JPWO2021147896A5 - - Google Patents

Description

Here, the second interval between each two adjacent through holes along the first direction is the minimum second interval between the two adjacent through holes along the first direction, and the minimum value B _min is This is the minimum value of the minimum second intervals.
In some embodiments, the maximum value A _max and the minimum value B _min satisfy the following relational expression.
A _max : B _min = 10 to 100

In some embodiments, the at least one patterning region includes one patterning region , and an orthogonal projection of the bending display portion of the flexible display panel in the first plane is an orthogonal projection of the patterning region in the first plane. Located within the projection .

1 is a schematic diagram illustrating the structure of a folding display according to some embodiments; FIG. FIG. 3 is a schematic diagram illustrating the structure of another folding display according to some embodiments. FIG. 2 is a sectional view taken along the line A1-A1' of the flexible display panel in FIG. 1 according to some embodiments. FIG. 2 is another cross-sectional view of the flexible display panel in FIG. 1 in the A1-A1' direction according to some embodiments; FIG. 2 is a cross-sectional view of the support plate in FIG. 1 taken along the direction B1-B1' according to some embodiments; 2 is another cross-sectional view of the support plate in FIG. 1 along B1-B1' according to some embodiments; FIG. FIG. 2 is yet another cross-sectional view of the support plate in FIG. 1 in the B1-B1' direction according to some embodiments; 6B is a cross-sectional view along C1-C1' of the bent support plate in FIG. 6B according to some embodiments; FIG. 2 is another cross-sectional view of the support plate in FIG. 1 along B1-B1' according to some embodiments; FIG. 2 is another cross-sectional view of the support plate in FIG. 1 along B1-B1' according to some embodiments; FIG. FIG. 2 is yet another cross-sectional view of the support plate in FIG. 1 in the B1-B1' direction according to some embodiments; FIG. 2 is yet another cross-sectional view of the support plate in FIG. 1 in the B1-B1' direction according to some embodiments; FIG. 3 is a schematic diagram illustrating the structure of a support plate after bending according to some embodiments; 6 is a partially enlarged view of location P in FIG. 5. FIG. 6 is a cloud atlas showing the stress distribution in the bending region after bending the support plate in FIG. 5; 9 is a partially enlarged view of location P' in FIG. 8. FIG. FIG. 3 is a schematic diagram illustrating the structure of yet another foldable display according to some embodiments. FIG. 3 is a schematic diagram illustrating the structure of yet another foldable display according to some embodiments. FIG. 2 is yet another cross-sectional view of the support plate in FIG. 1 in the B1-B1' direction according to some embodiments; FIG. 2 is yet another cross-sectional view of the support plate in FIG. 1 in the B1-B1' direction according to some embodiments; FIG. 2 is yet another cross-sectional view of the support plate in FIG. 1 in the B1-B1' direction according to some embodiments;

In some examples , an electroluminescent display panel has multiple sub-pixel regions. As shown in FIG. 3, the display substrate 21 includes a first base 210, a plurality of light emitting elements provided on the first base 210, and a plurality of pixel drive circuits. Typically, each pixel drive circuit corresponds to one light emitting element, and both are provided in one subpixel region. Each pixel drive circuit includes a plurality of thin film transistors 211. Each thin film transistor 211 includes an active layer, a source electrode, a drain electrode, a gate electrode, and a gate insulating layer, and the source electrode and the drain electrode each contact the active layer. Each light emitting device includes an anode 212, a light emitting functional layer 213, and a cathode 214. The anode 212 of each light emitting element is electrically connected to the drain electrode of the thin film transistor 211 serving as a drive transistor among the plurality of thin film transistors 211 of the corresponding pixel drive circuit.

In some embodiments of the present disclosure, a support plate 1 applied to the above-mentioned folding display is provided, and as shown in FIGS. 5 , 6A and 6B , the support plate 1 includes a support plate body 11 and a plurality of It has a through hole 10. The support plate main body 11 has at least one patterning region 03, and the plurality of through holes 10 are provided in the at least one patterning region 03 and extend along the thickness direction of the support plate main body 11. penetrate.

In some other examples, as shown in FIGS. 6A and 6B, the support plate body 11 has a plurality of patterning regions 03, and the plurality of through holes 10 are provided in the plurality of patterning regions 03 and have different patterns. The number of through holes in the patterning area 03 is not completely equal. Here, "not completely equal" means that the number of through holes in some patterning areas is equal and the number of through holes in some patterning areas is unequal, or the number of through holes in each patterning area is equal. This means that the numbers of through holes are not equal.

In some other embodiments, as shown in FIG. 7B, the projected shape of each of the plurality of through holes 10 on the first plane is a chamfered rectangle. Here, a chamfered rectangle means that all four interior corners of a rectangle are chamfered. Of course, the chamfered rectangle may be a rectangle with some internal corners chamfered .

When the support plate 1 is bent, as shown in FIG. 7A, the projected shape of at least one through hole 10 on the first plane is rectangular, and bending stress is concentrated at the intersection of two right-angled sides. As shown in FIG. 7B, when the projected shape of each through hole 10 on the first plane is a chamfered rectangle, bending stress is concentrated at the intersection of the arc of the chamfered rectangle and two adjacent sides. Comparing the two, the bending stress release ability of the through hole 10 whose projected shape on the first plane is a chamfered rectangle is greater than that of the through hole 10 whose projected shape on the first plane is a rectangular shape. is more difficult to break when bent.

In some examples, each curved section is a semicircle. That is, as shown in FIGS. 5 , 6A, and 6B , the projected shape of at least one through hole 10 on the first plane is a closed shape consisting of two straight line parts and two semicircles. In this way, when bending the support plate 1, bending stress is distributed semicircularly. Thereby, bending stress can be dispersed more widely, the bendability of the support plate 1 can be improved, and cracks that occur when the support plate 1 is bent can be prevented.

Illustratively , the projected shape of each through hole 10 on the first plane is a closed shape consisting of two straight line parts and two semicircles, and the area of the closed shape is completely equal, that is, each through hole 10 In the projected shape on the first plane, the lengths and intervals of the two straight line parts are equal, and the radii of the two semicircles are equal.

In some embodiments, as shown in FIGS. 5 to 8, the plurality of through holes 10 are arranged in multiple rows of through holes 10 along the second direction Y, and any two adjacent rows of through holes 10 are provided at intervals. 5 to 8 show examples in which each row of through holes 10 includes a plurality of through holes 10 arranged along the first direction. Of course, each row of through holes 10 in each row or some rows of through holes 10 in a plurality of rows of through holes 10 may include only one through hole 10. In the embodiment of the present disclosure, the number of through holes 10 arranged along the first direction X in each row of through holes 10 is not particularly limited.

In some examples, any of the through holes 10 in any two adjacent rows of the multiple rows of through holes 10 other than the two most extreme through holes 10 of the through holes 10 in one row The holes 10 also overlap with the projections of two adjacent through holes 10 of the other row of through holes 10 on a second plane perpendicular to the second direction Y. Exemplarily, as shown in FIG. 6A , the first through hole 101 is connected to the second through hole 102 and the third through hole 103 of the through holes 10 in adjacent rows, which are perpendicular to the second direction Y. It overlaps with the projection in two planes.

In some other examples, each of the two most extreme through holes 10 of one row of through holes 10 in any two adjacent rows of through holes 10 in a plurality of rows of through holes 10 The through-hole 10 overlaps with the projection of one of the through-holes 10 of the other row or two adjacent through-holes 10 in a second plane perpendicular to the second direction. Exemplarily, as shown in FIG. 6, the fourth through hole 104 of the through holes 10 in the middle row is perpendicular to the second direction Y of the second through hole 102 of the through holes 10 in the adjacent row. overlaps the projection in the second plane. In addition, illustratively, as shown in FIG. 6A , the second through hole 102 is perpendicular to the second direction Y of the first through hole 101 and the fourth through hole 104 of the through holes 10 in adjacent rows. overlaps the projection in the second plane.

As shown in FIG. 9, among the through holes 10 in any two adjacent rows of the multiple rows of through holes 10, any of the through holes 10 in one row is connected to the through hole in the other row. It completely overlaps with the projection of the corresponding one of the through holes 10 in the second plane perpendicular to the second direction Y. Based on this, the solid portion between any two adjacent through holes 10 among the through holes 10 in each row, and the space between two adjacent through holes 10 among the through holes 10 in the adjacent row. The solid portion is continuous in the second direction Y, as shown by the dotted elliptical portion 13 in FIG. 9, for example. In this way, when the support plate 1 is bent along the bending line 12, the direction of bending stress is parallel to the second direction Y, so that the stress applied to the solid portion between two adjacent rows of through holes 10 is large. Therefore, the support plate 1 becomes easy to break.

In some embodiments, as shown in FIGS. 5 to 7B, any two adjacent rows of through holes 10 in one row of through holes 10 in the plurality of rows of through holes 10 may be The projection in the second plane of the part between the two through-holes 10 of is located in the middle of the projection of one of the through-holes 10 of the other row of through-holes 10 in the second plane. Referring to FIG. 12, the support plate 1 is modeled, and a cloud diagram of the stress distribution after the support plate 1 is bent is analyzed using software. According to the stress distribution cloud diagram, the maximum value A _max of the lengths of the plurality of through holes 10 along the first direction The minimum value B _min of the second interval along the first direction The minimum value C _min of the first spacing along the second direction Y between the plurality of through holes 10, the maximum value D _max of the widths of the plurality of through holes 10 along the second direction, and the patterning The relationship between the bending radius R (shown in FIG. 10) of the support plate body 11 bent along the bending line 12 parallel to the first direction X in the region 03 and the thickness t of the support plate body 11 can be determined. .

For example, as shown in FIGS. 5 and 11, for through holes whose orthogonal projection on the first plane is a closed shape, the projected shape of each through hole 10 on the first plane is completely the same, and the area are equal and evenly distributed within the patterning area 03. Therefore, the maximum length A of each through hole 10 along the first direction X is equal, that is, A _max is equal to A, and the minimum second spacing along the first direction B is equal, that is, B _min is equal to B, where any one of the through holes 10 in one column has a connection with any one of the through holes 10 in the adjacent column. The minimum first spacing C along the second direction Y is equal, ie C _min is equal to C, and the maximum width D of each through hole 10 along the second direction Y is equal, ie D _max is equal to D.

For example, as shown in FIG. 13 (FIG. 13 is a partially enlarged view of P' in FIG. 8), for a through hole whose orthographic projection on the first plane is a closed shape, the first Although their projected shapes on a plane are completely the same, their areas are not completely the same, that is, their dimensions are not completely the same. The maximum length of each through hole 10 among the plurality of through holes 10 along the first direction X is not completely the same, that is, it has a plurality of maximum lengths, and in this case, the maximum value A _max is , is the maximum value A' of the plurality of maximum lengths. Among the through holes 10 in the same row among the plurality of through holes 10, the minimum second intervals along the first direction X of each two adjacent through holes 10 are not completely the same; , where the minimum value B _min is the minimum value B′ of the plurality of minimum second intervals. Among the through holes 10 in any two adjacent rows of the plurality of through holes 10, any one of the through holes 10 in one row and any one of the through holes in the adjacent row The minimum first spacings along the second direction Y with the two through-holes 10 are not completely the same, that is, they have a plurality of minimum first spacings, in which case the minimum value C _min has a plurality of minimum first spacings. This is the minimum value C' of the minimum first intervals. The maximum width of each of the plurality of through holes 10 along the second direction Y is equal, that is, D _max is equal to D'.

かつ最大値Ａ_ｍａｘと最小値Ｂ_ｍｉｎは、以下の関係式を満たす。
Ａ_ｍａｘ：Ｂ _ｍｉｎ ＝１０～１００ In some further examples, the maximum value A _max , the minimum value C _min , and the bending radius R satisfy the following relationship:

And the maximum value A _max and the minimum value B _min satisfy the following relational expression.
A _max : B _min = 10 to 100

かつ最小値Ｃ_ｍｉｎと支持プレート本体１１の厚さｔは、以下の関係式を満たし、
ｔ：Ｃ_ｍｉｎ＝１～４
かつ最大値Ｄ_ｍａｘと最小値Ｃ_ｍｉｎは、以下の関係式を満たし、
Ｄ_ｍａｘ：Ｃ_ｍｉｎ＝１～５
最小値Ｂ_ｍｉｎと最小値Ｃ_ｍｉｎは、以下の関係式を満たし、
Ｂ_ｍｉｎ：Ｃ_ｍｉｎ＝０．５～４
かつ最大値Ａ_ｍａｘと最小値Ｂ_ｍｉｎは、以下の関係式を満たす。
Ａ_ｍａｘ：Ｂ _ｍｉｎ ＝１０～１００ In some further examples, the maximum value A _max , the minimum value C _min , and the bending radius R satisfy the following relationship:

And the minimum value C _min and the thickness t of the support plate main body 11 satisfy the following relational expression,
t:C _min =1 to 4
And the maximum value D _max and the minimum value C _min satisfy the following relational expression,
_Dmax : _Cmin =1 to 5
The minimum value B _min and the minimum value C _min satisfy the following relational expression,
_Bmin : _Cmin =0.5~4
And the maximum value A _max and the minimum value B _min satisfy the following relational expression.
A _max : B _min = 10 to 100

In some embodiments, the maximum length of each through hole 10 along the first direction X is in the range of 1 mm to 50 mm, and the thickness t of the support plate body 11 is in the range of 0.01 mm to 0.00 mm. The range is 5mm.

For example, the maximum length of each through hole 10 along the first direction X may be 1 mm, 2 mm, 5 mm, 8 mm, 10 mm, 15 mm, 20 mm, 25 mm, 30 mm, or 50 mm. The thickness t of the support plate main body 11 may be 0.01 mm, 0.05 mm, 0.1 mm, 0.2 mm, or 0.5 mm.

Hereinafter, some specific examples will be provided and the values of each of the above parameters will be specifically explained. Each embodiment takes as an example the projected shape of a plurality of through holes 10 on the first plane and the arrangement method in the patterning area 03 shown in FIG. , the projected shape of each through hole 10 on the first plane is the same, the area is equal, and the second interval between each two adjacent through holes 10 in the first direction X and the second interval along the second direction Y The first interval is equal.

For example, if the maximum length A of each through hole 10 along the first direction The distance B is 0.2 mm, and the through holes 10 of any one of the through holes 10 in one row are aligned with the through holes 10 of any one of the through holes 10 of the adjacent row along the second direction Y. The minimum first interval C is 0.2 mm, the maximum width D of each through hole 10 along the second direction Y is 0.2 mm, and the thickness t of the support plate body 11 is 0.2 mm. Further, for example, if the maximum length A of each through hole 10 along the first direction The second interval B is 0.1 mm, and in the second direction Y between any one of the through holes 10 in one row of through holes 10 and any one of the through holes 10 of the adjacent row of through holes 10. The minimum first interval C along the line is 0.1 mm, the maximum width D of each through hole 10 along the second direction Y is 0.3 mm, and the thickness t of the support plate body 11 is 0.15 mm. .

Further, for example, if the maximum length A of each through hole 10 along the first direction X is 9 mm, the minimum length A of each two adjacent through holes 10 along the first direction The second interval B is 0.1 mm, and in the second direction Y between any one of the through holes 10 in one row of through holes 10 and any one of the through holes 10 of the adjacent row of through holes 10. The minimum first interval C along the direction Y is 0.1 mm, the maximum width D of each through hole 10 along the second direction Y is 0.1 mm, and the thickness t of the support plate body 11 is 0.1 mm.

により、αは２５であり、αは３０未満であることが算出され、ここで、αは、計量単位に着目せず、計算で得られた数値のみに着目する。この支持プレート１に対して、５ｍｍの曲げ半径Ｒで２０万回の曲げ試験を行ったところ、試験合格であり、割れもなく、かつ、平坦性への回復性も良好であった。 For example, if the maximum length A of each through hole 10 along the first direction The distance B is 0.2 mm, and the through holes 10 of any one of the through holes 10 in one row are aligned with the through holes 10 of any one of the through holes 10 of the adjacent row along the second direction Y. The minimum first interval C is 0.2 mm, the maximum width D of each through hole 10 along the second direction Y is 0.2 mm, the thickness t of the support plate body 11 is 0.2 mm , and The bending radius R is 5 mm . formula

As a result, it is calculated that α is 25 and that α is less than 30, and here, for α, attention is not paid to the unit of measurement, but only to the numerical value obtained by calculation. When this support plate 1 was subjected to a bending test of 200,000 times with a bending radius R of 5 mm, it passed the test, had no cracks, and had good recovery to flatness.

Further, for example, if the maximum length A of each through hole 10 along the first direction The second interval B is 0.2 mm, and in the second direction Y between any one of the through holes 10 in one row of through holes 10 and any one of the through holes 10 of the through holes 10 in the adjacent row. The minimum first interval C along the line is 0.2 mm, the maximum width D of each through hole 10 along the second direction Y is 0.2 mm, and the thickness t of the support plate body 11 is 0.2 mm. , and the bending radius R is 3 mm. α is 12.3457, and α is less than 30. When this support plate 1 was subjected to a bending test 200,000 times with a bending radius R of 3 mm, it passed the test, had no cracks, and had good recovery to flatness.

Further, for example, if the maximum length A of each through hole 10 along the first direction The second interval B is 0.1 mm, and the distance between any one of the through holes 10 in one row and any one of the through holes 10 in the adjacent row is along the second direction Y. The minimum first interval C is 0.1 mm, the maximum width D of each through hole 10 along the second direction Y is 0.1 mm, the thickness t of the support plate body 11 is 0.1 mm , and The bending radius R is 1.5 mm. α is 3.08642, and α is calculated to be less than 30. When this support plate 1 was subjected to a bending test of 200,000 times with a bending radius R of 1.5 mm, it passed the test, had no cracks, and had good recovery to flatness.

Further, for example, if the maximum length A of each through hole 10 along the first direction X is 4 mm, the minimum length A of each two adjacent through holes 10 along the first direction The second interval B is 0.1 mm, and in the second direction Y between any one of the through holes 10 in one row of through holes 10 and any one of the through holes 10 of the adjacent row of through holes 10. The minimum first interval C along the axis is 0.1 mm, the maximum width D of each through hole 10 along the second direction Y is 0.2 mm, and the thickness t of the support plate body 11 is 0.15 mm. , and the bending radius R is 1.5 mm. α is 10.4167, and α is calculated to be less than 30. When this support plate 1 was subjected to a bending test of 200,000 times with a bending radius R of 1.5 mm, it passed the test, had no cracks, and had good recovery to flatness.

Further, for example, if the maximum length A of each through hole 10 along the first direction X is 4.5 mm, the maximum length A of each through hole 10 along the first direction The minimum second interval B is 0.2 mm, and the second direction between any one of the through holes 10 in one row and any one of the through holes 10 in the adjacent row The minimum first interval C along the Y direction is 0.15 mm, the maximum width D of each through hole 10 along the second direction Y is 0.2 mm, and the thickness t of the support plate body 11 is 0.15 mm. and the bending radius R is 3 mm. α is 12.3457, and α is calculated to be less than 30. When this support plate 1 was subjected to a bending test 200,000 times with a bending radius R of 3 mm, it passed the test, had no cracks, and had good recovery to flatness.

In addition, by way of example, the maximum length A of each through hole 10 along the first direction The minimum second interval B is 0.2 mm, and the second direction between any one of the through holes 10 in one row and any one of the through holes 10 in the adjacent row The minimum first interval C along the Y direction is 0.1 mm, the maximum width D of each through hole 10 along the second direction Y is 0.2 mm, and the thickness t of the support plate body 11 is 0.15 mm. and the bending radius R is 5 mm. It is calculated that α is 25 and α is less than 30. When this support plate 1 was subjected to a bending test of 200,000 times with a bending radius R of 5 mm, it passed the test, had no cracks, and had good recovery to flatness.

In addition, by way of example, the maximum length A of each through hole 10 along the first direction The minimum second interval B is 0.1 mm, and the second direction between any one of the through holes 10 of one row of through holes 10 and any one of the through holes 10 of the adjacent row of through holes 10 The minimum first interval C along the Y direction is 0.1 mm, the maximum width D of each through hole 10 along the second direction Y is 0.2 mm, and the thickness t of the support plate body 11 is 0.15 mm. and the bending radius R is 5 mm. α is 0.2, and α is calculated to be less than 30. When this support plate 1 was subjected to a bending test of 200,000 times with a bending radius R of 5 mm, it passed the test, had no cracks, and had good recovery to flatness.

In addition, by way of example, the maximum length A of each through hole 10 along the first direction The minimum second interval B is 0.4 mm, and the second direction between any one of the through holes 10 of one row of through holes 10 and any one of the through holes 10 of the adjacent row of through holes 10 The minimum first interval C along the Y direction is 0.1 mm, the maximum width D of each through hole 10 along the second direction Y is 0.2 mm, and the thickness t of the support plate body 11 is 0.2 mm. and the bending radius R is 1.5 mm. α is 5.33, and α is calculated to be less than 30. When this support plate 1 was subjected to a bending test of 200,000 times with a bending radius R of 1.5 mm, it passed the test, had no cracks, and had good recovery to flatness.

In addition, by way of example, the maximum length A of each through hole 10 along the first direction The minimum second interval B is 0.1 mm, and the second direction between any one of the through holes 10 of one row of through holes 10 and any one of the through holes 10 of the adjacent row of through holes 10 The minimum first interval C along the Y direction is 0.2 mm, the maximum width D of each through hole 10 along the second direction Y is 0.4 mm, and the thickness t of the support plate body 11 is 0.2 mm. and the bending radius R is 3 mm. α is 2.67, and α is calculated to be less than 30. When this support plate 1 was subjected to a bending test 200,000 times with a bending radius R of 3 mm, it passed the test, had no cracks, and had good recovery to flatness.

Further, for illustrative purposes, the maximum length A of each through hole 10 along the first direction The minimum second interval B is 0.1 mm, and the second direction between any one of the through holes 10 of one row of through holes 10 and any one of the through holes 10 of the adjacent row of through holes 10 The minimum first interval C along the Y direction is 0.1 mm, the maximum width D of each through hole 10 along the second direction Y is 0.1 mm, and the thickness t of the support plate body 11 is 0.1 mm. and the bending radius R is 1.5 mm. α is 3.09, and α is calculated to be less than 30. When this support plate 1 was subjected to a bending test of 200,000 times with a bending radius R of 1.5 mm, it passed the test, had no cracks, and had good recovery to flatness.

Further, for illustrative purposes, the maximum length A of each through hole 10 along the first direction The minimum second interval B is 0.2 mm, and the second direction between any one of the through holes 10 in one row and any one of the through holes 10 in the adjacent row The minimum first interval C along the Y direction is 0.2 mm, the maximum width D of each through hole 10 along the second direction Y is 0.5 mm, and the thickness t of the support plate body 11 is 0.2 mm. and the bending radius R is 2 mm. α is 18.52, and α is calculated to be less than 30. When this support plate 1 was subjected to a bending test 200,000 times with a bending radius R of 2 mm, it passed the test, had no cracks, and had good recovery to flatness.

In addition, by way of example, the maximum length A of each through hole 10 along the first direction X is 8 mm, and the maximum length A of each through hole 10 along the first direction The minimum second interval B is 0.1 mm, and the second direction between any one of the through holes 10 of one row of through holes 10 and any one of the through holes 10 of the adjacent row of through holes 10 The minimum first interval C along the Y direction is 0.1 mm, the maximum width D of each through hole 10 along the second direction Y is 0.1 mm, and the thickness t of the support plate body 11 is 0.4 mm. and the bending radius R is 5 mm. α is 0.39, and α is calculated to be less than 30. When this support plate 1 was subjected to a bending test of 200,000 times with a bending radius R of 5 mm, it passed the test, had no cracks, and had good recovery to flatness.

Hereinafter, some specific examples will be provided and the values of each of the above parameters will be specifically explained. Each embodiment takes as an example the projected shape of a plurality of through holes 10 on the first plane and the arrangement method in the patterning area 03 shown in FIG. The projected shapes of the through holes 10 on the first plane are the same, but the areas are not completely the same.

により、αは１０．６６６６６７であり、αは３０未満であることが算出される。この支持プレート１に対して、６ｍｍの曲げ半径Ｒで２０万回の曲げ試験を行ったところ、試験合格であり、割れもなく、かつ、平坦性への回復性も良好であった。 For example, if the maximum length A _max of the plurality of through holes 10 along the first direction The minimum value B _min of the spacing is 0.2 mm, and the distance between any one of the through holes 10 of one row of through holes 10 and any one of the through holes 10 of the adjacent row of through holes 10 is The minimum value C _min of the first spacing along the two directions Y is set to 0.2 mm, the maximum value D _max of the widths of the plurality of through holes along the second direction Y is set to 0.2 mm, and the support The thickness t of the plate body 11 is 0.2 mm , and the bending radius R is 6 mm . formula

Therefore, it is calculated that α is 10.666667, which is less than 30. When this support plate 1 was subjected to a bending test 200,000 times with a bending radius R of 6 mm, it passed the test, had no cracks, and had good recovery to flatness.

Further, for example, if the maximum value A _max of the lengths of the plurality of through holes 10 along the first direction The minimum value B _min of the second interval along the The minimum value C _min of the first distance along the second direction Y with the through hole 10 is 0.2 mm, and the maximum value D _max of the widths of the plurality of through holes along the second direction Y is set as The thickness t of the support plate main body 11 is 0.2 mm , and the bending radius R is 3 mm . α is 21.333333, and α is calculated to be less than 30. When this support plate 1 was subjected to a bending test 200,000 times with a bending radius R of 3 mm, it passed the test, had no cracks, and had good recovery to flatness.

Further, for example, if the maximum value A _max of the lengths of the plurality of through holes 10 along the first direction The minimum value B _min of the second interval along the The minimum value C _min of the first distance along the second direction Y with the through hole 10 is 0.1 mm, and the maximum value D _max of the widths of the plurality of through holes along the second direction Y is set as The thickness t of the support plate main body 11 is 0.1 mm , and the bending radius R is 1.5 mm . α is 5.333333, and α is calculated to be less than 30. When this support plate 1 was subjected to a bending test of 200,000 times with a bending radius R of 1.5 mm, it passed the test, had no cracks, and had good recovery to flatness.

Further, for example, if the maximum value A _max of the lengths of the plurality of through holes 10 along the first direction The minimum value B _min of the second interval along the The minimum value C _min of the first distance along the second direction Y with the through hole 10 is 0.1 mm, and the maximum value D _max of the widths of the plurality of through holes along the second direction Y is The thickness t of the support plate main body 11 is 0.15 mm , and the bending radius R is 2 mm . α is 4 and α is calculated to be less than 30. When this support plate 1 was subjected to a bending test 200,000 times with a bending radius R of 2 mm, it passed the test, had no cracks, and had good recovery to flatness.

Further, for example, the maximum value A _max of the lengths along the first direction X of the plurality of through holes 10 is set to 4.5 mm, and the The minimum value B _min of the second interval along one direction The minimum value C _min of the first distance along the second direction Y with one through hole 10 is 0.15 mm, and the maximum value D _max of the width of the plurality of through holes along the second direction Y is set as 0.15 mm. The thickness t of the support plate body 11 is 0.15 mm , and the bending radius R is 3 mm. α is 12.3457, and α is calculated to be less than 30. When this support plate 1 was subjected to a bending test 200,000 times with a bending radius R of 3 mm, it passed the test, had no cracks, and had good recovery to flatness.

As shown in FIGS. 14 and 15, the orthographic projection of the bending display section 01 of the flexible display panel 2 on the first plane overlaps with the orthogonal projection of the patterning area 03 of the support plate 1 on the first plane. That is, the bent display section 01 of the flexible display panel 2 is formed by partially through-cutting at least one patterning area 03 of the support plate 1 in the thickness direction of the support plate 1 when the flexible display panel 2 is unfolded. Directly facing hole 10.

Claims (20)

a support plate body having at least one patterning area;
a plurality of through holes provided in the at least one patterning region and passing through the support plate main body along the thickness direction of the support plate main body, each through hole extending in the thickness direction of the support plate main body; A support plate comprising a plurality of through holes having a band-like projected shape in a first orthogonal plane. The support plate according to claim 1, wherein each of the plurality of through holes extends along a first direction in the first plane. The support plate according to claim 1 or 2, wherein a projected shape of at least one of the plurality of through holes on the first plane is rectangular. The support plate according to claim 1 or 2, wherein a projected shape of at least one of the plurality of through holes on the first plane is a chamfered rectangle. The projected shape of at least one of the plurality of through holes on the first plane is a closed shape consisting of two straight line parts and two curved parts, and both of the two straight line parts extend in the first direction. each end of one straight line portion is aligned with one end of the other straight line portion in a second direction, and the second direction is parallel to the first direction in the first plane. 3. A support plate according to claim 1 or claim 2, wherein each curved section is orthogonal and each curved section is connected to the respective aligned ends of the two straight sections. 6. The support plate of claim 5, wherein each curved section is a semicircle. The plurality of through-holes are arranged in a plurality of rows of through-holes along the second direction, the through-holes in any two adjacent rows are spaced apart, and the through-holes in each row are arranged in a plurality of rows of through-holes along the second direction. Support plate according to any one of claims 2 to 6, having at least one through hole arranged along the support plate, the second direction being perpendicular to the first direction in the first plane. Each row of through holes has a plurality of through holes arranged along the first direction,
Of the through holes in any two adjacent rows of the plurality of rows of through holes, any through hole other than the two extreme through holes in one row is a through hole in the other row. Overlapping with the projection of two adjacent through holes among the two on a second plane perpendicular to the second direction,
Each of the two through holes at both ends has a projection of one of the through holes of the other row or two adjacent through holes in a second plane orthogonal to the second direction. 8. Support plates according to claim 7, which overlap. The projection of a portion between any two of the through holes in the one row on the second plane is the projection of one of the through holes in the other row on the second plane. Support plate according to claim 8, located in the center of the projection. The maximum value A _max of the lengths of the plurality of through holes along the first direction, and any one of the through holes in one row and any one of the through holes in the adjacent row. or one through-hole along the second direction _; The support plate according to any one of claims 7 to 9, wherein the bending radius R to be bent satisfies the following relational expression.

Here, the length of each through hole along the first direction is the maximum length of the through hole along the first direction, and the maximum value A _max is the maximum length of the plurality of maximum lengths. and the first interval along the second direction between any one of the through holes in one column and any one of the through holes in the adjacent column is The minimum first interval between the two through holes along the second direction, the minimum value C _min is the minimum value among the plurality of minimum first intervals, the maximum value A _max and the minimum value C The units of _min and bending radius R are the same. The support plate according to claim 10, wherein the minimum value C _min and the thickness t of the support plate main body satisfy the following relational expression.
t:C _min =1 to 4 The support plate according to claim 10 or 11, wherein the maximum value D _max and the minimum value C _min of the widths of the plurality of through holes along the second direction satisfy the following relational expression.
_Dmax : _Cmin =1 to 5
Here, the width of each through hole along the second direction is the maximum width of the through hole along the second direction, and the maximum value D _max is the maximum value among the plurality of maximum widths. . The minimum value B _min and the minimum value C _min of the second intervals along the first direction between two adjacent through holes among the through holes in the same row satisfy the following relational expression: The support plate according to any one of items 10 to 12.
_Bmin : _Cmin =0.5~4
Here, the second interval between each two adjacent through holes along the first direction is the minimum second interval between the two adjacent through holes along the first direction, and the minimum value B _min is: It is the minimum value of the plurality of minimum second intervals. The support plate according to any one of claims 10 to 13, wherein the maximum value A _max and the minimum value B _min satisfy the following relational expression.
A _max : B _min = 10 to 100 The first interval along the second direction between any one of the through holes in one row and any one of the through holes in an adjacent row is equal, according to any one of claims 7 to 14. support plate. 16. The support plate according to claim 1, wherein each of the plurality of through holes has the same projected shape on the first plane and has the same area. Any one of claims 10 to 16, wherein the maximum length of each through hole along the first direction is in the range of 1 to 50 mm, and the thickness t of the support plate body is in the range of 0.01 to 0.5 mm. The support plate according to item 1. A flexible display panel having a bending display section;
The support plate according to any one of claims 1 to 17, which is provided on a side opposite to the light emission side of the flexible display panel, The folding display wherein the projection overlaps an orthogonal projection of each of the at least one patterning region in the first plane. The at least one patterning region includes one patterning region , and an orthogonal projection of the bending display portion of the flexible display panel on the first plane is located within an orthogonal projection of the patterning region on the first plane . 19. The foldable display according to item 18. Each of the plurality of through holes extends along a first direction in the first plane, and the bending display portion of the flexible display panel is bent along a bending line parallel to the first direction. A folding display according to claim 19.