JP5307395B2 - Elevator rope - Google Patents

Description

  The present invention relates to an elevator rope used as, for example, a rope for suspending a car.

  Conventionally, in order to improve the tensile strength, a wire rope in which an elastomer is filled between a rope core and six side strands twisted around the rope core has been proposed. The rope core and each side strand are respectively configured by twisting a plurality of strands. The cross-sectional area of each strand of the side strand is larger than the cross-sectional area of each strand of the rope core. The elastomer is also filled inside the rope core (see Patent Document 1).

Japanese Patent No. 2992783

  When such a conventional wire rope is used in an elevator apparatus as a rope for hanging a car, for example, a plurality of ropes are wound around a sheave. In such a case, since the number of side strands per rope is as small as six, the area of the portion where the rope comes into contact with the sheave becomes small, and the contact surface pressure of the rope becomes large. Therefore, the rope wears out early and the life of the rope is shortened.

  Further, when the diameter of the sheave is increased in order to extend the life of the rope, the entire elevator apparatus is increased in size.

  Furthermore, if the strength of the rope is improved in order to extend the life of the rope, the hardness of the strand increases and the sheave wears out early.

  The present invention has been made in order to solve the above-described problems, and provides an elevator rope capable of extending the life and preventing the entire elevator apparatus from being enlarged. With the goal.

  The elevator rope according to the present invention is provided with a core rope formed by twisting a plurality of strands, an inner layer covering covering the outer periphery of the core rope, and an outer peripheral portion of the inner layer covering at an interval from each other, A core rope having six inner layer strands in which a plurality of strands are twisted together, a core rope, an inner layer covering body, and an outer layer covering body that collectively covers each inner layer strand, and an outer peripheral portion of the outer layer covering body There are twelve outer layer strands that are spaced apart from each other and in which a plurality of strands are twisted together.

  In the elevator rope according to the present invention, six inner layer ropes are provided on the outer peripheral portion of the inner layer covering body that covers the core rope, and the outer layer cover body that covers the core rope, the inner layer covering body, and each inner layer rope in a lump. 12 outer layer strands are provided on the outer periphery of the core, so that the outer diameter of each of the core strand, the inner layer strand and the outer layer strand can be made uniform, and the diameter of each strand is also made uniform. be able to. Therefore, it is possible to prevent the bending stress of the elevator rope from being increased due to the extremely thick strands, and the extremely thin strands from being worn out at an early stage. From this, the diameter of the sheave on which the elevator rope is wound can be reduced, and the entire elevator apparatus can be reduced in size. In addition, the life of the elevator rope can be extended.

It is sectional drawing which shows the rope for elevators by Embodiment 1 of this invention. It is a typical side view which fractures | ruptures and shows a part of elevator rope of FIG. It is sectional drawing which shows the state by which the rope for elevators of FIG. 1 is wound around the sheave. It is sectional drawing which shows the rope for elevators by Embodiment 2 of this invention. It is sectional drawing which shows the rope for elevators by Embodiment 3 of this invention.

Preferred embodiments of the present invention will be described below with reference to the drawings.
Embodiment 1 FIG.
1 is a cross-sectional view showing an elevator rope according to Embodiment 1 of the present invention. FIG. 2 is a schematic side view showing a part of the elevator rope of FIG. In the figure, an elevator rope 1 has a core rope 2 and twelve outer layer ropes 3 provided on the outer periphery of the core rope 2.

  The core rope 2 includes a core rope 4, a resin inner layer covering 5 covering the outer periphery of the core rope 4, six inner layer ropes 6 provided on the outer periphery of the inner layer covering 5, and a core It has the outer layer covering body 7 which covers the rope 4, the inner layer covering body 5, and each inner layer cord rope 6 collectively.

  The core rope 4 is disposed at the center of the core rope 2. Moreover, the core rope 4 is provided with a core part, a first strand layer that surrounds the outer periphery of the core portion, and a second strand layer that surrounds the outer periphery of the first strand layer. . A steel strand is arranged as a central strand 8 at the center of the lasso. In the first strand layer, a plurality of steel strands twisted to the central strand 8 are arranged as the first strand 9. In the second strand layer, a plurality of steel strands twisted around the outer periphery of the first strand 9 are arranged as the second strand 10. That is, the core rope 4 is configured by twisting together a plurality of steel strands 8 to 10.

  Each second strand 10 is twisted in parallel with each first strand 9 so as to be in contact with the adjacent first strand 9. That is, the method of twisting the second strand 10 with respect to the first strand 9 is a parallel twist in which the strands 9 and 10 have the same twist length.

  The inner layer covering 5 is made of, for example, polyethylene resin or polypropylene resin. The inner layer covering 5 may be formed by covering the outer periphery of the core rope 4 with resin and then twisting each inner rope 6 to the outer periphery of the resin, or the core rope 4 and each inner layer. You may form by filling resin between the lasso 6.

  Each inner layer rope 6 is arranged at intervals along the outer periphery of the inner layer covering 5. Further, each inner layer cord 6 is twisted around the inner layer covering 5 so as to surround the core cord 4. Furthermore, a part of the inner layer cord 6 is buried in the outer peripheral portion of the inner layer covering 5.

  In the inner layer rope 6, similarly to the core rope 4, the center portion of the strand, the first strand layer that surrounds the outer periphery of the center portion of the strand, and the second strand layer that surrounds the outer periphery of the first strand layer. And are provided. A steel strand is arranged as a central strand 11 in the center of the strand. In the first strand layer, a plurality of steel strands twisted together with the central strand 11 are arranged as the first strand 12. In the second strand layer, a plurality of steel strands twisted around the outer periphery of the first strand 12 are arranged as the second strand 13. That is, the inner layer strand 6 is configured by twisting a plurality of steel strands 11 to 13.

  Each second strand 13 is twisted in parallel with each first strand 12 so as to be in contact with the adjacent first strand 12. That is, the method of twisting the second strand 13 with respect to the first strand 12 is a parallel twist in which the strand lengths of the strands 12 and 13 are equal.

  The outer layer covering 7 is made of, for example, polyethylene resin or polypropylene resin. A part of the inner layer cord 6 is buried in the inner peripheral portion of the outer layer covering 7. As a result, the inner layer covering body 5 and the outer layer covering body 7 are interposed between the inner layer strands 6. Moreover, the outer layer covering 7 is formed by twisting each outer layer cord 3 around the outer periphery of the resin after covering the core cord 4, the inner layer covering 5, and the inner layer cords 6 with resin. Alternatively, it may be formed by filling a resin between each inner layer strand 6 and each outer layer strand 3.

  Each outer layer cord 3 is arranged at intervals along the outer periphery of the outer layer covering 7. Moreover, each outer layer strand 3 is twisted by the outer periphery of the core rope 2 in the direction opposite to each inner layer strand 6 (FIG. 2). Furthermore, a part of the outer layer cord 3 is buried in the outer peripheral portion of the outer layer covering 7. Therefore, the outer layer covering 7 is interposed between the outer layer cords 3.

  Like the core rope 4, the outer strand 3 has a core part, a first strand layer that surrounds the outer periphery of the center portion, and a second strand layer that surrounds the outer periphery of the first strand layer. And are provided. A steel strand is arranged as a central strand 14 in the center of the strand. In the first strand layer, a plurality of steel strands twisted together with the center strand 14 are arranged as the first strand 15. In the second strand layer, a plurality of steel strands twisted around the outer periphery of the first strand 15 are arranged as the second strand 16. That is, the outer layer strand 3 is configured by twisting a plurality of steel strands 14 to 16.

  Each second strand 16 is twisted in parallel with each first strand 15 so as to contact the adjacent first strand 15. That is, the method of twisting the second strand 16 with respect to the first strand 15 is a parallel twist in which the strand lengths of the strands 15 and 16 are equal.

  The core rope 2 and each outer layer cord 3 are impregnated with a lubricant (for example, lubricating oil). That is, the lubricant is put in the minute gaps in the core rope 2 and in the outer layer cords 3. Moreover, each cross-section of the core rope 4, the inner layer rope 6 and the outer layer rope 3 is a seal type.

  Here, in order to further suppress the wear of the outer layer cord 3, the number of the outer layer cords 3 can be more than 12, but when the number of the outer layer cords 3 is more than 12, the outer layer cords 3 Since the diameter of 3 is reduced, the occupation area of the outer layer cord 3 with respect to the core rope 2 is reduced. Thereby, the ratio of the strength burden of each outer layer rope 3 occupying the elevator rope 1 (the strength burden ratio of the outer layer rope 3) is equal to the ratio of the strength burden of the core rope 2 occupying the elevator rope 1 (of the core rope 2). It becomes smaller than the strength burden ratio.

  On the other hand, when the elevator rope 1 is used in an elevator apparatus, in order to avoid problems due to deterioration of the elevator rope 1 over time, whether or not the elevator rope 1 needs to be replaced is determined by periodic inspection. . Judgment as to whether or not the elevator rope 1 needs to be replaced is performed by checking (observing) the state of the outer layer rope 3 (for example, the progress of breakage or wear of the strands 14 to 16). That is, whether or not the elevator rope 1 needs to be replaced is determined not by the state of the core rope 2 but by the state of the outer layer strands 3.

  Therefore, even if the core rope 2 is significantly damaged, if the state of the outer layer cord 3 is not deteriorated, it is determined that the replacement of the elevator rope 1 is unnecessary. In this case, if the strength burden ratio of the core rope 2 is larger than the strength burden ratio of the outer layer rope 3, the damage to the core rope 2 directly leads to a significant decrease in the strength of the elevator rope 1 as a whole. There is a possibility that the determination that the replacement is unnecessary is wrong.

  In order to eliminate such an erroneous determination, in the elevator rope 1, the number of outer layer strands 3 is set to 12 so that the strength burden rate of the outer layer strands 3 is larger than the strength burden rate of the core rope 2. It is set to be. Specifically, the total value of the breaking loads of each of the strands 8 to 13 constituting each of the core rope 4 and each inner layer rope 6 (collective breaking load of the core rope 2) constitutes each outer layer rope 3 The total value of the breaking loads of all the strands 14 to 16 (the aggregate breaking load of all the outer layer strands 3) is set to 0.6 times or less.

  With respect to the breaking load of the elevator rope 1, each of the strands 8 to 16 is applied to the total value of the breaking loads of all the strands 8 to 16 constituting the elevator rope 1 (collective breaking load of the elevator rope 1). The inventor's test results show that by twisting it is about 25% lower. That is, the inventor has that the breaking load of the elevator rope 1 has an efficiency reduction (twisting reduction rate) of about 25% with respect to the collective breaking load of the elevator rope 1 due to the twisting of the strands 8 to 16. It is known from the test results.

  Therefore, when the collective breaking load of the core rope 2 is set to 0.6 times the collective breaking load of all the outer layer cords 3, when the collective breaking load of all the outer layer cords 3 is A, The aggregate breaking load of the rope 2 is (0.6 × A), and the breaking load P1 of the elevator rope 1 immediately after manufacturing (initial) is expressed by the equation (1).

  P1 = (A + 0.6 × A) × (1-0.25) = 1.2 × A (1)

  On the other hand, when the elevator rope 1 is subjected to aged use (bending), the load sharing ratio of each of the strands 8 to 16 is equalized, and the twist reduction rate is improved by at least 5% or more. I know. Therefore, for example, when the elevator rope 1 is used, a plurality of inner layer ropes 6 are completely broken, the aggregate breaking load of the core rope 2 is reduced to 50% of the initial value, and each outer layer rope 3 is configured. When 10% of all the strands to be broken are broken, the breaking load P2 of the elevator rope 1 in use is expressed by the formula (2).

  P2 = (A × 0.9 + 0.6 × A × 0.5) × (1-0.2) = 0.96 × A (2)

  For this reason, among all the strands 14 to 16 constituting each outer layer strand 3, the percentage of the strands that are broken (the strand break ratio of the outer strand 3) is 10% or less. Is set as the reference for rope replacement, the rope replacement is performed before the breaking load P2 of the elevator rope 1 falls below 80% of the breaking load P1 of the initial elevator rope 1. It can be determined that it is necessary. In other words, the strength burden rate of the outer layer rope 3 that is the target of the necessity of rope replacement is set to a predetermined value or more, thereby preventing an erroneous determination as to whether rope replacement is necessary. Yes.

  In such an elevator rope 1, six inner layer ropes 6 are provided on the outer peripheral portion of the inner layer covering 5 that covers the core rope 4, and the core rope 4, the inner layer covering 5, and each inner layer rope 6 are connected to each other. Since the twelve outer layer cords 3 are provided on the outer peripheral portion of the outer layer covering 7 that collectively covers, it is possible to make the outer diameters of the core cord 4, the inner layer cord 6 and the outer layer cord 3 uniform. The diameters of the strands 8 to 16 can be made close to each other. Therefore, it is possible to prevent the bending stress of the elevator rope 1 from being increased due to the extremely thick strands, and the extremely thin strands from being worn out at an early stage. From this, the diameter of the sheave on which the elevator rope 1 is wound can be reduced, and the entire elevator apparatus can be reduced in size. Further, the life of the elevator rope 1 can be extended.

  Moreover, the area of the part which contacts the sheave of the rope 1 for elevators can be enlarged because the number of the outer layer strands 3 is larger than before. That is, FIG. 3 is a sectional view showing a state in which the elevator rope 1 of FIG. 1 is wound around a sheave. As shown in the figure, a groove 22 is provided on the outer peripheral portion of the sheave 21. In this example, the cross-sectional shape of the groove 22 is semicircular. The elevator rope 1 is wound around the sheave 21 while being inserted into the groove 22.

  When the elevator rope 1 is wound around the sheave 21, the outer layer rope 3 comes into contact with the inner surface of the groove 22. Since the number of outer layer cords 3 is 12, which is larger than the conventional six, the number of outer layer cords 3 that come into contact with the inner surface of the groove 22 increases, and the sheaves 21 of the elevator rope 1 come into contact. The area of the portion can be increased. Thereby, the contact surface pressure with respect to the sheave 21 of the rope 1 for elevators can be reduced, and abrasion of the rope 1 for elevators can be suppressed. Therefore, the lifetime of the elevator rope 1 can be further extended.

  In practice, the undercut groove is generally provided at the bottom of the groove 22, but even in such a case, if the undercut groove is not extremely large, the outer layer rope 3 and The contact state with the inner surface of the groove 22 can be ensured, and the contact area of the elevator rope 1 with the sheave 21 can be made larger than before.

  Furthermore, since the number of outer layer strands 3 is larger than before, the outer layer strands 3 can be constituted by the strands 14 to 16 that are thinner than before, and the fatigue resistance of the elevator rope 1 is improved. It can also be made. Thereby, the diameter of the sheave 21 can be further reduced, and the entire elevator apparatus can be further reduced in size. In this example, the diameter of the conventional sheave that has been 40 times or more the diameter of the elevator rope can be reduced to about 30 times the diameter of the elevator rope 1.

  Furthermore, since the wires 14 to 16 of the outer layer cord 3 are thinner than before, the mounting density of the wires 8 to 16 in the elevator rope 1 can be improved. Strengthening can also be achieved.

  In addition, the inner layer cords 6 are arranged at intervals along the outer peripheral portion of the inner layer covering 5, and the outer layer cords 3 are arranged at intervals from each other along the outer peripheral portion of the outer layer covering 7. Therefore, it is possible to prevent the core rope 4, the inner layer ropes 6 and the outer layer ropes 3 from contacting each other. Thereby, each wear of the core rope 4, each inner layer rope 6 and each outer layer rope 3 can be suppressed, and the life of the elevator rope 1 can be further extended. Further, the bending stress of the elevator rope 1 as a whole can be relaxed by the buffering action of the inner layer covering 5 and the outer layer covering 7.

  Moreover, since each of the core rope 4, the inner layer rope 6 and the outer layer rope 3 is formed by twisting a plurality of strands by parallel twisting, the contact state between the strands is defined as line contact. can do. Thereby, the contact surface pressure of each strand can be reduced, and abrasion of each strand can be suppressed. Therefore, the lifetime of the elevator rope 1 can be further extended. In addition, since the gap between each strand can be reduced, the mounting density (effective cross-sectional area) of each strand can be further improved.

  Moreover, since the core rope 2 and the outer layer cord 3 are impregnated with the lubricant, the friction between the strands 8 to 16 of the elevator rope 1 can be reduced. Wear can be suppressed. Thereby, life extension of the rope 1 for elevators can further be achieved.

  Further, the collective breaking load of the core rope 2 is set to 0.6 times or less than the collective breaking load of all the outer layer cords 3, so that the outer layer that is the target of the necessity of rope replacement is determined. The strength burden rate of the lasso 3 can be increased. Therefore, it is possible to more accurately determine whether or not the elevator rope 1 needs to be replaced simply by observing the state of each outer layer strand 3, and to make an erroneous determination as to whether or not the elevator rope 1 needs to be replaced. It is possible to prevent the occurrence.

  Moreover, since each outer layer strand 3 is twisted in the opposite direction to each inner layer strand 6, it is possible to reduce the untwisting torque of the elevator rope 1.

  In the above example, the collective breaking load of the core rope 2 is set to 0.6 times or less of the collective breaking load of all the outer layer cords 3, but the range of 0.4 to 0.6 times It is desirable to set within.

Embodiment 2. FIG.
4 is a sectional view showing an elevator rope according to Embodiment 2 of the present invention. In the drawing, the cross section of the strands 8 to 10 of the core rope 4 is deformed by compressing the core rope 4 from the outer periphery. Moreover, the cross section of the strands 11-13 of the inner layer strand 6 is deformed by compressing the inner layer strand 6 from the outer periphery. Furthermore, the cross sections of the strands 14 to 16 of the outer layer rope 3 are deformed by compressing the outer layer strand 3 from the outer periphery. That is, the cross sections of the strands of the core rope 4, the inner layer rope 6 and the outer layer rope 3 are deformed by individually compressing the core rope 4, the inner layer rope 6 and the outer layer rope 3 from the outer periphery. Has been. Other configurations are the same as those in the first embodiment.

  In such an elevator rope 1, the cross-sections of the strands of the core rope 4, the inner layer rope 6, and the outer layer rope 3 are individually arranged around the core rope 4, the inner layer rope 6 and the outer layer rope 3. Therefore, the gap between the strands in each of the strands 4, 6, and 3 can be further reduced, and the mounting density (effective cross-sectional area) of each strand 8 to 16 can be reduced. ) Can be improved. Also, since the outer periphery of each strand 4, 6, 3 is smoothed by deforming each strand, for example, when each strand 4, 6, 3 is in contact with each other due to aging or manufacturing errors, etc. Even so, the contact surface pressure between the strands can be reduced, and the life of the elevator rope 1 can be further extended.

Embodiment 3 FIG.
FIG. 5 is a sectional view showing an elevator rope according to Embodiment 3 of the present invention. In the drawing, the cross section of the strands 8 to 10 of the core rope 4 is deformed by compressing the core rope 4 from the outer periphery. Moreover, the cross section of the strands 11-13 of the inner layer strand 6 is deformed by compressing the inner layer strand 6 from the outer periphery.

  The cross sections of the strands 14 to 16 of the outer layer rope 3 are not modified, and have the same shape as the cross section of the strands 14 to 16 of the first embodiment (that is, a substantially circular shape). Thereby, the clearance gap between the strands 14-16 of the outer layer strand 3 is larger than the clearance between the strands 8-10 of the core strand 4 and the clearance between the strands 11-13 of the inner strand strand 6. ing.

  That is, of the core rope 4, the inner layer rope 6 and the outer layer rope 3, only the core rope 4 and the inner layer rope 6 are individually compressed from the outer periphery, so that the core rope 4 and the inner layer rope 6 Only the cross section of each of the strands 8 to 13 is deformed, and the cross section of the strands 14 to 16 of the outer layer cord 3 is prevented from being deformed. In other words, in the core rope 4, the cross-sectional shapes of the strands 8 to 10 when twisted together are deformed by compression from the outer periphery with respect to the core rope 4, and in the inner layer rope 6, when twisted together The cross-sectional shapes of the strands 11 to 13 are deformed by compression from the outer periphery with respect to the inner layer strand 6. On the other hand, in the outer layer cord rope 3, the cross-sectional shapes of the strands 14 to 16 when twisted together are left as they are. Other configurations are the same as those in the first embodiment.

  In such an elevator rope 1, among the core rope 4, the inner layer rope 6 and the outer layer rope 3, only the core rope 4 and the inner layer rope 6 are individually compressed from the outer periphery, whereby the core rope Since only the cross-section of each of the strands 8 to 13 of the inner rope 4 and the inner layer rope 6 is deformed, the mounting density (effective sectional area) of each of the strands 8 to 13 of the core rope 4 and the inner strand 6 is determined. It is possible to improve the strength of the elevator rope 1.

  Here, since the core rope 4 and the inner layer rope 6 are covered with at least the outer layer covering 7, the internal lubricant hardly flows out to the outside. Accordingly, even if the elevator rope 1 is used over time, the lubrication state inside each of the core rope 4 and the inner layer rope 6 is unlikely to deteriorate. On the other hand, since the outer layer rope 3 is in direct contact with the sheave 21, the internal lubricant easily flows out to the outside due to, for example, transfer of the lubricant to the sheave 21. Accordingly, when the elevator rope 1 is used over time, the lubrication state inside the outer layer cord 3 tends to deteriorate.

  Moreover, when the cross section of the strands 14-16 of the outer layer strand 3 is deformed, the lubricant inside the outer layer strand 3 is easily squeezed out by deforming, and the strands 14 to hold the lubricant Since the gap between 16 is also reduced, the lubrication state inside the outer layer rope 3 is likely to be further deteriorated.

  In the elevator rope 1, the cross-sections of the strands 14 to 16 of the outer layer strands 3 are prevented from being deformed. Therefore, more lubricant than the lubricant impregnated in the core strands 4 and the inner layer strands 6 is added. The outer layer strands 3 can be impregnated, and deterioration of the lubrication state inside the outer layer strands 3 can be suppressed. Thereby, life extension of the rope 1 for elevators can further be achieved.

  In each of the above embodiments, the cross-sectional structures of the core rope 4, the inner layer rope 6 and the outer layer rope 3 are sealed, but for example, the Warrington type, the Warrington seal type, the filler type, etc. It may be a cross-sectional structure.

  Further, in each of the above embodiments, the core strand 4 is composed of the core strand, the first strand layer that surrounds the outer periphery of the strand core, and the second strand layer that surrounds the outer periphery of the first strand layer. The third strand layer surrounding the outer periphery of the second strand layer is the core strand 4, the inner strand strand 6 and the outer strand strand 3, respectively. May be further provided. In this case, in the third strand layer, a plurality of steel strands twisted in parallel with the second strand so as to come into contact with the adjacent second strand are arranged as the third strand. .

In recent years, it has become possible to increase the strength of strands due to the progress of wire drawing technology for steel materials. Accordingly, in each of the above embodiments, for example, a strand having a strength of 2050 N / mm ² or more is applied to the core rope 4 and the inner layer rope 6, and a strand having a strength of 1770 N / mm ² or less is applied to the outer layer strand. 3 may be applied. In this way, wear of the sheave 21 due to contact with the outer layer cord 3 can be further suppressed, and the strength of the entire elevator rope 1 can be further increased.

Claims (6)

A core rope having a plurality of strands twisted together, an inner layer covering covering the outer periphery of the core rope, and an outer periphery of the inner layer covering are provided at intervals from each other. A core rope having six combined inner layer strands, the core strand, the inner layer covering body, and an outer layer covering body that collectively covers each inner layer strand, and an outer peripheral portion of the outer layer covering body spaced apart from each other It has 12 outer layer ropes that are installed and twisted together.
For each of the strands of the core cord and the inner layer cord, a strand having a strength of 2050 N / mm ² or more is used.
For the strand of the outer layer strand, a strand having a strength of 1770 N / mm ² or less is used ,
An elevator rope characterized in that a collective breaking load of the core rope is set to be 0.4 times or more and 0.6 times or less than a collective breaking load of all the outer layer cords . For each of the core rope, the inner layer rope and the outer layer rope, the center of the rope, the first strand layer surrounding the outer circumference of the strand, and the outer circumference of the first strand layer A surrounding second strand layer is provided,
The strand is arranged as a central strand in the center of the lasso,
In the first strand layer, the strand twisted to the central strand is arranged as a first strand,
In the second strand layer, the strands twisted in parallel with the first strands so as to be in contact with the adjacent first strands are arranged as second strands. The elevator rope according to claim 1.   The elevator rope according to claim 1, wherein the core rope and the outer layer cord are impregnated with a lubricant.   The cross section of the strand of each of the core cord, the inner layer cord and the outer layer cord is deformed by compressing the core cord, the inner layer cord and the outer layer cord individually from the outer periphery. The elevator rope according to claim 1, wherein the elevator rope is formed.   Of the core cord, the inner layer cord and the outer layer cord, only the core cord and the inner layer cord are individually compressed from the outer periphery, so that each of the core cord and the inner layer cord 2. The elevator rope according to claim 1, wherein only the cross section of the strand is deformed.   2. The elevator rope according to claim 1, wherein each of the outer layer ropes is twisted in the opposite direction to each of the inner layer ropes.

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