A foldable display device according to the present disclosure includes a display panel including a display area and a non-display area, a touch panel disposed on the display panel and including a bridge electrode, a plurality of insulating layers, a first touch electrode, and a second touch electrode. The device includes a plurality of crack stoppers disposed in the non-display area of the touch panel and configured by patterning the insulating layers and an adhesive layer. The adhesive layer fills a space between the plurality of crack stoppers from which the insulating layers are removed, and is disposed between the display panel and the touch panel. Accordingly, crack occurrence may be suppressed even if a folding/unfolding operation of the foldable display device is repeated. Thus, crack occurrence in the foldable display device may be improved and at the same time, folding characteristics may increase.

The present invention is an assembly layer for a flexible device. The assembly layer is derived from precursors that include about 0 to about 50 wt % C.sub.1-C.sub.9 alkyl(meth)acrylate, about 40 to about 99 wt % C.sub.10-C.sub.24 (meth)acrylate, about 0 to about 30 wt % hydroxyl(meth)acrylate, about 0 to about 10 wt % of a non-hydroxy functional polar monomer, and about 0 to about 5 wt % crosslinker.

A display device includes a cover window including a curved portion, and a panel member laminated on the cover window. A method of manufacturing a display device includes mounting a cover window including a curved portion on a first jig including a curved portion, mounting a panel member on a second jig that conforms to a surface of the first jig, and laminating the cover window to the panel member by moving a first one of the first jig or the second jig to a first other one of the first jig or the second jig. An apparatus for manufacturing a display device includes a first jig including a mount surface that is partially curved to conform to a surface of a cover window, a second jig including a surface conforming to the mount surface and configured to contact a panel member, and a driving unit.

A flexible display device includes a flexible display panel bendable along a bending axis. A support backplate is disposed on a side of the flexible display panel and located on an outer side of the flexible display panel when bending. The support backplate includes a support area and a plurality of extension areas defined on opposite sides of the bending axis and adjoining two sides of the support area. When the flexible display device is in an expanded state, a difference value between a length of the support backplate and a length of the flexible display panel in a direction perpendicular to the bending axis is greater than or equal to a first threshold. The flexible display device can reduce the risk of peeling of components in a bent state and can ensure a product lifespan.

Automotive glazing, with electrically controlled light transmittance, has been available for a number of years. Growth has been steady as the public recognizes the added utility provided. While a number of means of implementation are in use, all require a set of electrodes spanning opposite faces of the switchable portion of the glazing. As automotive electronic content has proliferated and the glazed area of the vehicle has increased, it is becoming more and more of a problem finding a suitable location for the controls, for the switchable glazing as well as for other functions. By structuring the electrodes, touch sensitive regions can be formed on the laminate and utilized for control.

A display device that includes: a glass substrate comprising a refractive index (n.sub.substrate); a display device structure coupled to the substrate to collectively define a viewing area; and a black mask structure surrounding the display device structure that is coupled to the substrate and comprises a black ink layer and at least one glossy layer between the black ink layer and the glass substrate. The viewing area is characterized by (a) a reflectance from 0.5% to 2.5% as measured at 8 degrees from normal in the visible spectrum, (b) a brightness in the CIE colorimetry system such that 5<L*<17 for the specular component included (SCI), and (c) a brightness in the CIE colorimetry system such that 0<L*<3 for the specular component excluded (SCE). Further, the at least one glossy layer comprises a refractive index (n.sub.glossy) such that |n.sub.glossy−n.sub.substrate|>0.1.

A method for dissipating the kinetic energy during an impact on a glass trim element into a motor vehicle's interior that includes fixation of the glass trim element to a support to provide an assembly that is integrated to motor vehicle's interior body. The support further includes a material with a permanent deformation or not to dissipate the kinetic energy during an impact.

Disclosed are a film pasting method and apparatus. The method includes: providing a protective film sheet, an electronic device and a push mechanism; aligning the protective film sheet with a screen; moving the push mechanism from a first side to a second side so as to sequentially paste the protective film sheet on the screen correspondingly. During a process of film pasting, an area where the protective film sheet is pasted with the screen defines a contact boundary proximate to the second side, the protective film sheet enters an exhaust state when the contact boundary moves, a contact angle is formed between a connection face which is formed by the contact boundary and the second side, and the screen, the contact angle gradually decreases along a moving direction of the contact boundary.

An electronic device is provided. The electronic device includes a back frame, a panel disposed on the back frame, a protective substrate disposed on the panel, and an adhesive element disposed on a portion of the back frame. The back frame and the protective substrate adhere to each other via the adhesive element.

A bonding structure includes a substrate, a first sensing electrode layer, a second sensing electrode layer, an optical film layer, and a protective layer. The substrate has opposite first and second surfaces. A sensing area and a bonding area are defined on the substrate. The first sensing electrode layer is disposed on the first surface. The second sensing electrode layer is disposed on the second surface. The optical film layer covers the first sensing electrode layer and has a first bonding opening located in the bonding area. The protective layer covers the second sensing electrode layer and has a second bonding opening located in the bonding area. The first and second bonding openings respectively expose a part of the first sensing electrode layer and a part of the second sensing electrode layer and are misaligned in a direction perpendicular to the first or second surface.