The present disclosure relates to displays, in particular to display backplanes, display devices and tiled display devices.
The backplane of an LED display conventionally includes several pixel areas, in which each pixel point contains a red LED, a blue LED and a green LED. Such RGB pixel areas constitute a display area; and both sides outside the display area are boundary regions. However, the boundary of the display may be wider due to a larger width of each boundary region caused by each individually current-driven LED and thousands of data lines.
Further, the tiling effect of the displays may be affected by their boundary, thereby affecting the display effect.
For this purpose, a display backplane, a display device and a tiled display device, which can reduce the boundary of the device and better the display effect thereof, may be necessarily provided.
The object is satisfied by the technical solution of the present disclosure which is as follows:
In a first aspect, a display backplane is provided in the present disclosure. The display backplane may include a backplane, a plurality of micro light-emitting diodes arranged on the backplane in a matrix structure, a plug-in circuit board arranged on one end of the backplane, and a plurality of signal lines electrically connected to the plurality of micro light-emitting diodes in a one-to-one correspondence and to the plug-in circuit board, wherein the backplane comprises a front surface and a back surface opposite to the front surface; a light-emitting area provided with the plurality of micro light-emitting diodes and arranged on the front surface; a first trace area and a second trace area arranged on both opposite sides of the light-emitting area, and a third trace area arranged on one side of the light-emitting area and between the opposite sides; the third trace area is arranged between the first trace area and the second trace area; the plurality of the signal lines comprises first signal lines and second signal lines; the first signal lines are routed from the first trace area and the second trace area and are electrically coupled to the plug-in circuit board through the third trace area, the second signal lines routed along the back surface from the first trace area and the second trace area are arranged on the third trace area in a winding manner, and are routed from the third trace area and electrically coupled to the plug-in circuit board.
In a second aspect, the present disclosure provides a display device which may include a housing and the above-mentioned display backplane arranged in the housing.
In a third aspect, the present disclosure provides a tiled display device which may include a housing and a plurality of the above-mentioned display backplanes arranged in the housing, wherein the plurality of display backplanes are spliced together.
With the above display backplane, display device and tiled display device, since the first signal lines is routed from the first trace area and the second trace area and is electrically connected to the plug-in circuit board, the second signal lines are routed from the first trace area and the second trace area to be arranged on the third trace area in a winding manner along the back surface.
The exemplary embodiments of the present disclosure will be described in detail with reference to the accompanying drawings to make the aforesaid features and advantages of the present disclosure more clear to those skilled in the art. There are shown in the drawings:
The present disclosure is set forth in a detailed description accompanied with the drawings to provide a clearer and more accurate understanding. Exemplary embodiments of the present disclosure are illustrated in the Drawings, in which elements that are the same or of the same kind are marked by the same reference numerals. It can be understood that the scale shown in the drawings is not the scale of the actual implementation of the present disclosure, and is only for illustrative purposes, and is not drawn according to the original size.
A display backplane 6 in a first embodiment is schematically shown in
The plurality of micro LEDs 111 are in a matrix arrangement. The number of the micro LEDs 111 may be determined on the basis of the size of the micro LEDs 111 and the size of the backplane 1.
For example, when the size of a single micro LED 111 is 20 μm (i.e. micron), the distance between two adjacent micro LEDs 111 is 20 μm, the length and the width of the light-emitting area 11 at the front surface 88 are 50 cm and 32 cm respectively, and the area of the light-emitting area 11 is 1600 cm2, the number of the micro LEDs 111 within the light-emitting area 11 is 40 million. When each micro LED 111 is provided with two signal lines 3, the number of the signal lines 3 is 80 million.
It should be understood that the foregoing is only an example and not a limitation.
Optionally, the plug-in circuit board 2 is arranged at one end of the third trace area 14 away from the light-emitting area 11 and electrically connected to the signal lines 3 of the micro LEDs 111. A drive circuit board 100 is connected to one end of the plug-in circuit board 2 away from the light-emitting area 11. The drive circuit board 100 is configured to control the micro LEDs 111.
Optionally, plug-in circuit board 2 is a flexible circuit board for coupling the display backplane 6 to the drive circuit board 100.
The plurality of signal lines 3 include first signal lines 31 and second signal lines 32. The first signal lines 31 are routed from the first trace area 12 and the second trace area 13 and electrically connected to the plug-in circuit board 2. The second signal lines 32 are routed along the back surface from the first trace area 12 and the second trace area in a winding manner to be arranged at the third trace area 14; further, they are routed from the third trace area 14 and electrically connected to the plug-in circuit board 2.
Optionally, the number of the signal lines may be configured on the basis of actual requirements, which is not specifically limited here.
Optionally, the areas of the first trace area 12 and the second trace area 13 are identical. For example, when the length and the width of the first trace area 12 are 32 cm and 2 cm respectively, and the length and the width of the second trace area 13 are also 32 cm and 2 cm respectively, the areas of the first trace area 12 and the second trace area 13 are both 64 cm2.
It should be understood that the foregoing is only an example and not a limitation.
Optionally, the first trace area 12 includes a first sub-area 121 and a second sub-area 122. The first sub-area 121 is close to one side of the plug-in circuit board 2, and the second sub-area 122 is away from one side of the plug-in circuit board 2. The first sub-area 121 is coupled to the second sub-area 122. The second trace area 13 includes a third sub-area 131 and a fourth sub-area 132. The third sub-area 131 is close to one side of the plug-in circuit board 2, and the fourth sub-area 132 is away from one side of the plug-in circuit board 2. The third sub-area 131 is coupled to the fourth sub-area 132. Specifically, the first signal lines 31 are arranged at the first sub-area 121 and the third sub-area 131; and the second signal lines 32 are arranged at the second sub-area 122 and the fourth sub-area 132, and are wound to the back surface from the second sub-area 122 and the fourth sub-area 132.
The second sub-area 122 and the fourth sub-area 133 each are provided with a first contact 4. The first contact 4 in the second sub-area 122 and the first contact 4 in the fourth sub-area 132 are arranged away from one side of the second sub-area 122 and the fourth sub-area 132 away from light-emitting area 11. The second signal lines 32 are turned to the back surface from the first contact 4. The first sub-area 121 and the third sub-area 131 each are provided with a second contact 5 which is close to one side of the plug-in circuit board 2. The second signal lines 32 are arranged at the front surface from the back surface in a winding manner via the second contact 5.
In this embodiment, the first contact 4 is an adhesive layer 41, and the second signal lines 32 in the second sub-area 122 and the fourth sub-area 132 are configured as a golden finger coupled to the adhesive layer 41. The second signal lines 32 are turned over to the back surface through the adhesive layer 41 and are fitted into the back surface. Correspondingly, the second signal lines 32 are routed from one end of the first sub-area 121 and the third sub-area 131 which is away from the second sub-area 122 and the fourth sub-area 132 to be arranged on the front surface 88 in a winding manner and are routed to the third trace area 14 to electrically couple to the plug-in circuit board 2. The first signal lines 31 are routed to the first sub-area 121 and the third sub-area 131. The first signal lines 31 in the first sub-area 121 and the third sub-area 131 are routed to the third trace area 14 from the front surface 88, and are electrically coupled to the plug-in circuit board 2.
In this embodiment, the signal lines 32 in the second sub-area 122 and the fourth sub-area are arranged on the back surface in a winding manner, thereby reducing the trace of the second sub-area 122 and the fourth sub-area 132 on the front surface 88; on this respect, the width of the first trace area 12 as well as that of the second trace area 13 can be set smaller. Further, the border of the display backplane can be narrowed, hence improving the display effect.
Optionally, the golden finger may be, but not limited to, a material with copper as the main component. In some implementable embodiments, the golden finger may also be made of gold plating.
A display backplane 61 in a second embodiment is schematically shown in
Optionally, both the first conductive hole 42 and the second conductive hole 51 are filled with conductive material. The conductive material can be, but is not limited to, a material whose main component is metal. In some implementable embodiments, the conductive material may also be selected from a group comprising: metal elements, alloys (copper alloys, aluminum alloys, etc.), composite metals, and other special-purpose conductive materials that do not take conductivity as the main function. Commonly used conductive fillers may include nickel-coated graphite powder, nickel-coated carbon fiber carbon black, metal powder, metal foil, metal fiber, and carbon fiber. The electrical properties of conductive materials are mainly represented by electrical resistivity.
The factors that affect the electrical resistivity may include temperature, impurity content, cold deformation, heat treatment and so on. The influence of temperature may often be represented by the temperature coefficient of the resistivity of conductive materials. Except at the temperature close to the melting point and ultra-low temperature, the electrical resistivity has a linear relationship with temperature in a general temperature range.
Optionally, the first conductive holes 42 and the second conductive holes 51 may be, but not limited to, conductive holes made by etching or laser, and the first conductive holes 42 and the second conductive holes 51 are filled with conductive materials. In this respect, the front surface 88 and the back surface are electrically coupled via the first conductive holes 42 and the second conductive holes 51.
Optionally, the conductive material can be, but is not limited to, a material whose main component is metal. In some implementable embodiments, the conductive material may also be selected from a group comprising: an alloy material, a composite metal material, and a special function conductive material. The electrical properties of conductive materials are mainly represented by electrical resistivity. The factors that affect the electrical resistivity may include temperature, impurity content, cold deformation, heat treatment and so on. The influence of temperature may often be represented by the temperature coefficient of the resistivity of conductive materials. Except at the temperature close to the melting point and ultra-low temperature, the electrical resistivity has a linear relationship with temperature in a general temperature range.
A display backplane in a third embodiment is schematically shown in
A display backplane 63 in a fourth embodiment is schematically shown in
Optionally, both the first contact 4 and the second contact 5 are configured as an adhesive layer 41.
It should be noted that the other structures of the display backplane 63 in the fourth embodiment are similar to those in the first embodiment, which will not be repeated here.
A display backplane 64 in a fifth embodiment is schematically shown in
A display backplane 65 in a sixth embodiment is schematically shown in
It should be noted that the other structures of the display backplane 65 in the sixth embodiment are similar to those of the display backplane 63 in the fourth embodiment, which will not be repeated here.
Optionally, the first sub-area 121, the second sub-area 122, the third sub-area 131, and the fourth sub-area 132 have the same size; and the first sub-area 121, the second sub-area 122, the third sub-area 131, and the fourth sub-area 132 have the same number of the signal lines.
In some implementable embodiments, the number of the signal lines arranged in the second sub-area 122 and the fourth sub-area 132 may be larger than that in the first sub-area 121 and the second sub-area 122. For example, the number of the second sub-area 122 and that of the fourth sub-area 132 are equal, the number of the signal lines in the second sub-area 122 and the fourth sub-area 132 accounts for ⅔, ¾, etc. of all signal lines, which will not be limited here. In some implementable embodiments, the width of the first sub-area 121 and that of the second sub-area 122 are identical, the width of the third sub-area 131 and that of the fourth sub-area 132 are also identical but smaller than the width of the first sub-area 121 and that of the second sub-area 122. The number of the signal lines arranged in the first sub-area 121 and the third sub-area 131 accounts for ⅔, ¾, etc. of all signal lines. It can be understood that the signal lines in each area can be set according to actual conditions, and are not limited to the above examples.
A display device 7 having the display backplane mentioned in a first embodiment is schematically shown in
A tiled display device 8 having the display device mentioned in a first embodiment is schematically shown in
Obviously, those skilled in the art can make various changes and modifications to the embodiments of the present disclosure without departing from the spirit and scope of the present disclosure. In this way, if these modifications and variations of the present disclosure fall within the scope of the claims of the present disclosure and equivalent technologies, the present disclosure is also intended to include these changes and modifications.
The above-listed are only the exemplary embodiments of the present disclosure, and of course cannot be used to limit the scope of rights of the present disclosure. Therefore, equivalent changes made in accordance with the claims of the present disclosure still fall within the scope of the present disclosure.
Number | Date | Country | Kind |
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202010049559.9 | Jan 2020 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/CN2020/076062 | 2/20/2020 | WO |