A sheet jig of the present invention includes a center placement face on which a center region of a sheet is placed as having a plurality of first air holes to cause the center region of the sheet to be stuck, a peripheral upper face formed outside the center placement face at height being lower than the center placement face as having a plurality of second air holes to cause a peripheral region of the sheet to be stuck, and a slope face formed from the center placement face to the peripheral upper face.

An unwinder of reels of web material wound around winding spindles (A), includes a unwinding station (13) with at least one unwinding member (23) to rotate a reel (B) that is located in the unwinding station and feed the web material toward a delivery path (E). Lifting members (51, 53) are provided to lift a spindle of a first exhausted reel from the unwinding station (13), in a removal position (PR). An insertion member (7; 33) is further provided to insert a second reel into the unwinding station (13). A pressing member (61) is arranged to press the web material coming from the first reel in removal position (PR) against the second reel in the unwinding station (13).

A position control system includes a roller rotatable about a longitudinal axis thereof and a pivotable member having a first member end rotatable about a first pivot axis and a second member end coupled to the roller. The second member end is rotatable about a second pivot axis spaced from the first pivot axis and the first and second pivot axes are movable relative to one another. A motor is adapted to move the roller along the longitudinal axis wherein movement of the roller along the longitudinal axis causes the pivotable member to pivot the roller relative to the longitudinal axis. A control system is responsive to a sensed parameter for controlling the motor. A position control method is also disclosed.

A method for manufacturing an electrode assembly includes a first combination step of combining a first electrode with an upper portion of a first separator to form a first combination, and a second combination step of combining the first combination so that a second electrode faces the first electrode with the first separator therebetween after the second electrode is stacked on a second separator, wherein the first combination step comprises a first electrode cutting process of moving the first electrode in an X-axis direction that is a progress direction to cut the first electrode to a predetermined size, a first electrode transfer process of transferring the cut first electrode, a first first-electrode position detection process of measuring a Y-axis position of the first electrode, a first separator meandering correction process of moving the first separator, a first stacking process of stacking the first electrode on the first separator.

A base material processing apparatus detects the amount of widthwise misregistration of a base material in each detection position (Po, and Pa to Pd) lying on a transport path, and then calculates a difference between a detection value in the reference position (Po) and a detection value in each of the remaining detection positions (Pa to Pd) as a meandering amount. Subsequently, the base material processing apparatus determines coefficients obtained when a variation with time in each meandering amount is applied to a predetermined model function, and thereafter calculates coefficients of the model function predicted as the meandering of the base material in each processing position (P1 to P4), based on the determined coefficients and a positional relationship between the reference position (Po), the remaining detection positions (Pa to Pd) and the processing positions (P1 to P4). This achieves the prediction of the meandering of the base material in the processing positions (P1 to P4) with accuracy without any detector disposed in the processing positions (P1 to P4).

Provided is a method for conveying a sheet member while the sheet member is supported by a roller member, the method including: detecting forces applied, by the sheet member supported by the roller member, to regions at both ends in a width direction of the roller member, respectively, as force components in a plurality of mutually different directions; and adjusting the force components in the regions at both ends in the width direction to a specific balance based on the detection results for the plurality of force components.

A medium processing device includes a drum; plural inner tapes; plural outer tapes; differing regions formed on a starting end portion that is an end at a drum side of at least one of the plural inner tapes or the plural outer tapes, and on a terminal end portion that is an inner reel side or an outer reel side of all of the inner tapes or all of the outer tapes; plural detecting unites that detect the physical property at a tape position of one of the inner tape or the outer tape that has a differing region formed on the starting end portion or the terminal end portion, the tape position being located between the drum and the inner and the outer reels; and a control unit that controls a rotation of the drum based upon the detection results of the plural detecting units.

A sheet transportation device includes a guide roll along which a sheet is to be wound. The sheet includes a plurality of tabs provided intermittently in a longitudinal direction along at least one end in a width direction. The guide roll includes a cylindrical roll main body and a short-diameter portion connected with the roll main body so as to be outer, in the width direction of the sheet, to the roll main body. The roll main body is located closer to a center, in the width direction, of the sheet than a transportation path for the end. A portion of the sheet that is closer to the center than the end is wound along the roll main body. The short-diameter portion is connected with the roll main body via a stepped portion, and has an outer diameter shorter than an outer diameter of the roll main body.

An image recording apparatus includes a pair of conveying rollers configured to convey a sheet in a conveying direction, a recording unit located downstream of the pair of conveying rollers in the conveying direction and configured to record an image on the sheet, a first side-guide located upstream of the pair of conveying rollers in the conveying direction and configured to come into contact with at least one of opposite ends of the sheet in a width direction orthogonal to the conveying direction. The first side-guide is movable in the width direction. The image recording apparatus further includes a second side-guide located downstream of the pair of conveying rollers and upstream of the recoding unit in the conveying direction, the second side-guide being configured to come into contact with at least one of opposite ends of the sheet in the width direction and movable in the width direction.

An image recording apparatus includes a pair of conveying rollers configured to convey a sheet in a conveying direction, a recording unit located downstream of the pair of conveying rollers in the conveying direction and configured to record an image on the sheet, a first side-guide located upstream of the pair of conveying rollers in the conveying direction and configured to come into contact with at least one of opposite ends of the sheet in a width direction orthogonal to the conveying direction. The first side-guide is movable in the width direction. The image recording apparatus further includes a second side-guide located downstream of the pair of conveying rollers and upstream of the recoding unit in the conveying direction, the second side-guide being configured to come into contact with at least one of opposite ends of the sheet in the width direction and movable in the width direction.