Provided are a bonding device and a bonding method capable of precisely positioning both workpieces and bonding both workpieces more accurately even when a bonding surface of each workpiece includes a concavo-convex curved surface in which a protruding curved surface and a recessed curved surface are continuous. The bonding device includes an upper suction base 4 that sucks and holds a first workpiece W1 molded in advance into a concavo-convex curved shape, and a lower suction base 6 that sucks and holds a flat second workpiece W2. The lower suction base 6 includes a fixed suction base 16 and a movable suction base 17, and an upper opening surface of the movable suction base 17 is covered with a suction screen 8. The movable suction base 17 can elevate and lower between a workpiece supporting position where the flat second workpiece W2 is sucked and held and a workpiece transfer position where the movable suction base lowers downward from an upper opening surface of the fixed suction base 16. At the workpiece transfer position, the second workpiece W2 is sucked and held along a shape of a concavo-convex curved part 18 of the fixed suction base 16. In a state where the first workpiece W1 and the second workpiece W2 face each other vertically, the second workpiece W2 is pressed against the first workpiece W1 by a bonding roller 7 and bonded thereto.

A device for magnetizing a packaging material for food-containing packages is disclosed. The device can include a feeder for feeding a packaging material through the device, the packaging material having a plurality of portions of magnetisable ink. The device can also include a static bar having at least one magnet for magnetizing the portions of ink applied to the packaging material. The device can also include a magnetizable ink applicator for applying the plurality of portions of magnetizable ink to the packaging material. The packaging material can be a non-creased packaging material. A system for producing a packaging material is also disclosed. A method of magnetizing a packaging material for a food-containing package is further disclosed.

A sheet processing device includes a conveyor, a rotator, a separator, and control circuitry. The conveyor conveys a sheet-shaped medium into a two-ply sheet in which two sheets are overlaid and partially bonded, and includes a drive roller and a driven roller. The rotator winds the two-ply sheet. The separator separates the two sheets of the two-ply sheet. The control circuitry causes the conveyor to convey the two-ply sheet in a winding direction to wind the two-ply sheet around the rotator to generate a space between the two sheets, and causes the separator to insert into the space between the two sheets to separate the two sheets. The drive roller and the rotator are disposed on a same side with respect to a sheet conveyance passage of the two-ply sheet, and the driven roller and the rotator are disposed on opposite sides with respect to the sheet conveyance passage.

The present invention discloses a heat-resistant glue roll structure with discharge through holes, which comprises a shaft sleeved with a high-temperature resistance insulation layer on the surface thereof. Multiple discharge through holes are formed on the high-temperature resistance insulation layer and communicate the outer and inner surface of the high-temperature resistant insulation layer. A heat-resistant soft glue outer layer is also sleeved on the surface of the high-temperature resistant insulation layer. Since the high-temperature resistant insulation layer is provided with the discharge through holes in the present invention, air bubbles generated both between the high-temperature resistant insulation layer and the heat-resistant soft glue outer layer and between the high-temperature resistant insulation layer and the shaft would be squeezed to move towards the discharge through holes and discharged therefrom. No air bubbles would be accumulated in the heat-resistant glue roll structure of the present invention. Therefore, the internal structure thereof is stable in structural connection and the structure has long serving life, high stability and high safety and reliability.

A wound dressing having a thin barrier layer of soft, pliant adhesive material with a flexible cover layer extending along one side of the adhesive layer and a removable release sheet on the opposite side is disclosed. The adhesive material has a center and border surrounding the center such that the adhesive is contoured. A method for making the contoured dressing using a gear pump and a laminating roller having a predetermined softness and firmness is also disclosed.

A glass film transfer apparatus includes a wind-off section that winds off the glass film from a roll around which the glass film is wound, a long interleaf being laminated on the glass film; a glass film transfer section that transfers the glass film which is wound off from the wind-off section and is separated from the interleaf; a take-up section that takes up the glass film transferred by the glass film transfer section in the form of roll, while laminating the long interleaf on the glass film; and an interleaf transfer section that carries out the interleaf separated from the glass film which is wound off from the wind-off section, and carries in the interleaf toward the take-up section. Furthermore, the glass film transfer apparatus includes a take-up adjusting mechanism that adjusts a take-up state of the interleaf and the glass film in the take-up section.

A laminate film manufacturing method is capable of preventing thickness unevenness of a cured layer and preventing wrinkling of the entire laminate film. A laminate film is manufactured by applying a coating solution including an active radiation curable resin to a surface of a first film that is continuously transported in an application part to form a coated film in a lamination part, laminating a second film that is continuously transported on the coated film to sandwich the coated film between the first film and the second film, and in a state in which the coated film is sandwiched between the first film and the second film, winding the first film around a backup roller and irradiating the coated film with infrared rays from an ultraviolet irradiation device while continuously transporting the first film to cure the coated film in a curing part so as to form a cured layer.

A method for making a badge includes laminating a printed substrate with a back side laminate sheet and a front side laminate sheet and disposing a barrier sheet between at least one of the back side laminate sheet and the printed substrate and the front side laminate sheet and the printed substrate. And a side loading pocket section is formed between at least one of the back side laminate sheet and the printed substrate and the front side laminate sheet and the printed substrate.

Methods and apparatus to remove gas and vapor from a panel for a decorative layer are disclosed. An example apparatus includes a first press plate of a hot press to engage a first surface of a panel. The hot press is to apply heat to the panel via the first press plate to cure resin of the panel. A first portion of the first press plate is composed of a permeable material to remove at least one of gas or vapor from the panel to deter the at least one of gas or vapor from exerting a pressure on a decorative layer to be coupled to the panel to deter separation of a portion of the decorative layer from the panel.

Methods and apparatus to form venting channels on a panel for a decorative layer are disclosed. An example method includes contacting an outer surface of a tool to an outer resin layer of a panel. The outer surface of the tool has protrusions. The example method includes moving the outer surface of the tool on the outer resin layer of the panel in a first direction to cause the protrusions of the tool to form first venting channels on the outer resin layer of the panel and coupling a decorative layer to the outer resin layer of the panel via an adhesive layer. The first venting channels are to vent at least one of gas or vapor away from the decorative layer to deter separation of a portion of the decorative layer from the outer resin layer.