KR101361919B1 - Method of composition for shellfish farm - Google Patents

Abstract

Due to the loss of sand and the reduction of sand due to the collection of aggregates in the seas, unfavorable conditions are formed in the clams, and the coastal reclamation project is progressing, which reduces the absolute area of the tidal flats where shellfish can grow. The main composition of the tidal-flat provides a method for improving the quality of shellfish farms, which is made into a new clam fish farm by improving the low-quality structure consisting of nizil. By making up 20% of pearl, 30% of king sand (2mm), and 50% of oyster shells, it is possible to check the composition, material, and amount of mud flats that can be inhabited by the input of oyster shells. To improve the quality of the shellfish farms in the tidal flats, which can improve the production of clams.
In this situation, the absolute area of tidal flats that can be clam-grown is reduced due to the loss of sand and sand reduction due to the collection of aggregates in the sea area. It can be created as a new clam farm.

Description

Shellfish farming method using shellfish {Method of composition for shellfish farm}

The present invention relates to a method of forming a tidal flat farm using shells, and provides a method of forming a new clam farm by adding oyster shells in nizil intertidal zone where clam is difficult to grow.

The total area of shellfish farms in Korea is 45,352 ha, and as of 2009, the total production of shellfish is about 40,000 tons. Despite the fact that shellfish are limited in the increase in production due to the characteristics of tidal flats, the demand for shellfish continues to increase.

Accordingly, the Ministry of Food, Agriculture, Forestry and Fisheries is promoting the "New Tidal Flat Fishing Project" as a new growth strategy industry in the next-generation fisheries industry, and in line with this, the ultimate goal of the New Tidal Flat Fishing Project is to use the results of the structural improvement research for improving the productivity and multipurpose use of shellfish farms. We are securing policy data and technical data that can serve as a role model for the construction of a tidal-flat fishing complex that can be commercialized and scaled up.

As a living creature, the clam ( Japanese littleneck ) is an edible floating filter-eating shellfish commonly found in mud sand or sandy bottoms up to 20m from the intertidal zones all over Korea. There are two types of forms. The individuals distributed in the intertidal zone have a smaller overall size than the subtidal individuals and have a shorter, plump feeling than the height. Flies Individuals in intertidal zones are hunted using hoe at low tide, while subtidal individuals are rescued using tools such as a colander on a ship.

In general, the habitat of clam is 70 ~ 80% of sand and 20 ~ 30% of pearl is known as a good habitat condition. However, the recent offshore farms are known to have lost sand and lost sand due to aggregate collection in the sea. Bad conditions have been formed for aquaculture. In addition, the progress of coastal reclamation projects is reducing the absolute area of tidal-flats where shellfish can inhabit, and even the tidal-flats where the remaining shellfish can be farmed are shrinking due to the influx of land pollutants. It is true.

In addition, in order to activate shellfish production, one of the unique functions of tidal flats, it is necessary to first identify the problems of shellfish farms and to improve the existing shellfish farming structure. For the past 40 years, shellfish farming has caused various problems every year, including loss of seed, overfishing, aging of fisheries, loss of productivity, lack of species, and mass mortality.

The present invention is derived from the results of structural improvement research for improving the productivity and multi-purpose shellfish farms, by inserting the oyster shells in the nizil intertidal zone where the clams are hard to inhabit Provide a method.

In Korean Patent Publication No. 10-06144660, a shell manufactured to a certain size by crushing dried shells as a composition of aquaculture product quality improving agent as a main component, and at least one or more of iron and zeolite, respectively, 0 to By adding 30% by weight as an additional ingredient to fish and shellfish farms, it is possible to continuously improve the quality of the fish and shellfish during the farming period, thereby preventing the fish and shellfish in the farms from being killed due to the poor quality of fish and shellfish. One configuration is disclosed that can greatly improve quality. Korean Patent Publication No. 10-03658930 relates to quality improvement and red tide inhibitors of coastal fish farms and aquaculture fisheries. The quality improvement and red tide inhibitors of coastal fish farms and fish farms are extracted from seawater with respect to 100 wt% of the total formulation. 1.0-2.0 wt% of activated calcium oxide of 200 or more; Iron 0.1-1.0 wt%; The rest is composed of active magnesium hydroxide with an activity of 100 or more to remove low quality organic matter, have no adverse effect on benthic and aquatic organisms, prevent red tide, and inhibit elution of heavy metals to improve low quality. The configuration is disclosed. Korean Patent No. 10-09855450 relates to a method for improving the productivity of a shellfish farm using steelmaking slag generated in the steelmaking process, wherein steelmaking slag having a particle size of 5 mm or less is discriminated among steelmaking slags generated in the steelmaking process. And the step where the fractionated steel slag is covered in the shellfish farm containing the contaminated sediment, and the contaminated sewage and the covered steel slag are mixed with each other in the shellfish farm by tillage and cultivation by the entrant line. A constitution is disclosed. The method related to the improvement of the quality of the farm is to improve the entire unspecified farms for which no target organisms have been determined, and the recent farms aimed at the present invention reduce sands due to sand loss and aggregate collection in the sea area. As a result of poor conditions for clam farming and coastal reclamation projects, the area of tidal flats where shellfish can be reduced is reduced. By improving the difference between the present invention for forming a new clam farm.

The present invention has been made in view of the above purpose, due to the loss of sand and sand reduction due to the collection of aggregates in the sea, such a bad condition is formed in the clam culture, the coastal reclamation project is in progress, so shellfish can inhabit As the absolute area of tidal flats decreases, the main composition of tidal flats, which cannot be grown in clams, provides a method of creating a tidal flat farm using shells through the improvement of low-quality structure consisting of nizil.

In order to solve the above problems, a method of forming a tidal-flat fish farm using shells to improve the low quality of the tidal flats, which are difficult to inhabit, into a low-quality environment of the tidal flats where clams can inhabit by mixing oyster shells, sand and pearls in a certain amount. To provide. In more detail, the common habitat of clams is in areas with 70 to 80% sand and 20 to 30% pearls.

Therefore, the composition of the low quality environment is composed of 20% of pearl, 80% of oyster shell and 20% of pearl, 30% of king sand (2mm) and 50% of oyster shell, and 20% of pearl and sand 80 as a control of the tidal flat. Through the biogrowth environment test, the growth and mortality of the clam in the environment was confirmed, and the composition, material, and amount of mixed tidal flats where the clam could be inhabited by the input of oyster shells were determined. It provides a method of forming a tidal flat farm using shells to improve the quality of the clams.

In addition, the area of the tidal flat with improved quality of the tidal flat is divided into a certain area in order to prevent the tidal flat section composed of clam farming fisheries from being mixed with the surrounding nitrile composition according to the flow of seawater. In addition, it provides a method of forming a tidal flat farm using a shell to pile the circumference of the edge of the predetermined section with a boundary stone of a certain height so as to prevent the mixing of nisin due to the flow of seawater.

According to the present invention, in the situation that the absolute area of the mud flat where the clam culture is reduced due to the loss of sand and the sand reduction due to the collection of aggregates in the sea area is reduced, the main configuration of the mud flat that is impossible to grow the existing clam is a tidal flat quality structure By mixing the oyster shells, sand, and pearls, it is possible to form the existing tidal-flat tidal flats into a fish farm that can be clam-cultured.

1 shows a permeability coefficient experiment apparatus.
Figure 2 shows the material used in the coefficient of permeability experiments (a) sandstone (d50 = 30mm ~ 40mm); (b) sand (d 50 = 0.18 mm); (c) shells.
3 shows a facility view of a tidal flat tank.
Figure 4 shows the changes in the length and weight of the control before the control clam experiment (left) and after the experiment (right).
FIG. 5 shows the mean and mean weight changes of the squares before the experiment (left) and after the experiment (right).
Figure 6 is a photograph showing the material used for the clam farm structure.
Figure 7 shows the process of making the boundary stone of the farm.
8 shows the process of installing the boundary stone of the farm.
9 shows the finished clam test cloth.
Figure 10 shows the results of measuring the length, gross weight, survival rate (%) after clam seed spraying.

According to an embodiment of the present invention, a method of forming a tidal flat farm using a shell includes: defining a section of a predetermined area on the tidal flat; Stacking a boundary stone of a predetermined height on an edge of an area of a predetermined partition to create a weir; Spraying a oyster shell or a mixture of oyster shells and royal sand with a predetermined thickness on the inner tidal flat of the boundary stone; After 5-7 days, the shell is settled on the ground, and then stabilized, characterized by consisting of the step of sprinkling the end of the clam.

In addition, the predetermined height of the boundary stone is 45-55cm, the composition of the constant thickness, which is sprayed on the mud flat, the composition ratio of the mud flat and the oyster shell is 20% by weight: 80% by weight, and the composition ratio of the mixture of the royal sand and the oyster shell and the tidal flat is 30% by weight. 50 wt%: 20 wt%.

Boundary stones stacked at a certain height so as not to be reduced to a high quality of high quality by seawater flow are made by stacking shells made of shell shells or sandstones in a net or by mixing sandstones and polyurethane adhesives in formwork having a certain shape. It may be one or more selected from one hexahedral cube of the light.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1. The quality of the farm Permeability coefficient  Experiment

1) Medium Permeation Test

The permeability coefficient experiment apparatus used in the present invention has a constant flow from the high head to the low head with a hydrostatic head test apparatus having both heights of 2.0 m and 0.8 m, respectively (FIG. 1).

The medium used in the present invention is a total of three types, sand, sandstone, oyster shell collected from the field (Fig. 2). (a) sandstone (d 50 = 30 mm-40 mm); (b) sand (d 50 = 0.18 mm); (c) shells. Each medium was installed in a permeability coefficient experiment apparatus to measure the time passed by a constant flow rate, and the permeability ratio was calculated by comparing the time passed by the flow rate under the condition of an empty tube.

3) Experimental results

As a result of the experiment, the time passed through each medium installed in the permeability coefficient device was found in the order of empty tube, oyster shell, gravel, and sand, and the permeability ratio for empty tube was 12.8% for sand, 24.8% for gravel, and oyster shell. The value was 37.3%.

This result becomes an essential review element for the maintenance of water level during sedimentation, sedimentation and retrieval before and after the site structure in the design of tidal flats. The oyster shell itself has a high permeability, so the water level seems to be a limiting material, but if it is installed in combination with a porous block or boundary structure, the role of oyster shell for improving the quality could be secured.

Permeability Coefficient Experiment Results medium Transit time (sec) Flow rate (m3 / sec) Flow rate ratio (/ guest house) Empty building 2.5 0.00760 1.00000 sand 19.5 0.00097 0.12821 Pebble 10.1 0.00188 0.24752 Oyster shell 6.7 0.00284 0.37313

2. Shellfish farm  Improvement test

1) Indoor experiment for improvement of clam farm

Generally 70 to 80% of sand and 20 to 30% of pearl are known as good habitat conditions for clam culture. However, due to the loss of sand and the reduction of sand due to the collection of aggregates in the sea, bad conditions for clam culture are formed. . Therefore, in the present invention, the indoor experiment to directly observe the effect of the oyster shell input and the practical effect of the spraying amount to create a new shellfish fish farm to improve the quality of the oyster shell in the Nijil intertidal zone where the clam is hard to inhabit And the experiment was made by making a field test. In order to promote the experiment was produced a tidal flat tank as shown in Figure 3 <Figure 3>.

The size of the produced tidal flat tank was 35 cm (H) x 30 cm (W) x 50 cm (L), and a control device was attached so that it could be immersed for 5 hours in 1 hour exposure. The bottom was 2cm thick and coral was covered with a sponge, and then the experimental quality was built up. The experimental water received the experimental breeding stock at 10cm of the 50cm length so that the water rose from the bottom through the coral sand, and it took 30 minutes to fill all the water and 30 minutes to drain the water. Adjusted.

Based on the volume, the composition 1 consisted of 20% pearl, 80% oyster shell, 20% pearl, 30% sand (2mm) and 50% oyster shell, and the control group 20% pearl and sand. 80% (FIG. 5).

Species of clam were collected from Wando, average length of 23.38mm, total weight of 2.84g, and 30 sprayed stocks at 5 ton / ha in the control.

The experimental water temperature was maintained at 18 ° C, and the experimental period was 50 days, and the feed organisms were mixed with Chaetoceros gracilis and Isochrysis galbana in equal proportions to 10 x 10 ⁴ cells. / ml / day was divided into am (10 pm) and evening (6 pm) and supplied. The survival rate, length, and total weight of the clams in the experimental group after the initial and 50 days were examined to see the change.

As a result of the clam shell experiment, the shell and the weight of the clam were increased more than before the experiment. Most of the shell of the clam were uneven before the experiment, but after 50 days, the clam of the clam was changed evenly (Fig. 4).

In the experiment of E2, the length of the clam before the experiment was 20.52mm, but after the experiment, 27.71mm showed a big change of 7.19mm, and in the same experiment, the weight of the clam changed from 2.00g to 4.29g and a large change of 2.29g. In the experimental group of D2, the length of the body showed a change of -4.56mm from 25.29mm to 20.73mm, and there was a tendency to decrease -1.53g from 3.98g to 2.45g in the experimental group of D2. The survival rate of the clams in the experimental group was 1 in the E2 experimental group, and 100% in each experimental group.

The average and standard deviations of the clam shells before the experiment were 23.38 ± 0.10, 24.16 ± 0.10 after the 50 days after the experiment, and the weight was 2.87 ± 0.03 before the experiment and 3.44 ± 0.03 after the 50 days after the experiment. Although there was a change, the change in the control tank and each tank that improved the quality was almost the same (Fig. 5).

In addition, in case of T-test through the statistical processing program, SPSS, the significant probability of length and weight is less than 0.05, and the result value is not significantly different. This is because there is no difference because the growth period of the clam is less than 50 days. Can be.

2) Improved low quality preservation by the formation of clam boundary bank

The boundary bank of the clam has the advantage of dissipation of wave energy due to the distribution of seawater and the impact of breaking wave when it hits the boundary stone and the surface area of seawater can be increased, so that the dissolved oxygen can be minimized. In addition, when the sand or shell is put in for improving the quality of the structural improvement measures, it has the effect of preventing the loss.

The boundary stone of the boundary bank is a test cloth using at least one selected from a pile of shells made of shell shells or sandstones in a net, or a cuboid of a flat side light formed by mixing a sandstone and a polyurethane adhesive in a formwork having a certain shape. Was completed, and the productivity effects of the test cloth and control were analyzed, and the change of low quality and water environment was monitored.

The boundary stone installation work was performed as follows.

A) boundary stone work

The materials used for the clam farm structure are composed of a machine that can mix oyster shells, building waste materials (gravel), gravel and dyes, and plywood used to make structures of dyes and boundary stones as shown in FIG.

The farm structure (boundary stone) is made of plywood, as shown in <Figure 7>, the structure of the boundary stone made of plywood, the structure does not move, and fixed in the fixed frame of the dye mixed gravel and then hardened for about a day to remove the frame from the boundary stone I made it.

B) Boundary stone dropping and test gun work

To facilitate the transport of the boundary stones from the test gun, a thick cloth was wrapped around the bottom of the boundary stone and the boundary stones were tied with a rope to make it easier for people to carry with the iron rods. In order to transport the boundary stone to the clam farm test gun, the vessel was transported to the test gun by high tide at low tide, and the boundary stone was dropped by marking the boundary stone dropping point with the flagged bamboo during low tide (Fig. 8).

The installation of the boundary stone was made by putting the iron rod on the rope tied to the boundary stone at low tide, and people carrying the boundary stone installed the test cloth. The composition of the test cloth was completed after the safety evaluation of the structure to make a height of 40-50 cm by installing a boundary stone (Fig. 9).

In addition to the test cloth, a certain test zone was established to determine the seed spread according to the feed biomass, and a new test zone was established to define the proper spreading rate by varying the stocking of the clam seed.

To test the environmental capacity of the clam, four test zones were installed (1.2m X 1.2m), and the rim was made of wood. Six cells were made in one test cloth and growth and survival rates were sequentially measured. In order to install the clam test zone, 1.2m of wood was used to make a square, and the oyster shell was put into the test zone to improve the quality.

3) Result of productivity improvement test of clam farm

The area of 5 x 5 ㎡ was set in the test fabrics formed on the tidal flats, and the control was set up in the areas where the oyster shells were sprayed and the non-sprinkled areas, and the shells, total weight, and survival rate were measured at three-month intervals. 10>. At this time, after the oyster shell was sprayed with 50cm thickness, the oyster shell was settled on the ground and stabilized.

Experimental results showed that the length and total weight of the oyster shells were increased in the control area than those of the oyster shells, which improved the quality, but the survival rate was higher than 90% after 6 months and 89% after 10 months. Showed a high survival rate. On the other hand, the control group significantly increased the length and total weight, while the survival rate was about 53.7% after 6 months and 50% after 10 months, and the survival rate was much lower than that of the sea area where oyster shells were used to improve the quality. .

From this, it is possible to create a fish farm where clams can be inhabited by mixing materials such as oyster shells with tidal flats made of existing nizil. Compared to the sani, the growth rate is similar to that of cultivated fish farms.

The present invention is to improve the low quality of the tidal-flat structure consisting of nizil is the main configuration of the tidal flat that is impossible to the existing clam culture in the situation that the absolute area of the tidal flat is reduced due to the loss of sand and sand reduction due to aggregate collection in the sea area It is possible to create a new clam farm.

Claims (4)

A) defining a predetermined area of area on the tidal flat;
B) It is a cube of 45-55cm high superhedral light, made by stacking a mesh made of shell shells or sandstones in a net at the edge of a designated compartment, or by mixing a sandstone and a polyurethane adhesive in a mold having a certain shape. Stacking boundary stones of a certain height to create a weir;
C) The oyster shell or oyster shell and royal sand mixture is sprayed on the tidal flat inside the boundary stone of step B) to form a 45-55cm thick layer.The composition ratio of oyster shell and tidal flat is 80% by weight: 20% by weight, and the mixture of royal sand and oyster shell Composition ratio of the tidal flat is 30% by weight: 50% by weight: 20% by weight;
D) 5-7 days after the shell is settled on the ground and stabilized, the method of forming a tidal flat farm using a shell characterized in that the step consisting of sprinkling the end shell of the clam. delete delete delete

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