SU771222A1 - Double-twined wire rope - Google Patents

Description

one

The invention relates to the field of steel wire rope production, namely to double lay-up wire ropes with a linear touch of a wire.

The double strand rope with linear contact of wires in strands x 1 is known. In this cable with linear contact of wires, the step of twisting wires in the box is allowed to be equal to more than 9 O diameters of the strand.

A disadvantage of the known technical solution is that, in such constructions of ropes, when working on blocks, they are in contact with the blockade stream 5 and all external wires in the strands are destroyed successively, which limits the technical life of the ropes.

The purpose of the invention is to increase the service life of the rope.

This is ensured by the fact that in the proposed rope, at the step of twisting a cable, an integer number of steps of twisting the wires into a strand are laid with an accuracy of 0.15.25

The purpose of the tolerance, tO, 15, is a consequence of the total deviation of the actual stride steps from those calculated in the manufacture of ropes, which in general does not affect the index

rope durability. Due to this performance of the ropes, the same wires come into contact with the block, therefore, only a portion of the wires in each strand are exposed to contact with the block, which significantly increases the life of the rope.

FIG. 1 conventionally shows one strand of a double twisted wire rope; in fig. 2 - diagram of the contact of the rope with the block.

Strand 1 is wound around the core 2 of the rope at an angle L- with the pitch H of the twist. Wire 3 retinues in strand with h step lay.

The lay of the wire in strand is expressed in terms of the parameters of the twist:

x,

T | -)

X COSOL K.

where .H / coSot is the length of prd I in step

H lay of the rope; - the number of steps b of twisting the wire into a strand on the length of the strand t at the step of twisting the rope, which is equal to any integer 1, 2, 3, etc.

The most acceptable, in terms of the technological design of the rope, are the numbers X 2. Assignment 3 leads to an increase in the angles of winding the wires into the strand, leads to an increase in the labor intensity of making ropes and is not justified by their durability.

In the proposed kata constructions 71 2. The wire 3 through the X1 step of rope twisting, bypassing the number of turns around the axis of the strand, returns to its original position in the cross section of the rope. So if the wire 3 at point a comes to the surface of the rope and comes into contact with the working surface of the winding body, for example, block 4, then through the stripping of the rope, the same wire again goes to the surface of the rope at point b and again comes into contact with the surface of the block 4 .

Thus, the strand 1 of the rope is in contact with the surface of the winding body all the time by the same wire 3. Therefore, in the cable of the proposed structure, one or a small group of wires in the cable strand and the rest of the wires are destroyed in contact with the working surface of the winding body. Pr do not come into contact with the coiling body at all. In the known rope constructions, which have a fractional number of stride steps, all external wires in the strand or most of them are successively destroyed by contact with the winding member.

Consequently, in the rope of the proposed construction, as gusts of wires accumulate, a greater technical resource is saved than in known rope designs. So, for example, if a wire break occurs at the points a and b from the contact of the rope with the block 4 (Fig. 1), the same wire 3 breaks in two places in the rope of the proposed construction. the strength of the strand is reduced by only one wire, and under similar conditions the strength of the strands of the known constructions is reduced by two wires.

In addition, during the bending of the rope on the block, the part of the body facing the block is compressed, and diametrically opposed to it - unclamping. Under the action of internal elastic forces, the length of the wire from the compression zone is displaced into the stretch zone. Therefore, when bending the rope, elastic axial displacements of the wires occur.

An equal to an integer number, the wire between the points of contact with the block, equal parts passes through the zones of tension and compression. Therefore, the resulting wire displacement at points a and b is zero, i.e. compensated for

the minimum length of the rope - his stride.

When the rope is operated on the block at point 4 (Fig. 2), the contact of the strand with the block and diametrically opposite the IP point of the contact of the strand with the wire core is clamped by the radial pressure force P, which prevents free elastic displacement of the wires at the indicated points. Therefore, if the rope is folded in such a way that, at the indicated points of contraction of b and g of the wire, elastic displacements should be obtained, then pinching them at these points prevents free elastic displacement of the wires, which leads to additional stresses in the wires and weakening of the structural stability of the wires. dey in these points.

In the proposed construction of the rope

At the step of its twisting, an integer number of steps of twisting the wires into a strand is laid, according to .3 the full compensation of the elastic displacements of the wires is achieved at the indicated clamping points b and%, and therefore there are no additional displacements strains in the rope and an increase in the structural stability of the strand, and consequently, an increase in the service life of the rope. In this case, due to the fact that in a straight line contact, all wires are twisted with the same pitch, compensation of displacements is provided simultaneously for all wires in the wires located on the radial pressure transmission line between diametrically opposite points b and 1, which increases the structural density is prd over its entire depth.

For the proposed cable construction at n 6.50, an integer is taken into account, which corresponds to the wire twisting step in strand, 6d. where d is the diameter pr; o is the diameter of the rope. The tests performed show 5 K) t that the rope of the proposed construction with h 10.6d has a longer service life than the rope made with h 9d.

The described invention may be

Q has been seamlessly introduced into industry; tick like its implementation does not require restructuring of the existing cable production. The proposed parameters of double lay ropes extend to rope designs with point-to-point contact of wires in strands, as well as to shaped straps of plastically crimped strands.

Along with this, the implementation of this

0 of the invention can give a significant technical and economic effect. Increasing the steps of twisting the wires in the strand from 9 to 10.6 diameters of the strands in the rope structure at the same rotational speed of the rotor of the straightening machine

accompanied by an increase in spinning speed

-100-Ь 17, in.

which significantly reduces the complexity of the manufacture of the rope.

Claims (2)

Invention Formula 1. A double-layered wire rope with a linear touch of wires in a strand, characterized in that, in order to increase the service life of the rope, during the stranding step, a whole number of wire stranding steps were laid in the strand with an accuracy of 0.1 2. Rope pop. 1, characterized in that the step of twisting the wires in the strand is calculated by the formula 4. .iL  To GtfSd where H is the step of twisting the strands into the rope;  - number of steps of wire twist in prd laid on one step twist strands into the rope; c is the angle of the twist of the strands into the rope. Sources of information taken into account during the examination 1. GOST 3241-66.