Rope (4) having an eye (2). The rope (4) comprises a first rope portion (8) and a second rope portion (10). The first rope portion (8) and the second rope portion (10) are spliced into each other for forming a spliced connection for obtaining the eye (2). The first rope portion (8) and the second rope portion (10) are formed from an end portion of the rope (4).

A forming device for forming links in the shape of a Mbius strip includes a rotation module with an inner path. The forming device has a widening for 180 rotation of a strip introduced into the rotation module. The rotation module has an inlet suitable for one end of a strip, an outlet suitable for the strip and the inner path extends from the inlet to the outlet. The widening is adapted for rotation of the end of the strip 180 about its longitudinal axis. The device also includes a gas injector positioned at the inlet of the rotation module intended to drive the strip through the inner path of the rotation module.

A hybrid rope (40) or a hybrid strand (50) comprising a core element (42, 52), a first (44, 54) and a second (46, 56) metallic closed layer surrounding said core element (42, 52). The core element (42, 52) includes a bundle of synthetic yarns. The first metallic closed layer (44, 54) includes a plurality of first strands of wires helically twisted together with the core element (42, 52) in a first direction. The second metallic closed layer (46, 56) includes a plurality of second wires or strands helically twisted together with said core element (42, 52) and said first metallic closed layer (44, 54) in a second direction. The cross-sectional area of the core element (42, 52) is larger than the total cross-sectional area of the first (44, 54) and second (46, 56) metallic closed layers. A corresponding method of producing such a hybrid rope or hybrid strand is also disclosed.

A hybrid rope (40) or a hybrid strand (50) comprising a core element (42, 52), a first (44, 54) and a second (46, 56) metallic closed layer surrounding said core element (42, 52). The core element (42, 52) includes a bundle of synthetic yarns. The first metallic closed layer (44, 54) includes a plurality of first strands of wires helically twisted together with the core element (42, 52) in a first direction. The second metallic closed layer (46, 56) includes a plurality of second wires or strands helically twisted together with said core element (42, 52) and said first metallic closed layer (44, 54) in a second direction. The cross-sectional area of the core element (42, 52) is larger than the total cross-sectional area of the first (44, 54) and second (46, 56) metallic closed layers. A corresponding method of producing such a hybrid rope or hybrid strand is also disclosed.

The invention provides a method and apparatus for easily and efficiently manufacturing a cable bead, which features excellent wire winding performance. In this method, an annular core is held by a core rotating means. Then a reel wound with a wire is revolved in one direction through the inside and the outside of the core by a reel revolving means by holding the reel wound with a wire alternately on one side and on the other side of the core. And a wire is wound helically around the core as the core is rotated in a circumferential direction in association with the revolving motion of the reel.

A method for manufacturing a strop (10) including a first eyelet (12a), a second eyelet (12b) and a slender central body (14). The strop comprises a core (16) surrounded by a tubular sheath (18) having a first stub (22a), a first hole (24a), a first inter-hole portion (26a), a second hole (28a), a central section (30), a third hole (28b), a second inter-hole portion (26b), a fourth hole (24b) and a second stub (22b). The method comprises a first priming step of fitting a belt (32) into the sheath (18), to form-a closed ring projecting from the first and second hole (24a, 28a) to create the first eyelet (12a) and projecting from the third and fourth hole (28b, 24b) to create the second eyelet (12b), a second connection step of connecting a reel (36) on the belt (32), and a third step of filling the sheath (18) driving the belt in rotation.

A dual cable alignment apparatus (10) for rotationally aligning assembled cable ends of two cables (3,4) of a twisted cable harness (2), the cable alignment apparatus (10) comprising two clamping jaws (7,8) and a central web (9) disposed between the clamping jaws (7,8). Each of the two clamping jaws (7,8), which can be moved towards one another in the closing direction (s), can clamp a cable (3,4) between the central web (9) and the clamping jaws (7,8). The clamping jaws (7,8) are further designed to be movable laterally past the central web (9) for changing the rotational position by rolling the cable (3,4) clamped between them. The clamping jaws (7,8) can be moved independently of one another in the lateral direction by means of their own lateral drives (16,17), ensuring that each cable (3,4) can be brought precisely and reliably into the desired rotational position.