A label application system for applying labels to relatively short, round, straight-walled articles is constructed and designed so that labels to be applied to passing articles are delivered to the label application zone on a carrier web in a short feed orientation, with each label being oriented lengthwise across a width of the carrier web. At the time of labeling, the label is held stationary on a flat vacuum surface, and the label is applied by spinning the articles past the vacuum surface. As a result, the system is capable of labeling articles at processing speeds of at least 450 articles per minute or more.

A labeling apparatus comprises a separation member configured to promote detachment of an adhesive label from liner web. Adhesive labels are fed to the separation member such that a surface of the facestock contacts the separation member. The separation member has a surface exhibiting a tack such that the tack force between the facestock and the separation member is greater than the release force between the release liner and the adhesive layer of the labels. The labels become associated with the separation member, and the label is applied to a surface of a substrate by contacting the exposed adhesive layer with a surface of a substrate, which causes the adhesive label to detach from the separation member.

The invention relates to a device (1) for coating workpieces (2), preferably consisting of wood, wood-based materials, plastics material or the like at least in sections, comprising a feed device (10) for feeding a coating material (12), a pressing unit (20) for pressing the coating material (12) against a surface (2a) of a workpiece (2), a conveyor device (4) for bringing about a relative motion between the pressing device (20) and the respective workpiece (2), an energy source (30) for applying energy onto the coating material (12) and/or the workpiece (2), and a control device (50) for controlling at least the energy source (30). The device according to the invention is characterized in that the energy source (30) comprises at least two energy generating sections (30, 30), wherein the control device (50) is equipped to operate at least two energy generating sections (30, 30) at least intermittently with at least one operating parameter, the parameters being different from each other, or the energy generating sections are different from each other.

A card substrate laminating device including a transfer roller configured to heat a portion of a transfer layer of a transfer ribbon and transfer the portion of the transfer layer from a carrier layer of the transfer ribbon to a surface of a card substrate. The transfer roller includes a diameter of less than 0.537 inches and a compliant exterior surface layer or coating. The compliant exterior surface layer or coating can include silicon rubber. The compliant exterior surface layer or coating can be approximately 0.020 inches thick. An internal heating element is configured to heat the transfer roller from an ambient temperature to a laminating temperature, at which laminating operations are performed, within 40 seconds.

A process and system for making a laminated surface covering and the surface covering itself are described. The covering includes several layers bonded to each other. The system performs the process. One example of the process includes passing a first material across a first conveyor, passing a second material across a second conveyor, passing a bonding material across a third conveyor, contacting the first material and the second material to the bonding material, and heating at least one of the first material and the second material. The process also includes introducing the first material, the second material, and the bonding material into a pressure zone such that the bonding material is introduced between a bottom surface of the first material and a top surface of the second material. The process applies pressure to bond the first material and second material together via the bonding material to produce a laminated material.

A cross-laminated timber processing equipment comprises a longitudinal board loading mechanism, a transverse board loading mechanism, an adhesive spraying mechanism, laying cars, presses, a transfer car, and an unloading car. The longitudinal board loading mechanism lays longitudinal boards on a laying car at an assembly station, and the transverse board loading mechanism lays transverse boards on the laying car. The longitudinal boards and the transverse boards are perpendicularly and alternately laid layer by layer. The adhesive spraying mechanism is provided above the assembly station, and sprays an adhesive on the upper surfaces of assembled boards. The transfer car moves back and forth between a conveying station and an idle press through the assembly station, carries the laying cars and the assembled boards, and feeds the laying cars and the assembled boards into the presses for compaction. The unloading car moves back and forth between a press completing compaction and an unloading station, and conveys an idle laying car to the assembly station. Compared with other international similar equipment, this equipment can implement fully-automatic cross-laminated timber processing and production, and has low apparatus cost, high production capacity, high processing efficiency, and a great leading advantage.

A display device, and a method and apparatus for manufacturing the display device, are provided. The display device includes a cover window including a curved portion, and a display panel smaller in at least one of length or width than the cover window and laminated on a flat portion of the cover window.

A method of transferring a micro device and an array of micro devices are disclosed. A carrier substrate carrying a micro device connected to a bonding layer is heated to a temperature below a liquidus temperature of the bonding layer, and a transfer head is heated to a temperature above the liquidus temperature of the bonding layer. Upon contacting the micro device with the transfer head, the heat from the transfer head transfers into the bonding layer to at least partially melt the bonding layer. A voltage applied to the transfer head creates a grip force which picks up the micro device from the carrier substrate.

A card substrate laminating device includes a transfer ribbon and a transfer roller. The transfer ribbon includes a carrier layer and a transfer layer attached to the carrier layer. The transfer roller is configured to heat and transfer a portion of the transfer layer from the carrier layer to a surface of a card substrate. The transfer roller has a circumference that is less than one-half of a length of the card substrate.

The present invention relates to a punch foot (1) for a label punch (2) of a device (3) for labeling individual packs (4), having a punch foot housing (5) which in an extent direction (E) extends from a first housing end (5a) having a first housing opening (6a) to a second housing end (5b) having a second housing opening (6b); having a pressure duct (7) which in the punch foot housing (5) extends from the first housing opening (6a) in the extent direction (E); having a perforated plate (8) which closes the second housing opening (6b) and is connected to the punch foot housing (5), by way of which at least one primary nozzle (9) extends in an orientation direction (V); having a pressure chamber (10) which in the punch foot housing (5) extends from the perforated plate (8) counter to the extent direction (E) and which in a manner orthogonal to the extent direction (E) is on all sides delimited by a punch foot housing wall portion (11); having a connection portion (12) which in the punch foot housing (5) in the extent direction (E) extends between the pressure duct (7) and the pressure chamber (10) and which connects the pressure duct (7) to the pressure chamber (10); and having a control element (13) which is disposed in the pressure chamber (10) and which is movable between two terminal positions (I, II) that effect dissimilar flows through the pressure chamber (10); whereby the at least one primary nozzle (9) connects the pressure chamber (10) to the environment of the punch foot housing (5). In order for the handling to be simplified, the invention proposes that at least one secondary nozzle (14) which connects the pressure chamber (10) to the environment of the punch foot housing (5) extends through the punch foot housing wall portion (11) that delimits the pressure chamber (10) on all sides in a manner orthogonal to the extent direction (E). The invention furthermore relates to a device (3) and to a method for labeling individual packs (4).