The invention relates to a microduct-tube winder (5) for winding up extruded empty plastics microduct tubes having an outside diameter of about 2 to about 20 mm, having a reel (8) which is rotatable about a rotation axis (16) and has a core (9) arranged between two radially projecting flanges (10), the tube being windable on said core (9), and having a tube guiding device (6), via which the tube is fed to the reel (8), wherein a first transfer point is provided on the tube guiding device (6), the tube losing contact with the tube guiding device (6) at said first transfer point in the operating state of the microduct-tube winder (5), and wherein provision is made of a second transfer point, assigned to the reel, the tube coming into contact with the core (9) or a tube layer wound onto the latter at said second transfer point, wherein the tube guiding device (6); is movable in a transverse plane of the reel (8) and the reel (8) is movable in the direction of its rotation axis (16) such that in the operating state the winding angle (a) at the second transfer point always remains the same. The invention also relates to a double station winder (1) having two such microduct-tube winders (5), to a processing system having a microduct-tube winder (5), to a manufacturing system having an extrusion apparatus and a processing system and to a method for winding up an empty plastics tube.

An apparatus for reducing fiber whip damage to optical fiber wound on a fiber winding spool is provided. The apparatus includes a fiber entry feed mechanism operatively coupled to the fiber winding spool to feed the optical fiber onto the fiber winding spool. The apparatus also includes a whip shield arranged to substantially surround the fiber winding spool. The whip shield includes a first surface aligned with and facing the fiber winding spool within an entry slot that is laterally offset from a second surface. The first surface transitions to the second surface such that a loose end of the optical fiber is initially directed into the entry slot away from the fiber winding spool and transitions to the second surface.

A carbon nanotube collection apparatus includes: a collection room having an opening part communicating with a carbon nanotube production apparatus; a winding member arranged inside the collection room and configured to wind a carbon nanotube passed through the opening part from the carbon nanotube production apparatus to form a carbon nanotube wound body; and a separation mechanism configured to move the carbon nanotube wound body from a base end side toward a tip end side of the winding member to separate the carbon nanotube wound body from the winding member.

A carbon nanotube collection apparatus includes: a collection room having an opening part communicating with a carbon nanotube production apparatus; a winding member arranged inside the collection room and configured to wind a carbon nanotube passed through the opening part from the carbon nanotube production apparatus to form a carbon nanotube wound body; and a separation mechanism configured to move the carbon nanotube wound body from a base end side toward a tip end side of the winding member to separate the carbon nanotube wound body from the winding member.

A device is disclosed for managing at least one flexible cable including a rigid portion. In at least one embodiment the device includes a first axial end and a second axial end distanced from one another along an axis of the device; at least a first winding surface at the first axial end and at least a second winding surface at the second axial for receiving at least first coil and a second coil of the flexible cable, the first and second winding surfaces being transversal with respect to the axis; and a constraint in the form of a clip or a cylindrical surface for supporting the rigid portion of the flexible cable between the first and the second axial end.

A device is disclosed for managing at least one flexible cable including a rigid portion. In at least one embodiment the device includes a first axial end and a second axial end distanced from one another along an axis of the device; at least a first winding surface at the first axial end and at least a second winding surface at the second axial for receiving at least first coil and a second coil of the flexible cable, the first and second winding surfaces being transversal with respect to the axis; and a constraint in the form of a clip or a cylindrical surface for supporting the rigid portion of the flexible cable between the first and the second axial end.

A cable-cord wrapping apparatus for promoting optimal wrapping and storage of audio or video cables. The cable-cord wrapping apparatus may primarily feature a handle integrally-connected to two arms running parallel to each other and integrally-connected to each other by a curved base. The arms create a channel within which to insert a cable or cord. Each arm may be tapered to provide optimal flexibility of the arms while maintaining desired structural integrity for securely storing a cable. Additionally, each arm may feature rounded ends which ease insertion of a cable or cord into the channel while also creating a barrier at the open end of the channel.

A cable-cord wrapping apparatus for promoting optimal wrapping and storage of audio or video cables. The cable-cord wrapping apparatus may primarily feature a handle integrally-connected to two arms running parallel to each other and integrally-connected to each other by a curved base. The arms create a channel within which to insert a cable or cord. Each arm may be tapered to provide optimal flexibility of the arms while maintaining desired structural integrity for securely storing a cable. Additionally, each arm may feature rounded ends which ease insertion of a cable or cord into the channel while also creating a barrier at the open end of the channel.

The present invention generally relates to an improved winding apparatus useful in the production of filament wound products and particularly wound tubular products having high length to diameter ratios. The improved winding apparatus comprises a support means for supporting a rotatable mandrel during the manufacture of wound products, the support means comprising a plurality of axially spaced pins extending circumferentially around the mandrel, and a support assembly having a semicircular inner face and an opening, wherein a portion of the plurality of pins is brought into contact with the inner face of the support assembly when the mandrel is rotated.

A drive unit is provided for powering a turret winding head for winding roving onto bobbin tubes. The drive unit comprises a closed housing, a first and a second spindle disposed in a turret base plate, wherein the turret base plate is formed as part of the housing and the spindles are disposed outside of the housing. A first drive is provided for the first spindle and a second drive is provided for the second spindle. The drives are disposed inside the housing, and the first and second drives are each provided with a fan wheel. An intake duct, through which air is drawn in by the fan wheel from outside of the housing, is in each case provided on the intake side of the fan wheel of the first and second drives.