RU198427U1 - Polymer-coated steel core with an organic core - Google Patents

Abstract

This device belongs to the rope production. The utility model is used as a traction or carrier-traction rope. The technical task of the claimed utility model is to increase the operational characteristics of the rope, namely: preserving the cross-section of the rope during operation, eliminating the "wave" defect, reducing the torque, increasing the modulus of elasticity, reducing the structural elongation To solve this problem, a steel rope with an organic core is proposed, consisting of strands of linear tangency twisted around an organic core 1, while the organic core is covered with a polymer shell 2 filling the turn-to-turn space, the thickness of which is 20-30% of the nominal diameter of the organic core 1, and the ratio of the diameters of the rope and the core is D1: D2 = (2.0 ÷ 2.15), while the outer strands of the 3 ropes are laid with gaps of 1.5-3.5% of the nominal diameter of the strands; in the process of twisting, the rope is pre-stretched by applying a load in the range (0.30 ÷ 0.55) of the breaking force of the rope. The peculiarity of a steel rope in a polymer sheath is that the outer strands 3 can be plastically deformed with a degree of compression of the cross-sectional area of 13-20%. 1 wp f-ly, 3 dwg

Description

This device relates to cable production. The utility model is used as a traction or non-traction rope.

Known commercially available steel double-strand ropes with an organic core according to GOST 3069 design 6 × 7 (1 + 6) + 1 ° C., double-strand rope GOST 2688 design 6 × 19 (1 + 6 + 6/6) +1 about. pp., double twist rope GOST 7668 construction 6 × 36 (1 + 7 × 7/7 + 14) +1 o.s., double twist rope GOST 3077 construction 6 × 19 (1 + 9 + 9) +1 о. from.

The disadvantage of these ropes is to reduce the cross-section during operation, due to the structural extension of the ropes under the action of loads; the unstable position of the strands, causing the waviness of the rope, as a result of asymmetric stretching of the rope during operation and thinning of the organic core.

The technical task of the claimed utility model is to increase the operational characteristics of the rope, namely: maintaining the cross section of the rope during operation, eliminating the “wave” defect, reducing torque, increasing the elastic modulus, reducing the structural elongation of the rope.

To solve this problem, a steel rope with an organic core is proposed, consisting of linear touch strands twisted around an organic core, characterized in that the organic core is covered with a polymer shell filling the inter-turn space, the thickness of which is 20-30% of the nominal diameter of the organic core, and the ratio of the diameters of the rope and the core is D1: D2 = (2.0 ÷ 2.15), while the outer strands of the rope are laid with gaps of 1.5-3.5% of the nominal diameter of the strands; in the process of twisting, the rope is subjected to preliminary stretching by applying a load in the range (0.30 ÷ 0.55) of the tensile strength of the rope.

The peculiarity of the steel rope in the polymer shell is that the outer strands can be plastically deformed with a compression ratio of 13-20% of the cross-sectional area.

The utility model is illustrated by images in which the same or similar elements are provided with the same reference position.

FIG. 1 - cross section of a rope of construction 6 × 36 (1 + 7 + 7/7 + 14) + 1 ° C., where 1 is an organic core, 2 is a polymeric sheath, 3 are outer strands of a rope.

FIG. 2 - cross section of a rope of construction 6 × 19 (1 + 6 + 6/6) +1 o.s., where 1 is an organic core, 2 is a polymer sheath, 3 is the outer strands of the rope.

FIG. 3 - cross section of a rope of construction 6 × K19 (1 + 9 + 9) + 1 ° C., where 1 is an organic core, 2 is a polymeric sheath, 3 are external plastically deformed strands of a rope.

The essence of the utility model is as follows.

The manufacture of a steel rope with an organic core in a polymer shell is carried out in three technological operations: the manufacture of outer strands of the rope, coating the organic core with polymer on the extrusion line, and stranding of the rope on the rope equipment.

The organic core 1 is coated with polymer 2 on an extrusion line. The polymer granules loaded into the extruder loading zone are conveyed by the screw to the head, heating to the melting temperature, and squeezed out under vacuum onto an organic core extending across the screw 20-30% of the nominal diameter of the organic core. To fix the applied coating, the organic core is gradually cooled with water.

As the polymer can be used polypropylene, polyethylene, polystyrene and other plastics.

The manufacture of external strands of rope is produced on spinning equipment. To obtain plastically deformed strands of rope 3, a rolling cage is used, which is installed directly on the spinning equipment after the die holder, the outgoing strand 3 of the dies, curling, enters the rolling cage. After passing the cage, the strand 3 acquires a smooth, regular and dense surface. This reduces the cross-sectional area of the strand 3 by 13-20% after compression.

The manufacture of the rope is made on the rope equipment. When twisting the rope, the surface of the organic core is uniformly heated to the softening temperature of the polymer. The pressure that occurs when winding around the core of the outer strands 3 compresses and profiles the polymer substance until it completely fills the inner free space in the rope and begins to be squeezed out through the gaps between the outer strands.

To reduce the residual technological stresses in the rope and improve operational characteristics, it is subjected to preliminary stretching (i.e., it is pulled before it even happens under load during operation). This operation is carried out on the same rope equipment equipped with a stretching device, while twisting the rope.

The proposed utility model allows to obtain the following technical result: the polymer shell of the organic core allows you to fix the position of the strands of the rope, which is achieved by pressing them when twisting the rope into the polymer, previously softened, eliminating the asymmetric stretching of the rope and the thinning of the organic core during operation.

The thickness of the polymer coating of 20-30% of the nominal diameter of the organic core is optimal, since the rope remains flexible and at the same time the organic core in the polymer shell has less elongation due to filling the inter-turn space with the polymer.

The organic core in the polymer shell better resists compressive and abrasion. The core serves as an internal support and shock absorber for the strands and the rope itself as a whole.

When the rope bends, the core forces it to maintain a symmetrical shape and prevents the rope diameter from decreasing under the action of a tensile load. This determines the ratio of the diameters of the rope and the core D1: D2 = (2.0 ÷ 2.15), as well as the cross-sectional dimension of the core should provide an inter-strand clearance of the outer strands of the rope, equal to 1.5-3.5% of the nominal diameter of the strands, avoiding the contact of wires of adjacent strands, excluding wire breaks under the action of inter-strand pressure. The overestimation and underestimation of the core diameter leads to a decrease in the technical resource of the rope.

The application of a load in the range (0.30 ÷ 0.55) of the tensile strength of the rope significantly exceeds the operational, which ensures uniform reduction of technological stresses and strains both in length and in the cross section of the rope. In addition, the rope after preliminary drawing has increased reliability by reducing torque, increasing the elastic modulus, reducing residual structural elongation.

Ropes with plastically deformed strands with a compression ratio of the cross-sectional area of 13-20% are abrasion resistant, due to the smooth surface, the wear of the block streams is reduced. They have increased strength while maintaining the diameter, and also increases the resistance of the rope to transverse crushing. When the rope is crimped less than 13%, the required breaking strength of the rope is not provided, while the surface remains embossed, which reduces the resistance of the rope to abrasion and crushing. Compression of more than 20% leads to the greatest loss of strength, a decrease in the mechanical properties of the wires of the strands and the rope as a whole.

The choice of design of the outer strands of the rope depends on the operating conditions of the rope.

So ropes of construction 6 × 36 (1 + 7 + 7/7 + 14) +1 o.s. characterized by a relatively large number of wires in the strands and therefore have increased flexibility. The presence of thick wires in the outer layer of these ropes allows them to be successfully used in conditions of abrasive wear and aggressive environments.

Ropes of construction 6 × 19 (1 + 6 + 6/6) +1 o.s. effective when operating in difficult working conditions with intense alternating bending due to the presence of wires of different diameters in the outer layer of the strands.

Construction ropes 6 × 19 (1 + 9 + 9) +1 o.s. or 6 × K19 (1 + 9 + 9) +1 o.s. effective in conditions of severe abrasion due to the presence of wires of increased diameter in the outer layer of the strands.

Laboratory tensile testing of the ropes showed a decrease in structural elongation of 20-30% compared with standard ropes with an organic core without a polymer shell.

Claims (2)

1. Steel rope with an organic core, consisting of linear tangles twisted around the organic core, characterized in that the organic core is covered with a polymer shell filling the inter-turn space, the thickness of which is 20-30% of the nominal diameter of the organic core, and the ratio of the diameters of the rope and the core is D1: D2 = (2.0 ÷ 2.15), while the outer strands of the rope are laid with gaps of 1.5-3.5% of the nominal diameter of the strands; in the process of twisting, the rope is subjected to preliminary stretching by applying a load in the range (0.30 ÷ 0.55) of the tensile strength of the rope. 2. Steel rope with an organic core according to claim 1, characterized in that the outer strands of the rope are plastically deformed with a compression ratio of 13-20% of the cross-sectional area.

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