The present invention relates to synthetic cables comprising core and splicing threads with high modulus threads, wherein the ends of the cable comprise looped or eyelet splice-type termination ends (1), and wherein each leg of the parallel splicing threads (13, 13′) is connected to parallel core threads (21) at an interpenetration region (12). The method comprises individually connecting each leg of the splicing threads (13) with a positive splice to a core thread(s) (21) of the beginning end of the cable (2); looping; straining all the threads and applying a normal compression force at the interpenetration region (12); applying a protective element(s) (32) along the cable and further individually connecting each leg of the splicing threads (21) to form a negative splice to a core thread(s) (21) of the final end of the cable core (2); and looping, straining and applying a normal compression force (12) on the negative splice at the interpenetration region.

The present invention relates to synthetic cables comprising core and splicing threads with high modulus threads, wherein the ends of the cable comprise looped or eyelet splice-type termination ends (1), and wherein each leg of the parallel splicing threads (13, 13′) is connected to parallel core threads (21) at an interpenetration region (12). The method comprises individually connecting each leg of the splicing threads (13) with a positive splice to a core thread(s) (21) of the beginning end of the cable (2); looping; straining all the threads and applying a normal compression force at the interpenetration region (12); applying a protective element(s) (32) along the cable and further individually connecting each leg of the splicing threads (21) to form a negative splice to a core thread(s) (21) of the final end of the cable core (2); and looping, straining and applying a normal compression force (12) on the negative splice at the interpenetration region.

The method allows the manufacture of at least first and second assemblies (26, 28) of M1 filamentary elements and M2 filamentary elements, at least one of the first and second assemblies (26, 28) comprising several filamentary elements (14) wound together in a helix.

The method comprises a step of assembling M filamentary elements (14) together into a layer of the M filamentary elements (14) around a temporary core (16) to form a temporary assembly (22), and a step of splitting the temporary assembly (22) into at least the first and second assemblies (26, 28) of M1 filamentary elements and M2 filamentary elements.

In order to manufacture a yarn in which filler materials are loaded into a tubular member, the method of manufacturing a yarn has a step of knitting a wire material to form the tubular member. In the step of knitting the wire material, knitting of the wire material is advanced by a plurality of knitting needles, which are placed substantially concentrically about a rotation axis, while revolvingly moving the knitting needles about the rotation axis. When a stitch is to be formed by the wire material, the wire material is prepared so that an arcuate loop portion, which defines a part of the external shape of the stitch, is expanded in a direction which, in a state where the tubular member is developed, is inclined with respect to a straight line that extends in the axial direction of the tubular member.

A rope (1) according to the invention comprises a main rope segment (4), a branching position (5) and an end connector segment (6), wherein the end connector segment comprises a first rope-branch (11) and a second rope-branch (12). The first rope-branch (11) comprises a noosed first rope-branch portion (21N) for making a noosed connection with a thickened rope portion, or a thickened first rope-branch portion for making a noosed connection with a noosed rope portion. The second rope-branch (12) comprises a noosed second rope-branch portion for making a noosed connection with a thickened rope portion, or a thickened second rope-branch portion (22T) for making a noosed connection with a noosed rope portion. The rope according to the invention allows for many various favourable manners of connecting the rope to other ropes and/or to other types of external objects.

Disclosed herein is a transport system, comprising an electrified static cable system, a carriage supported by a non-electrified static cable, an electrical drive system incorporated into the carriage—wherein the electrical drive system is utilized to move the carriage along the pair of parallel non-electrified cables, a transconnector configured to supply electrical power to the carriage, and a cabin mounted to the carriage. Corresponding methods of making and using the system also are disclosed.

An exemplary elongated elevator load bearing member includes a plurality of tension elements that extend along a length of the load bearing member. A plurality of weave fibers transverse to the tension elements are woven with the tension elements such that the weave fibers maintain a desired spacing and alignment of the tension elements relative to each other. The weave fibers at least partially cover the tension elements. The weave fibers are exposed and establish an exterior, traction surface of the load bearing member.

Embodiments disclose a reflective rope assembly consisting of a ladder comprised of two heavy duty safety carabiners, a series of anti-slip PVC rungs, attached to the flexible rope side supports which has reflective silk strands braided in for the purpose of reflecting light in nighttime/dark environment. The fire escape ladders doesn't require any assembly. The safety hooks allow for the ladder to be quickly attached to a window or a balcony railing in multiple ways. The ladder is fully deployed when the hooks are secured, and the ladder is lowered out of a window or a balcony to allow a safe descend.

Embodiments disclose a reflective rope assembly consisting of a ladder comprised of two heavy duty safety carabiners, a series of anti-slip PVC rungs, attached to the flexible rope side supports which has reflective silk strands braided in for the purpose of reflecting light in nighttime/dark environment. The fire escape ladders doesn't require any assembly. The safety hooks allow for the ladder to be quickly attached to a window or a balcony railing in multiple ways. The ladder is fully deployed when the hooks are secured, and the ladder is lowered out of a window or a balcony to allow a safe descend.

Disclosed herein is a transport system, comprising an electrified cable system, a carriage supported by a non-electrified static cable, an electrical drive system incorporated into the carriage, the electrical drive system being utilized to move the carriage along the non-electrified static cable, a transconnector configured to supply electrical power to the carriage, and a power distribution panel. Corresponding methods of making and using the system also are disclosed.