A device 100 produces an endless winding cable 101 by winding a yarn 106 around two thimbles 102, 104. The device 100 comprises an elongated guide 110, a carriage 112, a yarn feeder 114, a first thimble holder 116, and a second thimble holder 118. The first thimble holder 116 and the second thimble holder 118 each hold one of the two thimbles 102, 104. The carriage 112 is movable relative to the elongated guide 110. The yarn feeder 114 is connected to the carriage 112, and comprises at least one spool holder 120 for holding a spool 122 with the at least one yarn 106, and an output guide 124 for guiding the at least one yarn 106 to the cable during winding. The yarn feeder 114 comprises at least one yarn brake 126 for controlling a tension of the at least one yarn 106 during winding.

A method for creating a composite cable having at least one high-performance termination on at least one end. A high-performance termination is added to an end of a short synthetic tensile strength member. The strength of the tensile strength member and termination is then tested. Once tested satisfactorily, the short cable is spiced onto a long cable of the same type using prior art splicing techniques. The union of the short cable and the long cable creates a composite cable having a high-performance termination on at least one end. In most applications it is preferable to set the length of the short cable so that the interwoven splice will exist at a desired location.

A method for creating a composite cable having at least one high-performance termination on at least one end. A high-performance termination is added to an end of a short synthetic tensile strength member. The strength of the tensile strength member and termination is then tested. Once tested satisfactorily, the short cable is spiced onto a long cable of the same type using prior art splicing techniques. The union of the short cable and the long cable creates a composite cable having a high-performance termination on at least one end. In most applications it is preferable to set the length of the short cable so that the interwoven splice will exist at a desired location.

A winch line includes a length of synthetic rope having a connector end and a terminal end. An eye is formed by a splice at the connector end of the synthetic rope. An elastomeric coating encapsulates the eye. An elastomer mass is formed over and encapsulates a base portion of the eye and a portion of the splice. The winch line has a number of intermediate sections of consistent length along the length of the synthetic rope extending between the elastomer mass and the terminal end. A number of demarcations reside on a surface of the synthetic rope indicating a boundary between the intermediate sections.

A winch line includes a length of synthetic rope having a connector end and a terminal end. An eye is formed by a splice at the connector end of the synthetic rope. An elastomeric coating encapsulates the eye. An elastomer mass is formed over and encapsulates a base portion of the eye and a portion of the splice. The winch line has a number of intermediate sections of consistent length along the length of the synthetic rope extending between the elastomer mass and the terminal end. A number of demarcations reside on a surface of the synthetic rope indicating a boundary between the intermediate sections.

A mooring member comprises a rope configured for extending between a vessel floating in a body of water and an anchoring device. The mooring member comprises a plurality of functional elements, wherein a first functional element is wound onto at least a portion of the rope, a second functional element is wound onto the first functional element, and so on, until an outermost functional element is wound onto a second-to-outermost functional element. The functional elements are wound in a helical configuration, and are configured to provide at least one of the following functions: damage protection, buoyancy, optical detection, sonar detection, stiffness control, and anti-fouling.

An assembly and method for using a flexible tensile member as part of the rigging for a heavy machine such as those used in the mining industry. The inventive tensile member includes a core surrounded by a separate armor layer. The armor layer assumes various forms, including a hollow cylinder having a substantial wall thickness. The core produces excellent strength in tension (and with a substantial reduction in weight). The armor layer protects the core from external blows and forces produced by the weight of the other parts of the machine's rigging and the hostile environment in which the machine operates.

The present invention is related to a rope system (10, 20) comprising a first rope section (14, 24), a second rope section (16, 26) and a splice structure (12, 22), wherein the first and the second rope section comprise each at least 3 rope strands. Wherein said splice structure (12, 22) is between the first rope section (14, 24) and the second rope section (16, 26) and connects said first to said second rope section, wherein the rope system further comprises at least one conductive element (18, 28) extending from within the first rope section through the splice structure into the second rope section, whereby at least a portion of the conductive element is immobilized in both, the first and second rope section.

The present invention relates to a rope assembly (1) consisting of at least one rope (2) that is made of textile fibre material and is folded back to form two substantially parallel rope portions (2, 2), wherein load distribution between the two rope portions is enabled and the rope portions are surrounded by a common sleeve (4). The rope assembly according to the invention is particularly suitable as a winch rope or as a rope for drive pulley drives, e.g., as a lift cable, in Koepe hoists and in capstans.

The present invention relates to a rope assembly (1) consisting of at least one rope (2) that is made of textile fibre material and is folded back to form two substantially parallel rope portions (2, 2), wherein load distribution between the two rope portions is enabled and the rope portions are surrounded by a common sleeve (4). The rope assembly according to the invention is particularly suitable as a winch rope or as a rope for drive pulley drives, e.g., as a lift cable, in Koepe hoists and in capstans.