KR102094038B1 - Culturing method for shellfish using an artficial grass - Google Patents

Abstract

The present invention relates to a method for natural collection and intermediate cultivation of short-necked clams using an improved vortex facility. Provided are a fish seed cultivation device and an intermediate cultivation method using the same, wherein the fish seed cultivation device comprises: a vortex facility which is a virtual structure where one or more pipes having a predetermined diameter are fixed by being space apart from each other by means of a pipe clamp, the pipes facing each other are connected by a coating wire, and a safety net is horizontally installed on an upper portion of the coating wire; and a plurality of seed collectors which are installed in the vortex facility. Accordingly, by generating a vortex in the vortex facility, larva and spats of short-necked clams can be induced to the seed collectors, and the seed collects of the short-necked clams can be quickly and easily moved to an intermediate cultivation place to foster the short-necked clams. Therefore, it is expected to solve a problem of unstable supply and demand of seeds of short-necked clams in the local market. In addition, larva and spats of naturally collected short-necked clams can be quickly moved to the intermediate cultivation place to foster the short-necked clams therein and thus, a survival rate thereof can be maximized. Moreover, by securing a possibility of natural seed collection of infiltrative shellfish, the present invention can be applied to infiltrative shellfish other than the short-necked clams.

Description

{Culturing method for shellfish using an artficial grass}

The present invention relates to a natural seedling and mid-growth method of clams using a vortex facility, in which a pipe of a certain diameter is fixed to one or more spaces via a pipe clamp with a virtual structure structure, and the facing pipes are connected by a coating wire, coated A vortex facility in which a safety net is horizontally installed on the upper part of the wire, and a plurality of drawers are installed in the vortex facility to cause vortices in the vortex facility to induce clam larvae and plaque into the cultivator, and quickly grow the clam cultivator to medium growth. It relates to natural seedling and mid-cultivation method of clams using vortex facilities that can be moved and intermediate-grown.

The clams are bivalve belonging to the Liliaceae family, and there are two types of clams that have been reported in Korea, such as the clams ( Ruditapes philippinarum ) and the baby clams ( Ruditapes variegata ). In general, the varieties used for farming are clams, which inhabit the entire coast of Korea, and are mainly farmed on the west coast. Although some hermaphrodites are found in the clams, most of them are divided into male and female, and are fertilized underwater through spawning and stealing. When the fertilized egg is completed, the polar body is formed and begins cell division. Cell division → loss phase → blastocyst → blastocyst → Damnyunja larvae → D phase larvae → each period → crawling strabismus stage.

The clams are oval-shaped, and there are many radiations on the outer surface of the shell, and they cross the growth vein and become net-like. It is distributed in Japan and China along the coast of Korea. The clams are mainly collected from tidal flats and subtidal zones. They are rich in amino acids and contain iron, zinc, calcium, minerals, and vitamin B12, so they taste very good.

The main habitat of the clam is a bay area with few waves affected by broth, and it is known that there is little base change and the exposure time is about 6 hours. It also inhabits in areas with good distribution of seawater and rich in phytoplankton, a prey organism. In general, the clam is a summer spawning species that spawns in the summer, and is characterized by partial spawning 1-2 times from June to August. Sex maturity of the clam is closely related to seasonal changes in water temperature and prey organisms.

Clams were produced in the 1990s, about 750 thousand tons, but have decreased by about 60% over the past 30 years due to loss of habitat due to the purchase and reclamation of major river areas, aging of fishery, climate change, environmental pollution, and diseases. There are about 2.7 million tons produced. The clam shellfish is a very important variety in the tidal flat shellfish industry of the west coast, with 90% of the shellfish varieties among the shellfish shellfish in the west coast.

However, despite the very important varieties in the industry, the self-sufficiency rate of domestic clam remains at 20-30%. Currently, fishermen rely solely on nature for clam shelling, and all of them are imported from China, and they are very concerned about the outflow of foreign currency. In order to secure stable clam seeds, it can be secured through large-scale artificial seed production and natural seedling. The concept of natural cultivation is a method that installs a cultivator at an appropriate time through a primary spawning period survey and a floating larval survey of invertebrates such as oysters and shells, bird cockle, midduck, and arthropods. It is a method that is being carried out in the south coast.

In the past five years, the production of major bivalve shellfish in Korea has averaged 29,455 tons, a decrease of 57.6% compared to the average of 69,507 tons in the 1990s. On the other hand, imports of bivalve shellfish from foreign countries averaged 40,628 tons in the past five years, showing a steady increase every year. This phenomenon is thought to be because it is mainly dependent on imports from foreign countries as a measure to meet the demand in line with the rapid decline in the production of domestic seafood. The clams produced about 750,000 tons in the 90s, but their habitats decreased due to reclamation and construction of seawalls in major river areas, and the production volume continued to decrease due to climate change, aging of fishery, environmental pollution, and diseases. In recent years, about one third of the 90's have been produced. In addition, clams are a single breed, and the ratio of the West Coast is 90%, which is very high.

Currently, fishermen engaged in marine fisheries rely solely on nature for clam larvae, and the remainder of the cultivation necessary for farming is imported from China. In order to secure a stable clam seedling, it can be secured through large-scale artificial seed production and natural seedling. Manila clam artificial seed production system has been established, but industrialization is not progressing due to low price competitiveness, and the existing method has not been utilized as a natural seedling technology due to the characteristics of the marine environment on the west coast where the difference between tidal waves is large.

The proportion of clam varieties among the West Coast mud flat shellfish is also very high at 90%, and the supply of stable varieties or stable varieties in the West Coast mud flat shellfish industry is unstable. It is necessary to continuously supply about 10,000 tons for stable seed supply, but the West Coast is very different from the tide and the water quality environment is very large, so it is difficult to use the existing method for natural cultivation. Natural seedling for shellfish has not been attempted, and in order to increase the survival rate of clawed larvae and plaques that have been naturally grown, they must be quickly moved to medium growth and nurtured.

Accordingly, the present invention is to provide a natural seedling and mid-cultivation method of clams using a vortex facility to increase the efficiency of harvesting shellfish by utilizing air gaps in artificial grass to establish a natural seedling method on the west coast.

In Korean Patent No. 10-1140647, the method of forming a complex fishing ground facility that simultaneously processes tidal flat clam farming and oyster farming is done by digging the tidal flat to a certain depth so that no harmful organisms in the tidal flat are digging the tunnel. At the bottom of the cut section, there is provided a single cell network with a certain size of mango, and the empty space of the cut section is formed with the mixing ratio of soil, royal sand, oyster shell powder, etc. This article describes how to remedy tidal flat fisheries, including the step of installing aquaculture set structures, aquaculture facilities to create clams and tidal flats in a complex manner, and methods to promote a mixed culture environment for shellfish using them. In Korean Patent No. 10-1533969, the rotary bivalve shell farming apparatus includes a frame structure including a plurality of support frames, upper short frames, upper long frames, lower short frames, and lower long frames; A plurality of form cages rotatably connected to the upper part of the frame structure; An intermediate connection hinge connecting the form cages to each other between the form cages; An intermediate connecting housing integrally formed on one upper side of the frame structure and surrounding and supporting the intermediate connecting hinge; An end connecting hinge connecting the outermost farming cage to one side of the upper shortest frame of the outermost body; And it is integrally formed on one side of the upper shortest frame of the outermost, surrounding and supporting the end connection hinge, the end connection housing that the fixing bar meshes in one direction; Posts about the rotary bivalve farming device comprising a. In Korean Patent No. 10-1632849, a plurality of seedling networks formed vertically on the seabed surface are formed, and at least one or more floats are formed and spaced at the upper and lower parts of the seedling network to be connected in parallel at regular intervals. The buoy and the weight are formed to maintain a state in which the drawing network is vertically extended to the sea floor, and both ends of the drawing network are fixed with a fixing device to fix the drawing network to the sea floor. By providing a method for raising a new hut, it not only facilitates the cultivation of a new hut, but also improves the efficiency of the cultivation, and posts about the new cultivation and intermediate cultivation methods that can save labor in the process. In Korean Patent Registration No. 10-1402683, the tubular body having both ends open; A pair of caps that can be fitted to the opened body; It is composed of an internal positive net that can be internalized inside the main body, and a partition formed of a PE net is formed inside the main body so that two internal positive nets can be internalized in one body so that the plaque and the success or failure are not intertwined. We are launching a tidal flat cultivation network installation platform that can provide a training space to reduce mortality.

Natural shelling of shellfish has been mainly performed by attaching it to oyster shells, scallops shells, nets, etc., mainly from sticky shellfish (oysters, oysters) and temporary sticky shellfish (new cockle), but it is infiltrated on the west coast where the difference between tides is large. Natural seedling for shellfish clams has not been attempted.

Accordingly, the present invention is a virtual structure structure, a pipe of a certain diameter is fixed to one or more spaces via a pipe clamp, the facing pipe is connected by a coating wire, a vortex facility in which a safety net is horizontally installed on the top of the coating wire, The vortex facility is equipped with a plurality of seedling machines to generate vortices in the vortex facility to induce clam larvae and plaques into the cultivator, and provides a method to quickly move and cultivate the clam cultivator to medium growth, thereby preventing clam larvae and plaque. Can be drawn multiple times.

In order to achieve the above object, the natural seedling and mid-cultivation method of the clam using the vortex facility according to an embodiment of the present invention includes the clam resource distribution investigation step (A); Preparation and installation of infiltrating shellfish drawing device (B); Step (C) of joining the larvae to the cultivation plant installed in the tidal flat; Harvesting stage (D); It may be made of the intermediate growth step (E).

The infiltrating shellfish drawing device of step (B) may be installed in a floor-type manner. In addition, the infiltrating shellfish drawing device is a virtual structure in which a pipe of a certain diameter is fixed at least one spaced apart from the floor vertically via a pipe clamp to form a rectangular cross-section rectangular structure, and the parallel pipes are connected to a coating wire. , A vortex facility in which a safety net is horizontally installed above the coated wire; The vortex facility safety net upper or lower tidal flat may have a deposition plate formed of a polygonal structure of a certain size, and a drawing machine formed by combining artificial grass of a certain length on the upper side of the deposition plate.

The artificial turf may be made of synthetic fibers or polymer compounds to limit the movement of the artificial turf in the tidal flat so that infiltrating shellfish larvae can be settled in the gap between the turf and the grass made by the artificial turf.

In addition, the drawing machine is an outer frame constituting the back side of the polygon, and the inner side of the outer frame is a deposition plate on which a mesh made of a nodule mesh is formed; The mesh of the deposition plate mesh may be formed by combining artificial grass of a certain length to a cross section of the cross.

In addition, the drawing machine of the outer frame constituting the back side of the polygon, the inner side of the outer frame, the deposition plate is formed of a mesh made of an intact mesh, and the mesh of the mesh of the deposition plate crosses the cross of a certain length Artificial turf is combined, a through hole is formed in the edge portion of the side of the outer frame and connected to one end of the fixing line via a fixing device, and the other end of the fixed output may be connected to the connecting line of the streak.

The present invention can be expected to solve the problem of supply and demand of the unstable domestic clam clam larvae by installing a virtual structure on the surface of the tidal flat so that the clam larvae and plaque can be effectively drawn, by increasing the cultivation efficiency than the existing tidal flats. It is possible to rapidly move and cultivate plaque to intermediate meat growth, thereby maximizing the survival rate, and also to apply to other infiltrative shellfish other than clams by securing the natural seedling potential of infiltrating shellfish.

1 shows a schematic view of an intermediate breeding method using the seedling breeding apparatus of the infiltrating shellfish of the present invention.
Figure 2 shows a plan view of the seedling breeding apparatus of the infiltrating shellfish of the present invention.
Figure 3 shows a perspective view of the seedling breeding apparatus of the infiltrating shellfish of the present invention.
Figure 4 shows a perspective view of the drawing machine of the present invention.
5 shows a drawing machine example 1 of the present invention.
6 shows a drawing machine example 2 of the present invention.
7 shows Example 3 of the drawing machine of the present invention.
Figure 8 shows the results of the clam larvae and plaques.
Figure 9 shows the results of the natural larvae and plaque natural seedling effect of the present invention.
10 shows the intermediate training apparatus of the present invention.
Figure 11 shows the results of the change in yield in the mid-cultivation clam larvae and plaque harvester of the present invention.
Figure 12 is a schematic diagram of the distribution survey (investigation of the optimum location of the deposited shellfish) in the sporadic natural seed growth site included in step (A) of the present invention.
Figure 13 shows the distribution results of the natural clam clam resource distribution.
Figure 14 shows a schematic diagram of the investigation of sedimentary floating shellfish on the west coast to determine the optimal natural harvesting time.
15 shows a numerical flow diagram of the waters of Jugyo-myeon in Boryeong-si, Chungcheongnam-do.
Figure 16 shows a method for investigating the distribution of calm shellfish growth in spontaneous spermatozoa.
Figure 17 shows the results of sediment particle size analysis for each vertex of natural seed formation.
18 shows a schematic diagram of an investigation of a method for optimally collecting shellfish on the west coast.
Fig. 19 shows the artificial seedling type (bottom type, virtual type) and seedling substrate (oyster shell bead, oyster shell, royal sand, artificial turf), and deposition induction method (vortex facility) for landing crawler larvae.
20 shows a schematic diagram of a natural seedling experiment of calm shellfish.
Fig. 21 shows the results of the effect of depositing shellfish by size distribution.
Figure 22 shows the results of the investigation of the distribution of calm shellfish plaques in the natural growth site.
23 shows the results of a research experiment on the technique of inducing the seedlings of calm shellfish.

The natural vegetable of shellfish is mainly attached to oyster shells, scallop shells, nets, etc., from the attached shellfish (oysters, oysters) and temporarily attached shellfish (new cockle). In Korea, the existing natural harvesting method cannot be introduced on the West Coast, where the difference between tides and tides is large, and in particular, no natural cultivation has been attempted against infiltrating shellfish.

The present invention is a vortex facility that can improve the seeding technique and larvae and plaque attachment rate so that it becomes a natural seedling target for clam larvae and plaques, a seedling breeding device and an apparatus for cultivating infiltrating shellfish that can maximize the efficiency of natural seedling and using the same I would like to provide a method of drawing.

Figure 1 shows a schematic view of the natural seedling and mid-cultivation method of clams using the vortex facility of the present invention. The seedling method using the seedling breeding apparatus of the infiltrating shellfish of the present invention includes a claw resource distribution investigation step (A); Preparation and installation of infiltrating shellfish drawing device (B); Step (C) of joining the larvae to the cultivation plant installed in the tidal flat; Harvesting stage (D); It may be made of the intermediate growth step (E).

Hereinafter, the intermediate breeding method using the seedling breeding apparatus of the infiltrating shellfish according to the present invention will be described in detail as follows. As an embodiment according to the present invention, the infiltrating shellfish is intended to be described as clams, but is not limited thereto.

(A) Research on resource distribution

Eight lines were selected in the 11 km ² sea area of Jugyo-myeon, Boryeong-si, Chungcheongnam-do, and the peaks were selected at 100 m intervals based on the land portion at the time of high tide. The claw resource survey was collected 5 times for each advantage using a 10X10X30cm stainless steel core.

The drilled sediments were divided into 1-3 cm and 4-10 cm, sieved to a mesh size of 500 μm and 6 mm, fixed in 5% formalin, dyed red, and visually classified. As a result of the experiment, E-line 400m points (2,840spat / m ² ) out of the total of 124 vertices in the 8 lines showed the highest distribution of clams, followed by B-line 1,100m points (1,940spat / m ² ).

(B) Preparation and installation steps of the infiltrating shellfish drawing device

Preparation step (B) of the infiltrating shellfish seedling apparatus of the present invention is a step of installing a seedling breeding apparatus of the infiltrating shellfish according to the present invention in a place selected according to the step (A). As an embodiment according to the present invention, the selection site was selected according to the step (A) and selected and installed the 1,100m point of the B line, which has excellent access to fishery and plaque distribution, through the distribution survey of the water resources in the Jugyo-myeon area of Boryeong-si in April 2018. Did.

2 to 3 show a plan view and a perspective view of the seedling breeding apparatus of the infiltrating shellfish of the present invention. The seedling growth value of the present invention is formed in the form of a virtual structure. Seedling growth of infiltrating shellfish can consist of vortex facilities and harvesting plants.

In the vortex facility, one or more pipes of a certain diameter are fixed vertically to the floor through a pipe clamp on a selected tidal flat to form a rectangular structure on a flat cross-section, and the parallel pipes are connected to a coating wire, and on the upper side of the coating wire The safety net is installed horizontally.

The drawing machine is installed on a tidal flat above or below the vortex facility safety net, and consists of a combination of a deposition plate formed of a polygonal structure of a certain size and artificial grass of a certain length on the upper side of the deposition plate.

 In the vortex facility of the present invention, one or more pipes 41 of a certain diameter are fixed vertically to the floor via a pipe clamp (not shown) on a tidal flat selected according to step (A) in the form of a virtual structure. The installation of the pipe forms a rectangular flat cross-sectional structure. In addition, the pipes, which are installed parallel to the left and right, are connected to the coating wire 42, and a safety net 43 may be installed in the horizontal direction on the top of the coating wire.

The vortex facility according to the embodiment of the present invention was fixed so that 6 pipes formed with a diameter of 49 mm and a length of 1.5 m were exposed to both sides of the tidal flat of 6 m * 12 m (72 m ² ) and 6 m around. The pipes are fixed in a set of 2 pieces by 6 pipes with a diameter of 50 mm pipe clamps to form a virtual structure as a whole.

The above-mentioned virtual facility is a rectangular shape, and after installing 4mm diameter coated wires at 12m intervals on the lower 2 and 4m points, the mesh is 20mm wide and the 4m * 12m safety net is horizontal based on the stiff size formed of polyethylene (PE) material. This was installed.

On the right side of the plane of the mesh, the 1st and 4th quadrants are fixed at 2cm intervals by the mesh and the wire, and the remaining quadrants are fixed at 1m intervals for easy fixing and separation using wires. The vortex facility of the present invention has the effect of reducing the labor and time required for the installation of the device by easily installing and separating the device when the net in the facility is installed and collected.

Figure 4 shows a perspective view of the drawing machine of the present invention. The drawing machine of the present invention may be formed by combining a fixed size of the polygonal plate 20 and an artificial grass 10 of a predetermined length on the upper side of the plate. The drawing machine may be installed under one or more of the vortex facility nets. In general, in the case of installing a drawing machine on the mesh, the drawing machine is installed and fixed at 50 cm intervals.

The artificial turf 10 makes it possible to settle the shellfish larvae in the supply between the artificial turf and the artificial turf, thereby facilitating harvesting and increasing the efficiency of harvesting than the existing tidal flats, thereby solving the problem of supplying and receiving unstable domestic clams. .

The drawing machine according to the embodiment of the present invention is made of 28 mm long polyethylene and nylon thread, and artificial turf is installed on the top of a 700 * 430 mm sized plate. The pottery was placed on the bottom of the tidal flat, and 13mm in diameter and 700mm in length were placed in the vicinity of both front and rear edges of the pottery frame to fix the pottery in the tidal flat. The drawing machine was installed on July 17, 2018, and 100 pieces of drawing machines were installed and collected at the same time until October 2 every two weeks.

5 shows a drawing machine example 1 of the present invention. In the drawing machine according to the first embodiment of the present invention, the deposition plate 20 has an outer frame constituting a certain polygonal outer side, and an inner frame formed by crossing a mesh constituting a mesh made of a nodule mesh inside the outer frame. The artificial turf 10 of a certain length may be formed on a side surface crossing the cross of the artificial turf mat.

6 shows a drawing machine example 2 of the present invention. The drawing machine according to Embodiment 2 of the present invention may be formed by attaching and detachably attaching the bottom plate 30 to the bottom of the deposition plate of the structure according to Embodiment 1 above. This is an air gap formed by artificial turf. If shellfish larvae have infiltrated, the artificial turf mat must be inverted and shaken upside down to recover the larvae. It is easy to recover the settled shellfish larvae simply by lightly shaking off the larvae that have passed through the nodule mesh under the deposition plate without turning the plate upside down.

7 shows Example 3 of the drawing machine of the present invention. According to Example 3 of the present invention

In the drawing machine, artificial grass is coupled to the deposition plate made of the outer frame and the inner frame and the inner frame, and a through hole 31 is formed at the edge portion of the outer frame side to secure the fixing device 34. It is connected to one end of the fixing line 32 as a medium, and the other end of the fixing line may be connected to the streak line connecting portion 33.

As an embodiment according to Example 3, the outer frame of the polycarbonate (PC; polycarbonate) material is 745 * 480 * 55mm, the inner frame is formed in a size of 695 * 430 * 35mm, and the outer frame quadrant is about 5cm. A 1 cm diameter through hole is formed.

The fixing line is a diameter of 0.5mm and a length of 1m, which is installed on a conventional oyster-type sewer pipe, and is formed into a ring string with a diameter of 30mm, and the ring knot is fixed by pressing with a compactor using a compression sleeve 36SQ.

The fixing device 34 is formed of a stainless steel stainless steel stainless steel stainless steel structure and can be connected to the through holes and the fixing line rings to connect the deposition plate and the fixing line. The connecting line of the continuous line is a conventional snap shape, and the other end of the fixing line is integrally connected by means of a connecting line having a diameter of 0.5 mm and a length of 50 cm.

(C) larval seedling stage

Larval seedling step (C) of the present invention is a step of drawing latent shellfish larvae in a drawing machine installed according to step (B). In order to confirm the larvae in the cultivator, sediment was separated and sediment was separated by size using 1mm, 600㎛, and 150㎛ mesh in seawater, and the sediment was fixed with 5% formalin. After staining with Rose bengal reagent. Subsequently, they were transferred to the laboratory and visually separated the infiltrating shellfish in the sediment. For accurate counting, they were accurately judged under a stereo microscope and counted using a counter.

Figure 8 shows the results of the clam larvae and plaques. Spanning between July 2018 and September clam spat result of natural chaemyo, unit area (m ²⁾ the shellfish spat amount August 16 il 100 333 L / m ^2, 8 wol 29 il 37 183 L / m ^2, 9 chaemyo per May 12, 61033 L / m ^2, with two days in October were chaemyo 9517 L / m ^2.

Figure 9 shows the results of the natural larvae and plaque natural seedling effect of the present invention. When converted to 100 pieces of clam harvesters, a total of 6,242,000 were drawn on August 16 with 3,010,000 losses, August 29 with 1,115,500 losses, September 12 with 1,831,000 losses, and October 2 with 285,500 losses. Pear (August 29) showed high seedling effect.

(D) Collection stage

After the drawing is completed, the drawing machine removes the iron core fixed to the tidal flat. If the drawing machine is the drawing machine according to FIG. 7, it is moved to the intermediate meat growth as it is, or if it is not, the medium drawing machine is replaced with the intermediate growing machine according to FIG. 7.

(E) Intermediate development stage

The medium growth is accomplished by installing a medium growth device in water at a depth of about 1.8m. 10 shows the intermediate training apparatus of the present invention. The intermediate meat growth value according to the present invention includes a plurality of fixing devices 300 fixedly installed on the seabed surface; A continuous rope 200 connected to one side of the fixing device and installed parallel to the sea level; It is connected to the streak rope is connected to one or more rich 100 is installed at regular intervals is installed; The streak rope may be formed by connecting the medium-growing cultivator of the present invention.

Intermediate meat growth according to an embodiment of the present invention is a conventional festival farm made of an area of 100 * 100m, and a fixing device of a pile structure is fixed at both ends of the festival farm, and a streak rope made of polypropylene material having a diameter of 1 cm is connected to the end of the pile. , A plurality of 20L rich may be installed at 2m intervals, and 400L rich may be installed at 10m intervals on the continuous rope.

The drawing machine for intermediate growth, which has reached intermediate growth, is installed at 50 cm intervals on the continuous rope by connecting a connecting ring and a fixing line. Each time a part of the drawing machine (20 * 10cm) was cut out, surface sediments of the same area were collected from the control (natural tidal flat), and the amount of clam cultivation was counted.

Figure 11 shows the results of the change in yield in the mid-cultivation clam larvae and plaque harvester of the present invention. The mid-growing clam plaque took some samples (20 x 10 cm) at intervals of 2 weeks, and the size distribution and survival rate were determined by sifting through a 0.5 mm mesh sieve in consideration of the growth of the plaque, and the survival rate was 69.8-97.5% during the study period. It was stable. Of the approximately 6 million plaques drawn from the tidal flats, individuals who grew to 0.5-5 mm in size after 2 months were estimated to be 1.3 million plaques. In the case of clam plaques drawn on August 16, plaques of 0.5 mm or larger in size over time It was observed that the amount increased.

Experimental Example 1. Larval distribution of major shellfish farms on the west coast

FIG. 12 is a schematic diagram of distribution investigation (investigation of the optimum location for depositing shellfish) in the sporadic natural seed growth site included in step (A) of the present invention. The test site was targeted at 11.4km2 of Jugyo-myeon, Boryeong-si, Chungcheongnam-do, the place where natural spoils occurred, and in March 2017, four lines (AD) were used for 5 times using 10X10X30 cm2 cores at 100m intervals based on the boundary line between the water level line and the ground. It was collected repeatedly. The collected sediments were cut about 1-10 cm long, and the clams were separated using 5 mm and 0.5 mm sieve, and the size was measured and divided into 5 stages by size.

A total of 49 245 samples were collected from the natural spawning site of the clam, and the density was in the range of 0-1,017 individuals / m2, with the highest B-line (0-1,017 individuals / m2) and C-line (0-750 individuals). / m2) → D line (0-700 objects / m2) → A line (0-367 objects / m2). By branch, it was mainly distributed at the points of 600-1,300m, and the range of 100-500m was 0-100 objects / m2, mainly Upogebia major. Finally, as shown in Fig. 13, the optimal location of the shellfish shellfish was determined to be 900-1,000m (783-1,017 individuals / m2) of the B line.

Figure 14 shows a schematic diagram of the investigation of sedimentary floating shellfish on the west coast to determine the optimal natural harvesting time. In order to determine the optimal time for planting natural shellfish, we conducted a weekly floating larval survey from June 21 to October 31, 2017. The peak of the survey was the area of the existing natural erosion site and was surveyed at three peaks (top, middle, bottom) on three lines (A-C). As a material used in the vertical projection, a bonnet having a diameter of 30 cm (25 µm) was used and fixed with 5% formalin. After the fixation was completed, the samples were classified under an optical microscope (Olympus, BX41) into D-type, prismatic and attachment groups.

The calm shellfish floating larvae observed during the investigation period were 0-14,400 individuals / ton and C peak (D-type: 6,400 individuals / ton; each period: 6,400 individuals / ton; adherent: 1,600) on September 1, 2017. (Individuals / ton). It was confirmed that the floating larvae were mainly distributed in the middle and the middle part of the intertidal zone rather than the upper part of the intertidal zone, and more larvae were observed at a little time (less seawater flow) than in the sari. In particular, larvae and landing were normal only in the middle and lower regions of the C line, and almost no A-B line larvae were observed (D-type larval → adherence, survival rate 19.7%).

As a predicted cause of adherence larvae only in line C, the flow of algae flows from A to C as shown in FIG. 15, and the adherent larvae have died because they failed to live on lines A and B, or the second larvae. It is thought that there may be cases where C lines are gathered.

As such, the larval distribution information of the main shellfish farms on the west coast is used as a very important data to understand the state of the fishery, so it is necessary to continuously accumulate larval resource data, and accordingly, it is very helpful in understanding the rapidly changing tidal flat environment (reducing the amount of resources, pirates, etc.). It is believed to be.

Experimental Example 2. Investigation of the distribution of sedimentary shellfish cultivation in the spawning spout

Figure 16 shows a method for investigating the distribution of calm shellfish growth in spontaneous spermatozoa. The test site was the B peak of the existing study area of the main bridge, and the sedentary shellfish distribution within the same peak as the clam distribution survey point was examined every other week from August 8 to October 23. Each vertex was collected three times using a 20X20cm frame, and the collected samples were separated by visual observation of sediments and plaques using 1mm, 600㎛, and 150㎛ sieve.

22 is a result of the investigation of the distribution of calm shellfish plaques in the spontaneous growth site. As a result of investigating the distribution of sedimentary shellfish in the natural growth site, the middle and lower part (800-1,100m) of the intertidal zone showed a high distribution of plaque (210-3,644 individuals / m2), and the average survival rate of the plaque was 35.3%. In particular, the clam population observed at the top of the intertidal zone (100-500m) on September 6 is judged to be the result of joining the larvae spawned in mid-August (8/8, 8/17) in early August. This kind of calm shellfish survey can be used as data that can effectively use, preserve and restore existing fishery.

Figure 17 shows the results of sediment particle size analysis for each vertex of natural seed formation. The average particle size of the sediment at the lower and middle peaks of the intertidal zone (800-1,100m), which had the highest plaque distribution, was 2.1-3.7, 1.4-4.3% of gravel, 45.1-83.0% of sand, and 1.8-7.6% of nitrile + clay.

In the upper part of the intertidal zone, where the rate of plaque adhesion was poor, the ratio of nitrile + clay was more than 50% (52.2-73.8%). However, such a sedimentary environment is a sedimentary environment in which clams can be formed (gochang / pants cultured: gravel 0.5%, sandy 26.4%, nitrile + clay 73.1%), but there are large numbers of upogebia majors in this area, so Filter feeder, Dia a burrow) is thought to have a negative effect on plaque attachment.

Experimental Example 3. Optimal method of harvesting shellfish on the west coast

18 shows a schematic diagram of an investigation of a method for optimally collecting shellfish on the west coast. Calm shellfish inhabiting the west coast generally have a life history in which females and males are fertilized by warming and waiting in the water, and D-type larvae → Damnyunja larvae → Crawler larvae settle on the substrate.

Fig. 19 shows the artificial seedling type (bottom type, virtual type) and seedling substrate (oyster shell bead, oyster shell, royal sand, artificial turf), deposition induction method (vortex facility), and experiment example 3 is used. In order to find out the optimal method of drawing.

In March 2017, the 900-1,100m point of the B line with the highest distribution was selected as the peak through the distribution survey of the clam resources in the Jugyo-myeon area.The oyster shell beads (4mm) and oyster shells (3 ~ 4cm) using oyster shells were used as a drawing technique. The royal sand (3 ~ 4mm) and artificial grass (23 ~ 28mm) were used, and the floor type and the virtual type were selected as the style of drawing for the characteristics of the west coast.

In addition, 180cm piles were installed at 1m intervals in front, rear, left, and right of the floor-type and virtual-type facilities for induction of deposition. The cultivation facility was installed on July 13, 2017, and every other week until October 23, the cultivation of cultivation techniques was established and new cultivation techniques were installed.

The overall experimental schematic diagram is shown in FIG. 20. The drawn substrate was separated sediment using 1 mm, 600 µm, and 150 µm sieve, and the sediments separated were fixed with 5% formalin and stained with Rose bengal reagent. Subsequently, it was moved to the laboratory to separate the sedimentary shellfish in the sediment with the naked eye. 1mm and 600㎛ were able to separate, but in the case of 150㎛, the amount of sediment collected was large and counted as a sub-sample and estimated by converting it to the sediment amount. .

FIG. 21 shows the results of the deposition of shellfish shellfish by size distribution, and FIG. 23 shows the results of a research experiment on the deposition of shellfish shellfish induction technique. The most effective type of seedling was 'floor-type' as a result of investigating the calming shellfish cultivation technique. As for the cultivation technique, 'artificial grass' and vortex facilities for induction of deposition were 71 times higher than the control, and the survival rate of plaque was 47.1%. .

Most of the settled shellfish that is drawn is 0.15-0.6mm long, and it is necessary to carry out a total investigation of the plaque in 150㎛ sediment to calculate the accurate rate of seedling. It is judged that the effective harvesting period will be appropriate from mid-August to early September.

It is considered that it is necessary to advance the harvesting time of the harvesting machine (before 2 weeks to 1 week) because the existing floor-type method is used, but the sediment deposition rate is very fast after installing the drawing machine. In addition, the newly enrolled (seeded) clams have a survival rate of 1.2% after 9 months, and they die rapidly within 2 months after landing, so it is important to move to medium-growth quickly after harvesting in order to increase the survival rate of harvested calm shellfish. It is necessary to develop the existing natural seedling technology in order to ensure smooth supply and demand.

The present invention can improve productivity by increasing natural cultivation efficiency of clams from existing tidal flats through the development of improved vortex facilities and intermediate cultivation equipment, so that it is possible to increase the productivity of fishery by expanding the aquaculture base and developing the fisheries field as well as improving the international competitiveness of aquaculture technology. There is a potential industrial availability.

10: artificial grass 20: deposition plate
30: bottom plate 31: through
32: Fixing line 33: Continuous line connection
41: pipe 42: coated wire
43: safety net
100: rich 200: winning streak
300: fixture

Claims (6)

delete delete delete delete A plurality of fixing devices fixedly installed on the sea floor; A continuous rope connected to one side of the fixing device and installed parallel to the sea level; A rich person connected to the streak rope and installed at least one at regular intervals;
The outer frame constituting the outer side of the polygon, and the inner side of the outer frame, a deposition plate on which a mesh made of a nodule mesh is formed,
Artificial grass of a certain length is coupled to the cross section of the mesh of the mesh of the deposition plate, and a through hole is formed in the edge portion of the side of the outer frame, connected to one end of the fixing line through a fixing device, and the other end of the fixing line Chaemyogi connected to the connecting line of the streak;
The cultivation line connecting part of the cultivation line is connected to the continuation rope and is fixed in plurality. The outer frame constituting the outer side of the regular polygon and the inner side of the outer frame are composed of a mesh plate made of a mesh of nodule mesh, and a certain artificial turf is coupled at regular intervals to a portion where the mesh of the mesh crosses the cross. The bottom plate is attached to the bottom plate so that it can be detached, and natural padding and mid-cultivation of clams using vortex facilities, characterized by using a cultivator that allows the infiltrating shellfish larvae to settle in the gap between the grass and the grass made by the artificial turf. Way

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