In a thin film transistor layer, a first semiconductor film made of an oxide semiconductor, a first gate insulating film made of an inorganic insulating film, a first metal film, a first interlayer insulating film made of an inorganic insulating film, a second metal film, a protective insulating film made of an inorganic insulating film, and a flattening film made of an organic resin material are sequentially layered. The protective insulating film includes a thin film portion provided at a portion where a plurality of first wiring lines formed of the first metal film and a plurality of second wiring lines formed of the second metal film intersect with each other so as to be thinner than a portion of the protective insulating film around the intersecting portion.

A display device includes first and second common electrodes arranged in a first direction and separated from each other, a signal line located between the first and second common electrodes and extending in a second direction crossing the first direction, a pixel electrode electrically connected to the signal line and overlapping the first common electrode, a first metal line located between the first and second common electrodes and extending in the second direction, and a third common electrode arranged and extending in the second direction and separated from the first common electrode, overlapping the signal line. The first metal line is applied a predetermined voltage from plural connection portions, and includes arranged in the second direction a first line portion adjacent and electrically connected to the first common electrode and a second line portion, separated from the first line portion, and adjacent and electrically connected to the third common electrode.

An array substrate includes a thin film transistor including a drain electrode, a first insulation film included in an upper layer than the drain electrode and including a contact hole overlapping the drain electrode, a pixel electrode included in an upper layer than the first insulation film and overlaps the drain electrode at least inside the contact hole and is connected to the drain electrode, a second insulation film included in an upper layer than the pixel electrode and overlaps the pixel electrode inside the contact hole and extends outside the contact hole, a conductive portion included in an upper layer than the second insulation film and overlaps the pixel electrode at least inside the contact hole, and an insulation portion included in an upper layer than the pixel electrode and in a lower layer than the conductive portion and overlaps the pixel electrode inside the contact hole.

A display substrate, a method for manufacturing a display substrate and a display device are provided, and the display substrate includes: a base having a first surface, a second surface and a side surface, the base includes a display area and an epitaxial area; a driving functional layer in the display area and first binding electrodes in the epitaxial area on the first surface, the first binding electrodes are coupled with the driving functional layer; second binding electrodes located on the second surface and coupled with the first binding electrodes through side wirings; a portion of each side wiring is located on the side surface; a blocking wall on the first surface and in the epitaxial area, an orthographic projection of the blocking wall on the base at least passes through spacing regions between every two adjacent first binding electrodes along an arrangement direction of the first binding electrodes.

Disclosed is a display device that is capable of being driven with low power consumption. A first thin-film transistor including a polycrystalline semiconductor layer and a second thin-film transistor including an oxide semiconductor layer are disposed in an active area, thereby reducing power consumption. At least one opening formed in a bending area is formed to have the same depth as any one of contact holes formed in the active area, thereby making it possible to form the opening and the contact holes through the same process and consequently simplifying the process of manufacturing the device. A second source electrode of the second thin-film transistor and a second gate electrode of the second thin-film transistor overlap each other with an upper interlayer insulation film interposed therebetween so as to form a first storage capacitor.

A display panel and a display device are provided in the disclosure. The display panel includes a display region, a fan-out region, and a binding region. The fan-out region and the binding region are stacked on the display region. The binding region is co-planar with the fan-out region. The display region includes a substrate, a functional structure layer, and a first insulation layer stacked sequentially. The fan-out region and the binding region are stacked on the first insulation layer. The functional structure layer includes multiple functional lines. The fan-out region includes multiple electrical connection lines. The binding region includes multiple pin terminals. The multiple electrical connection lines electrically connect the multiple functional lines to the multiple pin terminals in one-to-one correspondence.

A display device is disclosed. In one aspect, the display device includes a substrate including a display area, the display area including a plurality of pixels configured to display an image and a pad area adjacent to the pad area and configured to transfer electrical signals. At least a portion of the pad area is bendable. The display device also includes an insulating layer formed over the substrate and including a bending groove in the pad area. The bending groove includes a sidewall. A plurality of peripheral wires is formed over the insulating layer, and a cutoff portion is connected to the sidewall and disposed between adjacent peripheral wires.

A display device that is suitable for increasing in size is achieved. Three or more source lines are provided for each pixel column. Video signals having the same polarity are input to adjacent source lines during one frame period. Dot inversion driving is used to reduce a flicker, crosstalk, or the like.

The present disclosure discloses a display panel and a display device. The display panel comprises a driving chip and fan-out wires. Fan-out wires in a first fan-out wire group are electrically connected to corresponding output terminals through a second side of an adjacent driving chip; each of the fan-out wires in the first fan-out wire group comprises a first fan-out section and a second fan-out section that are connected and located on different layers. The present disclosure adopts a wire-changing jumper design to prevent signal disorder caused by inconsistent orders of the output terminals and the fan-out wires.

According to one embodiment, a display device includes first semiconductor layers crossing a first scanning line in a non-display area, the first semiconductor layers being a in number, second semiconductor layers crossing a second scanning line in the non-display area, the second semiconductor layers being b in number, and an insulating film disposed between the first and second semiconductor layers and the first and second scanning lines, wherein a and b are integers greater than or equal to 2, and a is different from b, and the first and second semiconductor layers are both entirely covered with the insulating film.