JP3181957U - Scallop farming equipment - Google Patents

Abstract

[PROBLEMS] To suppress the ups and downs and vibrations of the rope due to waves and undulations, reduce the frequency and degree of closing of scallop shells, increase the intake of food, and promote scallop growth. Provide aquaculture equipment.
A plurality of floating bodies 53 floating on the sea surface, a horizontal rope 5 hung between the floating bodies 53, a plurality of vertical ropes 10 suspended from the horizontal rope 5 and the vertical ropes 10 A scallop culturing apparatus for cultivating scallops by suspending scallops 22 on a plurality of stopped locking pins 21 or by suspending a plurality of ridges for accommodating scallops on a vertical rope 10. It was installed.
[Selection] Figure 1

Description

  The present invention relates to an improvement of a scallop culture apparatus.

  As a scallop shell culture, the scallop shell cultivating and scallop culturing are known in the past. ing.

Utility Model Registration No. 3156673 (FIG. 14)

FIG. 14 of Patent Document 1 showing scallop farming will be described again with reference to FIG. 12 of the present invention.
In addition, the code | symbol was added again.
FIG. 12 shows scallop shell culture, in which a horizontal rope 104 is bound between the distal ends (upper end portions) of anchor ropes 103, 103 fixed to anchors 102, 102 fixed to the seabed 100. Reference numeral 104 denotes a plurality of floating bodies 105... (... represents a plurality, the same applies hereinafter) with intervals in the length direction (lateral direction), and the horizontal rope 104 is held at a predetermined depth below the sea surface 101.

A plurality of vertical ropes 106 are suspended from the horizontal rope 104 at predetermined intervals in the length direction, and each of the vertical ropes 106 is a locking pin at a predetermined pitch in the length direction (vertical direction) of the vertical rope 106. 107 are locked, and the ear pieces of the scallops 108 and 108 are locked to one end or both ends of each locking pin 107 (the figure shows an example in which both ends are locked).
An exposed floating body 109, whose upper half is exposed on the sea surface, is connected to both ends of the horizontal rope 104 and the anchor ropes 103, 103, and serves as a mark for a culture place on the sea surface.
As described above, scallop ear culture is implemented.

FIG. 13 is a detailed view showing scallop ear suspension culture.
Locking pins 107 are passed through the vertical rope 106 at a predetermined pitch and locked by retaining pieces 107b, 107b. The locking portions 107a, 107a at both ends provided with barbs are connected to the ears of the scallops 108, 108. The two scallop ear pieces 108a, 108a are engaged with both ends of the engagement pins 107, 107 through the engagement holes provided in the pieces 108a, 108a.

FIG. 14 is an enlarged view of a main part of FIG.
As shown in the figure, the vertical rope 106 has a large number of locking pins 107... Penetrating in a horizontal direction so as to be orthogonal to the rope, and scallops 108 at both ends of the locking pins 107. ... is locked and held.
The vertical rope is, for example, 10 to 15 m, the length of the locking pins is 7 to 8 cm, and the interval between the locking pins is 10 to 13 cm.

The above-described conventional scallop-cultured scallops are cultivated by engaging scallops with locking pins on vertical ropes 106 suspended in the sea as shown in FIG.
By the way, scallops originally inhabit the sea floor and inhabit and grow in a quiet environment without the influence of waves.
However, in the conventional hanging-type ear-hanging culture in which a vertical rope is hung in the sea and a scallop is locked to the vertical rope, the rope hanging in the sea generates vibrations and vibrations due to waves and swells. There is a problem that poor growth occurs.
The reason for this is that ropes held in the sea with floating bodies such as floating balls and floats to maintain the facilities are subject to waves and swells and vibrations, especially for scallops suspended near the floating body. As a result, scallops often close the shells they normally open, resulting in a decrease in the intake of plankton, which leads to poor growth. It becomes.
There is a similar problem in aquaculture in which a cocoon is suspended in a multi-layered or stacked manner through a rope instead of a locking pin, and a scallop is housed in the cocoon.

The present invention has been made to solve the above problems.
In the present invention, scallops are cultivated by hanging a rope in the sea to suppress the ups and downs and vibrations of the rope caused by waves and swells. An object of the present invention is to provide an aquaculture device that allows a large amount of ingestion and promotes the growth of scallops.

  In order to solve the above-mentioned problem, the invention according to claim 1 is a scallop culture in which scallops are locked to a rope suspended from a floating body via a locking pin, or scallops are cultivated by accommodating scallops in a cage. The apparatus is characterized in that a tension spring is interposed between the floating body and the rope.

  The invention according to claim 2 is the invention according to claim 1, wherein the rope is a floating rope supported horizontally in the sea and suspended from the horizontal rope, and the scallop is locked via a locking pin, or the scallop It is characterized in that a tension spring is interposed between the floating body and the horizontal rope.

  The invention according to claim 3 is the invention according to claim 1 or 2, wherein a part of the floating body is exposed on the sea surface, a tension spring is interposed between the floating body and the horizontal rope, and the scallop shell is suspended from the horizontal rope. It consists of a vertical rope that locks via a locking pin or accommodates a scallop shell via a cage.

  A device according to a fourth aspect is characterized in that, in any one of the first to third aspects, the lower end portion of the vertical rope is separated from the seabed.

  The invention according to claim 5 includes a plurality of floating bodies floating on the sea surface, a horizontal rope suspended between the floating bodies, a plurality of vertical ropes suspended from the horizontal rope, and the vertical ropes locked to the vertical ropes. In a scallop shell culture device that scallops are cultivated by scallop shells suspended by a plurality of locking pins, or by suspending a plurality of ridges that accommodate scallops on a vertical rope, a tension spring is interposed in the vertical rope. .

  The invention according to claim 6 is the invention according to claim 5, wherein the vertical rope is composed of a first rope connected to the horizontal rope and a second rope connected to the first rope and holding a scallop, A tension spring is interposed between the second rope and the second rope.

  A device according to a seventh aspect is characterized in that, in any one of the first to sixth aspects, the flanges at both ends of the tension spring are provided with drop-off preventing portions.

  The device according to claim 8 is characterized in that, in claim 7, the drop-off preventing portion of the tension spring is a C-shaped flange portion provided at the end portion, and a barb is formed at the tip portion of the flange portion.

  The invention according to claim 9 is the invention according to claim 7, wherein the drop-off preventing portion of the collar portion of the tension spring is a C-shaped collar portion provided at an end portion, and a string-like member is stretched between the C portions of the collar portion. It is characterized by a closed loop configuration.

  A device according to a tenth aspect is characterized in that in any one of the first to sixth aspects, a stopper for preventing the elastic spring from extending beyond the elastic limit is provided.

  The invention according to claim 11 is characterized in that, in claim 10, the stopper is a rope suspended between both ends of the tension spring and the connecting portion of the rope.

  The invention according to claim 12 is a floating body that is partially exposed on the sea surface, supports a horizontal rope that is arranged horizontally in the sea, and supports a plurality of vertical ropes suspended from the horizontal rope. In a scallop shell culture device that locks a scallop through a stop pin or accommodates the scallop in a cage and cultivates the scallop, a tension spring is interposed between the floating body and the horizontal rope, and the vertical rope and the horizontal rope It is characterized in that a tension spring is interposed therebetween.

  In the device according to claim 1, in the scallop shell culture device that locks the scallop shell to the rope suspended from the floating body via the locking pin or accommodates the scallop shell in the cage and cultivates the scallop shell, Because the tension spring is interposed between the ropes, the tension spring interposed in the rope absorbs the ups and downs and vibrations acting on the rope suspended in the sea due to the waves and swells, resulting in the waves and swells on the scallops. It can suppress shaking and vibration, reduce the frequency and degree of closing the shell, suppress the decrease in food intake, and promote scallop growth.

  In the device according to claim 2, the rope is a floating rope supported horizontally in the sea, suspended from the horizontal rope, and the scallop is locked via a locking pin, or the scallop is locked via a cage. In addition to the effect of claim 1, the transmission of waves and undulations to the horizontal rope caused by sea surface waves and undulations is made up of the vertical rope to be accommodated and the tension spring is interposed between the floating body and the horizontal rope. Is suppressed, attenuated and absorbed.

  In the device according to claim 3, a part of the floating body is exposed on the sea surface, a tension spring is interposed between the floating body and the horizontal rope, the suspension body is hung from the horizontal rope, and the scallop is engaged through the locking pin. Since it consists of a vertical rope that stops or accommodates scallops via a cage, the transmission of waves and swells to the horizontal ropes caused by sea surface waves and swells in particular is suppressed, attenuated and absorbed.

  In the device according to claim 4, since the lower end portion of the vertical rope is separated from the seabed, in addition to the effect of any one of claims 1 to 3, the vertical rope is caused by natural enemies such as sea stars and dredges. In the unlikely event of food damage, it can be prevented.

  In the device according to claim 5, a plurality of floating bodies floating on the sea surface, a horizontal rope suspended between the floating bodies, a plurality of vertical ropes suspended from the horizontal rope, and the vertical ropes are locked. In the scallop culturing device that scallops are cultivated by scallop shells being suspended by suspending scallops on a plurality of locking pins or by suspending a plurality of ridges containing scallops on a vertical rope, the vertical rope is The tension spring that is stably suspended in the sea and interposed in the vertical rope absorbs the vertical vibrations and vibrations acting on the rope suspended in the sea due to waves and swells, and the scallops are caused by waves and swells on the scallops. It can suppress vibration and vibration, reduce the frequency and degree of closing the shell, suppress a decrease in food intake, and promote scallop growth.

  In the device according to claim 6, the vertical rope is composed of a first rope connected to the horizontal rope and a second rope connected to the first rope and holding a scallop, and the first rope and the second rope. Since the tension spring is interposed between the ropes, the rope is stably suspended and is suspended in the sea by the tension spring interposed between the first rope and the second rope. The up and down vibrations and vibrations acting on the ropes due to waves and swells are absorbed, suppressing the vibrations and vibrations caused by waves and swells on the scallops, reducing the frequency and extent of closing the shells, and reducing food intake. Suppress and encourage growth.

  In the device according to claim 7, since the flanges at both ends of the tension spring are provided with drop-off prevention portions, in addition to the effect of any one of claims 1 to 6, even if there is a wave or swell, The tension spring is securely held on the rope.

  In the device according to claim 8, the drop-off preventing portion of the tension spring is a C-shaped collar provided at the end, and a barb is formed at the tip of the collar, so in addition to the effect of claim 7, A reliable drop-off prevention part having a drop-off prevention function can be obtained with a simple structure.

  In the device according to claim 9, the drop-off preventing portion of the collar portion of the tension spring is a C-shaped collar portion provided at the end portion, and a string-like member is stretched between the C portions of the collar portion to form a closed loop. Therefore, in addition to the effect of the seventh aspect, a reliable drop-off prevention portion having a drop-off prevention function can be obtained with a simple structure.

  In the device according to claim 10, since the stopper for preventing the elastic spring from extending beyond the elastic limit is provided, in addition to the effect of any one of claims 1 to 6, it is dropped at harvest time or in the sea. Since there is no buoyancy, it is possible to prevent the tension spring from extending beyond the elastic limit by applying an excessive load to the tension spring when the rope is pulled up and thrown in.

  According to the eleventh aspect of the present invention, the stopper is a rope that is stretched between both ends of the tension spring and the connecting portion of the rope. Therefore, in addition to the effect of the tenth aspect, the tension spring has a simple structure. Elongation beyond the elastic limit can be prevented.

  According to the twelfth aspect of the present invention, a floating rope that is partially exposed on the surface of the sea is used to support a horizontal rope that is disposed sideways in the sea, and a plurality of vertical ropes are suspended from and supported by the horizontal rope. In a scallop shell culture device that locks a scallop through a stop pin or accommodates the scallop in a cage and cultivates the scallop, a tension spring is interposed between the floating body and the horizontal rope, and the vertical rope and the horizontal rope Since a tension spring is interposed between the tension spring and the horizontal rope, the tension spring is a double tension spring between the vertical rope and the horizontal rope. Vibration can be further suppressed, damped and absorbed.

It is a figure which shows an example of the scallop culture apparatus which concerns on this invention, and is a figure which shows the whole culture apparatus. It is explanatory drawing which shows the connection of a tension | pulling spring, a 1st rope, and a 2nd rope, and is an enlarged view of the principal part of FIG. (A)-(c) is explanatory drawing which shows the absorption effect | action of the wave by the tension | pulling spring, the vibration by a wave, and a vibration. FIG. 4 is a cross-sectional view taken along line 4-4 of FIG. It is a figure which shows an example of the stopper which prevents extension of a tension spring. FIG. 6 is a diagram of another embodiment of FIG. 5. It is a partial explanatory view of a drop spring prevention part of a tension spring. It is a figure of the other Example of FIG. It is a figure which shows the other example of the scallop culture apparatus which concerns on this invention, and is a figure which shows the whole culture apparatus. It is a figure which shows the further another example of the scallop culture apparatus which concerns on this invention, and is a figure which shows a part of culture apparatus. It is a figure which shows another example of the scallop shell culture apparatus which concerns on this invention, and is a figure which shows a part of culture apparatus. It is explanatory drawing which shows the ear suspension culture of the conventional scallop. It is detail drawing of the ear suspension part of a scallop. It is an enlarged view of the principal part of FIG.

It is a figure which shows an example of the scallop culture apparatus which concerns on this invention, and is a figure which shows the whole culture apparatus.
The scallop aquaculture apparatus 1 includes an anchor rope held by an anchor 2 driven into the seabed 51, in the embodiment, two anchor ropes 3, 3 on the left and right sides, and bundling portions 4, 4 at the upper end of the anchor ropes 3, 3. It is composed of a horizontal rope 5 in which both ends are bound, and a plurality of vertical ropes 10 that are suspended (suspended) at a predetermined interval in the length direction (lateral direction) of the horizontal rope 5.

The upper end bundling portions 4 and 4 of the anchor ropes 3 and 3 are connected to an exposed floating body 53... Whose upper half is exposed on the sea surface 52 by a connecting string 54. The intermediate part was connected to the exposed floating body 53 with a connecting string 54. These exposed floating bodies 53 are used as landmarks for aquaculture sites on the sea surface.
In addition, a plurality of floating bodies 55 are connected via a connecting string 56 with a predetermined interval in the length direction of the horizontal rope 5, and the horizontal rope 5 is held at a predetermined depth from the sea surface.

The vertical ropes 10 are composed of a first rope 11 connected to the horizontal rope 5 by binding or the like at its upper end, and a second rope 12 whose lower end is separated from the seabed 51 by a predetermined height.
The first rope 11 and the second rope 12 are connected by a tension spring 13.
The details of the connecting portion are as shown in FIG.

FIG. 2 shows an example of the connection of the ropes 11 and 12, and the ring portion 11 b is provided at the lower end portion 11 a of the first rope 11, while the ring portion 12 b is provided at the upper end portion 12 a of the second rope 12, and the pulling is performed therebetween. Both were connected via a spring 13.
Specifically, the tension spring 13 includes C-shaped flange portions 13 a and 13 b at both ends and a coil portion 13 c therebetween, and one hook portion 13 a is hooked on the ring portion 11 b of the first rope 11. The other hook part 13b was hooked on the ring part 12b of the second rope 12 and locked.

The above-described vertical rope 10, specifically, the second rope 12, is passed through the locking pins 21... Through the longitudinal direction 10 (vertical direction) at a predetermined interval in a transverse direction so as to be orthogonal to the rope 12. Lock sideways.
The end pieces of the scallops 22, 22 are passed through the perforated portions and locked to both ends of the above-described locking pins 21.
The locking pins 21 are resin molded products, and the length of the locking pins is 7 to 8 cm, for example, and is locked to the rope 12 at intervals of 10 to 13 cm.

FIGS. 3A to 3C are explanatory views showing the action of absorbing waves, vibrations and vibrations caused by undulations by a tension spring.
(A) is when the sea level 52 is in a normal state, (b) is when the sea level is elevated relative to (a), and (c) is when the sea level is low relative to (a). Yes, the sea level 52 goes up and down as shown in (a) to (c) due to waves and swells.
As a result, the floating body 53 moves up and down due to the vertical movement of the sea surface, and the vertical rope 10 connected to and supported by the horizontal rope 5 connected to and supported by the floating body 53 is subject to vertical swinging and vibration from the horizontal rope 5.

In the present invention, the upper end of the vertical rope 10 (first rope 11) is connected to the horizontal rope 5, and the lower end of the vertical rope 10 (second rope 12) rises from the seabed 51 by a predetermined distance. 10 (between the first rope 11 and the second rope 12), the tension spring 13 is extended in the state (b) where the sea level is raised from the state (a), and the sea level is lowered ( In the state c), the tension spring 13 is contracted.
Due to the expansion and contraction action of the tension spring 13, the swing and vibration of the vertical rope 10 are absorbed.

  Therefore, the swing and vibration of the rope due to waves and undulations are absorbed and suppressed as much as possible, and the swing and vibration of the vertical rope 10 are absorbed and suppressed. Can be placed in a quiet environment as much as possible, and the frequency and degree of opening and closing of the shell can be reduced, and even a little more food can be consumed, and the growth of scallops can be promoted.

4 is a cross-sectional view taken along line 4-4 of FIG. 2, and is an explanatory view showing a state in which the tension spring is extended.
As shown in the figure, the tension spring 13 extends as described above and can follow up and down changes in the sea surface such as waves and swells. However, when the vertical rope 10 is lifted from the sea during harvesting, the tension spring 13 Excessive weight acts on.

That is, when scallops are harvested, scallops have grown greatly and their weight has increased dramatically compared to that of juveniles, and the ropes and shells have miscellaneous objects such as mussels, barnacles, and sea squirts. In combination with this, the weight when lifting the rope during harvesting becomes extremely large.
In addition, buoyancy is acting in the sea, but buoyancy disappears when it rises from the sea surface. Together, this causes an excessive load to act on the rope.

Therefore, a load exceeding the elastic limit may act on the tension spring 13 during harvesting. Therefore, it is preferable to provide a stopper that prevents the elongation beyond the elastic limit of the tension spring 13.
FIG. 5 is a diagram illustrating an example of a stopper that prevents the extension of the tension spring.
The support fitting 14 is fixed to the binding caulking portion 11c that binds and crimps the ring portion 11b of the first rope 11, and the support fitting 15 is attached to the binding caulking portion 12c that binds and crimps the ring portion 12b of the second rope 12. To fix.

Each of the support fittings 14 and 15 has flange portions 14a and 15a protruding to one side, and a string-like member, for example, a regulation rope made of steel having excellent rust prevention property, between the flange portions 14a and 15a. 16 is connected.
The tension spring 13 is allowed to extend within the range of the length of the restriction rope 16, and the elongation beyond the allowable length of the restriction rope 16 is restricted.
In the embodiment, both end portions 16a, 16a of the regulation rope 16 are fixed to the annular head portions 17a, 17a of the bolts 17, 17, and the bolts 17, 17 are screwed to the flange portions 14a, 15a via nuts 18 ... The length of the regulation rope 16 is supported in an adjustable manner to some extent.

  FIG. 6 is a view showing an example of a stopper for preventing the extension of the tension spring. The binding caulking portions 14A and 15A for caulking the ring portions 11b and 12b of the ropes 11 and 12 are symmetrically protruding to the left and right. It has a portion 14a, 14a, 15a, 15a, and spans two right and left restricting ropes 16A, 16B between these left and right flange portions 14a, 14a, 15a, 15a, and is long with bolts, nuts 17, 18. Is supported in an adjustable manner.

FIG. 7 is a partial explanatory view of a drop spring preventing portion of the tension spring.
Although the above-described ring portion 11b or 12b of the rope 11 or 12 is hooked on the C-shaped flange portion 13a or 13b at the end of the tension spring 13, it is preferable to provide a drop-off prevention portion for preventing the drop-off.
In FIG. 7, a return portion 13e is provided in the C-shaped opening portion 13d of the C-shaped flange portion 13a, and when the ring portion 11b of the rope 11 moves along the C-shaped inner edge of the flange portion 13a, the return portion 13e moves. It is intended to prevent.

FIG. 8 shows another embodiment, in which a string-like member 13h is bridged between both side portions 13f, 13g of the C-shaped opening portion of the collar portion 13a so as to close the opening portion 13d, and the rope 11 is pulled from the opening portion 13d. When the ring portion 11b moves along the C-shaped inner edge of the flange portion 13a, the string-like member 13h prevents the escape.
The string-like member 13h is made of steel having excellent rust prevention properties.

The present embodiment has been described above.
The lower end 12 d of the rope 10 (second rope 12) was separated from the seabed 51. As a result, it is possible to prevent the occurrence of damage caused by natural enemies such as sea stars and spears climbing through the vertical rope 10 and eating scallops.

The vertical rope is, for example, 10 to 13 m. Every 10 to 13 cm, the larva is locked with a locking pin, or accommodated in a cage and suspended, so the number of larvae is extremely large and the rope In addition, the shells grow and become heavy over time, and further, foreign matter such as mussels, barnacles, and sea squirts adhere to it, so that the weight of the rope increases as a whole.
As the scallops grow in this way, the facilities (ropes, etc.) become heavier and become so close to the seabed. In this case, a float (float) is added to increase the buoyancy, the entire facility is floated, and the shoulder 12d is separated from the seabed 51 to prevent food damage.

FIG. 9 is a diagram showing another example of the scallop culture device according to the present invention, and is a diagram showing the entire culture device.
In the figure, the same parts as those in the above-described embodiment are denoted by the same reference numerals and detailed description thereof is omitted.
In this embodiment, the connecting string 56 that holds the horizontal rope 5 supported horizontally in the sea by the exposed floating body 53... Is divided into a first string 56A and a second string 56B. A tension spring 33 is interposed.

  The connection between the first string 56A, the second string 56B, and both ends of the tension spring 33 may be the same as that shown in FIGS. 7 and 8, for example. 5 and the same method as in FIG.

FIG. 10 is a diagram showing still another example of the scallop culture apparatus according to the present invention, and is a diagram showing a part of the culture apparatus.
In the figure, the same parts as those in the above-described embodiment are denoted by the same reference numerals and detailed description thereof is omitted.
In this embodiment, a tension spring 43 is interposed between the exposed floating body 53... Partially exposed on the sea surface 52 and the horizontal rope 5.
The tension spring 43 is interposed in a connecting string 54 that connects the exposed floating body 53 and the horizontal rope 5.

The connecting string 54 is divided into a first string 54A connected to the exposed floating body 53 and a second string 54B connected to the lateral rope 5, with a tension spring 43 interposed therebetween.
The connection between the first string 56A, the second string 56B, and both ends of the tension spring 43 may be the same as that shown in FIGS. 7 and 8, for example. 5 and the same method as in FIG.

FIG. 11 is a diagram showing still another example of the scallop culturing apparatus according to the present invention, and is a diagram showing a part of the culturing apparatus.
In the figure, the same parts as those in the above-described embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
In this embodiment, in addition to the embodiment shown in FIG. 1, a tension spring 43 is interposed between the exposed floating body 53 and the horizontal rope 5, and a tension spring is interposed in the vertical rope 10.
In this way, by providing the tension springs 43 and 13 in a double manner, it is possible to further enhance the oscillation, suppression of vibration, attenuation, and absorption caused by waves, swells, and the like.
Also in this example, the lower end portion of the vertical rope 10 was separated from the seabed 51.

  The connecting portions of the tension springs 43 and 13 and the ropes and strings may be the same as those shown in FIGS. 7 and 8, for example, and the extension preventing means of the tension springs 13 and 43 is, for example, as shown in FIGS. A similar method may be used.

The embodiment has been described above.
In the embodiment, the scallop culture is shown as an ear suspension culture. However, the scallop culture can be similarly carried out in the drooping culture in the form of a cocoon culture in which the vertical ropes are stacked and stacked with cocoons containing the scallops.
Moreover, although the example which divided the vertical rope into 2 was shown in the Example, the structure which connected the end part of the tension | pulling spring to the horizontal rope, for example, and was made into one vertical rope may be sufficient.
Further, although the floating body has been described as an exposed floating body that is partially exposed on the sea and a floating body that is submerged in the sea, it is needless to say that the floating body may be configured by only a large number of exposed floating bodies.

  The present invention can be used for drooping ear-hanging culture and shark culture in the sea of scallops

  DESCRIPTION OF SYMBOLS 1 ... Scallop culture apparatus, 5 ... Horizontal rope, 10 ... Vertical rope, 11 ... 1st rope, 12 ... 2nd rope, 12d ... Lower end part, 13, 33, 43 ... Tensile spring, 13a, 13b ... C-shaped collar part , 13e ... return portion, 13h ... string-like member, 16 ... tension regulating stopper for tension spring, 51 ... seabed, 52 ... sea surface, 53, 55 ... floating body.

Claims (12)

In the scallop cultivating apparatus for scallops that are scalloped to a rope suspended from a floating body via a locking pin,
A tension spring is interposed between the floating body and the rope.
This is a scallop farming device.   The rope includes a horizontal rope supported horizontally in the sea by a floating body, and a vertical rope suspended from the horizontal rope and locking the scallop shell via a locking pin or accommodating the scallop shell via a fence. The scallop shell culture apparatus according to claim 1, wherein a tension spring is interposed between the floating body and the horizontal rope.   A part of the floating body is exposed on the sea surface, a tension spring is interposed between the floating body and the horizontal rope, the suspension is suspended from the horizontal rope, and the scallop is locked through a locking pin, or the scallop The scallop shell culture device according to claim 1, wherein the scallop shell culture device is composed of a vertical rope that accommodates the scallop through a cage.   The scallop culture apparatus according to any one of claims 1 to 3, wherein a lower end portion of the vertical rope is separated from the seabed. A scallop is attached to a plurality of floating bodies floating on the sea surface, a horizontal rope suspended between the floating bodies, a plurality of vertical ropes suspended from the horizontal rope, and a plurality of locking pins locked to the vertical rope. In the scallop culturing apparatus for cultivating scallops by suspending or hanging a plurality of ridges containing scallops on a vertical rope,
A tension spring is interposed in the vertical rope,
This is a scallop farming device. The vertical rope includes a first rope connected to the horizontal rope, and a second rope connected to the first rope and holding the scallop,
A tension spring is interposed between the first rope and the second rope.
The scallop culture apparatus according to claim 5.   The scallop shell culture apparatus according to any one of claims 1 to 6, wherein the flanges at both ends of the tension spring include a drop-off prevention unit.   8. The scallop culture apparatus according to claim 7, wherein the drop-off preventing part of the tension spring is a C-shaped hook part provided at an end part, and a return part is formed at a tip part of the hook part.   The drop-off prevention part of the collar part of the tension spring is a C-shaped collar part provided at an end part, and a string-like member is stretched between the C parts of the collar part to form a closed loop. 7. The scallop culture apparatus according to 7.   The scallop shell culture apparatus according to any one of claims 1 to 6, further comprising a stopper that prevents the tension spring from extending beyond an elastic limit.   The scallop culture apparatus according to claim 10, wherein the stopper is a rope spanned between both end portions of the tension spring and a connecting portion of the vertical and horizontal ropes. A floating body that is partially exposed on the sea surface supports a horizontal rope that is placed sideways in the sea, and several vertical ropes are suspended from the horizontal rope, and scallops are engaged with the vertical rope via locking pins. In a scallop farming device that scallops are cultivated by stopping or housing scallops in a cage,
A tension spring is interposed between the floating body and the horizontal rope,
A tension spring is interposed between the vertical rope and the horizontal rope.
This is a scallop farming device.

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