KR101352950B1 - Artificial structure for transplanting seagrass and marine ecosystem restoration method using thereof - Google Patents

Abstract

The two rods are connected to each other by X-shape or fifteen shape by a hinge axis, and the two rods are each 45 to 45 in an uncompressed state, with both ends thereof coupled to each of the two rods forming the support. Composed of a compression spring to form a cabinet of 135 degrees, the center of the hinge axis provides a seaweed transplant tool and a marine ecosystem restoration method characterized in that the through hole through which the seaweed can be inserted and fixed is formed.

Description

Artificial structure for transplanting seagrass and marine ecosystem restoration method using

The present invention relates to a seaweed transplant tool and a method for restoring marine ecosystem using the same.

Domestic coastal waters are being devastated by indiscriminate coastal development, diversification of fishery styles, increase in bottom form, increase in fishery quantity, rise in winter water temperature due to global warming, coastal pollution and whitening (algae whitening). In order to restore the damaged marine ecosystem and to protect the offshore fisheries, a sea forest development project is being continuously carried out.

The sea forest project is to recover the disappeared seaweed in the sea due to the bleaching phenomenon and to restore the useful fishery resources and the marine ecosystem by creating a stable ecological environment in the sea. When these sea forests are formed, phytoplankton and zooplankton are concentrated, as well as meat shelters and spawning places, and new fisheries are formed, which results in an increase in catches more than twice. In this way, the sea forest project has been extended to protect the fish stocks as it has proven to be effective by continuous experimentation and observation.

Seagrass is a flowering plant with roots, stems and leaves. In Korea, Zostera marina and Phyllospadix species belong to Zosteraceae.

In order to create an ocean forest, a method of artificially transplanting seaweed is generally used. For example, there are a method of dropping a seaweed graft in a clay ball and dropping it in water in a coater, a method of adhering grafts using an epoxy to an underwater rock bed, a method of hanging adult grafts with a stone, And a method in which seaweed is implanted into a rope and introduced into water.

However, the above-described conventional techniques have problems in that artificial structures are not adhered to the underwater floor, that seaweed actually roots and survive low, and that marine pollution is caused by the toxicity of chemicals used to adhere seaweeds Therefore, it is urgent to solve these problems.

The present invention is to solve the problems of the prior art as described above, it is an object of the present invention to provide a seaweed transplantation tool and a method of restoring the marine ecosystem using a simple structure, easy to use, excellent seaweed retention.

According to the present invention,

A support in which two rods are joined by a hinge axis in an X shape or a thirteen shape, and

Each of the two rods forming the support, each end of the two ends are combined with a compression spring to allow the two rods to form an internal angle of 45 ~ 135 degrees in an uncompressed state,

The hinge axis center provides a seaweed transplant tool, characterized in that a through hole through which seaweed can be inserted and fixed.

In the present invention, one or more through holes for inserting and fixing seaweeds may be further formed on the support.

In the present invention, a spike may be further provided at the distal end of each of the two rods forming the support.

In the present invention, the seaweed transplant tool may further include a rod-shaped spike fixing body coupled downwards to the inner end of each of the two rods forming the support, the angle 60 to 120 degrees, In this case, the spike may be fixed to form an internal angle of 30 to 120 degrees in the upper direction and the outer surface of the body for fixing the spike.

In the present invention, the end portion of each of the two rods forming the support may be further provided with a length extension means for extending the length of the rod.

In the present invention, the two rods forming the support may be made of stainless steel, FRP or reinforced plastic material.

Further, according to the present invention,

As a seaweed transplant method using the seaweed transplant tool,

Forming a hole in the rock into which the seaweed implant tool can be inserted;

Inserting and securing seaweed into the through hole of the seaweed implantation tool;

Compressing a compression spring by pressing two rods forming a support of the seaweed implantation tool into which the seaweed is inserted; And

A method for transplanting seaweeds, comprising placing the seaweed transplantation tool in the compressed spring compressed state in an insertion hole of a pre-formed seaweed transplantation tool, and releasing and fixing the pressure.

The step of inserting and fixing seaweed into the through hole of the seaweed transplantation tool may be performed after performing the step of securing the seaweed transplantation tool to the insertion hole of the seaweed transplantation tool.

The seaweed transplant tool of the present invention is not only simple to use by utilizing a compression spring, but also enables to securely fix the seaweed transplant seedlings to the sea bedrock and sand topography despite the simple structure.

Thus, seaweeds are prevented from being lost due to waves, algae, and the like, thereby providing an effect of more stably forming a seaweed community.

 In addition, the seaweed transplantation tool of the present invention can be applied to a variety of seabed topography by having a rod length extension means and various types of spikes, the industrial utility value is very high.

In addition, if the seaweed transplantation tool of the present invention is used, since the seaweed can be stably reproduced in large quantities, the coastal ecosystem can be expected to restore and increase coastal fishery productivity.

1 to 5 schematically show one embodiment of the seaweed implant tool of the present invention.
6 is a view showing the seaweed transplantation tool of the present invention installed on the rock.
7 shows experimental conditions when testing the performance of the seaweed transplantation tool of the present invention.
Figure 8 is a graph showing the survival rate of the experimental group compared to the control group using the seaweed transplant tool of the present invention.

The present invention

A support in which two rods are joined by a hinge axis in an X shape or a thirteen shape, and

Each of the two rods forming the support, each end of the two ends are combined with a compression spring to allow the two rods to form an internal angle of 45 ~ 135 degrees in an uncompressed state,

The hinge shaft center relates to a seaweed transplant tool, characterized in that a through hole through which seaweed is inserted and fixed.

Seaweed transplant tool of the present invention is not only easy to use by utilizing the compression spring, it is characterized in that despite the simple structure, the seaweed transplant seedlings can be firmly fixed to the sea bedrock and sand topography.

In addition,

As a seaweed transplant method using the seaweed transplant tool,

Forming a hole in the rock into which the seaweed implant tool can be inserted;

Inserting and securing seaweed into the through hole of the seaweed implantation tool;

Compressing a compression spring by pressing two rods forming a support of the seaweed implantation tool into which the seaweed is inserted; And

A method for transplanting seaweeds, comprising placing the seaweed implantation tool in the compressed spring compressed state in an insertion hole of a pre-formed seaweed implantation tool, and releasing and fixing the pressure.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, well-known functions or constructions are not described in detail since they would unnecessarily obscure the gist of the present invention.

1 to 5 schematically show one embodiment of the seaweed implant tool of the present invention.

Referring to FIG. 1, the seaweed transplantation tool of the present invention includes a support 10 having two rods coupled to each other by a hinge shaft 20 in an X shape or a thirteen shape, and each of the two rods forming the support. Compression springs 30 which allow the two rods to form an internal angle of 45 to 135 degrees in an uncompressed state by combining both ends by one end, and through holes through which seaweed can be inserted and fixed at the center of the hinge shaft 20 ( 40).

As a rod constituting the support 10, a cylindrical rod, a square rod, and the like may be used, but it is preferable to use a square rod in terms of manufacturing and installation. However, the present invention is not limited thereto.

In addition, as the material of the rod, stainless steel, fiber reinforced plastic (FRP), or reinforced plastic may be used, but is not limited thereto. Particularly, a material which does not rust in seawater can be preferably used.

The hinge shaft 20 is rotatably coupled to the two rods forming the support 10 with respect to each other, characterized in that the through hole 40 is formed in the center seaweed can be inserted and fixed. . The hinge shaft 20 may be used without limitation as is known in the art, it is preferable to use a material of the nature that does not rust in sea water.

The through hole 40 is a structure for inserting and fixing seaweeds to an implantation tool. The size of the through-hole 40 can be inserted into the seaweed, the size of the seaweed is implanted, preferably enough to grow, the shape of the through-hole is not particularly limited, round, oval, square, etc. Can be formed.

In addition, as a structure for inserting and fixing the seaweed to the implantation tool, the through hole may be formed on the support 10 in the required number. In this case, it is possible to obtain the effect of fixing a plurality of seaweeds using one seaweed transplant tool.

The compression spring 30 is coupled to both ends by one end to each of the two rods forming the support 10 so that the two rods form an internal angle of 45 to 135 degrees without being compressed. The cabinet is more preferably 45 to 90 degrees, but is not limited thereto, and those skilled in the art can appropriately adjust according to the flow of algae, the speed of the algae, the size and shape of the life forms formed on the rock to install the seaweed transplant tool.

In addition, one or two or more compression springs 30 may be provided on the support 10, which may be selected according to the topographical characteristics of installing the seaweed implant tool. For example, when the flow of algae is strong or the surface of the rock is smooth and a position where more fixing force of the implantation tool is required, the implantation tool may be configured by increasing the number of the compression springs 30.

Seaweed transplantation tool according to the present invention, by using the compression spring 30, not only the installation of the seaweed transplantation tool is simple, but also can be used very useful for transplantation of seaweeds because the seaweed fixation force is improved.

FIG. 2 illustrates a form in which the spike 50 is further provided on the seaweed transplantation tool shown in FIG. 1.

In the present invention, the spike 50 serves to improve the fixing force of the seaweed transplant tool by increasing the frictional force between the installation site of the seaweed transplant tool and the seaweed transplant tool. Therefore, those known in the art can be used without any particular limitation as long as they meet this purpose. For example, nails, pins, and the like, and projections made of a material such as rubber and the like having excellent frictional force may be used.

The spike 50 may be provided at the distal end of each of the two rods forming the support 10, and fixed to the distal end of the rod directly to the spike-like spikes, or in a separate spike fixing body Fixed spikes such as nails, and may be provided by fixing the spike fixing body to the distal end of the rod.

The number of spikes 50 may be adjusted in consideration of the fixing force required for the seaweed implant tool.

As the material of the spike 50, stainless steel, fiber reinforced plastic (FRP), reinforced plastic material, rubber having excellent friction with rock, etc. may be used, and in particular, it may be preferably used that does not rust in seawater.

3 shows a seaweed transplant tool having spikes 50 on the seaweed implant tool using a spike fixation body 60.

In the present invention, the spike fixing body 60 may be used in the form of a rod coupled downward to form an inner angle of 60 to 120 degrees, preferably 90 degrees, at the distal ends of the two rods forming the support 10. However, the present invention is not limited thereto. In this case, the spike 50 may be fixed to the outer surface of the spike fixing body 60 to form an inner angle of 30 to 120 degrees, preferably 30 to 90 degrees in the upward direction. However, the present invention is not limited thereto.

When fixing the spike 50 using the rod-shaped spike fixing body 60 as described above, it is possible to install in a hole formed in the rock, of course, can be fixed by driving in the soil soft soil, such as sand fields There is an advantage. Therefore, in this case, the rod used as the spike fixing body 60 is preferably the end of the acrosome. The length of the rod can be adjusted according to the environment of the installation site of the seaweed implantation tool, and the same material as the two rods forming the support 10 can be used.

FIG. 4 shows a seaweed implant tool further comprising an extension means 70 in the configuration of FIG. 1.

The extension means 70 is provided at the distal end of each of the two rods forming the support 10. The extension means 70 allows the transverse length of the support 10 to be extended or shortened, thereby allowing flexible application of the seaweed implant tool according to the installation site. The extension means 70 may be provided by applying a known technique. For example, the extension means 70 may be configured by a method of slidably installing a separate rod that can be used for length extension at the two rod end portions forming the support 10.

FIG. 5 shows a seaweed transplant tool further comprising spikes 50 in the configuration of FIG. 4. Such seaweed implant tool has the advantage of providing a high holding force as well as being able to adjust the length according to the installation terrain by having a spike 50 with the extension means (70).

Figure 6 shows the seaweed transplantation tool of the present invention installed on the rock.

7 shows experimental conditions when testing the performance of the seaweed transplantation tool of the present invention.

Figure 8 is a graph showing the survival rate of the experimental group compared to the control group using the seaweed transplant tool of the present invention.

The seaweed transplantation tool according to the present invention can be used for transplanting all kinds of seaweeds inhabiting sand or rock, for example, Phyllospadix or Zostera, which is a seaweed of Zosteraceae inhabiting in Korea. marina) can be used to implant it into the seabed.

The installation of the seaweed transplantation tool according to the present invention may be performed by, for example, installing the transplantation tool directly on the seabed terrain, or installing the transplantation tool first on a rock or the like on land, and dropping the rock on which the transplantation tool is installed to the seabed. Can be.

The installation of the seaweed transplantation tool of the present invention forms a hole in the rock through which the seaweed transplantation tool can be inserted, inserts and secures the seaweed in the through hole of the seaweed transplantation tool, and the seaweed implantation tool, Compressing the compression spring by pressing the two rods forming the support, placing the seaweed implant tool with the compressed spring compressed in the insertion hole of the pre-formed seaweed implant tool, and releasing the pressure to fix it. Can be implemented.

The step of inserting and fixing seaweed into the through hole of the seaweed transplantation tool may be performed after performing the step of securing the seaweed transplantation tool to the insertion hole of the seaweed transplantation tool.

Seaweed transplantation tool according to the present invention is preferably installed in a gloss layer in which seaweed can inhabit, and can be generally installed at a depth of 0 ~ 20m.

Hereinafter, the present invention will be described in more detail with reference to examples. However, the following examples illustrate the present invention and the present invention is not limited thereto.

Example  1. Survival test of the algae through the seaweed transplantation tool of the present invention

Survival of the algae through the seaweed transplantation tool of the present invention was tested in Garolman Bay's inner high wave retreat (N36 54 56.0 E126 20 00.2 ~ N36 55 11.2 E126 19 37.6). This area is the area that shows the most widespread habitat of Zalpi in the inner side of Garorim Bay. In the investigation method, two 5x5m compartments were selected and divided into a control group and an experimental group. The 30 algae in natural habitats in the control group were implanted with 30 algae using the seaweed transplantation tool of the present invention made of stainless steel in the experimental group (Fig. 7). Survival of the bark was investigated through the escape lock of the bivalve with time. In order to exclude the additional members, only the individuals having the best length of 50cm or more used in the experiment were used. A total of eight investigations were conducted for 180 days from the time of installation of the seaweed transplantation tool of the present invention. In the case of the control group, natural dwarf communities, 17 individuals decreased during the survey period, and finally 13 individuals survived and the survival rate was 43.3%. In the experimental group, 11 individuals were reduced during the irradiation time and 19 survived, and the survival rate was 63.3%. The results are shown in FIG. 8. In the experiment, the survival rate difference between the control group and the experimental group was found to have a significant effect of the seaweed transplant tool of the present invention to about 20.0%.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

10: support 20: hinge axis
30: compression spring 40: through hole
50: spike 60: body for fixing the spike
70: extension 80: rock

Claims (8)

A support in which two rods are joined by a hinge axis in an X shape or a thirteen shape, and
Each of the two rods forming the support, each end of the two ends are combined with a compression spring to allow the two rods to form an internal angle of 45 ~ 135 degrees in an uncompressed state,
Seaweed implant tool, characterized in that the through-hole is formed in the center of the hinge axis can be inserted and fixed seaweed. The method according to claim 1,
And at least one through hole for inserting and securing seaweeds on said support. The method according to claim 1,
Seaweed transplantation tool, characterized in that the spike is further provided at the distal end of each of the two rods forming the support. The method of claim 3,
The seaweed transplant tool further comprises a rod-shaped spike fixing body coupled downwards at an inner end of each of the two rods forming the support, the inner angle of 60 ~ 120 degrees, the spike is fixed to the spike fixing body Seaweed transplant tool, characterized in that fixed to form an interior of 30 to 120 degrees in the outer direction and the upward direction. The method according to claim 1,
The seaweed transplant tool, characterized in that the end portion of each of the two rods forming the support is further provided with a length extension means for extending the length of the rod. The method according to claim 1,
Two rods forming the support are seaweed transplant tools, characterized in that made of stainless steel, FRP or reinforced plastics material. A seaweed transplantation method using the seaweed transplantation tool of claim 1,
Forming a hole in the rock into which the seaweed implant tool can be inserted;
Inserting and securing seaweed into the through hole of the seaweed implantation tool;
Compressing a compression spring by pressing two rods forming a support of the seaweed implantation tool into which the seaweed is inserted;
And placing the seaweed implantation tool in the compressed spring compressed state in the insertion hole of the pre-formed seaweed implantation tool, and releasing the pressure to fix the seaweed implantation tool. 8. The method of claim 7, wherein the step of inserting and fixing the seaweed into the through hole of the seaweed transplantation tool is performed after the step of fixing the seaweed transplantation tool to the insertion hole of the seaweed transplantation tool.

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