DE3940547C1 - Wire rope binding - has core strand with precompressed outer and inner strand sections - Google Patents

Abstract

The wire rope consists of outer strands (1), inner strands (2) and a core strand (3). The outer and inner strands consists of single-layer strans with e.g. 1+6 wires, which are compressed during mfr. The core strand can consists of multi-layer strands with compressed outer strands. The single-layer strands inside the rope are compressed in dia. during mfr. by at least 20 percent less than the single-layer strands in the outer strands. With 50 percent redn., the bending capacity of the rope at the centre increase by 20 percent. ADVANTAGE - Capacity and service life are improved.

Description

The invention relates to a wire rope made of compacted strands, which preferably consists of two layers of strands. Essentially wire rope constructions come into question
with single-layer strands both in the outer rope strand layer and inside the rope,
with parallel lay strands both in the outer rope strand layer and inside the rope,
with single-layer strands inside the rope and parallel lay strands in the rope outer strand layer and
with parallel lay strands inside the rope and single-layer strands in the rope outer strand layer.

Increasingly, wire ropes are used in the manufacture of wire ropes compacted strands to the breaking strength of the wire rope and the resistance against harmful pressures during operation (see e.g. GB-PS 7 94 411). It has been shown that with increasing compression degree to which the strands are subjected during their production, the performance of the rope made from it sinks. The inside of the rope is sufficiently powerful It is of particular importance to make them capable, and therefore not in operation a rope is destroyed from the inside out; because it is known that A wire rope is ready to be discarded due to wire breaks at the rope periphery be recognizable.  

By roping the outer strand layer onto a rope core or a steel soul as well as preforming, postforming and related stretching processes strong radial pressures arise, which adversely affect the inside of the rope impact. If the inside of the rope is made of compacted strands anyway, The radial pressures and also add to these compressions Stretching of the end stranding, which can lead to serious problems especially during operation, the inner elements under the radial pressures of the outside elements have to work. The wear inside the rope is not necessary casually increased.

The invention is therefore based on the object of performance and to increase the lifespan of wire ropes from compacted strands.

To solve this problem are each characterized in claims 1-4 characteristics. The sub-claim contains a useful further training dung.

Through the measures according to the invention, the performance is achieved of wire ropes made of compacted strands. So increases, for example, when the degree of compression of the inner one is halved Strands compared to the outer strands of the same design, the bending performance of a wire rope by an average of almost 20%. This is the case with wire ropes Various constructions possible, the basic idea of the invention this is because strands are used inside the rope, the diameter moderately less compressed than the strands of the Rope outer strand layer. This applies to strands of the same design. With strands different designs (e.g. single-layer strands and parallel lay strands) are different due to the different compaction qualifications Conditions. A single-layer stranded wire can be due to the smaller Fill factor and the associated larger gaps between their elements compress higher than with less mechanical power loss Parallel strands. But it is advisable to compress them to be increased by a maximum of 60% more than that of parallel lay strands.  

The resulting lower inner rope wear causes an increased Lifespan. The percentage reduction in the outer strand diameter judges the type of strand used. If single-layer outer strands through have been reduced by about 10%, then it is advisable, e.g. Reduce parallel lay outer strands only by approx. 5%. The compaction process can be done by hammering, drawing dies or rolling Profile rolls or roller rolls are carried out. In practice it is To prefer rollers with rollers.

The following are essentially considered as rope constructions in which the measures according to the invention can be used:
Strand spiral ropes in parallel lay-up style;
rotation-free ropes;
Ropes with steel core.

With each type of rope, strand layers can be made from single-layer strands, from pa parallel lay strands or combinations of these types of strands.

The heart braid can also be one be uncompacted strand.

In the drawings there are exemplary embodiments of wire according to the invention shown ropes.

Show it:

Fig. 1 is a Litzenspiralseil in Parallelschlagmachart;

Fig. 2 is a strand spiral rope in parallel lay with filler strands;

Fig. 3 is a stranded spiral rope in parallel lay type of another design;

Fig. 4 is a stranded spiral rope in Warrington style;

FIG. 5 shows a rotation resistant wire rope;

Fig. 6 shows a rotation resistant cable with two Innenlitzenlagen;

FIG. 7 shows a rotation resistant cable of another type;

Fig. 8 is a wire with steel core;

Fig. 9 is a wire rope with a steel core of another type.

Fig. 1 shows a stranded spiral rope in parallel lay. It consists of outer strands 1 , inner strands 2 and a cardiac strand 3 . In the design shown, the outer strands 1 and the inner strands 2 consist of single-layer strands with 1 + 6 wires, which were compressed during their manufacture. The cardiac cord 3 can be a multi-layer strand with compressed outer wires, but it can also be undensified. The single-layer strands 2 in the interior of the rope were compressed in diameter by at least 20% less than the single-layer strands 1 of the outer rope strand layer.

Fig. 2 shows a stranded spiral rope in parallel lay with filler strands. Parallel lay strands are used both inside the rope (strands 5 ) and in the outer rope strand layer (strands 4 ). The parallel lay strands 5 inside the rope have been sealed ver at least 20% less than the parallel lay strands 4 of the outer rope strand layer during their manufacture. A single-layer, compacted strand of type 1 + 6 can serve as cardiac cord 7 . The filling strands 6 can also be compacted strands of type 1 + 6.

Fig. 3 also shows a stranded spiral rope in parallel lay, but of a different type. In this case, compressed parallel lay strands 8 are used only in the outer rope strand layer, while the inner strand layer has single-layer compressed strands 9 of type 1 + 6. Both strand layers 8 , 9 were compressed during their manufacture. The cardiac braid 10 can be designed as a multi-layer braid, which was compressed during its manufacture. But it can also be undensified. The single-layer strands 9 in the interior of the rope were compressed at most 60% more in diameter than the parallel lay strands 8 of the outer rope strand layer.

Fig. 4 shows a two-layer stranded wire rope in Warrington design, in which the features of the invention have been realized. The structure of the outer strands corresponds to FIG. 2, with thicker strands 11 and thinner strands 12 alternating. The inner Parallelschlaglitzenlage strands 13 corresponds to the position 5 of Fig. 2. Similarly, the corresponding Herzlitze 14 in construction to the Herzlitze 10 of Fig. 3. The Parallelschlaglitzenlage 13 inside the rope is less compressed in their preparation at least 20% than the Parallelschlaglitzen 11 , 12 of the outer rope strand layer.

Fig. 5 shows a rotation-free wire rope. The outer strand layer 15 , consisting of compacted strands of type 1 + 6, has been roped in the opposite direction of lay than the inner strands 16 , which are designed as parallel lay strands, corresponding to the strands 13 in FIG. 4. The cardiac strand 17 corresponds to the structure of the cardiac strand 14 in Fig. 4. The parallel lay inner strands 16 have been compressed in diameter by at least 60% less than the single-layer strands 15 of the outer rope strand layer.

Fig. 6 also shows a rotation resistant wire rope, but of a different design with two Innenlitzenlagen 19, 20. The outer strand layer of compacted strands 18 of type 1 + 6 has been roped up in the opposite direction. The outer strands 18 and the inner strands 19 have been compressed during their manufacture, while the strands 20 of the innermost strands were of the 1 + 6 design, compressed according to the strands 9 in FIG. 3, or also uncompacted. The Herzlitze 21 corresponds in its construction to the Herzlitze 10 of Fig. 3. The strands 19 are diametrically compressed during its production by more than 40% of the degree of compaction of the outer strands 18th The inner strands 20 are optionally compressed by at least 20% less than the outer strands 18 .

Fig. 7 shows another rotation-free wire rope of a different type, the strand layers consist of single-layer strands. The outer strand layer with its compressed strands 22 is roped in the opposite direction. The inner strand layer consists of compressed strands 23 , which alternate with thinner compressed strands 24 . The innermost strand layer 25 can be a compressed strand 1 + 6 corresponding to the strand 9 in Fig. 3, but it can also be undensified. The Herzlitze 26 ent speaks in structure to the Herzlitze 10 of Fig. 3. The strands 23, 24 and optionally 25 are diametrically less compacted in their preparation at least 20% than the outer strands 22nd

Fig. 8 shows a wire rope with a steel core. The outer strands 27 are strands in parallel lay-up style corresponding to the strands 4 in FIG. 2. The inner strands 28 correspond to the strands 5 in FIG. 2. The cardiac strand 29 corresponds to the cardiac strand 3 in FIG. 1. Here too, the strands 28 are in their manufacture position was compressed by at least 20% less in diameter than the strands 27 .

Fig. 9 shows a wire rope with a steel core of another type. The outer strands 30 are strands in parallel lay-up style corresponding to the strands 4 in FIG. 2. The inner strands 31 correspond to the strands 2 in FIG. 1. The cardiac strand 32 corresponds to the cardiac strand 7 in FIG. 2. Here, too, the strands 31 are of diameter in their manufacture have been compressed by at least 20% less than the strands 30 .

Claims (5)

1. wire rope from compacted strands with single-layer strands inside the rope and single-layer strands in the rope outer strand layer, characterized in that the single-layer strands ( 2 ) inside the rope were compressed in diameter at least 20% less than the single-layer strands ( 1 ) of the rope outer strand layer. 2. Wire rope made of compacted strands with parallel lay strands inside the rope and with parallel lay strands in the outer rope strand position, characterized in that the parallel lay strands ( 5 , 13 ) were compressed at least 20% less during manufacture than the parallel lay strands ( 4 ; 11 , 12 ) Rope outer strand layer. 3. wire rope made of compacted strands with single-layer strands inside the rope and parallel lay strands in the rope outer strand layer, characterized in that the single-layer strands ( 9 ) inside the rope were more thick in diameter, but at most 60% more compressed than the parallel lay strands ( 8 ) the outer rope strand layer. 4. wire rope made of compacted strands with parallel lay strands inside the rope and single-layer strands in the outer rope strand layer, characterized in that the parallel lay strands ( 16 ) inside the rope were compressed in diameter at least 60% less than the single-layer strands ( 15 ) of the outer rope strand layer. 5. wire rope made of compacted strands according to any one of claims 2-4 with a cardiac cord, characterized in that the cardiac cord ( 3 , 7 , 10 , 14 , 17 , 21 , 26 , 29 , 32 ) is an undensified cord.