed circuit board. 21. The device of the LED module according to claim 19 is characterized in that the ferromagnetic elements are mounted on the front surface of the circuit board between the LEDs. 22. The device of the LED module according to claim 19 is characterized in that the ferromagnetic elements are mounted on the surface of the printed circuit board of the LED module by soldering. 23. The LED module device according to claim 19 is characterized in that the ferromagnetic elements are glued to the surface of the printed circuit board. 24. The device of the LED module according to claim 19 is characterized in that the ferromagnetic elements are made of soft magnetic material. 25. The device of the LED module according to claim 19, characterized in that the ferromagnetic elements are made of hard magnetic material.

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