According to various embodiments, the temperature control roller may comprise: a cylindrical roller shell, which has a multiplicity of gas outlet openings; a temperature control device, which is configured to supply and/or extract thermal energy to or from the cylindrical roller shell; multiple gas lines made to extend along the axis of rotation; a gas distributing structure, which couples the multiple gas lines and the multiplicity of gas outlet openings to one another in a gas-conducting manner, the gas distributing structure having a lower structure density than the multiplicity of gas outlet openings.

A sheet affixing apparatus includes a drawing unit for drawing a sheet from a sheet roll and a sheet cutter for cutting the sheet drawn from the sheet roll by the drawing unit. The sheet cutter includes a sheet support for supporting from below the sheet drawn from the sheet roll by the drawing unit, a cutting knife for cutting the sheet supported by the sheet support, along the sheet support, and a sheet presser for pressing the sheet against the sheet support forwardly of the cutting knife in a direction along which the cutting knife moves in cutting the sheet, when the sheet is cut.

A sheet affixing apparatus includes a drawing unit for drawing a sheet from a sheet roll and a sheet cutter for cutting the sheet drawn from the sheet roll by the drawing unit. The sheet cutter includes a sheet support for supporting from below the sheet drawn from the sheet roll by the drawing unit, a cutting knife for cutting the sheet supported by the sheet support, along the sheet support, and a sheet presser for pressing the sheet against the sheet support forwardly of the cutting knife in a direction along which the cutting knife moves in cutting the sheet, when the sheet is cut.

Provided is a glass film manufacturing method in which manufacture-related processing is performed on a glass film while the glass film (G) is conveyed, the glass film manufacturing method comprising the step of conveying the glass film (G) on a suction roller (46), wherein the suction roller (46a) is configured to suck only a center portion of the glass film in a width direction of the glass film (G).

At the time of performing manufacture-related processing on a glass film (G1) with a manufacture-related-processing unit (9) while conveying the glass film (G1) with a belt conveyor (22d), the belt conveyor (22d) is configured to be capable of attracting the glass film (G1) to the belt (23d) on an upstream side in a conveyance direction of the glass film (G1) with respect to the manufacture-related-processing unit (9), and the belt conveyor (22d) is configured to be capable of changing attraction forces (P11 and P12) with respect to the glass film (G1) in a conveyance direction (X) of the glass film (G1).

At the time of performing manufacture-related processing on a glass film (G1) with a manufacture-related-processing unit (9) while conveying the glass film (G1) with a belt conveyor (22d), the belt conveyor (22d) is configured to be capable of attracting the glass film (G1) to the belt (23d) on an upstream side in a conveyance direction of the glass film (G1) with respect to the manufacture-related-processing unit (9), and the belt conveyor (22d) is configured to be capable of changing attraction forces (P11 and P12) with respect to the glass film (G1) in a conveyance direction (X) of the glass film (G1).

A carrying device includes: a carrying section having a receiving surface to be in contact with a first sheet material that is continuous in a carrying direction, wherein one edge of the first sheet material is wave-shaped, the carrying section defining an inclined slit portion, wherein the inclined slit portion defines an opening on the receiving surface, wherein the inclined slit portion extends in an inclined direction so as to be displaced from a proximal side toward a distal side of a protruding portion while extending downstream in the direction of carrying the first sheet material, and wherein the inclined slit portion sucks the protruding portion along the wave-shaped edge; and a box defining a suction space that keeps the inclined slit portion under a negative pressure so that the protruding portion is pulled into the inclined slit portion by suction.

A carrying device includes: a carrying section having a receiving surface to be in contact with a first sheet material that is continuous in a carrying direction, wherein one edge of the first sheet material is wave-shaped, the carrying section defining an inclined slit portion, wherein the inclined slit portion defines an opening on the receiving surface, wherein the inclined slit portion extends in an inclined direction so as to be displaced from a proximal side toward a distal side of a protruding portion while extending downstream in the direction of carrying the first sheet material, and wherein the inclined slit portion sucks the protruding portion along the wave-shaped edge; and a box defining a suction space that keeps the inclined slit portion under a negative pressure so that the protruding portion is pulled into the inclined slit portion by suction.

A sheet conveying device includes: a holding mechanism configured to hold suction members; and a driving device including a rotary shaft which is rotatable about a second axis parallel to the first axis and a connecting mechanism configured to connect the rotary shaft and suction members to each other; and a support mechanism configured to support the holding mechanism and the drive device. The connecting mechanism is connected to the suction members in a state where the suction members are movable in a radial direction of the circle about the first axis. The support mechanism supports the holding mechanism and the drive device such that the holding mechanism and the drive device are relatively movable from each other in a direction orthogonal to the first axis.

The present disclosure relates to a method performed by an alignment system for aligning tethers of a drop stitch fabric prior to feeding the drop stitch fabric to a drop stitch fabric processing machine. The alignment system feeds a drop stitch fabric having a first layer and a second layer tethered by drop stitch tethers, wherein the first layer is moving with a first velocity and the second layer is moving with a second velocity. The disclosure also relates to an alignment system in accordance with to the foregoing.