JP3480865B2 - Composite elastic fiber rope - Google Patents

Description

Detailed Description of the Invention

[0001]

FIELD OF THE INVENTION The present invention relates to a composite elastic fiber rope.

[0002]

2. Description of the Related Art Measuring instruments, observation instruments, and photographing instruments (hereinafter referred to as measuring instruments) for ocean observation, underwater and underwater exploration, etc. are high-performance instruments using electronic technology. As an observation method using such a measuring instrument, for example, a system as shown in FIG. 1 is adopted.
That is, the first rope 110, which is a wire rope, is lowered from the ship 100a, the float or buoy 100b that floats above the water, or the underwater buoyancy object 100c, and the underwater damper 120 that has the ability to absorb vibrations due to waves and tidal currents. To connect the underwater damper 120 and the measuring device 130 to a second rope 140 composed of a wire rope.
Are connected to each other, and in this state, the first rope 110 is positioned at a fixed point or towed while the measurement device 130 performs observation and exploration. 160 is an anchor. In such a system, since the underwater damper 120 absorbs vibration due to expansion and contraction, it is possible to perform favorable measurement and the like. However, when the underwater damper 120 is damaged for some reason and separated from the first rope 110, Expensive measuring device 13
0 will be leaked. Therefore, in order to prevent such troubles, the first rope 110 and the second rope 14
An auxiliary rope 15 is used to connect between 0s. As the auxiliary rope 15, so-called super fiber (high-performance fiber) having high strength and high elastic modulus is conventionally used. The super fiber has an advantage that it is strong even if it has a small diameter and is lightweight, but on the other hand, since it has a high elastic modulus, it does not extend so much that the underwater damper 120 is damaged and the auxiliary rope 15 has a shocking tensile force. It has a low ability to mitigate it when it acts. For this reason, a very large impact force is directly applied to the measuring device 130, which causes the measuring device 130 to
There was a great risk of damaging or destroying the precision components of the.

The present invention was made by research to solve the above-mentioned problems, and the first purpose thereof is to exert a good vibration absorbing function and to exert an impact tensile load. An object of the present invention is to provide a composite elastic fiber rope that can reliably receive the impact force after absorbing it. A second object of the present invention is to provide a composite elastic fiber rope capable of smoothly absorbing impact force in multiple stages and smoothly shifting to the final load receiving. INDUSTRIAL APPLICABILITY The present invention is suitable as an auxiliary rope for the above-mentioned underwater exploration and ocean observation, and can be widely used for hanging ropes, towing ropes, etc. of various objects that are likely to suffer performance deterioration or damage due to vibration or impact.

[0004]

In order to achieve the above-mentioned first object, the first invention is an elastic yarn alone or an elastic yarn for general purpose fibers.
A fiber having a lower elongation and a higher tensile strength than the outer layer braided rope is provided in the inner tubular hollow portion of the outer layer braided rope braided by using a high elongation fiber having a fiber elongation of 200% or more. The inner layer braided rope that is braided and has a length dimension larger than that of the outer layer braided rope is stored. In order to achieve the second object, the second invention is elastic.
Elongation of general-purpose fiber mixed with single thread or elastic thread is 2
An outer layer braided rope braided using high elongation fiber of 00% or more, and a plurality of outer layer braided ropes having a lower elongation and higher tensile strength than the outer layer braided rope and having a larger length dimension than the outer layer braided rope. An inner layer braided rope consisting of braided ropes is provided, and each of the braided ropes has a different elongation and a different tensile strength, and a relatively low elongation and a high tensile strength has a relatively long dimension, elongation is low braided rope high tensile strength is connected at both ends to successively higher braided rope relatively elongation of tensile strength lower than this, the inner tubular entire inner braided rope in this state the outer braided rope It is configured to be housed in the cavity .

In the second invention, the inner layer braided rope is the first
And the second two braided ropes, or the first to third three braided ropes. In the first invention and the second invention, the outer layer braided rope is constituted by strands or yarns made of elastic yarn alone or mixed with raw yarns of general-purpose fibers. The inner layer braided rope has a strand or yarn composed of raw material yarn of high strength and high elastic modulus fiber or general-purpose synthetic fiber. In the first invention and the second invention, the inner layer braided rope is stored in the outer layer braided rope by pulling the outer layer braided rope to the same length as the inner layer braided rope to fasten the inner layer braided rope, and then pulling the outer layer braided rope. The inner layer braided rope may be bent in a wavy shape by restoring the original length dimension by unloading. Alternatively, the inner layer braided rope may be formed by forming U-turn-shaped folds at predetermined intervals, and the inner layer braided rope may be pushed into the outer layer braided rope for storage. Furthermore, the inner layer braided rope may be compressed in the axial direction to increase the braid angle to shorten the length dimension, and may be pushed into the outer layer braided rope for storage. Further, in the second invention, the plurality of braided ropes forming the inner layer braided rope may be parallel to each other, or may be a nesting type in which the inner braided rope is housed in the outer braided rope. Good.

[0006]

In both the first and second inventions, since the outer layer braided rope 2 and the inner layer braided rope 3 both have a braided structure, no kink occurs, neither rotation nor twist occurs, and flexibility is good. It has the basic property of having a moderate elongation at break. And in the first invention,
When a load is applied, as shown in FIG. 12 (a), the outer layer braided rope 2 which had been in the shortened length l until then extends in accordance with the magnitude of the load, and the inner layer braided rope 3 gradually extends in the bent state. Be done. However, since the inner layer braided rope 3 is slack until the outer layer braided rope 2 reaches the total length L of the inner layer braided rope 3, the outer layer braided rope 2 does not take strength, and the outer layer braided rope 2 responds exclusively to the load with its own tensile strength. If the load is removed or reduced during this period, the original length l is restored. Then, when the load is large and the outer layer braided rope 2 extends to reach the total length L of the inner layer braided rope 3 as shown in FIG. 12 (b), the load is applied to the inner layer braided rope 3 for the first time, and the inherent elongation and large It is responsible for the applied load due to its tensile strength. In the case of a high-strength, high-modulus fiber or a general-purpose fiber rope, a steep angle load as shown by the curve Ra in FIG.
Due to the elongation property, shock stress is generated. Also,
In the case of only the high elongation fiber rope, the load-elongation characteristic is too gentle and sufficient strength cannot be obtained as shown by the curve Rb in FIG. On the other hand, in the first invention, due to the combined effect of the outer layer braided rope 2 and the inner layer braided rope 3, the elongation is large in the low load region as shown by the curve R in FIG. It is one of the characteristics that the strength of is demonstrated. And the elongation property (absolute amount of elongation) in the predetermined load range is stored in the inner layer braided rope 3
Since it can be freely set by adjusting the length L, the vibration and shock load can be smoothly absorbed.

In the second aspect of the present invention, two or more inner layer braided ropes having a lower elongation and a higher tensile strength and a length dimension larger than that of the outer layer braided rope are provided in the outer layer braided rope having a high elongation. The inner layer braided rope having a relatively high elongation and a relatively low tensile strength has a shorter length dimension. Therefore, when a load is applied from the state where the total length is l as shown in (a) of FIG. 21, the outer layer braided rope extends, but in the case of two inner layer braided ropes, for example, the first and second
Since the inner layer braided rope of (1) is longer than the outer layer braided rope, no load is applied. As shown in Fig. 21 (b), the elongation of the outer layer braided rope is the length L of the second inner layer braided rope.
_When it reaches ₂ , the second inner layer braided rope takes on the load. The second inner layer braided rope has a higher tensile strength than the outer layer braided rope, and the rope length returns between L ₂ and l when the load is reduced. When the second inner layer braided rope is stretched by the load and the length reaches the length L ₁ of the first inner layer braided rope as shown in FIG. 21 (c), the load is applied to the first inner layer braided rope for the first time here. Since the first inner layer braided rope has low elongation and high tensile strength, it can reliably bear the load. Since the elongation and the strength change in a plurality of steps in this way, the load-elongation characteristic becomes as shown in FIG. 20 in the case of the second invention, and the load absorption degree is made smoother than in the case of the first invention. You can smoothly transition to the final strength. In FIG. 20, Ra is a high strength and high elastic modulus fiber rope, Rb is a high elongation fiber rope, and Rc is each load-elongation characteristic of a general purpose fiber rope. Also in this second invention,
The elongation characteristic (absolute amount of elongation) in the predetermined load range can be freely set by adjusting the lengths L ₁ , L _2, ... Of the plurality of inner layer braided ropes to be stored.

[0008]

Embodiments of the present invention will be described below with reference to the accompanying drawings. 3 to 10 show a composite elastic fiber rope according to the first invention, and FIGS. 3 to 5 show a first embodiment thereof. In FIG. 3, 1 indicates the entire composite elastic fiber rope, 2 indicates an outer layer braided rope, and 3 indicates an inner layer braided rope. The inner layer braided rope 3 has a diameter smaller than that of the outer layer braided rope 2, and has a length dimension (free length) substantially longer than that of the outer layer braided rope 2 when no load is applied. Then, the inner layer braided rope 3 is accommodated in the tubular hollow portion 201 of the outer layer braided rope 2 in a state of being periodically bent in a wavy shape. Reference numerals 4 and 4 ′ are ice price portions formed at both ends of the composite elastic fiber rope 1.

The outer layer braided rope 2 and the inner layer braided rope 3
Is one or more sets of strands 20, 2 as shown in FIGS. 4 and 5.
It has a structure in which 0s are woven in a cross shape, and the braided structure has 8 striking (1 × 8, 2 × 4) and 12 striking (2 × 6, 1 × 1).
Although it is optional such as 2) or 24 striking, it is generally preferable that the outer layer braided rope 2 has a denser braid structure than the inner layer braided rope 3.

Each of the strands 20 and 20 constituting the outer layer braided rope 2 is composed of a plurality of yarns 200 in which a large number of raw material yarns are twisted together, and the raw material yarns have a high elongation, that is, when they are pulled by hand, they greatly expand. It is made of high elongation fiber that exhibits rubber-like properties that return to its original length when unloaded. This high elongation fiber (raw material yarn) has an elongation of 200% or more, for example, 200 to 600%, and a tensile strength of 0.6 gf / D.
Above, an elastic yarn having favorable characteristics of seawater resistance, weather resistance, acid resistance, and alkali resistance is preferable, and a specific example thereof is a polyurethane elastic yarn called spandex. However, if the strength is too weak with elastic threads alone, general-purpose synthetic fiber threads such as nylon and polyester are mixed in polyurethane to obtain a tensile strength of 1 to 1.3 gf / D.
A material having a degree of elongation of about 240 to 290% is used. The mixing method may be such that a general-purpose synthetic fiber yarn is spirally wound around an elastic yarn as a core.

Next, the inner layer braided rope 3 is also made into each strand 3
0 and 30 are composed of a plurality of yarns 300 in which a large number of raw material yarns are twisted, and the raw material yarns have a relatively low elongation and a relatively high tensile strength with respect to the raw material yarns of the outer layer braided rope 2. Is used. As the yarn 300, the following ones are appropriately selected and used depending on the use and rope specifications. High-strength, high-modulus fibers (high-performance fibers) such as aramid fibers, ultra-high-molecular-weight polyethylene, and aromatic polyesters with a tensile strength of 20 gf / D or more and an elongation of about 3 to 5% (tensile elastic modulus of 500 gf / D or more). . General-purpose fibers such as nylon, polyester, polyethylene with a tensile strength of 5-10 gf / D and an elongation of about 8-40%.

In the first embodiment, the corrugated portion 31 is formed on the inner layer braided rope 3 having a natural length and a long size, and the corrugated portion 31 is stored in the outer layer braided rope 2. In order to obtain such a storage structure, the elasticity of the outer layer braided rope 2 may be used.
6 (a) to 6 (c) show an example thereof, where the length of the outer layer braided rope 2 in the free length is l and the length of the inner layer braided rope 3 is L, the circumference of the inner layer braided rope 3 is shown. The outer layer braided rope 2 is braided, or the inner layer braided rope 3 and the outer layer braided rope 2 are made into a double braided state in a state where they are braided,
Put one end C of both ropes together and fasten them by binding. In this state, the inner layer braided rope 3 projects outwardly from the other end B of the outer layer braided rope 2 by a length m as shown in (a). In this state, the other end B of the outer layer braided rope 2 is grasped and pulled until it reaches the end A of the inner layer braided rope 3, and at this position, the outer layer braided rope 2 and the inner layer braided rope 3 are fastened by binding or the like. This is the state of (b). Then, when the pulling of the outer layer braided rope 2 is released in this state, the outer layer braided rope 2 becomes the length l again, and at this time, the end A of the inner layer braided rope 3 is also integrated with the outer layer braided rope 2, so that the outer layer braided rope 2 As the length is restored, the excess length of m is repeatedly bent and the wavy portion 31 is naturally formed, resulting in the stored state as shown in (c). After that, the fastening may be released, and even if the fastening is released, the outer layer braided rope 2 is in a free length state, and the inner layer braided rope 3 is bent and twisted due to friction with the outer layer braided rope 2 to form the outer layer braided rope. The total length fits within 2.
Instead of this method, the inner layer braided rope 3 is projected from the outer layer braided rope 2, and in this state, the outer layer braided rope 2 is tightened by pulling left and right so that both ends B and C coincide with both ends of the inner layer braided rope 3. Then, the state of (b) may be set, and then the tension on the outer layer braided rope 2 may be released.

7 and 8 show a second embodiment of the first invention. The second embodiment has the same basic configuration as the first embodiment, but the inner layer braided rope 3 is stored differently from the first embodiment, and the long inner layer braided rope 3 does not extend and contract the outer layer braided rope 2. It is designed to be decorated in. Specifically, the inner layer braided rope 3 is bent into U-turns at predetermined intervals so as to be equal to the free length l of the outer layer braided rope 2 to form the folds 32, 32. Then, the outer layer braided rope 2 is braided around the inner layer braided rope 3 or is inserted into the tubular hollow portion 201 after the outer layer braided rope 2 is braided and then stored. In this case, in order to prevent the folded portions 32, 32 from being unintentionally collapsed at the time of pushing in, the folded portions 32, 32 are stopped by the temporary fixing means 33 so that the stop is released when a predetermined tensile load is applied. It is also effective to do. Examples of the temporary fixing means 33 include binding or sewing with a thread and winding with a rubber band.

FIG. 9 shows a third embodiment of the first invention. This third embodiment has the same basic structure as that of the first embodiment, but the stored state is different. That is, the inner layer braided rope 3
Is compressed in the axial direction and is in a standing state (bellowed state) more than when the braid angle is natural length, whereby the length L is configured to be substantially the same as the length 1 of the outer layer braided rope 2. ,
In this state, the outer layer braided rope 2 is braided on the outer peripheral side, or the cylindrical hollow portion 2 is braided with the outer layer braided rope 2.
It is inserted in 01.

The length L of the inner layer braided rope 3 defines the absolute amount of elongation of the outer layer braided rope 2. By changing the length L of the inner layer braided rope 3, the outer layer braided rope 2 is changed.
The absolute elongation amount of can be adjusted arbitrarily. But,
From the viewpoint of the durability of the outer layer braided rope 2, it is generally preferable to set the length L of the inner layer braided rope 3 such that the elongation of the outer layer braided rope 2 is suppressed within 80%.

The ice-price parts 4, 4'in the first to third embodiments have their ends inverted in a U-turn shape and connected linearly with the rope body side by means of, for example, Satsuma insertion so that the inner layer braid is formed. The hairpin-shaped portion formed on the outer layer braided rope 2 by surrounding the ring portions 34, 34 formed on the rope 3 and the outer circumferences of the ring portions 34, 34, and inserting the free end 240 into the rope-side main body. It consists of 24. The method of forming such ice-price portions 4 and 4'is arbitrary. FIG. 10 shows an example thereof. In this example, first, with the inner layer braided rope 3 accommodated in the outer layer braided rope 2, the end A'of the inner layer braided rope 3 and the end A of the outer layer braided rope 2 are not displaced from each other by a string 5 or the like at the rear position D. Tie up. Then, as shown in (a), the required length of the end portion of the inner layer braided rope 3 is pulled out from the end A of the outer layer braided rope 2 from a predetermined rear position B. This can be easily done by expanding the space between the strands 20 of the outer layer braided rope 2 to form a hole. In this state, an arbitrary position C between the fastening point D and the position B is determined according to the size of the desired eye, a hole is formed in the outer layer braided rope 2 at the position C in the same manner as described above, and the finger is inserted from this hole. Alternatively, a jig is inserted to pull out the inner layer braided rope 3, and the end A ′ of the inner layer braided rope 3 and the end A of the outer layer braided rope 2 are aligned. This state is (b). BC is the size of the eye, there is a margin between AB and A'B ', A', B ', C'is A, B of the outer layer braided rope 2.
Each point of the inner layer braided rope 3 at the same position as B and C is indicated.

In this state, the portion 7 between B'A 'of the inner layer braided rope 3 is U-turned, and is linearly connected to the rear side of the drawn-out portion 6 by pinching or the like. Reference numeral 8 indicates this connecting portion, which means that the ring portion 34 is formed. In this state, the pull-out portion 6 is pushed into the outer layer braided rope 2 through the hole C. This is the state of (d), and the connecting portion 8 has the outer layer braided rope 2
It is stored inside. Then, while pulling the outer layer braided rope 2 along the exposed portion of the ring portion 34, the portion is accommodated in the outer layer braided rope 2 through the hole at the position B and becomes a state of a virtual line (d), AB of outer layer braided rope 2
The part (insertion allowance) remains cylindrical. Therefore, the outer layer braided rope 2 may be inserted from the end A into the hole at the position C, and the hairpin-shaped portion 24 is formed. After that, the staking point D mentioned above
All you have to do is to release the binding. With the above, the ice price portion 4 on one side is formed, and the ice price portion 4'on the other side can also be formed by the same procedure as described above. In this example, the fastening point D was formed when the first ice-price portion 4 was formed, but the end A of the outer layer braided rope 2 and the end A ′ of the inner layer braided rope 3 were formed without making the fastening point D. You may perform the said work in alignment. However, it is indispensable to make the fastening point D when forming the ice-price part 4'on the other side.

13 to 22 show the second invention.
13 to 15 show the first embodiment.
It In this embodiment, the outer layer braided rope 2 is the first
Same as Ming, except that the inner layer braided rope 3 is not one
Constructed from a total of two pieces, one braided rope 3a and a second braided rope 3b
The outer layer braided rope 2 by being formed and bent in a wavy shape
It is stored in. Specifically, the first braided rope 3a and the first
Both of the two braided ropes 3b are lower than the outer layer braided rope 2.
It has the characteristics of elongation and high tensile strength, and the outer layer braided braid
It has a natural length and a longer dimension than P2. And the
Elongation of one braided rope 3a₁, Of the second braided rope 3b
Elongation₂And the tensile strength of the first braided rope 3a is T
S₁, The tensile strength of the second braided rope 3b is TS₂And then
Free length of one braided rope 3a is L₁And the second braided rope
Free length of 3b is L₂And the first braided rope 3a
The second braided rope 3b has the following relationship. E₁<E₂, TS₁> TS₂, L₁> L₂ The diameters of the first braided rope 3a and the second braided rope 3b are the same.
However, due to the difference in tensile strength, the first
The braided rope 3a is thinner than the second braided rope 3b.

As a specific example, the first braided rope 3a is braided by the yarn 300 and the strand 30 which are made of raw material yarn of high strength and high elastic modulus fiber or high performance fiber, and the second braided rope 3b is made of raw material yarn of general purpose fiber. Nari Yarn 30
0, braided by strands 30. Then, the second braided rope 3b is discharged in parallel with the first braided rope 3a, and the both end portions 35, 35 of the first braided rope 3b are put into the first braided rope 3a by first insertion.
It is linearly fastened and integrated with the braided rope 3a. In order to obtain the inner layer braided rope 3 including the first braided rope 3a and the second braided rope 3b, in FIG. 15, first, the first braided rope 3a having a free length of L ₁ is made, and the first braided rope 3a having a free length of L ₂ is made. Make two braided ropes 3b. Next, the first braided rope 3a is started to be wound around a drum, and when this is wound a length a, one end 35 of the second braided rope 3b is connected to the first braided rope 3a by tapping or the like. Next, the second braided rope 3b is wound around the drum in parallel with the first braided rope 3a, and when the second braided rope 3ba is wound by the free length L ₂ , the other end 35 of the second braided rope 3b is inserted into the first braided rope 3a. Connect to. Then, the first braided rope 3a is further wound by the length b. The a length and the b length may or may not be equal. Since the inner layer braided rope 3 is obtained in this manner, the outer layer braided rope 2 is braided on the outer periphery by a free length 1 while unwinding it from the drum to form a double braid.
After that, the inner layer braided rope 3 may be housed in the tubular hollow portion 201 of the outer layer braided rope 2 by the outer layer braided rope pulling method as described with reference to FIG. 6.

16 and 17 show a second embodiment and a third embodiment of the second invention. The outer layer braided rope 2 and the inner layer braided rope 3 have the same structure as that of the first embodiment, but the storage structure for the outer layer braided rope 2 is different.
In the second embodiment, the first braided rope 3a and the second braided rope 3
b is a bundle, and U-turn-shaped folding portions 32, 32 are formed at predetermined intervals. And the folding part 32,
32 is lightly stopped by the temporary fastening means 33, and in this state, the outer layer braided rope 2 is braided or is inserted after the outer layer braided rope 2 is braided. In the third embodiment, the first braided rope 3a and the second braided rope 3b are compressed in the axial direction and formed into a bellows shape, so that the length is shortened.
Are stored by being braided or inserted after the outer layer braided rope 2 is braided.

18 and 19 show a fourth embodiment of the second invention. In this embodiment, the inner layer braided rope 3 is first
It is composed of three braided ropes 3a, a second braided rope 3b and a third braided rope 3c. First braided rope 3a, second braided rope 3b and third braided rope 3c
Have properties of lower elongation and higher tensile strength than the outer layer braided rope 2, and have natural length and longer dimension than the outer layer braided rope 2. And the first braided rope 3a
The elongation of the first braided rope 3a is E ₁ , the elongation of the second braided rope 3b is E ₂ , the elongation of the third braided rope ₃ is E ₃ , the tensile strength of the first braided rope 3a is TS ₁ , and the tensile strength of the second braided rope 3b is Strength T
And S _2, the tensile strength of the third braided rope 3c and TS _3, the free length of the first braided rope 3a and L _1, the free length of the second braided rope 3b and L _2, free of third braided rope 3c When the length is L ₃ , the first braid rope 3a to the third braid rope 3c have the following relationship. E ₁ <E ₂ <E ₃ , TS ₁ > TS ₂ > TS ₃ , L ₁ >
L ₂ > L ₃ The diameters of the first braided rope 3a to the third braided rope 3c may be the same, but in the normal case, due to the difference in tensile strength,
The first braided rope 3a is thinner than the other braided ropes.

As a specific example, the first braided rope 3a is braided by a yarn 300 made of raw material yarn of high strength and high elastic modulus fiber or high performance fiber and a strand 30, and the second braided rope 3b is made of general purpose fiber such as nylon. The yarn 300 and the strand 30 are braided, and the third braided rope 3c is braided by the yarn 300 and the strand 30 made of general-purpose fibers such as polyester. Then, as shown in FIG. 19, the third braided rope 3c is arranged in parallel with the second braided rope 3b, and the ends 35 ', 35 "are linearly fastened and integrated with the second braided rope 3b by inserting the ends. And the second braided rope 3b is the first braided rope 3
It is arranged in parallel with a, and both ends 35, 35 are linearly fastened and integrated with the first braided rope 3a by, for example, tatsusama insertion. The method of making the inner layer braided rope 3 in this embodiment is basically the same as that of the first embodiment, and when the first braided rope 3a is wound up to the position of the length a, the second braided rope 3b is connected, then, it was connected to the second braided rope 3b 'end 35 of the third braided rope 3c at wound only partial' length a, the first braided rope 3 to the position of length L ₃
a to the third braided rope 3c are wound in parallel, and at this position, the end portion 35 'of the third braided rope 3c is connected to the second braided rope 3c.
The end portion 35 of the second braided rope 3b is connected to the first braided rope 3a after being wound by the length b '. A method of storing the inner layer braided rope 3 having such a configuration in the outer layer braided rope 2 may be any of FIG. 13, FIG. 16 and FIG.

14 to 19, the first braided rope 3a, the second braided rope 3b or the third braided rope 3c constituting the inner layer braided rope 3 are parallel, but the present invention is not limited to this. It may be a nesting type (multi-braid type) instead of the one. That is, FIG. 22 shows a fifth embodiment of the second invention. (a) shows the case where two braided ropes 3a and 3b are used, and the second braided rope 3
b is stored in the first braided rope 3a in a bent or folded state. (b) is three braided ropes 3a, b
3, 3c is used, the third braided rope 3c is stored in the second braided rope 3b in a bent or folded state, and the second braided rope 3b is stored in the first braided rope 3a.
It may be stored in a bent or folded state. In any case, the inner layer braided rope 3 having such a multiple structure is stored in the outer layer braided rope 2 in a bent or folded state. Also in this embodiment, the relationship between the elongation, the tensile strength and the length of each braided rope 3a, 3b, 3c constituting the inner layer braided rope 3 is the same as that described above, and the connection method is also the same. The storing method may be the pulling / unloading method as shown in FIG. 7, the folding method as shown in FIG. 9 or the pushing method using a jig. In addition,
The structure and method of forming the splice portions 4 and 4'of the second invention are the same as those of the first invention, and thus the description thereof will be omitted.

[0024] In the second invention, when the inner braided rope 3 is composed of two, it is possible to adjust the absolute amount of elongation of the second braided rope 3b by setting L _1, outer braided rope set of L ₂ The absolute amount of elongation of 2 can be adjusted.
Further, if the inner braided rope 3 consists of three, the absolute amount of elongation of the second braided rope 3b by setting L _1, the absolute amount of elongation of the third braided rope 3c by setting L _2, also L ₃ The absolute amount of elongation of the outer layer braided rope 2 can be adjusted by setting the above. However, in consideration of durability, the absolute amount of elongation of the outer layer braided rope 2 is generally up to about 80%, and the absolute amount of elongation of the second braided rope 3b is about 80%, depending on the material characteristics of the fibers constituting the rope. Up to 40%, the absolute amount of elongation of the third braided rope 3c is preferably suppressed to about 15%, and L ₁ , L ₂ and L ₃ are set to correspond to this. Further, in both the first invention and the second invention, the outer layer braided rope 2 and the inner layer braided rope 3 have a diameter that allows the inner layer braided rope 3 to be bent so that the entire length of the outer layer braided rope 3 is reduced.
The movement should be such that the inner braided rope 3 is not disturbed by friction when it is stretched.

The composite elastic fiber rope 1 according to the first invention and the second invention is not necessarily limited to the one having ice prices at both ends. Depending on the application, as shown in FIG. 23, as an endless rope in which the ends of the outer layer braided rope 2 are connected by the connecting portion 9 and the ends of the inner layer braided rope 3 longer than the outer layer braided rope 2 are connected by the connecting portion 8. Good. In order to obtain this rope, both ends of the inner layer braided rope 3 protruding from both ends of the outer layer braided rope 2 in the free length state are connected, and then the central portion of the outer layer braided rope 2 is fastened, and the outer layer braided rope 2 is fixed. The both ends of the outer layer braided rope 2 may be connected by grasping both ends of the outer layer 2 and pulling them until reaching the connection portion of the inner layer braided rope 3. As a result, the excess length of the inner layer braided rope 3 is bent and stored in a wavy shape. Instead of this, as shown in FIGS. 8 and 16, the inner layer braided rope 3 is formed with the folded portions 32, 32, and is inserted into the outer layer braided rope 2 in this state,
Alternatively, the ends of the outer layer braided rope 2 may be connected to each other. Further, a compression / compression method as represented by FIGS. 9 and 17 may be adopted.

Specific examples of the present invention are as follows. [Specific Example 1] 1) The outer layer braided rope 2 has a nominal diameter of 20 mm and a length of 2
A 5 m spandex blade rope was used. This rope is made by making a strand of 2320D which is made by winding nylon filament 300D in a spiral shape on polywetan elastic yarn 840D as a yarn and striking it into a strand, which has a strength of 400 kgf and an elongation of 230.
%. For the inner layer braided rope 3, an aramid fiber braid rope having a nominal diameter of 8 mm and a length of 30 m was used. The rope is made by using aramid fiber 1500D as a yarn to form a strand and striking 8 strands of the strand.
000 kgf and elongation of 5.5%. 2) The inner layer braided rope 3 was housed in the outer layer braided rope 2 by the method shown in FIG. 6, and an ice price was formed at both ends by the method shown in FIG. 10 to obtain a sample rope. 3) The above-mentioned sample rope was attached to a tensile tester and subjected to a tensile test. As a result, when the load load reached 0 to 45 kgf, the length of the outer layer braided rope 2 reached the inner layer braided rope 3 (the elongation of the outer layer braided rope 2 was 20%). %), And thereafter, a load was applied to the inner layer braided rope 3 and it was broken at 5200 kgf. [Specific Example 2] The length of the inner layer braided rope 3 in Specific Example 1 was changed to 35 m to obtain a composite rope. In this case, 49
With the load of kgf, the length of the outer layer braided rope 2 reached the inner layer braided rope 3. At that time, the elongation of the outer layer braided rope 2 is 4
It is 0%.

[Specific Example 3] 1) The outer layer braided rope 2 has a nominal diameter of 23 mm and a length of 2
A 5 m spandex blade rope was used. This rope is made by using 2320D, which is made by winding Tayloron filament 300D in a spiral shape around polywetan elastic yarn 840D as a yarn to make a strand and striking it 24 times, with a strength of 500 kgf and an elongation of 230%.
Is. The first braided rope 3a has a nominal diameter of 8 mm and a length of 3
A 5 m aramid fiber braided rope was used. The rope is made by forming a strand using aramid fiber 1500D as a yarn and striking 8 strands of the strand.
It has an elongation of 00 kgf and an elongation of 5.5%. A nylon braid rope having a nominal diameter of 10 mm and a length of 30 m was used as the second braided rope 3b. The rope was made by using nylon fiber 1260D as a yarn to form a strand and striking eight strands, with a strength of 2350 kgf and an elongation of 30.
%belongs to. 2) The second braided rope 3b is arranged in parallel to the first braided rope 3a, and both ends of the second braided rope 3b are connected to the portions 1m away from the end of the first braided rope 3a by inserting the inner braided rope 3b. Got 3. The outer layer braided rope 2 was braided on the outer circumference of the inner layer braided rope 3 and housed by the method shown in FIG. 16, and ice prices were formed on both ends by the method shown in FIG. 10 to obtain a sample rope. 3) The sample rope was attached to a tensile tester and a tensile test was conducted. As a result, the load is 0 to 50 kgf.
Reaches the outer layer braided rope 2 and the length of the second braided rope 3
b (the elongation of the outer layer braided rope 2 is 20%), after which the second braided rope 3b receives the load, and 300 kgf
When it reaches, the second braided rope 3b extends to 35 m (elongation 40%, after which the first braided rope 3a is loaded,
It fractured at 50 kgf.

[Specific Example 4] 1) Outer layer braided rope 2, first braided rope 3a and second braided rope 3a
The same braided rope 3b as in Example 3 was used, and the third braided rope 3c was a polyester braid rope having a nominal diameter of 10 mm and a length of 33 m. The rope is
A polyester fiber 1500D is used as a yarn to make a strand, and eight strands are struck to obtain a strength of 250
It is 0 kgf and has an elongation of 20%. 2) This sample rope was attached to a tensile tester and a tensile test was conducted. As a result, the load is 0 to 50 kgf.
Reaches the outer layer braided rope 2 and the third braided rope 3
c (the elongation of the outer layer braided rope 2 is 20%), the third braided rope 3c receives the load, and when it reaches 190 kgf, the third inner layer braided rope 3c extends to 33 m (extension 32
%), Then the second braided rope 3b takes the load 3
When it reaches 30 kgf, it grows up to 35 m (40% elongation),
After that, a load is applied to the first inner layer braided rope 3a and 5210k.
It fractured at gf. It can be seen that the concrete example 4 can absorb the impact load in more stages than the concrete example 3.

From the above, when the composite elastic fiber rope of the first invention and the second invention is used as the auxiliary rope 15 for carrying out, for example, ocean observation, underwater, and bottom exploration, as shown in FIG. The upper and lower ropes may be connected in parallel with the damper 120. That is, the first rope 11
The upper part of the underwater damper 120 is connected to the holding member 111 of the terminal of 0, and the lower part of the underwater damper 120 is connected to the second rope 140.
Of the auxiliary rope 1 according to the present invention.
The ice price 4 at one end of 5 is connected to the holding member 111 via the connecting fitting 17, and the ice price 4'at the other end is connected to the holding member 141 via the connecting fitting 18. According to this structure, when performing ocean observation, underwater or water bottom exploration, etc., since the auxiliary damper function can be obtained due to the extension characteristics of the outer layer braided rope 2 and the inner layer braided rope 3 of the auxiliary rope 15, the underwater damper 120 is obtained. It can reduce the load and prolong the life of it. Further, when the underwater damper 120 is damaged due to a collision with rocks on the seabed in the sea and the connection with the first rope 110 is disconnected, and a shocking tensile load acts on the auxiliary rope 15, in the first invention, first, the outer layer braided rope is used. For example, when 2 stretches by 20 to 30%, the impact stress is absorbed, and then the outer layer braided rope 2 and the inner layer braided rope 3 extend, and the inner layer braided rope 3 receives the load.

In the case of the second invention, the outer layer braided rope 2 expands by 20 to 30% when a load is applied to absorb impact stress, and thereafter the outer layer braided rope 2 and the second braided rope 3b expand. Still absorbs impact stress,
The load is carried by the second braided rope 3b, and then the outer layer braided rope 2, the second braided rope 3b and the first braided rope 3a.
Stretches and further absorbs impact stress, and the load is taken up by the first braided rope 3a. Therefore, the shock can be finely and smoothly absorbed, the shock acting on the measuring device 130 is significantly reduced, and the damage and damage of the measuring device 130 can be reliably prevented.

[0031]

According to claim 1 of the present invention described above, when the outer layer braided rope having good vibration absorbing performance and high impact tensile load is stretched, the impact force of the outer layer braided rope is extended. Since the inner layer braided rope can absorb the tensile load after that, it is possible to provide a suitable effect as an auxiliary rope for ocean observation, underwater and water bottom exploration, and the like. According to the fourth to sixth aspects, in addition to the above effects, the excellent effect that the impact force can be smoothly absorbed in multiple stages and the final load receiving can be smoothly performed is obtained. Claims 2, 3,
According to 9 to 11, the excellent effect that the inner layer braided rope having a long length can be easily accommodated in the outer layer braided rope can be obtained.

[Brief description of drawings]

FIG. 1 is an explanatory view showing an example in which a composite elastic fiber rope of the present invention is applied.

FIG. 2 is a partially cutaway side view showing a state in which the present invention is applied to the example of FIG.

FIG. 3 is a partially cutaway side view showing a first embodiment of the composite elastic fiber rope of the first invention.

FIG. 4 is a partially enlarged view of FIG.

5 is an enlarged cross-sectional view taken along the line VV of FIG.

FIG. 6 is an explanatory view illustrating the method for storing the inner layer braided rope in the first embodiment.

FIG. 7 is a partially cutaway side view showing a second embodiment of the composite elastic fiber rope of the first invention.

FIG. 8 is an explanatory view illustrating the method for storing the inner layer braided rope in the second embodiment.

FIG. 9 is a cross-sectional view schematically showing a third embodiment of the composite elastic fiber rope of the first invention.

FIG. 10 is an explanatory view showing a stepwise method of forming an ice price in the present invention.

FIG. 11 is a load-elongation diagram of the composite elastic fiber rope of the first invention and another fiber rope.

FIG. 12 is an explanatory view schematically showing the behavior when a load is applied to the composite elastic fiber rope of the first invention.

FIG. 13 is a partially cutaway side view showing the first embodiment of the second invention.

FIG. 14 is a partially enlarged view of FIG.

FIG. 15 is a schematic explanatory view of an inner layer braided rope according to the first example of the second invention.

FIG. 16 is an explanatory view schematically showing a second embodiment of the second invention.

FIG. 17 is an explanatory view schematically showing a third embodiment of the second invention.

FIG. 18 is an explanatory view schematically showing a fourth embodiment of the second invention.

FIG. 19 is a schematic explanatory diagram of an inner layer braided rope according to a fourth example of the second invention.

FIG. 20 is a load-elongation diagram of the composite elastic fiber rope of the second invention and another fiber rope.

FIG. 21 is an explanatory diagram schematically showing the behavior when a load is applied to the composite elastic fiber rope of the second invention.

FIG. 22 is a partial sectional view showing a fifth embodiment of the second invention.

FIG. 23 is a cross-sectional view schematically showing another example of the composite elastic fiber rope of the present invention.

[Explanation of symbols]

2 outer layer braided rope 3 Inner layer braided rope 3a 1st braided rope 3b 2nd braided rope 3c Third braided rope 4,4 'ice price 20,30 Strand 31 Wavy section 32 Folding part

─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Kazuhide Ishinoda 1-7-12 Toranomon, Minato-ku, Tokyo Inside Oki Electric Industry Co., Ltd. (72) Inventor Toshiaki Kimura 1st Nakamura, Toyooka-cho, Gamagori-shi, Aichi 1 Toyo Tuna Rope Co., Ltd. (72) Inventor Yoshinori Matsumoto 1 at Nakamura, Toyooka-cho, Gamagori-shi, Aichi 1 Toyo Tuna Rope Co., Ltd. (56) Reference JP-A-59-197263 ( JP, A) JP 60-21990 (JP, A) JP 2-169788 (JP, A) JP 54-120767 (JP, A) Actually open 7-19395 (JP, U) Actually open SHO 48-89946 (JP, U) ACTUAL 53-56051 (JP, U) ACT 59-111142 (JP, U) (58) Fields investigated (Int.Cl. ⁷ , DB name) D07B 1 / 00-9/00

Claims (13)

(57) [Claims] 1. An elastic yarn alone or a general-purpose fiber mixed with the elastic yarn.
In the inner tubular cavity of the outer layer braided rope braided using the high elongation fiber having an elongation of 200% or more, a fiber having a lower elongation and a higher tensile strength than the outer layer braided rope is used. A composite elastic fiber rope, characterized in that it contains an inner layer braided rope that is braided with a material having a length dimension larger than that of the outer layer braided rope. 2. The inner layer braided rope is stored in a wavy bent state in the outer layer braided rope by restoring the length dimension by pulling the outer layer braided rope to the same length as the inner layer braided rope and then unloading. The composite elastic fiber rope according to claim 1. 3. The composite elastic fiber rope according to claim 1, wherein the inner layer braided rope has U-turn-shaped folds at predetermined intervals and is housed in the outer layer braided rope via these folds. 4. An elastic yarn alone or a general-purpose fiber mixed with the elastic yarn.
An outer layer braided rope braided by using a high elongation fiber having an elongation of 200% or more, and a length longer than the outer layer braided rope braided with a fiber having lower elongation and higher tensile strength than the outer layer braided rope An inner layer braided rope consisting of multiple braided ropes with large dimensions is provided, and each braided rope has different elongation and different tensile strength, and the lower the elongation and the higher the tensile strength, the longer the dimension. A braided rope with a relatively high elongation and a low tensile strength is connected at both ends to a braided rope with a relatively lower elongation and a higher tensile strength, and in this state all the inner layer braided ropes are A composite elastic fiber rope characterized by being housed in an inner tubular hollow portion of a braided rope. 5. The inner layer braided rope comprises a first braided rope and a second braided rope.
The composite elastic fiber rope according to claim 4, which is made of a braided rope. 6. The composite elastic fiber rope according to claim 4, wherein the inner layer braided rope is composed of first to third braided ropes. 7. The composite elastic fiber rope according to claim 4, wherein a plurality of braided ropes are parallel to each other. 8. A plurality of braided ropes, wherein a braided rope of relatively low elongation and high tensile strength is housed in a braided rope of relatively high elongation and low tensile strength. The composite elastic fiber rope according to any one of claims 4 to 6. 9. The inner layer braided rope is accommodated in a wavy bent state in the outer layer braided rope by restoring the length dimension by pulling the outer layer braided rope to the same length as the inner layer braided rope and then unloading. The composite elastic fiber rope according to any one of claims 4 to 8. 10. The inner layer braided rope has U-turn-shaped folds at predetermined intervals, and is housed in the outer layer braided rope through these folds.
7. The composite elastic fiber rope according to any one of 1. 11. The inner braided rope in the inner braided rope is corrugated in the outer braided rope by restoring the length dimension by pulling the outer braided rope to the same length as the inner braided rope and then unloading. The composite elastic fiber rope according to claim 8, which is stored in a bent state. 12. The composite elastic fiber rope according to any one of claims 1 to 11, which has ice prices at both ends. 13. An outer layer braided rope is composed of elastic yarns or yarns and strands in which general purpose fibers are mixed, and an inner layer braided rope is composed of yarns and strands of high strength and high elastic modulus fibers or general purpose synthetic fibers. The composite elastic fiber rope according to any one of claims 1 to 12.