The present invention is an apparatus and method for cutting individual label strips from a roll of label web utilizing a cutter assembly. A label cutter comprises a cutter assembly for continuously and independently controlling the rotational speeds of a rotating cutter shaft, a stationary shaft, and a label feed roller is provided. The length of the label strip is controlled by the distinct speed of rotation of a stationary knife, the stationary knife is rotatably coupled to the stationary shaft. At least one cutter blade is operatively associated to the rotating cutter shaft for cutting the label web. The stationary knife rotates with a to speed of rotation different from the speed of rotation of the cutter blade to produce longer or shorter label length strips. The frequency at which the cutter blade meets the stationary knife is inversely related to the length of the label strip that is produced during cut off.

An apparatus for manufacturing a glass laminated substrate includes a chamber, a cutting apparatus configured to cut the glass laminated substrate within the chamber, and a surface processing apparatus configured to process a surface of the glass laminated substrate that is cut. The cutting apparatus and the surface processing apparatus of the apparatus for manufacturing a glass laminated substrate can be used to manufacture in-line the glass laminated substrate within the chamber.

An apparatus for manufacturing a display device and a method for manufacturing a display device includes a stage; a first guide unit positioned on one side of the stage in a first direction and extending in a second direction crossing the first direction; and a first peeling unit disposed on the first guide unit, wherein the first peeling unit includes a first moving part configured to move along the first guide unit, a first rotating part coupled to the other side of the first moving part in the first direction and configured to rotate about an axis extending in the first direction, and a first gripping part coupled to the other side of the first rotating part in the first direction and disposed to overlap the stage.

A holding fixture includes a first blade support assembly and a second blade support assembly. The second blade support assembly is spaced at a distance from the first blade support assembly and includes a base plate removably mounted to a milling machine, an adjustable conic support connectable to the base plate via a spacer block, and a blade adjustment assembly movable to control a pressure applied by the blade adjustment assembly.

A method for manufacturing a display device includes a stage; a first guide unit positioned on one side of the stage in a first direction and extending in a second direction crossing the first direction; and a first peeling unit disposed on the first guide unit, wherein the first peeling unit includes a first moving part configured to move along the first guide unit, a first rotating part coupled to the other side of the first moving part in the first direction and configured to rotate about an axis extending in the first direction, and a first gripping part coupled to the other side of the first rotating part in the first direction and disposed to overlap the stage.

A method of manufacturing a window includes: preparing a glass substrate laminate which includes preparing a base substrate, alternately disposing glass substrates and adhesive layers on the base substrate, and disposing a cover substrate on the glass substrates and the adhesive layers alternately disposed; and cutting the glass substrate laminate, where the adhesive layers include a potassium nitrate (KNO.sub.3) particle and an adhesive resin. This method makes it possible to effectively manufacture an ultra-thin glass substrate used for a window.

A method includes cutting a glass laminate having a glass sheet laminated to a non glass substrate along a cutting path to form a glass laminate segment. Prior to cutting, a relief channel is formed in the glass laminate and comprises a first segment aligned with a final segment of the cutting path and a second segment extending away from the final segment of the cutting path. Another method includes forming a cutting channel in a glass laminate to define first and second regions of the glass laminate coupled by a web portion with a thickness of at least about 10% of a glass laminate thickness. The cutting channel is expanded to form an expanded cutting channel and a reduced web portion with a thickness of at least about 0.1% of the glass laminate thickness. The reduced web portion is severed to form a glass laminate segment.

A holding fixture includes a first blade support assembly and a second blade support assembly. The second blade support assembly is spaced at a distance from the first blade support assembly and includes a base plate removably mounted to a milling machine, an adjustable conic support connectable to the base plate via a spacer block, and a blade adjustment assembly movable to control a pressure applied by the blade adjustment assembly.

Disclosed is a method of manufacturing a wearable article assembled by a front belt, a back belt, and a central chassis, the central chassis having a front waist region and a back waist region separated from each other by a crotch region, wherein at least one of the front belt and the back belt is formed by an elastic belt, the methodmay comprise making the elastic belt and joining to the central chassis by the steps of: 1) advancing a first layer of continuous sheet having a first surface and an opposing second surface in a machine direction and defining a width in a cross machine direction; 2) advancing a second layer of continuous sheet having a first surface and an opposing second surface in the machine direction and having a smaller width than the first layer of continuous sheet; 3) advancing a first group of elastic bodies in the machine direction in a stretched state; 4) joining the first group of elastic bodies between the first surface of the first layer and the first surface of the second layer of continuous sheets to form a primary elastic belt precursor; 5) advancing a second group of elastic bodies in the machine direction in a stretched state; 6) joining the second group of elastic bodies to the first surface of the first layer of continuous sheet of the primary elastic belt precursor; 7) joining the central chassis to the second surface of the second layer of continuous sheet; and 8) folding the first layer of continuous sheet to form a first layer fold over of continuous sheet, such that at least one of the second group of elastic bodies is directly joined between the first surface of the first layer of continuous sheet and the first surface of the first layer fold over of continuous sheet.

A method of manufacturing a wearable article is disclosed. The method includes advancing a first layer of continuous sheet and a second layer of discrete continuous sheet having a smaller width than the first layer of continuous sheet; intermittently joining a first group of elastic bodies between the first layer of continuous sheet and the second layer of discrete continuous sheet; joining a second group of elastic bodies to the first layer of continuous sheets outward of the second layer of discrete continuous sheet; joining a center chassis with the first layer of continuous sheet and overlapping the first group of elastic bodies not joined to the first layer of continuous sheet; folding the first layer of continuous sheet to form a first layer fold over, wherein the first layer fold over overlaps the second group of elastic bodies, the center chassis, and the second layer of discrete continuous sheet.