JP2007244371A - Braid rope and method for producing the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a braid rope preventing a hung article from being dislocated from a prescribed position, and facilitating the treatment by a user; and to provide a method for producing the rope. <P>SOLUTION: Two engaging members 14 prepared so as to be neighbored are included in the skin 12 formed by twisting twelve strands. As a result, a pair of bulged parts 16 are formed in the appearance of the braid rope 10, and the hung article can be effectively held at the position of the engaging part 18 by fixing and binding a hanging thread 20 at the engaging part 18 between the bulged parts 16. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a blade rope and a manufacturing method thereof.

Shellfish such as scallops and oysters and kelp algae are cultivated in a long-line aquaculture facility installed on the sea.
The longline culture facility will be described with reference to the drawings. FIG. 5 is a schematic view of a conventional longline culture facility. FIG. 6 is a diagram showing the main rope of FIG.
The aquaculture facility 100 in FIG. 5 is an underwater facility in which a culture rod 106 and the like are suspended from a long rope 104 (referred to as “main rope” in this application) to which a float 102 is attached.

The main rope 104 used in the longline type aquaculture facility 100 used a relatively thick three-pipe rope having an outer diameter of 28 mm to 30 mm. As shown in FIG. 6, the three-strike rope is a rope formed by twisting three strands and has a relatively large uneven portion 108. In longline type aquaculture, the hanging thread 110 such as the culture rod 106 secured to the main rope 104 and the hanging thread 111 of the float 102 are displaced from the predetermined positions, and the balance of the weight applied to the main rope 104 is lost. The slanting of the cultivated body such as scallops and the like is caused due to the slant of the cultivated body such as scallops. There was a problem of doing. Therefore, a thick three-pipe rope having a relatively large uneven portion 108 is used so that the suspended object (such as the culture rod 106 and the float 102 in FIG. 5) does not shift.
Further, a suspension thread pulling roller is used when the main rope 104 is lifted in cleaning work of the attached matter on the cultured body. For this reason, it is necessary to use the main rope 104 having strength, and conventionally, a relatively thick three-pipe rope has been used.

  However, the uneven portion 108 of the main rope 104 becomes a smooth surface 112 because the surface of the main rope 104 is worn due to rubbing or slipping of the hanging threads 110 and 111 while being used in the sea. When the surface of the main rope 104 becomes a smooth surface 112, the hanging yarns 110 and 111 are moved from a predetermined position by waves and tides, and there is a problem that productivity of the above-described cultivation is lowered.

The aquaculture facility 100 includes several hundred floats 102 that support the main rope 104 at a predetermined depth. This float 102 is bound to the main rope 104 at two points, and has ears (holes) 102a and 102b through which the hanging thread 111 is passed. The suspension thread 111 is passed through the two ears, and the two suspension threads 110 are secured to the main rope 104, thereby preventing the float 102 from moving from a predetermined position.
However, the work of tying the hanging threads 110, 111 to the three-strand rope (main rope 104) is difficult to handle because the rope itself is thick, and the efficiency of the lashing work is poor. Therefore, it has been desired to use a one-point binding float that can halve the lashing operation and is inexpensive.

  Further, the smooth surface 112 formed on the main rope 104 has also caused the efficiency of the lifting work of the main rope 104 to be deteriorated. In longline culture, it is necessary to adjust the depth at which the main rope 104 is arranged according to the growth of cultured shellfish or the temperature change of seawater. The depth is adjusted by adjusting the number of floats 102. In addition, cleaning work for the deposits on the cultured body, which is important in aquaculture, is also performed. In the adjustment work and the cleaning work, the main rope 104 is pulled up using a lifting thread pulling roller installed on the ship, and as a previous stage work, a part of the main rope 104 is pulled up to the ship by hand. I do. The main rope 104 of the smooth surface 112 is thick and slippery, and therefore it was very difficult to pull it up by a worker. In particular, it was supposed to impose harsh labor on female workers with weak grip.

  Thus, the inventors of the present application investigated prior art documents that solve the above-mentioned problems, but at the time of filing the present application, they could not find a publicly known document that could solve the problems and came to propose the present invention.

  SUMMARY OF THE INVENTION In order to solve the above-described problems, an object of the present invention is to propose a blade rope that can be handled easily by a user, in which a suspended object does not deviate from a predetermined position, and a manufacturing method thereof.

In the blade rope of the present invention, a locking member having a convex portion is covered with an outer skin formed by twisting three or more strands, thereby providing the outer skin with a locking portion.
Further, the number of strands is twelve.
Further, the locking member is made of synthetic resin.

In the blade rope manufacturing method of the present invention, the outer member is formed by twisting three or more strands on a core provided with a locking member having a convex portion at a predetermined position.
Further, the number of strands is twelve.
Further, the locking member is made of synthetic resin.

The blade rope of the present invention forms a locking portion on the surface of the blade rope by incorporating a locking member having a convex portion in the blade rope. By tying the hanging thread to the engaging portion, it is possible to prevent the suspended object from moving to another position of the blade rope. Therefore, by using the blade rope of the present invention as the main rope, it is possible to prevent the hanging thread from moving on the surface of the main rope, and it is possible to improve the productivity of a cultured body such as a scallop. .
In addition, when the blade rope of the present invention is used as the main rope, a one-point bundled float can be used, so that the securing operation can be halved and the cost of the float equipment can be reduced.
Moreover, since the blade rope of the present invention has a raised portion, it is easy to catch a hand, while the portion without the raised portion is thin and easy to grip. Therefore, even for women, the work of lifting the main line becomes easier, and the work effort of the workers can be reduced.

  The present invention realizes an object that a suspended object does not deviate from a predetermined position and is easy for a user to handle.

The blade rope of this invention is demonstrated based on figures. FIG. 1 is a diagram showing a blade rope of the present invention. 2 is a locking member built in the blade rope of FIG. 1, FIG. 2A is a front view, and FIG. 2B is a central longitudinal sectional view of the front view.
The blade rope 10 of the present invention includes a plurality of locking members 14 incorporated in the outer skin 12.
The outer skin 12 is a single blade rope produced by twisting in a twist structure of 2 × 6 = 12 strokes (12 strands). The 12-strand twist structure may be a 1 × 12 = 12-strand twist structure.
The twisted structure of the outer skin 12 is a currently known fiber rope structure of a blade rope, which can be obtained by a blade rope manufacturing method under the trade name “Queen Blade” manufactured by Obama Steel Corporation.
Further, the surface (appearance) of the outer skin 12 is not formed with large unevenness such as the uneven portion 108 (FIG. 6) of the triple rope (main rope) 104.

The locking members 14 are spherical and are provided adjacent to each other in a cavity 26 (FIG. 3) described later formed in the outer skin 12. The surface of the outer skin 12 in which the locking member 14 is built is raised from the other surface, and a pair of raised portions 16 are formed on the surface of the blade rope 10. Further, a locking portion (constriction portion) 18 is formed between the pair of raised portions 16. The hanging thread 20 secured to the locking portion 18 is restricted from moving left and right by the left and right raised portions 16. That is, it is possible to hold the object suspended from the locking portion 18 of the blade rope 10. For example, when the blade rope 10 is used as the main rope, even if the surface becomes smooth, the culture rod or the float does not move from the position of the locking portion 18 to the left or right. Moreover, when restrict | limiting the movement to either one of right and left, the one locking member 14 is provided at predetermined intervals.
When the blade rope 10 is used as the main rope, the outer diameter of the locking member 14 is preferably 18 mm to 22 mm.

The locking member 14 of the present embodiment is made of a synthetic resin and is formed by combining hemispherical members 14a and 14b. Two rope grooves 24 are provided at opposing positions on the joint surface 22 of the two pieces 14a, 14b.
The shape of the locking member 14 may be a spherical shape having convex portions on the upper and lower sides, or a shape having two convex portions on the upper and lower sides like a bowl. When the hook-shaped locking member 14 is used, the hanging thread 29 is secured to the constricted portion. Moreover, when using as a main rope, in order to prevent the failure | damage of the locking member 14, what has elasticity is used.
Further, the locking member 14 may have a convex portion on either one of the upper and lower sides in addition to the spherical and bowl-shaped convex portions on the upper and lower sides.
In addition to the synthetic resin, rubber, timber (piece), and the like can be considered as the material for the locking member 14, but a synthetic resin that can be easily combined by welding is preferable. However, the material for the locking member 14 is not limited to these.

Next, the manufacturing method of the blade rope of this invention is demonstrated based on figures. FIG. 3 is a diagram showing the internal structure of the blade rope of the present invention.
The blade rope 10 of FIG. 3 has a core (core) 28 in which a plurality of sets of two locking members 14 are attached to a cavity (internal space) 26 formed in the outer skin 12. The core material of the core 28 is a thin three-stroke rope 28a. The locking member 14 passes the three-strike rope 28a through the rope grooves 24 (FIG. 2) of the two pieces 14a, 14b of the locking member 14, and welds the two pieces 14a, 14b to form the three-strike rope. It is attached to 28a.
Further, the blade rope 10 can be generated by covering the core 28 including the locking member 14 with the outer skin 12 so as to wrap.

The number of strands of the outer skin 12 is preferably 6 to 32. The current blade rope has a number of strands of 3 to 32. However, only when the number of strands is 6, 12, 16, 24, or 32, a cavity (internal space) 26 is formed in the outer skin 12. Can be formed. Considering the strength and cost of the blade rope, 12 is most preferable.
Further, the locking member 14 may be incorporated in a blade rope having three strands and eight strands. However, this rope blade is suitable for a usage mode in which tension is not applied because there is a risk of the locking member 14 being broken or the rope being cut in a usage mode in which the tension is applied to the broad rope.

The outer diameter of the outer skin 12 of the present embodiment can be set to approximately 30 mm to 34 mm by a known broad manufacturing method. The outer diameter 12 is larger than the conventional main rope (outer diameter 28 mm to 30 mm). However, since the outer diameter 12 has a hollow portion 26, the outer diameter 12 becomes thin when gripped by hand, and is easy to grip. is there. Furthermore, by using thermoplastic resin fibers such as polyolefin as the material of the outer skin 12, it is possible to provide a lighter, stronger and higher wear resistance than a three-pipe rope. Therefore, when the blade rope is operated by a worker's hand, it is difficult to slip, and the operation can be facilitated and the labor of the worker can be reduced.
In this embodiment, a thin three-pipe rope is used for the core 28, but the present invention is not limited to this.

Next, an embodiment of a blade rope of the present invention will be described based on the drawings. FIG. 4 is a use state diagram when the blade rope of FIG. 3 is used as a main rope.
In FIG. 4, a hanging thread 110 for hanging the culture rod 106 and a hanging thread 111 for supporting the single-point float 30 are fixed to the engaging portion 18 between the two raised portions 16 of the blade rope 10 (main rope). Is tied up. The hanging threads 110 and 111 are restricted from moving to the left and right by the raised portions 16 and are effectively held at the secured positions, that is, the locking portions 18. Therefore, the cultured trough 106 and the float 102 are not displaced from the predetermined positions by waves and tidal currents, thereby improving the production of the cultured body. In addition, since the cultured rod 106 can be hung directly under the float 30, the cultured rod 106 can be effectively supported.
The float 30 is a one-point bound float. The float 30 can be attached to the blade rope 10 by tying one hanging thread 111. Therefore, compared to the conventional two-point bundling float 102, the mounting labor can be halved. Further, since the float 30 is cheaper than the float 102, the cost of the float facility can be reduced.

  The said Example is one Example of this invention, and is not limited to utilization of this rope. The present invention provides a blade rope that holds a suspended object in a predetermined position, and can be widely used in other fields.

It is a figure showing the blade rope of this invention. It is a figure showing the locking member incorporated in the blade rope of FIG. It is a figure which shows the internal structure of the blade rope of this invention. It is a use condition figure at the time of using the blade rope of FIG. 3 as a main rope. It is the schematic of the conventional longline type culture facility. It is a figure showing the main rope of FIG.

Explanation of symbols

10 Blade rope 12 Outer skin 14 Locking member 18 Locking portion 28 Core

Claims (6)

A blade rope, wherein a locking portion is provided on the outer skin by covering a locking member having a convex portion with an outer skin generated by twisting three or more strands. The blade rope according to claim 1, wherein the number of strands is twelve. The blade rope according to claim 1 or 2, wherein the locking member is a synthetic resin. A method for producing a blade rope, characterized in that an outer skin is produced by twisting three or more strands on a core provided with a locking member having a convex portion at a predetermined position. The blade rope manufacturing method according to claim 4, wherein the number of strands is twelve. 6. The blade rope manufacturing method according to claim 4, wherein the locking member is a synthetic resin.