Embodiments of the present application provide an apparatus for carrying a substrate by an off-line vacuum suction and a method for transporting a substrate. The apparatus includes a carrying frame provided with a clamper, a vacuum suction device and a detaching device arranged on the carrying frame, wherein the vacuum suction device is arranged to suck and fix a substrate and is connectable to and detachable from a vacuum pipeline and the detaching device is arranged to detach the vacuum suction device and the vacuum pipeline from each other while keeping the vacuum suction device to continuously suck the substrate to be transported. The apparatus and the method can improve fixing of the substrate and achieve off-line suction to the substrate.

A polymer dispersed liquid crystal (PDLC) film, comprising: at least one first transparent flexible film coated with conductive material; at least one liquid crystal dispersion, allocated between said at least one first transparent flexible film and at least one second transparent flexible film; at least one second transparent flexible film coated with conductive material; where the PDLC comprises a pattern or a signage. Furthermore, the invention comprises a multichannel controller that enables independent control of each segment of the pattern,

An object of the present disclosure is to provide a component crimping device and a component crimping method that make it possible to improve accuracy of attaching a component onto a substrate by preventing the component from being excessively elongated due to rapid thermal expansion when the component is pressed against the substrate. A lower surface side of a substrate-side terminal part of a substrate held by a substrate holding table is supported by a support, a component placed on a placing table is picked up by a crimping head while heating the component, the component is compressed against a compressing table so as to be elongated, and then the component is pressed against the substrate-side terminal part.

An optical alignment device for a plurality of liquid crystal display panels is disclosed, and has a panel carrying stage, a UV lamp, and a plurality of irradiation masks. The panel carrying stage is used for placing the liquid crystal display panels, the UV lamp is used for applying a UV irradiation to the liquid crystal display panels on the panel carrying stage so that liquid crystals in each of the liquid crystal display panels have pretilt angles, and the irradiation masks are disposed between the UV lamp and the liquid crystal display panels for changing an irradiation intensity of the UV irradiation on the crystal display panels.

An alignment system includes: a light emitting device located on one side of an object to be aligned for emitting light towards the object to be aligned; a light receiving device located on the other side of the object to be aligned and at a standard position corresponding to an alignment mark disposed on the object to be aligned, the light receiving device being provided with a plurality of light sensors for sensing light emitting from the light emitting device on an end surface facing the object to be aligned; a processor configured to receive sensing signals transmitted from each of the light sensors and determine whether the object to be aligned is aligned accurately according to whether each of the light sensors sense the light emitted from the light emitting device. This alignment system shortens the processing time and enhances the processing efficiency.

An embodiment of the present invention discloses a polyimide coating method, which includes the following steps: providing a glass substrate and at least one nozzle; applying the nozzle to a polyimide solution onto the glass substrate to form a polyimide film; and moving the glass substrate to have the glass substrate pass through a roller that includes a printing plate so that the roller that includes the printing plate shapes the polyimide film uniformly distributed on the glass substrate to have a surface of the polyimide film formed on the glass substrate uniform and flat. The present invention also provides a polyimide coating device. The polyimide coating method and device of the present invention shorten coating time of polyimide, increase coating efficiency, and reduce coating cost.

The present invention discloses a processing machine of a display apparatus, the processing machine comprises: a metal support plate; a plurality of support structures, which is movably disposed on the support plate, is used for supporting on the non-display region of the glass substrate, wherein the position of which the support structure is disposed on the metal support plate is corresponded to the position of the non-display region in the panel of the glass substrate, in order to make the support structure placed on the non-display region. The present invention also discloses a processing method of a glass substrate. Through the above way, the present invention can avoid the support structure placed on the display region of the glass substrate, effectively preventing the phenomenon of the brightness uneven.

A display panel and a display panel fabrication method are provided. The display panel comprises a display region; and a peripheral circuit region surrounding the display region. The display panel has a display surface facing viewers and covering the display region and the peripheral circuit region. At least one corner of the display panel is provided with a chamfer having a chamfer surface, the chamfer surface is a new side surface which is going to be introduced to the display panel after the chamfer is formed. A chamfer cutting reflective layer is disposed on the display surface of the display panel and along an edge of the chamfer surface. In a direction perpendicular to a chamfer cutting line and towards the at least one corner of the display panel, a thickness of the chamfer cutting reflective layer is reduced.

A terminal capable of detecting rays, an enclosure, and a method for fabricating terminal are provided. The terminal comprises a terminal body and a ray detector in communication with the terminal body. The terminal body comprises a display panel. The ray detector detects rays around the terminal, and transmits the detected signal to the terminal body. The terminal body analyzes the detected signal and transmits the detected signal to the display panel for displaying. In the present disclosure, the detector and the display panel are formed at the same time, and the detector is integrated in a same display panel, so that the process is simplified. The terminal stores and analyzes the data about the collected ionizing radiation dose. As a result, the radiation dose can be read in real time, and an alert can be issued instantaneously to reduce unnecessary damage.

A bonding device for charging a liquid material into a space between plate-shaped members for bonding them together in situ, in which the liquid material may be prevented from exuding from the space between the plate-shaped members. The bonding device includes pair retaining base members for retaining the pair plate-shaped members facing each other, and a retaining base member movement unit for causing movement of the retaining base members towards and away from each other. The bonding device also includes an illumination unit that illuminates curing light to a photo-curable liquid material charged between the pair plate-shaped members held by the pair retaining base members, and a sensor that detects the wetting spreading state of the liquid material charged between the pair plate-shaped members.