An automated trimming system is provided that includes a vision system identifying the number of rings positioned within a coil and sheared positions where the rings need to be cut. One or more trimming mechanisms receive the sheared positions and proceed to cut the rings at the sheared positions. A hook arrangement interfaces with the coil for transferring the coil to a trimming area. Moreover, an automated trimming system is provided that includes a coil having a plurality of rings. One or more trimming mechanisms select a number of rings from the coil and proceed to form a sample of desired length, by cutting a portion of the rings. A receiver unit receives the sample from the one or more trimming mechanisms to evaluate the quality of the sample.

A device for rotating a reel of fiber optic cable comprising an elongated L-shaped frame with a first side for supporting a reel in its vertical position and a second side for supporting a reel in its horizontal position. Each of the first and the second sides may be supported by casters. When the L-shaped frame is in the vertical or horizontal position orientation, the casters provide a clearance gap between the floor and at least one transition disc which is located at the vertex of the L-shaped frame. The reel of fiber optic cable may be rotated from its vertical position to its horizontal position by adjusting the tension of chains attached to the distal ends of the L-shaped frame, thus shifting the weight from the first-side support casters, onto the transition disc, and onto the second-side support casters.

A winding machine (10) for winding and/or unwinding band-shaped or strip-like material (12) has at least one rotary plate (16), which is arranged on a pivot arm (24) and can be driven by means of at least two opposite coupling elements (20, 22), at least one coupling element (20) being associated with the rotary plate (16), and the rotary plate (16) being transferrable by means of a pivot device (30) between at least one decoupled state and at least one coupled state. Because the coupling elements (20, 22) can be positioned opposite one another in a coupling position in a sensor-based manner, this allows a coupling process which is as wear-free as possible.

A metal coil compression device includes: a lifting device configured to generate a vertically downward pressing force; a cylindrical outer pressure barrel that is supported by the lifting device; a cylindrical inner pressure barrel that is located inside a peripheral wall of the outer pressure barrel; and a connecting mechanism that connects the inner and outer pressure barrels so that the inner and outer pressure barrels are vertically engaged and are supported relatively rotatably in a circumferential direction. The outer pressure barrel has an outer recess being recessed vertically upward from a bottom end. The inner pressure barrel has an inner recess in a peripheral wall of the inner pressure barrel, the inner recess being recessed vertically upward from a bottom end, and a coil pressing surface that makes contact with a top of the metal coil to transmit the vertically downward pressing force to the metal coil.

In order to increase the operational safety of an unreeling apparatus and an unreeling method at high working speed, an unreeling apparatus for unreeling a ring of wire along a pull-off direction, having at least two reel crowns, which can each be brought into a pull-off position and into a preparation position and/or loading position by way of a displacement device, includes a safety apparatus having an overload safety device and having a safety guide track, which has a directional component that faces in the pull-off direction and acts independently of the other reel crown, at least for the reel crown situated in the pull-off position, wherein the overload safety device holds the reel crown situated in the pull-off position in the pull-off position and, in the event of an overload, releases the reel crown situated in the pull-off position into the safety guide track.

In order to increase the operational safety of an unreeling apparatus and an unreeling method at high working speed, an unreeling apparatus for unreeling a ring of wire along a pull-off direction, having at least two reel crowns, which can each be brought into a pull-off position and into a preparation position and/or loading position by way of a displacement device, includes a safety apparatus having an overload safety device and having a safety guide track, which has a directional component that faces in the pull-off direction and acts independently of the other reel crown, at least for the reel crown situated in the pull-off position, wherein the overload safety device holds the reel crown situated in the pull-off position in the pull-off position and, in the event of an overload, releases the reel crown situated in the pull-off position into the safety guide track.

There is provided herein a lifting and inversion bar especially configured for repositioning cable spools which typically comprise fragile end stop annuli. The present cable spool lifting and inversion bar is configured for repositioning a cable spool comprising a length and radius between horizontal (that is wherein the axis of the cable spool is horizontal) and vertical (that is wherein the axis of the cable spools vertical) orientations. The inversion bar comprises a straight frame and an orthogonal shaft bisecting the frame into long and short ends. Furthermore, for the vertical orientation, the spool is able to freely rests atop the frame without additional support which negates the requirement for horizontal spacers as does the prior art. In this way, the spool may be conveniently lifted from the inversion by using a forklift, a convenient procedure not made possible by the prior art arrangements.

There is provided herein a lifting and inversion bar especially configured for repositioning cable spools which typically comprise fragile end stop annuli. The present cable spool lifting and inversion bar is configured for repositioning a cable spool comprising a length and radius between horizontal (that is wherein the axis of the cable spool is horizontal) and vertical (that is wherein the axis of the cable spools vertical) orientations. The inversion bar comprises a straight frame and an orthogonal shaft bisecting the frame into long and short ends. Furthermore, for the vertical orientation, the spool is able to freely rests atop the frame without additional support which negates the requirement for horizontal spacers as does the prior art. In this way, the spool may be conveniently lifted from the inversion by using a forklift, a convenient procedure not made possible by the prior art arrangements.

An automated trimming system is provided that includes a vision system identifying the number of rings positioned within a coil and sheared positions where the rings need to be cut. One or more trimming mechanisms receive the sheared positions and proceed to cut the rings at the sheared positions. A hook arrangement interfaces with the coil for transferring the coil to a trimming area. Moreover, an automated trimming system is provided that includes a coil having a plurality of rings. One or more trimming mechanisms select a number of rings from the coil and proceed to form a sample of desired length, by cutting a portion of the rings. A receiver unit receives the sample from the one or more trimming mechanisms to evaluate the quality of the sample.

A coiling system (1) and a method for coiling a hot rolled product, the system comprising:a base assembly (3) comprising a base plate (6), a central drum (7) extending from the base plate along a vertical axis, and a receiving sleeve (8) arranged outside of said central drum,a support structure (2) configured to support the base assembly and comprising a first drive mechanism configured to rotate the base assembly around the vertical axis,a feeding device (4) configured to feed hot rolled product to the base assembly so as to form a coil (17), wherein the receiving sleeve is configured to receive a first end of the hot rolled product landing on said base plate so that a coil starts to form inside of said receiving sleeve and outside of said central drum, the base assembly being releasably connected to the first drive mechanism so that the base assembly, after coiling, may be removed from the support structure.