In a display device having high reliability, even if being a narrow framing type, and a method for manufacturing thereof, having a display panel, being made up with a first substrate 101 and a second substrate 201, which are adhered with using a seal 301, a main SOC 302 is disposed like a wall, on a peripheral end portion of the first substrate 101 and the second substrate 201, and the seal 301 is disposed inwardly of the main SOC 302. Also, in a method for manufacturing thereof, the main SOC 302 is formed in a region including a cutting plane between the display panel regions neighboring with, and on the cutting plane is made the cutting thereof.

In a display device having high reliability, even if being a narrow framing type, and a method for manufacturing thereof, having a display panel, being made up with a first substrate 101 and a second substrate 201, which are adhered with using a seal 301, a main SOC 302 is disposed like a wall, on a peripheral end portion of the first substrate 101 and the second substrate 201, and the seal 301 is disposed inwardly of the main SOC 302. Also, in a method for manufacturing thereof, the main SOC 302 is formed in a region including a cutting plane between the display panel regions neighboring with, and on the cutting plane is made the cutting thereof.

A spray device is provided. The spray device is capable of using in a production process of a liquid crystal display and disposed in a spray chamber. The spray device includes an upper rack, a connector, an eccentric wheel, and a motor. The eccentric wheel includes a center hole, a plurality of eccentric holes, and a connecting rod. The center hole is fixedly connected to the eccentric wheel. The eccentric holes are disposed on the eccentric wheel. The connecting rod is fixedly mounted on one of the eccentric holes. A rocker is sleeved on the connecting rod to realize a rotatable connection. The motor is configured to drive the eccentric wheel to rotate. The connecting rod is configured to rotate with the eccentric wheel to drive the rocker to realize a reciprocating motion of the upper rack.

A layered optical element includes a substrate layer, an electrode layer disposed on the substrate layer, a liquid crystal (LC) layer comprising LC molecules, and a nanopatterned alignment layer in physical contact with the LC layer and disposed on a surface of either the substrate layer or the electrode layer. The nanopatterned alignment layer includes an arrangement of nanostructures, e.g., a grouping of nanolines. For a subset of the grouping of nanolines, the nanolines are configured to orient the LC molecules along a varying local orientation direction of each of nanoline in the subset. The varying local orientation direction of each nanoline in the subset can vary along a length of each nanoline.

In a display device having high reliability, even if being a narrow framing type, and a method for manufacturing thereof, having a display panel, being made up with a first substrate 101 and a second substrate 201, which are adhered with using a seal 301, a main SOC 302 is disposed like a wall, on a peripheral end portion of the first substrate 101 and the second substrate 201, and the seal 301 is disposed inwardly of the main SOC 302. Also, in a method for manufacturing thereof, the main SOC 302 is formed in a region including a cutting plane between the display panel regions neighboring with, and on the cutting plane is made the cutting thereof.

Disclosed are a method for forming a pattern for liquid crystal orientation of a zenithal bi-stable liquid crystal panel, a liquid crystal orientation substrate including the pattern formed thereby, and a mask substrate used for forming the pattern. The method includes: (a) depositing a silicon-based compound on a silicon substrate, (b) forming a guide pattern on an upper portion of the deposited silicon-based compound layer by using an imprint lithography, (c) discontinuously exposing the silicon substrate by transferring a pattern from the guide pattern onto the silicon-based compound layer by dry etching, (d) forming a pattern in an asymmetrical form on the silicon substrate by wet etching, (e) removing the part of the remaining silicon-based compound layer, and then hydrophobically treating a pattern surface of the silicon substrate; and (f) transferring a pattern in an asymmetrical form onto a glass substrate by disposing the surface-treated silicon substrate to face the glass substrate, and supplying a dielectric therebetween.

In a display device having high reliability, even if being a narrow framing type, and a method for manufacturing thereof, having a display panel, being made up with a first substrate 101 and a second substrate 201, which are adhered with using a seal 301, a main SOC 302 is disposed like a wall, on a peripheral end portion of the first substrate 101 and the second substrate 201, and the seal 301 is disposed inwardly of the main SOC 302. Also, in a method for manufacturing thereof, the main SOC 302 is formed in a region including a cutting plane between the display panel regions neighboring with, and on the cutting plane is made the cutting thereof.

A method for manufacturing a liquid crystal aligning film includes preparing a multilayer structure in which a substrate, a conductive layer, a liquid crystal alignment layer, and a passivation film are sequentially provided, etching one area of the liquid crystal alignment layer by irradiating a pulse laser to the multilayer structure, and exposing one area of the conductive layer by removing the passivation film, wherein the pulse laser is irradiated to the liquid crystal alignment layer from the passivation film. The method is compatible with a continuous process.

A method for fabrication of a nano-scale mold to create a high precision alignment layer for liquid crystals is described. The method comprises forming a nano-scale mold with a negative of a liquid crystal alignment pattern and imprinting a resist material on the mold. The method further comprises performing a set operation on the resist material to cause the resist material to set, the resist material forming a liquid crystal alignment layer. The nano-scale mold is separated from the liquid crystal alignment layer. The method further comprises performing an infiltration operation to cause the liquid crystals to be deposited on the alignment layer, the alignment layer causing the liquid crystals to form the liquid crystal alignment pattern.

In a display device having high reliability, even if being a narrow framing type, and a method for manufacturing thereof, having a display panel, being made up with a first substrate 101 and a second substrate 201, which are adhered with using a seal 301, a main SOC 302 is disposed like a wall, on a peripheral end portion of the first substrate 101 and the second substrate 201, and the seal 301 is disposed inwardly of the main SOC 302. Also, in a method for manufacturing thereof, the main SOC 302 is formed in a region including a cutting plane between the display panel regions neighboring with, and on the cutting plane is made the cutting thereof.