JPS6012918A - Engagement of breeding shelfishes using wire like engaging tool - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a method for locking aquaculture equipment using a linear locking device, and in particular, to a method for locking aquaculture tools using a linear locking device, and in particular, to a method for locking aquaculture tools using a linear locking device, in particular, a method of locking aquaculture tools using a linear locking tool, and in particular, a method of locking aquaculture equipment using a linear locking device, and in particular, a method of locking aquaculture tools using a linear locking device, and in particular, a method of locking aquaculture tools using a linear locking device, and particularly, a method for locking aquaculture tools using a linear locking device. A method for locking aquaculture tools (using a linear locking device made of synthetic resin that locks young shellfish to a rope by flattening the free end of the device using rolling means) Regarding how to stop.

FIG. 1 (A) is an explanatory diagram showing the situation in which scallops are cultivated, in which a float 33 moored to the seabed 31 with a rope 32
．． A rope 35 is suspended from an L cope 34 stretched between 33, and a scallop 36 is suspended from this rope 35 by means of a locking device 1 made of synthetic resin or the like.

Conventionally, when hanging the young shellfish 36, a string was passed through the rope 35, and the string was tied through a hole made in the ear of the young shell 36.

As is well known, tegusu is a fairly hard and stiff wire-shaped object that is used to make it easier to pass through the rope and penetration, and it is similar to handling a knife, so rubber gloves are used to prevent the hands from getting rough. , I have done that work even more,
Therefore, there is a lot of time loss.

In addition, if the above-mentioned hanging of the young shellfish is not tied properly, the shellfish will often fall off during culture, and moreover, the shellfish will fall off when the shellfish grows and its weight increases. This is easy to do, and the quality of the work involved is highly dependent on the level of skill involved.

Furthermore, when suspending young shellfish using the rope 35, it is necessary to perform preliminary work to tie the rope 35 to the rope 35 during the body fishing season. It involves hanging work, which makes the work even more complicated.

Therefore, various linear fasteners made of synthetic resin have been proposed in order to quickly and simply attach the young shellfish 36, and a linear fastener 30 as shown in FIG. You can also see
The diameter of the hole drilled in the young shellfish is determined by 1. considering the growth rate of the young shellfish.
Since the diameter of the hook portion 38 for locking must be less than 5 fins, the diameter of the hook portion 38 for locking is significantly limited to about half the diameter of the linear portion 37, and at most the diameter is as small as about 0.7+u. Since the linear locking tool is not durable or the locking part is not strong enough,
It was not suitable for cultivating shellfish.

The method of the present invention has been made to solve the above-mentioned problems when securing aquaculture equipment to a rope, and its purpose is to solve By using a shaped locking device and a locking part forming means that anyone can easily use, you can quickly and easily attach two Japanese molluscs to a rope for aquaculture.
To provide a method for locking aquaculture tools using an excellent linear locking tool that can be used to hold fish, and is also durable.

For the above purpose, the present invention compresses and deforms the linear part of the linear fastener using a rolling means to form a flat part larger than the wire diameter of the linear part, thereby making it possible to hold shellfish in two-ply form. It is characterized by being designed to be locked.

The present invention will be described in detail below using the drawings.

4 (Δ) and (13) are a front view and a side view II+ of an embodiment of the rolling means 10 for carrying out the method of the present invention, with the cover removed.

The rolling means 10 of this embodiment has a front panel 11 and an intermediate panel 12 projecting parallel to each other at a predetermined interval on a base 13, and a rolling roller having stepped portions 14b and 15b at the rear thereof. The rotating shafts 14b and 15a extend between the front panel 11 and the intermediate panel 12, and are supported by rotating shafts 14b and 15a such that the rotating shafts 14 and 15 are in contact with each other. The rotating shafts 14a and 15a are both extended to the rear of the intermediate panel 12, and driven gears 16 and 17 are engaged with each other to rotate at the same speed in opposite directions.
are installed respectively.

These driven gears 16,17 are adapted to be rotated by a drive motor 19 mounted on the base 13, and in this embodiment the driven gear 17 meshes with a drive gear 18 mounted on this motor 19.

Further, in the front panel 11 of the rolling means 10, a horizontally elongated locking tool insertion hole 9 is bored at a position where the rolling roller 14, 15 comes into contact with the front panel 11.

Using the rolling means 10 configured as described above, the present invention provides a linear locking tool 1' having a locking part 3 provided with an insertion hole 2 at one end as shown in FIG. 3(A), for example. Lock it as follows: That is, the linear portion 5 of the linear locking tool 1'
After inserting into the insertion hole 2, the free end protruding from the insertion hole 2 is inserted through the large diameter part 9a of the insertion hole 9 provided in the front panel 1 of the rolling means 10, as shown in FIG. Move this to the right. Then, the linear portion 5 passes between the rolling rollers 14 and 15 that rotate at a constant speed, and is rolled by these rollers, and after passing, a rolling bulge 7 as shown in FIG. 6 is formed. Formed on the free end side. The diameter of the insertion hole 2, the diameter of the linear portion 5, or the pressing force of the rolling rollers 14 and 15 are determined so that the rolling bulge 7 is wider than the insertion hole 2 of the locking portion 3. If this is done, the linear locking device 1° will be locked in the state shown in Figure 6, making it easy to engage and connect various objects, especially when locking aquaculture tools η to the rope at intervals. can be used.

Figures 7 to 9 show an example in which the method of the present invention is applied to aquaculture of shellfish such as scallops using a rope, and Figures 7 and 8 show the lines in Figure 3 (A) above. This is an example in which a linear locking device 1'' is used, and FIG. 9 is an example in which a linear locking device 1'' shown in FIG. 3(B) is provided with a rod-shaped locking portion 3'' at one end. .

As mentioned above, in the cultivation of shellfish, such as scallops, using a rope, a small hole 22 is drilled in the ear part 21 of the scallop while it is young, and a thin yet strong rod such as a scallop is inserted into this hole 22. This is done by suspending it from a hanging cord such as a rope through a large connecting cord or wire, and then submerging it in the sea for a certain period of time.

Therefore, when applying the method of the present invention to such aquaculture, first insert the linear part of the linear locking tool 1'' into the small hole 22 provided in the ear part 21 of the scallop 20. concatenate several. Next, the linear portion 5 is passed through the rope 23 and then through the insertion hole 2 of the locking portion 3.
The linear portion 5 of the portion protruding from the rolling means 1 of FIG.
0 inside the insertion hole 9.

Then, as shown in FIG. 7, the linear portion 5 is compressed and deformed by the rolling roller, and becomes a rolled bulge portion 7.

Since the rolling bulge 7 prevents the engaging portion 3 from coming off,
The linear anchor l'' allows the scallop 20 to be suspended from the rope 23 while maintaining its annular shape.

FIG. 8 shows another example of the use of the linear locking device 1'', in which the linear portion 5 is first inserted into the thread of the linear rope 23', and then the insertion hole 2 of the locking portion 3 is inserted. Then, the linear portion 5 extending outward from the locking portion 3 is inserted into the hole 2 of the ear portion 21 of the scallop 20 in the same manner as described above.
2, and its end is compressed and deformed using the rolling means 10 in the same manner as described above, to form a rolled bulge 7 wider than the hole 22. Even in this case, the scallop 20 is held on the rope 23 by the linear locking tool 1'' and the rolled bulge formed thereon.
It is possible to suspend the device while it is locked in place.

FIG. 9 shows an example in which the method of the present invention is applied to the linear fastener l" shown in FIG. 22, the scallop 20 is locked by the rod-shaped locking part 3', and then the free end of the linear locking tool 1'' is inserted through the rope 23.

Then, after inserting another linear part 5 protruding from the rope 23 through the hole 22 of the ear part 21 of the scallop 20, the free end of the linear part 5 protruding from the scallop 20 is rolled into a bulging part by the rolling means IO. 7, this scallop 20 is locked.

Note that the linear fastener used in the method of the present invention is one in which the wire diameter of the linear portion 5 is uniform, as in the linear fastener 1.1'' shown in FIGS. 3(A) and 3(B). Although it is possible to attach the scallops 20 to the rope 23 using a rope 23, the workability of the operator who actually attaches the scallops 20 to the rope 23 and the scallops 20
Taking into account that the diameter of the hole 22 drilled at 0 is small, less than 1.5 fins, the linear fastener used in the method of the present invention has the shape shown in Fig. 2 (^). Optimal.

The linear fastener 40 shown in FIG. 2(A) has a linear portion 41 formed by stretching to be thin around l+ua.
Near the free end 42 is a large-diameter portion 43 for forming a pressure bulge.
Established & J. The wire diameter of this large diameter portion 43 is 1,2111
The diameter of the linear portion 41 is approximately 0, and is slightly thicker than the diameter of the linear portion 41. A locking portion 44 provided at one end of the linear locking tool 40
The hole diameter of the insertion hole 45 is made large enough to allow the large diameter portion 43 to pass through. Further, from the large diameter portion 43 to the free end 42
It is preferable that the wire diameter is tapered.

FIG. 2 (13) is a plan view of the linear fastening tool 40', not showing the shape of the linear fastening tool 40 shown in (Δ) before stretching, and is a plan view of the linear fastening tool 40' free i' /i+i Match 42 to get seven. The linear locking device 40 is made by pulling the locking portions 44 and 44 from both ends of the linear locking device 40′ in a heated state, and stretching the entire length β to about three times the central portion 4.
If you cut it at 6, it will be completed.

The linear locking device 4o formed in this way has a free end 4
2 is tapered, and a large diameter part 43 is continuously provided for a predetermined length behind the free end 42, and furthermore, the wire diameter is thin and flexible between the large diameter part 43 and the locking part 44. When inserting the linear locking tool 40 into the hole provided in the ear of the scallop, or when inserting it through the row 123, it is easy to do the work without electricity, and the large diameter part By rolling and expanding the scallops 43, the scallops can be held securely and with good durability.

As described above, the method for locking aquaculture tools of the present invention uses a linear locking device provided with a locking portion at one end, and rolls the free end of the linear locking device into a flat shape using a rolling means. It can be attached to ropes such as scallops.

In addition, in the method of the present invention, the rolled bulge can be formed anywhere on the linear part of the linear anchor, so the linear part can be formed depending on the number and size of the shells to be anchored to the rope. The method of the present invention can be used for cultivating various types of shellfish by adjusting the length by cutting or the like in advance.

FIG. 10 shows another embodiment of the rolling means 10, in which rotary cutters 24, 25, which are also rotated by a drive motor 19, are provided beside the rolling rollers 14, 15.

According to this rolling means, regardless of the length of the linear portion 5 of the linear fastener 1, the linear portion 5 is moved along the insertion hole 9 when forming the rolled bulge 7. In the case of row G, unnecessary portions of the linear portion 5 are cut off by the cassocks 24 and 25, so that the length of the linear locking tool 1 in the locked state can be maintained optimally. .

Note that the rolling means may be one that does not use a rotating rolling roller, but uses two arms such as pliers, or one that rolls by pressing from above and below, such as a press machine.

As explained above, the method for locking aquaculture tools using the linear locking device of the present invention is to connect the free end of the linear locking device having a locking portion at one end to the ear part of a young shellfish. After inserting it into the rope, it is rolled into a flat shape using a rolling means so that it bulges out from the wire diameter,
By using this rolled bulge to lock shellfish to the aquaculture rope, anyone can easily and quickly perform the work of locking shellfish using a linear locking tool.
Further, there is an effect that the length of the linear locking tool can always be set to the optimum length.

[Brief explanation of drawings]

Figure 1 (A) is an explanatory diagram showing the conventional scallop farming situation;
Figure (B) is a plan view of an example of a conventional linear locking device for aquaculture.
Fig. 2 (A) is a perspective view of an embodiment of the linear fastener used in the method of the present invention, which is close to the actual shape, and Fig. 2 (13) is a plane of the linear fastener shown in (△) before stretching. Figures 3(A) and 3(B) are perspective views showing examples of linear fasteners used in the method of the present invention, and Figures 4(A> and 4B) are for carrying out the method of the present invention. 5 is a perspective explanatory view for explaining the locking method of the present invention using the rolling means of FIG. 4; A perspective view showing the locked state of the linear locking tool in Figure (Δ), Figures 7 and 8 are Figure 3 (
Δ) is a perspective view showing the method of the present invention applied to shellfish culture using the cotton-like locking device, and FIG. 9 is a detailed view of the present invention using the linear locking device of FIG. 3(B). FIG. 10 is a front view showing a modification of the rolling means. LL', 1", 40... Linear locking tool, 2.45...
Insertion hole, 33', 44 locking part, 5.41... Linear part, 7... Rolling bulge part, 9... Insertion hole 9.10... Rolling means, 11... Front panel , 12...middle panel,
14.15 Rolling roller, 14b, i4b... Rolling step, 16.17 Gear 16
．． 17 gear, 18... drive motor, 20... shell, 13.
13'...rope, 14, 15...cutter. Agent: Patent attorney Makoto Ogawa - Patent attorney Ken Noguchi Teru Patent attorney Kazuhiko Saishita Procedural amendment letter 1982 13/1 1, Indication of the case 1982 Ill 58 1 Special π "Publication No. 1181/1
7 ShiJ2, Title of the invention: Locking force method for aquaculture furnace using linear locking device 3, Entry with f'1 (f'1) 4.!Bo [Applicant 4, Immediately
Person fi1'11 〒105 East Chubu Port I Me4rli Hashigetsu 1
13 No. 3-Pe'I Kambi J Shi Ogawa Tefl 11'i
i1・'1''l:l'j'l''1(f)ifsu1 in ilj story 43.1-5361.) (Attachment) 'UJl old man 11 everyone; ]8 Name of invention Linear locking 2. Method for locking aquaculture tools using a linear locking tool 2. Claims: Cheek locking method. 3. Detailed description of the invention [Technical field of the invention] The present invention relates to aquaculture tools using a linear locking tool. Regarding the method of locking, in particular, when cultivating scallops, the linear locking device made of synthetic resin for aquaculture used for attaching the moon to the rope for aquaculture can be rolled by rolling means. This invention relates to a method for locking aquaculture tools using a tool on a linear portion 1 which is deformed into a flat shape to lock young shellfish to a rope. [Prior art] Fig. 1 (A) is an explanatory diagram showing the situation in which scallops are cultivated, and shows a float 33 moored to the seabed 31 with a rope 32.
．． A rope 35 is hung from a rope 34 stretched between 33,
A scallop 36 is suspended from this rope 35 by a locking device made of synthetic resin or the like. Conventionally, when hanging the young shellfish 36, a string was passed through the rope 35, and the string was passed through a hole in the ear of the young shellfish 36 and tied. As is well known, tegusu is a fairly hard and stiff wire-shaped object that allows the rope and fire to pass through easily, and it is similar to handling a knife, so you must wear rubber gloves to prevent your hands from getting rough. As a result, the work has to be overdone even more, resulting in a lot of time loss. In addition, when suspending young shellfish with the above-mentioned tegus, if the knot is insufficient, the young shellfish often fall off during cultivation, and this falling off is likely to occur when the young shellfish grow and increase in weight. The above-mentioned tying has the disadvantage that the quality of the work is largely determined by the level of skill. Furthermore, when suspending young shellfish using the above-mentioned fishing rod, it is necessary to perform preliminary work by tying the fishing rod to 1 cope 35 in advance during the main fishing season. The work involves hanging the shellfish from a rope 35 with a rope, making the work even more complicated. Therefore, in order to quickly attach the young shellfish 36 to the node 1i, various linear fasteners made of synthetic resin have been proposed, such as the linear fastener shown in Fig. 1(B). 30 is also seen, but the diameter of the hook part 38 of the locking part is linear because it has to be lowered by less than 1.5IIIN considering the growth rate of the shellfish. It is significantly limited to about half the diameter of the portion 37, and the maximum diameter is 0.7 I
Since the diameter can only be as small as NIN and it cannot be stretched, the linear locking device lacks durability and the locking part is not strong enough, making it unsuitable for shellfish cultivation. What? [Object and Summary of the Invention] The method of the present invention has been made in order to solve the above-mentioned problems when securing aquaculture equipment to a rope, and its purpose is to By using a linear locking device with a unique structure and a locking part forming means that anyone can easily use, it is possible to quickly and easily attach young shellfish to the aquaculture robe.
Moreover, it is an object of the present invention to provide a method for locking aquaculture tools using an excellent linear locking tool that is also durable. For the above purpose, in the present invention, the linear portion of the linear anchor is compressed and deformed using a rolling means to form a flat portion larger than the wire diameter of the linear portion, thereby locking the shellfish to the rope. It is characterized by the fact that [Example] The present invention will be described in detail below with reference to the drawings. FIGS. 4A and 4B are a front view and a side view of an embodiment of the rolling means 10 for carrying out the method of the present invention, with the cover removed. The rolling means 10 of this embodiment has a front panel 11 and an intermediate panel 12 protruding parallel to each other at a predetermined interval on a base 13, and there are stepped portions at the rear between them.
The rollers 1-1 are supported by rotating shafts 14a, 15a extending between the front panel 11 and the intermediate panel 12 so that the rolling 1-1-rollers 14, 15 are in contact with each other. The rotating shafts 14a and 15a are both extended to the rear of the intermediate panel 12, and are engaged with each other to rotate the driven key 1' in opposite directions at a constant speed.
16 and 17 are numbered respectively. These driven gears 16, 17 are rotated by a drive motor 19 installed on the base 13-H, and in this embodiment, the driven gears 17 are the morph 19.
It meshes with a drive gear 18 attached to. Further, in the front panel 11 of the rolling means 10, a horizontally elongated locking tool insertion hole 9 is bored at a position where the rolling rollers 14 and 15 come into contact. In the present invention, using the rolling means 10 configured as described above, a linear locking tool 1'' having a locking portion 3 provided with an insertion hole 2 at one end as shown in FIG. 3(A), for example, is manufactured. The locking state is as follows.That is, the linear portion 5 of the linear locking tool 1'
After inserting into the insertion hole 2, the free end protruding from the insertion hole 2 is inserted through the large diameter part 9a of the insertion hole 9 provided in the front panel 11 of the rolling means 10, as shown in FIG. Move this to the right. Then, the linear portion 5 passes between the rolling rollers 14 and 15 that rotate at a constant speed, so it is rolled by these rollers, and after passing, the rolling bulge 7 is free as shown in FIG. Formed at the end. The diameter of the insertion hole 2, the diameter of the linear portion 5, or the pressing force of the rolling rollers 14 and 15 are determined so that the rolling bulge 7 is wider than the insertion hole 2 of the locking portion 3. If you do this, the linear locking device l'' will be locked in the state shown in Figure 6, so it can be used to engage and connect various items, especially when locking aquaculture tools to the rope at intervals. 7 to 9 show an example in which the method of the present invention is applied to the cultivation of shellfish such as scallops using a rope, and FIGS. This is an example in which the linear locking tool 1' of (A) is used, and FIG. 9 is not shown in FIG. 3 (B).
This is an example in which a linear locking device 1'' with a rod-shaped locking portion 3'' is used on the 111. Next, open a small hole 22 in the ear 21, pass a thin yet strong connecting string or wire through this hole 22, and hang it from a hanging silk such as a rope 1. This is done by submerging it into the period l)η. Therefore, when applying the method of the present invention to such aquaculture, first insert a linear portion of the linear lock υ, 1゛ into the small hole 22 provided in the ear portion 21 of the scallop 20. 20 scallops
concatenate several. Next, the wire portion 5 is passed through the rope L1 of the rope 23 and then through the insertion hole 2 of the locking portion 3, and the portion of the wire portion 5 protruding from the insertion hole 2 is inserted into the rolling means 10 of FIG. Move it laterally within the hole 9. Then, as shown in FIG. 7, the linear portion 5 is compressed and deformed by the rolling roller, and becomes a rolled bulge portion 7. The rolling bulge 7 prevents the engaging portion 3 from coming off.
The linear anchor 1'' can suspend the scallop 20 from the rope 23 while maintaining its annular shape. FIG. 8 shows another example of the use of the linear locking device 1'', in which the linear portion 5 is first inserted into the string of the linear rope 23”, and then the insertion hole 2 of the locking portion 3 is inserted. , forming a closed loop first. Then, the linear g35 extending outward from the locking part 3 is inserted into the hole 22 of the ear part 21 of the scallop 20 in the same manner as described above, and the end thereof is compressed and deformed using the rolling means 10 in the same manner as described above. , rolling bulges 1 to 7 wider than the hole 22 are formed. Even in this case, the scallop 20 can be suspended from the rope 23 by the linear anchor 1'' and the rolled bulge formed thereon. FIG. 9 shows an example in which the method of the present invention is applied to the linear fastener 1'' shown in FIG. 3(B). The linear part 5 is inserted into the hole 22, and the scallop 20 is locked by the rod-shaped locking part 3'', and then the free α (:I!) of the linear locking tool 1'' is inserted into the rope 23. After inserting the linear part 45 protruding from the rope 23 through the hole 22 of the ear part 21 of the scallop 20, the linear part 45 protruding from the scallop 20 is inserted into the free αii
This scallop moon 20 is fixed by using the rolled bulge 7 by the rolling means 10. In addition, the linear fastener used in the method of the present invention is one in which the wire diameter of the linear portion 5 is uniform, as in the linear fastener 1.1'' shown in FIGS. 3 (Δ) and (+3). Although it is possible to pick up the scallop 20 on the rope 23 using a
Considering the workability of the worker who takes the scallop onto the rope 23 and the small diameter of the hole 22 made in the scallop 20, which is less than 1.5 mm, the linear fastener used in the method of the present invention is The shape shown in FIG. 2 (Δ) is optimal. This linear locking tool 40, not shown in FIG. A large diameter portion 43 is provided. The wire diameter of this large diameter portion 43 is approximately 1.2111 mm, which is slightly thicker than the diameter of the linear portion 41. Insertion hole 4
The diameter of the hole No. 5 is made large enough to allow the large diameter portion 43 to pass through. Further, it is desirable that the wire diameter from the large diameter portion 43 to the free end 42 be tapered. FIG. 2(B) is a plan view of the linear fastening tool 40'' showing the shape of the linear fastening tool 40 shown in FIG. 2(A) before being stretched. It has been put together. If the linear locking device 40'' of the linear locking device 40 is heated, the locking portions 44 and 44 are pulled from both ends, the total length β is extended to about three times, and the linear locking device 40'' is cut at the center portion 46. 2 The linear locking device 40 formed in this way has a tapered free end 42, and a large diameter portion 43 is continuous at a predetermined length behind the free end 1 and 2. Since the wire diameter between the large diameter portion 43 and the locking portion 44 is small and flexible, the wire locking device 40 is inserted into the hole provided in the ear of the scallop.
It is very easy to insert the scallop through the loop 23 or through the loop 23 (also, by rolling and bulging the large diameter part 43, the locking of the scallop and the i+iJ durability are also good ( As described above, the method of locking aquaculture tools according to the present invention uses a linear locking tool LL having a locking portion at one end, and the free end of the locking tool is rolled by the rolling means G. By rolling the bulge into a flat shape, it can be locked to a rope such as a front row (1llt standing shell of a river). In addition, in the method of the present invention, the rolling bulge is attached to the linear part of the linear locking tool. It can be formed anywhere you like, so if you adjust the length of the linear part depending on the number and size of shellfish to be attached to the rope, you can attach it to various shellfish by adjusting the length by tightening or throating. The method of the invention can be used for the cultivation of M. No. 10-1 shows another embodiment of the rolling means 10, in which a drive motor is also provided beside the rolling rollers 14, 15. 19
The rotary cutters 24 and 25 are provided with rotary cutters 24 and 25 that are rotated by According to this rolling means, no matter how long the linear portion 5 of the linear fastener 1 is, the linear portion 5 is moved along the insertion hole 9 when forming the rolled bulge 7. If this is done, unnecessary portions of the linear portion 5 will be cut off by the cutters 24 and 25, so that the length of the linear locking tool 1 in the locked state can always be maintained at an optimum length. It should be noted that the rolling means may not use a rotating rolling roller, but may be one that uses two arms, such as pliers, or one that presses from below, such as a press machine, for rolling. It will be done. [Effects of the Invention] As explained above, the method for locking aquaculture equipment using the linear locking device of the present invention is such that the free end of the linear locking device, which has a locking portion at one end, is After inserting it into the ear of the shellfish and the rope, it is rolled into a flat shape using a rolling means so that it bulges out from the wire diameter, and the rolled bulge is used to lock the shellfish to the aquaculture rope. The work when locking shellfish using a linear locking device can now be done easily and quickly, and the length of the linear locking device can be adjusted to the optimum length. 4. Brief explanation of the drawings Figure 1 (A) is an explanatory drawing showing the conventional scallop farming situation;
Figure 2 (B) is a plan view of an example of a conventional linear anchor for aquaculture, and Figure 2 (A) is a perspective view of an embodiment of the linear anchor used in the method of the present invention, which is close to the actual shape. Figure 3 (B) is a plan view of the linear locking tool (Δ) before stretching, Figure 3 (Δ), (+3)
4 is a perspective view showing an embodiment of a linear fastener used in the method of the present invention, and FIGS. A side view, FIG. 5 is a perspective explanatory view for explaining the locking method of the present invention using the rolling means shown in FIG. 4, and FIG. 6 is a locking of the linear locking tool shown in FIG. 3(A). 7 and 8 are perspective views showing the state, and FIG. FIG. 3(B) is a detailed explanatory view of the present invention using a linear fastener, and FIG. 10 is a 1" front view showing a modification of the rolling means. 1.1', 1", 40 ... Linear locking tool, 2,45・
...Insertion hole, 33', 44...Locking part, 5,41...
- Linear part, 7... Rolled bulge part, 9... Insertion hole, IO
...Rolling means, 11...Front panel, 12...Intermediate panel, 14.15...Rolling roller, 14h, 1
4b...Rolling stepped portion, 16.17...Gear, 18...
・Drive motor, 20...shellfish, 23, 23'...
Rope, 24, 25...cutter. Agent: Patent Attorney Shin Ogawa − Patent Attorney Ken Noguchi Teru Patent Attorney Kazuhiko Saishita

Claims (1)

[Claims] The free end of a synthetic resin linear latching device with a latching portion at one end, or a synthetic resin linear latching device with a latching portion later processed into one end, is attached to the ear of a young shellfish. After inserting it into the aquaculture rope, it is rolled into a flat shape using a rolling means so that it bulges out from the wire diameter, and this rolling bulge allows the linear locking tool to attach the young shellfish to the aquaculture rope. A method for locking aquaculture tools using a large-line locking tool.