WO2021126008A1 - Combined polymer rope - Google Patents

Abstract

The present combined polymer rope relates to the design of braided ropes intended for lifting/lowering and holding various constructions, structures and equipment, comprising up to 48 heavy-duty polymer elements/strands having low structural elongation under tensile loads, and an information portion. Said information portion is in the form of a polymer tube - an optical module - containing one or more optical fibres laid freely therein. The optical module can be further reinforced by means of heavy-duty polymer elements disposed longitudinally or helically along the module axis in a main polymer shell encompassing said optical module. The optical module is arranged in the structure of the rope as a core or as an element in a layer, held in turn by one of the strands of the rope layer.

Description

Polymer combined rope

Description of the utility model

Braided ropes are manufactured in the Russian Federation by many enterprises, for example, Kanat JSC, Dzerzhinsk, Marine Supply LLC, Vladivostok, APERVID LLC, Moscow, etc., from various polymer materials - polyamides, polyester, polypropylene, polyethylene, which have different characteristics in terms of resistance to tensile loads, aggressive media (acids, alkalis, solvents, oxidizing agents), hydrophilicity / hydrophobicity. Ropes are made by braiding on special equipment, for example, by Herzog (Germany), Ratera (Spain) with a certain braiding pitch, which provides the best performance characteristics of the ropes from the above materials.

The rope made of aramid fibers (such as but not limited to: Kevlar ^®, Tvaron ^®) or ultrahigh molecular weight polyethylene (e.g., but not limited to: Dyneema ™, manufactured by DSM, the Netherlands; Spectra ™ Fiber, manufactured by Honeywell, USA).

A technical solution is known from the prior art [US Patent US 20140305744 Rope of a lifting device for an elevator and a condition monitoring method for the rope, publ. 2014], which describes a rope of predominantly rectangular shape, with an optical fiber rigidly incorporated into it, intended for lifting / lowering the elevator car, with the optical fiber / fiber bundle included in it, designed to control the integrity of the rope. The disadvantage of this solution is that a flat rope requires special mechanisms and guides for its use, complicates its use in conditions of external influences, as well as input / output of optical fiber without damaging the latter.

The task of the utility model is the development of the construction of a polymer combined rope, containing, as a rule, but not

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SUBSTITUTE SHEET (RULE 26) limited to this, 12, 16, 24, 32, 40 or 48 power polymer elements / strands of twine, providing minimal elongation of the structure of the utility model when exposed to tensile loads and a medium for data transmission, mainly an optical fiber, enclosed in an optical module integrated into the rope structure , a decrease in the mass-dimensional indicators of the combined rope, and, consequently, the cost of production.

The technical result of the claimed utility model is the creation of a rope of combined, predominantly circular cross-section, with an optical module included in it, containing an optical fiber / fiber bundle, as a data transmission medium.

The utility model is made of ultra-high molecular weight polyethylene (UHMWPE) or aramid threads, which have the lowest elongation when tensile loads are applied to them.

A polymer tube with a loosely laid optical fiber or a bundle of fibers - an optical module, is made of a polymer material that provides high strength and ductility of the module, with the possible addition of a polyamide copolymer, which has a low thermal conductivity and protects the optical fiber from high temperatures during thermal stabilization of the finished rope in infrared camera. The optical module is resistant to crushing loads up to 0.2 kN / cm or more, which ensures the safety of the optical fiber / fiber bundle. The optical fiber / bundle of fibers have a protective coating and fit freely into the optical module simultaneously with the manufacture of the optical module with a redundancy of up to 5%, which eliminates fiber damage when the rope is exposed to operating loads.

A utility model made of UHMWPE can be used, in particular, to hold tethered balloons, which can be widely used in the national economy, in particular, but not limited to, identifying foci of forest fires, conducting prospecting work, monitoring

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SUBSTITUTE SHEET (RULE 26) space from a height of up to 1500 meters or higher, by transmitting a video signal from a camera located on a balloon to an operator. Today, signal transmission from a balloon is carried out either via a radio channel, which either has a low bandwidth, or a short range and may be exposed to atmospheric precipitation, industrial emissions or actions of third parties to distort and / or block the radio signal, or via a separate optical cable, which has a greater weight and size due to its design and is attached to the holding rope with plastic ties or an outer braid made of polymer fiber, which increases the cross-section of the optical rope system and worsens its resistance to wind loads. The use of an external braid increases the weight of the rope by the weight of the braiding threads and leads to its rise in price, since the processes of braiding and braiding a rope are different technological cycles. Use of the utility model A combined polymer rope makes it possible to use optical fiber for signal transmission, rather than a radio channel, will eliminate the influence of atmospheric phenomena and external influence on the transmitted signal in order to block and / or distort it, the strength of the UHMWPE rope will make it small-sized to reduce the impact wind loads, low weight will increase the payload of the balloon, hydrophobicity will exclude wetting of the combined rope during precipitation, and the high resistance of UHMWPE to aggressive media will have a positive effect on the service life of the utility model. Manufacturing of a utility model - a combined polymer rope, is carried out in one technological cycle, which will have a positive effect on the cost of the final product.

Another area of application of a utility model made of UHMWPE can be fastening special equipment for seabed exploration in various areas of the national economy, for example, in the construction of offshore oil and gas platforms, oil and gas loading terminals, scientific research, fishing, where the rope holds

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SUBSTITUTE SHEET (RULE 26) equipment, and optical fiber provides high-quality high-speed data transmission. The positive buoyancy of the rope and the low linear mass will allow lowering more weight to greater depths, which is difficult to achieve using a steel rope / rope due to the fact that the own weight of the steel rope / rope at a certain moment will exceed its maximum breaking load.

The utility model made of aramid yarns can be used in the field of research, control and cleaning of oil wells at great depths, when working with high ambient temperatures, where aramid will provide long-term performance of the rope at temperatures above 60 degrees Celsius, and the optical module will ensure the operability of the fiber for transmitting telemetry data to the surface.

The combined rope can be used for lifting / lowering and holding various structures, structures and equipment without connecting optical fiber / fibers to the receiving-transmitting equipment.

The polymer combined rope has a predominantly circular cross-section and is hollow inside [1]. A ready-made optical module [2] with an optical fiber / fiber bundle [3] is integrated into the braided rope structure at the rope production stage in two ways. The first - like a rope core - fits freely inside the rope twist, see Fig. 1. After finishing the rope with a high friction elastomer, the optical module is held inside the rope by friction force along the entire length of the rope. The second method is as a module placed inside the elements of the rope twist (arrows indicate the direction of twisting of the rope strands) and held alternately by one of the strands [4] in the twist. See Fig. 2. The optical module is inserted and removed at an angle to the axis of the rope and is protected by a polymer or steel tube [5] with crush resistance of up to 0.4 kN / cm or more, which protects the optical module and optical fiber / beam

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SUBSTITUTE SHEET (RULE 26) fibers inside it during operation of a combined polymer rope, see Fig.Z.

In some cases, it is allowed to use an optical module [2], additionally reinforced longitudinally or spirally located along the axis of the module polymer power elements [6], for example, but not limited to, fiberglass rods enclosed in a polymer shell common with the optical module [7]. Fig. 4.

A variant of the practical implementation of the utility model is shown in Fig. 5.

It is obvious to a person skilled in the art that with the development and further development of technologies, the basic concept of the described utility model can be implemented in various ways, therefore, the embodiments of the utility model are not limited to the examples described above, but instead they can vary within the claims of the utility model.

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SUBSTITUTE SHEET (RULE 26)

Claims

Combined polymer rope Utility model formula Combined braided rope, mainly of circular cross-section, containing up to 48 power polymer elements / strands and an optical module integrated into the rope structure with a loosely laid optical fiber / fiber bundle inside. The power section ensures the resistance of the combined polymer rope to longitudinal tensile loads during operation, the information section provides data transmission. 6 SUBSTITUTE SHEET (RULE 26)