A method and a system of winding a continuous elongate element onto cylindrical elements. The continuous elongate element is wound from a feeder onto a first cylindrical element. The first cylindrical element rotates with the same rotational speed as a second cylindrical element provided on the other side of a central rotatable member. During the rotation, the feeder is displaced from being aligned with the first cylindrical element to being aligned with the second cylindrical element, wherein the displacement causes the continuous elongate element to come into engagement with an engagement portion of the central rotatable member, preventing the already wound portion of the continuous elongate element from being unwound from the first cylindrical element. The continuous elongate element from the feeder is continued to be wound onto the second cylindrical element by continuing to rotate the second cylindrical element.

A method and a system of winding a continuous elongate element onto cylindrical elements. The continuous elongate element is wound from a feeder onto a first cylindrical element. The first cylindrical element rotates with the same rotational speed as a second cylindrical element provided on the other side of a central rotatable member. During the rotation, the feeder is displaced from being aligned with the first cylindrical element to being aligned with the second cylindrical element, wherein the displacement causes the continuous elongate element to come into engagement with an engagement portion of the central rotatable member, preventing the already wound portion of the continuous elongate element from being unwound from the first cylindrical element. The continuous elongate element from the feeder is continued to be wound onto the second cylindrical element by continuing to rotate the second cylindrical element.

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.

Provided is a yarn box, a yarn stripping method, an electronic device and a storage media. The yarn box includes a support, a yarn stripping rod and a yarn receiving rod; where a first end of the yarn receiving rod is connected to the support, a first end of the yarn stripping rod is slidably connected to the support, the yarn stripping rod is configured to slide to a yarn stripping position corresponding to a first yarn receiving rod among the yarn receiving rod when multiple yarn spindles are sleeved outside the first yarn receiving rod and the number of yarn spindles of the first yarn receiving rod reaches a set condition, the yarn stripping rod is provided with multiple yarn strippers corresponding to the multiple yarn spindles one by one, and the yarn strippers are configured to strip fiber yarn on outer surfaces of the corresponding yarn spindles.

Provided is a yarn box, a yarn stripping method, an electronic device and a storage media. The yarn box includes a support, a yarn stripping rod and a yarn receiving rod; where a first end of the yarn receiving rod is connected to the support, a first end of the yarn stripping rod is slidably connected to the support, the yarn stripping rod is configured to slide to a yarn stripping position corresponding to a first yarn receiving rod among the yarn receiving rod when multiple yarn spindles are sleeved outside the first yarn receiving rod and the number of yarn spindles of the first yarn receiving rod reaches a set condition, the yarn stripping rod is provided with multiple yarn strippers corresponding to the multiple yarn spindles one by one, and the yarn strippers are configured to strip fiber yarn on outer surfaces of the corresponding yarn spindles.

Apparatus and methods for winding flexible material include a rotatable plate assembly rotatably driven by a first rotary shaft, the assembly supporting second and third rotary shafts with corresponding first and second mandrel parts mounted thereon. The first and second mandrel parts each form at least part of a winding spool. The second and third rotary shafts have rotational axes that are parallel to one another and parallel to, but laterally offset from, the rotational axis of the first rotary shaft. The rotation of the plate assembly is coordinated with counter rotation of the first and second mandrel parts. In embodiments, such coordinated rotation occurs during transition operations performed between winding operations that employ the first and second mandrel parts in an ordered sequence one after the other. The flexible material can be cable, wire, tubing, hose, rope, or other filamentary material. Other aspects are described and claimed.

Apparatus and methods for winding flexible material include a rotatable plate assembly rotatably driven by a first rotary shaft, the assembly supporting second and third rotary shafts with corresponding first and second mandrel parts mounted thereon. The first and second mandrel parts each form at least part of a winding spool. The second and third rotary shafts have rotational axes that are parallel to one another and parallel to, but laterally offset from, the rotational axis of the first rotary shaft. The rotation of the plate assembly is coordinated with counter rotation of the first and second mandrel parts. In embodiments, such coordinated rotation occurs during transition operations performed between winding operations that employ the first and second mandrel parts in an ordered sequence one after the other. The flexible material can be cable, wire, tubing, hose, rope, or other filamentary material. Other aspects are described and claimed.

An electromagnetic drive for a cutting device of a textile machine for severing a thread, a cutting device having an electromagnetic drive, and a yarn clearer having a cutting device are provided. The electromagnetic drive may comprise a solenoid and a piston configured to drive a cutting blade carrier. The piston may be guided for linear movement within the solenoid and may be configured to be linearly moved between a rest position and a working position. The electromagnetic drive may comprise an axial air gap between an end face of the piston and a counter face of a component of the solenoid. The component may be stationary relative to the piston and the axial air gap may be varier based on movement of the piston.

A device for fixing a tail end of a filament to a filament spool is provided. The device includes a filament threading module having a filament feeding module and a filament guide mechanism. The filament feeding module is configured to clamp the filament and pass the tail end of the filament through a first threading hole on the filament spool. And the filament guide mechanism including a filament guide assembly is used to guide the tail end to pass through a second threading hole on the filament spool after the tail end of the filament has passed through the first threading hole. The filament guide assembly including a filament guide and a filament driver. The filament driver is configured to move the filament guide assembly towards or away from the filament spool.