A winding module and a winding installation including winding modules for winding metal wire. In such a winding installation or take-up bench a driven capstan is used to pull the metal wire through a processing installation before being led onto a take-up spool. The spool is driven by a cantilever supported shaft. In prior art take-up benches, both the capstan and the spool is reachable by an operator from the same side. This means that the capstan direction—the direction from the driven side of the capstan to the operator side—is equal to the shaft direction—the direction from the drive side of the shaft to the open end of the shaft. In the inventive winding module the capstan direction is opposite to the shaft direction, which provides a completely different operation of the winding module and the winding installation and facilitates the introduction of doffing robots.

A winding module and a winding installation including winding modules for winding metal wire. In such a winding installation or take-up bench a driven capstan is used to pull the metal wire through a processing installation before being led onto a take-up spool. The spool is driven by a cantilever supported shaft. In prior art take-up benches, both the capstan and the spool is reachable by an operator from the same side. This means that the capstan direction—the direction from the driven side of the capstan to the operator side—is equal to the shaft direction—the direction from the drive side of the shaft to the open end of the shaft. In the inventive winding module the capstan direction is opposite to the shaft direction, which provides a completely different operation of the winding module and the winding installation and facilitates the introduction of doffing robots.

A winding apparatus (200) and a method of winding a product strip onto (202) a reel (204) are provided, the winding apparatus (200) comprises, a feeder module (216) for supplying the product strip to the reel; a first winding module part (218) that is configured to engage the reel, the first winding module part (218) being further configured to move along a first alignment path to align the reel in relation to the feeder module (216) at an operative position for receiving the product strip; wherein first winding module part (218) is configured to align the reel (204) in a horizontal position that is normal to a vertical axis (Y) of the winding apparatus and the reel (204) is rotatable at the operative position about a longitudinal axis passing through the reel; and wherein the feeder module (216) is arranged to convey the product strip (202) for winding onto the reel (204), the product strip (202) being within a vertical plane normal to the ground.

A robotic spooler may be provided. First, a first take-up section of a Capture, Cut, and Transfer (CCT) device may receive a longitudinally continuous material. Then, the CCT device may cause the longitudinally continuous material to be captured by a first spool adjacent to the CCT device, cause the longitudinally continuous material to be taken up onto the first spool, and to provide a first cut to the longitudinally continuous material. Next, the CCT device may transfer the longitudinally continuous material from the first take-up section of the CCT device to a second take-up section of the CCT device. Then the CCT device may cause the longitudinally continuous material to be captured by a second spool adjacent to the CCT device, cause the longitudinally continuous material be taken up onto the second spool, and to provide a second cut to the longitudinally continuous material.

A robotic spooler may be provided. First, a first take-up section of a Capture, Cut, and Transfer (CCT) device may receive a longitudinally continuous material. Then, the CCT device may cause the longitudinally continuous material to be captured by a first spool adjacent to the CCT device, cause the longitudinally continuous material to be taken up onto the first spool, and to provide a first cut to the longitudinally continuous material. Next, the CCT device may transfer the longitudinally continuous material from the first take-up section of the CCT device to a second take-up section of the CCT device. Then the CCT device may cause the longitudinally continuous material to be captured by a second spool adjacent to the CCT device, cause the longitudinally continuous material be taken up onto the second spool, and to provide a second cut to the longitudinally continuous material.

A wire body winding device that winds a wire body around a bobbin includes a bobbin pivoting mechanism that pivotally supports and pivots the bobbin, a wire body holding mechanism that holds the wire body, and a wire body moving mechanism configured to move the wire body holding mechanism. When the wire body is pulled out, the wire body moving mechanism moves the wire body holding mechanism between a take-up position where the wire body holding mechanism is capable of holding the wire body and a wire body winding position where the wire body is woundable around the bobbin.

A wire body winding device that winds a wire body around a bobbin includes a bobbin pivoting mechanism that pivotally supports and pivots the bobbin, a wire body holding mechanism that holds the wire body, and a wire body moving mechanism configured to move the wire body holding mechanism. When the wire body is pulled out, the wire body moving mechanism moves the wire body holding mechanism between a take-up position where the wire body holding mechanism is capable of holding the wire body and a wire body winding position where the wire body is woundable around the bobbin.

The subject matter of the invention is a manual multispool cabinet for winding a number of filaments (40, 40a) onto a respective removable transport spool (14, 14a) having a driven main winding shaft (10, 10a) per transport spool (14, 14a), wherein the main winding shaft (10, 10a) is formed for an exactly fitting reception of the transport spool (14, 14a, 214), and wherein the main winding shaft (10, 10a) drives the transport spool (14, 14a). Providing such a manual multispool cabinet that has such an increased filament speed is achieved in that, in addition to the transport spool (14, 14a), a buffer spool (12, 12a) is held on the main winding shaft (10, 10a).

The subject matter of the invention is a manual multispool cabinet for winding a number of filaments (40, 40a) onto a respective removable transport spool (14, 14a) having a driven main winding shaft (10, 10a) per transport spool (14, 14a), wherein the main winding shaft (10, 10a) is formed for an exactly fitting reception of the transport spool (14, 14a, 214), and wherein the main winding shaft (10, 10a) drives the transport spool (14, 14a). Providing such a manual multispool cabinet that has such an increased filament speed is achieved in that, in addition to the transport spool (14, 14a), a buffer spool (12, 12a) is held on the main winding shaft (10, 10a).

The subject matter of the invention is a manual multispool cabinet for winding a number of filaments (40, 40a) onto a respective removable transport spool (14, 14a) having a driven main winding shaft (10, 10a) per transport spool (14, 14a), wherein the main winding shaft (10, 10a) is formed for an exactly fitting reception of the transport spool (14, 14a, 214), and wherein the main winding shaft (10, 10a) drives the transport spool (14, 14a). Providing such a manual multispool cabinet that has such an increased filament speed is achieved in that, in addition to the transport spool (14, 14a), a buffer spool (12, 12a) is held on the main winding shaft (10, 10a).