DE695148C - Multi-lay, rotation-free stranded spiral rope - Google Patents

Description

Multi-strand, rotation-free stranded spiral rope. B. on tower cranes twisted ropes are used as lifting links to convey freely suspended loads, see above they are turned up by the load.

It is known that the tendency of ropes to untwist under load, its cause is that in the wires, which are in the form of helical lines are mounted around the rope core, the tensile load of the rope torques around the rope axis generated, and that ropes would have to be rotation-free if the algebraic sum of these torques of all wires of the rope, is equal to zero.

This is particularly evident with six- to eight-strand ropes Two to three-layer stranded spiral ropes can be used to remedy the tendency of the rope to twist with different directions of rotation of the individual layers and strands using the same Strand construction for the entire rope has been proposed, but without a satisfactory one Achieve results. On the well-known two to three-layer stranded spiral ropes The tensile load on the rope creates torques in the top layer two to four times larger than those rotated in the opposite direction Core layers. As a result of the tensile load, these known ones also rotate Ropes in the sense of the predominant torque. The top layer therefore rotates up and is relieved. The core layers are turned shut and thus overloaded, as they also account for the load share given off by the surface layer as a result of this twisting of the rope have to take up, and the whole rope tends as a result of its generated, extremely uneven load distribution on the individual wire and strand layers too early Wire and rope breakage. The untwisting of the rope therefore reduces considerably Measure the lifespan and break resistance of the rope and means danger for the with and under the rope. When using a strand with only few wires the whole rope becomes so stiff that it is practically impossible to operate a hoist useful is. When using multi-stranded, soft strands for the whole rope the same so, softly, that the thin wires of the top layer meet the high requirements, which are placed on the rope of a hoist, cannot withstand-_ After When the rope is built into the hoist, its work and probation begins when Thousands of times forward and backward bending of the rope around the pulleys and at Winding and unwinding of the cable drums with simultaneous strong tension and pressure and friction with extremely different operating conditions of the individual systems. The many thin-stranded strands of the declaration layer of known ropes hold such a rope It did not stand up to stress for a long time, as its softness made it resistant to attacks unable to offer enough resistance to such an operation. As a result of the ongoing Raising, pulling, pressing and rubbing the rope loosens up in a short time delicate structure of the top layer, making the rope unusable.

In contrast, the stranded spiral rope according to the invention differs, which consists of one or more core layers of wires or strands that are around a middle element are rotated, and a cover layer opposite to the core layers is provided by the fact that the cover layer consists of two-wire strands and the core layer or core layers of one or a greater number of stranded strands are made in such a way that the ratio: area of the wires a circle circumscribing a strand to the cross section of the wires of the same strand for the strands of the cover layer wholly or approximately a maximum and for the strands of the Core layers wholly or approximately a minimum 'and the lay angle of the strands to the rope in the core layers are kept so much smaller than the lay angle of the strands in the outer layer of the rope that the condition of the greatest possible freedom of rotation is satisfied.

In the top layer, the largest wire diameter is obtained with the smallest metal cross-sectional area. The thick wires of the outer layer give the rope the necessary strength without stiffening it too much, and form a resistant protective sheath for the core strands, which are much more sensitive to external attacks. In the case of multi-lay stranded spiral ropes with one or more layers of multi-stranded strands wound around the core strand, at least approximately complete freedom of rotation is achieved while maintaining the mentioned advantage, if the said condition of the circular area ratios is fully or approximately fulfilled and also the lay angles (p and Y all Strands and wires are chosen so that the conditional equation 'also quite. or is approximately fulfilled. An oil rope has not only wires of one and the same diameter, but very thin and very thick wires in the various layers of the rope cross-section, depending on the various stresses on the stranded layers concerned. The fine wires, which greatly increase the flexibility of the rope, are protected from all external attacks in the core layers, for which the much thicker wires of the outer layer form an effective protective cover. As already indicated, the lay direction of all core layers is opposite to that of the cover layer.

It has already been proposed to use two-wire strands in. Helical lines to be used as a top layer of a rope, for which freedom of rotation is not sought would, but whose core consists of straight, lengthwise juxtaposed wires, which are wrapped in a wide helical shape by means of two wires on the right and left. As a result of its inadequate cohesion, such a rope is constructed as a hoist rope not useable. The spaces between the helical ones under the top layer Winding wires prevent an intimate union of the core and the cover layer. If such a rope is passed over rollers or drums under load, then an indentation of the cover layer into the cavities takes place while immediately above the screw wires on the core, the top layer experiences a special stress, apart from an uneven flow of the mustard. If you wanted such a rope use as a hoist rope, the straight core wires and their winding wires would indeed generate no torque, but the top layer does, which is why the rope as a result the tensile load must turn in the sense of this only available torque and is therefore also not free of rotation.

Another suggestion was one made from wires or strands of wire Strand or a rope with two oppositely laid layers of rope elements based on the goal of freedom of rotation, in that the sum of the cross sections of the rope elements present in the inner layer is selected to be greater than the sum the cross-sections of the outer rope elements. Here, however, was particularly missing Knowledge of the influence of the lay angle of wire and strand on the freedom of rotation, so that according to the rule announced in this proposal, the desired freedom of rotation could not be reached. Another well-known suggestion concerns a rope with as large a number of strands as possible from a small one for the top layer Number of wires with the largest possible cross-section should serve, while the inner Rope consists of a small number of thin-stranded strands, with the outer strands are laid opposite to the inner strands. Freedom of rotation of the rope was neither aimed at nor attainable by this suggestion, since there the There was no knowledge of the relationship: the area of the circumscribing the wires of a strand Circle to the cross section of the wires of the same strand for the core strands whole or approximately one. Minimum and for the strands of the cover layer completely or approximately one Maximum.

Fig. I to 3 of the drawing each show an embodiment of the Subject of the invention shown in cross section and in side view.

Fig.i. The core of the rope consists of (i -E- 8 -f- 1d) laid on the left Strands. The cover layer i is formed by sixteen strands laid on the right. The (8 + 1q.) Core strands 2 are seven-wire, the cover strands are two-wire. The diameter ratio, from the cover layer stranded wire (outer wire) to core layer stranded wire (inner wire) is i: 0.5 to i: 0.7. The rope is particularly suitable as a tower crane rope.

Fig. 2. The core 2 of the rope consists of an ideal strand twisted to the left from seventy-three wires that never overlap the entire length of the pitch and from a layer 3 of twelve seven-strand strands laid on the left. The top layer i form eighteen two-wire strands laid on the right. The diameter ratio from outer wire to inner wire is i: 0.4 to i: o, g. The rope is particularly suitable as tower crane rope.

Fig. 3. The core 2 of the rope consists of a twenty-two wire warrington strand twisted to the left. The top layer a is formed by thirteen struck right two-wire strands. The rope is suitable as an overhead line.

The result of the new regulation is that it includes the core layers Circular area as seamlessly as possible into a large number of fine wires with as few as possible Cross-sectional loss is divided and that the annular surface of the top layer at closed strand layer with a few coarse wires and relatively large gaps is filled. The computational evaluation of this new relationship between the circular area to wire cross-sectional area results in the following applications: For the Warington core strand of Fig. 3 this ratio is a minimum of 1.172 "and for the ideal stranded core In Fig. 2, this ratio is a minimum of 1.13g, while for normal core strands of Fig. i the minimum of r, 285 with the one +. six-wire strand is achieved.

If one considers a rope over its entire length or only a part of it, the extension in the rope direction, caused by the rope pull, must be the same for all rope elements (wires and strands). From this condition and the decomposition of forces on the rope, the following conditional equation can be determined: When applying the conditional equation, a distinction must be made between: first, strands, the center of which coincides with that of the rope, and, second, strands, which are wrapped around a core as a whole element.

For strands of the first type, y = go ° and sin y = i; ooo. The equation of the conditional equation for the rotation-free stranded spiral ropes thus follows that of the rotation-free wire spiral ropes. Here p = pitch angle of the wire, F = cross-sectional area of the wire and r the distance between the center of the wire and the center of the rope. The direction of rotation of the wire determines the sign of its torque contribution.

For strands of the second type, y is the pitch angle of the wire, in relation to the strand axis, 99 is the angle of inclination of the strand axis, in relation to the rope axis, r the distance between the strand axis and the rope axis and F the cross-sectional area of the wire. For the core wire of the strand, sin y = i, ooo. The direction of impact of the Strand determines the sign of the moment contribution of all strand wires. The direction of rotation of the wire is disregarded for the sign of the moment of this type of strand.

The moments of all elements hit on the right get the opposite Sign of the left-hand mark.

The structure of the rope depends on the angle of incline q? and determine y. the smaller the angle of inclination y @ of the wires in a layer, the larger the core required for this and the larger the mean measured in the middle of the wire. Diameter d = 2r of the layer, which is to be calculated from the following formula: Mean in this if n - number of wires of the wire layer in question, 6 = wire diameter of the wire layer in question. Similarly, sin (p, cos T and the mean diameter of the strand layer are determined from the above three formulas, if the strand diameter D = d +. Ö takes the place of the wire diameter ö and that of the strand layer takes the place of the mean diameter of the wire layer.

The angle of impact is chosen to be smaller in one or more core layers than in the top layer. The lay angles (p and y of all strands and wires are chosen so that the condition of complete freedom of rotation is fully or approximately fulfilled. The condition formula states that the angle y should be a maximum for the inner strands and a minimum for the outer strands, while the angle cp should be a minimum for the inner strands and a maximum for the outer strands in order to be able to produce rotation-free ropes according to Figs The angle of incline and y) coincides, has the great advantage for the practical performance of the rope, along with others, that when it is loaded, the stress on all wires becomes more even and balanced than when only one angle of incline is observed.

The lay angles in the illustrated embodiments according to Fig. I for the eight wires of the innermost core strand g) = 58 °, for the eight strands of the first core layer #o = 62 °, for the fourteen strands of the second core layer P = 63 °, for the wires of the (8 to 14) core strands 2 y = 8i °, for the sixteen strands of the cover layer p = 68 ° and for the wires of the sixteen cover strands y = 75 °, according to Fig. 2 for the inner forty-eight wires of the ideal strand Ist iZ = Lay length of the wire layer concerned, then up to 82 °, for the twenty-four cover layer wires of the same 9 = 65 °, for the twelve strands of the core layer q @ = 68 °, for the wires of these twelve core strands y = Si ', for the cover strands (P = 68 ° and for the wires of the cover strands y = 75 °, according to Fig. 3 for the wires of the core strand p = 66 ° to 74 °, for the cover strands (p = 74 ° and for the wires of the cover strands y = 75 °.

Other angle and wire diameter ratios can also be used within the scope of the invention on these types and other types of rope than those shown in Fig. i, 2 and 3.

Experiments in practical operation with the stranded rope described Tower cranes have shown that when loaded from the unloaded state to to full load and vice versa from full load to complete relief does not turn significantly. The load remained as a result of this real freedom of rotation Evenly distributed over the entire cross-section of the rope, which ensures breakage and operational safety of the rope compared to known stranded ropes significantly increased and the risk of accidents is correspondingly reduced by a broken rope.

Claims (1)

PATENT CLAIM Multi-strand, rotation-free stranded spiral rope that consists of one or more core layers of wires or strands that surround a Center element are rotated, and a cover layer that is opposite to the core layers is stranded, characterized in that the cover layer consists of two-wire strands and the core layer or core layers of one or a greater number of stranded strands exist in such a way that the Ratio: area of the circle circumscribing the wires of a strand to the cross-section of the wires of the same Strand for the strands of the cover layer wholly or approximately a maximum and for the Strands of the core layers is wholly or approximately a minimum and the lay angle of the strands to the rope in the core layers are kept so much smaller than the lay angle of the strands in the outer layer of the rope that the condition of the greatest possible freedom of rotation is satisfied.