RU2774674C1 - Display panel and display device - Google Patents

Abstract

FIELD: display technology.

SUBSTANCE: invention relates to display panels and display devices. The result is achieved by the fact that the display panel includes the first color sub-pixel, the second color sub-pixel and a pixel-bounding layer. The pixel-bounding layer includes many holes, the first color sub-pixel includes the first effective light-emitting region, the second color sub-pixel includes the second effective light-emitting region, the area of the second effective light-emitting region is smaller than the area of the first effective light-emitting region. The first color sub-pixels include the first color light-emitting layer located in the hole and on the pixel-bounding layer, the second color sub-pixels include the second color light-emitting layer located in the hole and on the pixel-bounding layer, and the ratio of the areas between the orthogonal projections of the first color light-emitting layer and the first effective light-emitting region on the base substrate is less, than is the ratio of the areas between the orthogonal projections of the second color light-emitting layer and the second effective light-emitting region on the base substrate. In the embodiment of the present disclosure, the area ratios between the light-emitting layers and the effective light-emitting regions of the various colored sub-pixels are different to ensure that the deviation caused by the evaporation process was more balanced for each sub-pixel.

EFFECT: increase in the display quality of organic light-emitting display devices.

37 cl, 41 dwg

Description

The technical field to which the invention belongs

At least one embodiment of the present disclosure relates to a display panel and a display device.

State of the art

Organic light emitting display devices are considered as next-generation display technology with great development prospects due to their advantages of light weight and thickness, flexibility, low power consumption, wide color gamut and high contrast, etc. At present, the focus of research on organic light emitting display devices is focused on how to improve the display quality of organic light emitting display devices.

Disclosure of the essence of the invention

At least an embodiment of the present disclosure provides a display panel and a display device.

At least an embodiment of the present disclosure provides a display panel comprising: a base substrate and multiple first color sub-pixels, multiple second color sub-pixels, multiple third color sub-pixels, and a pixel-bounding layer on the base substrate. The display panel includes a display area and a peripheral area located on the periphery of the display area; multiple first color subpixels are arranged in the display area, multiple first color subpixels are arranged in the first direction to form multiple rows of first color subpixels, multiple rows of first color subpixels are arranged in the second direction, and adjacent rows of first color subpixels in the multiple rows of first color subpixels are offset from each other. friend in the first direction; multiple second color subpixels are arranged in the display area and arranged in an array in the first direction and the second direction, and four second color subpixels surround one first color subpixel; the pixel limiting layer is located in the display area and the peripheral area, the pixel limiting layer contains multiple holes for forming effective light emitting regions of multiple subpixels, the plurality of first color subpixels contain multiple first effective light emitting regions, the plurality of second color subpixels contain multiple second effective light emitting regions, and an area of one of the plurality of second effective light emitting regions is less than the area of one of the plurality of first effective light emitting regions. Numerous first color subpixels contain multiple first color light emitting layers located in the respective holes and on the pixel limiting layer surrounding the respective holes, numerous second color subpixels contain multiple second color light emitting layers located in the respective holes and on the pixel limiting layer surrounding the respective holes, the plurality of first color light emitting layers included in the plurality of first color subpixels are spaced apart from each other, and the plurality of second color light emitting layers included in the plurality of second color subpixels are spaced apart from each other; the area ratio between the orthogonal projections of the first color light emitting layer and the first effective light emitting area corresponding to the same first color subpixel on the base substrate is the first area ratio, the area ratio between the orthogonal projections of the second color light emitting layer and the second effective light emitting area corresponding to one and the same second color subpixel on the base substrate is the second area ratio, and the first area ratio is less than the second area ratio.

For example, in an embodiment of the present disclosure, the first area ratio and the second area ratio are between 1 and 15.

For example, in an embodiment of the present disclosure, the first area ratio and the second area ratio are in the range of 4 to 6.

For example, in an embodiment of the present disclosure, the first area ratio and the second area ratio are in the range of 6 to 8.

For example, in an embodiment of the present disclosure, the first area ratio is in the range of 2 to 6.

For example, in an embodiment of the present disclosure, the first area ratio is in the range of 1.5 to 3.

For example, in an embodiment of the present disclosure, the second area ratio is in the range of 4 to 9.

For example, in an embodiment of the present disclosure, the second area ratio is in the range of 6.5 to 8.

For example, in an embodiment of the present disclosure, at least a portion of the plurality of second effective light emitting regions has a length direction and a width direction, the length direction is the extension direction of the connecting line between the two most distant points from each other in one of the plurality of second effective light emitting regions, and the width direction substantially perpendicular to the length direction of one of the plurality of second effective light emitting regions; for one second effective light emitting area in the length direction, the ratio of the maximum size of the second color light emitting layer corresponding to the second effective light emitting area to the maximum size of the second effective light emitting area is the first ratio, and in the width direction, the ratio of the maximum size of the second color light emitting layer corresponding to the second effective light emitting region to the maximum size of the second effective light emitting region is the second ratio, and the first ratio is smaller than the second ratio.

For example, in an embodiment of the present disclosure, for the same second effective light emitting region, in the length direction, the difference between the maximum size of the second color light emitting layer and the maximum size of the second effective light emitting region is the first difference, and in the width direction, the difference between the maximum size of the second color light emitting layer and the maximum size of the second effective light emitting area is the second difference, and the first difference is smaller than the second difference.

For example, in an embodiment of the present disclosure, the ratio of the maximum size of the second color light emitting layer in the length direction of the corresponding second effective light emitting region to the maximum size of the second color light emitting layer in the width direction of the corresponding second effective light emitting region is less than the ratio of the maximum size of the second effective light emitting region in the direction its length to the maximum size of the second effective light emitting region in its width direction.

For example, in an embodiment of the present disclosure, the display panel further comprises: multiple third color subpixels located in the display area, wherein the multiple first color subpixels and the multiple third color subpixels are arranged alternately in the first direction and the second direction, the multiple first color subpixels, and the multiple second color subpixels are alternately arranged in the third direction as a first group, the plurality of third color subpixels and the plurality of second color subpixels are alternately arranged in the third direction as a second group, the first group and the second group are alternately arranged in the fourth direction, and the third direction and the fourth direction intersect as the first direction, and with the second direction. The multiple third color subpixels comprise multiple third effective light emitting regions, wherein the area of one of the multiple second effective light emitting regions is smaller than the area of one of the multiple third effective light emitting regions, the multiple third color subpixels comprise multiple third color light emitting layers disposed in the respective apertures and on the bounding the pixels of the layer surrounding the respective holes and the multiple third color light emitting layers included in the multiple third color subpixels are spaced apart from each other, the area ratio between the orthogonal projections of the third color light emitting layer and the third effective light emitting region corresponding to the same third color subpixel, onto the base substrate is a third area ratio, and the third area ratio is less than the second area ratio.

For example, in an embodiment of the present disclosure, the area of the first effective light emitting region of one of the plurality of first color subpixels is smaller than the area of the third effective light emitting region of one of the plurality of third color subpixels, and the first area ratio is greater than the third area ratio.

For example, in an embodiment of the present disclosure, the third area ratio ranges from 1 to 15.

For example, in an embodiment of the present disclosure, the third area ratio is in the range of 1.5 to 7.

For example, in an embodiment of the present disclosure, the third area ratio is in the range of 2 to 3.

For example, in an embodiment of the present disclosure, the third area ratio is in the range of 3 to 4.

For example, in an embodiment of the present disclosure, the first color light emitting layer and the second color light emitting layer, which are placed in the third direction and are adjacent to each other, overlap each other, and the second color light emitting layer and the third color light emitting layers, which are placed in the third direction and are adjacent to each other, overlap each other.

For example, in an embodiment of the present disclosure, the overlapping portion between the first color light emitting layer of one first color subpixel and the light emitting layers of other subpixels is the first overlapping portion, the overlapping portion between the third color light emitting layer of one third color subpixel and the light emitting layers of other subpixels is the second overlapping portion , and the overlapping portion between the second color light emitting layer of one second color subpixel and the light emitting layers of the other subpixels is the third overlapping portion. The area ratio between the orthogonal projections of the first overlapping part and the first color light emitting layer onto the base substrate, and the area ratio between the orthogonal projections of the second overlapping part and the third color light emitting layer onto the base substrate is smaller for both of both than the ratio of the areas between the orthogonal projections of the third overlapping part and the second color light emitting layer onto the base substrate.

For example, in an embodiment of the present disclosure, the first color light emitting layer and the third color light emitting layer, which are adjacent to each other, do not overlap; or the overlap area between the first color light emitting layer and the third color light emitting layer, which are adjacent to each other, is smaller than the overlap area between the first color light emitting layer and the second color light emitting layer, which are adjacent to each other, and the overlap area between a second color light emitting layer and a third color light emitting layer that are adjacent to each other.

For example, in an embodiment of the present disclosure, the width of the pixel limiting layer in the third direction, which is between the first effective light emitting region and the second effective light emitting region, which are adjacent to each other, is in the range of 15 to 25 μm; the pixel-limiting layer comprises a first surface spaced from the base substrate and between the first effective light emitting region and the second effective light emitting region, which are adjacent to each other, in a plane parallel to the base substrate, and in the third direction, a part of the first surface coated with the first colored light emitting layer , is 0.3-0.8 of the width of the pixel-bounding layer, the part of the first surface covered with the second color light-emitting layer is 0.3-0.8 of the width of the pixel-bounding layer.

For example, in an embodiment of the present disclosure, the edge region of the light emitting layer of each subpixel comprises an annular region, the width of the annular region of the annular region is a; the width of the portion of the pixel limiting layer, between the first effective light emitting region and the second effective light emitting region, which are adjacent to each other, is a', the width, in the third direction, of the overlapping portion of the first light emitting layer and the second light emitting layer, which are adjacent to each other is equal to o1, and o1≥a and o1<(0.5*a')-a; the width of the portion of the pixel limiting layer between the third effective light emitting region and the second effective light emitting region that are adjacent to each other is a', the size, in the fourth direction, of the overlapping portion of the third color light emitting layer and the second color light emitting layer that are adjacent to each other with the other is o2, o2≥a and o2<(0.5*a')-a, and a is in the range from 1 to 4 microns.

For example, in an embodiment of the present disclosure, the thickness of the annular region of each light emitting layer is less than or equal to 90% of the thickness of the central region of the corresponding light emitting layer.

For example, in an embodiment of the present disclosure, each of the plurality of subpixels further comprises a first electrode and a second organic light emitting element electrode, a second organic light emitting element electrode located on the side of the light emitting layer of the organic light emitting element and the pixel limiting layer facing the base substrate, the second organic light emitting element electrode contains a main base electrode in each of the numerous subpixels, and in the direction from the center of the effective light emitting region to the edge of the effective light emitting region, the size of the overlapping part between the main base electrode and the pixel limiting layer does not exceed the size of the overlapping part between the light emitting layer and the pixel limiting layer.

For example, in an embodiment of the present disclosure, the display panel further comprises: multiple third color subpixels located in the display area, wherein the multiple first color subpixels and the multiple third color subpixels are arranged alternately in the first direction and the second direction, the multiple first color subpixels, and the multiple second color subpixels are alternately arranged in the third direction as a first group, the plurality of third color subpixels and the plurality of second color subpixels are alternately arranged in the third direction as a second group, the first group and the second group are alternately arranged in the fourth direction, and the third direction and the fourth direction intersect as the first direction, and with the second direction. Numerous third color subpixels contain multiple third effective light emitting areas, multiple third color subpixels contain multiple third color light emitting layers located in the respective holes and on the pixel limiting layer surrounding the respective holes, and multiple third color light emitting layers included in the multiple third color subpixels, spaced apart from each other, the display panel further comprises: an encapsulating layer located in the display area and the peripheral area; a first sensor electrode layer located on the side of the encapsulating layer remote from the base substrate, wherein the first sensor electrode layer comprises multiple first sensor electrodes extending in a first direction and multiple second sensor electrodes extending in a second direction, each of the multiple first sensor electrodes comprising multiple first sensor electrodes, each of the multiple second sensor electrodes contains multiple second sensor electrodes, the layer of first sensor electrodes contains multiple lines of sensor electrodes, multiple lines of sensor electrodes intersect to form a plurality of first cells, both from each block of first sensor electrodes and each block of second sensor electrodes the electrodes contain numerous first cells connected to each other; second sensor electrode layer containing multiple connecting jumpers, wherein the second sensor electrode layer contains multiple jumpers, multiple jumpers intersect to form multiple second cells, each of the multiple connecting jumpers contains multiple second cells connected to each other and adjacent blocks of second sensor electrodes electrically connected through at least one connecting jumper; a sensor insulating layer located between the layer of the first sensor electrodes and the layer of the second sensor electrodes, and the block of the second sensor electrodes, electrically connected to the connecting jumper through a through hole passing through the sensor insulating layer, an orthogonal projection of a plurality of lines of sensor electrodes in the display area onto the base substrate are located within the orthogonal projection of the pixel-limiting layer onto the base substrate.

For example, in an embodiment of the present disclosure, in the display area, more than 80% of the orthogonal projection of the center line of each segment of the pixel-bounding layer and in the direction of the continuation of the corresponding segment onto the base substrate is located in the orthogonal projection of the sensor electrode line onto the base substrate.

For example, in an embodiment of the present disclosure, spaces are provided between the first color light emitting layer, the second color light emitting layer, and the third color light emitting layer that are adjacent to each other, the first color light emitting layer having a shape including a first rounded rectangle and a first protruding portion located at the rounded corner of the first rounded rectangle and protruding towards the gap, the first protruding portion at least partially protrudes from the extension line of the straight edge of the first rounded rectangle adjacent to the second color light emitting layer; the third color light emitting layer has a shape containing a third rounded rectangle and a second protruding section located in the rounded corner of the third rounded rectangle and protruding towards the gap, and the second protruding section at least partially protrudes from the extension line of the straight edge of the third rounded rectangle located next to the second colored light emitting layer, the orthogonal projections of the first protruding portion and the second protruding portion onto the base substrate are at least partially overlapped by the orthogonal projection of the line of the sensor electrodes onto the base substrate.

For example, in an embodiment of the present disclosure, in the display area, an orthogonal projection of more than 50% of the line of the sensor electrodes onto the base substrate is located within the orthogonal projection of the overlapping portion of the light emitting layer onto the base substrate, and the overlapping portion of the light emitting layer comprises an overlapping portion of at least two, selected from the group consisting of the first color light emitting layer, the second color light emitting layer and the third color light emitting layer.

For example, in an embodiment of the present disclosure, in a display area, the orthogonal projection of the effective light emitting area of each of the plurality of subpixels onto the base substrate is within the orthogonal projection of each of the plurality of first cells onto the base substrate; the ratio of the open area of the first cell corresponding to the first color subpixel to the area of the first effective light emitting area, and the ratio of the open area of the first cell corresponding to the third color subpixel to the area of the third effective light emitting area is less than the ratio of the opening area of the first cell corresponding to the second color subpixel, to the area of the second effective light emitting region.

For example, in an embodiment of the present disclosure, each of the plurality of subpixels further comprises a first electrode and a second electrode of the organic light emitting element, the second electrode of the organic light emitting element is located on the side of the light emitting layer of the organic light emitting element and the pixel limiting layer facing the base substrate, each of the plurality of subpixels further contains a pixel circuit between the second electrode of the organic light emitting element and the base substrate, and the pixel circuit contains a driving transistor; at least one electrode selected from the group consisting of a second organic light emitting element electrode of the first color subpixel, a second organic light emitting element electrode of the second color subpixel, and a second organic light emitting element electrode of the third color subpixel is overlapped by a line of sensor electrodes; and/or the control transistor of at least one selected from the group consisting of: the first color sub-pixel, the second color sub-pixel and the third color sub-pixel, is covered by a line of sensor electrodes.

For example, in an embodiment of the present disclosure, the driving transistor in the second color subpixel is overlapped by the line of sensor electrodes, and the second electrode of the organic light emitting element of the second color subpixel is substantially not overlapped by the line of sensor electrodes; in the first color subpixel, the driving transistor is overlapped by the second organic light emitting element electrode but not substantially overlapped by the sensor electrode line, and the second organic light emitting element electrode is overlapped by the sensor electrode line; in the third color subpixel, the driving transistor is overlapped by the second organic light emitting element electrode but not substantially overlapped by the sensor electrode line, and the second organic light emitting element electrode is overlapped by the sensor electrode line.

For example, in an embodiment of the present disclosure, in the second color subpixel, both the second organic light emitting element electrode and the driving transistor are overlapped by a line of sensor electrodes; in the first color sub-pixel, both the second electrode of the organic light emitting element and the driving transistor are not substantially overlapped by the sensor electrode line; and in the third color subpixel, both the second organic light emitting element electrode and the driving transistor do not substantially overlap with the sensor electrode line.

For example, in an embodiment of the present disclosure, in the second color subpixel, both the second organic light emitting element electrode and the driving transistor are not substantially overlapped by the sensor electrode line; in the first color subpixel, both the second electrode of the organic light emitting element and the driving transistor are overlapped by a line of sensor electrodes; and in the third color subpixel, both the second electrode of the organic light emitting element and the driving transistor are overlapped by a line of sensor electrodes.

For example, in an embodiment of the present disclosure, in the first color subpixel, the second electrode of the organic light emitting element is not covered by the driving transistor or the sensor electrode line, and the driving transistor is covered by the sensor electrode line; in the third color subpixel, the second electrode of the organic light emitting element is not overlapped by the driving transistor or the sensor electrode line, and the driving transistor is overlapped by the sensor electrode line; in the second color sub-pixel, the second electrode of the organic light emitting element is covered by the driving transistor and the sensor electrode line, and the driving transistor is covered by the sensor electrode line.

For example, in an embodiment of the present disclosure, the pixel circuit of each of the multiple subpixels further comprises a data recording transistor and a threshold compensation transistor; the first electrode of the data recording transistor is electrically connected to the first electrode of the control transistor, the second electrode of the data recording transistor is electrically connected to the data line to receive the data signal, and the gate electrode of the data recording transistor is electrically connected to the scan signal line to receive the scan signal; the first electrode of the threshold compensation transistor is electrically connected to the second electrode of the threshold compensation transistor, the second electrode of the threshold compensation transistor is electrically connected to the gate electrode of the driving transistor, and the gate electrode of the threshold compensation transistor is electrically connected to the scan signal line to receive the compensation control signal; the pixel circuit data recording transistor of at least one selected from the group consisting of the first color sub-pixel, the second color sub-pixel and the third color sub-pixel is overlapped by the sensor electrode line, and/or the pixel circuit threshold compensation transistor of at least one selected from the group, consisting of the first color sub-pixel, the second color sub-pixel and the third color sub-pixel, is overlapped by a line of sensor electrodes.

For example, in an embodiment of the present disclosure, in the first color subpixel, the second electrode of the organic light emitting element is overlapped by at least one of the threshold compensation transistor and the data recording transistor, and neither the threshold compensation transistor nor the data recording transistor is overlapped by the sensor electrode line; in the third color subpixel, the second electrode of the organic light emitting element is covered by at least one of the threshold compensation transistor and the data recording transistor, and neither the threshold compensation transistor nor the data recording transistor is covered by the sensor electrode line; and in the second color subpixel, the second electrode of the organic light emitting element is not covered by the threshold compensation transistor or the data recording transistor, and at least one of the threshold compensation transistor and the data recording transistor is covered by the sensor electrode line.

For example, in an embodiment of the present disclosure, in the first color subpixel, the second electrode of the organic light emitting element is covered by at least one of a threshold compensation transistor and a data recording transistor; in the third color subpixel, the second electrode of the organic light emitting element is covered by at least one of the threshold value compensation transistor and the data recording transistor; and in the second color subpixel, the second electrode of the organic light emitting element is covered by the threshold compensation transistor, and the data recording transistor is covered by the sensor electrode line.

For example, in an embodiment of the present disclosure, the display panel further comprises: multiple third color subpixels located in the display area, wherein the multiple first color subpixels and the multiple third color subpixels are alternately arranged in the first direction and the second direction, the multiple first color subpixels, and the multiple second color subpixels are alternately arranged in the third direction as a first group, the plurality of third color subpixels and the plurality of second color subpixels are alternately arranged in the third direction as a second group, the first group and the second group are alternately arranged in the fourth direction, and the third direction and the fourth direction intersect as the first direction, and with the second direction. The display panel further comprises a plurality of spacers located on the surface of the pixel-bounding layer remote from the base substrate, and spacers in the display area are located in spaces between subpixels placed in the first direction, and spacers in the display area are spaced in spaces between subpixels placed in the second direction. . In the display area, the area ratio K between the separator and the pixel-bounding layer satisfies the inequality K ≤ S0/[k1*n*m*(S1 _G -S2 _G )+k2*n*m*(S1 _R -S2 _R )+k3*n *m*(S1 _B - S2 _B )], where n is the number of middle subpixels in one line, which are located between adjacent separators among the separators placed in the first direction, m is the number of middle subpixels in the same line, which is located between adjacent separators among the separators placed in the second direction, S0 is the area of one separator; S1 _G , S1 _R and S1 _B are areas of light-emitting layers of the second color sub-pixel, the first color sub-pixel and the third color sub-pixel, respectively; S2 _G , S2 _R and S2 _B are the aperture areas of the pixel-bounding layer corresponding to the second color sub-pixel, the first color sub-pixel and the third color sub-pixel, respectively; and k1, k2, and k3 are the proportions of the second color subpixels, the first color subpixels, and the third color subpixels in the display area with respect to all subpixels, respectively.

For example, in an embodiment of the present disclosure, the area ratio between the orthogonal projection of the separators onto the base substrate and the orthogonal projection of the pixel-bounding layer onto the base substrate does not exceed 8%.

For example, in an embodiment of the present disclosure, in the display area, the numerical ratio between separators and all subpixels does not exceed 1:16.

For example, in an embodiment of the present disclosure, four second color subpixels are placed between adjacent spacers in the second direction, and two first color subpixels and two third color subpixels are placed between adjacent subpixels in the first direction; or six second color subpixels are placed between adjacent spacers in the second direction, and three first color subpixels and three third color subpixels are placed between adjacent spacers in the first direction; or four second color subpixels are placed between adjacent spacers in the second direction, and three first color subpixels and three third color subpixels are placed between adjacent spacers in the first direction; or six second color subpixels are placed between adjacent spacers in the second direction, and two first color subpixels and two third color subpixels are placed between adjacent spacers in the first direction.

For example, in an embodiment of the present disclosure, each spacer comprises a first region and a second annular region surrounding the first region. The first region contains a central region separators, and the area ratio between the orthogonal projections of the first region and the separators onto the base substrate does not exceed 1/4; in the display area, the first area of the at least one spacer is not overlapped by any of the first color light emitting layer, the second color light emitting layer, or the third color light emitting layer; or the first region of the at least one spacer is covered by only one type of color light emitting layer.

For example, in an embodiment of the present disclosure, the display panel further comprises: an encapsulating layer located in the display area and the peripheral area; a first sensor electrode layer located on the side of the encapsulating layer remote from the base substrate, wherein the first sensor electrode layer comprises multiple first sensor electrodes extending in a first direction and multiple second sensor electrodes extending in a second direction, each first sensor electrode comprising multiple first sensor electrodes, each second sensor electrode contains multiple second sensor electrodes, the layer of first sensor electrodes contains multiple lines of sensor electrodes, the multiple lines of sensor electrodes intersect to form multiple first cells, and both of each block of first sensor electrodes and each block of second sensor electrodes contain numerous associated with each other first cells; second sensor electrode layer containing multiple connecting jumpers, wherein the second sensor electrode layer contains multiple jumpers, multiple jumpers intersect to form multiple second cells, each connecting jumper contains multiple second cells connected to each other and adjacent blocks of second sensor electrodes electrically connected at least at least through one connecting jumper; a sensor insulating layer located between the first sensor electrode layer and the second sensor electrode layer, and the second sensor electrode unit is electrically connected to the connecting jumper through a through hole passing through the sensor insulating layer, in the display area, the jumper lines covering one second cell overlap no more than one delimiter.

For example, in an embodiment of the present disclosure, in the display area, the jumper lines of the second cells included in one connection jumper connecting adjacent second sensor electrode units are overlapped by no more than three separators, and all connection jumpers connecting adjacent second sensor electrode units are overlapped. up to four delimiters.

For example, in an embodiment of the present disclosure, the display panel further comprises: multiple third color subpixels located in the display area, wherein the multiple first color subpixels and the multiple third color subpixels are alternately arranged in the first direction and the second direction, the multiple first color subpixels, and the multiple second color subpixels are alternately arranged in the third direction as a first group, the plurality of third color subpixels and the plurality of second color subpixels are alternately arranged in the third direction as a second group, the first group and the second group are alternately arranged in the fourth direction, and the third direction and the fourth direction intersect as the first direction, and with the second direction. Numerous third color subpixels contain multiple third effective light emitting areas, multiple third color subpixels contain multiple third color light emitting layers located in the respective holes and on the pixel limiting layer surrounding the respective holes, and multiple third color light emitting layers included in the multiple third color subpixels, spaced apart from each other. Each of the multiple subpixels contains the first electrode and the second electrode of the organic light emitting element, the second electrode of the organic light emitting element is located between the base substrate and the first electrode of the organic light emitting element, each subpixel contains functional film layers between the first electrode and the second electrode of the organic light emitting element, an orthogonal projection of the functional film layers on the base substrate is overlapped by orthogonal projections of the first electrode and the second electrode of the organic light emitting element onto the base substrate, the total thickness of the functional film layers is less than the depth of the hole in the pixel-bounding layer corresponding to the subpixel, the functional film layers contain a light emitting layer, the light emitting layers of the subpixels contain the first color light emitting layers, second color light emitting layers and third color light emitting layers, total functional thickness the total thickness of the functional film layers between the first electrode and the second electrode of the organic light emitting element of the first color subpixel is greater than the total thickness of the functional film layers between the first electrode and the second electrode of the organic light emitting element of the second color subpixel, and the total thickness of the functional film layers between the first electrode and the second electrode of the organic light emitting element element of the second color subpixel is greater than the total thickness of the functional film layers between the first electrode and the second electrode of the organic light emitting element of the third color subpixel.

For example, in an embodiment of the present disclosure, the functional film layers between the first electrode and the second electrode of the organic light emitting element of each subpixel further comprise an auxiliary light emitting layer and the auxiliary light emitting layer, and the auxiliary light emitting layer is located between the light emitting layer and the second electrode of the organic light emitting element, the thickness of the auxiliary light emitting layer of the first color sub-pixel is larger than the thickness of the auxiliary light-emitting layer of the second color sub-pixel, and the thickness of the auxiliary light-emitting layer of the second color sub-pixel is larger than the thickness of the auxiliary light-emitting layer of the third color sub-pixel.

For example, in an embodiment of the present disclosure, each subpixel comprises a first electrode and a second electrode of an organic light emitting element, a second electrode is located between the base substrate and the first electrode, and the first electrode is an integral film layer in the display area. The display panel further comprises: an encapsulating layer located in the display area and the peripheral area; a first sensor electrode layer located on the side of the encapsulating layer remote from the base substrate, wherein the first sensor electrode layer comprises multiple first sensor electrodes extending in a first direction and multiple second sensor electrodes extending in a second direction, each first sensor electrode comprising multiple first sensor electrodes, each second sensor electrode contains multiple second sensor electrodes, the layer of first sensor electrodes contains multiple lines of sensor electrodes, the multiple lines of sensor electrodes intersect to form multiple first cells, and both of each block of first sensor electrodes and each block of second sensor electrodes contain numerous associated with each other first cells; second sensor electrode layer containing multiple connecting jumpers, wherein the second sensor electrode layer contains multiple jumpers, multiple jumpers intersect to form multiple second cells, each connecting jumper contains multiple second cells connected to each other and adjacent blocks of second sensor electrodes electrically connected at least at least through one connecting jumper; a sensor insulating layer located between the first sensor electrode layer and the second sensor electrode layer, and the second sensor electrode block electrically connected to the connecting bridge through a through hole passing through the sensor insulating layer. One of the first sensor electrode layer and the second sensor electrode layer, which is closer to the first electrode, is the sensor electrode near layer, in the display area, the total thickness of the insulating layer between the first electrode located in the effective light emitting region and the sensor electrode near layer is greater than the total thickness of the insulating layer between the first electrode located on the outer side of the effective light emitting region and the near layer of the sensor electrodes.

For example, in an embodiment of the present disclosure, the display panel further comprises: multiple third color subpixels located in the display area, wherein the multiple first color subpixels and the multiple third color subpixels are alternately arranged in the first direction and the second direction, the multiple first color subpixels, and the multiple second color subpixels are alternately arranged in the third direction as a first group, the plurality of third color subpixels and the plurality of second color subpixels are alternately arranged in the third direction as a second group, the first group and the second group are alternately arranged in the fourth direction, and the third direction and the fourth direction intersect as the first direction, and with the second direction. Numerous third color subpixels contain multiple third effective light emitting areas, multiple third color subpixels contain multiple third color light emitting layers located in the respective holes and on the pixel limiting layer surrounding the respective holes, and multiple third color light emitting layers included in the multiple third color subpixels, spaced apart from each other. Each of the plurality of subpixels includes a first electrode and a second organic light emitting element electrode, the second organic light emitting element electrode is located between the base substrate and the first organic light emitting element electrode. The pixel-bounding layer comprises multiple first bounding portions and multiple second bounding portions substantially extending in the first direction, the first bounding portions and the second bounding portions are alternately placed in the second direction, and in the second direction, the average heights of one first bounding portion and one second bounding portion, which are located on both sides of the same row of subpixels arranged in the first direction are different; the average heights of the multiple first bounding portions in the display area are approximately the same, the average heights of the multiple second bounding portions in the display area are approximately the same; the average height of the first boundary portion is the average height from the surface of the first boundary portion remote from the base substrate to the plane where the surface of the main base electrode of the second electrode is located, remote from the base substrate, and the average height of the second boundary portion is the average height from the surface of the second a boundary portion remote from the base substrate to a plane where the surface of the main base electrode of the second electrode is located, remote from the base substrate.

For example, in an embodiment of the present disclosure, the average height of one first boundary area is greater than the average height of the second boundary area, and the pixel boundary layer in the peripheral area is the third boundary area, the average height of the third boundary area is greater than the average height of the second boundary area.

For example, in an embodiment of the present disclosure, two adjacent rows of subpixels arranged in the second direction form a row of pixel blocks, and in the second direction, the average height of the first two bounding areas located on both sides of the same pixel block row is greater than the average height of the second bounding area. located between two sub-pixel rows in one row of pixel blocks.

For example, in an embodiment of the present disclosure, a pixel arrangement structure formed from multiple first color subpixels, multiple second color subpixels, and multiple third color subpixels contains multiple minimum repeat blocks arranged in a first direction, and each minimum repeat block contains one first color subpixel, one third color sub-pixel and two second color sub-pixels that are distributed in two sub-pixel rows; in the second direction, the first limiting areas are located on both sides of the minimum repeating blocks placed in the first direction, and the second limiting areas are located in the gap between two subpixel lines in which the minimum repeating blocks are distributed.

For example, in an embodiment of the present disclosure, the pixel-bounding layer comprises a flat area and a sloped area, the sloped area surrounds each aperture, and the sloped area includes a first sloped sub-region located adjacent to the flat portion and a second sloped sub-region located away from the flat area. In the third direction or the fourth direction, the aspect ratio between the orthogonal projections of the first inclined sub-section and the second inclined sub-section onto the base substrate does not exceed 1/4, and the average inclination angle of the first inclined sub-section is less than the average inclination angle of the second inclined sub-section.

For example, in an embodiment of the present disclosure, the first color subpixel is a red subpixel, the second color subpixel is a green subpixel, and the third color subpixel is a blue subpixel.

At least one embodiment of the present disclosure provides a display panel that includes: a base substrate and multiple first color sub-pixels, multiple second color sub-pixels, and a pixel-bounding layer on the base substrate. The display panel includes a display area and a peripheral area located on the periphery of the display area; multiple first color subpixels are arranged in the display area, multiple first color subpixels are arranged in the first direction to form multiple rows of first color subpixels, multiple rows of first color subpixels are arranged in the second direction, and adjacent rows of first color subpixels in the multiple rows of first color subpixels are offset from each other. friend in the first direction; multiple second color subpixels are arranged in the display area and arranged in an array in the first direction and the second direction, and four second color subpixels surround one first color subpixel; the pixel limiting layer is located in the display area and the peripheral area, the pixel limiting layer contains multiple holes for forming effective light emitting areas of multiple subpixels, the multiple first color subpixels include multiple first effective light emitting areas, the multiple second color subpixels include multiple second effective light emitting areas, the light output of the first color subpixel is less than the light output of the second color subpixel. Numerous first color subpixels contain multiple first color light emitting layers located in the respective holes and on the pixel limiting layer surrounding the respective holes, numerous second color subpixels contain multiple second color light emitting layers located in the respective holes and on the pixel limiting layer surrounding the respective holes, the plurality of first color light emitting layers included in the plurality of first color subpixels are spaced apart from each other, and the plurality of second color light emitting layers included in the plurality of second color subpixels are spaced apart from each other; the area ratio between the orthogonal projections of the first color light emitting layer and the first effective light emitting area corresponding to the same first color subpixel on the base substrate is the first area ratio, the area ratio between the orthogonal projections of the second color light emitting layer and the second effective light emitting area corresponding to one and the same second color subpixel on the base substrate is the second area ratio, and the first area ratio is less than the second area ratio.

For example, in an embodiment of the present disclosure, the display panel further comprises: plurality of third color subpixels located in the display area, plurality of first color subpixels and plurality of third color subpixels alternately arranged in the first direction and second direction, plurality of first color subpixels and plurality of second color subpixels in turn arranged in the third direction as a first group, wherein the plurality of third color subpixels and the plurality of second color subpixels are alternately arranged in the third direction as a second group, the first group and the second group are alternately arranged in the fourth direction, and the third direction and the fourth direction intersect as with the first direction, and with the second direction. The plurality of third color subpixels comprise a plurality of third effective light emitting regions, the light output of the first color subpixel is less than that of the second color subpixel; the plurality of third color sub-pixels comprise the plurality of third color light-emitting layers located in the respective holes and on the pixel-limiting layer surrounding the respective holes, and the plurality of third color light-emitting layers included in the plurality of third color sub-pixels are spaced apart from each other. The area ratio between the orthogonal projections of the third color light emitting layer and the third effective light emitting region corresponding to the same third color subpixel onto the base substrate is a third area ratio, and the third area ratio is less than the second area ratio.

For example, in an embodiment of the present disclosure, the light output of the first color subpixel is greater than the light output of the third color subpixel, and the first area ratio is greater than the third area ratio.

For example, in an embodiment of the present disclosure, the ratio of the aperture ratio of the first color subpixel to the aperture ratio of the second color subpixel is in the range of 0.5 to 1.6.

For example, in an embodiment of the present disclosure, the ratio of the aperture ratio of the second color subpixel to the aperture ratio of the third color subpixel is approximately 1:(1.1~1.9).

At least an embodiment of the present disclosure provides a display panel that includes: a base substrate and multiple first color sub-pixels, multiple second color sub-pixels, multiple third color sub-pixels, and a pixel-bounding layer on the base substrate. The display panel includes a display area and a peripheral area located on the periphery of the display area; multiple first color subpixels are arranged in the display area, multiple first color subpixels are arranged in the first direction to form multiple rows of first color subpixels, multiple rows of first color subpixels are arranged in the second direction, and adjacent rows of first color subpixels in the multiple rows of first color subpixels are offset from each other. friend in the first direction; multiple second color subpixels are arranged in the display area and arranged in an array in the first direction and the second direction, and four second color subpixels surround one first color subpixel; multiple third color subpixels are arranged in the display area, multiple first color subpixels and multiple third color subpixels are alternately arranged in the first direction and the second direction, multiple first color subpixels and multiple second color subpixels are alternately arranged in the third direction as a first group, multiple third color subpixels and the plural second color subpixels are alternately arranged in the third direction as a second group, the first group and the second group are alternately arranged in the fourth direction, and the third direction and the fourth direction intersect with both the first direction and the second direction. The pixel limiting layer is located in the display area and the peripheral area, the pixel limiting layer contains multiple holes for forming effective light emitting areas of multiple subpixels. Each of the plurality of subpixels includes a first electrode and a second organic light emitting element electrode, the second organic light emitting element electrode is located between the base substrate and the first organic light emitting element electrode. The pixel-bounding layer comprises multiple first bounding portions and multiple second bounding portions substantially extending in the first direction, the first bounding portions and the second bounding portions are alternately placed in the second direction, and in the second direction, the average heights of one first bounding portion and one second bounding portion, which are located on both sides of the same row of subpixels arranged in the first direction are different; the average heights of the multiple first bounding portions in the display area are approximately the same, the average heights of the multiple second bounding portions in the display area are approximately the same; the average height of the first boundary portion is the average height from the surface of the first boundary portion remote from the base substrate to the plane where the surface of the main base electrode of the second electrode is located, remote from the base substrate, and the average height of the second boundary portion is the average height from the surface of the second a boundary portion remote from the base substrate to a plane where the surface of the main base electrode of the second electrode is located, remote from the base substrate.

For example, in an embodiment of the present disclosure, the average height of one first boundary area is greater than the average height of the second boundary area, and the pixel boundary layer in the peripheral area is the third boundary area, the average height of the third boundary area is greater than the average height of the second boundary area.

For example, in an embodiment of the present disclosure, two adjacent rows of subpixels arranged in the second direction form a row of pixel blocks, and in the second direction, the average height of the first two bounding areas located on both sides of the same pixel block row is greater than the average height of the second bounding area. located between two sub-pixel rows in one row of pixel blocks.

For example, in an embodiment of the present disclosure, a pixel arrangement structure formed from multiple first color subpixels, multiple second color subpixels, and multiple third color subpixels contains multiple minimum repeat blocks arranged in a first direction, and each minimum repeat block contains one first color subpixel, one third color sub-pixel and two second color sub-pixels that are distributed in two sub-pixel rows; in the second direction, the first limiting areas are located on both sides of the minimum repeating blocks placed in the first direction, and the second limiting areas are located in the gap between two subpixel lines in which the minimum repeating blocks are distributed.

For example, in an embodiment of the present disclosure, the pixel-bounding layer comprises a flat area and a sloped area, the sloped area surrounds each aperture, and the sloped area includes a first sloped sub-region located adjacent to the flat portion and a second sloped sub-region located away from the flat area. In the third direction or the fourth direction, the aspect ratio between the orthogonal projections of the first inclined sub-section and the second inclined sub-section onto the base substrate does not exceed 1/4, and the average inclination angle of the first inclined sub-section is less than the average inclination angle of the second inclined sub-section.

For example, in the embodiment of the present disclosure, the display panel further comprises: multiple spacers located on the surface of the pixel-bounding layer remote from the base substrate, and the spacers in the display area are located in the spaces between the sub-pixels placed in the first direction, and the spacers in the display area are located in the spacing between subpixels arranged in the second direction. In the display area, the area ratio K between the separator and the pixel-bounding layer satisfies the inequality K ≤S0/[k1*n*m*(S1 _G -S2 _G )+k2*n*m*(S1 _R -S2 _R )+k3*n *m*(S1 _B -S2 _B )], where n is the number of middle subpixels in one line, which are located between adjacent separators among the separators placed in the first direction, m is the number of middle subpixels in the same line, which is located between adjacent separators among the separators placed in the second direction, S0 is the area of one separator; S1 _G , S1 _R and S1 _B are areas of light-emitting layers of the second color sub-pixel, the first color sub-pixel and the third color sub-pixel, respectively; S2 _G , S2 _{R and} S2 _B are the aperture areas of the pixel-bounding layer corresponding to the second color sub-pixel, the first color sub-pixel and the third color sub-pixel, respectively; and k1, k2, and k3 are the proportions of the second color subpixels, the first color subpixels, and the third color subpixels in the display area with respect to all subpixels, respectively.

For example, in an embodiment of the present disclosure, the area ratio between the orthogonal projection of the separators onto the base substrate and the orthogonal projection of the pixel-bounding layer onto the base substrate does not exceed 8%.

For example, in an embodiment of the present disclosure, in the display area, the numerical ratio between separators and all subpixels does not exceed 1:16.

For example, in an embodiment of the present disclosure, four second color subpixels are placed between adjacent spacers in the second direction, and two first color subpixels and two third color subpixels are placed between adjacent spacers in the first direction; or six second color subpixels are placed between adjacent spacers in the second direction, and three first color subpixels and three third color subpixels are placed between adjacent spacers in the first direction; or four second color subpixels are placed between adjacent spacers in the second direction, and three first color subpixels and three third color subpixels are placed between adjacent spacers in the first direction; or six second color subpixels are placed between adjacent spacers in the second direction, and two first color subpixels and two third color subpixels are placed between adjacent spacers in the first direction.

For example, in an embodiment of the present disclosure, the multiple first color subpixels comprise multiple first effective light emitting regions, the multiple second color subpixels comprise multiple second effective light emitting regions, and the area of one of the multiple second effective light emitting regions is smaller than the area of one of the multiple first effective light emitting regions. Numerous first color subpixels contain multiple first color light emitting layers located in the respective holes and on the pixel limiting layer surrounding the respective holes, numerous second color subpixels contain multiple second color light emitting layers located in the respective holes and on the pixel limiting layer surrounding the respective holes, the plurality of first color light emitting layers included in the plurality of first color subpixels are spaced apart from each other, and the plurality of second color light emitting layers included in the plurality of second color subpixels are spaced apart from each other; the area ratio between the orthogonal projections of the first color light emitting layer and the first effective light emitting region corresponding to the same first color subpixel onto the base substrate is the first area ratio, the area ratio between the orthogonal projections of the second color light emitting layer and the second effective light emitting region corresponding to to the same second color subpixel on the base substrate is the second area ratio, and the first area ratio is less than the second area ratio.

For example, in an embodiment of the present disclosure, at least a portion of the second effective light emitting regions has a length direction and a width direction, wherein the length direction is the extension direction of the connecting line between two points furthest apart in the one second effective light emitting region, and the direction width substantially perpendicular to the length direction of the same second effective light emitting region. For one second effective light emitting area, in the length direction, the ratio of the maximum size of the second color light emitting layer corresponding to the second effective light emitting area to the maximum size of the second effective light emitting area is the first ratio; in the width direction, the ratio of the maximum size of the second color light emitting layer corresponding to the second effective light emitting region to the maximum size of the second effective light emitting region is the second ratio; and the first ratio is less than the second ratio.

For example, in an embodiment of the present disclosure, for the same second effective light emitting region, in the length direction of the second effective light emitting region, the difference between the maximum size of the corresponding second color light emitting layer and the maximum size of the second effective light emitting region is the first difference; in the width direction of the second effective light emitting region, the difference between the maximum size of the second color light emitting layer and the maximum size of the second effective light emitting region is the second difference; and the first difference is less than the second difference.

For example, in an embodiment of the present disclosure, the ratio of the maximum size of the second color light emitting layer in the length direction of the second effective light emitting region to the maximum size of the second color light emitting layer in the width direction of the second effective light emitting region is less than the ratio of the maximum size of the second effective light emitting region in the length direction of the second effective light emitting area to the maximum size of the second effective light emitting area in the width direction of the second effective light emitting area.

For example, in an embodiment of the present disclosure, the area ratio between the orthogonal projections of the third color light emitting layer and the third effective light emitting region corresponding to the same third color subpixel onto the base substrate is a third area ratio, and the third area ratio is less than the second ratio areas.

For example, in an embodiment of the present disclosure, the area of the first effective light emitting region of one of the plurality of first color subpixels is smaller than the area of the third effective light emitting region of one of the plurality of third color subpixels, and the first area ratio is greater than the third area ratio.

For example, in an embodiment of the present disclosure, the display panel further comprises: an encapsulating layer located in the display area and the peripheral area; a first sensor electrode layer located on the side of the encapsulating layer remote from the base substrate, wherein the first sensor electrode layer comprises multiple first sensor electrodes extending in a first direction and multiple second sensor electrodes extending in a second direction, each of the multiple first sensor electrodes comprising multiple first sensor electrodes, each of the multiple second sensor electrodes contains multiple second sensor electrodes, the layer of first sensor electrodes contains multiple lines of sensor electrodes, multiple lines of sensor electrodes intersect to form multiple first cells, both from each block of first sensor electrodes and each block of second sensor electrodes the electrodes contain numerous first cells connected to each other; second sensor electrode layer containing multiple connecting jumpers, wherein the second sensor electrode layer contains multiple jumpers, multiple jumpers intersect to form multiple second cells, each of the multiple connecting jumpers contains multiple second cells connected to each other and adjacent blocks of second sensor electrodes electrically connected through at least one connecting jumper; a sensor insulating layer located between the layer of the first sensor electrodes and the layer of the second sensor electrodes, and the block of the second sensor electrodes electrically connected to the connecting jumper through a through hole passing through the sensor insulating layer, moreover, the orthogonal projection of multiple lines of sensor electrodes in the display area onto the base substrate located within the orthogonal projection of the pixel-limiting layer onto the base substrate.

For example, in an embodiment of the present disclosure, in the display area, more than 80% of the orthogonal projection of the center line, each segment of the pixel-bounding layer, and in the direction of the continuation of the corresponding segment, onto the base substrate is located in the orthogonal projection of the sensor electrode line onto the base substrate.

For example, in an embodiment of the present disclosure, spaces are provided between the first color light emitting layer of the first color subpixel, the second color light emitting layer of the second color subpixel, and the third color light emitting layer of the third color subpixel that are adjacent to each other, the first color light emitting layer has a shape containing the first a rounded rectangle and a first protruding portion located in the rounded corner of the first rounded rectangle and protruding in the direction of the gap, the first protruding portion at least partially protrudes from the extension line of the straight edge of the first rounded rectangle closest to the second color light emitting layer; the third color light emitting layer has a shape containing a third rounded rectangle and a second protruding section located in the rounded corner of the third rounded rectangle and protruding in the direction of the gap, and the second protruding section at least partially protrudes from the extension line of the straight edge of the third rounded rectangle closest to the second color light emitting layer, the orthogonal projections of the first raised portion and the second raised portion onto the base substrate are at least partially overlapped by the orthogonal projection of the line of the sensor electrodes onto the base substrate.

For example, in an embodiment of the present disclosure in the display area, an orthogonal projection of more than 50% of the sensor electrode line onto the base substrate is located within the orthogonal projection of the overlapping portion onto the base substrate, and the overlapping portion of the light emitting layer comprises an overlapping portion of at least two selected from the group consisting of a first color light emitting layer, a second color light emitting layer, and a third color light emitting layer.

For example, in an embodiment of the present disclosure, in a display area, the orthogonal projection of the effective light emitting area of each of the plurality of subpixels onto the base substrate is within the orthogonal projection of each of the plurality of first cells onto the base substrate; the ratio of the opening area of the first cell corresponding to the first color subpixel to the area of the first effective light emitting region, and the ratio of the opening area of the first cell corresponding to the third color subpixel to the area of the third effective light emitting region is less than the ratio of the opening area of the first cell corresponding to the second color subpixel, to the area of the second effective light emitting region.

For example, in an embodiment of the present disclosure, each of the multiple subpixels further comprises a pixel circuit between the second electrode of the organic light emitting element and the base substrate, and the pixel circuit comprises a driving transistor; at least one electrode selected from the group consisting of a second organic light emitting element electrode of the first color subpixel, a second organic light emitting element electrode of the second color subpixel, and a second organic light emitting element electrode of the third color subpixel is overlapped by a line of sensor electrodes; and/or the control transistor of at least one selected from the group consisting of the first color sub-pixel, the second color sub-pixel and the third color sub-pixel is covered by a line of sensor electrodes.

At least an embodiment of the present disclosure provides a display panel that includes: a base substrate and multiple first color sub-pixels, multiple second color sub-pixels, multiple third color sub-pixels, and a pixel-bounding layer on the base substrate. The display panel includes a display area and a peripheral area located on the periphery of the display area; multiple first color subpixels arranged in the display area, wherein the multiple first color subpixels are arranged in the first direction to form multiple rows of first color subpixels, the multiple rows of first color subpixels are arranged in the second direction, and adjacent rows of first color subpixels in the multiple rows of first color subpixels are offset relative to each other in the first direction; multiple second color subpixels are arranged in the display area and arranged in an array in the first direction and the second direction, and four second color subpixels surround one first color subpixel; multiple third color subpixels are arranged in the display area, multiple first color subpixels and multiple third color subpixels are alternately arranged in the first direction and the second direction, multiple first color subpixels and multiple second color subpixels are alternately arranged in the third direction as a first group, multiple third color subpixels and the plural second color subpixels are alternately arranged in the third direction as a second group, the first group and the second group are alternately arranged in the fourth direction, and the third direction and the fourth direction intersect with both the first direction and the second direction. The pixel limiting layer is located in the display area and the peripheral area, the pixel limiting layer contains multiple holes for forming effective light emitting areas of multiple subpixels. The display panel further comprises a plurality of spacers located on the surface of the pixel-bounding layer remote from the base substrate, and spacers in the display area are located in spaces between subpixels placed in the first direction, and spacers in the display area are spaced in spaces between subpixels placed in the second direction. . In the display area, the area ratio K between the separator and the pixel-bounding layer satisfies the inequality K ≤S0/[k1*n*m*(S1 _G -S2 _G )+k2*n*m*(S1 _R -S2 _R )+k3*n *m*(S1 _B -S2 _B )], where n is the number of middle subpixels in one line, which are located between adjacent separators among the separators placed in the first direction, m is the number of middle subpixels in the same line, which is located between adjacent separators among the separators placed in the second direction, S0 is the area of one separator; S1 _G , S1 _R and S1 _B are areas of light-emitting layers of the second color sub-pixel, the first color sub-pixel and the third color sub-pixel, respectively; S2 _G , S2 _{R and} S2 _B are the aperture areas of the pixel-bounding layer corresponding to the second color sub-pixel, the first color sub-pixel and the third color sub-pixel, respectively; and k1, k2, and k3 are the proportions of the second color subpixels, the first color subpixels, and the third color subpixels in the display area with respect to all subpixels, respectively.

For example, in an embodiment of the present disclosure, the area ratio between the orthogonal projection of the separators onto the base substrate and the orthogonal projection of the pixel-bounding layer onto the base substrate does not exceed 8%.

For example, in an embodiment of the present disclosure, in the display area, the numerical ratio between separators and all subpixels does not exceed 1:16.

For example, in an embodiment of the present disclosure, four second color subpixels are placed between adjacent spacers in the second direction, and two first color subpixels and two third color subpixels are placed between adjacent spacers in the first direction; or six second color subpixels are placed between adjacent spacers in the second direction, and three first color subpixels and three third color subpixels are placed between adjacent spacers in the first direction; or four second color subpixels are placed between adjacent spacers in the second direction, and three first color subpixels and three third color subpixels are placed between adjacent spacers in the first direction; or six second color subpixels are placed between adjacent spacers in the second direction, and two first color subpixels and two third color subpixels are placed between adjacent spacers in the first direction.

For example, in an embodiment of the present disclosure, each spacer comprises a first region and a second annular region surrounding the first region. The first region contains a central region separators, and the area ratio between the orthogonal projections of the first region and the separators onto the base substrate does not exceed 1/4; in the display area, the first area of the at least one spacer is not overlapped by any of the first color light emitting layer, the second color light emitting layer, or the third color light emitting layer; or the first region of the at least one spacer is covered by only one type of color light emitting layer.

For example, in an embodiment of the present disclosure, the display panel further comprises: an encapsulating layer located in the display area and the peripheral area; a first sensor electrode layer located on the side of the encapsulating layer remote from the base substrate, wherein the first sensor electrode layer comprises multiple first sensor electrodes extending in a first direction and multiple second sensor electrodes extending in a second direction, each first sensor electrode comprising multiple first sensor electrodes, each second sensor electrode contains multiple second sensor electrodes, the layer of first sensor electrodes contains multiple lines of sensor electrodes, the multiple lines of sensor electrodes intersect to form multiple first cells, and both of each block of first sensor electrodes and each block of second sensor electrodes contain numerous associated with each other first cells; a layer of second sensor electrodes containing multiple connecting jumpers, wherein the layer of second sensor electrodes contains multiple jumpers, the multiple jumpers intersect to form multiple second cells, each connecting jumper contains a plurality of communicating second cells, and adjacent blocks of second sensor electrodes are electrically connected through at least one connecting jumper; a sensor insulating layer located between the first sensor electrode layer and the second sensor electrode layer, and the second sensor electrode unit is electrically connected to the connecting jumper through a through hole passing through the sensor insulating layer. In the display area, jumper lines spanning one second grid are overlapped by at most one separator.

For example, in an embodiment of the present disclosure, in the display area, the jumper lines of the second cells included in one connection jumper connecting adjacent second sensor electrode units are overlapped by no more than three separators, and all connection jumpers connecting adjacent second sensor electrode units are overlapped. up to four delimiters.

For example, in an embodiment of the present disclosure, the multiple first color subpixels comprise multiple first color light emitting layers located in respective holes and on a pixel-bounding layer surrounding the respective holes, the multiple second color sub-pixels comprising multiple second light-emitting layers located in respective holes and on the pixel-bounding layer. the layer surrounding the respective holes, the plurality of first color light emitting layers included in the plurality of first color subpixels are spaced apart from each other, and the plurality of second light emitting layers included in the plurality of second color subpixels are spaced apart from each other; numerous third color subpixels contain numerous third effective light emitting areas, numerous third color subpixels contain numerous third color light emitting layers located in the respective holes and on the pixel limiting layer surrounding the respective holes, and numerous third color light emitting layers included in the numerous third color subpixels, spaced apart from each other. Each of the multiple subpixels contains the first electrode and the second electrode of the organic light emitting element, the second electrode of the organic light emitting element is located between the base substrate and the first electrode of the organic light emitting element, each subpixel contains functional film layers between the first electrode and the second electrode of the organic light emitting element, an orthogonal projection of the functional film layers on the base substrate is overlapped by orthogonal projections of the first electrode and the second electrode of the organic light emitting element onto the base substrate, the total thickness of the functional film layers is less than the depth of the hole in the pixel-bounding layer corresponding to the subpixel, the functional film layers contain a light emitting layer, the light emitting layers of the subpixels contain the first color light emitting layers, second color light emitting layers and third color light emitting layers, total functional thickness the total thickness of the functional film layers between the first electrode and the second electrode of the organic light emitting element of the first color subpixel is greater than the total thickness of the functional film layers between the first electrode and the second electrode of the organic light emitting element of the second color subpixel, and the total thickness of the functional film layers between the first electrode and the second electrode of the organic light emitting element element of the second color subpixel is greater than the total thickness of the functional film layers between the first electrode and the second electrode of the organic light emitting element of the third color subpixel.

For example, in an embodiment of the present disclosure, the functional film layers between the first electrode and the second electrode of the organic light emitting element of each subpixel further comprise an auxiliary light emitting layer, and the auxiliary light emitting layer is located between the corresponding light emitting layer and the second electrode of the organic light emitting element, the thickness of the auxiliary light emitting layer of the first color subpixel is greater than than the thickness of the auxiliary light emitting layer of the second color subpixel, and the thickness of the auxiliary light emitting layer of the second color subpixel is greater than the thickness of the auxiliary light emitting layer of the third color subpixel.

For example, in an embodiment of the present disclosure, each subpixel comprises a first electrode and a second electrode of an organic light emitting element, the second electrode being positioned between the base substrate and the first electrode, and the first electrode being an integral film layer in the display area. The display panel further comprises: an encapsulating layer located in the display area and the peripheral area; a first sensor electrode layer located on the side of the encapsulating layer remote from the base substrate, wherein the first sensor electrode layer comprises multiple first sensor electrodes extending in a first direction and multiple second sensor electrodes extending in a second direction, each first sensor electrode comprising multiple first sensor electrodes, each second sensor electrode contains multiple second sensor electrodes, the layer of first sensor electrodes contains multiple lines of sensor electrodes, the multiple lines of sensor electrodes intersect to form multiple first cells, and both of each block of first sensor electrodes and each block of second sensor electrodes contain numerous associated with each other first cells; second sensor electrode layer containing multiple connecting jumpers, wherein the second sensor electrode layer contains multiple jumpers, multiple jumpers intersect to form multiple second cells, each connecting jumper contains multiple second cells connected to each other and adjacent blocks of second sensor electrodes electrically connected at least at least through one connecting jumper; a sensor insulating layer located between the first sensor electrode layer and the second sensor electrode layer, and the second sensor electrode block electrically connected to the connecting bridge through a through hole passing through the sensor insulating layer. One of the first sensor electrode layer and the second sensor electrode layer, which is closer to the first electrode, is the sensor electrode near layer in the display area; the total thickness of the insulating layer between the first electrode located in the effective light emitting region and the sensor electrode near layer is greater than the thickness of the insulating layer between the first electrode located on the outer side of the effective light emitting region and the near layer of the sensor electrodes.

For example, in an embodiment of the present disclosure, each of the plurality of subpixels comprises a first electrode and a second organic light emitting element electrode, the second organic light emitting element electrode is positioned between the base substrate and the first organic light emitting element electrode. The pixel-bounding layer comprises multiple first bounding portions and multiple second bounding portions substantially extending in the first direction, the first bounding portions and the second bounding portions are alternately placed in the second direction, and in the second direction, the average heights of one first bounding portion and one second bounding portion, which are located on both sides of the same row of subpixels arranged in the first direction are different; the average heights of the multiple first bounding portions in the display area are approximately the same, the average heights of the multiple second bounding portions in the display area are approximately the same; the average height of the first boundary portion is the average height from the surface of the first boundary portion remote from the base substrate to the plane where the surface of the main base electrode of the second electrode is located, remote from the base substrate, and the average height of the second boundary portion is the average height from the surface of the second a boundary portion remote from the base substrate to a plane where the surface of the main base electrode of the second electrode is located, remote from the base substrate.

For example, in an embodiment of the present disclosure, the average height of one first bounding area is greater than the average height of the second bounding area, and the pixel-bounding layer in the peripheral area is the third bounding area, the average height of the third bounding area is greater than the average height of the second bounding area.

For example, in an embodiment of the present disclosure, two adjacent rows of subpixels arranged in the second direction form a row of pixel blocks, and in the second direction, the average height of the first two bounding areas located on both sides of the same pixel block row is greater than the average height of the second bounding area. located between two sub-pixel rows in one row of pixel blocks.

For example, in an embodiment of the present disclosure, a pixel arrangement structure formed from multiple first color subpixels, multiple second color subpixels, and multiple third color subpixels contains multiple minimum repeat blocks arranged in a first direction, and each minimum repeat block contains one first color subpixel, one third color sub-pixel and two second color sub-pixels that are distributed in two sub-pixel rows; in the second direction, the first limiting areas are located on both sides of the minimum repeating blocks placed in the first direction, and the second limiting areas are located in the gap between two subpixel lines in which the minimum repeating blocks are distributed.

For example, in an embodiment of the present disclosure, the pixel bounding layer comprises a flat portion and a sloped portion, the sloped portion surrounds each aperture, and the sloped portion comprises a first sloped sub-region adjacent to the flat region and a second sloped sub-region spaced from the flat portion. In the third direction or the fourth direction, the aspect ratio between the orthogonal projections of the first inclined sub-section and the second inclined sub-section onto the base substrate does not exceed 1/4, and the average inclination angle of the first inclined sub-section is less than the average inclination angle of the second inclined sub-section.

For example, in an embodiment of the present disclosure, the multiple first color subpixels comprise multiple first effective light emitting regions, the multiple second color subpixels comprise multiple second effective light emitting regions, and the area of one of the multiple second effective light emitting regions is smaller than the area of one of the multiple first effective light emitting regions. Numerous first color subpixels contain multiple first color light emitting layers located in the respective holes and on the pixel limiting layer surrounding the respective holes, numerous second color subpixels contain multiple second color light emitting layers located in the respective holes and on the pixel limiting layer surrounding the respective holes, the plurality of first color light emitting layers included in the plurality of first color subpixels are spaced apart from each other, and the plurality of second color light emitting layers included in the plurality of second color subpixels are spaced apart from each other; the area ratio between the orthogonal projections of the first color light emitting layer and the first effective light emitting region corresponding to the same first color subpixel onto the base substrate is the first area ratio, the area ratio between the orthogonal projections of the second color light emitting layer and the second effective light emitting region corresponding to the same second color subpixel, on the base substrate, is the second area ratio, and the first area ratio is less than the second area ratio.

For example, in an embodiment of the present disclosure, at least a portion of the second effective light emitting regions has a length direction and a width direction, the length direction is the extension direction of a connecting line between two points furthest apart in one second effective light emitting region, and a width direction substantially perpendicular to the length direction of the same second effective light emitting region. For one second effective light emitting area in the length direction, the ratio of the maximum size of the second color light emitting layer corresponding to the second effective light emitting area to the maximum size of the second effective light emitting area is the first ratio; in the width direction, the ratio of the maximum size of the second color light emitting layer corresponding to the second effective light emitting region to the maximum size of the second effective light emitting region is the second ratio; and the first ratio is less than the second ratio.

For example, in an embodiment of the present disclosure, for the same second effective light emitting region, in the length direction of the second effective light emitting region, the difference between the maximum size of the corresponding second color light emitting layer and the maximum size of the second effective light emitting region is the first difference; in the width direction of the second effective light emitting region, the difference between the maximum size of the second color light emitting layer and the maximum size of the second effective light emitting region is the second difference; and the first difference is less than the second difference.

For example, in an embodiment of the present disclosure, the ratio of the maximum size of the second color light emitting layer in the length direction of the second effective light emitting region to the maximum size of the second color light emitting layer in the width direction of the second effective light emitting region is less than the ratio of the maximum size of the second effective light emitting region in the length direction of the second effective light emitting area to the maximum size of the second effective light emitting area in the width direction of the second effective light emitting area.

For example, in an embodiment of the present disclosure, the plurality of third color subpixels comprise plurality of third effective light emitting regions, the area of one of the plurality of second effective light emitting regions is less than the area of one of the plurality of third effective light emitting regions, the plurality of third color subpixels comprise plurality of third color light emitting layers arranged in the respective apertures and on the pixel limiting layer surrounding the respective apertures, and the plurality of third color light emitting layers included in the plurality of third color subpixels are spaced apart from each other, the area ratio between the orthogonal projections of the third color light emitting layer and the third effective light emitting region that correspond to one and the same third color subpixel, on the base substrate has a third area ratio, and the third area ratio is less than the second ratio n horses.

For example, in an embodiment of the present disclosure, the area of the first effective light emitting region of one of the plurality of first color subpixels is smaller than the area of the third effective light emitting region of one of the plurality of third color subpixels, and the first area ratio is greater than the third area ratio.

For example, in an embodiment of the present disclosure, each of the plurality of subpixels comprises a first electrode and a second organic light emitting element electrode, the second organic light emitting element electrode is positioned between the base substrate and the first organic light emitting element electrode. The pixel-bounding layer comprises multiple first bounding portions and multiple second bounding portions substantially extending in the first direction, the first bounding portions and the second bounding portions are alternately placed in the second direction, and in the second direction, the average heights of one first bounding portion and one second bounding portion, which are located on both sides of the same row of subpixels arranged in the first direction are different; the average heights of the multiple first bounding portions in the display area are approximately the same, the average heights of the multiple second bounding portions in the display area are approximately the same; the average height of the first boundary portion is the average height from the surface of the first boundary portion remote from the base substrate to the plane where the surface of the main base electrode of the second electrode is located, remote from the base substrate, and the average height of the second boundary portion is the average height from the surface of the second a boundary portion remote from the base substrate to a plane where the surface of the main base electrode of the second electrode is located, remote from the base substrate.

For example, in an embodiment of the present disclosure, the average height of one first boundary area is greater than the average height of the second boundary area, and the pixel boundary layer in the peripheral area is the third boundary area, the average height of the third boundary area is greater than the average height of the second boundary area.

For example, in an embodiment of the present disclosure, two adjacent rows of subpixels arranged in the second direction form a row of pixel blocks, and in the second direction, the average height of the first two bounding areas located on both sides of the same pixel block row is greater than the average height of the second bounding area. located between two sub-pixel rows in one row of pixel blocks.

For example, in an embodiment of the present disclosure, a pixel arrangement structure formed from multiple first color subpixels, multiple second color subpixels, and multiple third color subpixels contains multiple minimum repeat blocks arranged in a first direction, and each minimum repeat block contains one first color subpixel, one third color sub-pixel and two second color sub-pixels that are distributed in two sub-pixel rows; in the second direction, the first limiting areas are located on both sides of the minimum repeating blocks placed in the first direction, and the second limiting areas are located in the gap between two subpixel lines in which the minimum repeating blocks are distributed.

At least an embodiment of the present disclosure provides a display panel that includes a base substrate comprising a display area and a peripheral area located on the periphery of the display area; plural first color subpixels arranged in the display area, wherein the plurality of first color subpixels are arranged in the first direction to form multiple rows of first color subpixels, the plurality of first color subpixel rows are arranged in the second direction, and adjacent rows of first color subpixels in the plurality of first color subpixel rows are offset relative to each other in the first direction; multiple second color subpixels located in the display area and arranged in an array in the first direction and the second direction, and four second color subpixels surrounding one first color subpixel; a plurality of third color subpixels arranged in the display area, wherein the plurality of first color subpixels and the plurality of third color subpixels are alternately arranged in the first direction and the second direction, the plurality of first color subpixels and the plurality of second color subpixels are alternately arranged in the third direction as a first group, the plurality of third the color subpixels and the plurality of second color subpixels are alternately arranged in the third direction as a second group, the first group and the second group are alternately arranged in the fourth direction, and the third direction and the fourth direction intersect with both the first direction and the second direction; a pixel limiting layer located in the display area and the peripheral area, wherein the pixel limiting layer contains multiple holes for forming effective light emitting areas of multiple subpixels, multiple first color subpixels contain multiple first effective light emitting areas, multiple second color subpixels containing multiple second effective light emitting areas, and the plurality of third color subpixels comprise the plurality of third effective light emitting regions. Numerous first color subpixels contain multiple first color light emitting layers located in the respective holes and on the pixel limiting layer surrounding the respective holes, numerous second color subpixels contain multiple second color light emitting layers located in the respective holes and on the pixel limiting layer surrounding the respective holes, the plurality of first color light emitting layers included in the plurality of first color subpixels are spaced apart from each other, and the plurality of second color light emitting layers included in the plurality of second color subpixels are spaced apart from each other; the plurality of third color sub-pixels comprise the plurality of third color light-emitting layers located in the respective holes and on the pixel-limiting layer surrounding the respective holes, and the plurality of third color light-emitting layers included in the plurality of third color sub-pixels are spaced apart from each other. The display panel further comprises: an encapsulating layer located in the display area and the peripheral area; a first sensor electrode layer located on the side of the encapsulating layer remote from the base substrate, wherein the first sensor electrode layer comprises multiple first sensor electrodes extending in a first direction and multiple second sensor electrodes extending in a second direction, each first sensor electrode comprising multiple first sensor electrodes, each second sensor electrode contains multiple second sensor electrodes, the layer of first sensor electrodes contains multiple lines of sensor electrodes, the multiple lines of sensor electrodes intersect to form multiple first cells, and both of each block of first sensor electrodes and each block of second sensor electrodes contain numerous first cells connected to each other; second sensor electrode layer containing multiple connecting jumpers, wherein the second sensor electrode layer contains multiple jumpers, multiple jumpers intersect to form multiple second cells, each connecting jumper contains multiple second cells connected to each other and adjacent blocks of second sensor electrodes electrically connected at least at least through one connecting jumper; a sensor insulating layer located between the layer of the first sensor electrodes and the layer of the second sensor electrodes, and the block of the second sensor electrodes is electrically connected to the connecting jumper through a through hole passing through the sensor insulating layer. The orthogonal projection of the multiple lines of the sensor electrodes in the display area onto the base substrate is located within the orthogonal projection of the pixel-limiting layer onto the base substrate.

At least an embodiment of the present disclosure provides a display panel that includes a base substrate comprising a display area and a peripheral area located on the periphery of the display area; and multiple subpixels located in the display area. Each subpixel contains the first electrode and the second electrode of the organic light emitting element, the second electrode is located between the base substrate and the first electrode, and the first electrode is an integral film layer in the display area. The display panel further comprises: an encapsulating layer located in the display area and the peripheral area; a first sensor electrode layer located on the side of the encapsulating layer remote from the base substrate, wherein the first sensor electrode layer comprises multiple first sensor electrodes extending in a first direction and multiple second sensor electrodes extending in a second direction, each first sensor electrode comprising multiple first sensor electrodes, each second sensor electrode contains multiple second sensor electrodes, the layer of first sensor electrodes contains multiple lines of sensor electrodes, the multiple lines of sensor electrodes intersect to form multiple first cells, and both of each block of first sensor electrodes and each block of second sensor electrodes contain numerous associated with each other first cells; a layer of second sensor electrodes containing multiple connecting jumpers, a layer of second sensor electrodes contains multiple jumpers, and multiple jumpers intersect to form multiple second cells, each connecting jumper contains multiple interconnected second cells and adjacent blocks of second sensor electrodes electrically connected along at least one connecting jumper; a sensor insulating layer located between the first sensor electrode layer and the second sensor electrode layer, and the second sensor electrode unit is electrically connected to the connecting jumper through a through hole passing through the sensor insulating layer. One of the first sensor electrode layer and the second sensor electrode layer, which is closer to the first electrode, is the sensor electrode proximal layer, and in the display area, the total thickness of the insulating layer between the first electrode located in the effective light emitting region and the sensor electrode proximal layer is larger, than the total thickness of the insulating layer between the first electrode located on the outer side of the effective light emitting region and the near layer of the sensor electrodes.

At least an embodiment of the present disclosure provides a display device comprising a display panel as mentioned above.

Brief description of the drawings

In order to clearly illustrate the technical solutions of the embodiments, the drawings of the embodiments will be briefly described below; it is obvious that the described drawings relate only to some embodiments of the disclosure and, thus, do not limit the disclosure.

1A is a partial planar structural view of a display panel shown in an exemplary embodiment of the present disclosure;

1B is a partial planar structural view of a display panel of another exemplary embodiment of the present disclosure;

1C is a planar structural view of a hole in a pixel-bounding layer of a display panel shown in another exemplary embodiment of the present disclosure;

1D-1H are schematic representations of various pixel arrangement structures on display panels provided by embodiments of the present disclosure;

Figure 2 is a partial structural sectional view taken along the line A-A shown in Figure 1A;

Fig. 3 is a partial structural sectional view taken along line BB of Fig. 1A;

4 is a partial planar structural view of a sensor structure on a display panel provided in an embodiment of the present disclosure;

Fig. 5 is an enlarged structural view of the region C shown in Fig. 4;

Fig. 6 is a partial structural sectional view taken along line DD of Fig. 5;

Fig. 7 is a partial structural sectional view taken along line E-E of Fig. 5;

Fig. 8 is a schematic representation of the positional relationship between the sensor electrode and the effective light emitting area of each subpixel;

Fig. 9 is an enlarged view of area F (Fig. 8);

10 is a partial planar structural view of a pixel structure provided by another embodiment of the present disclosure;

Fig. 11 is a schematic representation of the positional relationship between the pixel structure and the sensor electrode line shown in Fig. 10;

Fig. 12A is a schematic representation of a pixel circuit included in each sub-pixel;

12B is a schematic representation of the position relationship of each transistor illustrated in the active layer and the gate line layer of each subpixel;

13A-13E are schematic representations of various positional relationships between pixel circuits and sensor electrode lines provided by embodiments of the present disclosure;

Fig. 14A is a schematic representation of the evaporation of a light emitting layer using FMM;

Fig. 14B is a schematic representation of a positional relationship between a pixel bounding layer and a spacer;

15A-15G are schematic representations of various positional relationships between separators and subpixels presented in embodiments of the present disclosure;

Fig. 16 is a partial structural sectional view taken along line G-G of Fig. 1A;

17A is a planar view of a pixel limiting layer and an effective light emitting area in a display area provided in an embodiment of the present disclosure;

Fig. 17B and Fig. 17C planar structural views of the display area pixel bounding layer and the peripheral area at two different positions, respectively;

17D is a planar structural view of a display area pixel bounding layer shown in another example;

Fig. 18 is a partial structural sectional view taken along the line H-H shown in Fig. 17A; and

Fig. 19 is a partial sectional view of the transition region shown in Fig. 1A.

Implementation of the invention

In order to make the objects, technical details and advantages of the embodiments of the disclosure obvious, the technical solutions of the embodiments will be described in a clear and fully understandable manner in connection with the drawings relating to the embodiments of the disclosure. Obviously, the described embodiments are only a part, but not all, of the embodiments of the disclosure. Based on the embodiments described herein, those skilled in the art can obtain other embodiment(s) without any inventive work to be within the scope of the disclosure.

Unless otherwise indicated, all technical and scientific terms used herein have the same meanings as generally understood by a person skilled in the art to which this disclosure belongs. The terms "first", "second", etc., which are used in the disclosure, are not intended to indicate any sequence, quantity or importance, but are intended to distinguish between the various components. The terms "comprise", "comprising", "include", "including", etc. are intended to indicate that the elements or objects listed before these terms encompass the elements or objects and their equivalents listed after these terms, but do not exclude other elements or objects.

In the course of the study, the authors of the present application found that: in the course of the continuous development of display technology, people place more and more high demands on the resolution of display devices, and the application range of high-resolution display devices having the advantages of high display quality is becoming wider and wider. etc. In general, the resolution of a display device can be increased by reducing the pixel size and decreasing the spacing between pixels. However, the reduction of the pixel size and the reduction of the distance between the pixels require increasingly high demands on the accuracy of the manufacturing process, which leads to the complexity of the manufacturing process and the increase in the manufacturing cost of the display devices.

Embodiments of the present disclosure provide a display panel and a display device. The display panel includes: a base substrate including a display area and a peripheral area located on the periphery of the display area; plural first color subpixels arranged in the display area, wherein the plurality of first color subpixels are arranged in the first direction to form multiple rows of first color subpixels, the plurality of first color subpixel rows are arranged in the second direction, and adjacent rows of first color subpixels in the plurality of first color subpixel rows are offset relative to each other in the first direction; multiple second color subpixels located in the display area and ordered in the first direction and the second direction, and four second color subpixels surrounding one first color subpixel; a pixel-bounding layer located in a display area and a peripheral area, wherein the pixel-bounding layer includes multiple apertures for forming sub-pixel effective light-emitting areas, each first color sub-pixel includes a first effective light-emitting area, every second color sub-pixel includes a second effective light-emitting area area, and the area of the second effective light emitting area is smaller than the area of the first effective light emitting area.

In some embodiments, the one first color subpixel includes one first effective light emitting area, the one second color subpixel includes one second effective light emitting area, and the area of the one second effective light emitting area is less than the area of one first effective light emitting area. In some embodiments, one first color subpixel includes at least two first effective light emitting regions, or one second color subpixel includes at least two second effective light emitting regions, and the total area of all second effective light emitting regions included in one second the color sub-pixel is smaller than the total area of all first effective light-emitting regions included in one first color sub-pixel. In some embodiments, the first effective light emitting regions and the second effective light emitting regions are separate. In some embodiments, the first effective light emitting regions and the second effective light emitting regions are formed by multiple individual apertures formed in the pixel-bounding layer. In some embodiments, each first effective light emitting region is formed by a light emitting layer that is located between the anode and cathode opposite each other in a direction perpendicular to the base substrate, and is driven to emit light in the corresponding first color substrate. pixel. In some embodiments, each second effective light emitting region is formed by a light emitting layer that is located between the anode and cathode opposite each other in a direction perpendicular to the base substrate, and is driven to emit light in the corresponding second color substrate. pixel. In some embodiments, each first effective light emitting region and each second effective light emitting region are formed by a respective light emitting layer and an electrode (anode or cathode) or a portion of the electrode that is capable of transporting carriers (holes or electrons) by means of the respective light emitting layer. In some embodiments, each first effective light emitting region and each second effective light emitting region is formed by at least a portion of the cathode and at least a portion of the anode, in which the orthogonal projections on the base substrate overlap, the orthogonal projections of at least a portion of the cathode and at least a portion of the anode onto the base substrate are not overlapped by the orthogonal projection of the first insulating layer onto the base substrate, and the first insulating layer is located between the cathode and the anode in a direction perpendicular to the base substrate. For example, the first isolation layer includes a pixel-bounding layer. In some embodiments, each first color subpixel and each second color subpixel, respectively, includes: a first electrode, a light emitting layer on one side of the first electrode adjacent to the base substrate, and a second electrode on one side of the light emitting layer away from the first electrode; in a direction perpendicular to the base substrate, the second insulating layer is also placed between the first electrode and the light emitting layer and/or between the second electrode and the light emitting layer, the orthogonal projection of the second insulating layer on the base substrate is overlapped by the orthogonal projection of the first electrode or the second electrode, and the second insulating layer has hole; an opening of the second insulating layer on one side facing the light emitting layer may expose at least a portion of the first electrode or at least a portion of the second electrode so that at least a portion of the first electrode or at least a portion of the second electrode may contact the light emitting layer, or functional layer for auxiliary light emission. In some embodiments, the second insulating layer includes a pixel-bounding layer. In some embodiments, the light emission assist functional layer may be any one or more layers selected from the group consisting of hole injection layer, hole transport layer, electron transport layer, hole blocking layer, electron blocking layer, electron injection layer, auxiliary light emitting layer, interface enhancement layer, transmission enhancement layer, etc. In some embodiments, the first electrode may be the anode and the second electrode may be the cathode. In some embodiments, the first electrode may include a laminate that includes at least two layers of indium tin oxide (ITO) and silver (Ag), such as a laminate of three layers of ITO, Ag, and ITO. In some embodiments, the second electrode material may include any one or more materials selected from the group consisting of magnesium (Mg), Ag, ITO, and indium zinc oxide (IZO), such as a mixed or alloy layer of Mg and Ag .

Each subpixel includes a light emitting layer, each first color subpixel includes a first color light emitting layer located in the hole and on the pixel limiting layer, every second color subpixel includes a second color light emitting layer located in the hole and on the pixel limiting layer, and the area ratio between the orthogonal projections of the first color light emitting layer and the first effective light emitting area of each first color subpixel onto the base substrate is less than the area ratio between the orthogonal projections of the second color light emitting layer and the second effective light emitting area of each second color subpixel onto the base substrate.

In general, the quality of the light emitting layer located in the effective light emitting region has a large influence on the display effect of the subpixel. In the case where an evaporation process such as a Fine Metal Mask (FMM) process (described below) is adopted for evaporation, in the display region, multiple effective light emitting regions are in one-to-one correspondence with a plurality of light emitting layer patterns in display area, while the patterns of the light emitting layer are in one-to-one correspondence with the FMM (Fine Metal Mask) apertures. Assuming that there are deviations in the alignment of the FMM and the display panel, or when there are problems such as uneven material caused by evaporation, the smaller the area of the effective light emitting region of the subpixel, the more likely that poor quality of the light emitting layer will occur in the effective light emitting region; even if the deviation is too large, a case of poor quality of the light emitting layer in the effective light emitting region occurs for all color subpixels, the subpixel with the effective light emitting region having the smallest area will be most affected. If the sub-pixel with the effective light-emitting area of the smallest area happens to be a sub-pixel of a certain color, which has the greatest influence on display brightness, display uniformity, or other display parameters such as green sub-pixel, the display panel will have some display problems such as dark spots, roughness, uneven brightness and color deviation, etc. In embodiments of the present disclosure, the area ratio between the second color light emitting layer and the second effective light emitting area of the second color subpixel is set to be larger than the area ratio between the first color light emitting layer and the first effective light emitting area of the first color subpixel, so that the evaporation process headroom for the second color subpixel with an effective light emitting region having a relatively smaller area can be set relatively large, and thus the quality of the second color light emitting layer formed in the second effective light emitting region is more stable, and thereby the influence of deviations or fluctuations caused by the evaporation process is reduced. , on the display quality of each subpixel.

The area of each light emitting layer, for example, can be measured using the following test means. For example, the area of the light emitting layer can be measured by taking pictures with a fluorescent microscope, and, for example, the boundary of the light emitting layer can be obtained using photoluminescence, when the electroluminescent (EL) material is excited by ultraviolet rays. For example, secondary ion time-of-flight mass spectrometry (TOF-SIMS) can be used for testing. TOF-SIMS is an extremely high resolution measurement technology that uses primary ions to excite the sample surface, emits an extremely small amount of secondary ions, and determines the mass of the ion according to the different flight time of the secondary ions to the detector due to different mass. Of course, the area and boundary of each light emitting layer can also be measured using other existing test tools.

The display panel and display device provided by the embodiments of the present disclosure will be described below with reference to the accompanying drawings.

FIG. 1A is a partial planar structural view of a display panel provided in an embodiment of the present disclosure, and FIG. 2 is a partial structural sectional view taken along line A-A of FIG. 1A. As shown in FIG. 1A and FIG. 2, the display panel includes a base substrate 10, and the display panel includes a display area 11 and a peripheral area 12 located on the periphery of the display area 11. For example, the display area 11 is a display area such as an area including illuminating pixels. The boundaries of the display area may be defined by the first and last rows of illuminated pixels and the first and last columns of illuminated pixels. The peripheral area 12 is an area surrounding the display area 11 and not used for display. For example, in some embodiments, the display area may also include dummy pixels, such as pixels formed from the light emitting layer but not used for display. The display panel includes a plurality of first color sub-pixels 100 and a plurality of second color sub-pixels 200 located in the display area 11 of the base substrate 10, with the plurality of first color sub-pixels 100 arranged in a first direction (i.e., the X direction) to form multiple rows 1001 of first color sub-pixels , the plurality of first color subpixel rows 1001 are arranged in the second direction (that is, the Y direction), and adjacent rows of first color subpixels 1001 in the plurality of first color subpixel rows 1001 are offset from each other in the first direction. That is, the adjacent first color subpixel rows 1001 have a certain offset in the first direction, so the first color subpixels 100 in the adjacent first color subpixel rows 1001 are not aligned in the second direction. For example, the pixel arrangement methods in the first color subpixel rows 1001 which are odd rows are the same, and the pixel arrangement methods in the first color subpixel rows 1001 which are even rows are the same. For example, the shift between adjacent rows 1001 of first color subpixels in the first direction is approximately one step. In some embodiments, the pitch is, for example, half the distance between the centers of the effective light emitting regions in two adjacent first color subpixels 100 in the first direction, where the center of the effective light emitting region is relative to the geometric center of the effective light emitting region planar shape. In some embodiments, the step is equal to, for example, the size of the 2-subpixel pixel control schemes in the row direction. In some embodiments, the step is approximately the size of the pixel driving circuit, equal to 1 subpixel in the column direction. In some embodiments, the step is approximately equal to the size of the display area in the row direction divided by the number of pixels in the row direction, or equal to the size of the display area in the column direction divided by the number of pixels in the column direction. For example, for QHD products (the resolution is four times smaller than HD (Quarter High Definition), the resolution is 960*540, and the pitch is approximately equal to the size of the display area in the row direction divided by 960, or equal to the size of the display area in the column direction, divided by 540; for HD (high definition) products, the pitch is approximately equal to the size of the display area in the row direction divided by 1280, or equal to the size of the display area in the column direction divided by 720; for FHD products (resolution equal to HD, Full High Definition ) the pitch is approximately equal to the display area size in the row direction divided by 1920, or equal to the display area size in the column direction divided by 1080; for QHD products (four times the resolution of HD, Quad High Definition), the pitch is approximately equal to the area size display in row direction divided by 2560, or equal to display area size in column direction, div ennom at 1440; for UHD (Ultra High Definition) products, the pitch is approximately equal to the size of the display area in the row direction divided by 3840, or equal to the size of the display area in the column direction divided by 2160; etc. The adjacent rows of first color subpixels described above refer to two rows of first color subpixels without any other row of first color subpixels in between.

As shown in FIG. 1A, multiple second color sub-pixels 200 are arrayed in the first direction and the second direction, and four second color sub-pixels 200 surround one first color sub-pixel 100. That is, the second color sub-pixel 200 is in a different row and column, different from the first color subpixels 100, and one row of second color subpixels 200 (that is, one row of second color subpixels) disposed in the first direction is located between adjacent first rows 1001 of first color subpixels, and row 1001 of first color subpixels and row of second color subpixels placed in sequence. Similarly, one column of second color subpixels 200 (i.e., one column of second color subpixels) arranged in the second direction is interposed between adjacent columns of first color subpixels, and the first column of color subpixels and the second column of color subpixels are arranged alternately.

For example, the distances from the centers of the four second color subpixels to the center of the first color subpixels are approximately the same. For example, among the second color subpixels surrounding the first color subpixel, there are only four second color subpixels closest to the first color subpixel, and the distances from the centers of these four second color subpixels to the center of the first color subpixel are approximately the same. The term "closest to" means that the line connecting the center of the first color subpixel and the center of the second color subpixel does not pass through any other first color subpixel or second color subpixel.

For example, arranging four second color subpixels surrounding one first color subpixel may be a layout method on the inside of the display area, and the layout method on the edge of the display area may be different from the layout method on the inside of the display area. For example, in the case where the first row or first column of subpixels, or the last row or last column of subpixels are first color subpixels, only two second color subpixels surround the first color subpixel at the edge of the display area. For example, the edge shape of the display area may have a rounded corner, or the shape of the display area is a display area of a special shape, such as a non-rectangular display area including a round display area, etc., or a rectangular display area having an area with indentations for holes located near a certain edge of the rectangular display area, and the first color sub-pixel may be surrounded by one, two or three second color sub-pixels at the edge of the display area.

An embodiment of the present disclosure is described using the aforementioned arrangement structure as an example, but is not limited to this pixel structure, and the number of subpixels is also not limited. For example, a stripe layout pattern, or a triangular layout pattern, or a tiled layout pattern, or a layout pattern having any other combination of different sizes, shapes, and positions may be adopted. For example, RGB (ie, R sub-pixel, G sub-pixel, and B sub-pixel) may be the same size or may not be the same size. For example, with regard to the size of the hole in the pixel-bounding layer for limiting one sub-pixel, B may be greater than R, and B may be greater than G. For example, with regard to the size of the hole in the pixel-bounding layer for limiting one sub-pixel, B may be greater than R , and R may be greater than G. For example, with regard to the size of the hole in the pixel-bounding layer for limiting one sub-pixel, B may be greater than R, and R may be greater than G. For example, with regard to the size of the hole in the pixel-bounding layer for limiting one sub-pixel, R may be greater than G. For example, with regard to the size of the hole in the pixel-bounding layer for limiting one sub-pixel, G may be greater than R. For example, with regard to the size of the hole in the pixel-bounding layer for limiting one sub-pixel, G may be greater than B. For example, the number of subpixels included in each repeat block or pixel block can be any one or combination two or more selected from the group consisting of 2, 3, 4, 5, 6, 7, 8, 9, 10, etc. For example, the numerical proportion of subpixels included in each repeat block or pixel block, for example R:G:B, can be any one or a combination of two or more selected from the group consisting of 1:2:1, 1:1: 2, 1:1:1, 1:2:2, 2:2:1, 1:2:3, 3:3:2, 1:3:2, 2:3:1, 3:2:3, 2:3:3 etc. The subpixel color types may include any type selected from the group consisting of two, three, four, five, and six. For example, the color of the subpixels may be one or a combination of several selected from the group consisting of red, green, blue, white, yellow, cyan, magenta, orange, and so on.

As shown in FIG. 1A and FIG. 2, the display panel further includes a pixel limiting layer 400 located in the display area 11 and the peripheral area 12, a hole 401 corresponding to each subpixel can be formed in the pixel limiting layer 400 according to the layout structure. subpixels, that is, the pixel limiting layer 400 includes multiple apertures 401 for delimiting the effective light emitting areas of the multiple subpixels, and the shape of the effective light emitting area of each subpixel may be limited by the aperture 401 of the pixel limiting layer 400. The multiple first color subpixels 100 include the multiple first effective light emitting area 101, and the plurality of second color subpixels 200 include the plurality of second effective light emitting regions 201, and the area of one second effective light emitting region 201 is smaller than the area of one first effective light emitting area 101.

In some embodiments, the effective light emitting area of each subpixel may not be limited by the aperture of the pixel-bounding layer, and, for example, it may be directly limited by the actual light emitting area of each subpixel.

For example, one subpixel corresponds to one effective light emitting area, that is, each subpixel includes only one effective light emitting area. An embodiment of the present disclosure is not limited to this, and, for example, one sub-pixel may also correspond to multiple effective light emitting regions that are driven by one common pixel circuit or receive the same control signal.

For example, the area of each second effective light emitting region is larger than the area of each first effective light emitting region. In some embodiments, the area of each of the second effective light emitting regions is approximately the same, and the area of each of the first effective light emitting regions is approximately the same. In this document, "about the same" means that the error is between plus and minus 10%.

In some embodiments, some subpixels of the same color may have different area effective light emitting areas. For example, in some embodiments, subpixels included in one repeating block or one pixel block include two green subpixels, two red subpixels, two blue subpixels, or two pairs of subpixels in which each pair of subpixels has the same color (e.g. , two green sub-pixels and two red sub-pixels), and the effective light-emitting areas of sub-pixels of the same color may be different. In some embodiments, in the case where subpixels with the same color are located in an extreme position, in a special shape region or in a folding region, etc., and their effective light emitting regions may have different regions or shapes from the effective light emitting regions of the subpixels of the same the same colors in other areas.

As shown in FIG. 1A and FIG. 2, each sub-pixel includes a light emitting layer, each first color sub-pixel 100 includes a first color light-emitting layer 110 located in the aperture 401 and on the pixel-limiting layer 400, and every second color sub-pixel 200 includes a second color light emitting layer 210 disposed in the aperture 401 and on the pixel limiting layer 400. Multiple first color light emitting layers 110 included in multiple first color subpixels 100 are spaced apart from each other, and multiple second color light emitting layers 210 included in multiple second color subpixels 200 spaced apart from each other.

In some embodiments, some light emitting layers cannot be spaced apart from each other. For example, two light emitting layers of the same color, made by 2 in 1 technology (two light emitting layers are produced using one evaporation hole), can be continuous, two light emitting layers can be combined (their orthogonal projections on the base substrate are continuous, but may not actually be connected due to the segment difference between the film layers under the two light emitting layers during the process), may correspond to two subpixels, and the light emitting layers of different pairs of subpixels are spaced apart from each other. Accordingly, the light emitting layers made by 3 in 1 technology (three light emitting layers are produced using one evaporation hole) correspond to three sub-pixels, and the light emitting layers made by 4 in 1 technology (four light emitting layers are produced by using one evaporation hole) correspond to four subpixels. For example, as shown in FIG. 1D, with respect to two light emitting layers with the same color made by 2 in 1 technology (two light emitting layers are produced using one evaporation hole), such as the light emitting layers of the second color subpixels 200, the area ratio of the light emitting layer and holes in the pixel-bounding layer (or effective light-emitting area) of the respective two subpixels can be calculated using half the area of the light-emitting layer and the area of one hole in the pixel-bounding layer of the corresponding subpixel in the case where the sizes of the holes in the pixel-bounding layer of the two subpixels are approximately the same.

For example, as shown in FIG. 1A and FIG. 2, the plurality of first color subpixels 100 include the plurality of first color subpixels 100 that are located in respective apertures 401 and on the pixel bounding layer 100 surrounding the respective apertures 401, and the plurality of second color subpixels. 200 include multiple second color light emitting layers 210 that are located in respective holes 401 and on a pixel-bounding layer 400 surrounding the respective holes. For example, as shown in FIG. 1A and FIG. 2, the light emitting layer of each color sub-pixel is formed all around the hole of the pixel-bounding layer, and for example, a portion of the light-emitting layer of each color sub-pixel on the outside of the hole and on the pixel-bounding layer is shaped as a single rings. For example, the structure of the pixel-bounding layer to form a hole corresponding to each sub-pixel may be divided or formed into a single network structure. For example, a part of the pixel-limiting layer for forming holes on the outermost line (row or column) and on the side of the holes remote from the center of the display area is integrated with the structure of the pixel-limiting layer on the periphery of the display area, or a part of the pixel-limiting layer for forming holes on the display area itself. the deleted line (row or column) serves as the peripheral structure of the pixel-bounding layer around the display area. For example, a portion of the pixel-limiting layer for forming holes on the outermost line (row or column) and on the side of the holes remote from the center of the display area is sized in a direction perpendicular to the extension direction of the edge of the display panel, which corresponds to the part of the pixel-limiting layer, greater than than the size of the portion of the pixel-bounding layer between adjacent holes in the pixel-bounding layer in the display area. For example, as shown in FIG. 1A and FIG. 2, the light emitting layer located on the pixel limiting layer and the light emitting layer located in the hole are combined. The embodiment of the present disclosure is not limited to this, and the hole light emitting layer and the pixel limiting layer light emitting layer can be separated, that is, the hole light emitting layer and the pixel limiting layer light emitting layer are discontinuous film layers. For example, the light emitting layer is discontinuous or discontinuous due to the large difference in segments between the film layers below the light emitting layer. In some embodiments, the orthogonal projections of the light emitting layer located on the pixel-bounding layer and the light emitting layer located in the hole of each subpixel onto the base substrate are substantially continuous.

The area ratio between the orthogonal projections of the first color light emitting layer 110 and the first effective light emitting area 101 of each first color subpixel 100 onto the base substrate 10 is less than the area ratio between the orthogonal projections of the second color light emitting layer 210 and the second effective light emitting area 201 of each second color subpixel 200 on base substrate 10. For example, the orthogonal projection area of the first color light emitting layer 110 onto the base substrate 10 is larger than the orthogonal projection area of the second color light emitting layer 210 onto the base substrate 10.

For example, the area ratio between the orthogonal projections of the first color light emitting layer 110 and the first effective light emitting region 101 corresponding to the same first color subpixel 100 onto the base substrate is the first area ratio, the area ratio between the orthogonal projections of the second color light emitting layer 210 and the second of the effective light emitting area 201 corresponding to the same second color subpixel 200 on the base substrate is the second area ratio, and the first area ratio is smaller than the second area ratio.

For example, the first area ratio is the ratio of the areas of one first color light emitting layer to one first effective light emitting area, that is, the ratio of the area of one first color light emitting layer to the area of one first effective light emitting area; and the second area ratio is the ratio of the area of one second color light emitting layer to one second effective light emitting area, that is, the ratio of the area of one second color light emitting layer to the area of one second effective light emitting area. For example, both the first area ratio and the second area ratio are greater than 1. For example, the first area ratio and the second area ratio can be in the range of 1 to 15. For example, the first area ratio and the second area ratio can be in the range of 1 to 15 For example, the first area ratio and the second area ratio may be in the range of 1 to 10. For example, the first area ratio and the second area ratio may be in the range of 3 to 12. For example, the first area ratio and the second area ratio may be in the range 2 to 8. For example, the first area ratio and the second area ratio may be in the range of 4 to 6. For example, the first area ratio and the second area ratio may be in the range of 3 to 7. For example, the first area ratio and the second area ratio may range from 6 to 8. For example, the first area ratio may range from 3 to 5. For example, ne The first area ratio may be in the range of 1.5 to 3. For example, the first area ratio may be in the range of 3 to 4. For example, the first area ratio may be in the range of approximately 4 to 5. For example, the first area ratio may be in the range of approximately in the range of 4 to 6. For example, the second area ratio may be in the range of approximately 5 to 7. For example, the second area ratio may be in the range of 5 to 7. For example, the second area ratio may be in the range of approximately 6 to 7 For example, the second area ratio may be in the range of approximately 3 to 5. For example, the second area ratio may be in the range of approximately 3 to 6. For example, the second area ratio may be in the range of approximately 5 to 8. For example, the second ratio areas may range approximately from 4 to 9. For example, the second area ratio ranges from 6.5 to 8.

For example, the area of the first color light emitting layer of one first color subpixel is larger than the area of the second color light emitting layer of one second color subpixel.

For example, the first color sub-pixel 100 may be a red sub-pixel or a blue sub-pixel, and the second color sub-pixel 200 may be a green sub-pixel.

For example, the light output of the first color sub-pixel is less than the light output of the second color sub-pixel. For example, the first area ratio corresponding to the first color subpixel is smaller than the second area ratio corresponding to the second color subpixel.

For example, the light output amount of a subpixel refers to the amount of intensity of light emitted from the light emitting element of the subpixel under the same electrical signal conditions. For example, if the light intensity of a sub-pixel is high, the light output is said to be large. For example, the same state of the electrical signal means that the voltages written on the data line are the same. For example, the same state of the electrical signal means that the current written into the light emitting element has the same amount. For example, the light output of a subpixel refers to the density of the current flowing through the light emitting element under the same state of the electrical signal.

For example, the aperture ratio of the first color subpixel is larger than the aperture ratio of the second color subpixel.

For example, the aperture ratio of the first color sub-pixel refers to the area ratio of the first color sub-pixel area actually used to emit light in the display area. For example, the luminosity of the second color sub-pixel refers to the area ratio of the area of the second color sub-pixel actually used to emit light in the display area.

For example, an embodiment of the present disclosure illustratively shows that the first direction is perpendicular to the second direction, but is not limited thereto, and the first direction may not be perpendicular to the second direction.

For example, the light emitting layer of each subpixel may be made using an evaporation process. The evaporation process is to align the evaporation mask plate with the display panel, and the evaporation source is used to heat the light emitting layer material so that the light emitting layer material is deposited at the corresponding positions of the display panel. The evaporation mask may include a precision metal mask (FMM) with sub-pixel pattern holes corresponding to the sub-pixels, and a plurality of independent patterns may be formed on the FMM according to patterns of different colored sub-pixels, so that patterns of different materials and/or different thicknesses may be formed in different subpixels.

For each subpixel, the effective light emitting area is substantially located within the hole of the pixel-bounding layer, and for example, the effective light emitting area has substantially the same area as the corresponding hole. The glow area of each subpixel determines the aperture ratio of the subpixel, which further affects the display brightness of the subpixel on the display panel. In order to improve the luminosity and display quality of each sub-pixel, it is necessary to maximize the quality of the film layers inside the hole of the pixel-limiting layer during the evaporation process. Thus, in the evaporation process of each light emitting layer by the FMM, the holes in the mask plate for forming sub-pixel patterns with different colors are usually set larger than the holes in the pixel-bounding layer, so that the light emitting layer evaporated through the hole in the mask plate can completely cover the hole of the pixel-bounding layer. That is, the light emitting layer of each subpixel includes a part located in the hole of the pixel limiting layer and another part located on the surface of the pixel limiting layer.

Due to deviation in the alignment accuracy of the mask plate and the display panel to be evaporated, and due to the diffusion properties of the material of the evaporation source, the processing accuracy (technological tolerance, that is, the allowable shift between the hole of the precision metal mask plate and the hole of the pixel-limiting layer during evaporation ) of different subpixels will also be different. The service life and light output of the luminescent materials in the light emitting layers of subpixels with different colors on an organic light emitting diode (OLED) display panel are different, so the light areas of subpixels of different colors can be set differently. For example, the luminous area of the first color sub-pixel (eg, the blue sub-pixel) may be set to the maximum, and the luminous area of the second color sub-pixel (eg, the green sub-pixel) may be set to the minimum. The difference between the areas of illumination of subpixels of different colors leads to different requirements for technological tolerance. When the light emitting layer is formed from subpixels having a smaller luminous area, manufacturing tolerance fluctuations are more likely to affect the quality stability of the film layers inside the hole of the pixel-bounding layer, and thus the manufacturing tolerance of subpixels with different colors can be adjusted according to the luminous area of the subpixel, such as the area of the hole of the pixel bounding layer. In an embodiment of the present disclosure, the area ratio between the second color light emitting area and the second effective light emitting area of the second color subpixel is set to be larger than the area ratio between the first color light emitting layer and the first effective light emitting area of the first color subpixel, so that the manufacturing tolerance of evaporation of the second color subpixel having the smaller effective light emitting area can be set relatively large, thus ensuring that the deviation caused by the evaporation process is more balanced for the respective subpixels.

For example, each subpixel further includes a first electrode such as a cathode (to be described later) disposed on one side of the light emitting layer remote from the base substrate and a second electrode such as an anode (to be described later) disposed on one side of the light emitting layer. layer facing the base substrate. For example, the first color sub-pixel 100 includes a second electrode 120 located on one side of the first color light emitting layer 110 facing the base substrate, and the second color sub-pixel 200 includes a second electrode 220 located on one side of the second color light emitting layer 210, facing the base substrate. For example, the sloped portion 402 may be provided in a position where the pixel-bounding layer 400 defines the opening 401, and the opening 401 is an area surrounded by an intersection line between the sloped portion 402 and the second electrode, or the opening is a partial area of the second electrode exposed by the pixel-limiting layer 400. Taking the first color sub-pixel 100 as an example, the second electrode 120 of the first color sub-pixel 100 may be disposed between the pixel-limiting layer 400 and the base substrate 10, and the pixel-limiting layer 400 includes an opening 401 exposing a portion of the second electrode 120 to limit subpixel. In the case where the first color light emitting layer 110 is formed in the opening 401 of the pixel limiting layer 400, the top and bottom sides of the entire structure are formed from the first color light emitting layer 110, and other functional film layers that are auxiliary to light emitting (for example, one or more layers selected from the group consisting of an electron injection layer, an electron transport layer, a hole injection layer, a hole transport layer, an auxiliary light emitting layer, an electron blocking layer, and a hole blocking layer) are in contact with the first electrode and the second electrode 120, respectively. The first electrode and the second electrode can drive the first color light emitting layer 110 within the hole 401 of the pixel limiting layer 400 to emit light, and the hole 401 of the pixel limiting layer 400 determines the shape of the first effective light emitting area 101 of the first color light emitting layer 110.

For example, as shown in FIGS. 1A and 2, at least a portion of the second effective light emitting regions 201 has a length direction and a width direction, the length direction being the extension direction of the connecting line between two points furthest from each other in one second effective light emitting region 201 ( the V direction as shown in FIG. 1A), and the width direction (U direction as shown in FIG. 1A) is substantially perpendicular to the length direction of the same second effective light emitting region 201. For example, for one second effective light emitting region 201, in the length direction, the ratio of the maximum size of the second color light emitting layer 210 corresponding to the second effective light emitting region 201 to the maximum size of the second effective light emitting region 201 is the first ratio (the maximum size of the second color light emitting layer 210 corresponding to the second effective light emitting region area 201 is divided by the maximum size of the second effective light emitting area 201); in the width direction, the ratio of the maximum size of the second color light emitting layer 210 corresponding to the second effective light emitting region 201 to the maximum size of the second effective light emitting region 201 is the second ratio (the maximum size of the second color light emitting layer 210 corresponding to the second effective light emitting region 201 is divided by the maximum the size of the second effective light emitting region 201); and the first ratio is less than the second ratio. The length direction described above may be the third direction, and the width direction described above may be the fourth direction.

For example, the multiple second effective light emitting regions included in the multiple second color subpixels are substantially the same in shape and area.

For example, the length direction of every second effective light emitting region has an included angle with the line direction. For example, the included angle between the length direction of each second effective light emitting region and the line direction may be 15 to 75 degrees. For example, the included angle between the length direction of each second effective light emitting region and the line direction may be 30 to 60 degrees. For example, the included angle between the length direction of each second effective light emitting region and the line direction may be 40 to 50 degrees.

For example, as shown in FIG. 1A and FIG. 2, the shape of the second effective light emitting region 201 is a long strip such as a hexagon, octagon, trapezoid, ellipse, or rectangle, and so on. The long stripe in an embodiment of the present disclosure may be a regular pattern, such as a symmetrical pattern, where the continuation direction of the symmetrical pattern is its length direction, and the direction perpendicular to the continuation direction is its width direction. The long strip in the embodiment of the present disclosure may also be an irregular pattern, the continuation direction of the irregular pattern is its length direction, and the direction perpendicular to the continuation direction is its width direction. For example, the extension direction (i.e., the length direction) of the long strip-shaped effective light emitting region is the third direction (i.e., the V direction), and the direction perpendicular to the third direction is the fourth direction (i.e., the width direction). For example, the shape of the opening 401 of the pixel-bounding layer 400 corresponding to the second color sub-pixel 200 is a long hexagon or ellipse, and the opening 401 may have a first axis of symmetry parallel to a third direction and a second axis of symmetry parallel to a fourth direction. For example, in the third direction, the first color subpixels 100 and the second color subpixels 200 are alternately arranged.

In an embodiment of the present disclosure, the direction of continuation of the second effective light emitting region in the form of a long strip is defined as the third direction, and in the case where the directions of continuation of different second effective light emitting regions are different, the third directions change along with the directions of continuation of the various second effective light emitting regions. For example, in the case where the extension directions of two adjacent second effective light emitting regions intersect, the third directions corresponding to the two adjacent second effective light emitting regions also intersect. Likewise, the fourth directions change along with the extension directions of the various second effective light emitting regions.

For example, as shown in FIG. 1A and FIG. 2, in the third direction, the ratio of the maximum size of the second color light emitting layer 210 to the maximum size of the second effective light emitting region 201 is the first ratio; in the fourth direction, the ratio of the maximum size of the second color light emitting layer 210 to the maximum size of the second effective light emitting region 201 is the second ratio; and the first ratio is less than the second ratio. In an embodiment of the present disclosure, the maximum size of the second color light emitting layer in a certain direction refers to the maximum size of the orthogonal projection of the second color light emitting layer onto the base substrate in that direction. For example, the ratio of the maximum size of the second color light emitting layer 210 to the maximum size of the second effective light emitting region 201 in the long axis direction of the hole 401 is smaller than the ratio of the maximum size of the second color light emitting layer 210 to the maximum size of the second effective light emitting region 201 in the short axis direction of the hole 401 for in order to avoid affecting the position of the second color light emitting layer formed in the hole of the pixel limiting layer in the case where the hole of the mask plate strongly deviates from the hole of the pixel limiting layer, and to further reduce the influence of the manufacturing tolerance on the second color subpixel in the direction of the short axis of the corresponding limiting hole layer pixels.

For example, for the same second effective light emitting region 201, in the length direction of the second effective light emitting region 201, the difference between the maximum size of the corresponding second color light emitting layer 210 and the maximum size of the second effective light emitting region 201 is the first difference; in the width direction of the second effective light emitting region 201, the difference between the maximum size of the second color light emitting layer 210 and the maximum size of the second effective light emitting region 201 is the second difference; and the first difference is less than the second difference.

For example, the first difference may be in the range of 5 to 15 microns. For example, the first difference may be in the range of 6 to 14 µm. For example, the first difference may be in the range of 7 to 12 µm. For example, the first difference may be in the range of 8 to 11 µm. For example, the second difference may be in the range of 8 to 30 µm. For example, the second difference may be in the range of 9 to 20 µm. For example, the second difference may be in the range of 10 to 18 µm.

For example, both the first difference and the second difference are greater than the pixel position accuracy deviation (ppa) (to be described later).

For example, the minimum size difference values between the light emitting layers and the respective effective light emitting regions of the subpixels at different positions are approximately the same, and for example, the minimum size difference values may be in the range of 7 to 9 µm, and for example, the minimum size difference values may be in the range from 6 to 8 µm.

For example, as shown in FIG. 1A and FIG. 2, in the third direction, the difference between the maximum size of the second color light emitting layer 210 and the maximum size of the second effective light emitting region 201 is the first difference; in the fourth direction, the difference between the maximum size of the second color light emitting layer 210 and the maximum size of the second effective light emitting region 201 is the second difference; and the first difference is smaller than the second difference in order to reduce the influence of the manufacturing tolerance on the second color subpixel in the width direction of the second effective light emitting area.

For example, as shown in FIG. 1A and FIG. 2, in the second color subpixel 200, the ratio of the maximum size of the second color light emitting layer 210 in the third direction to the maximum size of the second color light emitting layer 210 in the fourth direction is less than the ratio of the maximum size of the second effective light emitting layer 210 area 201 in the third direction to the maximum size of the second effective light emitting area 201 in the fourth direction in order to reduce the influence of the manufacturing tolerance on the second color subpixel in the width direction of the second effective light emitting area. That is, the ratio of the maximum size of the second color light emitting layer in the length direction of the second effective light emitting region to the maximum size of the second color light emitting layer in the width direction of the second effective light emitting region is smaller than the ratio of the maximum size of the second effective light emitting region in the length direction of the second effective light emitting region to the maximum size the second effective light emitting region in the width direction of the second effective light emitting region. In some embodiments, the ratio of the maximum size of the second color light emitting layer 210 in the third direction to the maximum size of the second color light emitting layer 210 in the fourth direction, that is, the ratio of the size of the second color light emitting layer 210 in the length direction to the size of the second color light emitting layer 210 in the width direction, is in the range of about 0.8 to 1.2, and, for example, in the range of 0.9 to 1.1, and, for example, it may be 1. The size of the second color light emitting layer 210 in the length direction and the size of the second of the color light emitting layer 210 in the width direction are approximately the same, so that the symmetry of the pattern of the second color light emitting layer 210 is improved, and during the FMM process, the hole on the FMM corresponding to the pattern of the second color light emitting layer 210 is deformed better, and the formed pattern of the second color light emitting layer 210 becomes more accurate .

For example, as shown in FIG. 1A, the flat shape (i.e., the shape of the orthogonal projection onto the base substrate) of the second color light emitting layer 210 of the second color subpixel 200 may be substantially circular, but not limited thereto, and the flat shape may also be oval or polygonal. , such as quadrilateral, pentagon, hexagon, octagon, etc. For example, FIG. 1B shows a partial planar structural view of a display panel in another exemplary embodiment of the present disclosure. As shown in FIG. 1B, the display panel in the present example differs from the display panel shown in FIG. 1A in that the shape of the second color light emitting layer of the second color subpixel may be approximately a rounded rectangle or a rounded square. The shape of the second color light emitting layer of the second color subpixel may also be any other shape such as triangle, quadrilateral, pentagon, hexagon, octagon, etc., and it may be a symmetrical pattern, may be a centrosymmetric pattern, and may be any other irregular pattern. It can be designed according to the layout space of the display panel and the hole distribution of the FMM to improve the hole ratio, ensure the alignment accuracy, or reduce the deformation of the hole pattern on the FMM.

For example, taking as an example that the shape of the second color light emitting layer 210 of the second color subpixel 200 is round, since the hole 401 of the pixel limiting layer 400 limiting the second effective light emitting area 201 of the second color subpixel 200 has a long axis and a short axis, the second a color light emitting layer 210 having a circular shape covers the hole 401 of the pixel limiting layer 400, and, in the long axis direction and the short axis direction corresponding to the hole 401 of the pixel limiting layer 40, the second light emitting layer 210 includes portions located on the outer side of the hole 401 limiting layer 400, that is, areas covering the surface of the pixel limiting layer 400 remote from the base substrate 10. The maximum size and coverage area of the second color light emitting layer 210 covering the pixel limiting layer 400 in the fourth direction (i.e., in the short direction axis) is larger than the maximum size and coverage area of the second color light emitting layer 210 covering the pixel limiting layer 400 in the third direction (that is, the long axis direction). Taking as an example that the shape of the light emitting layer 210 of the second color second color subpixel 200 is oval or hexagonal, for example, the second color light emitting layer 210 covers the hole 401 of the pixel limiting layer 400 in the long axis direction and in the short axis direction of the hole 401 in the pixel limiting layer 400 corresponding to the second color light emitting layer, the second color light emitting layer 210 includes portions located on the outer side of the opening 401 of the pixel bounding layer 400, that is, portions covering the surface of the pixel bounding layer 400 remote from the base substrate 10. The maximum size and the coverage area of the second color light emitting layer 210 covering the pixel limiting layer 400 in the first set of opposite sides that are opposite to each other in the fourth direction (that is, in the short axis direction), respectively, is larger than the maximum size and the coverage area of the second color light emitting layer 210 covering the pixel limiting layer 400 in the second set of opposite sides that are opposite to each other in the third direction (that is, the long axis direction), that is, the ratio of the long axis to the short axis of the second color light emitting layer 210 is smaller, than the ratio of the long axis to the short axis of the opening 401 of the second effective light emitting region 201. The maximum size of the second color light emitting layer 210 in the third direction is the length of the second color light emitting layer 210 in the long axis direction, and the maximum size of the second color light emitting layer 210 in the fourth direction is is the length of the second color light emitting layer 210 in the short axis direction.

For example, FIG. 3 is a partial structural sectional view taken along line BB of FIG. 1A. As shown in FIG. 1A and FIG. 3, the display panel further includes multiple third color sub-pixels 300 located in the display area 11 on the base substrate 10, multiple first color sub-pixels 100 and multiple third color sub-pixels 300 alternately arranged in the first direction, and second direction, and the plurality of third color subpixels 300 and the plurality of second color subpixels 200 are alternately arranged in the short axis direction of the second color subpixel 200. Thus, in the pixel arrangement structure presented in the embodiment of the present disclosure, the second color subpixels are arranged in the array in the row direction and the column direction, the first color subpixels and the third color subpixels are alternately arranged in rows and columns, the rows of the second color subpixel and the rows of the first color subpixel are alternately placed in the column direction, and the columns of the second color subpixel and the columns of the first color the subpixels are alternately arranged in the row direction. Every second color subpixel is surrounded by two first color subpixels and two third color subpixels. For one second color subpixel, two first color subpixels are located on both sides of the second color subpixel in the third direction, and two third color subpixels are located on both sides of the second color subpixel in the fourth direction; alternatively, the first two color subpixels are located on either side of the second color subpixel in the fourth direction, and the two third color subpixels are located on either side of the second color subpixel in the third direction. The third direction, for example, is the first direction (eg, line direction) rotated counterclockwise by an acute angle, such as 45 degrees, and the fourth direction, for example, is the first direction rotated clockwise by an acute angle, such as 45 degrees. In addition, it is also possible to swap the third direction and the fourth direction. The third direction and the fourth direction intersect with both the first and the second directions.

For example, the plurality of first color subpixels and the plurality of second color subpixels are alternately arranged in the third direction to form the first group, the plurality of third color subpixels and the plurality of second color subpixels are alternately arranged in the third direction to form the second group, and the first group and the second group are alternately distributed in fourth direction. The second color subpixels in the second group and the first color subpixels in the first group are alternately placed in the fourth direction, and the second color subpixels in the first group and the third color subpixels in the second group are alternately placed in the fourth direction. The above U direction corresponds to every second color subpixel, the U direction corresponding to some second color subpixels is the fourth direction, and the U direction corresponding to some other second color subpixels is the third direction.

In some embodiments, the first color subpixel, the second color subpixel, and the third color subpixel may also have the same color. For example, the first color subpixel and the second color subpixel emit light of the same color (for example, the light emitting layers of the first color subpixel and the second color subpixel may be made of the same material, or the first color subpixel and the second color subpixel have the same light emitting structure). elements). In some embodiments, for example, the first color subpixel and the third color subpixel emit light of the same color. For example, a fourth color sub-pixel may be included and the light emitted from the fourth color sub-pixel may have a color different from the light emitted from any of the first color sub-pixels, the second color sub-pixels, and the third color sub-pixels, or the light emitted from the fourth color sub-pixels may have the same color as the light emitted by one of the first color subpixels, the second color subpixels, and the third color subpixels.

In the above embodiments, the light color, size, shape, and position distribution of the respective subpixels can be combined arbitrarily. For example, the size and shape of the subpixels may be partly the same and partly different; or completely identical; or completely different. For example, some subpixels are the same size but different shapes. For example, some sub-pixels have substantially the same shape and contour but different area. For example, there may be a different number of second color subpixels around the first color subpixels, and the number may be 2, 3, 4, 5, 6, 7, 8, and so on. These second color subpixels may have approximately the same distance from the first color subpixel, or some of these second color subpixels have the same distance from the first color subpixel and some of these second color subpixels have different distances from the first color subpixel. For example, there may be a different number of third color subpixels around the second color subpixels, and their number may be 2, 3, 4, 5, 6, 7, 8, and so on. These third color sub-pixels may have approximately the same distance from the second color sub-pixel, or some of these third color sub-pixels have the same distance from the second color sub-pixel, and some of these third color sub-pixels have different distances from the second color sub-pixel. For example, there may be a different number of second color subpixels around other third color subpixels, and the number may be 2, 3, 4, 5, 6, 7, 8, and so on. These second color subpixels may have approximately the same distance from the third color subpixel, or some of these second color subpixels have the same distance from the third color subpixel and some of these second color subpixels have different distances from the third color subpixel.

For example, as shown in FIG. 1A and FIG. 2, the multiple third color subpixels 300 include multiple third effective light emitting regions 301, an area of one second effective light emitting region 201 smaller than an area of one third effective light emitting region 301, and multiple third color the subpixels 300 include the plurality of third color light emitting layers 310 located in the respective apertures 401 and on the pixel limiting layer 400 surrounding the respective apertures 401, the plurality of third color light emitting layers 310 included in the plurality of third color subpixels 300 are spaced apart from each other, the ratio areas between the orthogonal projections of the third color light emitting layer 310 and the third effective light emitting region 301 corresponding to the same third color subpixel 300 onto the base substrate is a third area ratio, and a third area ratio less e than the second area ratio.

For example, the third area ratio is greater than 1. For example, the third area ratio may be in the range of 1 to 10. For example, the third area ratio may be in the range of 2 to 8. For example, the third area ratio may be in the range of 3 to 7. For example, the first area ratio may be in the range of 3 to 5. For example, the third area ratio may be in the range of 3 to 5. For example, the second area ratio may be in the range of approximately 5 to 7. For example, the first area ratio may be in the range of approximately 4 to 5. For example, the second area ratio may be in the range of approximately 6 to 7. For example, the third area ratio may be in the range of 3 to 4. For example, the third area ratio may be in the range of 1.5 to 7. For example, the third area ratio may be in the range of 2 to 3. For example, the third area ratio may be in the range one from 3 to 4.

For example, the first color sub-pixel 100 is a red sub-pixel, the second color sub-pixel 200 is a green sub-pixel, and the third color sub-pixel 300 is a blue sub-pixel.

For example, the light output of the third color subpixel is less than the light output of the second color subpixel.

For example, the light output of the third color sub-pixel is less than the light output of the first color sub-pixel.

For example, the ratio of the light output of the third color subpixel to the light output of the second color subpixel is in the range of 0.3 to 1. For example, the ratio of the light output of the third color subpixel to the light output of the second color subpixel is in the range of 0.4 to 1. For example, the light output ratio of the third color The ratio of the light output of the third color subpixel to the light output of the second color subpixel is in the range of 0.6 to 1. For example, the ratio of the light output of the third color subpixel to the light output of the second of the color sub-pixel is in the range of 0.7 to 1. For example, the ratio of the light output of the third color sub-pixel to the light output of the second color sub-pixel is in the range of 0.8 to 1. For example, the ratio of the light output of the third color sub-pixel to the light output of the second color sub-pixel is in the range of 0.9 to 1.

For example, the light output ratio of the third color subpixel to the light output of the first color subpixel is in the range of 0.5 to 1. For example, the ratio of the light output of the third color subpixel to the light output of the first color subpixel is in the range of 0.6 to 1. For example, the light output ratio of the third color subpixel The ratio of the light output of the third color subpixel to the light output of the first color subpixel is in the range of 0.8 to 1. For example, the ratio of the light output of the third color subpixel to the light output of the first color subpixel ranges from 0.9 to 1.

For example, the third area ratio corresponding to the third color subpixel is smaller than the second area ratio corresponding to the second color subpixel.

For example, the third area ratio corresponding to the third color subpixel is smaller than the first area ratio corresponding to the first color subpixel.

For example, the light output value of a subpixel refers to the intensity of light emitted from the light emitting element of the subpixel under the same electrical signal state. If the light intensity of the sub-pixel is high, the light output is said to be large. For example, the same state of the electrical signal means that the voltage written to the data line is the same. For example, the same state of the electrical signal means that the current written into the light emitting element has the same amount. For example, the light output of a subpixel refers to the density of the current flowing through the light emitting element under the same state of the electrical signal.

For example, the aperture ratio of one third color subpixel is greater than the aperture ratio of one second color subpixel.

For example, the aperture ratio of one third color subpixel is greater than the aperture ratio of one first color subpixel.

For example, the luminosity of the third color sub-pixel refers to the area ratio of the area of the third color sub-pixel actually used to emit light into the display area.

For example, the ratio of the aperture ratio of the first color sub-pixel to the aperture ratio of the third color sub-pixel is approximately 1:(1.1~1.9). For example, the ratio of the aperture ratio of the first color sub-pixel to the aperture ratio of the third color sub-pixel is approximately 1:(1.2~1.8). For example, the ratio of the aperture ratio of the first color sub-pixel to the aperture ratio of the third color sub-pixel is approximately 1:(1.3~1.7). For example, the ratio of the aperture ratio of the first color sub-pixel to the aperture ratio of the third color sub-pixel is approximately 1:(1.4~1.6). For example, the ratio of the aperture ratio of the first color sub-pixel to the aperture ratio of the third color sub-pixel is approximately 1:(1.2~1.5).

For example, the ratio of the aperture ratio of the second color sub-pixel to the aperture ratio of the third color sub-pixel is approximately 1:(1.1~1.9). For example, the ratio of the aperture ratio of the second color sub-pixel to the aperture ratio of the third color sub-pixel is approximately 1:(1.2~1.8). For example, the ratio of the aperture ratio of the second color sub-pixel to the aperture ratio of the third color sub-pixel is approximately 1:(1.3~1.7). For example, the ratio of the aperture ratio of the second color sub-pixel to the aperture ratio of the third color sub-pixel is approximately 1:(1.4~1.6). For example, the ratio of the aperture ratio of the second color sub-pixel to the aperture ratio of the third color sub-pixel is approximately 1:(1.2~1.5).

For example, in the display area, the number of second color subpixels is greater than the number of first color subpixels.

For example, in the display area, the ratio of the number of second color subpixels to the number of first color subpixels is about 2.

For example, the ratio of the aperture ratio of the first color subpixel to the aperture ratio of the second color subpixel is in the range of 0.5 to 1.6. For example, the ratio of the aperture ratio of the first color subpixel to the aperture ratio of the second color subpixel is in the range of 0.5 to 1. For example, the aperture ratio of the first color subpixel is in the range of 0.5 to 1. For example, the ratio of the aperture ratio of the first color subpixel to the aperture ratio of the second color The ratio of the aperture ratio of the first color subpixel to the aperture ratio of the second color subpixel is in the range of 0.7 to 1. For example, the ratio of the aperture ratio of the first color subpixel to the aperture ratio of the second color subpixel is in the range of 0 8 to 1. For example, the aperture ratio of the first color subpixel is in the range of 0.8 to 1. For example, the ratio of the aperture ratio of the first color subpixel to the aperture ratio of the second color subpixel is in the range of 0.9 to 1. subpixel to the luminosity of the second color subpixel is in the range from 1 to 1.1. For example, the ratio of the aperture ratio of the first color subpixel to the aperture ratio of the second color subpixel is in the range of 1 to 1.2. For example, the ratio of the aperture ratio of the first color subpixel to the aperture ratio of the second color subpixel is in the range of 1 to 1.3. For example, the ratio of the aperture ratio of the first color subpixel to the aperture ratio of the second color subpixel is in the range of 1 to 1.4. For example, the ratio of the aperture ratio of the first color subpixel to the aperture ratio of the second color subpixel is in the range of 1 to 1.5.

For example, as shown in FIG. 1A and FIG. 3, the third color subpixel 300 includes a third effective light emitting region 301, and the area of the second effective light emitting region 201 is smaller than the area of the third effective light emitting region 301. Every third color subpixel 300 includes The third color light emitting layer 310 provided in the opening 401 of the pixel limiting layer 400 and on the pixel limiting layer 400, and the plurality of third color light emitting layers 310 included in the plurality of third color subpixels 300 are spaced apart from each other. The area ratio between the orthogonal projections of the third color light emitting layer 310 and the third effective light emitting area 301 of each first color subpixel 300 onto the base substrate 10 is smaller than the area ratio between the orthogonal projections of the second color light emitting layer 210 and the second effective light emitting area 201 of each second color subpixel 200 on base substrate 10. In an embodiment of the present disclosure, the area ratio between the second color light emitting layer and the second effective light emitting layer, the area of the second color subpixel is set to be larger than the area ratio between the third color light emitting layer and the third effective light emitting area of the third color subpixel, so that the process margin evaporation of the second color subpixel with an effective light emitting area having a relatively smaller area can be set relatively large, and thus the quality The nature of the second color light emitting layer formed in the second effective light emitting region is more stable, and thus the influence of deviations or fluctuations caused by the evaporation process on the display quality of each subpixel is reduced.

In some embodiments, the area of the first effective light emitting area of the first color subpixel, the area of the second effective light emitting area of the second color subpixel, and the area of the third effective light emitting area of the third color subpixel do not meet the requirements of the above embodiments (for example, the area of the second effective light emitting area 201 is not less than than the area of the third effective light emitting region (the emitting region 301), and for example, the area of the second effective light emitting region 201 is not smaller than the area of the first effective light emitting region 101). However, due to high manufacturing tolerance requirements for the light emitting layer of a certain color, or due to some characteristics (such as diffusion coefficient, volatility, adhesion, etc.) of the material of the light emitting layer of a certain color, the area ratio between the light emitting layer and the effective light emitting area a subpixel with a certain color may be set larger or smaller than the area ratio between the light emitting layer and the effective light emitting area of the subpixel with a different color. In some embodiments, due to different application scenarios, or different display conditions or different display areas, the area ratio between the light emitting layer and the effective light emitting area of a particular subpixel may be set to be larger or smaller than the area ratio between the light emitting layer and the effective light emitting area of another subpixel, which optionally satisfies the ratio of the magnitudes of the corresponding effective light emitting area, or the ratio of the magnitudes of the corresponding light output, or the ratio of the magnitudes of the corresponding luminosity. That is, the ratio of the effective light emitting area, or the ratio of the light output amounts or the ratio of the aperture ratios is not a necessary requirement for the area ratio between the light emitting layer and the effective light emitting area, and factors affecting the area ratio between the light emitting layer and the effective light emitting area may also include process, materials, specific applications, shaping, etc. For example, as shown in FIGS. 1A to 3, the area of the first effective light emitting region 101 of each first color subpixel 100 is smaller than the area of the third effective light emitting region 301 of each third color subpixel 300. layers of subpixels of different colors, the effective light emitting area of each red subpixel is set to be smaller than the effective light emitting area of each blue subpixel.

For example, the area ratio between the orthogonal projections of the first color light emitting layer 110 and the first effective light emitting region 101 of each first color subpixel 100 onto the base substrate 10 is larger than the area ratio between the orthogonal projections of the third color light emitting layer 310 and the third effective light emitting region 301 of each third color subpixel 300 to the base substrate 10. In an embodiment of the present disclosure, the area ratio between the first color light emitting layer and the first effective light emitting region of the first color subpixel is set to be larger than the area ratio between the third color light emitting layer and the third effective light emitting region of the third color subpixel, so that the production margin evaporation process, the second color subpixel having an effective light emitting area of a relatively smaller area can be set relatively large, and thus the quality The property of the second color light emitting layer formed in the second effective light emitting region is more stable, and thus the influence of deviations or fluctuations caused by the evaporation process on the display quality of each subpixel is reduced. The overlapping part between the first color light emitting layer of one first color subpixel and the light emitting layers of other subpixels is the first overlapping part, the overlapping part of the technological margin of the third color light emitting layer of one third color subpixel and the light emitting layers of other subpixels is the second overlapping part, and the overlapping part between the second the color light emitting layer of one second color subpixel and the light emitting layers of the other subpixels is the third overlapping portion. Each of the area ratio between the orthogonal projections of the first overlapping portion and the first color light emitting layer onto the base substrate and the area ratio between the orthogonal projections of the second overlapping portion and the third color light emitting layer onto the base substrate is less than the area ratio between the orthogonal projections of the third overlapping portion and the second color light emitting layer layer on the base substrate.

For example, as shown in FIGS. 1A and 1C, an embodiment of the present disclosure exemplarily shows that the shapes of the apertures 401 limiting the effective light emitting areas of the first color subpixel 100 and the third color subpixel 300 are square or octagonal, that is, the shapes of the first effective light emitting the areas 101 and the third effective light emitting area 301 are square and octagonal; the hole shapes of the mask plate used to form the light emitting layers of the first color subpixel 100 and the third color subpixel 300 are also square or octagonal, that is, the flat shapes of the first color light emitting layer 110 and the third color light emitting layer 310 are substantially square or octagonal; the shape of the hole 401 for forming the second effective light emitting region 201 of the second color subpixel 200 is elliptical, and the shape of the hole on the mask plate used for forming the second color light emitting layer 210 is round.

For example, the shape of the first color light emitting layer 110 is substantially square or rhombic, the length of the hole side of the mask plate corresponding to the first color light emitting layer may be 33 microns; the hole 401 defining the first effective light emitting region 101 has a substantially square or rhombic shape, and its side length may be 15.2 μm. For example, the shape of the second color light emitting layer 210 is substantially round or octagonal, the hole diameter of the mask plate corresponding to the second color light emitting layer may be 33 microns; the shape of the hole 401 defining the second effective light emitting area 201 is essentially any shape selected from the group consisting of ellipse, oval, hexagon, octagon and rectangle, and its long axis may be 14 microns, and its short axis may be 12 microns . For example, the diameter of an octagon may be the size of the octagon in a direction through the geometric center of the octagon and perpendicular to a pair of opposite sides of the octagon. For example, the shape of the third color light emitting layer 310 is substantially square or rhombic, and the diagonal length of the hole on the mask plate corresponding to the third color light emitting layer may be 50 microns; the hole 401 defining the third effective light emitting region 301 has a substantially square or rhombic shape, and its side length may be 18.3 µm. For example, the long axis of a hexagon, octagon, or rectangle may be in their longitudinal direction, and their short axis may be in their width direction, such as in a direction perpendicular to the long axis direction. For example, each polygonal pattern described above may be a pattern with rounded corners.

For example, the orthogonal projection area (flat shape area) of the first color light emitting layer 110 of the first color subpixel 100 onto the base substrate 10 may be 900-1200 square microns, such as 1000-1100 square microns, and the area of the first effective light emitting region 101 may be 150- 300 square microns, for example, 220-240 square microns, and the ratio between the orthogonal projection area of the first color light emitting layer and the area of the first effective light emitting region is 3-6, for example, 4-5. For example, the planar area of the second color light emitting layer 210 of the second color subpixel 200 may be 700-1000 square microns, such as 800-900 square microns, and the area of the second effective light emitting region 201 may be 100-200 square microns, such as 100-150 square microns, and the ratio between the area of the flat shape of the second color light emitting layer and the area of the second effective light emitting region is 5-8, for example, 6-7. For example, the flat shape area of the third color light emitting layer 310 of the third color subpixel 300 may be 1000-1500 square microns, such as 1200-1300 square microns, and the area of the third effective light emitting layer region 301 may be 200-500 square microns, such as 300- 400 square microns, and the ratio between the area of the flat shape of the third color light emitting layer and the area of the third effective light emitting region is 2-6, for example, 3-4. According to the above data, it can be seen that the area ratio between the flat shape area of the second color light emitting layer and the second effective light emitting area of the second color subpixel is larger than the area ratio between the flat shape area of the first color light emitting layer and the area of the first effective light emitting area of the first color subpixel , and the area ratio between the flat shape area of the first color light emitting layer and the area of the first effective light emitting area of the first color subpixel is greater than the area ratio between the flat shape area of the third color light emitting layer and the area of the third effective light emitting area of the third color subpixel.

For example, as shown in FIGS. 1A to 3, the first color light emitting layer 110 and the second color light emitting layer 210 arranged in the third direction and adjacent to each other overlap, and the second color light emitting layer 210 and the third color light emitting layer 310, placed in the fourth direction and adjacent to each other overlap. That is, the boundary of the second color light emitting layer 210 may overlap to some extent with the boundary of the first color light emitting layer 110, and the boundary of the second color light emitting layer 210 may also overlap to some extent with the boundary of the third color light emitting layer 310, thereby improving the resolution of the display panel and the manufacturing tolerance. The term "overlap" in an embodiment of the present disclosure means that the two elements overlap in a direction perpendicular to the base substrate, that is, the orthogonal projections of the two elements onto the base substrate have an overlapping portion.

For example, the formation order of the subpixel light emitting layers may be the first color light emitting layer, the second color light emitting layer and the third color light emitting layer, or the third color light emitting layer, the first color light emitting layer and the second color light emitting layer. For example, taking this order as an example, in which the first color light emitting layer, the second color light emitting layer, and the third color light emitting layer are sequentially formed, the boundary of the third color light emitting layer covers the boundary of the second color light emitting layer, and the boundary of the second color light emitting layer covers the boundary of the first color light emitting layer. light emitting layer. For example, the planar shapes of the first color light emitting layer and the third color light emitting layer are rectangular, the light emitting layers at positions of opposite sides or corners of the first color light emitting layer and the third color light emitting layer may or may not overlap; the planar shape of the second color light emitting layer is circular or elliptical, the part of the second color light emitting layer close to the side or corner of the first color light emitting layer may not be overlapped by the first color light emitting layer, and the part of the second color light emitting layer close to the side or corner of the third color light emitting layer may not be overlapped by the third color light emitting layer.

For example, as shown in FIGS. 1A to 3, the overlapping portion between the first color light emitting layer 110 of one first color subpixel 100 and the light emitting layers of other subpixels is the fourth overlapping portion, the overlapping portion between the third color light emitting layer 310 of one third color subpixel 300 and light emitting layers of other subpixels is the fifth overlapping part, and the overlapping part between the second color light emitting layer 210 of one second color subpixel 200 and the light emitting layers of other subpixels is the sixth overlapping part. Each of the area ratio between the orthogonal projections of the fourth overlapping portion onto the base substrate 10 and the orthogonal projections of the first color light emitting layer 110 onto the base substrate 10 and the area ratio between the orthogonal projections of the fifth overlapping portion onto the base substrate 10 and the orthogonal projections of the third color light emitting layer 310 onto the base substrate 10 is less than the ratio of the areas between the orthogonal projections of the sixth overlapping portion onto the base substrate 10 and the orthogonal projections of the second color light emitting layer 210 onto the base substrate 10.

For example, the second color light emitting layer 210 of the second color sub-pixel 200 is overlapped by other color sub-pixels in both the third direction and the fourth direction. For example, the boundary of the second color light emitting layer 210 overlaps with the boundary of the adjacent first color light emitting layer 110 in the effective light emitting area length direction of the second color light emitting layer 210, and the boundary of the second color light emitting layer 210 overlaps with the boundary of the adjacent third color light emitting layer 310 in the effective light emitting area width direction of the second color light emitting layer 210.

For example, as shown in FIGS. 1A to 3, the first color light emitting layer 110 and the third color light emitting layer 310 adjacent to each other do not overlap, that is, the boundary of the first color light emitting layer 110 cannot overlap with the boundary of the third color light emitting layer 310 adjacent to the first color light emitting layer. The above term "adjacent" means that there is no other first color light emitting layer or a third color light emitting layer between the first color light emitting layer and the third color light emitting layer, and may mean that the first color light emitting layer and the third color light emitting layers are adjacent to at least one of the first direction, the second direction, the third direction and the fourth direction.

For example, the overlap area of the first color light emitting layer 110 and the third color light emitting layer 310 adjacent to each other is smaller than the overlap area of the first color light emitting layer 310 and the second color light emitting layer 210 adjacent to each other and the overlap area of the third color light emitting layer 310 and the second color light emitting layer 210 adjacent to each other.

For example, the maximum size of the overlapping portion between the boundaries of the first color light emitting layer 110 and the third color light emitting layer 310 adjacent to each other in the first direction, and the maximum size of the overlapping portion between the boundaries of the first color light emitting layer 110 and the third color light emitting layer 310 adjacent to each other other in the second direction, less than the maximum size of the overlapping portion between the boundaries of the first color light emitting layer 110 and the second color light emitting layer 210 adjacent to each other in the third direction, and the maximum size of the overlapping portion between the boundaries of the second color light emitting layer 210 and the third color light emitting layer layer 310 adjacent to each other in the fourth direction. In the embodiment of the present disclosure, since the orthogonal projection area of the second color light emitting layer on the base substrate is the smallest, the overlapping area of the second color light emitting layer and other color light emitting layers is set relatively large, thereby increasing the manufacturing tolerance of the second color subpixel.

For example, the distance between the center of the light emitting layer of each subpixel and the center of the corresponding effective light emitting area, that is, the pixel position accuracy deviation (ppa), is less than 6 microns. For example, the ppa deviation may be ±3 µm. For example, in the case where the display panel provided in the embodiment of the present disclosure is applied to vehicle-mounted products, the deviation ppa of each sub-pixel may be -6 to 6 microns, such as -5 to 5 microns. For example, in the case where the display panel provided in the embodiment of the present disclosure is applied to a high PPI display device, the ppa deviation of each subpixel may be ±1.5 microns.

For example, the area of the second color light emitting layer of the second color subpixel is the smallest, and its deviation ppa is the largest fraction of the size of the light emitting layer.

The aforementioned ppa deviation may indicate the alignment accuracy between the precision metal mask and the display panel, which directly affects the alignment accuracy between the hole of the mask plate and the hole of the pixel bounding layer corresponding to the same subpixel. The hole in the mask plate is used to form the light emitting layer, one aspect of the alignment accuracy between the FMM (precision metal mask) and the display panel is the distance between the center of the light emitting layer and the center of the corresponding hole of the pixel bounding layer.

For example, as shown in FIGS. 1A through 3, the pixel-bounding layer 400 includes a flat surface 403 on one side of the pixel-bounding layer 400 spaced from the base substrate 10, wherein the width of the flat surface 403 between the first effective light emitting region 101 and the second effective light emitting region 201 adjacent to each other in the third or fourth direction is approximately equal to the width of the flat surface 403 between the second effective light emitting region 201 and the third effective light emitting regions 301 adjacent to each other in the fourth direction or the third direction. That is, the gaps of the pixel bounding layer between subpixels with different colors (PDL gaps) are approximately the same. For example, the distance between the adjacent first effective light emitting region and the second effective light emitting region in the third or fourth direction is approximately equal to the distance between the adjacent second effective light emitting region and the third effective light emitting region in the fourth or third direction. For example, the distance between the adjacent first effective light emitting region and the second effective light emitting region in the length direction of the second effective light emitting region is approximately equal to the distance between the adjacent second effective light emitting region and the third effective light emitting region in the width direction of the second effective light emitting region.

For example, the width of the pixel limiting layer between the adjacent first effective light emitting region and the second effective light emitting region in the third direction is in the range of 15 to 25 microns; the pixel limiting layer includes a first surface spaced from the base substrate, and between the adjacent first effective light emitting region and the second effective light emitting region, in a plane parallel to the base substrate and in a third direction, the width of the portion of the first surface covered by the first color light emitting layer 0.3-0.8 times smaller than the width of the pixel-limiting layer. For example, the width of the part of the first surface covered with the second color light emitting layer is 0.3 to 0.8 times smaller than the width of the pixel limiting layer. For example, the width of the pixel limiting layer between the adjacent third effective light emitting region and the second effective light emitting region in the third direction is in the range of 15 to 25 microns. For example, the pixel limiting layer includes a second surface spaced from the base substrate and between the adjacent third effective light emitting region and the second effective light emitting region, in a plane parallel to the base substrate, and in the third direction, the width of the portion of the second surface covered by the third color light emitting region layer, 0.3-0.8 times less than the width of the layer limiting the pixels. For example, the width of the portion of the second surface covered with the second color light emitting layer is 0.3 to 0.8 times smaller than the width of the pixel limiting layer.

For example, the width of a portion of the pixel limiting layer 400 between the adjacent first effective light emitting region 101 and the second effective light emitting region 201 in the length direction of the second effective light emitting region 201 may be in the range of 15 to 25 microns, that is, the size of the PDL gap is approximately 15 to 25 micron. For example, the PDL gap size is approximately 16 to 18 microns. For example, when there is an inclined portion at the position of the pixel-bounding layer where the hole is formed, the width of the flat surface 403 of the pixel-bounding layer 400 is smaller than the size of the gap PDL.

For example, the width of the portion of the light emitting layer of each subpixel covering the flat surface 403 of the pixel bounding layer 400 is 0.3 to 0.8 times smaller than the width of the pixel bounding layer 400. The width of the covered portion of the flat surface 403 of the pixel bounding layer 400 in the light emitting layer of each subpixel is 0.4-0.6 times smaller than the width of the flat surface 403.

For example, in a plane parallel to the base substrate and in the length direction (for example, in the third direction) of the second effective light emitting region, the width of the portion of the first surface covered by the first color light emitting layer is 0.3 to 0.8 times smaller than the width of the bounding layer pixels. For example, in a plane parallel to the base substrate and in the length direction (for example, in the third direction) of the second effective light emitting region, the width of the portion of the first surface covered with the second colored light emitting layer is 0.3 to 0.8 times smaller than the width of the bounding layer pixels.

For example, the width of the pixel-bounding layer at each position may be a dimension in a direction substantially perpendicular to the center line of the pixel-bounding layer at each position and passing through the centers of adjacent effective light emitting regions. For example, in the display area, the pixel-bounding layer is shaped like a cell, and the center line (center line CL shown in FIG. 17B) of the pixel-bounding layer at each position may be the center line of each segment of the pixel-bounding layer forming a cell in its continuation direction, the center line is parallel to the extension direction of the pixel-bounding layer segment, and the center line may divide the pixel-bounding layer segment into two parts with approximately the same area on both sides.

In order to realize the dense arrangement of sub-pixels of each color, the processing precision of each sub-pixel must be the same in the manufacturing process, and each light emitting layer not only covers a corresponding hole in the pixel-bounding layer, but also covers approximately half the width of a flat surface between adjacent holes.

For example, the length direction of one second color subpixel 200 is the third direction, and the width direction of the second color subpixel 200 is the fourth direction. The first color light emitting layer 110 covers the pixel limiting layer 400 between the adjacent first color subpixel 100 and the second color subpixel 200, and the width of the part of the first color light emitting layer 110 covering the flat surface 403 of the pixel limiting layer 400 in the third direction, in 0.3-0, 8 times smaller than the width of the pixel limiting layer 400 in the third direction; the second color light emitting layer 210 covers the pixel bordering layer 400 between the adjacent first color subpixel 100 and the second color subpixel 200, and the width of a part of the second color light emitting layer 210 covering the flat surface 403 of the pixel bordering layer 400 in the third direction, in 0.3-0, 8 times smaller than the width of the pixel limiting layer 400 in the third direction.

For example, the length direction of one second color subpixel 200 is the third direction, and the width direction of the second color subpixel 200 is the fourth direction. The third color light emitting layer 310 covers the pixel limiting layer 400 between the adjacent third color sub pixel 300 and the second color sub pixel 200, and the width of a part of the third color light emitting layer 310 covering the flat surface 403 of the pixel limiting layer 400 in the fourth direction, in 0.3-0, 8 times smaller than the width of the pixel limiting layer 400 in the fourth direction; the second color light emitting layer 210 covers the pixel limiting layer 400 between the adjacent third color sub pixel 300 and the second color sub pixel 200, and the width of a part of the second color light emitting layer 210 covering the flat surface 403 of the pixel limiting layer 400 in the fourth direction, in 0.3-0, 8 times smaller than the width of the pixel limiting layer 400 in the fourth direction.

For example, as shown in FIGS. 2 and 3, the edge region of each light emitting layer includes an annular region that extends approximately a certain width in the direction from the outer edge towards the center. In the manufacturing process of the light emitting layer of each color subpixel, each color light emitting layer will diffuse to the periphery for technological reasons, and the inner extension of the light emitting layer may be uneven, so that a shadow region is formed. For example, the annular region includes a shadow region. The annular region is located in the edge region of the light emitting layer, and the width a of the annular region may be 1-4 microns, and for example, may be 3-4 microns, and, for example, may be 1-3 microns. For example, the average thickness of the light emitting layer in the annular region is smaller than the average thickness of the light emitting layer in the effective light emitting region. For example, the light emitting layer of the annular region is located on the outer side of the opening of the pixel-bounding layer, for example, on the pixel-bounding layer. For example, the light emitting layer in the annular region is overlapped by the center line of the corresponding pixel-limiting layer in its extension direction. For example, the average thickness of the light emitting layer in the annular region is less than or equal to 90% of the average thickness of the light emitting layer in the aperture of the pixel-bounding layer. For example, the average thickness of the light emitting layer in the annular region is less than or equal to 95% of the average thickness of the light emitting layer in the aperture of the pixel-bounding layer. For example, the average thickness of the light emitting layer in the annular region is less than or equal to 80% of the average thickness of the light emitting layer in the aperture of the pixel-bounding layer.

For example, taking the first color light emitting layer 110 as an example, the edge regions of the first color light emitting layer 110 adjacent to the adjacent second color light emitting layer 210 and the adjacent third color light emitting layer 310 may be annular regions, and the width in the third direction of the annular region the first color light emitting layer 110 adjacent to the second color light emitting layer 210 is equal to a. The first color light emitting layer 110, which is adjacent to the second color light emitting layer 210 in the first direction, has an annular region which has a width a in the first direction. The first color light emitting layer 110, which is adjacent to the third color light emitting layer 210 in the second direction, has an annular region which has a width a in the second direction.

For example, annular regions of adjacent light emitting layer patterns of different colors overlap. For example, the annular area of the red light emitting layer and the annular area of the green light emitting layer overlap. For example, the annular area of the green light emitting layer and the annular area of the blue light emitting layer overlap. For example, the annular area of the red light emitting layer and the annular area of the blue light emitting layer overlap. For example, in at least some areas, all annular areas of the red light emitting layer, the green light emitting layer, and the blue light emitting layer overlap.

For example, the distance between light emitting layers emitting light of the same color is not less than 10 microns. For example, the distance between light emitting layers emitting light of the same color is not less than 12 microns. For example, the minimum distance between the light emitting layers of green subpixels is at least 11 microns. For example, the minimum distance between light emitting layers of red subpixels is larger than the minimum distance between light emitting layers of green subpixels. For example, the minimum distance between the light emitting layers of the red subpixels is at least 15 microns. For example, the minimum distance between the light emitting layers of the red subpixels is at least 20 microns. For example, the minimum distance between the light emitting layers of the blue subpixels is larger than the minimum distance between the light emitting layers of the green subpixels. For example, the minimum distance between the light emitting layers of a blue subpixel is at least 14 microns. For example, the minimum distance between the light emitting layers of the blue subpixels is at least 18 microns.

For example, the width of the portion of the pixel bounding layer between adjacent subpixels is a', that is, the width of the PDL gap is a'; the width of the overlapped portion of the adjacent light emitting layers is o, and o≥a and o<(0.5*a')-a. For example, the size of the overlapping portion between the adjacent first color light emitting layer and the second color light emitting layer in the third direction is o1, o1≥a and o1<(0.5*a')-a; the size of the portion of the pixel limiting layer between the adjacent third color light emitting layer and the second color light emitting layer in the fourth direction is a', the size of the overlapping portion of the adjacent third color light emitting layer and the second color light emitting layer in the fourth direction is o2, o2≥a and o2<( 0.5*a')-a.

For example, as shown in FIGS. 1A to 3, in the area of each light emitting layer located on the flat surface 403 of the pixel bounding layer 400, the area that is not covered by the light emitting layers of other subpixels is larger than the area that is covered by the light emitting layers of other subpixels. .

For example, the portion of the first color light emitting layer 110 disposed on the flat surface 403 includes a first part overlapped by the second color light emitting layer 210 and a second part not overlapped by the second color light emitting layer 210, the size of the first part in the third direction is smaller than the size the second part in the third direction; the portion of the second color light emitting layer 210 located on the flat surface 403 includes a third part overlapped by the first color light emitting layer 110 and a fourth part not overlapped by the first color light emitting layer 110, the size of the third part in the third direction is smaller than the size of the fourth part in the third direction.

For example, the portion of the third color light emitting layer 310 located on the flat surface 403 includes a fifth part overlapped by the second color light emitting layer 210 and a sixth part not overlapped by the second color light emitting layer 210, the size of the fifth part in the fourth direction is smaller than the size a sixth in the fourth direction; the portion of the second color light emitting layer 210 located on the flat surface 403 includes a seventh part overlapped by the third color light emitting layer 310 and an eighth part not overlapped by the third color light emitting layer 310, the size of the seventh part in the fourth direction is smaller than the size of the eighth part in the fourth direction.

For example, as shown in FIG. 2, on one side of the center line of the PDL gap, in the light emitting layer on the pixel limiting layer, the width of the portion not overlapped with adjacent light emitting layers is larger than the width of the portion overlapped by the adjacent light emitting layer.

For example, as shown in FIGS. 2 and 3, the first color sub-pixel 100 further includes a second electrode 120 between the first color light emitting layer 110 and the base substrate, the second color sub-pixel 200 further includes a second electrode 220 between the second color light emitting layer 210 and the base substrate, and the third color sub-pixel 300 further includes a second electrode 320 between the third color light emitting layer 310 and the base substrate. The second electrode of each subpixel and the pixel limiting layer 400 have an overlapping portion in a direction perpendicular to the base substrate, and the size of the overlapping portion is smaller than the overlapping portion between the light emitting layer of the corresponding subpixel and the pixel limiting layer 400, and also smaller than the overlapping portion between the light emitting layer of the corresponding subpixel and light emitting layers of adjacent subpixels.

For example, the second electrode in each subpixel includes a main base electrode (referring to FIG. 13A), and, in the direction from the center of the effective light emitting region to the edge of the effective light emitting region, the size of the overlapping portion between the main base electrode and the pixel limiting layer does not exceed the size of the overlapping portion between the light emitting layer and the pixel limiting layer. For example, in each subpixel, the shape of the main base electrode and the shape of the effective light emitting region are substantially the same or approximate patterns. Referring to FIG. 13A, in the first color subpixel, the shape of the main base electrode 121 and the shape of the first effective light emitting region 101 are substantially the same, and both are approximately square, for example.

For example, in a display panel, the total luminosity of the first color subpixel 100 may be 4-5.5%, such as 4-5% and, for example, 4.81%. For example, the overall aperture ratio of the second color subpixel 200 may be 4-7%, such as 5-6% and, for example, 5.49%. For example, the total aperture ratio of the third color subpixel 300 may be 5-8%, such as 6-7% and, for example, 6.97%. For example, the PDL gap may be 18-25 microns, such as about 24 microns, such as about 23 microns, such as about 22 microns, such as about 21 microns, such as about 20 microns, and, for example, about 19 microns. For example, the distance between the second electrodes of adjacent subpixels may be 1-6 µm, eg 2-4 µm, eg 2-3 µm, and eg 2.5 µm. For example, the width of the overlapping portion between the second electrode and the pixel-bounding layer may be 0.5-4 µm, such as 1-3 µm, such as 1-2 µm, and, for example, 1.5-1.7 µm.

For example, the aperture ratio of the first color subpixel may be 4.45%, the aperture ratio of the second color subpixel may be 6.20%, and the aperture ratio of the third color subpixel may be 8.53%. For example, the PDL gap may be 19 microns. For example, the distance between the second electrodes of adjacent subpixels may be 5 microns, and the width of the overlapping portion between the second electrode and the pixel-bounding layer may be 2.5 microns.

For example, as shown in FIG. 2, the dimension b of the overlapping portion between the main base electrode of the second electrode 120 in the first color subpixel 100 and the pixel limiting layer 400 in the third direction is smaller than the dimension c of the overlapping portion between the first color light emitting layer 110 and the pixel limiting layer. 400 in the third direction. Similarly, the size of the overlapping portion between the main base electrode of the second electrode 220 in the second color subpixel 200 and the pixel limiting layer 400 in the third direction is smaller than the size of the overlapping portion between the second color light emitting layer 210 and the pixel limiting layer 400 in the third direction.

Note that the second electrode of each subpixel includes a main base electrode (to be described later) and a connection electrode (to be described later) connected to the main base electrode, and the connection electrode is capable of being connected to a pixel circuit (to be described later). For example, the "overlapping portion between the second electrode and the pixel-bounding layer" referred to in the embodiment of the present disclosure may refer to the overlapping portion between the main base electrode of the second electrode and the pixel-bounding layer.

For example, the size b of the overlapping portion between the main base electrode of the second electrode 120 in the first color subpixel 100 and the pixel limiting layer 400 may be smaller than the size of the overlapping portion between the first color light emitting layer 110 and the adjacent second color light emitting layer 210 in the third direction. The size of the overlapping portion between the main base electrode of the second electrode 220 in the second color subpixel 200 and the pixel limiting layer 400 in the third direction is smaller than the size of the overlapping portion between the second color light emitting layer 210 and the adjacent first color light emitting layer 110 in the third direction.

For example, as shown in FIG. 3, the size d of the overlapping part between the main base electrode of the second electrode 220 in the second color subpixel 200 and the pixel limiting layer 400 in the fourth direction is smaller than the size e of the overlapping part between the second color light emitting layer 210 and the pixel limiting layer. 400 in the fourth direction. Similarly, the size of the overlapping portion between the main base electrode 320 in the third color subpixel 300 and the pixel limiting layer 400 in the fourth direction is smaller than the size of the overlapping portion between the third color light emitting layer 310 and the pixel limiting layer 400 in the fourth direction.

For example, the size d of the overlapping portion between the second electrode 220 in the second color subpixel 200 and the pixel limiting layer 400 is smaller than the size of the overlapping portion between the second color light emitting layer 210 and the adjacent third color light emitting layer 310 in the fourth direction. Similarly, the size of the overlapping portion between the second electrode 320 in the third color subpixel 300 and the pixel limiting layer 400 in the fourth direction is smaller than the size of the overlapping portion between the third color light emitting layer 310 and the adjacent second color light emitting layer 210 in the fourth direction.

For example, the width of the overlap area between the pixel limiting layer 400 and the main base electrode of every second electrode is larger than 1.7 microns and, for example, larger than 2 microns. If the size of the portion of the main electrode of every second electrode covered with the pixel-bounding layer is too large, the aperture ratio of the sub-pixel will decrease; however, if the edge of the main base electrode of the second electrode is not covered with a pixel-limiting layer, it will immediately lead to problems of breakdown, short circuit, etc. in the corner of the main base electrode of the second electrode. Thus, under the condition of preventing breakdown, minimizing the overlap area between the pixel-bounding layer and the second electrode can improve aperture ratio for the better, increase display brightness, and reduce power consumption.

In some embodiments, the display panel may not have a touch function, that is, it may not include touch electrodes. In some embodiments, the display panel touch electrodes may not be based on the layout of the touch electrode lines and jumper lines, and for example, the touch electrodes may be flat shaped electrodes. In some embodiments, the display panel touch electrode material may be metal, metal oxide, or any other conductive material.

In some embodiments, spacers may be located on the pixel-bounding layer. In some embodiments, the spacers on the pixel-bounding layer may be integrally formed with the pixel-bounding layer. In some embodiments, the pixel bounding layer may not have separators. For example, separators are located on other film layers. For example, separators are formed on the opposite substrate. For example, separators are formed on the mask plate. In some embodiments, the separators may not be overlaid by the pixel-bounding layer. In some embodiments, the size and area of the separator and the pixel-bounding layer may optionally satisfy the relationship in the following embodiments. For example, a relatively high density of separators is set; for example, the number of separators is approximately equal to the number of pixels, and, for example, the ratio of the number of separators to the number of subpixels is 0.8-1.2. For example, in the direction of the center connecting line of the holes of the adjacent pixel-bounding layer, the spacer size is equivalent to the size of the gap between the holes of the pixel-bounding layer, and, for example, the ratio between the size of the spacer and the size of the gap between the holes of the pixel-bounding layer is approximately 0.8-1.2.

Due to the rapid development of touch technologies, many consumer electronic devices such as mobile phones, GPS navigation systems, tablet personal computers (PCs), personal digital assistants (PDAs) and portable PCs have devices that are combined with a touch input function. At present, the development of touch panels is very diverse, and common technologies include resistive type, capacitive type, optical type, and so on. The capacitive touch panel has become the mainstream touch technology due to its high precision, multi-touch support, high durability and high touch resolution. The principle of operation of the capacitive touch panel is to use touch electrodes to detect changes in the capacitance of the touch points, and use touch signal paths connecting the electrodes in different directions to send signals back to complete the positioning.

In capacitive touch panel technology, the sensing electrode is made of a transparent conductive material such as indium tin oxide. Since the resistivity of the transparent conductive material is higher than that of the metallic conductive material, the problem that the total resistance value is too large to affect the reaction rate may occur when the transparent conductive material is used to form the sensing electrode. Thus, the design of forming the sensing electrode using a metal cell intertwined with metal tracks instead of a transparent conductive material can improve the reaction rate.

With the development of display devices based on flexible organic light emitting diodes, it has become a trend to provide low cost flexible touch solutions. The flexible touch solution includes: making touch electrodes on a thin film (eg encapsulating film layer) to form a touch screen. The encapsulating film layer may be, for example, an inorganic layer or a multilayer structure of an organic layer and an inorganic layer. The material of the inorganic layer may be, for example, silicon nitride; and the material of the organic layer may be, for example, polyimide. After the encapsulating film layer is formed, for example, a silicon dioxide film layer is formed thereon, and then a first cellular metal layer, a sensor insulating layer, and a second cellular metal layer are successively formed on one side of the silicon dioxide film remote from the encapsulating film layer.

According to different touching methods, capacitive touch screens can be divided into capacitive touch screens and mutual capacitive touch screens. Since mutual capacitive touch screens can realize multi-touch support, mutual capacitive touch screens have become a staple in today's touch screen market and a development trend in the future.

Fig. 4 is a partial planar structural view of a touch structure on a display panel shown in an embodiment of the present disclosure, Fig. 5 is an enlarged structural view of region C of Fig. 4, Fig. 6 is a partial structural sectional view, taken along line D-D of FIG. 5 and FIG. 7 is a partial structural sectional view taken along line E-E of FIG. As shown in FIG. 6, each subpixel further includes a first electrode located on one side of the light emitting layer of the second electrode. For example, taking the first color subpixel and the second color subpixel as examples, the first color subpixel 100 includes the first electrode 130, and the second color subpixel 200 includes the first electrode 230.

For example, the first electrode of each subpixel may be formed as a continuous film layer, that is, the first electrode is the common electrode of the subpixel. For example, the encapsulating layer 500 covering the display area 11 and the peripheral area 12 is provided on one side of the first electrode away from the base substrate, and the encapsulating layer 500 covers subpixels in the display area and the pixel limiting layer 400. For example, the encapsulating layer 500 may include the first inorganic encapsulation layer 501, the organic encapsulation layer 502, and the second inorganic encapsulation layer 503, which are sequentially arranged on top of each other. For example, a buffer layer 650 is provided on one side of the encapsulating layer 500 from the first electrode, and a sensor insulating layer 660 is provided on one side of the buffer layer 650 away from the insulating layer 500. The material of the sensor insulating layer 660 may include an inorganic material such as an oxide silicon or silicon nitride, etc.

For example, as shown in FIGS. 4 to 7, at least one embodiment of the present disclosure provides a display panel that includes: a base substrate including a display area and a peripheral area located on the periphery of the display area; plural first color subpixels arranged in the display area, wherein the plurality of first color subpixels are arranged in the first direction to form multiple rows of first color subpixels, the plurality of first color subpixel rows are arranged in the second direction, and adjacent rows of first color subpixels in the plurality of first color subpixel rows are offset relative to each other in the first direction; multiple second color subpixels located in the display area and ordered in the first direction and the second direction, and four second color subpixels surrounding one first color subpixel; a plurality of third color subpixels arranged in the display area, wherein the plurality of first color subpixels and the plurality of third color subpixels are alternately arranged in the first direction and the second direction, the plurality of first color subpixels and the plurality of second color subpixels are alternately arranged in the third direction as a first group, the plurality of third the color subpixels and the plurality of second color subpixels are alternately arranged in the third direction as a second group, the first group and the second group are alternately arranged in the fourth direction, and the third direction and the fourth direction intersect with both the first direction and the second direction; a pixel limiting layer located in a display area and a peripheral area, wherein the pixel limiting layer includes multiple apertures for forming effective light emitting areas of multiple subpixels, the multiple first color subpixels include multiple first effective light emitting regions, the multiple second color subpixels include multiple second effective light emitting regions, and the plurality of third color subpixels include the plurality of third effective light emitting regions. The multiple first color subpixels include multiple first color light emitting layers located in the respective holes and on the pixel-bounding layer surrounding the respective holes, the multiple second color sub-pixels include multiple second color light-emitting layers located in the respective holes and on the pixel-bounding layer, surrounding the respective holes, the plurality of first color light emitting layers included in the plurality of first color subpixels are spaced apart from each other, and the plurality of second color light emitting layers included in the plurality of second color subpixels are spaced apart from each other; the plurality of third color subpixels includes the plurality of third color light-emitting layers located in the respective holes and on the pixel-limiting layer surrounding the respective holes, and the plurality of third color light-emitting layers included in the plurality of third color subpixels are spaced apart from each other.

The display panel further includes: an encapsulating layer located in the display area and the peripheral area; a first sensor electrode layer located on one side of the encapsulating layer remote from the base substrate, wherein the first sensor electrode layer includes multiple first sensor electrodes extending in a first direction and multiple second sensor electrodes extending in a second direction, each first sensor electrode includes multiple blocks of first sensor electrodes, each second sensor electrode includes blocks of multiple second sensor electrodes, the layer of first sensor electrodes includes multiple lines of sensor electrodes, multiple lines of sensor electrodes intersect to form multiple first cells, and like each block of first sensor electrodes, and each block of the second sensor electrodes, include multiple associated with each other first cells; a second sensor electrode layer including multiple connecting bridges, wherein the second sensor electrode layer includes multiple bridges, the multiple bridges intersect to form multiple second cells, each connection bridge includes multiple second cells connected to each other, and adjacent blocks of second sensor electrodes are electrically connected through at least one connecting jumper; a sensor insulating layer located between the first sensor electrode layer and the second sensor electrode layer, and the second sensor electrode unit is electrically connected to the connecting jumper through a through hole passing through the sensor insulating layer. The orthogonal projection of the multiple lines of the sensor electrodes in the display area onto the base substrate is located within the orthogonal projection of the pixel-limiting layer onto the base substrate.

In some embodiments, the first color sub-pixel, the second color sub-pixel, and the third color sub-pixel cannot be placed according to the above embodiments. The sensor electrode line and the bridge of each sensor electrode are located in the space between the light emitting regions of the subpixels, and for example, the orthogonal projection of the sensor electrode line and the bridge of each sensor electrode may be substantially located within the orthogonal projection of the pixel-bounding layer onto the base substrate. In some embodiments, only a partial area of the display panel has a touch function, and the line of touch electrodes and the jumper line of each touch electrode may be placed only in this partial area. In some embodiments, the line of sensor electrodes and the jumper of each sensor electrode are located on a different substrate opposite the base substrate. In some embodiments, the touch electrode line and the jumper line of each touch electrode are located on the touch substrate, and the touch substrate and the base substrate with pixel structures are assembled to form a display panel with a touch function. In some embodiments, the aspect ratio of the area ratio between the subpixel light emitting layer and the corresponding effective light emitting area on the display panel may be the same as set in the above embodiments. In some embodiments, the ratio of the area ratio between the light emitting layer of the subpixel and the corresponding effective light emitting area on the display panel may be different from that set in the above embodiments, that is, the area ratio may not have a certain ratio of values, or the ratio of the area ratio of at least some subpixels may not satisfy the ratio in the above embodiments.

For example, as shown in FIGS. 4 through 7, the display panel further includes a first sensor electrode layer 610 and a second sensor electrode layer 620 located on one side of the buffer layer 650 away from the encapsulating layer 500. For example, the second layer 620 sensor electrodes may be located between the first sensor electrode layer 610 and the encapsulating layer 500, and the sensor insulating layer 660 is further placed between the first sensor electrode layer 610 and the second sensor electrode layer 620. An embodiment of the present disclosure is not limited to this, and the second sensor electrode layer 620 may also be located on one side of the first sensor electrode layer 610 away from the encapsulating layer 500.

For example, the first sensor electrode layer 610 includes multiple first sensor electrodes 611 and multiple second sensor electrodes 612, each first sensor electrode 611 includes multiple first sensor electrodes 6110 disposed in the first direction, and each second sensor electrode includes multiple blocks 6120 of the second sensory electrodes placed in the second direction. The first sensor electrode layer 610 includes multiple sensor electrode lines 6112, and the multiple sensor electrode lines 6112 intersect to form multiple first cells 601. And each first sensor electrode unit 6110 and each second sensor electrode unit 6120 include multiple interconnected first cells 601. As used herein, multiple connected first cells refer to multiple first cells that are electrically connected and combined.

For example, the second sensor electrode layer 620 includes multiple connection bridges 621, each connection bridge includes multiple bridges 6210, the multiple bridges 6210 intersect to form multiple second cells 602, each connection bridge 621 includes multiple second cells connected to each other. 602 and adjacent second sensor electrode units 6120 are electrically connected via at least one connection jumper 621. As used herein, multiple interconnected second cells refer to multiple second cells that are electrically connected and combined.

For example, one of the first touch electrode 611 and the second touch electrode 612 is a touch sensing electrode, and the other of the first touch electrode 611 and the second touch electrode 612 is a touch drive electrode. Both the touch detection electrode and the touch control electrode are formed in the same electrode layer, that is, in the first sensor electrode layer 610 . One kind of touch sensing electrodes and touch control electrodes, such as multiple first touch electrode units 6110, are directly connected, and other types of touch electrodes and control sensor electrodes, such as multiple second sensor electrode units 6120, are disconnected at the position where adjacent blocks are directly connected the first sensor electrodes, and a connecting bridge is formed through the other electrode layer. That is, the line of the first sensor electrode blocks 6110 arranged in the X direction is directly electrically connected, and the line of the second sensor electrode blocks 6120 arranged in the Y direction is electrically connected through the connection jumper 621 in the second sensor electrode layer 620.

For example, in Fig.4 - Fig.5 illustratively shows that two adjacent blocks 6120 of the second sensory electrodes are electrically connected through two connecting jumpers 621, which is not limited to this, and two adjacent blocks of 6120 second sensory electrodes can also be electrically connected through one connecting jumper. jumper or several connecting jumpers.

For example, as shown in FIGS. 4 to 7, the orthogonal projection of the multiple sensor electrode lines 6112 located in the display area onto the base substrate is within the orthogonal projection of the pixel bounding layer 400 onto the base substrate, that is, the line width of each line 6112 sensor electrodes is smaller than the PDL gap width. The width of each line 6112 sensor electrodes is 2-5 microns. For example, the width of each sensor electrode line 6112 may be 3 microns. For example, the material of the sensor electrode line may include metal. For example, the sensor electrode line material may include three layers of Ti/Al/Ti. Since the sensor electrode line includes metal and has a certain width and thickness, it has a certain shielding effect on the light emitted by each color subpixel. So that the touch electrode line does not affect the balance of the entire display, the width of the touch electrode line can be set relatively narrow, and the touch electrode line cannot be overlapped by the effective light emitting area of each subpixel.

For example, the width of the sensor electrode line 6112 may be the same as the width of the jumper line 6210 for ease of manufacture, but without limitation. And the line width of the jumpers can also be larger than the line width of the sensor electrodes.

For example, as shown in FIGS. 4 through 7, in the pixel-bounding layer 400, the segment of the pixel-bounding layer overlapped by the sensor electrode line 6112 has a center line extending in the continuation direction of the sensor electrode line 6112. In the display area, more than 80% of the orthogonal projection of the center line onto the base substrate is located in the orthogonal projection of the sensor electrode line 6112 onto the base substrate. For example, in the display area, more than 90% of the orthogonal projection of the center line onto the base substrate is located in the orthogonal projection of the sensor electrode line 6112 onto the base substrate. For example, with the exception of the break part of the sensor electrode line 6112, the orthogonal projection of the center line onto the base substrate is substantially located in the orthogonal projection of the sensor electrode line 6112 onto the base substrate. For example, the center line of the pixel-bounding layer extending in the direction of the continuation of the line of the sensor electrodes may also be a boundary line equal to half the width of the pixel-bounding layer between effective light-emitting regions of subpixels of different colors.

In some embodiments, the continuation direction of each portion of the sensor electrode line 6112 or jumper line may not be exactly the same as the continuation direction of the corresponding segment of the pixel-bounding layer, and for example, there is a certain included angle between the continuation directions, as noted above. For example, the included angle ranges from 0 to 30 degrees. In some embodiments, certain segments of the pixel-bounding layer have a particular shape or curved portions. For example, some regions have indentations or protrusions, and their direction of continuation may tend to widen the main body portion or the general trend of broadening the curved portion.

In the embodiment of the present disclosure, the sensor electrode line is located at the middle position of the PDL gap, and, for example, the center line of the pixel-bounding layer is covered by the sensor electrode line, which can prevent the touch electrode line from affecting the balance of the entire display of the display panel.

For example, the orthogonal projection of the center line extending in the direction of the extension of the bar line 6210 of the surface of the pixel bounding layer 400 on one side remote from the base substrate onto the base substrate is located within the orthogonal projection of the bar line 6210 onto the base substrate. In the embodiment of the present disclosure, the sensor electrode line is placed at the middle position of the PDL gap, and, for example, the center line of the pixel limiting layer is covered with a jumper line, which can prevent the jumper line from affecting the balance of the entire display of the display panel.

For example, as shown in FIGS. 4 to 7, the first electrode in the effective light emitting area of each subpixel is not overlapped by the sensor electrode line 6112 and the jumper line 6210, and the thickness of the insulating layer between the first electrode and the second sensor electrode layer 620 in the effective light emitting area of each subpixel is larger than the thickness of the insulating layer between the first electrode and the second sensor electrode layer 620 in the non-light emitting region. Since the second sensor electrode layer is formed on the sealing film, the distance between the first electrode and the second sensor electrode layer is small. The signal at the first electrode is a signal for causing the light emitting layer to emit light, and the signal at the sensor electrode layer is a sensor electrode signal; the two signals are different and interference will occur if the distance between the first electrode and the layer of the second sensor electrodes is set too small. thus, by setting a relatively large thickness of the insulating layer between the first electrode and the sensor electrode layer in the effective light emitting area of each subpixel, it is possible to effectively eliminate signal interference between the first electrode and the sensor electrode layer in order to prevent normal display or accuracy from being affected. touch.

For example, as shown in FIG. 6, the first electrodes of the multiple subpixels are an integral film layer, one of the first sensor electrode layer and the second sensor electrode layer, which is closer to the first electrode, is the near layer of the sensor electrodes, the distance between the first electrode in the area effective display and the near layer of the sensor electrodes is greater than the distance between the first electrode on the pixel-limiting layer and the near layer of the sensor electrodes.

For example, the first electrode is an integral film layer, and the distance between the first electrode located in the effective light emitting region and the first sensor electrode layer is greater than the distance between the first electrode located on the outer side of the effective light emitting region and the first sensor electrode layer. For example, the first electrode disposed on the outer side of the effective light emitting region is a portion formed on one side of the particular pixel-bounding layer structure remote from the base substrate and overlapping with the particular pixel-bounding layer structure. For example, there are only a few functional light emitting film layers between the first electrode located on the outer side of the effective light emitting region and the specific structure of the pixel boundary layer, and two surfaces of these light emitting functional film layers, respectively, are in contact with the first electrode located on the outer side. effective light emitting area, and a particular structure of the pixel-limiting layer.

For example, in the display region, the total thickness of the insulating layers between the first electrode located in the effective light emitting region and the near layer of the sensor electrodes is greater than the total thickness of the insulating layer between the first electrode located on the outer side of the effective light emitting region and the near layer of the sensor electrodes. For example, the insulating layers may include insulating layers in the encapsulating layer, such as a first inorganic layer, a first organic layer, a second inorganic layer, and a buffer layer between the encapsulating layer and the sensor electrode layer (e.g., the buffer layer is between the encapsulating layer and the first sensor layer). electrodes in the case where the layer of the first sensor electrodes is located between the layer of the second sensor electrodes and the base substrate). Herein, the total thickness may be the average total thickness of the insulating layers in the effective light emitting region, such as the thickness of the respective insulating layers in each of the first effective light emitting region, the second effective light emitting region, and the third effective light emitting region.

For example, as shown in FIG. 4, multiple first sensor electrodes 610 and multiple second sensor electrodes 620 are connected to terminal area 640 via multiple sensor electrode lines 630, and detection of touch operations and detection of positions at which touch operations take place by means of applying electrical detection signals to multiple sensor electrode lines 630. For example, both sides of the first sensor electrode 610 in the X direction are electrically connected to the sensor electrode lines 630 to realize two-way driving. Of course, the embodiment of the present disclosure is not limited to this, and only one side of the first sensor electrode may be electrically connected to the sensor electrode line to realize one-way driving. A sensor electrode line 630 may be placed around the outer sides of the first sensor electrode and the second sensor electrode. For convenience of description in the accompanying drawings, the space of the area where the line of sensor electrodes is located is increased. The first touch electrode and the second touch electrode may be overlapped by the display area and not covered by the non-display area.

Multiple first sensor electrodes 610 and multiple second sensor electrodes 620 may form capacitors at overlapping positions. When a finger is touched, the coupling of the capacitor near the touch point changes, which leads to a change in the capacitance of the capacitor near the touch point. Thus, by changing the capacitance, one can judge the position of the touch. An embodiment of the present disclosure is not limited to this, and for example, the sensor layer may include a mutual capacitance touch structure, and may also include a touch structure using self capacitance. In addition, the sensor layer can also be made of materials such as nano-silver wires.

For example, FIG. 8 is a schematic representation of the positional relationship between the sensor electrode and the effective light emitting area of each subpixel, and FIG. 9 is an enlarged view of the F region (FIG. 8). As shown in FIGS. 8 and 9, in the display area, the effective light emitting area of each subpixel is located in each first cell 601, that is, one first cell 601 surrounds the effective light emitting area of one subpixel. For example, the shape of the first cell 601 is approximately rectangular. The ratio of the opening area of the first cell 601 corresponding to the first color subpixel to the area of the first effective light emitting region is less than the ratio of the opening area of the first cell 601 corresponding to the second color subpixel to the area of the second effective light emitting region and the ratio of the opening area of the first cell 601 corresponding to the third color subpixel to the area of the third effective light emitting region is less than the ratio of the opening area of the first cell 601 corresponding to the second color subpixel to the area of the second effective light emitting region. The first cell corresponding to each subpixel refers to the cell surrounding the effective light emitting area of the subpixel. In an embodiment of the present disclosure, the area of the effective light emitting area of the second color subpixel is the smallest and has the greatest influence on the integrated brightness uniformity of the display panel. By setting the ratio of the opening area of the first cell corresponding to the second color subpixel to the area of the second effective light emitting region to the maximum, it is possible to reduce the limitation of the sensor electrode line on the light emission angle of the second color subpixel. The above "first cell opening area" refers to the area of the hollow area surrounded by lines of sensor electrodes. For example, the shape of the hollow region may be approximately rectangular.

For example, the shape of the first cell corresponding to the first color subpixel may be rectangular, and for example, it may be approximately square. The two sides of the rectangle may be 30-33 microns in length, their area may be 900-1000 square microns, the opening area of the pixel-bounding layer corresponding to the first color sub-pixel may be 200-250 square microns, and the ratio of the two areas may be 4-5 . For example, the shape of the first cell corresponding to the second color sub-pixel may be rectangular, the two sides are 28-31 microns and 30-33 microns in length, respectively, and its area may be 850-1100 square microns, for example, 900-1000 square microns, the hole area the pixel-bounding layer corresponding to the second color sub-pixel may be 100-180 square microns, eg 100-150 square microns, and the ratio of the two areas may be 5-9, eg 7-8. For example, the shape of the first cell corresponding to the third color sub-pixel may be rectangular and, for example, may be approximately square. The length of the two sides is 30-38 microns, their area may be 900-1300 square microns, for example, 1100-1200 square microns, the opening area of the pixel-bounding layer corresponding to the third color sub-pixel may be 300-400 square microns, and the ratio of the two areas can be 3-4.

For example, in the direction of the connecting line from the center of the first effective light emitting area of the first color subpixel to the center of the second effective light emitting area of the second color subpixel adjacent to the first color subpixel, the size of the part of the pixel limiting layer covered by each light emitting layer is in the range of 5 to 15 microns. for example, the size may be in the range of 7 to 13 microns.

For example, the distance between the edge of the line of sensor electrodes and the edge of the opening of the pixel-bounding layer close to each other may be 3.5-13.5 microns, and, for example, 3.5-11.5 microns. In the embodiment of the present disclosure, by designing the distance between the boundary of the sensor electrode line and the edge of the hole of the pixel-bounding layer relatively large, it can be ensured that the line of touch electrodes is as far away from the hole of each pixel-bounding layer as possible, and shielding the light emitted from of each subpixel by the sensor electrode line is reduced, thereby avoiding the color deviation caused by unbalanced screening of different colored subpixels by the sensor electrode lines.

For example, as shown in FIGS. 4-8, each second cell 602 is V-shaped, and both V-shaped endpoints are electrically connected to second sensor electrode assemblies 6120 through openings 603 in sensor insulating layer 660. The second sensor electrode units 6120 can be electrically connected via two connection bridges 621, and the V-shaped holes of the two connection bridges 621 are located opposite each other. An embodiment of the present disclosure is not limited thereto, and adjacent second contact electrodes may also be electrically connected via a single connection bridge or multiple connection bridges.

For example, every second cell 602 corresponds to two first effective light emitting regions 101, five second effective light emitting regions 201, and two third effective light emitting regions 301. For example, the second effective light emitting region 201 is located in the second cell, where the two end points closest to V figurative hole. For example, the ratio of sub-pixels on the display panel is such that the ratio of the first color sub-pixel, the second color sub-pixel, and the third color sub-pixel is 1:2:1, and the ratio between the first color sub-pixel and the third color sub-pixel surrounded by the connecting bridge 621 is less than than the numerical ratio between the first color sub-pixel and the third color sub-pixel in the display area, which makes it possible to reduce restrictions on light emitted from the first color sub-pixel and the third color sub-pixel and improve the luminous efficiency of the first color sub-pixel and the luminous efficiency of the third color sub-pixel.

FIG. 10 is a partial planar structural view of a pixel structure shown in another embodiment of the present disclosure, and FIG. 11 is a schematic representation of the positional relationship between the pixel structure and the sensor electrode line shown in FIG. 10. FIG. As shown in Fig. 10 and Fig. 11, spaces 20 are provided between the first color light emitting layer 110, the second color light emitting layer 210, and the third color light emitting layer 310 which are adjacent to each other, the first color light emitting layer 110 is shaped including the first rounded rectangle and the first protruding portion 1101 located in the rounded corner of the first rounded rectangle and protruding towards the gap 20. The second color light emitting layer 210 has a shape including the second rounded rectangle and the first protruding portion 1101 protrudes at least partially from a straight edge extension line of the first rounded rectangle closest to the second color light emitting layer 210, and, for example, the straight edge is parallel to the edge of the corresponding effective light emitting area adjacent to the straight edge. The third color light emitting layer 310 has a shape including a third rounded rectangle and a second protruding portion 3101 located in the rounded corner of the third rounded rectangle and protruding towards the gap 20, and the second protruding portion 3101 at least partially protrudes from the line extending the straight edge of the third a rounded rectangle closest to the second color light emitting layer 210, and, for example, the straight edge is parallel to the edge of the corresponding effective light emitting region closest to the straight edge. In the pixel structure shown in the embodiment of the present disclosure, the shape of the first color light emitting layer includes a first protruding portion located in the rounded corner of the first rounded rectangle and protruding in the gap direction. Compared with the first color light emitting layer without the first raised portion, the first raised portion of the first colored light emitting layer in the embodiment of the present disclosure occupies part of the gap area, that is, the gap area is reduced; thus, on the one hand, the gap utilization can be increased, and on the other hand, the distance between the rounded edge of the first colored light emitting layer and the rounded edge of the corresponding second electrode (i.e., anode) can be increased, thereby reducing or even avoiding the risks of defects such as color mixing, color deviation, etc., and improving the yield of good parts. For example, the gap may be an area surrounded by one first color light emitting layer, one second color light emitting layer, and one third color light emitting layer, which are adjacent to each other and distributed in a triangular shape, and there is no light emitting layer in the area. One first color light emitting layer, one second color light emitting layer and one third color light emitting layer that are adjacent to each other and distributed in a triangular shape, for example, one first color light emitting layer and one third color light emitting layer that are adjacent to each other with the other in the same row, and one second color light emitting layer that is in an adjacent row and is adjacent to both the first color light emitting layer and the third color light emitting layer.

For example, the orthogonal projections of the first raised portion and the second raised portion onto the base substrate are at least partially overlapped by the orthogonal projection of the sensor electrode line onto the base substrate.

For example, the overlapping portion of the edges of the light emitting layers of two adjacent subpixels with different colors on the pixel limiting layer 400 is an overlapping portion 21, and the orthogonal projection of the sensor electrode line 6112 onto the base substrate is overlapped by at least a portion of the orthogonal projection of the overlapping portion 21 onto the base substrate.

In some embodiments, the pixel arrangement shown in Fig. 10 may not be applied, and for example, a pixel arrangement such as the stripe arrangement shown in Fig. 1E, one triangular arrangement shown in Fig. 1H, the other triangular the layout shown in FIG. 1F or the tiled layout shown in FIG. 1G. For example, as shown in FIG. 1H, by setting the size of the blue sub-pixel 300 to be larger than the size of the red sub-pixel 100 and the size of the green sub-pixel 200, the service life of the display panel can also be increased.

For example, as shown in FIGS. 10 and 11, in the display area, an orthogonal projection of more than 50% of the sensor electrode line 6112 onto the base substrate is located within the orthogonal projection of the overlapping portion 21 onto the base substrate. For example, in the display region, an orthogonal projection of more than 50% of the line of the sensor electrodes onto the base substrate is located within the orthogonal projection of the overlapping portion of the light emitting layer onto the base substrate, and the overlapping portion of the light emitting layer includes an overlapping portion of at least two selected from the group consisting of a first color light emitting layer, a second color light emitting layer, and a third color light emitting layer. For example, in the display area, an orthogonal projection of more than 70% of the line of the sensor electrodes onto the base substrate is located within the orthogonal projection of the overlapping portion of the light emitting layer onto the base substrate. For example, in the display area, an orthogonal projection of more than 80% of the sensor electrode line onto the base substrate is located within the orthogonal projection of the overlapping portion of the light emitting layer onto the base substrate. The overlapping part of the light-emitting layers of different colors due to crosstalk can easily produce some unwanted colors and may lead to a display defect, and in order to reduce the effect of crosstalk, the sensor electrode lines can be used to partially shield to improve the display effect.

In the evaporation process of the light emitting layer using the FMM, the distance between the FMM hole and the edge of the second electrode of each subpixel is a key parameter to ensure the evaporation output. However, for the conventional FMM, due to the influence of the manufacturing process, the actual distance between the rounded edge of the FMM hole and the anode edge may not reach the theoretical design value, so that the holes of different FMMs in the FMM set are different. That is, the gap between adjacent light emitting layers of different colors is relatively large and may not be fully utilized, which increases the risk of defects such as color mixing and color deviation, etc. Thus, by designing a new FMM and using the aforementioned gap, the distance between the rounded edge of the FMM hole and the rounded edge of the second electrode of each subpixel is made relatively large, that is, the rounded edge of the FMM hole is compensated (increased in size), thereby reducing or even avoiding the above-mentioned risks of occurrence. defects such as color mixing, color deviation, etc., and improving the yield of good parts. It should be noted that the distance between the FMM hole and the edge of the second electrode mentioned above refers to the distance between the edge of the orthogonal projection of the FMM hole onto the base substrate including the second electrode and the edge of the second electrode, not a three-dimensional distance.

In the precision metal mask processing, for the corner position of the light emitting layer, such as the nearest position of the light emitting layers of the first color subpixel and the third color subpixel, the film layer material may be missing or the quality of the film layer is defective. Thus, for opposite portions of the first color subpixel and the third color subpixel, the pattern shape of the light emitting layer can be adjusted; for example, the position of the hole corner of the precision metal mask is smoothed, and the hole of the precision metal mask protrudes outward to both sides of the corner, so that the quality of the film layer at the position corresponding to each corner and the manufacturing tolerance at the corner position can be improved.

In some embodiments, the implementation of the light emitting layer having a raised portion may have any other shape, such as a triangle, quadrilateral, pentagon, hexagon or octagon. In some embodiments, adjacent light emitting layers may not be distributed at the corners; for example, portions of adjacent light emitting layers closest to each other may also be distributed in a corner-to-edge or edge-to-edge manner, or completely shifted (i.e., orthogonal projections of opposite and nearest portions of two adjacent light emitting layers on a straight line in between between two light-emitting layers basically do not overlap).

For example, taking the center line of the part of the pixel bounding layer between the first color subpixel and the second color subpixel as the baseline, at least part of the first color light emitting layer passes through the center of the line, and at least part of the center line is located in the overlapping area of the light emitting layers of the first color subpixel and a second color subpixel. Similarly, taking the center line of a portion of the pixel-bounding layer between the second color sub-pixel and the third color sub-pixel as a reference, at least a portion of the second color light emitting layer extends through the center line, and at least a portion of the center line is located in the light emitting overlap region. layers of the second color sub-pixel and the third color sub-pixel.

For example, by adjusting the shapes of at least a portion of the light emitting layers, a boundary of each light emitting layer can be overlapped by a boundary of an adjacent light emitting layer. For example, for an edge region where the composition or thickness changes, a molecular probe can be used to measure the number of molecules and the thickness of materials. For example, for the overlapping part of the light emitting layers of the first color subpixel and the second color subpixel, the film layer material of the overlapping part, which is close to the center of the light emitting layer of the first color subpixel, is mainly the material of the light emitting layer of the first color subpixel, and is complemented by the material of the second color light emitting layer, and the thickness the first color light emitting layer is greater than the thickness of the second color light emitting layer. At least a portion of the concave-convex shape that appears at the boundary position of the light emitting layer of each subpixel (that is, the planar shape of the boundary position of the light emitting layer is a concave-convex shape) is covered with a line of sensor electrodes, and the uniformity of the film layer of the light emitting layer pattern near the center of the gap The PDL of the pixel bounding layer is bad. Since the lateral leakage current may lead to unwanted light or crosstalk between adjacent light emitting layers, the display quality of a display panel can be improved by using a line of sensor electrodes to shield the overlapping part of the boundaries of the light emitting layers.

For example, the line width of the sensor electrodes may be 3 microns, and if the boundaries of two adjacent light emitting layers are connected, the width of the shadow region may be 2a, that is, 6-8 microns. For example, in the direction of a connecting line connecting the hole centers of two adjacent pixel-bounding layers, the width of the overlapping part of the borders of the adjacent light-emitting layers may be less than 6-8 microns. For example, the orthogonal projection of the line of the sensor electrodes, located at least in an intermediate position between the first color subpixel and the second color subpixel on the base substrate, completely falls into the orthogonal projection of the overlapping part of the borders of the light emitting layers on the base substrate. For example, for positions of opposite angles between the first color light emitting layer of the first color subpixel and the third color light emitting layer of the third color subpixel, there can be no overlap of the light emitting layers, so the part of the line of the sensor electrodes cannot be overlapped by the overlapping area of the light emitting layers. Thus, the orthogonal projection of at least 50% of the line of the sensor electrodes in the display area onto the base substrate is located within the orthogonal projection of the overlapped area of the light emitting layers onto the base substrate. For example, an orthogonal projection of at least 80% of the line of the sensor electrodes in the display area onto the base substrate is located within the orthogonal projection of the overlapping area of the light emitting layers onto the base substrate, thereby reducing cross color caused by overlapping of the light emitting layers.

For example, each subpixel includes an organic light emitting element and a pixel circuit connected to the organic light emitting element, and each pixel circuit is located between the organic light emitting element and the base substrate.

For example, FIG. 12A is a schematic representation of a pixel circuit included in each subpixel, and FIG. 12B is a schematic representation of the position relationship of each transistor of each subpixel in the active layer and the gate line layer. As shown in FIGS. 12A and FIG. 12B, taking the first color sub-pixel as an example, for example, the first color sub-pixel 100 includes an organic light emitting element 1100 and a pixel circuit 1200. The first color sub-pixel pixel circuit 1200 may include a driving transistor T1 , the first light emission control transistor T4, the second light emission control transistor T5, the data recording transistor T2, the storage capacitor C, the threshold value compensation transistor T3, the first reset transistor T6, and the second reset transistor T7. The driving transistor T1 includes a gate electrode, a first electrode, and a second electrode, and is configured to provide the organic light emitting element 1100 with a drive current that is used to drive the organic light emitting element 1100 to emit light. The display panel further includes a data line Vd (shown in FIG. 13A) located at the same level as the power signal transmission line VD-D (shown in FIG. 13A), and the data line runs in the same direction as and power signal transmission line; the display panel further includes a gate line Ga, a light emission control signal line EM, and a reset control signal line Rst, which are located on one side of the power signal transmission line facing the base substrate and parallel to each other, and the extension direction of the gate line intersects with the direction extension of the data line, and, for example, the extension direction of the gate line is perpendicular to the extension direction of the data line; the display panel further includes a power reset signal line (not shown) extending in the first direction, which is located between the film layer where the gate line is located and the film layer where the data line is located.

For example, as shown in Fig. 12A, Fig. 12B and Fig. 13A, the first electrode of the data recording transistor T2 is electrically connected to the first electrode of the control transistor T1, the second electrode of the data recording transistor T2 is electrically connected to the data line Vd to receive a signal data, and the gate electrode of the data recording transistor T2 is configured to be electrically connected to the gate line Ga to receive the scanning signal; the first electrode CC1 of the storage capacitor C is electrically connected to the first voltage terminal VD-D, and the second electrode CC2 of the storage capacitor C is electrically connected to the gate electrode of the driving transistor T1; the first electrode of the threshold compensation transistor T3 is electrically connected to the second electrode of the control transistor T1, the second electrode of the threshold compensation transistor T3 is electrically connected to the gate electrode of the control transistor T1, and the gate electrode of the threshold compensation transistor T3 is electrically connected to the gate line Ga for receiving a compensation control signal; the first electrode of the first reset transistor T6 is electrically connected to the power reset signal line Vinit to receive the reset signal, the second electrode of the first reset transistor T6 is electrically connected to the gate electrode of the control transistor T1, and the gate electrode of the first reset transistor T6 is electrically connected to a reset control signal line Rst for receiving a reset control signal; the first electrode of the second reset transistor T7 is electrically connected to the power reset signal line Vinit to receive the reset signal, the second electrode of the second reset transistor T7 is electrically connected to the second electrode of the organic light emitting element 1100, and the gate electrode of the second reset transistor T7 is electrically connected with a reset control signal line Rst for receiving a reset control signal; the first electrode of the first light emission control transistor T4 is electrically connected to the first voltage terminal VD-D, the second electrode of the first light emission control transistor T4 is electrically connected to the first electrode of the control transistor T1, and the gate electrode of the first light emission control transistor T4 is electrically connected with a light emission control signal line EM for receiving a light emission control signal; the first electrode of the second light emission control transistor T5 is electrically connected to the second electrode of the light emission control transistor T1, the second electrode of the second light emission control transistor T5 is electrically connected to the second electrode of the organic light emitting element 1100, and the gate electrode of the second light emission control transistor T5 is configured to electrically connecting to a light emission control signal line EM for receiving a light emission control signal; the first electrode of the organic light emitting element 1100 is electrically connected to the second voltage terminal VSS.

For example, one of the first voltage terminal VD-D and the second voltage terminal VSS is a high voltage terminal, and the other of the first voltage terminal VD-D and the second voltage terminal VSS is a low voltage terminal. For example, in the embodiment shown in FIG. 12A, the first voltage output VD-D is a voltage source for outputting a constant first voltage, which is a positive voltage; and the second voltage output VSS may be a voltage source for the constant second voltage output, which is a negative voltage.

For example, according to the characteristics of transistors, transistors can be divided into n-type transistors and p-type transistors. In the embodiment of the present disclosure, the transistors are assumed to be p-type transistors (for example, p-type MOSFETs) as an example, that is, in the description of the present disclosure, the control transistor T1, the data recording transistor T2, the threshold compensation transistor T3, the first light emission control transistor T4, the second light emission control transistor T5, the first reset transistor T6 and the second reset transistor T7, and so on. may be p-type transistors. However, the transistors in the embodiment of the present disclosure are not limited to p-type transistors, and those skilled in the art may also implement the functions of one or more transistors in the embodiment of the present disclosure using n-type transistors (e.g., n-type MOSFETs) in according to actual needs. The transistors used in the embodiment of the present disclosure may be thin film transistors, or FETs or other switching elements having the same characteristics, and the thin film transistors may include oxide semiconductor thin film transistors, amorphous silicon thin film transistors, or polysilicon thin film transistors, etc. .d. The source electrode and drain electrode of a transistor may be symmetrical in structure, so the source electrode and drain electrode may be indistinguishable in physical structure. In an embodiment of the present disclosure, in order to distinguish between the transistor electrodes, as in the case of electrodes other than the gate electrode that serves as the gate electrode, it is explicitly described that one of them is the first electrode and the other is the second electrode, so the first electrode and the second the electrode of all or part of the transistors in the embodiment of the present disclosure can be replaced if necessary.

Note that, in an embodiment of the present disclosure, the pixel circuit may have a 7T1C structure (i.e., seven transistors and one capacitor) as shown in Fig. 1, and may also have a structure including a different number of transistors and capacitors, such as a structure 7T2C, 6T1C pattern, 6T2C pattern, or 9T2C pattern, without limitation in an embodiment of the present disclosure. In an embodiment of the present disclosure, the pixels may be based on any arrangement method such as a stripe arrangement, a triangular arrangement, a tiled arrangement, and so on. In an embodiment of the present disclosure, the RGB numeric proportion in a single pixel block or repeat block may have any one or combination of two or more elements selected from the group consisting of 1:1:2, 1:2:1, 2:2:1 , 1:1:1, 1:2:3, 3:3:2, 1:3:2, 2:3:1, 3:2:3, 2:3:3, etc. For example, RGBs may be the same size or may not be the same size. For example, the size of the hole in the pixel limiting layer for limiting the light emitting layer B is larger than that of R, and the size of the hole in the pixel limiting layer for limiting the light emitting layer B is larger than that of G. For example, the size of the hole in the pixel limiting layer for limiting the light emitting layer B larger than R, and the size of the hole in the pixel limiting layer for limiting the light emitting layer R is larger than that of G. For example, the size of the hole in the pixel limiting layer for limiting the light emitting layer B is larger than R, and the size of the hole in the pixel limiting layer for limiting the light emitting layer, R is the same as G. For example, the size of the hole in the pixel limiting layer for limiting the light emitting layer B is the same as R, and the size of the hole in the pixel limiting layer for limiting the light emitting layer R is larger than G. For example, the size of the hole in the pixel limiting layer for limiting the light emitting layer R b larger than G. For example, the size of the hole in the pixel limiting layer for limiting the light emitting layer of G is larger than R. For example, the size of the hole in the pixel limiting layer for limiting the light emitting layer of G is larger than that of B. For example, the number of subpixels included in each repeating block or pixel block can be any one or a combination of two or more elements selected from the group consisting of 2, 3, 4, 5, 6, 7, 8, 9, 10, etc.

In some embodiments, some subpixels of the same color may have different area effective light emitting areas. For example, in some embodiments, subpixels included in one repeating block or pixel block include two green subpixels of the same color, two red subpixels of the same color, two blue subpixels of the same color, or two pairs of subpixels, where each pair of subpixels of the same color (for example, two green subpixels and two red subpixels), and the areas of effective light emitting regions of the subpixels of the same color may be different. In some embodiments, in the case where subpixels of the same color are located in an extreme position, in a special shape region, or in a folding region, etc., their effective light emitting regions may have different areas or shapes relative to the effective light emitting regions of the subpixels of the same and the same color in other areas.

In the above-described embodiments, the luminescence color, size, shape, and position of each sub-pixel can be freely combined. For example, the size and shape of the subpixels may be partly the same and partly different; either completely the same or completely different. For example, some subpixels are the same size but different shapes. For example, some subpixels have almost the same shape outline, but different areas. For example, there may be a different number of second color subpixels around the first color subpixels, and the number of second color subpixels may be 2, 3, 4, 5, 6, 7, 8, and so on. The second color subpixels may have approximately the same distance from the first color subpixel, or some of these second color subpixels have the same distance from the first color subpixel and some of these second color subpixels have different distances from the first color subpixel. For example, there may be a different number of third color subpixels around other second color subpixels, and the number of third color subpixels may be 2, 3, 4, 5, 6, 7, 8, and so on. The third color subpixels may have approximately the same distance from the second color subpixel, or some of these third color subpixels have the same distance from the second color subpixel and some of these third color subpixels have different distances from the second color subpixel. For example, there may be a different number of second color subpixels around other third color subpixels, and the number of second color subpixels may be 2, 3, 4, 5, 6, 7, 8, and so on. The second color subpixels may have approximately the same distance from the third color subpixel, or some of these second color subpixels have the same distance from the third color subpixel and some of these second color subpixels have different distances from the third color subpixel.

FIG. 13A is a schematic representation of a positional relationship between a pixel circuit and a line of sensor electrodes shown in an exemplary embodiment of the present disclosure. As shown in FIG. 13A, at least one electrode selected from the group consisting of the second electrode 120 of the first color sub-pixel 100, the second electrode 220 of the second color sub-pixel 200, and the second electrode 320 of the third color sub-pixel 300 is overlapped by the sensor electrode line 6112.

For example, as shown in FIG. 13A, the second electrode 220 in the second color subpixel 200 includes a main base electrode 221, a connection electrode 222, and an auxiliary electrode 223. For example, the main base electrode, the connection electrode, and the auxiliary electrode of the second color subpixel 200 are integrated electrode.

For example, in the second electrode 220 of the second color subpixel 200, the main base electrode 221 is covered by the second effective light emitting region 201, and the shape of the main base electrode 221 is approximately the same as that of the second effective light emitting region 201; and the connection electrode 222 and the auxiliary electrode 223 are not overlapped by the second effective light emitting region 201. For example, the connection electrode 222 is configured to be electrically connected to the second electrode of the second light emission control transistor T5. For example, the auxiliary electrode 223 is covered by the driving transistor T1, and the sensor electrode line 6112 is not covered by the second electrode 220 of the second color subpixel 200.

For example, as shown in FIG. 13A, the second electrode 120 of the first color subpixel 100 includes a main base electrode 121 and a connection electrode 122, the main base electrode 121 overlaps the first effective light emitting region 101, and the shape of the main base electrode 121 is approximately the same as and the shape of the first effective light emitting region 101; and the connecting electrode 122 does not overlap with the first effective light emitting region. For example, the connection electrode 122 is configured to be electrically connected to the second electrode of the second light emission control transistor T5. For example, the second electrode 120 of the first color subpixel 100 is overlapped by the sensor electrode line 6112, and, for example, the connection electrode 122 of the first color subpixel 100 is overlapped by the sensor electrode line 6112.

For example, as shown in FIG. 13A, the second electrode 320 of the third color subpixel 300 includes a main base electrode 321 and a connection electrode 322, the main base electrode 321 is covered by the third effective light emitting region, and the shape of the main base electrode 321 is approximately the same as and the shape of the third effective light emitting region; and the connecting electrode 322 is not overlapped by the third effective light emitting region. For example, the connection electrode 322 is configured to be electrically connected to the second electrode of the second light emission control transistor T5. For example, the second electrode 320 of the third color subpixel 300 is overlapped by the sensor electrode line 6112, and, for example, the connecting electrode 322 of the third color subpixel 300 is overlapped by the sensor electrode line 6112.

For example, at least one electrode selected from the group consisting of the second electrode of the first color subpixel, the second electrode of the second color subpixel, and the second electrode of the third color subpixel is overlapped by a line of sensor electrodes; and/or the control transistor of at least one selected from the group consisting of the first color sub-pixel, the second color sub-pixel and the third color sub-pixel is covered by a line of sensor electrodes. The second electrode not only functions as a driving electrode of the light emitting element for emitting light, but can also be used, for example, to shield a part of the structure of some transistors, which can better perform an additional shielding role by overlapping the sensor electrode line.

For example, as shown in FIG. 13A, the driving transistor T1 of the second color subpixel 200 is covered by the sensor electrode line 6112, while the driving transistors of the first color subpixel 100 and the third color subpixel 300 are not covered by the sensor electrode line 6112. The above case in which the driving transistor is covered by the sensor electrode line includes that the gate electrode of the driving transistor (for example, the second storage capacitor electrode CC2 shown in FIG. 12B) is covered by the sensor electrode line. Of course, the embodiment of the present disclosure is not limited to this. The driving transistor T1 further includes a source electrode region T11 and a drain electrode region T12, which are obtained by doping, etc., to be electrically connected to each structure. The case in which the driving transistor T1 is overlapped by the sensor electrode line may also include that the source electrode region T11 and the drain electrode region T12 of the driving transistor are overlapped by the sensor electrode line. The driver transistor plays an important role in the output current of the pixel circuit, and the size of the driver transistor (for example, the size of the gate electrode or the size of the source and drain electrodes and the size of the semiconductor region between the source and drain electrodes) is generally larger than the size of other transistors. In addition, lighting and other factors freely affect the driving transistor, so by using the sensor electrode line to partially shield the driving transistor, the driving transistor can be better stabilized so that the output current is less likely to interfere.

For example, as shown in FIG. 13A, the second electrode 220 of the second color subpixel 200 is not substantially overlapped by the sensor electrode line 6112. For example, the second electrode of the first color sub-pixel 100 and the second electrode of the third color sub-pixel 300 do not overlap with the sensor electrode line 6112.

For example, the part of the driving transistor T1 of the second color subpixel 200 that is not covered by the auxiliary electrode 223 is covered by the sensor electrode line 6112, and the driving transistors T1 of the first color subpixel 100 and the third color subpixel 300 are not substantially covered by the sensor electrode line 6112.

The pixel patterns of the multiple sub-pixels are approximately rectangular areas and are arranged in a periodic manner. The second electrodes of the first color subpixel and the third color subpixel can substantially overlap the positions of the driving transistors of the respective pixel circuits, while the second electrode of the second color subpixel and the corresponding driving transistor do not overlap or have a small overlap area. For example, the main base electrodes of the second electrodes of the first color subpixel and the third color subpixel may cover the driving transistors of the respective pixel circuits, while the main base electrode of the second electrode of the second color subpixel is not covered by the driving transistor of the corresponding pixel circuit. Thus, the second electrode of the second color sub-pixel extends the area (ie the auxiliary electrode) in a direction close to the driving transistor in order to shield the driving transistor. At the same time, the sensor electrode line helps to shield the portion of the driving transistor that is not covered by the auxiliary electrode to further stabilize the driving transistor of the second color sub-pixel.

For example, as shown in FIG. 13A, the data recording transistor T2 or the threshold compensation transistor T3 of the second color subpixel 200 is covered by the sensor electrode line 6112. For example, as shown in FIG. 13A, the threshold compensation transistor T3 of the second color subpixel 200 is covered by the sensor electrode line 6112. For example, the line of sensor electrodes may be covered by a data recording transistor. For example, data recording transistors T2 and threshold compensation transistors T3 of the first color sub-pixel 100 and the third color sub-pixel 300 do not overlap with the sensor electrode line 6112.

For example, the data recording transistor T2 or the threshold compensation transistor T3 (channel, gate electrode, drain electrode) of the second color sub-pixel is shielded by the sensor electrode line, thereby stabilizing the transistor. Since the threshold compensation transistor T3 is directly connected to the gate electrode and the drain electrode of the driving transistor, it has a direct effect on the working state of the driving transistor, so it can generally be a double gate transistor; the active layer between the two gate electrodes is easily exposed to light or other external factors, so it must be shielded. Accordingly, the threshold compensation transistors T3 of the first color sub-pixel and the third color sub-pixel are shielded by the respective second electrodes. For example, the threshold compensation transistors T3 of the first color sub-pixel and the third color sub-pixel are shielded by the respective base electrodes, while the threshold compensation transistors T3 of the second color sub-pixel are not covered by the main base electrode of the second color sub-pixel.

For example, in a subpixel with a small overlap area between the second organic light emitting element electrode and the first storage capacitor electrode (eg, in the second color subpixel), the overlap area between the sensor electrode line 6112 and the first storage capacitor electrode is large.

For example, in the charging stage, T1 and T3 continuously charge node N1, and the potential of node N1 directly affects the working state of T1, while the film layer where the data line of node N1 is located and the film layer where the first electrode of the storage capacitor is located, has a partial overlapping load; in the light emitting stage, in the case where the VD-D signal is injected into the film layer where the storage capacitor first electrode is located, if the N1 node is not sufficiently charged due to the overlapping load, the N1 node experiences the interference generated by the VD-D signal, which will cause potential change and then will affect the working state of T1, and the working state of T1 will affect the light emitted by the OLED element. Thus, during charging, it must be ensured that the charging potential of the N1 node is sufficient; the charging voltage of N1 node is related to the states of T1 and T3, and since TFTs are especially sensitive to light, the corresponding characteristics of TFTs will shift due to the influence of light, so during charging, it is necessary to protect and shield T1 or T3 to ensure the charging voltage of the node N1 to maintain the stable working state of T1 and not affect the normal operation of the OLED element.

FIG. 13B is a schematic representation of a positional relationship between a pixel circuit and a line of sensor electrodes shown in another exemplary embodiment of the present disclosure. For example, as shown in FIG. 13B, the driving transistor in the second color subpixel 200 is overlapped by the sensor electrode line 6112, and the second OLE electrode 220 of the second color subpixel 200 is not substantially overlapped by the sensor electrode line 6112; in the first color subpixel 100, the driving transistor is overlapped by the second organic light emitting element electrode 120 but not substantially overlapped by the sensor electrode line 6112, and the second organic light emitting element electrode 120 is overlapped by the sensor electrode line 6112; in the third color subpixel 300, the driving transistor is overlapped by the second organic light emitting element electrode 320 but not substantially overlapped by the sensor electrode line 6112, and the second organic light emitting element electrode 320 is overlapped by the sensor electrode line. The second electrode of the organic light emitting element of the second color subpixel includes a main base electrode 221, a connection electrode 222, and an auxiliary electrode 223; in the second color subpixel 200, the connecting electrode 222 and the auxiliary electrode 223 are not substantially overlapped by the second effective light emitting region 201, the main base electrode 221 is not substantially overlapped by the driving transistor, and the auxiliary electrode 223 is covered by the driving transistor.

For example, as shown in FIG. 13B, the second organic light emitting element electrode 220 of the second color subpixel 200 is covered by the second effective light emitting region 201. For example, the connecting electrode 222 of the second organic light emitting element electrode 220 is electrically connected to the second electrode of the second emission control transistor T5 light through the through hole 388 in the insulating layer.

For example, as shown in FIG. 13B, in the first color subpixel, at least one of the threshold compensation transistor and the data recording transistor is overlapped by the second electrode of the organic light emitting element and is not overlapped by the sensor electrode line; in the third color subpixel, at least one of the threshold compensation transistor and the data recording transistor is covered by the second electrode of the organic light emitting element; in the second color subpixel, both the threshold compensation transistor and the data recording transistor are not covered by the second organic light emitting element electrode, and the threshold compensation transistor or the data recording transistor is covered by the sensor electrode line.

For example, as shown in FIG. 13C, in the second color subpixel 200, both the second organic light emitting element electrode 220 and the driving transistor are overlapped by the sensor electrode line 6112; in the first color subpixel 100, both the second organic light emitting element electrode 120 and the driving transistor are not substantially overlapped by the sensor electrode line 6112; in the third color subpixel 300, both the second organic light emitting element electrode 320 and the driving transistor do not substantially overlap with the sensor electrode line 6112.

For example, as shown in FIG. 13D, in the second color sub-pixel 200, the driving transistor is overlapped by the second organic light emitting element electrode 220 but not overlapped by the sensor electrode line 6112, and the second organic light emitting element electrode 220 is overlapped by the sensor electrode line 6112; in the first color sub-pixel 100, the driving transistor is overlapped by the sensor electrode line 6112 but is not overlapped by the second organic light emitting element electrode 120, and the second organic light emitting element electrode 120 is not overlapped by the sensor electrode line 6112; in the third color sub-pixel 300, the driving transistor is overlapped by the sensor electrode line 6112 but not overlapped by the second organic light emitting element electrode 320, and the second organic light emitting element electrode 320 is not overlapped by the sensor electrode line 6112.

For example, as shown in FIG. 13D, in the first color subpixel, the second electrode of the organic light emitting element is not covered by the driving transistor or the sensor electrode line, and the driving transistor is covered by the sensor electrode line; in the third color subpixel, the second electrode of the organic light emitting element is not overlapped by the driving transistor or the sensor electrode line, and the driving transistor is overlapped by the sensor electrode line; in the second color sub-pixel, the second electrode of the organic light emitting element is covered by the driving transistor and the sensor electrode line, and the driving transistor is covered by the sensor electrode line.

For example, the second organic light emitting element electrode 220 of the second color subpixel 200 is covered by the driving transistor T1 and is covered by the threshold compensation transistor T3 of the second color subpixel 200, the sensor electrode line 6112 is covered by the part of the driving transistor T1 of the second color subpixel 200 that is not covered by the second organic light emitting electrode 220 element, thereby further stabilizing the control transistor of the second color subpixel. In the second color subpixel, the second electrode of the organic light emitting element includes a main base electrode, a connection electrode, and an auxiliary electrode. For example, in some embodiments, an auxiliary electrode is used to shield some transistors (such as a data recording transistor or a threshold compensation transistor), so the sensor electrode line may overlap to some extent with the auxiliary electrode of the organic light emitting element's second electrode.

For example, the sensor electrode line 6112 is covered by the second organic light emitting element electrode 220 of the second color subpixel 200. For example, the sensor electrode line 6112 is covered by the portion of the threshold compensation transistor T3 of the second color subpixel 200 that is not covered by the second organic light emitting element electrode 220. The portion of the second electrode of the organic light emitting element of the second color subpixel extending in a direction close to the threshold compensation transistor shields the threshold compensation transistor; meanwhile, the sensor electrode line contributes to shielding the part of the threshold compensation transistor that is not covered by the second organic light emitting element electrode, thereby further stabilizing the threshold compensation transistor of the second color subpixel. Thus, the charging voltage of the node N1 can be ensured, the operating state T1 can be maintained stable, and the normal operation of the OLED element can be avoided to be adversely affected.

For example, as shown in FIG. 13D, in the second organic light emitting element electrode 120 of the first color subpixel 100, the main base electrode 121 overlaps with the first effective light emitting region 101, and the connecting electrode 122 does not overlap with the first effective light emitting region. For example, the connection electrode 122 is configured to be electrically connected to the second electrode of the organic light emitting element of the second light emitting driving transistor T5 through the through hole 388 in the insulating layer.

For example, the second organic light emitting element electrode 120 of the first color subpixel 100 is not overlapped by the sensor electrode line 6112. For example, the second OLE electrode 120 of the first color subpixel 100 covers the threshold compensation transistor T3 of the first color subpixel 100, thereby stabilizing the threshold compensation transistor of the first color subpixel. In this way, the charging voltage of the node N1 can be ensured, the operating state T1 can be kept stable, and the normal operation of the OLED element can be avoided to be adversely affected.

For example, the second organic light emitting element electrode 120 of the first color subpixel 100 is not substantially covered by the driving transistor T1 of the first color subpixel 100. For example, the sensor electrode line 6112 is covered by the driving transistor T1 of the first color subpixel 100, so that the driving transistor of the first color subpixel can be stabilized.

For example, as shown in FIG. 13D, in the second organic light emitting element electrode 320 of the third color subpixel 300, the main base electrode 321 is overlapped by the third effective light emitting region, and the connecting electrode 322 is not overlapped by the third effective light emitting region. For example, the connection electrode 322 is configured to electrically connect to the second electrode of the second light emitting driving transistor T5 through the through hole 388. For example, the second electrode 320 of the organic light emitting element of the third color subpixel 300 is not overlapped by the sensor electrode line 6112.

For example, as shown in FIG. 13D, the second organic light emitting element electrode 320 of the third color subpixel 300 is not overlapped by the sensor electrode line 6112. For example, the second OLE electrode 320 of the third color sub-pixel 300 includes a raised portion 323, the raised portion 323 covers the threshold compensation transistor T3 of the third color sub-pixel 300, thereby stabilizing the threshold compensation transistor of the third color sub-pixel. In this way, the charging voltage of the node N1 can be ensured, the operating state T1 can be kept stable, and the normal operation of the OLED element can be avoided to be adversely affected.

For example, the second organic light emitting element electrode 320 of the third color subpixel 300 is not substantially covered by the driving transistor T1 of the third color subpixel 300. For example, the sensor electrode line 6112 is covered by the driving transistor T1 of the third color subpixel 300, so that the driving transistor of the third color subpixel can be stabilized.

For example, as shown in FIG. 13E, in the second color subpixel 200, both the second organic light emitting element electrode 220 and the driving transistor are not substantially overlapped by the sensor electrode line 6112; in the first color subpixel 100, both the second organic light emitting element electrode 120 and the driving transistor are overlapped by the sensor electrode line 6112; in the third color subpixel 300, both the second organic light emitting element electrode 320 and the driving transistor are overlapped by the sensor electrode line 6112.

Fig. 14A shows a schematic representation of the evaporation of a light emitting layer using FMM. The pixel boundary layer 400 is formed on the base substrate 10, the pixel boundary layer 400 has a hole 401, the spacer 700 is formed on the pixel boundary layer 400, the spacer serves to support the FMM 104, the FMM 104 has a through hole 1040, the through hole 1040 may be a hole formed in during etching, and the material to be evaporated is deposited on the base substrate 10 from bottom to top through the through hole 1040. To prevent damage to the FMM of the film layer on the base substrate 10, a spacer (e.g., photospace, PS) is provided on the base substrate 10 to support the FMM during evaporation. . During evaporation, the base substrate 10 is placed over the FMM 104 and the spacer 700 is attached to the FMM. In order to improve the accuracy of the evaporation position, it is generally necessary to place a Gaussian plate 105 with strong magnetism over the base substrate 10 for adsorption of the FMM 104 so that the FMM 104 is more tightly attached to the base substrate 10. The arrow in Fig. 14A indicates the direction of gas flow.

Since the FMM is made of metal, the material deposited on the base substrate 10 is easily damaged when it comes into contact with the base substrate 10. Thus, in the structure of the OLED backplane, the spacer 700 plays a supporting role when the FMM 104 is attached to the base substrate. 10, thus preventing the FMM 104 from being scratched on the surface of the base substrate 10. The spacers 700 may be arrayed throughout the panel, but are not limited to this.

For example, in the case where the spacer 700 is used to support the FMM, the top of the spacer 700 cannot be vaporized with the light emitting layer. For example, each spacer 700 includes a first area 701 and a second annular area 702 surrounding the first area 701. The first area 701 includes a center area of the spacers 700 and an area ratio between orthogonal projections of the first area 701 and the size of the spacers 700 onto the base substrate 10 is no more than 1/4. For example, the area ratio between the orthogonal projections of the first region 701 and the separator 700 onto the base substrate 10 is 1/3 to 1/4, and the top of the separator 700 is located in the first region 701.

For example, in the display area, the first area of the at least one spacer is not overlapped by any of the first color light emitting layer, the second color light emitting layer, or the third color light emitting layer. For example, the first region 701 of at least one spacer 700 is not covered by the light emitting layer. For example, the first area 701 of at least one spacer 700 is only covered by one type of color light emitting layer, for example, the first area 701 of at least one spacer 700 is only covered by a green light emitting layer. For example, the first area 701 of at least one spacer 700 is only overlapped by two types of color light emitting layers, for example, the first area 701 of at least one spacer 700 is only covered by a red light emitting layer and a blue light emitting layer.

For example, the spacer may be located between the first color subpixel and the second color subpixel, and in the case where there is no light emitting layer overlapping on top of the spacer, lateral crosstalk or cross color can be further reduced. For example, when the light emitting layer of the first color subpixel is evaporated, the spacer part adjacent to the opening of the pixel limiting layer for forming the second color subpixel maintains the FMM so that this part is not evaporated with the first color light emitting layer; when the light emitting layer of the third color subpixel is evaporated, the spacer part adjacent to the opening of the pixel limiting layer for forming the first color subpixel maintains the FMM so that this part is not evaporated with the third color light emitting layer. When the light emitting layer of the second color sub-pixel is evaporated, the second color light emitting layer is formed partly on both sides of the spacers, and there is no second color light emitting layer in other areas. Since the holes do not overlap, the distribution of the color light emitting layers in the central region (for example, the first region) of the spacer does not substantially overlap or has a small overlapping portion (for example, less than 30%) due to factors such as manufacturing tolerance, etc. .

For example, the orthogonal projection of the dividers onto the base substrate is at least selected from the group consisting of a rounded rectangle, an ellipse, and a circle. For example, the orthogonal projection of the dividers onto the base substrate is an axisymmetric pattern. For example, the separator is located at the intersection of parts of the pixel-bounding layer with different extension directions (for example, the separator covers the intersection of parts of the pixel-bounding layer with different directions of extension), and has two axes of symmetry, and two axes of symmetry are approximately parallel to the two directions of extension of the pixel-bounding layer in places where two axes of symmetry are located. For example, the orthogonal projection of the separators onto the base substrate has a size of 20-50 µm in the direction of the long axis. For example, the orthogonal projection of the spacer onto the base substrate has a size of 12-30 µm in the direction of the short axis. For example, the orthogonal projection area of the separator on the base substrate is less than 48 µm * 26 µm. For example, the orthogonal projection size range of separators on the base substrate is less than 41 µm * 25 µm. For example, the orthogonal projection size range of separators on the base substrate is less than 33 µm * 20 µm. For example, the size range of the orthogonal projection of the separators on the base substrate is less than 2 5 µm * 15 µm.

For example, FIG. 14B shows a schematic representation of a positional relationship between a pixel-bounding layer and a spacer. As shown in FIG. 14B, for example, the distance between the boundary of the spacer 700 and the edge of the opening 401 of the pixel-bounding layer 400 is at least 6.5 μm.

For example, separator 700 and pixel-bounding layer 400 may be an integrated structure without obvious boundaries. For example, separator 700 and pixel bounding layer 400 may be padded with a position at which the inflection point of the slope curve appears. For example, directly for the pixel-bounding layer in the direction from one of the edges of the hole located on both sides of the center line of its extension direction to the center line of the extension direction of the pixel-bounding layer, the slope angle tends to be large to small, and the slope angle may be approximately from 0 to 5 degrees on the surface of the pixel-bounding layer, which is nearly flat; from the surface of the pixel-limiting layer, which is almost flat, to the boundary of the separators, the slope angle tends to increase again. For example, at the separator boundary, the angle of inclination may increase from about 0 degrees to about 10 degrees (eg, 5 to 10 degrees) or more than 10 degrees. The inclination angle may be an angle, the angle included between the outer tangent of the position of the measurement point and the plane where the main base electrode surface of the nearest second electrode (eg, anode) is located, remote from the base substrate. For example, the thickness of a portion of the pixel-bounding layer 400 without the spacer 700 is the first thickness (eg, the average thickness of the flat portion), and the maximum thickness of the portion of the pixel-bounding layer 400 with the spacer 700 is the second thickness. The boundary between the spacer 700 and the pixel-bounding layer 400 can be defined as follows: the part having the first thickness from the surface of the pixel-bounding layer 400 near the base substrate can be defined as the pixel-bounding layer 400 itself, and the part at a distance from the first thickness to the second thickness can be defined as a separator.

For example, the thickness of a portion of the pixel-bounding layer 400 without spacer 700 is the first thickness (eg, the average thickness of a nearly flat portion), and, for example, the first thickness is 0.8-1.8 µm. For example, the thickness of a portion of the pixel-bounding layer 400 without spacer 700 is the first thickness (eg, the average thickness of a nearly flat portion), and, for example, the first thickness is greater than or equal to 1.1 μm. For example, the thickness of a portion of the pixel-bounding layer 400 without spacer 700 is the first thickness (eg, the average thickness of a nearly flat portion), and, for example, the first thickness is less than 3 μm. If the pixel limiting layer 400, as part of the organic layer encapsulation barrier, is too thin, and overflow of the organic layer can easily affect the encapsulation effect. If the first thickness of the pixel limiting layer 400 is too large, it is easy to cause a relatively large limitation of the light angle and affect the light output.

For example, the angle of the portion of the pixel-bounding layer close to the hole is 15-25 degrees. For example, the angle of the portion of the pixel-bounding layer near the hole is 17-21 degrees. For example, the angle of inclination of a portion of the pixel-bounding layer near the hole is 18-20 degrees.

For example, as shown in FIGS. 15A to 15G, at least one embodiment of the present disclosure provides a display panel that includes: a base substrate including a display area and a peripheral area located on the periphery of the display area; plural first color subpixels arranged in the display area, wherein the plurality of first color subpixels are arranged in the first direction to form multiple rows of first color subpixels, the plurality of first color subpixel rows are arranged in the second direction, and adjacent rows of first color subpixels in the plurality of first color subpixel rows are offset relative to each other in the first direction; multiple second color subpixels located in the display area and ordered in the first direction and the second direction, and four second color subpixels surrounding one first color subpixel; a plurality of third color subpixels arranged in the display area, wherein the plurality of first color subpixels and the plurality of third color subpixels are alternately arranged in the first direction and the second direction, the plurality of first color subpixels and the plurality of second color subpixels are alternately arranged in the third direction as a first group, the plurality of third the color subpixels and the plurality of second color subpixels are alternately arranged in the third direction as a second group, the first group and the second group are alternately arranged in the fourth direction, and the third direction and the fourth direction intersect with both the first direction and the second direction; a pixel limiting layer disposed in a display area and a peripheral area, the pixel limiting layer including multiple apertures for forming effective light emitting regions of the plurality of subpixels, the plurality of first color subpixels including the plurality of first effective light emitting regions, the plurality of second color subpixels including the plurality of second effective light emitting regions, and the plurality of third color subpixels include the plurality of third effective light emitting regions. The multiple first color subpixels include multiple first color light emitting layers located in the respective holes and on the pixel-bounding layer surrounding the respective holes, the multiple second color sub-pixels include multiple second color light-emitting layers located in the respective holes and on the pixel-bounding layer, surrounding the respective holes, the plurality of first color light emitting layers included in the plurality of first color subpixels are spaced apart from each other, and the plurality of second color light emitting layers included in the plurality of second color subpixels are spaced apart from each other; the plurality of third color subpixels includes the plurality of third color light-emitting layers located in the respective holes and on the pixel-limiting layer surrounding the respective holes, and the plurality of third color light-emitting layers included in the plurality of third color subpixels are spaced apart from each other.

For example, the display panel further includes a plurality of spacers located on the surface of the pixel-bounding layer remote from the base substrate, and the spacers in the display area are located in the spaces between the subpixels arranged in the first direction, and the spacers in the display area are located in the spaces between the subpixels, placed in the second direction. In the display area, the area ratio K between the separator and the pixel-bounding layer satisfies the inequality K ≤ S0/[k1*n*m*(S1 _G -S2 _G )+k2*n*m*(S1 _R -S2 _R )+k3*n *m*(S1 _B - S2 _B )], where n is the number (for example, 4, as shown in FIG. 15F in the long F1 frame) of middle subpixels in the same line (for example, two red subpixels 100 and two blue subpixels 300 in the same row and between two separators in the row direction, as shown in FIG. long bar frame F2 in FIG. separators placed in the second direction, S0 is the area of one separator; S1 _G , S1 _R and S1 _B are areas of light-emitting layers of the second color sub-pixel, the first color sub-pixel and the third color sub-pixel, respectively; S2 _G , S2 _{R and} S2 _B are the aperture areas of the pixel-bounding layer corresponding to the second color sub-pixel, the first color sub-pixel and the third color sub-pixel, respectively; and k1, k2, and k3 are the proportions of the second color subpixels, the first color subpixels, and the third color subpixels in the display area with respect to all subpixels, respectively. For example, k1 is 1/2. For example, k2 is 1/4. For example, k3 is 1/4. For example, k1 + k2 + k3 = 1.

For example, S2G is about 80-180 square microns. For example, the size of S2G is about 100-140 square microns. For example, S2R is about 150-280 square microns. For example, S2R is about 160-250 square microns. For example, the size of S2B is about 200-400 square microns. For example, the size of S2B is about 260-350 square microns.

The same line mentioned above refers to the same row or to the same column. For example, the same line in the first direction refers to the same line. For example, the same line in the second direction refers to the same column.

In some embodiments, the delimiters are not in the same row as the subpixels and, for example, the delimiters are in between two adjacent rows of subpixels; and/or the spacers are not in the same column as the subpixels, and for example the spacers are in between two adjacent columns of subpixels. Thus, the area ratio K between the separator and the pixel-bounding layer satisfies the inequality K ≤ S0/[1/4*k1*N*M* (S1 _G -S2 _G )+ 1/4*k2*N*M* (S1 _R -S2 _R )+1/4*k3*N*M*(S1 _B -S2 _B )], where N is the number of columns of subpixels corresponding to one delimiter period in the first direction, such as the row direction, and M is the number of columns subpixel rows corresponding to one delimiter period in a second direction, such as a column direction. For example, one separator period is that one separator is set for every N columns of subpixels in a first direction, such as a row direction. For example, one separator period is that one separator is set for every M rows of subpixels in a second direction such as a column direction.

In some embodiments, the subpixel rows are offset. As shown in FIG. 15G, separators and subpixels are located in the same row, and in the first direction, such as the row direction, the number N of subpixel columns corresponding to one separator period is twice the number n of middle subpixels in the same row. same line that are placed between adjacent separators among the separators placed in the first direction, and, for example, n is 4 and N is 8 (as shown by the box with a long bar in the figure).

In some embodiments, the columns of subpixels are offset. As shown in FIG. 15G, separators and subpixels are arranged in the same column, and in the second direction, such as the column direction, the number M of subpixel rows corresponding to one separator period is twice the number m of average subpixels of pixels in one and on the same line that are placed between adjacent delimiters among the delimiters placed in the second direction, and, for example, m is 4 and M is 8 (as shown by the long bar box in the figure).

15A and 15B show schematic representations of positional relationships between separators and subpixels presented in embodiments of the present disclosure.

As shown in FIG. 15A, multiple display panel dividers 700 are disposed on the surface of the pixel bounding layer 400 at a distance from the base substrate 10, and the area ratio between the orthogonal projections of the dividers 700 onto the base substrate and the orthogonal projection of the pixel bounding layer 400 onto the base substrate does not exceed 12 %. For example, the area ratio between the orthogonal projections of the spacer 700 onto the base substrate and the orthogonal projection of the pixel bounding layer 400 onto the base substrate does not exceed 8%. For example, the area ratio between the orthogonal projections of the spacer 700 onto the base substrate and the orthogonal projection of the pixel bounding layer 400 onto the base substrate does not exceed 7%. For example, the area ratio between the orthogonal projections of the divider 700 onto the base substrate and the orthogonal projection of the pixel bounding layer 400 onto the base substrate does not exceed 6%. For example, the area ratio between the orthogonal projections of the spacer 700 onto the base substrate and the orthogonal projection of the pixel bounding layer 400 onto the base substrate does not exceed 5%. For example, the area ratio between the orthogonal projections of the spacer 700 onto the base substrate and the orthogonal projection of the pixel bounding layer 400 onto the base substrate does not exceed 4%. For example, the area ratio between the orthogonal projections of the spacer 700 onto the base substrate and the orthogonal projection of the pixel bounding layer 400 onto the base substrate does not exceed 3%.

For example, multiple separators are located on the surface of the pixel-bounding layer, remote from the base substrate. In the display area, the numerical ratio between separators and all subpixels is less than or equal to 1:4. In the display area, the numerical ratio between separators and all subpixels is less than or equal to 1:8. For example, in the display area, the numerical ratio between separators and all subpixels does not exceed 1:12. For example, in the display area, the numerical ratio between separators and all subpixels does not exceed 1:16. For example, in the display area, the numerical ratio between separators and all subpixels does not exceed 1:20. For example, in the display area, the numerical ratio between separators and all subpixels does not exceed 1:24.

For example, in the direction of the connecting line between the centers of the light emitting layers of two adjacent subpixels, the ratio of the spacer 700 size to the size of the pixel-bounding layer 400 (eg, the surface of the pixel-bounding layer on which the spacer is located, such as the top surface) is less than 0.9. For example, in the direction of the connecting line between the centers of the light emitting layers of two adjacent subpixels, the ratio of the size of the spacer 700 to the size of the pixel limiting layer 400 is less than 0.8.

For example, as shown in FIG. 15A, four second color subpixels 200 are placed between adjacent spacers 700 in the second direction, and two first color subpixels 100 and two third color subpixels 300 are placed between adjacent spacers 700 in the first direction. For example, the ratio of the area of the orthogonal projection of the dividers 700 onto the base substrate to the area of the orthogonal projection of the pixel bounding layer 400 onto the base substrate does not exceed 6%. Taking as an example that one spacer is placed every four subpixels in the row direction, and one spacer is placed every four subpixels in the column direction, one spacer corresponds to eight second color subpixels, four first color subpixels, and four third color subpixels. For example, the ratio between the orthogonal projection area of the spacer 700 onto the base substrate and the orthogonal projection area of the pixel-bounding layer 400 onto the base substrate does not exceed 8%. The density and size of the separators tend to get smaller and smaller, which reduces the number of particles produced during the process and increases the yield. The first direction and the second direction in an embodiment of the present disclosure may be interchanged.

For example, as shown in FIG. 15B, six second color subpixels 200 are placed between adjacent spacers 700 in the second direction, and three first color subpixels 100 and three third color subpixels 300 are placed between adjacent spacers 700 in the first direction. For example, the area ratio between the orthogonal projections of the spacer 700 onto the base substrate and the orthogonal projection of the pixel bounding layer 400 onto the base substrate is less than 6%. One spacer is placed every six subpixels in the row direction, and one spacer is placed every six subpixels in the column direction.

For example, as shown in FIGS. 15A and 15B, in the display area, the divider 700 is not covered by a jumper line. For example, in the display area, the jumper lines spanning one second cell are overlapped by at most one separator 700. For example, the second cell 602 is in the form of a long strip, and the size of the overlapping portion between the separator 700 and the jumper line is smaller than the size of the second cell 602 in the direction , perpendicular to the continuation direction of the second cell 602. Since the first electrode of each subpixel is closest to the jumper line at the spacer position, less overlap between the jumper line and the spacer can reduce crosstalk.

For example, as shown in FIG. 15C, assuming that two adjacent second sensor units are electrically connected via two connecting bridges as an example, the second cells, where the two end points and the midpoint of rotation of one connection bridge 621 are located, can be overlapped by a spacer 700, while the other connecting bridge 621 is not overlapped by the separator 700. An embodiment of the present disclosure is not limited to this, and for example, in the case where five or six second color subpixels are placed between two adjacent separators, only the second cell where the middle pivot point is located one connecting jumper, can be overlapped by a separator. For example, as shown in FIG. 15A, taking as an example that two adjacent second sensor units are electrically connected via two connecting jumpers, one connecting jumper 621 is covered by one spacer 700, and the other connection jumper 621 is also covered by one spacer 700. For example, an embodiment of the present disclosure is not limited to the positional relationship between the spacer and the connecting bridge shown in Fig. 15A, and if the spacers in Fig. 15A are moved up by the size of the second cell, one connection bridge is covered by one spacer and the other connection bridge is not covered by the spacer.

For example, FIG. 15F shows that adjacent spacers in the row direction are separated by four subpixels, such as two red subpixels and two blue subpixels, and that adjacent spacers in the column direction are separated by four subpixels, such as four subpixels, such as four green subpixels. For example, each divider corresponds to an approximately rectangular area (shown as a solid box in the figure). The area includes, for example, four rows of green sub-pixels, and each row includes four green sub-pixels; that is, the area includes sixteen green subpixels. The area includes, for example, four lines, each line of which is formed by alternating red sub-pixels and blue sub-pixels, and each line includes two red sub-pixels and two blue sub-pixels; that is, the area includes eight red subpixels and eight blue subpixels. Among the separators distributed in all four rows and four columns of subpixels (for example, the first separators filled with vertical lines in the figure), one separator (for example, the second separator filled with small cells in the figure) is also distributed approximately in the middle of the 2 * 2 matrix formed by all four delimiters in the inner area. The first separators and the second separators have the same distribution rule and approximately the same number. Every second spacer also corresponds to an approximately rectangular area (shown by the dotted box in the figure), and this area also includes, for example, sixteen green subpixels, eight red subpixels, and eight blue subpixels. The first separators and the second separators have the same distribution and approximately the same number, the rectangular regions corresponding to the first separators cover approximately the entire display area, and the rectangular regions corresponding to the second separators also cover approximately the entire display area, so each subpixel in the rectangular regions corresponding to the first separator and the second separator, is included in two rectangular areas. For example, the number of subpixels substantially corresponding to the first separator and the second separator is eight green subpixels, four red subpixels, and four blue subpixels (only on the inside of the display area, a certain part of the number of subpixels at the extreme part may have some differences due to the shape or algorithm ). For example, when considering the repetition of rectangular regions corresponding to the first separators and the second separators, the region obtained after dividing each rectangular region by two is approximately a display region substantially corresponding to one separator, and the regions may be in one-to-one correspondence with the separators within display area. For example, the area of the display area corresponding to one separator is approximately the area occupied by eight green sub-pixels, four red sub-pixels, and four blue sub-pixels.

For example, the ratio between separators and subpixels in a display area is 1:16.

For example, the ratio of the area of one separator to the area of the orthogonal projection of the layer limiting pixels in the display area corresponding to the separator does not exceed 8%.

For example, a pixel-bounding layer surrounding each sub-pixel is substantially covered by a respective light emitting layer. For example, the boundary of the hole for forming the light emitting layer of each sub-pixel of the mask plate is approximately located on the center line of each portion of the pixel-bounding layer. For example, the area of the pixel-bounding layer surrounding the hole corresponding to each sub-pixel is approximately equal to the area of the hole for forming the light-emitting layer of the sub-pixel of the mask plate minus the area of the hole of the pixel-bounding layer. Or, for example, regardless of factors such as manufacturing tolerance, etc., the area of the pixel-bounding layer surrounding the hole corresponding to each sub-pixel is approximately equal to the area (S1) of the light-emitting layer of the sub-pixel minus the area (S2) of the hole of the pixel-bounding layer .

For example, the FMM hole corresponding to the green sub-pixel has the shape of a circle or a square with a diameter or side length of 30-35 µm and, for example, 33 µm. For example, the FMM hole corresponding to the red subpixel is square with a side length of 30-35 µm, such as 33 µm. For example, the FMM hole corresponding to the blue subpixel is square with a side length of 33-38 µm and eg 35.5 µm.

For example, the aperture of the pixel-bounding layer corresponding to the green subpixel is shaped like an oval or rectangle (it can be considered that the length of the long side of the rectangle is equal to the size of the long axis and the length of the short side of the rectangle is equal to the size of the short axis), and its long axis is 12-16 µm, eg 14 µm and its short axis is 10-14 µm, eg 11 µm. For example, the aperture of the pixel-bounding layer corresponding to the red sub-pixel is square, and its side length is approximately 14-17 µm, such as 15 µm. For example, the opening of the pixel-bounding layer corresponding to the blue sub-pixel is square-shaped, and its side length is about 16-20 µm, such as 18 µm.

For example, in the display area, the pixel limiting layer may include a part covered with a light emitting layer and may also include a part not covered with a light emitting layer.

For example, in the display area, the area ratio K between the separator and the pixel-bounding layer satisfies the inequality K ≤ S0/[k1*n*m*(S1 _G -S2 _G )+k2*n*m*(S1 _R -S2 _R )+ k3*n* m*(S1 _B -S2 _B )], where n is the column number of middle subpixels between adjacent separators in one row, m is the row number of middle subpixels between adjacent separators in the same column, S0 is the area of one separator ; S1 _G , S1 _R and S1 _B are areas of light emitting layers or corresponding FMM holes of green sub-pixel, red sub-pixel and blue sub-pixel, respectively; S2 _G , S2 _R and S2 _B are the hole areas of the pixel-bounding layer corresponding to the green sub-pixel, red sub-pixel and blue sub-pixel, respectively; and k1, k2, and k3 are the ratios of green subpixels, red subpixels, and blue subpixels to all subpixels in the display area. For example, k1 + k2 + k3 = 1. For example, for the device shown in FIG. 15F, the ratio between G subpixels, R subpixels, and G subpixels is 2:1:1, then k1 is 2/(2 + 1 + 1 ) = 1/2, k2 is 1/(2 + 1 + 1) = 1/4, and k3 is 1/(2 + 1 + 1) = 1/4. For example, for a layout with an equal number of RGB subpixels, k1 = k2 = k3 = 1/3.

For example, regardless of other factors, the larger n or m, the more sparse the distribution of separators and the smaller the value of K. For example, regardless of other factors, the larger the area of the light emitting layer of each subpixel, the larger the corresponding aperture FMM; the spacer respectively supports the part on the outside of the FMM hole, thus, compared with the area of the FMM hole part, the area of the part that can be supported by the spacer decreases as the area of the light emitting layer increases, and the size of the spacers is correspondingly reduced, or the spacer distribution number relatively smaller (since this is necessary to avoid opening each FMM), so the value of K is also smaller. For example, regardless of other factors, the smaller the aperture area of the pixel-bounding layer corresponding to each sub-pixel, the larger the object area of the pixel-bounding layer, and accordingly, the area ratio K between the spacer and the pixel-bounding layer is smaller at the same distribution density. For example, n can be equal to m and, for example, both are 4, or both are 6, or both are 5.

For example, n may not be equal to m, for example, one of them is 4 and the other is 6.

In some embodiments, the display panel may not have a touch function, that is, it does not include touch electrodes. In some embodiments, the display panel touch electrodes may not be based on the layout of the touch electrode lines and jumper lines, and for example, the touch electrodes may be flat shaped electrodes. In some embodiments, the display panel touch electrode material may be metal, metal oxide, or any other conductive material.

As shown in FIGS. 4 to 8 and 16, at least one embodiment of the present disclosure provides a display panel that includes: a base substrate including a display area and a peripheral area located on the periphery of the display area; and multiple subpixels located in the display area. Each subpixel includes a first electrode and a second electrode, the second electrode is located between the base substrate and the first electrode, and the first electrode is an integral film layer in the display area. The display panel further includes: an encapsulating layer located in the display area and the peripheral area; a first sensor electrode layer located on one side of the encapsulating layer remote from the base substrate, wherein the first sensor electrode layer includes multiple first sensor electrodes extending in a first direction and multiple second sensor electrodes extending in a second direction, each first sensor electrode includes multiple first sensor electrode blocks, each second sensor electrode includes multiple second sensor electrode blocks, the first sensor electrode layer includes multiple sensor electrode lines, the multiple sensor electrode lines intersect to form multiple first cells, and both of each block the first sensor electrodes and each block of the second sensor electrodes include multiple connected with each other first cells; a second sensor electrode layer including multiple connecting bridges, wherein the second sensor electrode layer includes multiple bridges, the multiple bridges intersect to form multiple second cells, each connection bridge includes multiple second cells connected to each other, and adjacent blocks of second sensor electrodes are electrically connected through at least one connecting jumper; a sensor insulating layer located between the first sensor electrode layer and the second sensor electrode layer, and the second sensor electrode unit is electrically connected to the connecting jumper through a through hole passing through the sensor insulating layer. One of the first sensor electrode layer and the second sensor electrode layer, which is closer to the first electrode, is the sensor electrode proximal layer, and in the display area, the total thickness of the insulating layer between the first electrode located in the effective light emitting region and the sensor electrode proximal layer is larger, than the total thickness of the insulating layer between the first electrode located on the outer side of the effective light emitting region and the near layer of the sensor electrodes.

Note that, in an embodiment of the present disclosure, the pixel circuit may have a 7T1C structure (i.e., seven transistors and one capacitor) as shown in FIG. 15B, and may also have a structure including a different number of transistors and capacitors, such as a 7T2C, 6T1C pattern, 6T2C pattern, or 9T2C pattern, without limitation in an embodiment of the present disclosure. In an embodiment of the present disclosure, the pixels may be based on any arrangement method such as a stripe arrangement, a triangular arrangement, a tiled arrangement, and so on. In an embodiment of the present disclosure, the RGB numeric proportion in a single pixel block or repeat block may have any one or combination of two or more elements selected from the group consisting of 1:1:2, 1:2:1, 2:2:1 , 1:1:1, 1:2:3, 3:3:2, 1:3:2, 2:3:1, 3:2:3, 2:3:3, etc. For example, RGBs may have the same size or may not have the same size. For example, the size of the hole in the pixel limiting layer for limiting the light emitting layer B is larger than that of R, and the size of the hole in the pixel limiting layer for limiting the light emitting layer B is larger than that of G. For example, the size of the hole in the pixel limiting layer for limiting the light emitting layer B larger than R, and the size of the hole in the pixel limiting layer for limiting the light emitting layer R is larger than that of G. For example, the size of the hole in the pixel limiting layer for limiting the light emitting layer B is larger than R, and the size of the hole in the pixel limiting layer for limiting the light emitting layer, R is the same as G. For example, the size of the hole in the pixel limiting layer for limiting the light emitting layer B is the same as R, and the size of the hole in the pixel limiting layer for limiting the light emitting layer R is larger than G. For example, the size of the hole in the pixel limiting layer for limiting the light emitting layer R b larger than G. For example, the size of the hole in the pixel limiting layer for limiting the light emitting layer of G is larger than R. For example, the size of the hole in the pixel limiting layer for limiting the light emitting layer of G is larger than that of B. For example, the number of subpixels included in each repeating block or pixel block can be any one or a combination of two or more elements selected from the group consisting of 2, 3, 4, 5, 6, 7, 8, 9, 10, etc.

In some embodiments, some subpixels of the same color may have different area effective light emitting areas. For example, in some embodiments, subpixels included in one repeating block or pixel block include two green subpixels of the same color, two red subpixels of the same color, two blue subpixels of the same color, or two pairs of subpixels, where each pair of subpixels of the same color (for example, two green subpixels and two red subpixels), and the areas of effective light emitting regions of the subpixels of the same color may be different. In some embodiments, in the case where subpixels of the same color are located in an extreme position, in a special shape region, or in a folding region, etc., their effective light emitting regions may have different areas or shapes relative to the effective light emitting regions of the subpixels of the same and the same color in other areas.

In the above-described embodiments, the luminescence color, size, shape, and position of each sub-pixel can be freely combined. For example, the size and shape of the subpixels may be partly the same and partly different; either completely the same or completely different. For example, some subpixels are the same size but different shapes. For example, some subpixels have almost the same shape outline, but different areas. For example, there may be a different number of second color subpixels around the first color subpixels, and the number of second color subpixels may be 2, 3, 4, 5, 6, 7, 8, and so on. The second color subpixels may have approximately the same distance from the first color subpixel, or some of these second color subpixels have the same distance from the first color subpixel and some of these second color subpixels have different distances from the first color subpixel. For example, there may be a different number of third color subpixels around other second color subpixels, and the number of third color subpixels may be 2, 3, 4, 5, 6, 7, 8, and so on. The third color subpixels may have approximately the same distance from the second color subpixel, or some of these third color subpixels have the same distance from the second color subpixel and some of these third color subpixels have different distances from the second color subpixel. For example, there may be a different number of second color subpixels around other third color subpixels, and the number of second color subpixels may be 2, 3, 4, 5, 6, 7, 8, and so on. The second color subpixels may have approximately the same distance from the third color subpixel, or some of these second color subpixels have the same distance from the third color subpixel and some of these second color subpixels have different distances from the third color subpixel.

FIG. 16 is a partial structural sectional view taken along line G-G of FIG. 1A. 16 only illustratively shows the film layers between the second electrode and the first electrode of each subpixel. As shown in FIG. 16, the total thickness of the film layers between the first electrode and the second electrode of each sub-pixel is smaller than the depth of the hole in the pixel-bounding layer 400. For example, the total thickness of the functional film layers between the first electrode 130 and the second electrode 120 of the first color sub-pixel 100 is greater than than the total thickness of the functional film layers between the first electrode 230 and the second electrode 220 of the second color subpixel 200, and the total thickness of the functional film layers between the first electrode 230 and the second electrode 220 of the second color subpixel 200 is greater than the total thickness of the functional film layers between the first electrode 330 and the second electrode 320 of the third color sub-pixel 300.

For example, the depth of the hole in the pixel-bounding layer 400 is approximately 0.8 to 1.8 microns. For example, the total thickness of the functional film layers between the first electrode 130 and the second electrode 120 of the first color subpixel may be 2800-2900 angstroms, the total thickness of the functional film layers between the first electrode 230 and the second electrode 220 of the second color subpixel 200 may be 2300-2400 angstroms, and the total thickness of the functional film layers between the first electrode 330 and the second electrode 320 of the third color subpixel 300 may be 1800-1900 angstroms.

For example, as shown in FIG. 16, the functional film layers between the first electrode and the second electrode of each subpixel include an auxiliary light emitting layer, and the auxiliary light emitting layer is disposed between the light emitting layer and the second electrode. For example, the auxiliary light emitting layer is in direct contact with the light emitting layer. For example, the first color subpixel 100 includes an auxiliary light emitting layer 140 between the first color light emitting layer 130 and the second electrode 120, the second color subpixel 200 includes an auxiliary light emitting layer 240 between the second color light emitting layer 230 and the second electrode 220, and the third color subpixel 300 includes an auxiliary light emitting layer 340 between the third color light emitting layer 330 and the second electrode 320. For example, the thickness of the auxiliary light emitting layer 140 of the first color subpixel 100 is larger than the thickness of the auxiliary light emitting layer 240 of the second color subpixel 200, and the thickness of the auxiliary light emitting layer 240 of the second of the color sub-pixel 200 is larger than the thickness of the auxiliary light-emitting layer 340 of the third color sub-pixel 300.

For example, the auxiliary light emitting layer may be at least one of film layers having functions of hole transfer, electron blocking, electron transfer, hole blocking, light emission, and so on. For example, the auxiliary light emitting layer is in direct contact with the light emitting layer. For example, the light emitting layer is formed directly on the surface of the auxiliary light emitting layer remote from the base substrate. For example, the auxiliary light emitting layer in each color subpixel in the embodiment of the present disclosure can be formed using the same precision metal mask as the corresponding color light emitting layer, so that the auxiliary light emitting layer of each color subpixel has basically the same shape, size , projection characteristics, etc., as the corresponding color light emitting layer, which is not repeated in this case.

For example, the distance between the base substrate and one surface of the first color light emitting layer 130 remote from the base substrate is greater than the distance between the base substrate and one surface of the second color light emitting layer 230 remote from the base substrate, and the distance between the base substrate and one surface of the second of the color light emitting layer 230 remote from the base substrate is greater than the distance between the base substrate and one surface of the third color light emitting layer 330 from the base substrate.

For example, the distance between one surface of the first color light emitting layer 130 away from the base substrate and the flat surface of the pixel-bounding layer 400 is greater than the distance between one surface of the second color light-emitting layer 230 away from the base substrate and the flat surface of the pixel-bounding layer 400, the distance between one surface of the second color light emitting layer 230 away from the base substrate and the flat surface of the pixel-bounding layer 400 is greater than the distance between one surface of the third color light-emitting layer 330 away from the base substrate and the flat surface of the pixel-bounding layer 400.

For example, the slope angle of the sloping portion at the opening of the pixel-bounding layer 400 may be in the range of 16 to 22 degrees. For example, the angle of inclination of the sloped portion at the opening of the pixel-bounding layer 400 may be in the range of 18 to 20 degrees. In the case where the slope portion of the pixel bounding layer is an arc surface, the slope angle is an included angle between the tangent line at the intersection of the slope portion and the second electrode of the subpixel organic light emitting element and the base substrate. But, without being limited to this, there is a connecting line connecting a midpoint at a position equal to half the height of the pixel limiting layer 400 and an intersection point between the pixel limiting layer 400 and the second electrode of the subpixel organic light emitting element, and the angle of inclination may also be the angle between the connecting line and the plane where the base substrate is located.

For example, as shown in FIG. 16, the hole transfer integral layer 30 and the hole injection integral layer 40 are also placed between the light emitting layer and the second electrode of the organic light emitting element of each subpixel. For example, the thickness of the hole injection layer 40 may be 5-10 nm, and the thickness of the hole transfer layer 30 may be 90-120 nm. Since there are multiple continuous film layers between the light emitting layer and the second electrode, a cross-leakage current may occur in the hole transfer layer and the hole injection layer when a voltage is applied to the second electrode of the organic light emitting element of one color subpixel, resulting in the light emitting layer of the adjacent of a subpixel, crosstalk easily occurs due to the presence of an overlapping portion between the light emitting layer of the adjacent subpixel and the light emitting layer of the subpixel that emits light.

For example, the thickness of the auxiliary light emitting layer 140 of the first color subpixel 100 may be 70 to 90 nanometers, the thickness of the auxiliary light emitting layer 240 of the second color subpixel 200 may be 30 to 40 nanometers, and the thickness of the auxiliary light emitting layer 340 of the third color subpixel 300 may be 5 to 10 nanometers. .

For example, at least one layer selected from the group consisting of an electron injection layer (not shown in the figure), an electron transport layer (not shown in the figure), and a hole-blocking layer (not shown in the figure) is also placed between the light emitting layer and the first electrode of the organic light emitting element of each subpixel. For example, the electron injection layer, the electron transport layer, and the hole blocking layer are continuous integral film layers.

For example, the thickness of the hole-blocking layer may be in the range of 5 to 10 nanometers. For example, the thickness of the electron transport layer may be 20 to 30 nanometers.

For example, the second electrode of the organic light emitting element of each subpixel may have a multilayer structure such as a multilayer structure including indium tin oxide, silver, and indium tin oxide. For example, the thickness of the second electrode of the organic light emitting element may be in the range of 100 to 180 nanometers. For example, the thickness of the second electrode of the organic light emitting element may be in the range of 110 to 130 nanometers.

As shown in FIG. 16, the first electrodes of the organic light emitting element of the plural subpixels are an integral film layer, and the sum of the thickness of the first organic light emitting element electrode and the thickness of the film layers between the first electrode and the second electrode of the organic light emitting element is smaller than the hole depth of the pixel-bounding layer, so that the first electrode of the organic light emitting element located in the hole and on the pixel-bounding layer forms a reflective cup-like structure, thereby increasing light output and reducing scattering.

For example, the material of the first electrode of the organic light emitting element may include magnesium and silver, such as a magnesium-silver alloy. For example, the thickness of the first electrode of the organic light emitting element may be in the range of 10 to 18 nanometers. For example, the thickness of the first electrode of the organic light emitting element may be in the range of 12 to 15 nanometers. For example, the thickness of the first electrode of the organic light emitting element may be 100 angstroms.

For example, the light emitting layer and the electron transport layer of each subpixel may include doped host-guest materials, and the other film layers are single molecular weight materials. For example, the material of the electron transport layer may include at least one material selected from the group consisting of ytterbium (Yb), magnesium (Mg) and lithium fluoride (LiF). For example, the material of the electron injection layer may be Yb or a material doped with Mg and LiF.

For example, the auxiliary light emitting layer may have a hole transfer function. For example, in an embodiment of the present disclosure, only the light emitting layers and the auxiliary light emitting layers are film layers that are manufactured using FMM and spaced apart from each other, and the other organic film layers are continuous common film layers. For example, the materials of the sub-pixel auxiliary light-emitting layers of different colors are different. For example, the materials of the hole transfer layer and the auxiliary light emitting layer may be aromatic amine derivatives.

For example, triazine/azine derivatives can be used as the hole blocking layer material. For example, the light emitting layer of the third color subpixel includes a base material and a dopant material, and the thickness of the light emitting layer of the third color subpixel may be 15-20 nm. For example, the light emitting layer of the second color subpixel includes a base material and a dopant material, and the thickness of the light emitting layer of the second color subpixel may be 30 to 40 nm. For example, the luminescent base material of the third color subpixel may include anthracene derivatives, the luminescent base material of the second color subpixel may include a mixture of carbazole and triazine, and the luminescent base material of the first color subpixel may include heterocyclic conjugated classes.

For example, the display panel further includes: a light output layer disposed between the first electrode of the organic light emitting element and the encapsulating layer. For example, the light extraction layer may be an organic layer that is formed on one side of the first electrode, such as the cathode, away from the base substrate during evaporation.

For example, the display panel further includes: a transmission enhancing layer disposed between the first electrode of the organic light emitting element and the encapsulating layer. For example, the transmission enhancing layer may be an inorganic layer that is formed on one side of the first electrode of an organic light emitting element such as a cathode away from the base substrate by an evaporation process. For example, the transmission enhancement layer may include LiF.

In some embodiments, the implementation of the encapsulating layer may have a multilayer structure of the first inorganic encapsulating layer, the organic encapsulating layer and the second inorganic encapsulating layer, which are located in series; the edge of the light extraction layer is located on one side of the edge of the first electrode near the display area, and the edge of the light extraction layer is in contact with the edge of the first electrode and the first inorganic encapsulating layer. The common layer formed using the open mask includes at least a cathode layer and a light output layer, and a boundary of the first electrode is larger than the boundary of the light output layer in order to realize the connection of the first electrode with a track that is on the periphery of the first electrode and is connected to the VSS power terminal. For example, the first electrode is connected to the anode bonding layer, which is located in the same layer as the second electrode, through a through hole, and the anode bonding layer is connected to the track, which is connected to the VSS power terminal and is located in the film layer where the transmission line is located. data.

In some embodiments, at least one of the light extraction layer and the transmission enhancement layer may be omitted from the display panel in order to save the cost of the evaporation process.

In some embodiments, some refractive index control layers may also be included between the final film layer (e.g., cathode layer, light output layer, transmission enhancement layer, or any other functional layer) formed by the evaporation process and the encapsulating layer, and refractive index control the layers include, for example, inorganic layers. For example, the refractive index control layer may include silicon oxide or silicon nitride. For example, the thickness of the refractive index regulating layer is in the range of 30 nm to 1 micron. For example, the refractive index control layer may have a thickness of 40 nm to 500 nm. For example, the refractive index control layer may have a thickness of 50 nm to 200 nm. For example, the refractive index control layer may have a thickness of 50 nm to 100 nm. For example, the refractive index control layer can be made by vapor deposition. For example, the refractive index control layers have different densities, such as gradient change or multilayer change, to meet refractive index requirements. For example, the refractive index of the refractive index adjusting layer is in the range of 1.3 to 1.8. For example, the refractive index of the refractive index adjusting layer is in the range of 1.4 to 1.7. For example, the refractive index of the refractive index adjusting layer is in the range of 1.6 to 1.7.

For example, the surface of the first inorganic encapsulating layer, remote from the base substrate, is formed in such a way as to have a plurality of periodically distributed concave-convex structures. For example, in the concave-convex structure of the surface of the first inorganic encapsulating layer, remote from the base substrate, the height difference between the concave part and the convex part in the direction perpendicular to the base substrate (for example, relative to the plane where the main portion of the anode body is located) is in the range of approximately from 0.5 µm to 1.5 µm. For example, in the concave-convex structure of the surface of the first inorganic encapsulating layer, remote from the base substrate, the height difference between the concave part and the convex part in the direction perpendicular to the base substrate (for example, relative to the plane where the main portion of the anode body is located) is in the range of approximately from 0.6 µm to 1.2 µm. For example, in the concave-convex structure of the surface of the first inorganic encapsulating layer, remote from the base substrate, the height difference between the concave part and the convex part in the direction perpendicular to the base substrate (for example, relative to the plane where the main portion of the anode body is located) is in the range of approximately from 0.8 µm to 1.1 µm. For example, in the concave-convex structure of the surface of the first inorganic encapsulating layer remote from the base substrate, one of the concave part and the convex part has a size in the range of (10-20) µm*(10-20) µm, and, for example, the concave part has size in the range (10-20) µm * (10-20) µm. For example, in the concave-convex structure of the surface of the first inorganic encapsulating layer remote from the base substrate, the other of the concave part and the convex part is substantially formed in the form of connected cells, and the cell line width is approximately 18-25 µm, in order to enhance adhesion between the first inorganic an encapsulating layer and an organic encapsulating layer in direct contact with the first inorganic encapsulating layer; for example, the convex part is essentially in the form of connected cells. By forming a concave-convex structure on the first inorganic encapsulation layer, the water and oxygen permeation path can be reduced and the encapsulation effect can be improved.

For example, as shown in FIGS. 17A to 18, at least one embodiment of the present disclosure provides a display panel that includes: a base substrate including a display area and a peripheral area located on the periphery of the display area; plural first color subpixels disposed in the display area, wherein the plurality of first color subpixels are disposed in a first direction to form multiple rows of first color subpixels, the plurality of first color subpixel rows are arranged in a second direction, and adjacent rows of first color subpixels in the plurality of first color subpixel rows are offset relative to each other in the first direction; multiple second color subpixels located in the display area and arranged in an array in the first direction and the second direction, and four second color subpixels surrounding one first color subpixel; a plurality of third color subpixels arranged in the display area, wherein the plurality of first color subpixels and the plurality of third color subpixels are alternately arranged in the first direction and the second direction, the plurality of first color subpixels and the plurality of second color subpixels are alternately arranged in the third direction as a first group, the plurality of third the color subpixels and the plurality of second color subpixels are alternately arranged in the third direction as a second group, the first group and the second group are alternately arranged in the fourth direction, and the third direction and the fourth direction intersect with both the first direction and the second direction; a pixel limiting layer located in a display area and a peripheral area, wherein the pixel limiting layer includes multiple holes for forming an effective light emitting area of multiple subpixels, the multiple first color subpixels include multiple first effective light emitting areas, the multiple second color subpixels include color the plurality of second effective light emitting regions, and the plurality of third color subpixels include the plurality of third effective light emitting regions. The multiple first color subpixels include multiple first color light emitting layers located in the respective holes and on the pixel-bounding layer surrounding the respective holes, the multiple second color sub-pixels include multiple second color light-emitting layers located in the respective holes and on the pixel-bounding layer, surrounding the respective holes, the plurality of first color light emitting layers included in the plurality of first color subpixels are spaced apart from each other, and the plurality of second color light emitting layers included in the plurality of second color subpixels are spaced apart from each other; the plurality of third color subpixels include the plurality of third color light-emitting layers located in the respective holes and on the pixel-limiting layer surrounding the respective holes, and the plurality of third color light-emitting layers included in the plurality of third color subpixels are spaced apart from each other. The subpixel includes a first electrode and a second electrode, and a second electrode located between the base substrate and the first electrode; the pixel bounding layer includes a plurality of first bounding portions and a plurality of second bounding portions substantially extending in the first direction, the first bounding portions and the second bounding portions are alternately arranged in the second direction, and in the second direction, the average height of one first bounding portion and one second bounding portion the area located on both sides of the same row of subpixels placed in the first direction are different; the average heights of the multiple first bounding portions in the display area are approximately the same, the average heights of the multiple second bounding portions in the display area are approximately the same; the average height of the first boundary portion is the average height from the surface of the first boundary portion remote from the base substrate to the plane where the surface of the main base electrode of the second electrode is distant from the base substrate, and the average height of the second boundary portion is the average height from the surface of the second boundary a portion remote from the base substrate to a plane where the main base electrode surface of the second electrode is away from the base substrate.

In some embodiments, the relationship between the pixel limiting layer and the light emitting layer and the pixel arrangement method may be different from those in the above embodiments.

For example, FIG. 17A is a planar view of a pixel limiting layer and an effective light emitting region in a display area shown in an embodiment of the present disclosure, and FIG. 18 is a partial structural sectional view taken along line H-H shown in FIG. 17A. 17A exemplarily shows a pixel limiting layer and a second electrode and a light emitting layer of each subpixel. As shown in FIGS. 17A and FIG. 18, the pixel bounding layer 400 includes undulating first bounding portions 410 and undulating second bounding portions 420 alternately arranged in the first direction, and the average height of the first bounding portions 410 is greater than the average height of the second bounding portions. areas 420. For example, the pixel bounding layer 400 includes multiple first bounding portions 410 and multiple second bounding portions 420 substantially extending in the first direction, the first bounding portions and the second bounding portions are alternately placed in the second direction, and in the second direction, average heights one first boundary portion 410 and one second boundary portion 420 located on both sides of the same subpixel row are different; the average heights of the multiple first bounding portions 410 located in the display area are approximately the same, the average heights of the multiple second bounding portions 420 located in the display area are approximately the same; the average height of the first boundary portion 410 is the average height from the surface of the first boundary portion 410 away from the base substrate to the plane where the surface of the main base electrode of the second electrode is away from the base substrate, and the average height of the second boundary portion 420 is the average height from the surface the second limiting portion 420 remote from the base substrate to the plane where the surface of the main base electrode of the second electrode is removed from the base substrate. For example, since the second electrode may be uneven, the plane in which the portion of the second electrode is substantially located in the hole of the pixel-bounding layer is taken as the reference plane. For example, the main base electrode of the second electrode may be a portion of the second electrode exposed by the aperture of the pixel-bounding layer. For example, the main base electrode of the second electrode may not only include a portion of the second electrode exposed by the hole of the pixel-bounding layer, but also include an annular portion surrounding the portion of the second electrode exposed by the hole of the pixel-bounding layer, and the width of each portion the annular section is approximately the same. For example, the main base electrodes of the second electrodes exposed by the apertures of the pixel-bounding layer may be disposed in substantially the same plane.

FIG. 17A only illustratively shows the effective light emitting area of each subpixel, and the size and shape of the effective display area of each subpixel in this document is the same as the size and shape of the effective display area of each subpixel shown in FIG. 1A. 17A exemplarily shows a first bounding area and a second bounding area with different fill colors, and the first bounding area and the second bounding area can be combined to form a cell.

For example, the first boundary portion 410 and the second boundary portion 420 are used to separate at least two rows of subpixels.

For example, both the length of the first boundary portion 410 extending in the first direction and the length of the second boundary portion 420 extending in the first direction at least include the sum of the size of the effective light emitting regions of four successive subpixels in that direction and the size of the gaps between effective light emitting areas of four consecutive subpixels in that direction.

For example, as shown in FIG. 17A, two adjacent subpixel rows form a pixel block row 1010, and in the second direction, the average height of the first two bounding portions 410 located on either side of one pixel block row 1010 is greater than the average height of one second bounding box. a plot 420 located between two sub-pixel lines in one line 1010 of pixel blocks. For example, the pixel block row 1010 includes a row in which the first color subpixel 100 and the third color subpixel 300 are alternately arranged, and a row formed by the second color subpixels 200.

For example, the angle of inclination of the midpoint of the slope at the opening of the first boundary portion 410 is greater than the angle of inclination of the midpoint of the slope at the opening of the second boundary portion 420, the midpoint of the slope is, for example, at a position approximately half the thickness of the slope in the direction perpendicular to base substrate, or at a position approximately half the size of the projection of the inclined portion onto the plane. For example, the trend of changing the angle from one end of the opening of the first boundary portion 410 remote from the second organic light emitting element electrode to the other end of the opening of the first boundary portion 410 located adjacent the second organic light emitting element electrode is slower than the trend of changing the angle of inclination from one end of the opening of the second boundary portion 420 of the second organic light emitting element electrode to the other end of the opening of the second boundary portion 420 adjacent the second organic light emitting element electrode.

For example, the average height of the first boundary portion and the average height of the second boundary portion refer to the height relative to the surface on which the main base electrode of the second electrode of the organic light emitting element of each sub pixel is located. For example, the alignment layer is provided on one side of the second electrode of the organic light emitting element facing the base substrate, and the average height of the first boundary portion and the average height of the second boundary portion may also refer to the average distance between the surface of each boundary portion remote from the alignment layer and the surface each bounding area adjacent to the leveling layer.

For example, as shown in FIG. 17A, a pixel arrangement structure formed from multiple first color subpixels 100, multiple second color subpixels 200, and multiple third color subpixels 300 includes multiple minimum repeat blocks 1000 arranged in the first direction, and each minimum the repeating block 1000 includes one first color sub-pixel 100, one third color sub-pixel 300, and two second color sub-pixels 200 which are distributed in two sub-pixel rows; one second color sub-pixel 200 and first color sub-pixel 100 form a first virtual pixel, while second color sub-pixel 200 and third color sub-pixel 300 form a second virtual pixel, first color sub-pixel 100 and third color sub-pixel 300 are shared by two virtual pixels, respectively. The virtual pixel described in the present embodiment is not a pixel in the strict sense, that is, a pixel entirely defined by one blue sub-pixel, one green sub-pixel, and one red sub-pixel. The minimum repeating block in this document means that the pixel arrangement structure can be formed by re-arranging the minimum repeating blocks. In an embodiment of the present disclosure, the virtual pixel method for reducing the number of subpixels by sharing some subpixels can reduce the density of physical subpixels while maintaining the same resolution of component images, thereby reducing the complexity of the display device manufacturing process, improving productivity and reducing cost.

For example, in the second direction, the first bounding areas 410 are located on either side of the minimum repeating blocks 1000 placed in the first direction, and the second bounding areas 420 are located in the space between two subpixel rows in which the minimum repeating blocks 1000 are distributed. For example, the first virtual pixel and a second virtual pixel are alternately placed in the first direction and the second direction, the first bounding areas 410 are located on either side of the minimum repeating blocks 1000 placed in the first direction, and the second bounding areas 420 extend through the interval between two subpixels in each virtual pixel. In an embodiment of the present disclosure, by alternately arranging the first boundary portion and the second boundary portion, the color shift at the edge of the display area can be reduced, and display uniformity between the edge and the inside of the display area can be improved, which is useful for blending colors of subpixels in a virtual pixel.

For example, FIG. 17B and FIG. 17C show planar structural views of the display area pixel bounding layer and the peripheral area at two different positions, respectively. As shown in FIGS. 17B and 17C, the average height of one first bounding area 410 is greater than the average height of the second bounding area 420, and the pixel-bounding layer 400 in the peripheral area is the third bounding area 430. For example, the average height of the third bounding area 430 greater than the average height of the second bounding area 420. For example, the average height of the pixel-bounding layer 400 in the peripheral area is approximately equal to the average height of the first bounding area 410. In this document, the term "approximately equal" means that, taking into account deviations in the processing process, the area of the pattern the pixel-bounding layer in the peripheral area is larger than the pattern area of the pixel-bounding layer in the display area, so the processing may cause the height of the pixel-bounding layer in the peripheral area to be slightly increased or the height of the first bounding area to be slightly reduced. For example, the average height ratio between the pixel-bounding layer in the peripheral area and the first bounding portion is 1.1:0.9.

For example, as shown in FIG. 17B and FIG. 17C, the pixel-bounding layer in the peripheral area may be integrated with the first bounding areas and the second bounding areas. In addition to the portion of the peripheral region shown in the figure, another portion of the peripheral region may also include some patterns in the same layer as the pixel-bounding layer, such as barrier baffles for encapsulation, such as insulating protrusions for isolating organic functional film layers. and pixel-bounding layer materials remaining in some through holes or hollow structures in the peripheral region. In some embodiments, the pixel-bounding layer in the display area is completely covered by the cathode.

For example, FIG. 17D shows a planar structural view of a pixel-bounding layer in a display area shown in another example. As shown in FIG. 17D, the present example differs from the example shown in FIG. 17A in that the first boundary portion 410 and the second boundary portion 420 are substantially linear, and the first boundary portion 410 and the second boundary portion 420 are connected by a boundary connecting portion 440 For example, the first boundary portion 410, the second boundary portion 420, and the boundary connecting portion 440 may be combined.

For example, as shown in FIG. 18, the pixel bounding layer 400 includes a flat portion 404 and a sloped portion 405, the sloped portion 405 surrounds each aperture, and the sloped portion 405 includes a first sloped sub-section 4051 adjacent the flat portion 404, and a second sloping sub-section 4052 located at a distance from the flat section 404. In the third direction or the fourth direction, the aspect ratio between the orthogonal projections of the first sloping sub-section 4051 and the second sloping sub-section 4052 onto the base substrate does not exceed 1/4, and the average angle of inclination of the first sloping sub-section 4051 is smaller than the average angle of inclination of the second slanted sub-section 4052. For example, a flat area is a substantially flat structure, such as an area exceeding 80% of the maximum thickness of the pixel-bounding layer. Herein, the slope angle is, for example, the included angle between a tangent drawn from the sloped surface and the surface of the base substrate, and the average value of the slope angles measured at several consecutive points or several points at fixed intervals on the surface is the average slope angle.

For example, the thickness of the pixel-bounding layer is generally greater than 1.1 microns, the angle of the hole in the pixel-bounding layer is 20 degrees, and the length of the sloped portion is about 3 microns.

For example, as shown in FIG. 1A, in order to prevent the peripheral region 12 from affecting the organic light emitting elements in the display region 11 close to the peripheral region 12, a transition region 13 is provided in the region of the peripheral region 12 adjacent to the display region 11. Some fictitious sub-pixels 31 may be made in the transition region 13.

For example, FIG. 19 is a partial sectional view of the transition region shown in FIG. 1A. 19 illustrates an exemplary sectional view of a first type of dummy sub-pixel 31A and a second type of dummy sub-pixel 31A'. As shown in FIG. 19, in the dummy subpixel, the pixel limiting layer 400 may not have a hole region. In the first type of dummy sub-pixel 31A, the second electrode 41A' is disposed on one side of the pixel limiting layer 400 facing the base substrate 10, while the first dummy auxiliary light emitting layer 42A, the first dummy light emitting material layer 43A, and the first electrode 24 are sequentially stacked on the side of the pixel-bounding layer 400 away from the base substrate 10.

Note that, in an embodiment of the present disclosure, the pixel circuit may have a 7T1C structure (i.e., seven transistors and one capacitor) as shown in Fig. 1, and may also have a structure including a different number of transistors and capacitors, such as a structure 7T2C, 6T1C pattern, 6T2C pattern, or 9T2C pattern, without limitation in an embodiment of the present disclosure. In an embodiment of the present disclosure, the pixels may be based on any arrangement method such as a stripe arrangement, a triangular arrangement, a tiled arrangement, and so on. In an embodiment of the present disclosure, the RGB numeric proportion in a single pixel block or repeat block may have any one or combination of two or more elements selected from the group consisting of 1:1:2, 1:2:1, 2:2:1 , 1:1:1, 1:2:3, 3:3:2, 1:3:2, 2:3:1, 3:2:3, 2:3:3, etc. For example, RGBs may be the same size or may not be the same size. For example, the size of the hole in the pixel limiting layer for limiting the light emitting layer B is larger than that of R, and the size of the hole in the pixel limiting layer for limiting the light emitting layer B is larger than that of G. For example, the size of the hole in the pixel limiting layer for limiting the light emitting layer B larger than R, and the size of the hole in the pixel limiting layer for limiting the light emitting layer R is larger than that of G. For example, the size of the hole in the pixel limiting layer for limiting the light emitting layer B is larger than R, and the size of the hole in the pixel limiting layer for limiting the light emitting layer, R is the same as G. For example, the size of the hole in the pixel limiting layer for limiting the light emitting layer B is the same as R, and the size of the hole in the pixel limiting layer for limiting the light emitting layer R is larger than G. For example, the size of the hole in the pixel limiting layer for limiting the light emitting layer R b larger than G. For example, the size of the hole in the pixel limiting layer for limiting the light emitting layer of G is larger than R. For example, the size of the hole in the pixel limiting layer for limiting the light emitting layer of G is larger than that of B. For example, the number of subpixels included in each repeating block or pixel block can be any one or a combination of two or more elements selected from the group consisting of 2, 3, 4, 5, 6, 7, 8, 9, 10, etc.

In some embodiments, some subpixels of the same color may have different area effective light emitting areas. For example, in some embodiments, subpixels included in one repeating block or pixel block include two green subpixels of the same color, two red subpixels of the same color, two blue subpixels of the same color, or two pairs of subpixels, where each pair of subpixels of the same color (for example, two green subpixels and two red subpixels), and the areas of effective light emitting regions of the subpixels of the same color may be different. In some embodiments, in the case where subpixels of the same color are located in an extreme position, in a special shape region, or in a folding region, etc., their effective light emitting regions may have different areas or shapes relative to the effective light emitting regions of the subpixels of the same and the same color in other areas.

In the above-described embodiments, the luminescence color, size, shape, and position of each sub-pixel can be freely combined. For example, the size and shape of the subpixels may be partly the same and partly different; either completely the same or completely different. For example, some subpixels are the same size but different shapes. For example, some subpixels have almost the same shape outline, but different areas. For example, there may be a different number of second color subpixels around the first color subpixels, and the number of second color subpixels may be 2, 3, 4, 5, 6, 7, 8, and so on. The second color subpixels may have approximately the same distance from the first color subpixel, or some of these second color subpixels have the same distance from the first color subpixel and some of these second color subpixels have different distances from the first color subpixel. For example, there may be a different number of third color subpixels around other second color subpixels, and the number of third color subpixels may be 2, 3, 4, 5, 6, 7, 8, and so on. The third color subpixels may have approximately the same distance from the second color subpixel, or some of these third color subpixels have the same distance from the second color subpixel and some of these third color subpixels have different distances from the second color subpixel. For example, there may be a different number of second color subpixels around other third color subpixels, and the number of second color subpixels may be 2, 3, 4, 5, 6, 7, 8, and so on. The second color subpixels may have approximately the same distance from the third color subpixel, or some of these second color subpixels have the same distance from the third color subpixel and some of these second color subpixels have different distances from the third color subpixel.

In some embodiments, the display panel may not have a touch function, that is, it does not include touch electrodes. In some embodiments, the touch electrodes of the display panel may not adopt the method of arranging sensor electrode lines and jumper lines, and for example, they may be electrodes having a planar shape. In some embodiments, the display panel touch electrode material may be metal, metal oxide, or any other conductive material.

For example, the transition area 13 on the outside of the display area 11 may include two circles of dummy subpixels 31.

For example, in the transition area 13 on the outer side of the display area 11, the number of rows or columns of dummy subpixels is different at different positions such as a rounded corner area, a notch area, a perforated area, and so on.

For example, an open mask is used to form a common layer on an integral display panel, that is, all sub-pixels use film layers of the same material and the same thickness, such as an electron injection layer, an electron transport layer, and the like. In addition to the organic functional layers between the cathode and the anode, the cathode and the optical functional layer located on one side of the cathode from the anode, such as a light extraction layer (for example, an organic layer), a transmission enhancing layer (for example, an inorganic layer such as LiF) and etc. can also be formed in the evaporation process, and for example, an open mask is used for evaporation.

For example, the distance between the border of the display area of the display panel and the border of the orthogonal projection of the open mask on the display panel may be 0.3 mm.

For example, the distance between the light emitting layer at the edge of the display area and the orthogonal projection boundary of the open mask on the display panel may be 0.01-0.02 mm.

For example, the distance between the boundary of the display area and the boundary of the first electrode of the organic light emitting element may be 0.3 mm.

The following statements should be noted:

(1) In the accompanying drawings of the embodiments of the present disclosure, the drawings only include the structure(s) in connection with the embodiment(s) of the present disclosure, and other structure(s) may be referred to as the overall design(s).

(2) If there is no conflict, the features in one embodiment or in different embodiments may be combined.

(3) For a combination of different embodiments, some features in some embodiments may be combined with some features in other embodiments. The combination of technical features in each embodiment is added for the convenience of understanding the completeness of the description of the circuit, in which some features are not necessary in the embodiment in which they are located, and in some cases, some features may be omitted.

What has been described above are only specific implementations of the present disclosure, the scope of the present disclosure is not limited to this, and the scope of the present disclosure should be based on the scope of the claims.

Claims (110)

1. Display panel, containing: a base substrate containing a display area and a peripheral area located on the periphery of the display area; a plurality of first color subpixels arranged in a display area, wherein a plurality of first color subpixels are arranged in a first direction to form a plurality of first color subpixel rows, a plurality of first color subpixel rows are arranged in a second direction, and adjacent first color subpixel rows in a plurality of first color subpixel rows are shifted relative to each other in the first direction; a plurality of second color subpixels located in the display area and arrayed in the first direction and the second direction, the four second color subpixels surrounding the first one color subpixel; a pixel limiting layer disposed in a display area and a peripheral area, wherein the pixel limiting layer comprises a plurality of holes for forming an effective light emitting region of a plurality of subpixels, the plurality of first color subpixels comprise a plurality of first effective light emitting regions, the plurality of second color subpixels comprise a plurality of second effective light emitting regions, and the area of one of the plurality of second effective light emitting regions is less than the area of one of the plurality of first effective light emitting regions, wherein the plurality of first color subpixels comprise a plurality of first colored light-emitting layers located in the respective holes and on the pixel-bounding layer surrounding the respective holes, the plurality of second colored sub-pixels comprise a plurality of second colored light-emitting layers located in the respective holes and on the pixel-limiting layer surrounding the respective holes. apertures, a plurality of first color light emitting layers included in the plurality of first color subpixels are spaced apart from each other, and a plurality of second color light emitting layers included in the plurality of second color subpixels are spaced apart from each other; the area ratio between the orthogonal projections of the first color light emitting layer and the first effective light emitting region corresponding to the same first color subpixel onto the base substrate is the first area ratio, the area ratio between the orthogonal projections of the second color light emitting layer and the second effective light emitting region corresponding to one and the same second color subpixel, onto the base substrate is the second area ratio, and the first area ratio is less than the second area ratio. 2. The display panel of claim 1, wherein the first area ratio and the second area ratio are between 1 and 15. 3. The display panel according to claim 1 or 2, in which the first area ratio and the second area ratio are in the range from 4 to 6; or, the first area ratio and the second area ratio are in the range of 6 to 8; or the first area ratio is in the range of 2 to 6, and the second area ratio is in the range of 6.5 to 8. 4. The display panel according to any one of claims 1 to 3, wherein at least a portion of the plurality of second effective light emitting regions has a length direction and a width direction, the length direction being the extension direction of a connecting line between two points furthest from each other in one of the plurality of second effective light emitting regions, and the width direction is substantially perpendicular to the length direction of said one of the plurality of second effective light emitting regions; for one second effective light emitting area in the length direction, the ratio of the maximum size of the second color light emitting layer corresponding to the second effective light emitting area to the maximum size of the second effective light emitting area is the first ratio, and in the width direction, the ratio of the maximum size of the second color light emitting layer corresponding to the second effective light emitting region to the maximum size of the second effective light emitting region is the second ratio, and the first ratio is smaller than the second ratio. 5. The display panel according to claim 4, wherein for the same second effective light emitting area in the length direction, the difference between the maximum size of the second color light emitting layer and the maximum size of the second effective light emitting area is the first difference, and in the width direction, the difference between the maximum the size of the second color light emitting layer and the maximum size of the second effective light emitting area is the second difference, and the first difference is smaller than the second difference. 6. The display panel according to claim 4 or 5, wherein the ratio of the maximum size of the second color light emitting layer in the length direction corresponding to the second effective light emitting area to the maximum size of the second color light emitting layer in the width direction corresponding to the second effective light emitting area is less than the ratio of the maximum size of the second effective light emitting region in its length direction to the maximum size of the second effective light emitting region in its width direction. 7. Display panel according to any one of claims 1 to 6, further comprising: a plurality of third color subpixels arranged in the display area, wherein a plurality of first color subpixels and a plurality of third color subpixels are alternately arranged in the first direction and a second direction, a plurality of first color subpixels and a plurality of second color subpixels are alternately arranged in the third direction as a first group, a plurality of third color subpixels and a plurality of second color subpixels are alternately arranged in a third direction as a second group, wherein the first group and the second group are alternately arranged in the fourth direction, and the third direction and the fourth direction intersect with both the first direction and the second direction; wherein the plurality of third color subpixels comprise a plurality of third effective light-emitting regions, wherein the area of one of the plurality of second effective light-emitting regions is less than the area of one of the plurality of third effective light-emitting regions, the plurality of third color subpixels comprise a plurality of third color light-emitting layers located in respective holes, and on the pixel limiting layer surrounding the respective holes, and the plurality of third color light emitting layers included in the plurality of third color subpixels are spaced from each other, the area ratio between the orthogonal projections of the third color light emitting layer and the third effective light emitting region corresponding to the same third color subpixel onto the base substrate is a third area ratio, and the third area ratio is less than the second area ratio. 8. The display panel of claim 7, wherein the area of the first effective light emitting region of one of the plurality of first color subpixels is smaller than the area of the third effective light emitting region of one of the plurality of third color subpixels, and the first area ratio is greater than the third area ratio. 9. The display panel according to claim 7 or 8, wherein the third area ratio is in the range of 1 to 15. 10. Display panel according to any one of paragraphs.7-9, in which the third area ratio is in the range from 1.5 to 7; or the third area ratio is in the range of 2 to 3; or the third area ratio is in the range of 3 to 4. 11. The display panel according to any one of claims 7 to 10, wherein the first color light emitting layer and the second color light emitting layer, which are arranged in the third direction and adjacent to each other, overlap each other, and the second color light emitting layer and the third color light emitting layer layers that are arranged in the third direction and are adjacent to each other overlap each other. 12. The display panel according to any one of claims 7 to 10, wherein the overlapping portion between the first color light emitting layer of one first color subpixel and the light emitting layers of other subpixels is the first overlapping portion, the overlapping portion between the third color light emitting layer of the one third color subpixel and the light emitting layers other subpixels is the second overlapping part, and the overlapping part between the second color light emitting layer of one second color subpixel and the light emitting layers of other subpixels is the third overlapping part; the area ratio between the orthogonal projections of the first overlapping portion and the first color light emitting layer onto the base substrate, and the area ratio between the orthogonal projections of the second overlapping portion and the third color light emitting layer onto the base substrate is less than the area ratio between the orthogonal projections of the third overlapping portion and the second color light emitting layer to the base substrate. 13. The display panel according to any one of claims 7 to 10, wherein the first color light emitting layer and the third color light emitting layer, which are adjacent to each other, do not overlap each other; or the overlap area between the first color light emitting layer and the third color light emitting layer, which are adjacent to each other, is less than the overlap area between the first color light emitting layer and the second color light emitting layer, which are adjacent to each other, and the overlap area between the second color light emitting layer layer and a third color light emitting layer that are adjacent to each other. 14. The display panel according to any one of claims 7 to 10, wherein the width of the pixel limiting layer in the third direction, which is between the first effective light emitting region and the second effective light emitting region, which are adjacent to each other, is in the range of 15 to 25 µm; wherein the pixel-bounding layer includes a first surface facing away from the base substrate and located between the first effective light emitting region and the second effective light emitting region, which are adjacent to each other, in a plane parallel to the base substrate, and in the third direction, a portion of the first surface coated with the first color light emitting layer is 0.3-0.8 of the width of the pixel-bounding layer, and the part of the first surface covered by the second colored light-emitting layer is 0.3-0.8 of the width of the pixel-bounding layer. 15. The display panel according to any one of claims 7 to 14, wherein each of the plurality of subpixels further comprises a first electrode and a second organic light emitting element electrode, the second organic light emitting element electrode being located on the light emitting layer side of the organic light emitting element and the pixel limiting layer facing to the base substrate the second electrode of the organic light emitting element in each of the plurality of subpixels comprises a main base electrode, and in the direction from the center of the effective light emitting region to the edge of the effective light emitting region, the size of the overlapping portion between the main base electrode and the pixel limiting layer does not exceed the size of the overlapping portion between the light emitting layer and the pixel limiting layer layer. 16. The display panel according to claim 1, further comprising: a plurality of third color subpixels arranged in the display area, wherein a plurality of first color subpixels and a plurality of third color subpixels are alternately arranged in the first direction and a second direction, a plurality of first color subpixels and a plurality of second color subpixels are alternately arranged in the third direction as a first group, a plurality of third color subpixels and a plurality of second color subpixels are alternately arranged in a third direction as a second group, wherein the first group and the second group are alternately arranged in the fourth direction, and the third direction and the fourth direction intersect with both the first direction and the second direction; wherein the plurality of third color subpixels comprise a plurality of third effective light-emitting regions, wherein the plurality of third color subpixels comprise a plurality of third colored light-emitting layers located in the respective holes and on the pixel-limiting layer surrounding the respective holes, and a plurality of third colored light-emitting layers included in the plurality of third colored subpixels, spaced apart, while the display panel additionally contains: an encapsulating layer located in the display area and the peripheral area; a first sensor electrode layer located on the side of the encapsulating layer facing away from the base substrate, wherein the first sensor electrode layer comprises a plurality of first sensor electrodes extending in a first direction and a plurality of second sensor electrodes extending in a second direction, each of the plurality of first sensor electrodes comprising a plurality of blocks of first sensor electrodes, each of the plurality of second sensor electrodes contains a plurality of blocks of second sensor electrodes, a layer of first sensor electrodes contains a plurality of lines of sensor electrodes, a plurality of lines of sensor electrodes intersect to form a plurality of first cells, each block of first sensor electrodes and each block of second the sensor electrodes comprise a plurality of first cells connected to each other; a layer of second sensory electrodes containing a plurality of connecting jumpers, wherein the layer of second sensory electrodes contains a plurality of jumpers, the plurality of jumpers intersect to form a plurality of second cells, each of the plurality of connecting jumpers contains a plurality of second cells connected to each other, and adjacent blocks of the second sensory electrodes are electrically connected through at least one connecting jumper; a sensor insulating layer located between the layer of the first sensor electrodes and the layer of the second sensor electrodes, and the block of the second sensor electrodes is electrically connected to the connecting jumper through a through hole passing through the sensor insulating layer, wherein the orthogonal projection of the plurality of sensor electrode lines in the display area onto the base substrate is located within the orthogonal projection of the pixel-limiting layer onto the base substrate. 17. The display panel of claim 16, wherein in the display area, an orthogonal projection of the effective light emitting area of each of the plurality of subpixels onto the base substrate is within an orthogonal projection of each of the plurality of first cells onto the base substrate; the ratio of the opening area of the first cell corresponding to the first color subpixel to the area of the first effective light emitting region and the ratio of the opening area of the first cell corresponding to the third color subpixel to the area of the third effective light emitting region is less than the ratio of the opening area of the first cell corresponding to the second color subpixel to area of the second effective light emitting region. 18. The display panel according to claim 16 or 17, wherein each of the plurality of subpixels further comprises a first electrode and a second organic light emitting element electrode, the second organic light emitting element electrode being located on the light emitting layer side of the organic light emitting element and the pixel limiting layer facing the base the substrate, each of the plurality of sub-pixels further includes a pixel circuit between the second electrode of the organic light emitting element and the base substrate, and the pixel circuit includes a driving transistor; at least one electrode selected from the group consisting of a second organic light emitting element electrode of the first color subpixel, a second organic light emitting element electrode of the second color subpixel, and a second organic light emitting element electrode of the third color subpixel overlaps with the sensor electrode line; and/or the driving transistor of at least one sub-pixel selected from the group consisting of the first color sub-pixel, the second color sub-pixel and the third color sub-pixel overlaps with the sensor electrode line. 19. The display panel of claim 18, wherein the driving transistor in the second color subpixel overlaps with the sensor electrode line, and the second organic light emitting element electrode of the second color subpixel does not substantially overlap with the sensor electrode line; in the first color subpixel, the driving transistor overlaps with the second organic light emitting element electrode but does not substantially overlap with the sensor electrode line, and the second organic light emitting element electrode overlaps with the sensor electrode line; in the third color subpixel, the driving transistor overlaps with the second organic light emitting element electrode but does not substantially overlap with the sensor electrode line, and the second organic light emitting element electrode overlaps with the sensor electrode line, or in the second color subpixel, both the second organic light emitting element electrode and the driving transistor overlap with the sensor electrode line; in the first color subpixel, both the second organic light emitting element electrode and the driving transistor do not substantially overlap with the sensor electrode line; and in the third color subpixel, both the second organic light emitting element electrode and the driving transistor do not substantially overlap with the sensor electrode line, or in the second color subpixel, both the second organic light emitting element electrode and the driving transistor do not substantially overlap with the sensor electrode line; in the first color subpixel, both the second organic light emitting element electrode and the driving transistor overlap with the sensor electrode line; and in the third color subpixel, both the second organic light emitting element electrode and the driving transistor overlap with the sensor electrode line. 20. The display panel of claim 18, wherein in the first color subpixel, the second electrode of the organic light emitting element does not overlap with the driving transistor or the sensor electrode line, but the driving transistor overlaps with the sensor electrode line; in the third color subpixel, the second electrode of the organic light emitting element does not overlap with the driving transistor or the sensor electrode line, but the driving transistor overlaps with the sensor electrode line; in the second color subpixel, the second electrode of the organic light emitting element overlaps with the driving transistor and the sensor electrode line, and the driving transistor overlaps with the sensor electrode line. 21. The display panel of claim 18, wherein the pixel circuit of each of the plurality of subpixels further comprises a data recording transistor and a threshold compensation transistor; the first electrode of the data recording transistor is electrically connected to the first electrode of the driving transistor, the second electrode of the data recording transistor is electrically connected to the data transmission line to receive the data signal, and the gate electrode of the data recording transistor is electrically connected to the scanning signal line to receive the scanning signal; the first electrode of the threshold compensation transistor is electrically connected to the second electrode of the control transistor, the second electrode of the threshold compensation transistor is electrically connected to the gate electrode of the control transistor, and the gate electrode of the threshold compensation transistor is electrically connected to the scan signal line to receive the compensation control signal; the pixel circuit data recording transistor of at least one pixel selected from the group consisting of the first color sub-pixel, the second color sub-pixel and the third color sub-pixel overlaps with the sensor electrode line, and/or the pixel circuit threshold compensation transistor of at least one pixel, selected from the group consisting of the first color sub-pixel, the second color sub-pixel, and the third color sub-pixel overlaps with the sensor electrode line. 22. The display panel according to claim 1, containing: a plurality of third color subpixels arranged in the display area, wherein a plurality of first color subpixels and a plurality of third color subpixels are alternately arranged in the first direction and a second direction, a plurality of first color subpixels and a plurality of second color subpixels are alternately arranged in the third direction as a first group, a plurality of third color subpixels and a plurality of second color subpixels are alternately arranged in a third direction as a second group, wherein the first group and the second group are alternately arranged in the fourth direction, and the third direction and the fourth direction intersect with both the first direction and the second direction; while the display panel additionally contains: a plurality of spacers disposed on a surface of the pixel-bounding layer facing away from the base substrate, the spacers in the display area being spaced between the sub-pixels disposed in the first direction and the spacers in the display space being spaced between the sub-pixels disposed in the second direction; at the same time, in the display area, the ratio K of the areas between the separator and the layer limiting the pixels satisfies the inequality K ≤ S0/[k1*n*m*(S1 _G -S2 _G )+k2*n*m*(S1 _R -S2 _R )+k3 *n*m*(S1 _B -S2 _B )], where n is the number of middle subpixels in the same line, which are located between adjacent separators among the separators placed in the first direction, m is the number of middle subpixels in the same lines that are placed between adjacent separators among the separators placed in the second direction, S0 is the area of one separator; S1 _G , S1 _R and S1 _B are the areas of the light-emitting layers of the second color sub-pixel, the first color sub-pixel and the third color sub-pixel, respectively; S2 _G , S2 _R and S2 _B are the areas of holes of the pixel-bounding layer corresponding to the second color sub-pixel, the first color sub-pixel and the third color sub-pixel; and k1, k2, and k3 are the proportions of the second color subpixels, the first color subpixels, and the third color subpixels in the display area relative to all subpixels, respectively. 23. The display panel of claim 22, wherein the area ratio between the orthogonal projection of the separator onto the base substrate and the orthogonal projection of the pixel-bounding layer onto the base substrate does not exceed 8%. 24. The display panel according to claim 1, further comprising: a plurality of third color subpixels arranged in the display area, wherein a plurality of first color subpixels and a plurality of third color subpixels are alternately arranged in the first direction and a second direction, a plurality of first color subpixels and a plurality of second color subpixels are alternately arranged in the third direction as a first group, a plurality of third color subpixels and a plurality of second color subpixels are alternately arranged in a third direction as a second group, wherein the first group and the second group are alternately arranged in the fourth direction, and the third direction and the fourth direction intersect with both the first direction and the second direction; wherein the plurality of third color subpixels comprise a plurality of third effective light-emitting areas, the plurality of third color subpixels comprise a plurality of third colored light-emitting layers located in the respective holes and on the pixel-limiting layer surrounding the respective holes, and the plurality of third colored light-emitting layers included in the plurality of third color subpixels spaced apart, each of the plurality of subpixels contains the first electrode and the second electrode of the organic light emitting element, the second electrode of the organic light emitting element is located between the base substrate and the first electrode of the organic light emitting element, each subpixel contains functional film layers between the first electrode and the second electrode of the organic light emitting element, an orthogonal projection of the functional film layers onto the base substrate overlaps with the orthogonal projections of the first electrode and the second electrode of the organic light emitting element onto the base substrate, the total thickness of the functional film layers is less than the hole depth in the pixel-bounding layer corresponding to the subpixel, the functional film layers contain a light emitting layer of each subpixel, and the light emitting layers the subpixels comprise first color light emitting layers, second color light emitting layers, and third color light emitting layers; the total thickness of the functional film layers between the first electrode and the second electrode of the organic light emitting element of the first color subpixel is greater than the total thickness of the functional film layers between the first electrode and the second electrode of the organic light emitting element of the second color subpixel, and the total thickness of the functional film layers between the first electrode and the second electrode the organic light emitting element of the second color subpixel is greater than the total thickness of the functional film layers between the first electrode and the second electrode of the organic light emitting element of the third color subpixel. 25. The display panel of claim 24, wherein the functional film layers between the first electrode and the second electrode of the organic light emitting element of each subpixel further comprise an auxiliary light emitting layer, the auxiliary light emitting layer being disposed between the light emitting layer and the second electrode of the organic light emitting element, the thickness of the auxiliary light emitting layer of the first color sub-pixel is larger than the thickness of the auxiliary light-emitting layer of the second color sub-pixel, and the thickness of the auxiliary light-emitting layer of the second color sub-pixel is larger than the thickness of the auxiliary light-emitting layer of the third color sub-pixel. 26. The display panel of claim 1, further comprising: a plurality of third color subpixels arranged in the display area, wherein a plurality of first color subpixels and a plurality of third color subpixels are alternately arranged in the first direction and a second direction, a plurality of first color subpixels and a plurality of second color subpixels are alternately arranged in the third direction as a first group, a plurality of third color subpixels and a plurality of second color subpixels are alternately arranged in a third direction as a second group, wherein the first group and the second group are alternately arranged in the fourth direction, and the third direction and the fourth direction intersect with both the first direction and the second direction; wherein the plurality of third color subpixels comprise a plurality of third effective light-emitting regions, wherein the plurality of third color subpixels comprise a plurality of third colored light-emitting layers located in the respective holes and on the pixel-limiting layer surrounding the respective holes, and a plurality of third colored light-emitting layers included in the plurality of third color subpixels spaced apart; each of the plurality of subpixels includes a first electrode and a second organic light emitting element electrode, a second organic light emitting element electrode located between the base substrate and the first organic light emitting element electrode; the pixel-bounding layer comprises a plurality of first bounding portions and a plurality of second bounding portions extending substantially in the first direction, the first bounding portions and the second bounding portions are alternately placed in the second direction, and in the second direction, the average heights of one first bounding portion and one second bounding portion, which are located on both sides of the same row of subpixels arranged in the first direction are different; the average heights of the plurality of first bounding portions in the display area are approximately the same, the average heights of the plurality of second bounding portions in the display area are approximately the same; the average height of the first boundary portion is the average height from the surface of the first boundary portion facing away from the base substrate to the plane in which the surface of the main base electrode of the second electrode is located facing away from the base substrate, and the average height of the second boundary portion is the average height from the surface the second limiting portion, facing away from the base substrate, to the plane in which the surface of the main base electrode of the second electrode, facing away from the base substrate, is located. 27. The display panel of claim 26, wherein the average height of one first boundary portion is greater than the average height of one second boundary portion, and the pixel-bounding layer in the peripheral area is the third boundary portion, wherein the average height of the third boundary portion is greater than the average the height of the second bounding area. 28. The display panel of claim 26, wherein two adjacent rows of subpixels arranged in the second direction form a row of pixel blocks, and in the second direction, the average height of the first two boundary portions located on either side of one row of pixel blocks is greater than the average height of one second bounding area located between two rows of subpixels in said one row of pixel blocks. 29. The display panel according to any one of claims 26 to 28, wherein the pixel arrangement pattern formed from the plurality of first color subpixels, the plurality of second color subpixels, and the plurality of third color subpixels comprises a plurality of minimum repeating blocks arranged in the first direction, and each minimum the repeating block contains one first color sub-pixel, one third color sub-pixel, and two second color sub-pixels, which are distributed in two sub-pixel rows; in the second direction, the first bounding areas are located on both sides of the minimum repeating blocks placed in the first direction, and the second bounding areas are located in the gap between two subpixel lines in which the minimum repeating blocks are distributed. 30. Display panel, containing: a base substrate containing a display area and a peripheral area located on the periphery of the display area; a plurality of first color subpixels arranged in a display area, wherein a plurality of first color subpixels are arranged in a first direction to form a plurality of first color subpixel rows, a plurality of first color subpixel rows are arranged in a second direction, and adjacent first color subpixel rows in a plurality of first color subpixel rows are shifted relative to each other in the first direction; a plurality of second color subpixels located in the display area and arrayed in the first direction and the second direction, the four second color subpixels surrounding the first one color subpixel; a pixel limiting layer located in a display area and a peripheral area, wherein the pixel limiting layer includes a plurality of holes for forming effective light emitting areas of a plurality of subpixels, a plurality of first color subpixels comprising a plurality of first effective light emitting regions, and a plurality of second color subpixels comprising a plurality of second effective light emitting regions; wherein the light output of the first color subpixel is less than the light output of the second color subpixel; wherein the plurality of first color subpixels comprise a plurality of first colored light-emitting layers located in the respective holes and on the pixel-bounding layer surrounding the respective holes, the plurality of second colored sub-pixels comprise a plurality of second colored light-emitting layers located in the respective holes and on the pixel-limiting layer surrounding the respective holes. openings, a plurality of first color light emitting layers included in the plurality of first color subpixels are spaced apart from each other, and a plurality of second color light emitting layers included in the plurality of second color subpixels are spaced apart from each other; the area ratio between the orthogonal projections of the first color light emitting layer and the first effective light emitting region corresponding to the same first color subpixel onto the base substrate is the first area ratio, the area ratio between the orthogonal projections of the second color light emitting layer and the second effective light emitting region corresponding to one and the same second color subpixel, onto the base substrate is the second area ratio, and the first area ratio is less than the second area ratio. 31. The display panel of claim 30, further comprising: a plurality of third color subpixels arranged in the display area, wherein a plurality of first color subpixels and a plurality of third color subpixels are alternately arranged in the first direction and a second direction, a plurality of first color subpixels and a plurality of second color subpixels are alternately arranged in the third direction as a first group, a plurality of third color subpixels and a plurality of second color subpixels are alternately arranged in a third direction as a second group, wherein the first group and the second group are alternately arranged in the fourth direction, and the third direction and the fourth direction intersect with both the first direction and the second direction; wherein the plurality of third color subpixels comprise a plurality of third effective light emitting areas; the light output of the second color subpixel is greater than the light output of the third color subpixel; the plurality of third color subpixels comprise a plurality of third colored light-emitting layers located in the respective holes and on the pixel-limiting layer surrounding the respective holes, and the plurality of third colored light-emitting layers included in the plurality of third color subpixels are spaced apart from each other, an area ratio between orthogonal projections of the third color light emitting layer and the third effective light emitting region corresponding to the same third color subpixel onto the base substrate is a third area ratio, the third area ratio being smaller than the second area ratio; the light output of the first color sub-pixel is greater than the light output of the third color sub-pixel, and the first area ratio is greater than the third area ratio. 32. The display panel according to claim 31, in which the ratio of the aperture ratio of the first color subpixel to the aperture ratio of the second color subpixel is in the range from 0.5 to 1.6; and/or the ratio of the aperture ratio of the second color sub-pixel to the aperture ratio of the third color sub-pixel is approximately 1:(1.1 ~ 1.9). 33. Display panel, containing: a base substrate containing a display area and a peripheral area located on the periphery of the display area; a plurality of first color subpixels arranged in a display area, wherein a plurality of first color subpixels are arranged in a first direction to form a plurality of first color subpixel rows, a plurality of first color subpixel rows are arranged in a second direction, and adjacent first color subpixel rows in a plurality of first color subpixel rows are shifted relative to each other in the first direction; a plurality of second color subpixels located in the display area and arrayed in the first direction and the second direction, the four second color subpixels surrounding the first one color subpixel; a plurality of third color subpixels arranged in the display area, wherein a plurality of first color subpixels and a plurality of third color subpixels are alternately arranged in the first direction and a second direction, a plurality of first color subpixels and a plurality of second color subpixels are alternately arranged in the third direction as a first group, a plurality of third color subpixels and a plurality of second color subpixels are alternately arranged in a third direction as a second group, wherein the first group and the second group are alternately arranged in the fourth direction, and the third direction and the fourth direction intersect with both the first direction and the second direction; a pixel limiting layer located in the display area and the peripheral area, the pixel limiting layer having a plurality of holes for forming an effective light emitting area of the plurality of subpixels; wherein each of the plurality of subpixels comprises a first electrode and a second organic light emitting element electrode, the second organic light emitting element electrode being positioned between the base substrate and the first organic light emitting element electrode; the pixel-bounding layer comprises a plurality of first bounding portions and a plurality of second bounding portions extending substantially in the first direction, the first bounding portions and the second bounding portions are alternately placed in the second direction, and in the second direction, the average heights of one first bounding portion and one second bounding portion, which are located on both sides of the same row of subpixels arranged in the first direction are different; the average heights of the plurality of first bounding portions in the display area are approximately the same, the average heights of the plurality of second bounding portions in the display area are approximately the same; the average height of the first bounding portion is the average height from the surface of the first bounding portion facing away from the base substrate to the plane in which the surface of the main base electrode of the second electrode is located facing away from the base substrate, and the average height of the second bounding portion is the average height from the surface the second limiting portion, facing away from the base substrate, to the plane in which the surface of the main base electrode of the second electrode, facing away from the base substrate, is located. 34. The display panel of claim 33, wherein the average height of one first boundary portion is greater than the average height of one second boundary portion, and the pixel boundary layer in the peripheral area is the third boundary portion, the average height of the third boundary portion is greater than the average height said one second boundary portion; or two adjacent rows of subpixels arranged in the second direction form a row of pixel blocks, and in the second direction, the average height of the first two bounding areas located on either side of one row of pixel blocks is greater than the average height of one second bounding area located between the two rows subpixels in the specified single row of pixel blocks. 35. The display panel of claim 33, wherein the pixel arrangement pattern formed from the plurality of first color subpixels, the plurality of second color subpixels, and the plurality of third color subpixels comprises a plurality of minimum repeat blocks arranged in the first direction, and each minimum repeat block comprises one a first color sub-pixel, one third color sub-pixel, and two second color sub-pixels that are distributed in two sub-pixel rows; in the second direction, the first bounding areas are located on both sides of the minimum repeating blocks placed in the first direction, and the second bounding areas are located in the gap between two subpixel lines in which the minimum repeating blocks are distributed. 36. Display panel, containing: a base substrate containing a display area and a peripheral area located on the periphery of the display area; a plurality of first color subpixels arranged in a display area, wherein a plurality of first color subpixels are arranged in a first direction to form a plurality of first color subpixel rows, a plurality of first color subpixel rows arranged in a second direction, and adjacent first color subpixel rows in a plurality of first color subpixel rows offset relative to each other in the first direction; a plurality of second color subpixels located in the display area and arrayed in the first direction and the second direction, the four second color subpixels surrounding the first one color subpixel; a plurality of third color subpixels arranged in the display area, wherein a plurality of first color subpixels and a plurality of third color subpixels are alternately arranged in the first direction and a second direction, a plurality of first color subpixels and a plurality of second color subpixels are alternately arranged in the third direction as a first group, a plurality of third color subpixels and a plurality of second color subpixels are alternately arranged in a third direction as a second group, wherein the first group and the second group are alternately arranged in the fourth direction, and the third direction and the fourth direction intersect with both the first direction and the second direction; a pixel-bounding layer located in a display area and a peripheral area, wherein the pixel-bounding layer has a plurality of holes for forming effective light-emitting regions of a plurality of subpixels, while the display panel additionally contains: a plurality of spacers located on the surface of the pixel-bounding layer facing away from the base substrate, wherein the spacers in the display area are located in the spaces between the sub-pixels placed in the first direction, and the spacers in the display area are located in the spaces between the sub-pixels placed in the second direction, in the display area, the area ratio K between the separator and the pixel-bounding layer satisfies the inequality K ≤ S0/[k1*n*m*(S1 _G -S2 _G )+k2*n*m*(S1 _R -S2 _R )+k3*n *m*(S1 _B -S2 _B )], where n is the number of middle subpixels in one line that are located between adjacent separators among the separators placed in the first direction, m is the number of middle subpixels in the same line that runs between adjacent separators among the separators placed in the second direction, S0 is the area of one separator; S1 _G , S1 _R and S1 _B are the areas of the light-emitting layers of the second color sub-pixel, the first color sub-pixel and the third color sub-pixel, respectively; S2 _G , S2 _R and S2 _B are the areas of holes of the pixel-bounding layer corresponding to the second color sub-pixel, the first color sub-pixel and the third color sub-pixel; and k1, k2, and k3 are the proportions of the second color subpixels, the first color subpixels, and the third color subpixels in the display area relative to all subpixels, respectively. 37. A display device comprising a display panel according to any one of claims 1 to 36.

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