The present disclosure relates to segmented transfer tapes useful in the transfer of only a portion of the segments of the transfer tapes and methods of making thereof. The segmented transfer tapes include a removable template layer having a structured surface; a transfer layer comprising a backfill layer, wherein the backfill layer has a structured first major surface, and an adhesive layer; at least one transferable segment formed in the transfer layer; at least one non-transferable segment formed in the transfer layer, the at least one non-transferable segment includes an adhesive surface, wherein a passivating layer is disposed on at least a portion of the adhesive surface of the at least one non-transferrable segment; and at least one kerf extending from the first major surface of the adhesive layer and into at least a portion of the removable template layer. The present disclosure also provides micro-optical assemblies and methods of making micro-optical assemblies from the segmented transfer tapes.

A laminating apparatus may include a first conveyor unit having a conveyance speed; a laminating unit disposed downstream of the first conveyor unit, wherein the laminating unit laminates a surface of a glass sheet with a film in a single stroke with the conveyance speed; and at least one first imaging unit disposed upstream of the laminating unit, the at least one first imaging unit correcting a position of the glass sheet entering the laminating unit.

The application discloses a display screen. The display screen includes a screen body including a cover glass and a substrate glass. The cover glass and the substrate glass each has a bonding surface and an outer surface opposite to the bonding surface. The outer surfaces of the cover glass and the substrate glass are provided with a cracking prevention layer at least in a peripheral region of a predetermined slotted region of the screen body. In a screen body cutting method disclosed in the application, cracking prevention layers are formed on the outer surfaces of both the cover glass and the substrate glass, so as to reduce the edge cracking or breaking of the screen body during the slotting and to reduce crack generated in the cover glass and the substrate glass, thereby improving overall strength of the screen body and increasing the yield of the product.

Disclosed herein is a method of manufacturing a natural cork film, which includes forming a thin cork layer by slicing a prepared natural cork material, forming a fiber layer by attaching a fiber sheet to one surface of the cork layer formed in the forming a thin cork layer, pre-treating a lamination of the cork layer and the fiber layer formed in the forming a fiber layer, for preventing discoloration of the cork layer, and forming a resin layer by attaching a resin sheet to the fiber layer passing through the pre-treating a lamination of the cork layer and the fiber layer. Accordingly, it is possible to prevent the manufactured cork film from naturally discoloring due to light and to significantly reduce a phenomenon such as brittleness or wrinkling caused when the cork layer is decolorized alone.

Disclosed is a panel reversing apparatus which reverses a panel, the panel reversing apparatus including: a panel support unit which supports the panel; and a rotating unit which rotates the panel support unit so as to reverse a direction, in which one surface of the panel supported by the panel support unit faces, and a direction, in which the other surface of the panel faces, in which the panel support unit includes a single surface contact unit which is in contact with only one surface between the one surface and the other surface of the panel.

A processing method of a bonded wafer includes generating coordinates of an outermost circumference of a joining layer, forming a plurality of modified layers by positioning focal points of laser beams inside a first wafer, from a back surface of the first wafer, holding a second wafer side on a chuck table and grinding the back surface of the first wafer to thin the first wafer. The plurality of focal points of the laser beams are set in a form of descending stairs to reach the lowermost focal point from the uppermost focal point so as to gradually get closer to the joining layer from an inner side toward an outer side in a radial direction of the first wafer. A crack that extends from the modified layer formed by the lowermost focal point reaches the coordinates of the outermost circumference of the joining layer.

The present disclosure relates generally to cladding for covering a building surface. The present disclosure relates more particularly to a method of manufacturing a building surface panel. The method includes providing a foam piece having a 30 day/23? C. residual shrinkage of no more than 0.2%. The foam piece having the 30 day/23? C. residual shrinkage of no more than 0.2% is attached to a rear side of an outer shell so as to form the building surface panel. In some embodiments, a front side of the outer shell forms a visible surface of the building surface panel. The foam piece can be provided, e.g., by aging the foam piece for a time and at a temperature such that the 30 day/23? C. residual shrinkage is no more than 0.2%. The foam piece to be aged can, in some embodiments, be cut from a body of foam.

A method for manufacturing a loofah dish sponge includes cutting a first cover layer and a second cover layer from the dried-out fibrous loofah skeleton, positioning a slightly smaller sized inner layer in between the first and second cover layers with their respective external sides facing outward and away from the internal layer, deforming and sewing the peripheral edges of the first and second cover layers together, thereby forming an internal volume in between thereof allowing the inner layer placed inside to freely float in this space. The sponge is made without using any synthetic materials. It features superior durability, improved ergonomics, impedes mold growth after use and is fully compostable.

A laminated vehicle windshield for head-up display, includes a first glazing, forming an exterior glazing, a lamination interlayer made of polymeric material, the lamination interlayer having a cross section which decreases in wedge shape from the top toward the bottom of the laminated glazing, a second glazing, forming an interior glazing, the second main face and the third main face being the internal faces of the laminated glazing, a set of diodes, each diode emitting in the direction of the interior glass. For each of the diodes, the lamination interlayer includes a blind aperture housing the diode.

A fabric production method and a fabric, the production method includes the following steps: (1) selecting an impermeable fabric, an intermediate absorbent layer and a polyester brocade microfiber fabric; (2) sequentially performing alkali fiber-splitting treatment and degreasing treatment on the polyester brocade microfiber fabric; (3) cleaning the treated polyester brocade microfiber fabric ; (4) arranging the cleaned polyester brocade microfiber fabric as a surface material and the impermeable fabric as a base material, disposing the intermediate absorbent layer therebetween, and employing an ultrasonic laminating machine to laminate the three layers of materials into one; (5) slitting and crosscutting; (6) folding two ends of a strip of the composite material along a length direction thereof, and arranging a buckle, thus obtaining a semi-finished product; and (7) cleaning the obtained semi-finished product. The fabric has features such as powerful cleaning ability and good adsorption.