CN216551315U - Composite rope and mooring rope comprising same - Google Patents

Abstract

The utility model relates to the technical field of rope manufacturing, in particular to a composite rope and a mooring rope comprising the same, wherein the rope is formed by rope yarns and a supporting framework in a weaving or twisting mode; the rope yarns are made of ultra-high molecular weight polyethylene fibers and ultra-high molecular weight polyethylene split fibers; the diameter of the rope is 4-15 mm. The composite rope prepared by the utility model is high-strength, wear-resistant and bending-resistant rope prepared by utilizing the performance of the material, wherein the support framework provides toughness, the ultra-high molecular weight polyethylene fiber improves the strength of the rope, and the ultra-high molecular weight polyethylene split fiber strengthens the wear-resistant performance of the rope. The utility model also provides a cable made of a plurality of the ropes, the strength of the cable can reach more than 300Kn, and the cable can be widely applied to the field of high-end rope nets.

Description

Composite rope and mooring rope comprising same

The technical field is as follows:

the utility model relates to the technical field of rope manufacturing, in particular to a composite rope and a cable comprising the same.

Background art:

the existing steel wire rope has larger strength and higher durability, but has small elasticity, cannot resist impact load, is hard, cannot bear sharp bending and kinking, is difficult to hold in operation, is easy to slip off from hands, sometimes has broken steel wire ends on the surface of the rope to leak out, and is very easy to prick hands. In addition, the density of the steel cable is high, the weight of the steel cable is heavy, and inconvenience and even danger are often brought when the steel cable is used and operated, so that in some application scenes of high-strength steel cables, a substitute of the steel cable is needed to be found.

In order to solve the problems, the research of replacing a steel wire rope with a high polymer material rope is carried out at present. The UHMWPE material has the advantages of smaller density, extremely high specific strength and specific modulus, good chemical stability, ultraviolet resistance, corrosion resistance and the like, and is widely applied to the bulletproof protection fields of military, public security, frontier defense, armed police and the like and the civil field of high-performance rope netting gear and the like. However, although the ultra-high molecular weight polyethylene fiber rope has high tensile strength, the ultra-high molecular weight polyethylene fiber rope is soft and has poor wear resistance, so that the rope made of the ultra-high molecular weight polyethylene fiber rope has defects in rigidity, bending resistance and wear resistance, and the ultra-high molecular weight polyethylene fiber rope cannot completely replace the existing steel wire rope in special occasions such as a cable-stayed steel cable. In order to solve the problem of wear resistance, chinese patents CN210596791U, CN111962316A, CN112323247A and the like propose solutions, which mainly include adding a wear-resistant layer or a lubricant to the ultra-high molecular weight polyethylene fiber rope, but adding a conventional wear-resistant material will greatly affect the tensile strength of the rope, and adding a lubricant will reduce the cohesive force between the ultra-high molecular weight polyethylene fibers, thereby adversely affecting the performance of the rope. In addition, the insufficient bending resistance causes the application scene of the ultra-high molecular weight polyethylene fiber rope to be limited.

In order to solve the technical problems, the utility model prepares the rope with light weight, high strength, wear resistance and high toughness.

The utility model has the following contents:

the utility model aims to provide a composite rope and a cable comprising the same, aiming at solving the defects of the existing rope in the background technology and preparing the rope with light weight, high strength, wear resistance and high toughness and the cable comprising the same.

The utility model provides a composite rope, which is characterized in that: the rope is formed by weaving or twisting rope yarns and a supporting framework, the rope yarns comprise ultrahigh molecular weight polyethylene fibers and ultrahigh molecular weight polyethylene split fibers, and the diameter of the rope is 4-15 mm.

For the convenience of description, the ultra-high molecular weight polyethylene is hereinafter referred to by its abbreviation UHMWPE.

The rope can be divided into four-stage structures of rope, rope yarn, yarn and fiber, and the UHMWPE fiber and the UHMWPE split fiber are the fourth-stage structure, namely the base material of the rope yarn.

In the present invention, each base level can be twisted or braided to obtain a higher level structure, for example, fibers can be twisted or braided to obtain yarns, yarns can be twisted or braided to obtain rope yarns, and rope yarns can be twisted or braided to obtain a rope. In addition, if the weaving mode is adopted, each basic layer is woven.

For the fourth stage structure fiber, the fiber may be an UHMWPE fiber or an UHMWPE split fiber.

For the third stage structure yarn, the yarn may be a pure UHMWPE fiber yarn made only of UHMWPE fibers; or a pure UHMWPE split fiber yarn made only from UHMWPE split fibers; or a hybrid yarn made of UHMWPE fibers and UHMWPE split fibers.

For the second level structure yarns, the yarns may be pure UHMWPE fibre yarns made only of pure UHMWPE fibre yarns; or pure UHMWPE split fiber yarns made only from pure UHMWPE split fiber yarns; or mixed rope yarn made of mixed yarn; or a mixed rope yarn made of at least two yarns of pure UHMWPE fiber yarn, pure UHMWPE split fiber yarn and mixed yarn.

For the rope with the first-level structure, the rope yarns of the rope are at least two of pure UHMWPE fiber rope yarns, pure UHMWPE split fiber rope yarns and mixed rope yarns; or a rope made entirely of mixed yarns. In addition, in actual use, the number of the hierarchical structures of the ropes can be further adjusted according to actual conditions such as the thickness of the ropes.

Through the hierarchical structure, the rope yarns of the finally manufactured rope are made of the ultra-high molecular weight polyethylene fibers and the ultra-high molecular weight polyethylene split fibers, so that the wear resistance of the UHMWPE rope can be improved, and the tensile strength of the rope is not reduced as much as possible.

The material of the rope yarns of the utility model includes, but is not limited to, UHMWPE fibers and UHMWPE split fibers, and other functional additives or functional materials can be added into the rope yarns to further enhance the performance of the rope.

Furthermore, in the preferable rope structure, the rope yarns at the periphery of the rope are pure UHMWPE split fiber rope yarns, and the rope yarns at the inner part are pure UHMWPE fiber rope yarns. The wear resistance of the UHMWPE split fibers and the high strength performance of the UHMWPE fibers can be fully exerted by adopting the mode.

Further, it is preferred that the yarns used in the rope are all mixed yarns made of UHMWPE fibers and UHMWPE split fibers, and mixing the two fibers from the most basic level results in a more homogeneous rope.

Further, the fibers used in the rope may be composite fibers made by wrapping a bundle of UHMWPE fibers with UHMWPE split fibers, and yarns, ropes and ropes are gradually made from the composite fibers.

Furthermore, the yarns used in the rope may be hybrid yarns made of yarns of pure UHMWPE fibre covered by UHMWPE split fibres, in such a way that the amount of UHMWPE split fibres used is reduced and the effect of the UHMWPE split fibres on the strength of the rope is reduced compared to the way described in the preceding paragraph. On the other hand, if the surface of the rope yarns is coated with the UHMWPE split fibers, the UHMWPE split fibers are in the form of a film, and the contact area between the rope yarns is reduced, which results in a reduction in the cohesive force between the rope yarns. Therefore, it is preferable to use the UHMWPE split fibers to coat the pure UHMWPE yarns at this yarn level to form a hybrid yarn.

The surface of the fiber is coated with the UHMWPE split fiber, so that the wear resistance of the split fiber and the high strength performance of the UHMWPE fiber can be utilized to the maximum extent, the wear resistance of the final rope can be further improved, and the high strength performance of the UHMWPE rope can be maintained.

Preferably, the rope yarn is made of at least three yarns.

Preferably, the supporting framework can be made of materials with certain hardness and bending resistance, such as PET, PP, PA, PE, PPS, epoxy resin, metal and the like.

Preferably, the supporting framework can be formed by a single or a plurality of thin frameworks.

Preferably, the plurality of thin strands are dispersed within the cord.

Compare in single thicker support chassis, many more thin frameworks disperse can make support chassis and rope yarn distribute more evenly in the inside mode of rope, make simultaneously between support chassis and the rope yarn cohesion inseparabler, can effectively avoid slipping between support chassis and the rope yarn.

Preferably, the mass ratio of the supporting framework in the rope is 15-20%.

The modulus and the occupation ratio of the supporting framework are flexibly adjusted according to the use scene, and the utility model is not particularly limited to this.

Preferably, the diameter of the supporting framework is 1-4 mm.

Preferably, the ultrahigh molecular weight polyethylene split fibers account for 50-90% of the mixed yarn by mass. The wear resistance and creep resistance of the rope can be improved by the high content of the ultrahigh molecular weight polyethylene split fibers.

Preferably, the rope yarn has a diameter of 1-3 mm.

Preferably, the diameter of the hybrid yarn is 0.1 to 2 mm.

Preferably, the total content of the ultrahigh molecular weight polyethylene split fibers and the ultrahigh molecular weight polyethylene fibers in the rope is 60-95%.

Preferably, the diameter of the ultrahigh molecular weight polyethylene split fiber yarn is 0.1-1 mm.

Preferably, the fineness of the ultrahigh molecular weight polyethylene split fiber is 800-.

Preferably, the diameter of the ultra-high molecular weight polyethylene fiber yarn is 0.1-1 mm.

Preferably, the titer of the ultra-high molecular weight polyethylene fiber is 300-1600D.

Preferably, the diameter of the rope is preferably 5-10 mm.

Preferably, the breaking strength of the rope is 20-40 KN.

Further, the utility model also provides a composite cable, which is characterized in that: the cable is formed from a plurality of individual ropes as described above in a further twisted or braided manner.

Preferably, the number of strands of the cable produced by twisting is 3, 4, 6, etc.

Preferably, the number of strands of the cable produced by weaving is 8, 12, 16, 24, etc.

Preferably, the diameter of the cable is 15-50 mm.

Preferably, the breaking strength of the cable is 100-900 KN.

The cable can replace the steel wire rope in practical application.

Compared with the prior art, the utility model has the following beneficial effects:

the composite rope is formed by compounding three materials, namely ultrahigh molecular weight polyethylene split fibers, ultrahigh molecular weight polyethylene fibers and a supporting framework, wherein the supporting framework provides bending resistance, the ultrahigh molecular weight polyethylene fibers improve the strength of the rope, and the ultrahigh molecular weight polyethylene split fibers strengthen the wear resistance of the rope. Because the ultrahigh molecular weight polyethylene split fibers have excellent wear resistance and the strength is close to that of the UHMWPE fibers, the UHMWPE split fibers and the UHMWPE fibers are mixed and braided into the rope, the wear resistance of the rope can be effectively increased, and the high strength of the ultrahigh molecular weight polyethylene rope can be kept as far as possible, which is difficult to achieve by other wear-resistant fibers. The rope with light weight, high strength, wear resistance and high toughness is prepared by compounding the three materials and utilizing the properties of the materials.

According to the scheme provided by the utility model, a cable is prepared by twisting or weaving a plurality of ropes, and the cable can replace a steel wire rope in practical application. Compared with a steel wire rope, the cable rope provided by the utility model greatly reduces the weight of the rope, and improves the convenience and safety in operation and construction.

Description of the drawings:

the present invention will now be described in connection with certain preferred embodiments with reference to the following illustrative figures. It is emphasized that this description is provided to enable those skilled in the art to make clear how the several forms of the utility model may be embodied and practiced and not limited to the specific figures set forth.

Fig. 1 is a cross-sectional view of a rope.

Fig. 2 is a cross-sectional view of a rope yarn.

Fig. 3 is a cross-sectional view of a cable.

Fig. 4 is a perspective view of the cable.

In fig. 1, 11 is pure UHMWPE fiber rope yarn, 12 is pure UHMWPE split fiber rope yarn, and 13 is a supporting skeleton.

Fig. 2A is a pure UHMWPE fiber rope yarn made from pure UHMWPE fiber yarns;

FIG. 2B is a pure UHMWPE split fiber rope yarn made from pure UHMWPE split fiber yarn;

FIG. 2C is a rope yarn made of a mixture of UHMWPE fiber yarn and UHMWPE split fiber yarn;

fig. 2D shows a rope yarn made of UHMWPE fiber yarn, UHMWPE split fiber yarn and hybrid yarn.

The specific implementation mode is as follows:

example 1

The utility model provides a composite rope, which comprises the following specific manufacturing steps:

s1: respectively twisting 1600D ultra-high molecular weight polyethylene fiber and 3600D ultra-high molecular weight polyethylene film-split fiber to obtain ultra-high molecular weight polyethylene fiber yarn with the diameter of 0.6mm and ultra-high molecular weight polyethylene film-split fiber yarn with the diameter of 0.8mm, wherein the twist number is 25T/m, and the twist direction is S. Here, the ultra-high molecular weight polyethylene fiber yarn may be an ultra-high molecular weight polyethylene fiber without twisting.

And (3) slowly passing the twisted yarns through a glue pool, soaking the twisted yarns in waterborne polyurethane orange glue for 30s, and extruding the redundant glue through a yarn hole with the diameter being less than 20% of the twisted yarn diameter. And drying the yarn impregnated with the glue water by a constant-temperature oven at 50 ℃ and then rolling again, wherein the drying time is 2 min.

S2: respectively twisting 3 ultrahigh molecular weight polyethylene fiber yarns and 3 ultrahigh molecular weight polyethylene split fiber yarns to obtain ultrahigh molecular weight polyethylene fiber rope yarns with the diameter of 1.5mm, wherein the cross section is shown in figure 2A, and the cross section is shown in figure 2B. Wherein the twist number is 25T/m during twisting, and the twist direction is S.

S3: 4 PET round filaments with the diameter of 1mm and the fineness of 9600D are used as a supporting framework, 7 ultra-high molecular weight polyethylene fiber rope yarns and 11 ultra-high molecular weight polyethylene film-split fiber rope yarns are twisted together to prepare a rope with the diameter of 8mm, the breaking strength of 30KN and the breaking friction times of 600 times, the cross-sectional view is shown in figure 1, 11 in the figure is a pure UHMWPE fiber rope yarn, 12 is a pure UHMWPE film-split fiber rope yarn, and 13 is a supporting framework. Wherein the lay length of the rope is 56mm, and the lay direction is Z.

Example 2

The composite rope provided by the utility model can be prepared in the following way:

s1: the ultra-high molecular weight polyethylene fiber with the fineness of 1600D and the ultra-high molecular weight polyethylene split fiber with the fineness of 3600D are mixed and twisted to prepare a mixed yarn with the diameter of 1mm, wherein the ultra-high molecular weight polyethylene fiber accounts for 30 wt%, the ultra-high molecular weight polyethylene split fiber accounts for 70 wt%, the twist is 25T/m, and the twist direction is S.

And (3) slowly passing the twisted yarns through a glue pool, soaking the twisted yarns in waterborne polyurethane orange glue for 30s, and extruding the redundant glue through a yarn hole with the diameter being less than 20% of the twisted yarn diameter. And drying the yarn impregnated with the glue water by a constant-temperature oven at 50 ℃ and then rolling again, wherein the drying time is 2 min.

S2: twisting 3 mixed yarns to prepare mixed rope yarns with the diameter of 2mm, wherein the twist number is 25T/m, and the twisting direction is S.

S3: 4 PET round filaments with the diameter of 1mm and the fineness of 9600D are used as a supporting framework and twisted together with 18 mixed rope yarns to prepare a rope with the diameter of 8mm, the breaking strength of 26KN and the breaking friction times of 750 times, wherein the lay length is 56mm, and the lay direction is Z.

Example 3

The composite rope provided by the utility model can be prepared in the following way:

s1: respectively twisting 1600D ultra-high molecular weight polyethylene fiber and 3600D ultra-high molecular weight polyethylene split fiber to prepare ultra-high molecular weight polyethylene fiber yarn with the diameter of 0.6mm and ultra-high molecular weight polyethylene split fiber yarn with the diameter of 0.8mm, wherein the twist is 25T/m, and the twist direction is S.

And (3) slowly passing the twisted yarns through a glue pool, soaking the twisted yarns in waterborne polyurethane orange glue for 30s, and extruding the redundant glue through a yarn hole with the diameter being less than 20% of the twisted yarn diameter. And drying the yarns impregnated with the glue water by a constant-temperature oven at 50 ℃, and then rolling again, wherein the drying time is 2 min.

S2: the 1 ultra-high molecular weight polyethylene fiber yarn and the 2 ultra-high molecular weight polyethylene split fiber yarns are mixed and twisted to prepare a mixed fiber rope yarn with the diameter of 2mm, and the cross section is shown in fig. 2C. Wherein the twist number is 25T/m during twisting, and the twist direction is S.

S3: 4 PET round filaments with the diameter of 1mm and the fineness of 9600D are used as a supporting framework and twisted together with 18 mixed fiber rope yarns to prepare a rope with the diameter of 8mm, the breaking strength of 34KN and the breaking friction times of 710 times, wherein the lay length is 56mm, and the lay direction is Z.

Example 4

The composite rope provided by the utility model can be prepared in the following way:

s1: 1) respectively twisting ultra-high molecular weight polyethylene fiber with the fineness of 1600D and ultra-high molecular weight polyethylene split fiber with the fineness of 3600D to prepare ultra-high molecular weight polyethylene fiber yarn with the diameter of 0.6mm and ultra-high molecular weight polyethylene split fiber yarn with the diameter of 0.8 mm;

2) the ultra-high molecular weight polyethylene fiber with the fineness of 1600D and the ultra-high molecular weight polyethylene split fiber with the fineness of 3600D are mixed and twisted to prepare a mixed yarn with the diameter of 0.8mm, wherein the ultra-high molecular weight polyethylene fiber accounts for 30 wt%, and the ultra-high molecular weight polyethylene split fiber accounts for 70 wt%.

Wherein, the twist number is 25T/m and the twist direction is S.

And (3) slowly passing the twisted yarns through a glue pool, soaking the twisted yarns in waterborne polyurethane orange glue for 30s, and extruding the redundant glue through a yarn hole with the diameter being less than 20% of the twisted yarn diameter. And drying the yarn impregnated with the glue water by a constant-temperature oven at 50 ℃ and then rolling again, wherein the drying time is 2 min.

S2: the 1 ultrahigh molecular weight polyethylene fiber yarn, the 1 ultrahigh molecular weight polyethylene split fiber yarn, and the 1 mixed yarn were twisted together to produce a mixed fiber rope yarn with a diameter of 2mm, and a cross-sectional view is shown in fig. 2D. Wherein the twist number is 25T/m during twisting, and the twist direction is S.

S3: 4 PET round filaments with the diameter of 1mm and the fineness of 9600D are used as a supporting framework and twisted together with 18 mixed fiber rope yarns to prepare a rope with the diameter of 8mm, the breaking strength of 33KN and the breaking friction times of 550 times, wherein the lay length is 56mm, and the lay direction is Z.

Example 5

The utility model also includes that 1 rope prepared in the example 1 is used as a core, 6 ropes are used as strands to prepare a rope with the diameter of 26mm, the breaking strength of 280KN and the breaking friction times of 7500 times in a twisting mode, the cross section is shown in figure 3, and the perspective view is shown in figure 4. Wherein the lay length of the cable is 175mm, and the lay direction is Z. The breaking strength of the cable prepared by the method reaches the strength of a common steel wire rope, and the cable also has certain bending resistance compared with a polymer rope, and can replace the steel wire rope in practical application.

Example 6

The utility model also comprises 8 strands of the rope obtained in example 1 braided into a rope having a diameter of 29mm, a breaking strength of 300KN and a number of rubbings at break of 7000, with an intercept of 186mm and a lay direction of Z.

The utility model provides a composite rope and a cable prepared from the rope. Compared with the steel wire rope, the material is soft, is not easy to hurt people, and has high strength; compared with the rope made of the ultra-high molecular weight polyethylene fiber, the rope has certain hardness and good wear resistance; the added supporting framework can well improve the bending resistance of the rope. The rope does not need any protective measures in actual use, and can be widely applied to the fields of high-end protection and rope nets.

While the utility model has been described with reference to preferred embodiments, it will be understood by those skilled in the art that various modifications and combinations can be made to the utility model without departing from the scope of the utility model.

Claims (7)

1. A composite rope, characterized by: the rope is formed by weaving or twisting rope yarns and a supporting framework, the rope yarns comprise UHMWPE fibers and UHMWPE split fibers, and the diameter of the rope is 4-15 mm.

2. A composite rope according to claim 1, characterized in that: the mass ratio of the support framework in the rope is 15-20%.

3. A composite rope according to claim 1, characterized in that: the rope yarn is made of yarn.

4. A composite rope according to claim 3, characterized in that: the yarns are pure UHMWPE fiber yarns made of UHMWPE fibers; or the UHMWPE split fibers are made into pure UHMWPE split fiber yarns; or a hybrid yarn made of a mixture of UHMWPE fibers and UHMWPE split fibers.

5. A composite rope according to claim 4, characterized in that: the rope yarn is a pure UHMWPE fiber rope yarn made of pure UHMWPE fiber yarn only; or pure UHMWPE split fiber yarns made only from pure UHMWPE split fiber yarns; or a mixed rope yarn made entirely of UHMWPE fibers and UHMWPE split fibers; or a mixed rope yarn made of at least two yarns of pure UHMWPE fiber yarn, pure UHMWPE split fiber yarn and mixed yarn.

6. A composite rope according to claim 4, characterized in that: the mixed yarn is made of UHMWPE split fiber coated pure UHMWPE fiber yarn.

7. A composite rope, characterized by: the cable is formed by a plurality of ropes according to any one of claims 1-6, further twisted or braided.

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