The present invention relates to the technical field of optical film production, and provides a light guide film production device, including a feeding unit, a fusion stirring unit, an extrusion molding unit, a cooling shaping unit, a guide leveling unit, a flattening unit, and a finished product winding unit. The cooling shaping unit is provided with a first water tank to perform heat exchange on an extruded light guide film for heat recovery, so that edge film pressing mechanisms press pressure blocks at the edge film positions using the memory effect of a memory alloy. Circulating water of the first water tank subjected to heat exchange is delivered to a second water tank disposed in the flattening unit, so that a first conveyor belt made of the memory alloy in a third drive device drives a second rolling roller set to rotate to realize secondary utilization of recovered heat. In the present invention, an air delivery mechanism with one airflow pipe to the cooling shaping unit, and the other airflow pipe to the flattening unit is further provided. According to the present invention, the heat of the light guide film production process is used to improve the quality of the light guide film and reduce the energy consumption of the light guide film production process.

A vacuum roller system and a method of operating the vacuum roller system can include a group of vacuum rollers operable to move a sheet of media through a dryer. The vacuum rollers do not require a vacuum to be drawn between the vacuum rollers. Each vacuum roller can include a plenum operable to direct the vacuum to a top portion of the vacuum roller to drive the sheet of media from one roller to the next roller. The plenum can engage vacuum holes in a rotating vacuum roller when the vacuum holes in the vacuum roller are aligned with the plenum.

Suction roller structure for the pneumatic transport of sheets inside an interfolding unit, comprising a suction source, an external roller (3) rotating with respect to the cylinder (1) and provided with longitudinal rows of bores (4) angularly spaced and selectively communicating with said internal cavity (2) during the angular rotation of the roller (3), a distribution of pneumatic valves (5) that are normally closed, inserted between said internal cavity (2) and at least one bore (4), cam means (6) operatively associated with the rotation of the roller (3) and arranged to open one or more of said valves (5) at one or more angular positions taken by the roller (3).

A vacuum roller system and a method of operating the vacuum roller system can include a group of vacuum rollers operable to move a sheet of media through a dryer. The vacuum rollers do not require a vacuum to be drawn between the vacuum rollers. Each vacuum roller can include a plenum operable to direct the vacuum to a top portion of the vacuum roller to drive the sheet of media from one roller to the next roller. The plenum can engage vacuum holes in a rotating vacuum roller when the vacuum holes in the vacuum roller are aligned with the plenum.

Suction roller structure for the pneumatic transport of sheets inside an interfolding unit, comprising a suction source, an external roller (3) rotating with respect to the cylinder (1) and provided with longitudinal rows of bores (4) angularly spaced and selectively communicating with said internal cavity (2) during the angular rotation of the roller (3), a distribution of pneumatic valves (5) that are normally closed, inserted between said internal cavity (2) and at least one bore (4), cam means (6) operatively associated with the rotation of the roller (3) and arranged to open one or more of said valves (5) at one or more angular positions taken by the roller (3).

A machine for processing individual sheets comprises at least one processing station, in particular in inkjet printing station, and a transport system (100) for transporting the individual sheets through the processing station, along a transport direction. The transport system (100) comprises at least one gripper conveyor (150) movable along the transport direction, for gripping one of the individual sheets defining a sheet position in transport direction. The transport system (100) further comprises at least one support conveyor (190) movable along the transport direction for supporting a region of the individual sheet, wherein the support conveyor (190) comprises a vacuum system for supporting the individual sheet on an interacting surface of the support conveyor, the vacuum system comprising a plurality of orifices in the interacting surface. The machine allows for efficient and flexible handling of individual sheets, in particular large format sheets of materials such as corrugated cardboard or other materials that have a certain degree of inherent stability.

A fixing structure for fixing a reel is disclosed. The fixing structure includes a shaft having a first end having a first plurality of protrusions, and a second end having a second plurality of protrusions, wherein each of the first plurality of protrusions and one of its adjacent protrusions have a first recess therebetween, and each of the second plurality of protrusions and one of its adjacent protrusions have a second recess therebetween; and a supporting device, including a first supporting portion supporting the first end, and having a first protruding portion abutting the first recess; and a second supporting portion supporting the second end, and having a second protruding portion abutting the second recess.

A vacuum wheel for transporting a substrate includes a fixed conduit that is connectable to a suction source. A vacuum surface on a circumference of the vacuum wheel includes vacuum openings that are distributed around the circumference, such that rotation of the wheel causes the vacuum openings to successively fluidically connect to the fixed conduit. When suction is applied to the fixed conduit, suction is applied to one or more of the vacuum openings that are currently fluidically connected to the fixed conduit. At least one contact surface on the circumference of the vacuum wheel is adjacent to, and extends outward beyond, the vacuum surface. When suction is applied to the vacuum openings, the substrate is drawn toward the vacuum surface so as to contact the contact surface without contacting the vacuum surface, creating a friction force that enables transport of the substrate when the wheel rotates.

A vacuum wheel for transporting a substrate includes a fixed conduit that is connectable to a suction source. A vacuum surface on a circumference of the vacuum wheel includes vacuum openings that are distributed around the circumference, such that rotation of the wheel causes the vacuum openings to successively fluidically connect to the fixed conduit. When suction is applied to the fixed conduit, suction is applied to one or more of the vacuum openings that are currently fluidically connected to the fixed conduit. At least one contact surface on the circumference of the vacuum wheel is adjacent to, and extends outward beyond, the vacuum surface. When suction is applied to the vacuum openings, the substrate is drawn toward the vacuum surface so as to contact the contact surface without contacting the vacuum surface, creating a friction force that enables transport of the substrate when the wheel rotates.

A workpiece carrier for taking over, transporting and transferring a workpiece formed as a segment of a material web, with a support surface formed on a carrier body for placing the workpiece on, and a suction device for sucking the workpiece onto the support surface, wherein the suction device has at least one movable suction nozzle which projects from the support surface in the rest position and, when subjected to vacuum, is configured to be moved against a force holding the suction nozzle in the rest position into a retracted position in which the suction nozzle does not project beyond the support surface.