A punching system for an electrode base material is disclosed, in which the electrode base material coated with an active material on a surface of a collector is molded or cut in a predetermined shape. The punching system comprises: an unwinder on which the electrode base material in the form of a roll is mounted and around which the electrode base material is unwound; a punching device spaced a predetermined distance from the unwinder, the punching device being configured to mold or cut the electrode base material supplied from the unwinder in a predetermined shape; and a curl correcting device disposed between the unwinder and the punching device to inject or suction air onto a surface of the electrode base material while the electrode base material moves to the punching device so as to planarize the electrode base material. A punching method for an electrode base material is also disclosed.

A solar cell chip arrangement machine includes a feeding mechanism and a slicing mechanism. The feeding mechanism includes a whole battery piece. A push block is connected to the back of the whole battery piece, and a pressing plate is arranged above the front of the whole battery piece. The slicing mechanism is arranged on the pressing plate above the front of the whole battery piece. The slicing mechanism includes a vacuum sucker, a guide plate, a guide plate slide rail, a positioning block, a positioning block slide rail, a cylinder, a fixed plate, and a vacuum generator. The positioning block is arranged on the positioning block slide rail, a pulley is arranged on the positioning block, and the guide plate is provided with a limit slot corresponding to the pulley. The vacuum sucker is arranged on the positioning block, and the vacuum sucker is connected to the vacuum generator.

A trimming device includes: a moving unit including a transport unit that transports a booklet which includes one or more sheets and which is folded in half at a center portion of the booklet, with a folded portion of the booklet at a front, a correction unit that corrects a posture of the booklet in response to a leading end of the booklet transported by the transport unit abutting against the correction unit, the correction unit being capable of advancing to an abutting position on a path of the booklet and retracting from the path, and an upper guide unit that extends at least between the transport unit and the correction unit, the upper guide unit that guides an upper surface of the booklet, the moving unit being movable in a transport direction between (i) a predetermined upstream position and (ii) a downstream position downstream of the upstream position in the transport direction; a lower guide unit that guides a lower surface of the booklet transported by the transport unit; and a cutting unit that cuts a downstream fore edge portion of the booklet in the transport direction, the cutting unit being capable of advancing to the path of the booklet and retracting from the path of the booklet. The upper guide unit is configured such that a gap between the upper guide unit and the lower guide unit widens in accordance with a thickness of the booklet to allow the booklet to pass through the gap.

A punching/perforation machine creates a predefined punching/perforation pattern in a material that is supplied in a direction of travel. The machine comprises a punching/perforation tool that includes an upper tool part which can be moved in a direction of stroke and which is equipped with a plurality of punching dies/perforation needles that are arranged in a predefined grid in a transverse direction and can be moved by a pressure beam that is operatively connected to a drive unit via a control device in order to produce a punching/perforation stroke. The material is supplied between the upper tool part and a lower tool part. The material is placed or clamped in a frame mechanism. The punching/perforation machine includes a frame accommodation/connection device for accommodating/connecting the frame mechanism, and the frame mechanism containing the material is supplied between the upper tool part and the lower tool part.

A device for carrying out cutting operations on at least one open format edge of a printed product, includes: a transport unit configured to transfer the printed product along a guide path from a first cutting location to a second cutting location and from the second cutting location to a third cutting location for an edge-related cutting operation, the transport unit having at least one gripper configured to grip the printed product by its spine to convey the printed product from one cutting location to the next in a suspended manner, and at at least one cutting location, at least one cutting tool configured to perform the edge-related cutting operation comprising a first edge-related cutting operation and optionally at least one second subsequent edge-related cutting operation.

In a first aspect there is disclosed a spike assembly (10) including a base (12) and a spike formation (14) operatively attached to the base (12). The spike formation (14) is adapted to hold a plurality of impaled sheets and includes an elongate spike (16) longitudinally extending between a base end (18) and an impale end (20). The base end (18) of the spike (16) is operatively adapted for attachment to the base (12). The spike assembly (12) further includes a (i) handle (26) operatively associated with the spike formation (14) and moveable relative to the spike formation to apply force to a sheet to be impaled on the spike formation, and (ii) a guide assembly (28) operatively adapted to guide movement of the handle (26) relative to the spike formation (14).

Processing units 4 to 6 aligned along the transport path for a sheet bundle S are accommodated in a housing together with transport units 2 and 3. Windows 10a to 10c are provided in the housing front face, and variable-color lighting units 17 are arranged inside the housing. Light emitting surfaces (projection plates 18) of the variable-color lighting units are arranged facing the windows. Sensor units 13, 15a, and 15b that detect an anomaly of an operation of the transport unit and sensor units 14 and 16 that detect an anomaly of the operation of respective processing units are provided. A binding processing unit stops when an anomaly is detected by the sensor unit, when a system error occurs, or when an emergency stop instruction is input. The color of emission light from a light emitting surface changes to indicate the operation status of the binding processing system.

Discussed is an apparatus for notching an electrode sheet for an electrode tab, the apparatus including: a transfer unit including first and second transfer rollers to continuously, transfer the electrode sheet at regular intervals; a jig unit disposed between the first and second transfer rollers, and supporting a non-coating portion of the electrode sheet; and a notching unit to notch the non-coating portion supported on the jig unit, wherein the jig unit includes: a rotation member provided between the first and second transfer rollers and rotated in a direction perpendicular to a transfer direction of the electrode sheet; and two or more jigs to support the non-coating portion disposed between the first and second transfer rollers, and the jig unit is able to improve a supporting force of the electrode sheet, to prevent the electrode sheet from vibrating, and accurately notch an electrode tab to the electrode sheet.

A sheet processing apparatus includes a conveyance unit that conveys a sheet, a processing unit that performs processing on the sheet conveyed by the conveyance unit, and a controller that controls the conveyance unit and the processing unit. The processing unit includes a cutting unit capable of cutting the sheet along a cutting line, a holding unit that is configured to be movable between a holding position and a release position and that is disposed such that a holding line, which is formed on the sheet when the sheet is held, is substantially parallel to the cutting line, and an angle adjuster capable of adjusting an angle of the cutting unit and the holding unit with respect to a conveying direction.

A cutter module comprises an active rotary cutting blade driven by a blade drive, a passive cutting blade opposite the active rotary cutting blade, and a traction mechanism to pinch a medium to be cut in an area adjacent to the active rotary cutting blade and the passive cutting blade.