The present disclosure provides a backlight source module including a backplate; a bottom reflective sheet, a light guide plate and an optical sheet which are stacked on the backplate in that order; and a frame disposed at peripheral edges of the backplate for holding the bottom reflective sheet, the light guide plate and the optical sheet on the backplate. The backlight source module further includes a gap adjusting element configured to adjust a gap between the optical sheet and the frame in a direction perpendicular to the backplate.

A rubber frame, a backlight, a display device and assembling method thereof are disclosed. Embodiments of the present disclosure relate to the field of display technology, can prevent the liquid crystal panel and the backlight from being loosen or separated from each other and can eliminate or at least reduce display faults caused thereby. The rubber frame of the disclosure is suitable for liquid crystal display devices, and a side wall of the rubber frame is provided a slot for receiving a liquid crystal cell. The slot is formed as a half-closed structure having three enclosing side walls and only one open side. The rubber frame and the display device of the present disclosure include the rubber frame.

An electronic device with a flexible display subassembly is provided. The display stack may use two layers of adhesives having different elastic properties to improve mechanical impact resistance, with a first adhesive layer made of a viscoelastic material and a second adhesive layer having a low modulus of elasticity. The display stack may also include a hot melt protective sheet (HMPS) covering the display subassembly. The HMPS may be wrapped around the two side edges of a rigid substrate to attach directly to the substrate, thereby aiding in the adhesion of the display stack to the substrate. The display stack may also includes a patterned back protective sheet in which the protective backing layer is removed along the curved portions of the display stack.

A display assembly includes a display unit for displaying an image. The display unit includes a backlight unit configured to provide light. A color conversion layer is positioned adjacent to and configured to receive the light from the backlight unit. A structural layer is positioned adjacent to the color conversion layer and configured to support the display unit. A first stack is positioned adjacent to the structural layer and includes a first thin-film-transistor (TFT) layer, a color filter layer and a first liquid crystal layer. The display unit is configured to be bendable to a fixed shape such that the display unit retains the fixed shape.

According to one embodiment, a display device includes a display panel including a display surface and a rear surface located in an opposite side to the display surface, a support plate including a first main surface opposing the rear surface of the display panel, a second main surface located in an opposite side to the first main surface and a first opening opposing at least a central portion of the display panel, and an adhesive tape disposed on the second main surface so as to be overlaid on the first opening, and including a first adhesive region attached on the second main surface around the first opening and a second adhesive region located in the first opening and attached on the rear surface of the display panel.

The disclosure is directed to electronic device displays which are constructed to withstand damage from an impact resistance test wherein a steel ball of 2 g having a diameter of 8 mm is dropped from a designated height greater than 1 ft, more preferably greater than 2 ft, even more preferably greater than 3 ft, still even more preferably greater than 4 ft, yet even more preferably greater than 5 ft and even more preferably greater than 6 ft. The displays are configured using, for example, ultrathin glass adhered to a base glass, wherein the adhesive layer is optimized for thinness and stiffness.

An array substrate, a manufacturing method thereof, a display panel and a display device are disclosed to solve the technical problem that defects are caused to signal line wiring in a periphery area of the array substrate due to pressure applied to a sealant. The array substrate comprises a display area and a periphery area which is provided with a signal line wiring, wherein the periphery area is provided with a protection layer which at least partially covers the signal line wiring.

A method for manufacturing an array substrate includes steps of: forming a pattern which includes a scanning line and a gate on a base substrate (301); forming a gate insulating layer on the pattern which includes the scanning line and the gate; forming a pattern which includes an active layer, a data line and a spacer matrix on the gate insulating layer; forming a passivation layer on the pattern which includes the active layer, the data line and the spacer matrix; dry etching the passivation layer to form a via hole which exposes the spacer matrix; under effect of an electric field generated between the spacer matrix exposed from the via hole and an etching gas, products obtained during the etching is induced to be deposited on the exposed surface of the spacer matrix so as to form a spacer. An array substrate and a display pane are further provided.

A display panel includes a first substrate, a second substrate, and a liquid crystal layer between the first substrate and the second substrate. A volume-variable structure is arranged between the first substrate and the second substrate. The volume-variable structure effectively reduces the requirement on the deformation capacity of the spacer due to the liquid crystal margin, which is favorable for improving the surface strength of the display panel. The display panel can be used in a display device.

A geometrically true and perfectly flat display screen includes a first frame, a backlight module and a first bolster. The backlight module is received in the first frame and includes a reflector plate at a lower portion of the backlight module. The first bolster is directly attached to the reflector plate.