CS211508B1 - Rope from triangular strands - Google Patents

Abstract

The invention relates to a rope made of triangular strands, which has one or more strands of a wedge-shaped profile, which are formed in the form of wires wound on a core. In many hoists and lifting systems, the lifting rope is required to concentrate physically contradictory properties, such as flexibility and increased wear resistance. The first is achieved by a large number of thin wires and the second by a small number of thick wires. Therefore, none of the known types of rope has a combination of the above properties. These shortcomings are eliminated according to the invention in that at least part of the wires of the strand form twisted groups of wires, in which these wires are formed in the form of a circular sector and are in contact with each other along the helical surfaces.

Description

The invention relates to a triangular strand rope having one or more wedge-shaped strands which are formed in the form of wires wound on a tube.

In many hoists and hoisting systems, the hoisting rope is required to concentrate physically conflicting properties such as flexibility and increased wear resistance. The first is achieved by a large number of thin wires and the second by a small number of thick wires. Therefore, none of the known types of rope have a combination of these properties.

Many design variations of triangular strands and triangular strands are known, the strands of which have wires of round profile wound on a tube, see German Patent 830 015, U.S. Patent 6,018,461 and 3,457,718, U.S. Pat. US-A-567 004, US-A-89592 and US-A-656 123, US-A-patent, or include non-round profile wires, US-A-2 122911, and others.

The known ropes of triangular strands have high rigidity with increased wear resistance. For this reason, they are mainly used in shafts, hoists and other objects that use large diameter rope pulleys and drums. Experiments using ropes of this type in hoists with relatively small pulley and drum diameters have proven unusable for these ratios. because of their low working ability. This is related in particular to the fact that ropes of triangular strands of mainly large diameter require relatively strong and therefore little flexible wires for the construction of the outer layer of the strand as compared to the layer wires located below the outer layer. In addition, the large wires produced according to the known technology have a lower breaking strength than thin ones, which results in a reduction in the overall tensile strength of the rope.

The wires in the ropes of the first assembly touch as a result of the round profile of the wires in the adjacent layer along the helices and leave large unoccupied spaces in the strands, not filled with metal. Wires in core strands of first assembly wear quickly *

The tensile strength of the core itself is limited by the relatively low degree of filling of the strand cross-section with the metal with a relatively low wire strength due to its large diameter.

The profile of the wire shapes in the inner tubes of the second assembly ensures the contact of adjacent wires along the helical surfaces, a high degree of abrasion resistance and a high degree of metal filling, but at the same time has less flexibility and otherwise otherwise the lowest wire strength. particularly strong wires are required.

Thus, the known combinations of triangular strands do not provide a combination of flexibility, wear resistance and rope strength.

The purpose of the present invention is to overcome the above drawbacks.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a triangular strand rope in which the strands are designed to provide a high flexibility of the rope with a sufficiently high resistance to wear and tear.

The object is achieved in that, in a triangular strand rope having one or more wedge-shaped strands consisting of wires wound on a tube, according to the invention, at least a part of the strands of the strand forms a twisted group of wires in which these wires are formed circular sectors and are in contact with each other along the helical surfaces.

The embodiment of strands of wire ropes of which at least e.d. some of which are twisted groups, it follows that thin and more flexible and stronger wires may be used. The formation of these wires in the shape of a circular sector gives the possibility to fill the cross section of the test room with a maximum amount of metal and thus increase its strength. All this together gives such a group of wires the possibility of functional properties of one wire, with an equivalent cross-sectional area and higher strength. At the same time, such a group has increased flexibility, since the wires belonging to the group have the possibility of relative relative displacement relative to each other when bending the rope and unifying sectoral wires, i.e. round sector wires, of high strength into one group. -.

The invention is further characterized in that all strands of the strands form twisted groups of wires in which the strands are formed in the form of a circular sector and are in contact with each other along the helical surfaces.

It is expedient for the twisted groups of wires to be laid on the circumference of the strands, thus allowing the thicker, rigid and low-strength wires to be replaced by these groups.

In some triangular strand wire structures, an interlayer of wires may be arranged between the twisted wire groups and the core, and the cross-sectional area of each wire approximates the cross-sectional area of the wires belonging to the twisted wire groups. level the conditions of their work in the spring and in the rope.

It is also expedient for the twisted groups of wires to be formed from the same number of the same wires. This gives the possibility to simplify the production of both groups and strands of rope as much as possible, to create a rope of physically equivalent wires and to largely level the working conditions of the groups in the strand and overall in the rope.

Is expediently soul strands formed by at least one group of twisted wires in which the wires are formed in the shape of a circular sector and are in contact with each other along the helical surface in _t According to the invention a group of wires twisted strands diarrhea in contact along the helical surfaces.

They have a wedge-shaped cross-section and, in addition to increasing the contact area within the group, the contact area between the groups can also be increased, which increases the abrasion resistance of the strands and overall the rope as well as the maximum increase in the degree of filling the strand.

It is further desirable that the wires belonging to the twisted groups of wires that form the core and the layers of the strand have cross-sections that are close in size to each other. cross-sectional area.

In some triangular strand rope designs, individual wires may be positioned between twisted groups of strand wires to increase the degree of fill of the strand cross-section with metal. The individual wires may have a profile shape.

The invention is further characterized in that the invention has a wedge-shaped cross-section of the rope pulleys and drums, thereby providing high resistance to abrasion and a single-strand rope being made according to this which allows the rope to fit well into the wedge. value in gearing t t t.

In addition to the increased strength and abrasion resistance, the triangular strand rope according to the invention has a high flexibility, which substantially increases its service life, extends the application range and makes it possible to produce a large diameter triangular strand rope from predetermined strength wires.

The invention will now be explained in more detail with reference to the accompanying drawings.

FIG. 1 is a schematic illustration of a triangular strand rope of six identical strands, the structure of which is shown in cross section on one of the strands. .

FIG. 2 shows the same as FIG. 1 with a different strand structure.

FIG. 3 schematically illustrates a triangular strand rope of four strands, each of which has an interlayer of individual wires between groups of wires that are located on the perimeter of the strand and between the core.

Figure 4 is a schematic illustration of a strand of rope, the core of which is made of groups of wires,

FIG. 5 shows the same as FIG. 4 with a different structure of the inner tube.

FIG. 6 is a schematic illustration of a strand of rope in which the core is formed from groups of wires and individual wires.

FIG. 7 shows the same as FIG. 6 with another strand structure.

Figure 8 schematically shows a strand of rope in which the core is made of twisted wedge groups of wires.

The triangular strand rope according to the invention has a plurality of strands 6, as shown in Fig. 1,

2, 3 or one strand as shown in Figs. 4-8, which strands have a wedge profile.

Each of the strands 1 is in the form of wires 3 and 3a wound on the core 2, the wires 3 having a considerably smaller cross-sectional area than the cross-sectional area of the wires 3a.

The number of strands 1 in the rope can vary, as shown in Figures 1 and 3, and is determined by their particular purpose of use. For the sake of simplicity, the structure of one of the strands is shown in Fig. 1-3, with the other strands showing only their outlines.

In the center 4 of the rope, a central core can be provided, which is made of the same metal as the strand wires or of a metal which is softer than the metal of which the wires 3 and 3a consist, of organic or synthetic material. This is not shown in FIG. 1 to make the drawing more readable, especially when this does not affect the nature of the invention.

Inner tubes having only one strand 7 having any structure of the structures shown in Figures 1-8 have a wedge-shaped cross-section, allowing them to fit well into the wedge grooves of the cable pulleys and drums. V-ropes of this kind are intended for use in lifting and load-bearing devices of various purposes, for hoists in mines, lifts, cableways, etc. At the same time, arbitrary strands 6 and 6 can be used to form a rope of triangular strands having multiple strands. the structure of which is shown in Figures 4-8.

The rope strands may have only one layer as shown in Figs. 1 and 2, or more, for example two layers of wires as shown in Fig. 3.

In each of the wires 3 and 3a consisting of the strand 1 / FIG. 1) form part of the wires, for example only the wires of the twisted group A of wires, wherein the cross-sectional area of the group A of wires 3 is equal to or almost equal to the cross-sectional area of wires 3a.

In these wire groups A, the wires 3 'have the shape of a circular die, which has rectilinear sections 5 in the drawing and the wires touch each other due to these rectilinear sections 5 along the helical surfaces.

In a single-layer strand embodiment, the twisted wire groups A are arranged on the periphery of the strand 1 and form its outer layer. The outer strand layer can only be formed entirely from twisted wire groups A / FIG. 2 and 4) with the same cross-sectional area, or may have both twisted groups A of wires / fig. 1 / and also individual wires 3a, but the cross-sectional area of the individual wires 3a is equal to or almost equal to the cross-sectional area of the wire groups A

In a strand 6 made of two layers / FIG. 3), the outer layer is formed only by twisted wire groups A, which consist, for example, of three wires 6, while the intermediate layer, which lies between the twisted wire groups A, and the core 2, is formed of individual wires 7 and a cross-sectional area substantially approximates the cross-sectional area of the wires 6 belonging to the twisted groups A of the wires,

In the rope shown in FIG. 4, all the wires 8 of the strand 1 form a twisted wire group A. In each of these groups A, the wires 6 are formed in the form of a circular sector with rectilinear sections 6 in the drawing and the wires are in contact with each other along the helical surfaces due to these rectilinear sections 9. The shape of the twisted wire groups A may vary it can have the shape of a circle / fig. 1-4, 5, 7) or wedge-shaped, for example trapezoidal in shape (FIGS. 6 and 8), which has rectilinear sections 10 in the drawing, as shown in FIG. 6. Such groups A in the strand are in contact with each other along the screw It is preferred that the number of wires in each twisted wire group A for each strand of soul is the same, for example three. 3 /, four / fig. 1, 2, 6, 7 /, five / fig. The optimum number of wires in group A is determined by the specific purpose of the rope.

The core 6 in each strand can be of any known construction and can be made of wires. 1) of the same or softer metal as the wires of the sliver layers, of organic or synthetic material / fig. 3 /.

The strand 2 of the strand may additionally have a sheath 11 of metal, of organic or synthetic material, as shown in Fig. 2.

To simplify the production technology of the rope as well as to execute the rope, respectively. To produce a rope of the same construction, the strand core 2 can be made of a twisted group of wires, as shown in FIGS. 1, 2, in which group of wires the wires 12 are round / FIG. 1), in the form of a circular sector (FIG. 2 / or have a different profile shape. In a core 2 with wires 12 in the shape of a circular sector, these wires are in contact with each other along the helical surfaces due to the rectilinear sections.

wires in the shape of a round slice.

The core 2 may also consist of a plurality of twisted wire groups 6, as shown in FIG.

4, 6 and in each of them the wires 14 are in the form of a circular sector and are in contact with each other along the helical surfaces.

In FIGS. 4, 5, 6, 7, the twisted core groups 11 of the core wires have a circular cross-section, but this does not exclude the possibility that they have any other shape.

For example, FIG. 8 shows a triangular strand of triangular rope in which the core 6 has twisted groups of wires that are in the wedge shape (triangular). Due to this shape, the groups B in the tubes 2 are in contact with each other and with the twisted groups A of the wires in contact along the helical surfaces. In the core 2 between the groups B there can be located a filling means 6 of synthetic or organic material for closer filling of its cross-section.

Groups A and B wires which form the layers of the source and spirit 2_ £ _t are each in size while the cross-sectional area approaching.

In the strand, the wire groups A are made of the same number of wires of the same type. This applies equally to the twisted groups 6 of the wires of the tube 6. The strand, as shown in Fig. 4, can also be formed from wire groups A and 6 having the same number of wires.

Between the twisted wire groups 6 / FIG. 6 (duse ropes) individual wires 15 of circular profile (not shown in the figure) or shaped profile as shown in FIG.

and 7.

1508

The triangular strand rope of Figures 1 to 8 produced according to the invention and its strands can be produced by any known method using known apparatus.

The ropes made according to the invention can advantageously be used in various lifting devices with large and small diameter of the winding drum.

Claims (9)

A triangular strand rope having one or more wedge-shaped strands consisting of wires wound on a core, characterized in that at least a portion of the strands of the strand (1) form twisted groups (A) of wires in which the strands have wires a cross-section in the shape of a circular sector and are in contact with each other along the screw faces. Triangular strand rope 2 according to claim 1, characterized in that the twisted groups (A) of the wires in the strand (1) are arranged on its circumference. 3. A triangular strand rope according to claim 2, characterized in that an interlayer of wires ΠΙ is arranged between the twisted groups (A) of the strand wires (1) and the inner tube (2), the cross-sectional area of each said wire (7) being approximates the cross-sectional area of the wires (6) belonging to the twisted groups (A) of the wires. Triangular strand rope according to one of Claims 1 to 3, characterized in that the twisted groups (A) of the strands of the strand (1) are formed from the same number of the same wires. A triangular strand rope according to claim 3, characterized in that the strand (2) of the strand (1) is formed by at least one twisted group (B) of wires in which the wires are formed in cross section in the shape of a circular sector and along the helical surface. Triangular strand rope according to one of Claims 1 to 4, characterized in that the twisted strands (A) of the strand wires are wedge-shaped in cross-section and are in contact with each other along the helical surfaces. 7. Triangular strand rope according to claim 5, characterized in that the wires belonging to the twisted groups (A and B) of the wires which form the strand layers (1) or the core (2) have a cross-sectional area approaching each other. . 8. Triangular strand rope according to Claims 1 to 7, characterized in that individual wires (15) are arranged between the twisted groups (A, B) of the strand wires (1). Triangular strand rope according to claim 7, characterized in that the individual wires (15) are designed with a shape profile.