A food dispensing module for a delaminating food dispensing system includes an outer housing; and a delaminating housing. The delaminating housing has a first portion being located within said outer housing and a second portion located outside said outer housing. The delaminating housing includes delaminating nips, a first film take-up roller, a second film take-up roller, an output opening, and a trap void. The output opening is located in the second portion of the delaminating housing.

There is provided a component supply device for supplying a component to a component mounter, including; a transporter that transports a carrier tape in which the component is stored and of which an upper surface is sealed with a cover tape, along a transport path; a peeler that is disposed above the transport path and peels off the cover tape from the carrier tape; and an ejector that ejects a gas for capturing the cover tape by the peeler.

A method of removing backing film from a sheet element is provided. The sheet element has a preimpregnated layer, and sheets of backing film are adhered to the top and bottom of the preimpregnated layer. The backing film has a different coefficient of thermal expansion than the preimpregnated layer, and a plane of the sheet element is defined by the peripheral edge. A shear strain is created between the backing films and the preimpregnated layer by cooling the sheet element. A fluid stream is directed at a portion of the peripheral edge, the fluid stream being directed in the plane of the sheet element. The fluid stream causes the backing films to separate from the top and bottom of the preimpregnated layer. A differential pressure is simultaneously applied to the backing films relative to the fluid stream to cause the backing films to be removed from the preimpregnated layer.

A method of peeling off the protective film includes: providing a panel lower sheet, where a protective film is provided on one surface of the plane lower sheet and the protective film has a bending line extending in a first direction parallel to opposing sides thereof; gripping a portion of the protective film; moving the gripped portion of the protective film in a second direction which is a thickness direction thereof; and moving the panel lower sheet in a third direction perpendicular to the bending line.

Disclosed is a turntable cloth peeling jig including: a cylindrical winding cylinder including a slit formed on an outer periphery of the cylindrical winding cylinder and extending in an axial direction thereof; a cloth clamping member disposed inside the winding cylinder and configured to clamp an outer peripheral edge of a cloth inserted into the slit; an extension bar attached to one end portion of the winding cylinder so as to extend coaxially therewith; an engaging portion provided at a tip end portion of the extension bar and engaged with a rotation jig configured to rotate the winding cylinder; and a handle provided in the engaging portion and configured to support the winding cylinder when rotating the rotating jig.

The present invention provides a method for enhancing the specific uptake of a neurotoxin polypeptide into cells, the method comprising: incubating cells susceptible to neurotoxin intoxication with a neurotoxin polypeptide for a time and under conditions which allow for the neurotoxin polypeptide to exert its biological activity, the incubation comprising at least one of the following steps: (i) K.sup.+-mediated depolarization of the cells, (ii) a reduced neurotoxin polypeptide exposition time and/or (iii) agitation of the cells during neurotoxin polypeptide exposition, thereby enhancing the specific uptake of the neurotoxin polypeptide into said cells. In addition, the invention pertains to a method for directly determining the biological activity of a neurotoxin polypeptide in cells, comprising: a) incubating cells susceptible to neurotoxin intoxication with a neurotoxin polypeptide for a time and under conditions which allow for the neurotoxin polypeptide to exert its biological activity, the incubation comprising at least one of the following steps: (i) K.sup.+-mediated depolarization of the cells, (ii) a reduced neurotoxin polypeptide exposition time and/or (iii) agitation of the cells during neurotoxin polypeptide exposition; b) fixing the cells and, optionally, permeabilizing the cells with a detergent; c) contacting the cells with at least a first capture antibody specifically binding to the non-cleaved and neurotoxin-cleaved substrate and with at least a second capture antibody specifically binding to the cleavage site of the neurotoxin-cleaved substrate, under conditions which allow for binding of said capture antibodies to said substrates; d) contacting the cells with at least a first detection antibody specifically binding to the first capture antibody, under conditions which allow for binding of said first detection antibody to said first capture antibody, thus forming first detection complexes and with at least a second detection antibody specifically binding to the second capture antibody, under conditions which allow for binding of said second detection antibody to said second capture antibody, thus forming second detection complexes; e) determining the amount of the first and second detection complexes of step d); and f) calculating the amount of substrate cleaved by said neurotoxin polypeptide in said cells by means of the second detection complexes, thereby determining the biological activity of said neurotoxin polypeptide in said cells.

A film-removing device, includes: a load-bearing platform including a load-bearing surface; a film-removing roller provided at one side close to the load-bearing surface of the load-bearing platform, a central axis of the film-removing roller being parallel to the load-bearing surface of the load-bearing platform; a rotation driver connected to the film-removing roller and configured to drive the film-removing roller to rotate around a central line parallel to the central axis of the film-removing roller, such that an edge of the film-removing roller close to the load-bearing surface moves within the load-bearing surface of the load-bearing platform.

Disclosed is an apparatus for manufacturing a display module. An apparatus for manufacturing a display module according to an exemplary embodiment of the present invention, which attaches a polarizing plate, from which a release film is peeled, onto a display panel, includes: a separator configured to peel a release film from a polarizing plate, and formed with a flow path, through which foreign substances dropped from the release film when the release film is peeled are dischargeable; and a suction unit coupled to the separator to suck the foreign substances.

A display laminate which includes a front electrode layer, a display material layer and a protective film layer, wherein the protective film layer and the display material layer are narrower than the front electrode layer and wherein the protective film layer and the display material layer have a common edge with the front electrode layer on a first side and a common edge with each other but not with the front electrode layer on an opposite side.

A label web and method utilize a substrate, first and second longitudinally spaced label arrays each including two or more double-sided adhesive labels removably attached to the substrate, and a peelable protective covering web extending generally coextensive with the substrate. The label arrays and the peelable protective web are configured such that the peelable protective web is selectively removable to expose the first label array while remaining removably attached to the second label array, with both the first and second label arrays remaining removably attached to the substrate, to thereby facilitate removal of all labels in the first label array as a group while the peelable protective covering web remains in place over the second label array.