Abstract: A light guide plate including a light emitting surface, a bottom surface, a light incident surface, multiple protrusion structures, and multiple grooves is provided. The light incident surface is connected between the light emitting surface and the bottom surface. The protrusion structures are disposed along a first direction and extend toward a second direction. The protrusion structures have a light condensing angle along the first direction, and the light condensing angle ranges from 10 degrees to 40 degrees. The grooves are disposed in the protrusion structures of the light guide plate. The grooves extend toward the first direction. The protrusion structures have a light receiving surface that defines each groove and is closer to the light incident surface. An angle between the light receiving surface and the bottom surface ranges from 35 degrees to 65 degrees. A display apparatus adopting the light guide plate is also provided.

Abstract: A method for manufacturing an ultra-thin glass substrate includes: providing a glass base material preset with n substrate areas and a skeleton area surrounding the substrate areas; at least forming an etching protection layer on an upper surface and a lower surface of each substrate area of the glass base material, respectively; at least etching the skeleton area of the glass base material to separate the substrate areas from the glass base material, and form a stress dissipation edge along an edge of each substrate area; and removing the etching protection layer to get independent glass substrates. A method for manufacturing a display panel is also disclosed. An aim is to prevent quality of the ultra-thin glass substrate from damage caused by scribing wheel cutting or laser cutting, therefore the quality of the ultra-thin glass substrate is improved.

Abstract: A method for manufacturing ultra-thin glass substrates and a method for manufacturing a display panel are provided, including: providing a glass base material preset with n substrate areas and a skeleton area surrounding the substrate areas, wherein n is greater than or equal to 1; at least forming an etching protection layer, wherein, each etching protection layer includes a main area and at least one thinned area extending along a preset bending path; at least etching the skeleton area of the glass base material to separate the substrate areas from the glass base material, forming at least one bending stress dissipation groove, and forming a stress dissipation edge along an edge of each substrate area; removing the etching protection layer to get independent glass substrates having the bending stress dissipation groove. The method improves bending performance along the preset bending path.

Abstract: A method for manufacturing ultra-thin glass substrates and a method for manufacturing a display panel are provided. The method for manufacturing ultra-thin glass substrates includes: providing a glass base material preset with n substrate areas and a skeleton area surrounding the substrate areas; at least forming an etching protection layer on each substrate area of the glass base material; immersing the glass base material in a reaction chamber having etching medium; after the edge of each substrate area is etched to form the stress dissipation edge and the substrate areas are separated from the glass base material, the substrate areas falling down by gravity and falling into the basket; pulling the basket out of the reaction chamber to get the substrate areas separated from the glass base material; removing the etching protection layer to get independent glass substrates.

Abstract: The present invention relates to the field of screen display technology, and discloses an automotive organic light-emitting diode (OLED) display screen, including a foldable OLED panel. The foldable OLED panel is of a rectangular structure and includes a display panel end and a folding region. The folding region is folded outwards to form a folded panel end. The foldable OLED panel is provided with at least one folded panel end. A back of the display panel end is bonded and fixed to the folded panel end. A circular polarizer is attached to a surface of the display panel end via an optical adhesive. A protective cover plate is attached to a surface of the circular polarizer via an optical adhesive.

Abstract: A method for manufacturing an ultra-thin glass substrate includes: providing a glass base material preset with n substrate areas and a skeleton area surrounding the substrate areas; at least forming an etching protection layer on an upper surface and a lower surface of each substrate area of the glass base material, respectively; at least etching the skeleton area of the glass base material to separate the substrate areas from the glass base material, and form a stress dissipation edge along an edge of each substrate area; and removing the etching protection layer to get independent glass substrates. A method for manufacturing a display panel is also disclosed. An aim is to prevent quality of the ultra-thin glass substrate from damage caused by scribing wheel cutting or laser cutting, therefore the quality of the ultra-thin glass substrate is improved.

Abstract: An OLED display is disclosed, which includes a substrate and a plurality of pixel groups arranged on the substrate. Each pixel group includes a first, a second, a third and a fourth sub-pixel. Arrangements of the first, second, third and fourth sub-pixels in two neighboring pixel groups are symmetrical with each other. In addition, the distance between the third sub-pixels and the distance between the fourth sub-pixels in two neighboring pixel group are greater than the distance between the first sub-pixels in the two neighboring pixel group.

Abstract: An OLED display is disclosed, which includes a substrate and a plurality of pixel groups arranged on the substrate. Each pixel group includes a first, a second, a third and a fourth sub-pixel. Arrangements of the first, second, third and fourth sub-pixels in two neighboring pixel groups are symmetrical with each other. In addition, the distance between the third sub-pixels and the distance between the fourth sub-pixels in two neighboring pixel group are greater than the distance between the first sub-pixels in the two neighboring pixel group.

Abstract: This disclosure provides a display apparatus and the sealing method thereof. The display apparatus includes: a substrate having a displaying region and a non-displaying region surrounding the displaying region; and a frit disposed on the non-displaying region to form a closed loop which surrounds the displaying region and has both a start portion and an end portion not overlapping each other; wherein a first light beam is applied to the frit to sinter it along the loop in a first direction, and a second light beam is applied to the frit to sinter it along the loop in a second direction, starting at the start portion and ending up at the end portion; wherein, the second direction is different from the first direction.

Abstract: An OLED display is provided. The OLED display includes a substrate, a first light-emissive layer, a second light-emissive layer, and two third light-emissive layers. The two third light-emissive layers corresponds a first sub-pixel and a second sub-pixel adjacent to the first sub-pixel. An axis passes through the first light-emissive layer and the second light-emissive layer. The axis is between the two third light-emissive layers. The configuration of the first sub-pixel and the second sub-pixel are symmetrical with respect to the axis.

Abstract: A display device packaging method comprises steps of: providing a first substrate including a display region and a non-display region that surrounds the display region; providing an adhesive material which is disposed on the first substrate and formed into a closed curve surrounding the display region, wherein the closed curve has a start zone and an end zone connected to the start zone; providing a light-blocking element at least covering the end zone; providing a heating source radiating to the light-blocking element and moving the heating source to the start zone of the adhesive material; and scanning the adhesive material from the start zone to the end zone along the closed curve by the heating source. A display device is also disclosed.

Abstract: This disclosure provides a display apparatus and the sealing method thereof. The display apparatus includes: a substrate having a displaying region and a non-displaying region surrounding the displaying region; and a frit disposed on the non-displaying region to form a closed loop which surrounds the displaying region and has both a start portion and an end portion not overlapping each other; wherein a first light beam is applied to the frit to sinter it along the loop in a first direction, and a second light beam is applied to the frit to sinter it along the loop in a second direction, starting at the start portion and ending up at the end portion; wherein, the second direction is different from the first direction.

Abstract: An OLED display is disclosed, which includes a substrate and a first and a second light emitting unit arranged on the substrate. A first, a second, a third and a fourth region are defined on the substrate, wherein the sub-pixels in the first and fourth regions and the sub-pixels in the second and third regions are symmetrical with each other. Alternatively, the sub-pixels in the first region and the sub-pixels in the third region are point symmetric to a center of the first light emitting unit, so as to improve displaying resolution of the OLED display.

Abstract: An OLED display is provided. The OLED display includes a substrate, a first light-emissive layer, a second light-emissive layer, and two third light-emissive layers. The two third light-emissive layers corresponds a first sub-pixel and a second sub-pixel adjacent to the first sub-pixel. An axis passes through the first light-emissive layer and the second light-emissive layer. The axis is between the two third light-emissive layers. The configuration of the first sub-pixel and the second sub-pixel are symmetrical with respect to the axis.

Abstract: A display device packaging method comprises steps of: providing a first substrate including a display region and a non-display region that surrounds the display region; providing an adhesive material which is disposed on the first substrate and formed into a closed curve surrounding the display region, wherein the closed curve has a start zone and an end zone connected to the start zone; providing a light-blocking element at least covering the end zone; providing a heating source radiating to the light-blocking element and moving the heating source to the start zone of the adhesive material; and scanning the adhesive material from the start zone to the end zone along the closed curve by the heating source. A display device is also disclosed.

Abstract: An OLED display is disclosed, which includes a substrate and a first and a second light emitting unit arranged on the substrate. A first, a second, a third and a fourth region are defined on the substrate, wherein the sub-pixels in the first and fourth regions and the sub-pixels in the second and third regions are symmetrical with each other.

Abstract: This disclosure provides a display apparatus and the sealing method thereof. The display apparatus includes: a substrate having a displaying region and a non-displaying region surrounding the displaying region; and a frit disposed on the non-displaying region to form a closed loop which surrounds the displaying region and has both a start portion and an end portion not overlapping each other; wherein a first light beam is applied to the frit to sinter it along the loop in a first direction, and a second light beam is applied to the frit to sinter it along the loop in a second direction, starting at the start portion and ending up at the end portion; wherein, the second direction is different from the first direction.