A method of manufacturing a stretched display panel includes: cutting the TFT substrate to a desired size; cutting the color filter substrate; forming an open-circuit line for open-circuiting a portion defined between a horizontal pixel line that is located at an end of the TFT substrate and another horizontal pixel line adjacent thereto in order to prevent electrical noise due to the horizontal pixel lines being introduced into the end of the TFT substrate exposed from the pixel exposure portion; and forming a reinforcement seal for covering the pixel exposure portion using a reinforcement material in order to prevent occurrence of short circuit due to introduction of foreign matter into a gap defined between the horizontal pixel line and the other horizontal pixel line and at the same time to increase rigidity of the pixel exposure portion.

A substrate processing apparatus for forming a coating film on a peripheral edge portion including a peripheral edge of a front surface and a side surface of a substrate, includes: a substrate holder for rotatably holding the substrate; a first chemical liquid supplier for supplying a first chemical liquid onto the peripheral edge including a rear surface of the substrate; a partial removing part for removing the first chemical liquid adhering to at least a portion of the front and side surfaces; a second chemical liquid supplier for supplying a second chemical liquid for forming the coating film onto the front and side surfaces; a first chemical liquid removing part for removing the first chemical liquid remaining on the substrate to which the second chemical liquid adheres; and a controller for controlling the parts described above.

Provided are methods and systems for applying materials at interface areas formed by fasteners and parts. Specifically, a material is delivered to an interface area such that at least a portion of a fastener remains free from this material. The interface area may be sealed such that the material is contained within that area. As such, a controlled amount of the material is dispensed in a precise location. An applicator used for this process may include a housing and inner guide slidably disposed within this housing. The material may be delivered through an annular flow channel between the housing and inner guide. The inner guide may be sealed against and, in some embodiments, centered with respect to the fastener. The housing may be sealed with respect to the part and, in some embodiments, may be rotated with respect to the part to redistribute the material at the interface area.

An adhesive and release liner application system and method. A bottom table is slidable with respect to a frame and a middle table is slidable with respect to the bottom table. An elevator drive subsystem between a top table and the middle table is configured to adjust the elevation of the top table relative to the middle table. An adhesive head, connected to an adhesive supply subsystem, a release liner applicator, a release liner cutter, and a staple gun are mounted to the top table for applying the adhesive to a surface of a structural member positioned adjacent the top table, for applying a release liner over the adhesive on the surface, for inserting at least one staple through the release liner and into the surface, and for cutting the release liner.

A liquid film cartridge includes: a nozzle section 10 which ejects a foamable solution 100 and generates a liquid film in a space; and a liquid leading section 20 which leads the foamable solution 100 to the nozzle section 10, in which when an outermost portion of a liquid ejecting port 11 of the nozzle section 10 and an inner wall 21 of the liquid leading section 20 are disposed with a gap therebetween so as to satisfy a condition of a predetermined separation relationship, a distance from the inner wall 21 generating air bubbles 103 to the liquid ejecting port 11 in the liquid leading section 20 corresponding to a flow path immediately before the foamable solution 100 reaches the nozzle section 10 is increased and the amount of the air bubbles 103 entering from the liquid leading section 20 into the nozzle section 10 can be reduced.

An end-face coating apparatus for applying a fluid to an end face of a glass substrate includes a workpiece holder and a fluid dispenser. The workpiece holder has a holding surface for holding a glass substrate in a horizontal position such that an end face of the glass substrate projects from the workpiece holder. The fluid dispenser extends in a vertical direction orthogonal to the main faces of the glass substrate and has a nozzle. A dispensing opening for dispensing a fluid is formed on the outer circumferential surface of the nozzle. The dispensing opening has a size equal to or smaller than the width of the end face as measured in the thickness direction of the glass substrate. The fluid dispenser is moved relative to the glass substrate by a Z-axis drive mechanism, a -axis drive mechanism, a Y-axis drive mechanism, and an X-axis drive mechanism.

Systems apply a material (e.g., adhesive) to an article (e.g., a component in an article of footwear) with a multiple-nozzle tool. A first nozzle of the multiple-nozzle tool is effective to provide an edge application of the material that is consistent in application of the material. A second nozzle of the multiple-nozzle tool is effective to provide a greater material coverage application than the first nozzle. The second nozzle may be implemented to apply the material at an interior area from the edge at which the first nozzle applies the material, in an exemplary aspect.

A substrate processing apparatus includes a holder, a nozzle arm and a position adjusting device. The holder is configured to hold a substrate. The nozzle arm has a nozzle configured to supply a processing liquid to a peripheral portion of the substrate. The position adjusting device is provided at the nozzle arm and is configured to adjust a position of the substrate to a given position on the holder.

According to one embodiment, an imprint template manufacturing apparatus includes: a supply head that supplies a liquid-repellent material in liquid form to a template having a convex portion where a concavo-convex pattern is formed on a stage; a moving mechanism that moves the stage and the supply head relatively in a direction along the stage; a controller that controls the supply head and the moving mechanism such that the supply head applies the liquid-repellent material to at least a side surface of the convex portion so as to avoid the concavo-convex pattern; and a cleaning unit that supplies a liquid to the template coated with the liquid-repellent material. The liquid-repellent material contains a liquid-repellent component and a non-liquid-repellent component that react with the surface of the template, and a volatile solvent that dissolves the liquid-repellent component. The liquid is a fluorine-based volatile solvent that dissolves the non-liquid-repellent component.

A bookbinding machine calculates a rotational speed coefficient, which represents the percent change of a rotational speed of a pump 6 relative to the reference rotational speed of the pump, depending on a thickness of a book block P to be bound and a conveying speed of a clamper by use of a first function defining a relationship between the thickness of the book block and the rotational speed coefficient and a second function defining a relationship between the rotational speed coefficient and the conveying speed of the clamper, calculates the set value of the rotational speed of the pump based on the rotational speed coefficients and the reference rotational speed, and sets the rotational speed of the pump according to the set value of the rotational speed.