KR102474707B1 - guidance equipment for landing of shellfish - Google Patents

Abstract

The present invention relates to a device for inducing a shellfish landing, and more specifically to the device for inducing a shellfish landing which is installed in the intertidal zone and forms a vertical vortex and slows down a flow to form an optimal environment for shellfish to land, thereby allowing the shellfish to be landed more easily. In order to achieve the purpose, the device for inducing a shellfish landing comprises: a main pillar installed at regular intervals in the intertidal zone; and a net installed on the main pillar. The net is installed on both sides of the main pillar, and is installed to be inclined outward as going downward.

Description

Guidance equipment for landing of shellfish}

The present invention relates to an apparatus for inducing young plaque landing, and more particularly, it is installed in the intertidal zone to form a vortex in the vertical direction as well as to form an optimal environment in which young plaque can be settled by slowing the flow rate, thereby making it easier for young plaque to settle. It relates to a device for inducing a chakjeo chakjeo that allows it to be chakjeo.

Clams are bivalves belonging to the Liliaceae family, and the types of clams reported in Korea include Ruditapes philippinarum and Ruditapes variegata. In general, the variety used for aquaculture is clams, which live all over the coast of Korea and are mainly farmed in the west coast.

Although some hermaphrodites are found in these clams, most of them are hermaphroditic, with females and males divided, and are fertilized in the water through eggs and eggs. The fertilized clam egg starts cell division as polar bodies are formed. It grows in the stages of cell division→mortal stage→blastocyst stage→growth stage→growth stage→d-phase larvae→angular stage→growth stage, and settles down in search of a substrate to infiltrate.

The clam is an oval shape, and there are many radial ribs on the outer surface of the shell, and the growth veins intersect to form a net pattern. It is distributed in all coastal areas of Korea as well as the coasts of Japan and China. Clams are mainly collected from the intertidal and subtidal zones of tidal flats, and are rich in amino acids and contain iron, zinc, calcium, minerals, and vitamin B12.

In general, clams are summer spawning species that spawn in summer, and are characterized by partial spawning once or twice in the water temperature of 20 ~ 25℃ from June to August. There is a close relationship.

By the way, clams as described above are transformed into young shells after going through the larval stage, and there is a problem in that a large amount of young shells do not survive due to failure of the landing site when the landing environment is not good.

So, in order to solve this problem, the technology described in Korean Registered Patent No. 10-1397762 (registered on May 14, 2014) as shown in FIG. A lower fixing plate to hold, a support rod having a diameter of 32 to 50 mm connected to the lower fixing plate, and a vortex generating plate having an area of 500 to 1,000 mm in width and 250 to 500 mm in length on the top of the support rod is connected at a certain angle to the support rod to be characterized

However, the technology described in Korean Patent Registration No. 10-1397762 (registered on May 14, 2014) installs a vortex generating plate on the upper part of the support to form a vortex, creating an environment of tidal flats so that young shells can land easily There is an advantage that can be done, but since the vortex generating plate is formed in a plate shape, the flow speed increases in the space formed between the vortex generating plates. There is a problem.

Korean Registered Patent No. 10-1397762 (registered on May 14, 2014)

The present invention has been made to solve the above problems, and the object of the present invention is composed of a plurality of main struts installed at regular intervals in the intertidal zone and a mesh net installed to be inclined on both sides of the main strut to vortex in an up and down direction In addition to forming, by slowing the flow rate of seawater, it is to provide an induction device that allows the young to be worn more easily.

And, another object of the present invention is to form two layers of nets installed on both sides of the main props to more stably reduce the flow rate, and also to connect the fixed ropes for fixing the nets to the support ropes installed to support the main props. It is to provide an induction device that can be connected and stably supported even in the flow of seawater.

The present invention to solve these problems;

It is characterized in that it consists of a main prop installed at regular intervals in the intertidal zone and a net installed on the main prop.

Here, the mesh is installed on both sides of the main support, characterized in that it is installed so as to be inclined outward toward the bottom.

At this time, the mesh is characterized in that it is installed in two layers.

In addition, a support rope is installed on both sides of the main prop, and the upper end of the support rope is connected to the upper end of the main prop, and the lower end is connected to a fixing pack installed on the floor.

Here, the upper end of the net is connected to the upper end of the main support, and the end of the fixed rope connected to the lower end is characterized in that connected to the fixed pack.

At this time, the fixed rope is characterized in that a connection rope connected to the support rope is further installed.

In addition, the lower end of the net is characterized in that it is spaced 30 ~ 60cm from the floor.

According to the present invention having the above configuration, the water depth is composed of a plurality of main supports installed at regular intervals on the tidal flats and a net installed to be inclined on both sides of the main supports. , there is an effect of enabling the young plate to be installed more easily.

In addition, the present invention not only reduces the flow rate more stably by forming two layers of nets installed on both sides of the main props, but also connects the fixed ropes for fixing the nets to the support ropes installed to support the main props with connecting ropes to seawater. There is an effect that can be stably supported even in the flow of.

1 is a conceptual diagram of a conventional chipae chakjeo induction device.
Figure 2 is a perspective view of the chipae chakjeo induction device according to the present invention.
Figure 3 is a front view of the chipae chakjeo induction device according to the present invention.
Figure 4 is a graph showing the change in flow rate after installation of the chipae chakjeo induction device according to the present invention.
5 is a graph showing the change in seabed quality after installation of the sapphire mounting bottom induction device according to the present invention.
Figure 6 is a graph showing the change in classification degree after installation of the chipae chakjeo induction device according to the present invention.
7 is an exemplary view of installing the chipae chakjeo induction device according to the present invention in a cross direction.
Figure 8 is a perspective view of installing the chipae chakjeo induction device according to the present invention in a vertical form.
Figure 9 is a perspective view of installing the chipae chakjeo induction device according to the present invention in a horizontal form.
Figure 10 is a comparison table compared by type of chipae chakjeo induction device according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. The same reference numerals are used for the same components in the drawings, and redundant descriptions of the same components are omitted. And, it should be understood that the present invention may be embodied in many different forms and is not limited to the described embodiments.

Figure 2 is a perspective view of a toothpaste chakjeo induction device according to the present invention, Figure 3 is a front view of the toothpaste chakjeo induction device according to the present invention, Figure 4 is a graph showing the change in flow rate after installation of the toothpaste chakjeo induction device according to the present invention Figure 5 is a graph showing the change in seabed quality after installation of the induction device for induction device according to the present invention, Figure 6 is a graph showing the change in classification after installation of the induction device for induction device according to the present invention, 7 is an exemplary view of installing the toothpaste induction device according to the present invention in the cross direction, Figure 8 is a perspective view of installing the toothpaste induction device according to the present invention in a vertical form, Figure 9 is the induction of the toothpaste attachment according to the present invention It is a perspective view of the device installed in a horizontal form, and Figure 10 is a comparison table for each type of chipae chakjeo induction device according to the present invention.

As shown in FIGS. 2 to 6, the present invention relates to a lagoon induction device, and its configuration is constant in the intertidal zone, which is exposed to the surface of the water at low tide when the sea level is low and submerged below the water surface at high tide when the sea level is high according to the tidal change. It may be made of a main holding 100 installed at intervals and a net 200 installed on the main holding 100.

Here, the net 200 not only reduces the flow rate of seawater generated by tidal changes, etc., but also generates vortices in the process of colliding with the net 200, changing the state of the tidal flat to a state in which it is easy for small shells to settle By doing so, it is possible to stably mount the clams, such as clams.

In addition, the mesh 200 may be formed in a size of 400 cm in width X 500 cm in length, and the mesh forming the mesh 200 may be formed in a size of 20 cm X 20 cm.

Here, the net 200 may be installed on both sides of the main post 100, and by being installed so as to be inclined outward from the top to the bottom, it is possible to stably withstand the load applied when seawater flows.

At this time, there may be some error in the size of the mesh, but if it is formed excessively large, there may be a problem that the flow rate is not sufficiently reduced, and if formed excessively small, excessive load is applied to the mesh 200 As a result, a problem of deterioration in durability may occur.

On the other hand, the main support 100 is inserted into the floor and installed, and a support rope 110 may be installed on both sides of the main support 100, and the upper end of the support rope 110 is the main support 100 ), and the lower end is connected to the fixing pack 120 installed on the floor to support the main post 100 so as not to shake.

Here, the top of the net 200 may be directly coupled to the top of the main holding 100, or may be connected by connecting a separate fixing rope 210 as shown in the drawing, the main holding 100 Although not shown in the drawing, the top of the fixing rope 210 or the net 200 is fixed by providing a fixing member (not shown) at the top of the ).

At this time, the fixed rope 210 is connected to the lower end of the net 200, and the lower end of the fixed rope 210 is connected to the fixing pack 120 installed on the floor, so that the net 200 is spread diagonally. is installed to

So, as described above, it is possible to stably support the load applied to the net 200 and the main post 100 when seawater flows.

In addition, an auxiliary support rope 112 may be further installed in an outward direction along the longitudinal direction of the net 200 in the main support 100 installed at the end of the net 200, the auxiliary support rope 112 ), it is possible to support the main post 100 more firmly.

At this time, a connection rope 220 may be further provided in the fixed rope 210 connected to the lower part of the net 200, and the connection rope 220 connects the support rope 110 and the fixed rope 210. By doing so, the load applied to the net 200 is distributed to the support rope 110 so that the net 200 can more stably support the load of seawater, thereby increasing overall durability.

In addition, the net 200 installed on the main column 100 may be installed in a single layer as shown in the drawing, but may also be installed in a double layer, by installing the net 200 in a double layer, seawater By applying a stronger resistance to the flow, the flow rate can be made slower, and accordingly, more vertical vortices can be formed, thereby creating a better landing environment.

At this time, the lower end of the net 200 installed on the main post 100 may be installed so as to be 50 cm apart from the floor. By installing the net 200 so as to be 30 to 60 cm apart from the floor, It prevents sediments from being deposited around the net 200 according to the flow rate so that sea water can move stably.

Thus, it is possible to prevent deterioration of the environment for the landing of the young plate.

That is, the environment for the clams to settle is the flow velocity of 0.3 to 0.4 m/s or less, the average particle size of the seabed is 1.8 (Ø) or less, the classification is 1.4 (Ø) or more, sand and clay (silt and clay) The ratio of 8:2 is considered optimal. If the ratio of clay to sand is too high, it may be difficult for the young to move up and down.

For the experiment, after spawning, the eggplant induction device according to the present invention was installed. Let's compare the environment before and after installing the eggplant induction device of the present invention described above.

First, in the case of the flow rate, as shown in FIG. 4, as measured in a temporarily installed state, the measured flow rate sometimes shows a flow rate of 0.5 m / s, but mostly shows a flow rate slower than 0.3 m / s.

Next, looking at the composition ratio of the seafloor sediment, as shown in FIG. 5, the ratio of sand to clay (silt and clay) was 8.9:1.1 before installation, and 8.3:1.7 two months after installation. After 8 months, it is 8.2:1.8, and it can be seen that it is close to 8:2, which is an ideal environment.

Next, looking at the change in the classification diagram expressing the particle size distribution range and the degree of dispersion of the sediment, as shown in FIG. It is 1.79 (Ø), and the classification degree is 1.95 (Ø) at the time of 8 months after installation, and the classification degree has changed to poor over time.

Finally, the density of the young larvae increased by 60.1% after the installation of the juvenile induction device of the present invention compared to before installation. Considering this fact, the changed marine environment (vortex, decrease in flow rate, Improvement of seabed quality, etc.) shows a positive effect in terms of population increase.

On the other hand, the induction device of the present invention may be installed adjacently in front and rear or left and right, but as shown in FIG. 7, it is installed in a cross shape to stably reduce the flow rate even if the moving direction of seawater is not constant and It allows the formation of vortexes so that the small plates can be settled more stably.

For comparison, using the same net, as shown in FIGS. 8 and 9, respectively, vertical and horizontal chipping bottom induction devices were configured and compared with the present invention (oblique shape).

Here, looking at the characteristics of each type of the induction device of the present invention, as shown in Figure 10, in the case of installation convenience, the diagonal and vertical types are shown to be intermediate, and in the case of the horizontal type, the height is not high, so it is easy It can be installed easily and can be evaluated as a prize.

In the case of the rate of decrease in flow rate, in the case of the diagonal type, the flow rate is greatly reduced, in the case of the horizontal type, the decrease in the flow rate is insignificant, and in the case of the vertical type, it is reduced to some extent, but the decrease is smaller than that of the diagonal type.

In addition, the high rate of decrease in flow velocity means that the resistance to the flow velocity is high, and the vortex generated accordingly also increases, so that the quality of the seabed can be changed more quickly.

On the other hand, looking at the durability, in the case of the oblique and vertical types, which are greatly affected by the flow rate, the durability is lower than the horizontal type, but the durability is not bad when viewed as a whole in consideration of the fact that it is supported by the support rope 110, etc. is evaluated as

After installation, as time elapses, the degree of attachment of organisms living in the sea is difficult because the oblique and vertical types have high resistance to flow speed, so it is difficult for organisms to attach, and only a small amount is attached. Since it is not large, it is relatively easy for organisms to attach to it, so that a large amount of organisms attach to it.

In this regard, since many marine organisms are attached to the net 200 in a short time, the net 200 must be replaced every year in the case of a horizontal type, but in the case of a diagonal type and a vertical type, since many marine organisms are not attached to the net 200. The mesh 200 may be replaced every two years.

Therefore, it can be seen that the present invention (diagonal shape) is most effective compared to the vertical or horizontal type for inducing the bottom of the young plate.

Although preferred embodiments of the present invention have been described above, the scope of the present invention is not limited thereto, and the spirit of the present invention extends to those within the scope substantially equivalent to the embodiments of the present invention. Various modifications and implementations are possible by those skilled in the art to which the present invention pertains within the scope that does not deviate from the above.

The present invention relates to an apparatus for inducing young plaque landing, and more particularly, it is installed in the intertidal zone to form a vortex in the vertical direction as well as to form an optimal environment in which young plaque can be settled by slowing the flow rate, thereby making it easier for young plaque to settle. It relates to a device for inducing a chakjeo chakjeo that allows it to be chakjeo.

100: main holding 110: support rope
120: fixed pack 200: net
210: fixed rope 220: connecting rope

Claims (7)

It consists of a main prop installed at regular intervals in the intertidal zone and a net installed on the main prop,
The mesh is installed on both sides of the main support, and is installed so as to be inclined outward as it goes downward,
The mesh is installed in two layers,
A fixed rope is connected to the lower end of the net, and the lower end of the fixed rope is connected to a fixed pack,
Support ropes are installed on both sides of the main support, and a connection rope connected to the support rope is installed on the fixed rope to distribute the load applied to the net to the support rope,
In order to prevent sediments from being deposited around the net due to the flow rate slowed by the net, the lower end of the net is spaced 30 to 60 cm from the bottom,
A small decker induction device characterized in that it stably reduces the flow rate even if the moving direction of seawater is not constant by installing the decking induction device in a cross shape.
delete delete According to claim 1,
The upper end of the support rope is connected to the upper end of the main support, and the lower end is connected to a fixing pack installed on the floor.
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