EP0261550B1 - Wire cable for a hanging application over a large height difference, in particular a mine cage cable, deep sea cable or cable car cable - Google Patents

Abstract

A wire rope is constructed so that the twisting moment generated in the rope per unit load decreases from one end of the rope to the other . This is accomplished by varying the length of lay along the rope.

Description

The invention relates to a wire rope for hanging use over a large height difference, in particular with a lower end held against rotation, in particular a conveyor rope, deep-sea rope or cable car rope.

The invention has for its object to increase the structural strength of such a wire rope.

According to the invention, this purpose is achieved by changing the lay length over the rope length such that the load-specific torque of the wire rope decreases upwards.

This is explained as follows:

• m = k · p · d
  (m = Drehmoment; k = konstanter Faktor; p = in der Litzenlage wirkende Längskraft; d = Durchmesser der Litzenlage). Der Faktor k schließt einen Umwandlungsfaktor Längskraft - Tangentialkraft ein, der von der Schrägstellung der Litzen abhängt. Je schräger die Litzen stehen, d.h. je kleiner die "Schlaglänge" im Verhältnis zum Durchmesser d ist, umso größer ist diese Umwandlung und damit der Faktor k und damit bei gleichem p das Drehmoment m. Bei einem Drahtseil mit nur einer Litzenlage auf einer Hanfseele ist die am Seil angreifende Zugkraft exakt gleich der an der Litzenlage angreifenden Zugkraft. Bei einem Drahtseil, das eine Herzlitze und eine Mehrzahl Litzenlagen aufweist, verteilt sich die Zugkraft im wesentlichen auf die Litzenlagen; der Anteil der Herzlitze ist gering.

In a wire rope, the strands run helically, ie at an angle to the longitudinal direction of the wire rope. If a tensile force acts on the wire rope, it acts in the longitudinal direction. She tries to pull the strands in the longitudinal direction, i.e. to untwist them. This creates torque in a strand layer

• m = kpd
  (m = torque; k = constant factor; p = longitudinal force acting in the strand layer; d = diameter of the strand layer). The factor k includes a conversion factor longitudinal force - tangential force, which depends on the inclination of the strands. The more inclined the strands are, ie the smaller the "lay length" in relation to the diameter d, the greater this conversion and thus the factor k and thus the torque m at the same p. In the case of a wire rope with only one strand layer on a hemp core, the tensile force acting on the rope is exactly the same as the tensile force acting on the strand layer. In the case of a wire rope which has a cardiac strand and a plurality of strand layers, the tensile force is essentially distributed over the strand layers; the percentage of cardiac strands is low.

The tensile force acting on the wire rope is equal to the payload at the lower end of the wire rope and the payload on the hanging length of the wire rope is increased by the weight of the wire rope below the point in question in each case. This means that the torque M of the wire rope rises from the lower end of the wire rope upwards in the previous wire ropes. There is no balance of the torques over the length of the wire rope. This results in twists within the rope structure until equilibrium is reached. In the upper area of the wire rope, where the torque is greater than in the lower area, there is a greater tendency to untwist than in the lower area. This leads to untwisting in the upper area with further twisting in the lower area until equilibrium is reached. The untwisting in the upper area loosens the rope structure there. When running over rope sheaves or winding on rope drums, this leads to longitudinal displacements within the rope. Overall, there is damage that shortens the lifespan.

d.h. das von der Lasteinheit erzeugte Drehmoment, nach oben verkleinert.The invention is based on this knowledge and provides a remedy in such a way that the upward increase in the torque M is counteracted by an upward change in the rope structure, which is the load-specific torque

ie the torque generated by the load unit, reduced upwards.

This is possible by changing the lay length over rope length, in a variety of ways and according to three different basic principles:

The first basic principle is to decrease the factor k by increasing the lay length of the strand layer (s) in the equation m = k - p • d - see above explanations.

This basic principle is applicable to only one strand and to several strands of wire strands with the same lay direction, whereby in the latter apart from the outer strand layer also the inner or, if there are several inner strand layers, the next inner strand layer should have an increasing lay length.

The basic principle can also be used if one or more inner strand layers is or are present, which partly or all have the opposite direction of lay than the outer strand layer (s), but due to the dimensions and / or the structure has or have neutral turning behavior, ie is unable or are jointly able to generate substantial torque.

The second basic principle is, by increasing the elasticity of the outer strand layer (s), possibly two outer strand bearings stranded in the same lay direction, and / or reducing the elasticity of the rest of the rope core upwards, the outer strand layer (s) under additional load on the rest Relieve the core of the rope and thus reduce the factor p in the equation m = kp - d for the outer (n) strand layer (s), which primarily determine or determine the torque of the wire rope due to its larger diameter.

This basic principle can be used on its own if the remaining rope core itself does not generate any significant torque due to a special low-rotation structure, namely by reducing the lay lengths in the strands of the outer strand layer (s) and / or increasing the lay lengths in the rest of the strands Rope core upwards, which increases or decreases the elasticity of the strands even upwards.

Depending on the circumstances, this basic principle can also be used in competition with the effect of the first basic principle by reducing the lay lengths of the outer strand layer (s) upwards, which increases the elasticity of the strand layer (s) upwards and thus reduces it by reducing its share of the force absorption acts on the factor p, but at the same time increases the factor k according to the first basic principle. It depends on the structure of the rope as a whole which influence prevails and to what extent the second basic principle of relief can be applied in this way.

The first basic principle of the change in the force conversion determined by the lay length or the lay angle is, as is evident from the above, in competition with a relief which occurs at the same time, depending on the circumstances, according to the second basic principle. The application of the basic principle of changing the force conversion therefore requires that no such relief can take place to any significant extent. This is the case with a single-layer rope with a fiber core or an otherwise sufficiently elastic core remaining under the relevant strand layer (s). Conversely, the application of the basic principle of relief requires a core rope remaining under the relevant strand layer (s), which, after its neutral turning behavior, is at least so much less elastic that it absorbs the intended additional load, and also the necessary metal cross-section having.

The third basic principle is always in competition with the first basic principle of changing the force conversion, according to which a load is shifted from the outer strand layer (s) to at least the next inner strand layer with the opposite lay direction:

Due to the increasing elasticity of the outer strand layer (s) and / or decreasing elasticity of the (only) inner or the next inner strand layer, as already stated, the proportion of the load bearing capacity of the outer strand layer (s) decreases with their metal cross-section and diameter, which exceeds all other strand layers, usually absorbs or absorbs most of the load and generates the torque resulting in the rope. The load portion shifted into the inner or next inner strand layer struck in the opposite direction increases upwards the portion of the counter-torque which arises in this strand layer. The resulting torque then does not increase proportionally with the increase in rope weight. It can be kept constant.

• Die Elastizität der äußeren Litzenlage kann durch Verkleinerung der Schlaglänge dieser Litzenlage gesteigert werden. Die Auswirkung der damit erzeugten Lastverlegung in die innere bzw. nächstinnere Litzenlage auf das resultierende Drehmoment des Drahtseils muß in diesem Falle zur Erzielung des gewünschten Effektes größer sein als die Auswirkung der mit der Verkleinerung der Schlaglänge verbundenen Vergrößerung des Faktors k der äu-βeren Litzenlage, d.h. der Kraftumwandlung nach dem ersten Grundprinzip.

The same means are available as for the second basic principle of relieving the outer strand layers:

• The elasticity of the outer strand layer can be increased by reducing the lay length of this strand layer. In this case, in order to achieve the desired effect, the effect of the load transfer thus generated in the inner or next inner strand layer on the resulting torque of the wire rope must be greater than the effect of the increase in the factor k of the outer strand layer associated with the reduction in the lay length, ie the force conversion according to the first basic principle.

The elasticity of the inner or next inner strand layer can be reduced by increasing the lay length of this strand layer. The effect of the resulting load shift on the torque of the wire rope - magnification of p in the inner or next inner strand layer - in this case, in order to achieve the desired effect, the reduction in the factor k associated with the increase in the lay length exceed this strand layer. Depending on the circumstances, this is quite possible.

Instead of reducing or increasing the lay length of the strand layer itself or in addition to this, a reduction or enlargement of the lay length of wire layers in the strands in question is also possible; this also increases or decreases the elasticity.

It is understood that the basic principle of the load shifting caused by a change in elasticity between the outer and the reverse lay direction of the inner or next inner strand layer can only be used if the inner or next inner strand layer is capable of its dimensions and its construction, a substantial torque to create. If, for example, the inner strand layer is part of a core rope, the diameter of which does not make up more than a third of the rope diameter, it can be neglected.

Finally, it is proposed as an advantageous embodiment of the invention that the specific load absorption, in other words: the load distribution, is approximately uniform in the cable cross-section at the upper end of the cable and that the relatively greater load of individual strand layers necessarily associated with the described load shift then occurs in the lower regions of the wire cable where the load is less.

In order not to have to set up a machine used for the production of the wire rope specifically for continuous change of lay length, the lay length concerned can be changed step by step.

In the following, the invention will be explained in more detail using an exemplary embodiment.

• Fig. 1 einen Querschnitt durch ein Drahtseil,
• Fig. 2 ein Diagramm, in dem für das Drahtseil nach Fig. 1 das Drehmoment M über der Belastung für verschiedene Schlaglängenfaktoren aufgetragen ist, und
• Fig. 3 ein Diagramm, in dem für ein Drehmoment M der Schlaglängenfaktor über der Belastung aufgetragen ist.

Show in the accompanying drawing

• 1 shows a cross section through a wire rope,
• Fig. 2 is a diagram in which the torque M is plotted against the load for various lay length factors for the wire rope of Fig. 1, and
• 3 shows a diagram in which the lay length factor is plotted against the load for a torque M.

1, consists of a cardiac cord 2, an inner strand layer of six strands 3, a plastic sheathing 4 of the inner strand layer and an outer strand layer of ten strands 5 pressed into it.

As can also be seen in FIG. 1, the cardiac cord 2 and the strands 3 and 5 are compressed; the strands 5 are parallel lay strands.

The lay direction of the two strands is different. Both strands are stranded in a cross lay. The average fill factor is 0.68, the stranding factor 0.84 and the weight factor 0.86.

The nominal diameter - at the same time the diameter of the outer strand layer consisting of the strands 5 - is 26 mm, the total metal cross-section 364.0 mm ² , the outer wire diameter 1.40 mm, the length weight 310 kg /% m, the arithmetical Breaking strength 72,800 kp and the minimum breaking force 61,150 kp (nominal strength of the wires 1960 N / mm ² ).

The diameter of the core rope consisting of the cardiac cord 2 and the strands 3 is 14.8 mm. The lay length factor (quotient of lay length and diameter) of the core rope is 6.3. The share of the core rope in the total metal cross-section of the wire rope is 30%.

The free hanging rope length is set at 800 m. The total rope weight is 2.5 t. The rope safety should be 8. This results in a total load of 9.1 t and a payload of 6.6 t or a load on the wire rope on the highest rope cross section of 12.5% and on the lowest rope cross section of 9.1% of the calculated breaking strength.

The diagram in Fig. 2 shows the torque occurring in the wire rope as a function of the load for different lay lengths.

The curves have been determined experimentally on four wire cables of the structure shown in FIG. 1, which have been stranded with different lay lengths of the outer strand layer, with lay lengths factors of 7.7; 7.0; 6.5 and 5.9.

If the torque is to be the same at every height of the wire rope, the lay lengths must be matched to the loads on the wire rope at different heights in such a way that a horizontal line is obtained in the diagram in FIG. 2. In the present example, the greatest load is 12.5% of the calculated breaking strength of the wire rope and the smallest experimentally tested lay length, i.e. Lay length factor 5.9, chosen as starting point A. This results in point B between 7.0 and 7.7 for the lowest load of 9.1% and the same for the loads in between.

In the diagram in FIG. 3, the diagram in FIG. 2, at the same time with an enlarged scale, has been redrawn in such a way that the lay length factor over the load has been plotted for the line AB. There is a lay length factor of about 7.3 for point B. At the same time, the rope length is entered in the diagram in FIG. 3. The dashed line indicates how the desired lay length factor of the outer strands can be read for each point of the rope length. So the rope according to Fig. 1 is constructed.

In the case of a gradual change in the lay length factor, for example, the first 80 m of the wire rope are made with a lay length factor of 5.9, the second 80 m with a lay length factor of 6.06, etc.

Claims (8)

1. Wire rope for suspended use over a great height difference, in particular a wire rope the bottom end of which is secured such that it is prevented from turning, in particular a mining rope, deep- sea rope or ropeway rope, characterised by a change in the length of lay over the rope length in such a way that the load-specific twisting moment of the wire rope (1) decreases towards the top.

2. Wire rope according to claim 1, characterised in that the reduction in the load-specific twisting moment is dimensioned such that it substantially balances out the increase in the own weight of the wire rope (1) towards the top in its effect on the twisting moment.

3. Wire rope according to claim 1 or 2, characterised in that in the case of a wire rope with only one strand layer, the length of lay of the strand layer increases towards the top.

4. Wire rope according to claim 1 or 2, characterised in that in the case of a wire rope with a plurality of strand layers with the same direction of lay, the length of lay of at least the outer strand layer, preferably also that of the inner strand layers or next inner strand layer, increases towards the top.

5. Wire rope according to claim 1 or 2, characterised in that in the case of a wire rope (1) with a plurality of strand layers with different directions of lay, the length of lay of the outer strand layer (5) stranded with a reversed direction of lay compared to the inner or next inner strand layer (3), decreases towards the top and/or the length of lay of the inner strand layer(s) increases/increase towards the top.

6. Wire rope according to claim 1 or 2 or 5, characterised in that in the case of a wire rope with a plurality of strand layers with different directions of lay, the length of lay of the wire layers in the strands of the outer strand layer, stranded with a reversed direction of lay compared to the next inner strand layer, decreases towards the top and/or increases in the strands of the inner strand layer(s).

7. Wire rope according to any one of the claims 4 to 6, characterised in that the specific load in the rope cross-section in the upper part of the rope is approximately homogeneons.

8. Wire rope according to any one of the claims 1 to 7, characterised in that the change in the length of lay is effected in steps.

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