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 power cord handling device and a method to adjust a power cord extending from a device are provided. A frame assembly may include a base supporting a device receiving area to receive a device. A wheel assembly may be adapted to facilitate coiling of a power cord extending from the device when the device is disposed in the device receiving area. The wheel assembly may include a protrusion member. The protrusion member may include one or more slots. A controller may be configured to control a wheel assembly motor. Guide arms may be adapted to receive one or more second portions of the power cord extending from the device and to guide the power cord during a power cord handling operation. The controller may be configured to cause the wheel assembly to perform a power cord handling operation.

The apparatus and methods disclosed herein are directed to detecting the presence of a whipping tail when using a fiber winding system to wind a fiber onto a rotating spool. The fiber is guided onto the rotating spool through a containment region between the spool and a whip shield to create the wound fiber. The whipping tail outwardly extends from the wound fiber and periodically or quasi-periodically passes through a light beam to create a series intensity dips in the light beam, thereby forming a modulated light beam. The modulated light beam is converted into a digital electrical signal made up of electrical pulses having a timing defined by the intensity dips. The measured timing of the electrical pulses is compared to an estimated timing based on the rotating spool to ascertain the presence of a whipping tail.

The apparatus and methods disclosed herein are directed to detecting the presence of a whipping tail when using a fiber winding system to wind a fiber onto a rotating spool. The fiber is guided onto the rotating spool through a containment region between the spool and a whip shield to create the wound fiber. The whipping tail outwardly extends from the wound fiber and periodically or quasi-periodically passes through a light beam to create a series intensity dips in the light beam, thereby forming a modulated light beam. The modulated light beam is converted into a digital electrical signal made up of electrical pulses having a timing defined by the intensity dips. The measured timing of the electrical pulses is compared to an estimated timing based on the rotating spool to ascertain the presence of a whipping tail.

The invention relates to the use of a yarn spool handling container (1) for a yarn spool (2). The yarn spool handling container (1) comprises a frame or a housing (6). With respect to the frame or housing (6), a spindle (15) is rotatably supported. In the yarn spool handling container (1) a winding and unwinding of the technical yarn occurs. The yarn spool (2) is arranged in the yarn spool handling container (1) even during stocking and transport.

The invention relates to the use of a yarn spool handling container (1) for a yarn spool (2). The yarn spool handling container (1) comprises a frame or a housing (6). With respect to the frame or housing (6), a spindle (15) is rotatably supported. In the yarn spool handling container (1) a winding and unwinding of the technical yarn occurs. The yarn spool (2) is arranged in the yarn spool handling container (1) even during stocking and transport.

This winding device includes: a bobbin for winding an optical fiber, the bobbin being a striated body; a cover that covers the outer periphery of the bobbin, the cover having provided thereto a slit that is parallel to the axial direction of the bobbin, and the optical fiber being inserted through the slit; and a roller for directly guiding the optical fiber to the bobbin. In accordance with the bobbin winding barrel diameter of the optical fiber on the bobbin, the bobbin and the roller are caused to move relatively, or the position of the slit in the cover is caused to move in the circumferential direction.

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.

A power cord handling device and a method to adjust a power cord extending from a device are provided. A frame assembly may include a base supporting a device receiving area to receive a device. A wheel assembly may be adapted to facilitate coiling of a power cord extending from the device when the device is disposed in the device receiving area. The wheel assembly may include a protrusion member. The protrusion member may include one or more slots. A controller may be configured to control a wheel assembly motor. Guide arms may be adapted to receive one or more second portions of the power cord extending from the device and to guide the power cord during a power cord handling operation. The controller may be configured to cause the wheel assembly to perform a power cord handling operation.