JP5454891B2 - Fiber rope - Google Patents

Description

  The present invention relates to a drive fiber rope for house curtains used at high loads, long distances, and long strokes, and a fiber rope applicable as a moving rope for industrial machinery.

  For example, a drive rope for a house curtain is generally a small rope with a rope diameter of less than 4 mm, the rope length is up to 100 m, the stroke is up to 8 m, and the entire length is extended via a small diameter drum and a number of small diameter guide rollers. It is under severe conditions where tension and bending act. In addition, when installing the drive rope, the rope is twisted at an angle greater than expected to avoid various obstacles in the greenhouse, and a force acts in the direction of sudden pulling or contracting to pull the rope. It is.

  Conventionally, wire ropes made of steel wire have been used for house curtain drive ropes in the past, and they have very little elongation. In this respect, it is satisfactory, but in situations where they are used at high loads, long distances, and long strokes. Originally, bending fatigue durability is not sufficient, and frequent replacement is required.

  On the other hand, a resin fiber rope is also used, and a double-structure fiber rope having a core fiber layer and an outer braided fiber layer covering the core fiber layer is common. Double-structure fiber ropes have excellent bending fatigue durability due to simple bending, but the rope cross-section is soft under the conditions of high load, long distance, and long stroke, and the drum and sheave It is out of shape at the contact surface, has a large elongation, and requires frequent rewinding.

  In general, fiber ropes with a high core fiber layer ratio are widely used as ropes that are made of hard rope to prevent the deformation of the resin fiber ropes. A so-called pop-out phenomenon that protrudes outward from the gap of the stitches of the layer is likely to occur. On the other hand, a fiber rope having a low ratio of the core fiber layer is also common, but at present, the absolute strength is small and the elongation is large.

  In addition, the fiber ropes shown in the following Patent Document 1 and Patent Document 2 that have been put to practical use as high-strength fiber ropes for moving ropes have a very high ratio of the core fiber layers, and the structure of the core fiber layers is devised. The absolute strength is very high with this technology, which is perfect in this respect, but it is loosely tied to prevent the core fiber layer from popping out. The collapse property is not enough.

JP 11-293574 A JP 2002-60163 A

  The present invention has been made in view of the above problems, and the core fiber layer jumps and drums even under severe conditions in which tension and bending act over the entire length via a small-diameter drum and a large number of small-diameter guide rollers. An object of the present invention is to provide a fiber rope which prevents occurrence of deformation of the surface per sheave and has high elongation with little elongation with respect to load.

In order to achieve the above object, the present invention has a core fiber layer and an outer braided fiber layer covering the core fiber layer, and the total cross-sectional area of the core fiber layer and the outer braided fiber layer is divided by the apparent apparent cross-sectional area. The value obtained by multiplying the obtained value by 100 is defined as the effective cross-sectional area ratio (%), and the value obtained by dividing the cross-sectional area of the core fiber layer by the total cross-sectional area of the rope including the outer braided fiber layer is multiplied by 100. In the figure defined as the fiber layer content (%) and showing the relationship between the effective cross-sectional area ratio and the core fiber layer content shown as FIG. 1 in the accompanying drawings, in the region surrounded by A, B and C shown below There is provided a fiber rope characterized by having an effective cross-sectional area ratio and a core fiber layer content ratio.
A: Effective area ratio = 53%, core fiber layer content ratio = 40%, B: Effective area area ratio = 66%, Core fiber layer content ratio = 40%, C: Effective area area ratio = 53%, Core fiber Layer content = 56.25%.

  The present inventor analyzed the jumping mechanism of the core fiber layer of the resin fiber rope, and when a local bending is applied to the rope, if the material is very elastic such as a rubber string, the outer side is subjected to tensile stress. Thus, the compressive stress acts on the inner side and the inner side contracts, and the cross-sectional shape and the cross-sectional area of the local bending portion are substantially maintained. On the other hand, when local bending is applied to a rope using multi-fibers, the fiber on the outer periphery of the core fiber layer does not stretch even if a tensile stress is applied, causing a phenomenon of being driven into the bent portion. At the same time, it was confirmed that the volume of the core fiber layer in the bent portion was greatly increased compared to that before the bending because the space volume that could exist in the inner multi-fiber was decreased by bending. The state where the locally bent portion of the vinyl hose used for household use collapses and spreads sideways is spread out sideways (the vinyl hose has no core). Next, when local bending is applied to the outer braided fiber layer, the circumference of the inner side of the bend is reduced compared to before bending, and the outer side is further driven into the inner periphery of the previous core fiber layer. As a result, it was confirmed that the braided fiber was excessive and the stitches were loosened. If the volume of the core fiber layer is greatly increased and the stitches of the outer braided fiber layer are loosened, the core fiber layer easily protrudes there.

  Many conventional ropes have been developed with a limited element technology that uses flex fatigue durability, flexibility, or high elastic fibers to improve elongation and strength, but the core fiber layer content and effective Focusing on the cross-sectional area ratio, improving the cross-sectional hardness of the rope to prevent the deformation of the drum / sheave contact surface, resulting in a fiber rope with a high overall balance that has little elongation with respect to load and high strength. This is a new finding of the present inventors that has not been studied.

  In the present invention, the fiber rope prevents the core fiber layer from jumping out and out of shape even under severe conditions in which tension and bending act over the entire length, and has a low elongation and high strength against the load. For this reason, the optimum ranges of the core fiber layer content and the effective cross-sectional area ratio have been found.

Moreover, this invention provides the fiber rope characterized by an outer diameter being less than 4 mm.
The drive fiber rope for house curtain, which is subjected to tension and bending over the entire length via a small-diameter drum and a large number of small-diameter guide rollers, is preferably a small-diameter rope having an outer diameter of less than 4 mm.

In addition, the present invention shows a value obtained by dividing the recorded length of the rope when the rope is tensioned to 25 kgf by a tensile tester and dividing the result by the base rope length and multiplying by 100. A fiber rope characterized by having a "25 kgf load elongation" of 3% or less is provided.
By having the effective area ratio and the core fiber layer content in the specific region, it is possible to obtain a fiber rope that has little elongation with respect to the load.

In addition, the present invention provides a fiber rope characterized in that the braided outer fiber layer is 16 beats.
With 8 shots, the mesh structure is coarse, making it difficult to secure the core fiber layer pop-out property. With 24 shots, there is a problem that the price is expensive and impractical.

  The fiber rope of the present invention has a core fiber layer jump-out and a drum / sheave surface mold even under severe conditions where tension and bending act over the entire length via a small-diameter drum and a large number of small-diameter guide rollers. Prevents the occurrence of collapse, has little elongation with respect to load, and has high strength.

It is a graph which shows the relationship between the effective area of a fiber rope, and a core fiber layer content rate. An embodiment of the fiber rope of the present invention is shown, (a) is a side view, (b) is a sectional view.

  Hereinafter, although the embodiment of the fiber rope of the present invention is described, the present invention is not limited to the following embodiment.

  The fiber rope of the present invention has a structure of a core fiber layer and an outer braided fiber layer covering the core fiber layer. The drive fiber rope for house curtains used at high loads, long distances, and long strokes is subjected to severe conditions in which tension and bending act over the entire length via a small-diameter drum and a large number of small-diameter guide rollers. Under such conditions, the fiber rope has a high strength and a low elongation with a low elongation with respect to the load, suppressing the occurrence of a jump-out phenomenon and a loss of shape when the core fiber layer protrudes through the gap between the stitches of the outer braided fiber layer. As a result of studying the above, it has been achieved by focusing on the effective area ratio and the core fiber layer content shown below, and setting these values as values in a specific range.

  Effective cross-sectional area ratio (%): A value obtained by multiplying a value obtained by dividing the total cross-sectional area of the core fiber layer and the outer braided fiber layer by the apparent cross-sectional area of the rope by 100.

  Core fiber layer content (%): A value obtained by dividing the value obtained by dividing the cross-sectional area of the core fiber layer by the total cross-sectional area of the rope including the outer braided fiber layer by 100.

FIG. 1 shows a graph showing the relationship between the effective area of the fiber rope and the core fiber layer content. In FIG. 1, by using a fiber rope having an effective cross-sectional area ratio and a core fiber layer content ratio in a triangular region surrounded by A, B, and C shown below, a small-diameter drum and a large number of small-diameter guide rollers are used. Thus, even under severe conditions where tension and bending act over the entire length, it is difficult for the core fiber layer to jump out or lose its shape, and it has a low elongation and high strength with respect to the load.
A: Effective area ratio = 53%, core fiber layer content = 40%,
B: Effective area ratio = 66%, core fiber layer content = 40%,
C: Effective area ratio = 53%, core fiber layer content = 56.25%.

  The reason for setting the effective area ratio to 53% or more and 66% or less is that if the rope is less than 53%, the rope is loose and easily loses its shape, and tends to be initially stretched. This is because breakage or the like is likely to occur, and the stringing property is deteriorated, which is not practical, and the rope is harder and the core fiber layer is likely to jump out.

  The reason why the core fiber layer content is set to 40% or more and 56.25% or less is that if it is less than 40%, the volume and effective cross-sectional area of the core fiber layer that bears the tensile stress are insufficient, and the initial elongation tends to be long. When the strength exceeds 56.25%, the volume of the outer braided fiber layer is insufficient even if the mesh structure is fine, and the core fiber layer is likely to jump out, which is effective to prevent this. This is because when the cross-sectional area ratio is lowered from 53%, the shape loss and initial elongation are likely to occur.

  Rope with an effective cross-sectional area of 53% or more is commonly found as a rope made of hard rope to prevent the deformation of the rope made of resin fiber, but the core fiber layer jumps out due to local bending. Since it tends to occur, it is common to use a rope with a low core fiber layer content of less than 40% based on experience, and the current situation is that the absolute strength is small and the elongation is large. .

  Further, the fiber ropes shown in Patent Document 1 and Patent Document 2 that have been put to practical use as high-strength fiber ropes for moving cords have a core fiber layer content exceeding 50% and a very high core fiber layer content. In addition, the absolute strength is very high with the technology to devise the structure of the core fiber layer, but the effective area is less than 53% for the purpose of preventing the core fiber layer from jumping out. In this case, the initial stretch and the drum and sheave contact surfaces are not sufficient in terms of shape loss.

  In FIG. 2, sectional drawing and side view of one Embodiment of the fiber rope of this invention were shown. The fiber rope of this embodiment has a core / outer layer double core having a core fiber layer 2 composed of 14 bundles of fiber bundles 21 and 16 striking outer braided fiber layers 3 covering the core fiber layer 2 in the drawing. Structure. Since the fiber bundles 21 of the core fiber layer 2 are strongly hardened, the cross-sectional shape is actually crushed as shown in the figure. Further, the braided outer fiber layer 3 is knitted with 16 right-handed yarns and 8 left-handed yarns intersecting to make 16 strokes.

  The fiber used is a well-known aramid fiber, ultra-high, if the spun yarn, composite elastic yarn or braided part with greatly different mechanical properties, such as extremely large stretch and compression properties of the material, are not post-processed and fused. Multi-fibers such as molecular weight polyethylene fiber, polyarylate fiber, polyamide fiber, polyester fiber, polyvinyl alcohol fiber, polyethylene fiber, polypropylene fiber, and polyvinyl chloride fiber can be used in the core fiber layer and the outer braided fiber layer in total or in combination. The fibers of the core fiber layer and the outer braided fiber layer may be different or the same fiber may be used. As a driving rope for house curtains, it is practical to use polyester fiber that has the basic properties of strength and elongation among the above-mentioned fibers, has excellent environmental characteristics such as weather resistance and moisture absorption stability, and is relatively inexpensive. And preferred.

  When applied as a drive curtain for a house curtain, it is preferably used as a small-diameter rope having a rope diameter of less than 4 mm because it is used with a high load, a long distance and a long stroke via a small-diameter drum and a large number of small-diameter guide rollers. .

  It is preferable that the outer braided fiber layer has 16 strokes. For example, since the mesh structure is coarse at 8 strokes, the triangular region surrounded by A, B and C of the core fiber layer content rate and the effective cross-sectional area ratio shifts to the lower left in order to ensure the core fiber layer pop-out property. There is a risk of insufficient strength and excessive growth. On the other hand, it is thought that the mesh structure becomes fine with 24 strikes, and the core fiber layer pop-out performance exceeds 16 strikes. However, in order to implement 24 strikes, the price of a rope with the same diameter as the introduction of an expensive 24 striker However, considering the use of expensive thin fiber bundles, there is a risk that the cost will be high.

(Example)
1. Creation of Fiber Rope A rope having the specifications shown in Table 1 was created using Teijin Fibers' polyester multi-fiber (high strength grade).

The cross-sectional area of the fiber layer is
Cross-sectional area (square mm) = fineness (dtex) ÷ [fiber specific gravity × 10000]
Calculated by

A reference example is a sample No. 1 rope described in JP-A-11-293574 (Patent Document 1).

2. Rope test (1) Tensile strength:
The recorded maximum strength was measured when the rope was pulled at 100 mm / min with a tensile tester and tested to the point of breaking.
(2) 25 kgf load elongation:
When the rope was pulled with a tensile tester and reached approximately 25 kgf, the recorded stretch length of the rope was divided by the base rope length, and the stretch amount indicated by a factor of 100 was measured. 25 kgf is about 1/10 of the breaking strength of the rope, and is an average tension used as a drive rope for house curtains.
(3) Shape retention at 25 kgf load:
The outer diameter of the rope around the steel pipe is 180 ° opposite to the direction of tension when the rope is half-rounded on a steel pipe with a diameter of 34 mm and one end of the rope is pulled almost to a balance of 25 kgf with a tensile tester. Was measured, and the amount of deformation indicated by a 100-fold value divided by the base rope diameter was measured.
(4) Core fiber protrusion property:
Grabbing the rope with fingers at intervals of about 20 mm, twisting and kinking, repeating repeated compression and pulling from the longitudinal direction, and bending locally as it is for about 30 seconds continuously, the core fiber layer is the outer braided fiber layer The case where it was not observed by visually observing was marked with ◯, and the case where it was ejected was marked with x.

Table 2 shows the results of the above tests performed on the ropes shown in Table 1.

  In addition, the breaking strength of a reference example is a literature description value.

  It has been shown that the breaking strength almost depends on the size of the fineness of the core fiber layer (representing the “thickness” of the yarn). In Examples, the range is 260 to 310 kgf, whereas in Comparative Examples 1 to 4 in which the core fiber layer content (%) is less than 40%, the range is 160 to 235 kgf, and particularly the core fiber fineness. The smallest Comparative Example 1 had the lowest core fiber layer content and the lowest breaking strength. With the same core fiber fineness, it was speculated that a rope with a high effective cross-sectional area ratio could be made uniform in the rope of the fiber bundle, and the breaking strength tended to be slightly higher.

  The 25 kgf load elongation tends to decrease as the effective area and the core fiber layer content increase. Moreover, even if the ropes have the same core fiber layer content, the elongation tends to increase as the effective area ratio decreases. The 25 kgf load elongation of the Example showed 2.3 to 3.0%. On the other hand, in Comparative Example 1 where the effective area was 48.1% and the core was loose, the elongation was very large, showing 6.7%. The portion responsible for 25 kgf load elongation is considered to depend on the core fiber layer as well as the breaking strength, and the effective cross-sectional area ratio is improved when the outer fiber layer is braided with the slack in the rope longitudinal direction of the core fiber layer. Although the present invention aims at the effect of suppressing by removing together, there is a limit to the improvement of the effective area ratio, and Examples 1, 5 and Comparative Examples 5, 6 and 7 showed a nearly flat state.

  It can be seen that the shape retention at 25 kgf load almost depends on the effective area ratio. Even if the core fiber layer content was small as in Comparative Example 2, there was no effect, and it was presumed that even a rope with a high core fiber layer content would easily lose its shape if it was loosely stringed.

  As shown in Comparative Examples 5 and 6, the core fiber pop-out property was shown to be easy to pop out when the effective cross-sectional area ratio is high and the core fiber layer content is large. It is recognized that it does not occur when either one is low.

  It can be seen that the examples according to the present invention are fiber ropes having a 16-ply braided outer fiber layer that have a very high balance of the high strength, low elongation, and shape loss resistance required for the rope.

  The fiber rope of the present invention can be used as a drive fiber rope for house curtains used at high loads, long distances, and long strokes, and as a moving rope for industrial machinery.

1: Fiber rope 2: Core fiber layer 21: Fiber bundle 3: Outer braided fiber layer

Claims (4)

A core fiber layer and an outer braided fiber layer covering the core fiber layer, and an effective cross-sectional value obtained by multiplying a value obtained by dividing the total cross-sectional area of the core fiber layer and the braided outer fiber layer by the apparent apparent cross-sectional area by 100 The value obtained by dividing the cross-sectional area of the core fiber layer by the total cross-sectional area of the rope including the outer braided fiber layer by 100 times is defined as the core fiber layer content (%). In the figure which shows the relationship between the effective cross-sectional area ratio shown as FIG. 1 in an accompanying drawing, and a core fiber layer content rate, the effective cross-sectional area ratio and core fiber layer content rate in the area | region enclosed by A, B, and C shown below are shown. Fiber rope characterized by having:
A: Effective area ratio = 53%, core fiber layer content = 40%,
B: Effective area ratio = 66%, core fiber layer content = 40%,
C: Effective area ratio = 53%, core fiber layer content = 56.25%.   The fiber rope according to claim 1, wherein an outer diameter is less than 4 mm.   “25 kgf load elongation” expressed as a value obtained by dividing the recorded rope elongation by the base rope length and multiplying by 100 when the rope is pulled to the approximate balance of 25 kgf with a tensile tester. The fiber rope according to claim 2, wherein the content is 3% or less.   The fiber rope according to any one of claims 1 to 3, wherein the outer braided fiber layer is 16 beats.

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