KR101346681B1 - Artificial container for transplanting seagrass and marine ecosystem restoration method using thereof - Google Patents

Abstract

The present invention relates to a seaweed transplant container, specifically, the port-type transplant container is a port body portion to which the seaweed is implanted in the inner space and to facilitate the insertion of the transplant container in the seaweed transplant site, the bottom of the body portion It consists of a tapered acrosome from the edge toward the central axis of the body portion, characterized in that one or more spikes are formed on the outer surface of the port body portion.

Description

Artificial container for transplanting seagrass and marine ecosystem restoration method using

The present invention relates to a seaweed transplant container and a method for restoring a 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 to provide a seaweed transplant container and a marine ecosystem restoration method using the same, easy to use, excellent seaweed fixing ability, growth and reproduction effect.

The present invention

In the port-shaped seaweed transplant container,

Port body part where seaweed is implanted in the inner space

A tapered acrosome from the edge of the bottom of the body portion towards the central axis of the body portion to facilitate insertion of the graft container into the seaweed transplant site,

The outer surface of the port body portion provides a seaweed transplant container, characterized in that one or more spikes are formed.

In the present invention, the spike may form an angle of 110 to 150 degrees in the downward direction and the outer surface of the port body portion.

In the present invention, the spike may form an angle of 20 to 90 degrees in the upper direction and the outer surface of the port body portion.

In the present invention, the spike may be formed of a rod having a semi-circular or triangular cross section, and may be fixed to a plane included in a semi-circular or triangular rod on a surface facing the port body.

In the present invention, the body portion may be formed in a cylindrical shape, the acrosome may be formed in a cone shape.

In the present invention, the seaweed transplant container may be made of a biodegradable polymer material.

Further, according to the present invention,

As a seaweed transplant method using the seaweed transplant container,

Transplanting the seaweed into the seaweed transplant container; And

Provided is a method of transplanting seaweeds comprising the step of inserting and fixing the seaweed transplant container transplanted with seaweeds in the seaweed transplantation site in the step.

Transplanting seaweed into the seaweed transplant container may include sowing the seaweed seeds in the seaweed transplant container, or transplanting seedlings.

The seaweed transplant container of the present invention is very convenient because it can be sown, grown, transplanted to a transplant site using a single container. In addition, since the seaweeds grown in the seaweed transplant container can be transplanted with the transplant container, it provides an effect of greatly improving the survival rate of seaweed at the transplant site.

In addition, by providing a spike on the outer surface of the seaweed transplant container, the ability to fix the seaweed to the transplant site is very excellent, thereby preventing the loss of seaweed caused by waves or algae, and provides the effect of forming a seaweed colony more stably. do.

In addition, by providing a tapered acrosome from the edge of the bottom of the body toward the central axis of the body, installation to the implantation site is facilitated.

1 is a view schematically showing an embodiment of the seaweed transplant container of the present invention.
2 is a view showing a state in which the seaweed transplant container of the present invention is installed on the sand topography.
3 shows experimental conditions when testing the performance of the seaweed transplant container of the present invention.
Figure 4 is a graph showing the survival rate of the experimental group compared to the control group using the seaweed transplant container of the present invention.

The present invention

In the port-shaped seaweed transplant container,

Port body part where seaweed is implanted in the inner space

A tapered acrosome from the edge of the bottom of the body portion towards the central axis of the body portion to facilitate insertion of the graft container into the seaweed transplant site,

The outer surface of the port body portion relates to a seaweed transplant container, characterized in that one or more spikes are formed.

The seaweed transplant container of the present invention has spikes and acrosomes, so that it is easy to install at the transplant site, and the seaweeds can be secured to the transplant site. It is very convenient because it can use a container.

Further, according to the present invention,

As a seaweed transplant method using the seaweed transplant container,

Transplanting the seaweed into the seaweed transplant container; And

It relates to a method for transplanting seaweeds comprising the step of fixing the seaweeds transplant container implanted with seaweeds in the step to the seaweeds transplant site.

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 is a view schematically showing an embodiment of the seaweed transplant container of the present invention.

Referring to Figure 1, the seaweed transplant container 10 of the present invention is to facilitate the insertion of the port container portion 10 and the transplant container to the seaweed transplant site, the seaweed is implanted into the inner space, the bottom of the body portion 10 It consists of a tapered acrosome 20 toward the central axis of the body portion from the edge, characterized in that at least one spike 30 is formed on the outer surface of the port body portion 10.

The body portion 10 may be formed in various forms, including cylindrical, polygonal, elliptic, and the like. The acrosome 20 is preferably formed according to the shape of the body portion 10. For example, when the body portion has a cylindrical shape, it is preferable that the body portion is formed in a conical shape.

In the present invention, the body portion 10 and the acrosome portion 20 may be made of a material such as biodegradable polymer, stainless steel, fiber reinforced plastic (FRP) or reinforced plastic. When manufacturing a transplant container using a biodegradable polymer material, after transplanting the seaweed transplant container to the transplant site, the transplant container is gradually degraded as the seaweed grows, thereby preventing marine ecosystem pollution that may be caused by the installation of artificial structures. There is an advantage that can be.

The spike 30 is provided on the outer surface of the port body portion 10 serves to improve the fixing force of the seaweeds transplant container by increasing the frictional force between the installation place of the seaweeds transplant container and the seaweeds transplant container. Therefore, those known in the art can be used without any particular limitation as long as they meet this purpose. For example, nails and pins can be used, and protrusions made of a material such as rubber having excellent frictional force can be used.

The spike 30 is formed on at least one outer surface of the port body portion 10, the spike is 110 to 160 degrees, more preferably 130 to 150 degrees in the downward direction and the outer surface of the port body portion It is preferably provided to form. Spikes formed at such an angle serve to allow the implant container to be well embedded in sand terrain and the like.

In addition, the spike 30 is preferably provided to form an angle of 20 to 90 degrees, more preferably 45 to 90 degrees in the upper direction and the outer surface of the port body portion. This angle of formation of the spike 30 prevents the once fixed seaweed fixation tool from easily exiting from the sand terrain or the like, thus improving the fixation force of the fixation tool.

 In the present invention, the spike 30 may be formed of a rod having a semicircular or triangular cross section, and in this case, a plane included in a semicircular or triangular rod is fixed to a surface facing the port body portion. desirable. However, the present invention is not limited thereto. When the portion of the spike facing the port body portion is a semi-circle or a triangular plane under the above-described conditions, when the transplant container is installed in a sand terrain or the like, there is an effect of improving the fixing force that prevents the transplant container from exiting therefrom. In addition, when the spike 30 is installed in the form described above, a semicircular arc shape or a triangular pointed shape is positioned below the spike 30 facing the installation place, and the spike 30 is placed on a sand terrain or the like. When plugged in, it makes installation easier.

The number of spikes 30 may be adjusted in consideration of the fixing force required for the seaweed fixing tool.

The spike 30 may be manufactured using a material such as a biodegradable polymer, stainless steel, fiber reinforced plastic (FRP) or reinforced plastic, but is not limited thereto. Particularly, a material which does not rust in seawater can be preferably used.

2 is a view showing a state of use of the seaweed transplant container of the present invention.

The seaweed transplant container according to the present invention can be used for transplanting all kinds of seaweeds inhabiting the sand topography, for example, can be used to transplant Zostera marina, a seaweed of Zosteraceae inhabiting Korea. Can be.

In the seaweed transplant container according to the present invention, since the seaweed seeds or seedlings are grown in the transplant container inner space and grown to adults, the seaweed transplant container according to the present invention can be installed with the seaweeds. When used, the process from the growth of the seaweed to the transplantation can be made very simple.

In addition, it has a positive buoyancy buoyancy, it is not easy to grow and secure it to the seabed, but in the case of the seaweed transplant container according to the present invention attached to the sand terrain more easily due to the seaweed transplant container weight and spikes can do.

The seaweed transplant container according to the present invention is preferably installed in a gloss layer in which seaweed can inhabit, and can generally be installed at a depth of 0 to 20m.

3 shows experimental conditions when testing the performance of the seaweed transplant container of the present invention.

Figure 4 is a graph showing the survival rate of the experimental group compared to the control group using the seaweed transplant container of the present invention.

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

Example  1. Survival test of the algae using the seaweed transplant container of the present invention

Survival of the algae through the seaweed transplant container of the present invention was tested in the garrison bay inner high wave north bovine habitat (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 in the inner side of Garorim Bay, and it is suitable for experimenting with the effect of the seaweed transplant container according to the present invention. Irradiation method was selected in two 5x5m compartment divided into a control group and an experimental group, and 30 groups of jaalpi in natural habitats in the control group, 30 groups of jaalpi were transplanted using the seaweed transplant container of the present invention made of stainless steel in the experimental group (Fig. See 3). Survival of zalpi was examined through the dropping of the zalpi individuals with time. In addition, only the individuals with a longest length of 50 cm or more used in the experiment were used to exclude additional members. A total of eight irradiations were conducted for 180 days from the time of installation of the seaweed transplant container of the present invention. In the case of the control group, 17 individuals were reduced during the investigation period and finally 13 survived, and the survival rate was 43.3%. In the experimental group, 10 individuals were reduced during the irradiation time and 20 survived, and the survival rate was 66.7%. The results are shown in Fig. The survival rate difference between the control group and the experimental group in the experiment was confirmed to have a significant effect of the seaweed transplant container of the present invention about 23.4%.

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: port body 20: acrosome
30: spike 40: seaweed
50: Sandbox

Claims (8)

In the port-shaped seaweed transplant container,
Port body part where seaweed is implanted in the inner space
A tapered acrosome from the edge of the bottom of the body portion towards the central axis of the body portion to facilitate insertion of the graft container into the seaweed transplant site,
Seaweed transplant container, characterized in that at least one spike is formed on the outer surface of the port body portion. The method according to claim 1,
The spikes are seaweed transplant container, characterized in that forming an angle of 110 to 150 degrees in the downward direction and the outer surface of the port body portion. The method according to claim 1 or 2,
The spikes are seaweed transplant container, characterized in that forming an angle of 20 to 90 degrees in the upper direction and the outer surface of the port body portion. The method of claim 3,
The spike is formed of a rod having a semi-circular or triangular cross-section, the seaweed transplant container, characterized in that the plane facing the port body portion is fixed so that the plane included in the semi-circular or triangular rod. The method according to claim 1,
The body portion is formed in a cylindrical shape, the acrosome transplant container, characterized in that formed in a conical shape. The method according to claim 1,
The seaweed transplant container is a seaweed transplant container, characterized in that made of a biodegradable polymer material. As a seaweed transplant method using the seaweed transplant container of claim 1,
Transplanting the seaweed into the seaweed transplant container; And
And inserting and fixing the seaweed transplant container into which the seaweed is transplanted, in the step. The method of claim 7,
The method of transplanting seaweeds to the seaweed transplant container is sowing the seaweed seeds in the seaweed transplant container, or transplanting seedlings.

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