KR20130085267A - Seaweeds adhesion method forming sea forest - Google Patents

Abstract

PURPOSE: A method for transplanting marine algae to form sea forest is provided to rapidly transplant marine algae using environmentally friendly supports and adhesives and to improve an insertion rate. CONSTITUTION: A method for transplanting marine algae to form sea forest comprises: a step of selecting a sea area to form sea forest; a step of selecting an attachment substrate including natural rocks or artificial fish reefs; a step of transplanting marine algae on the surface of the attachment substrate by fixing a support for supporting the marine algae on the surface of the attachment substrate under water. [Reference numerals] (AA) Selecting a sea area; (BB) Selecting an attachment substrate; (CC) Underwater transplation step; (DD) Cleaning an attachment substrate; (EE) Collecting marine algae; (FF) Fixing a support; (GG) Transplanting marine algae

Description

Seaweeds adhesion method forming sea forest}

The present invention relates to a method for transplanting algae for the establishment of a sea forest, transplanting algae in the water using eco-friendly support and adhesive to the reefs or natural rocks already installed in the sea area to create a sea forest, the transplantation is fast and there is no damage to the marine environment It relates to a seaweed transplant method that can increase the growth rate.

The large brown algae communities that make up the marine forests are estimated to have high productivity over the temperate temperate forests of land (Hirata et al., 1990, Taniguchi, 1996) and are considered to be very important in terms of biological circulation in the ocean. It is becoming.

Recently, however, marine pollution and physical destruction of the coastal environment are accelerating the desolation of the seabird communities, and are a serious problem in terms of marine environment conservation and fishery resource protection. In addition, seabird communities are being reduced or destroyed due to indiscriminate coastal development, environmental pollution, and tidal flats in coastal fisheries, and various marine biomass are decreasing (Fujita, 1987).

Due to the industrialization and the development of the city due to the recent construction of the RBC, the coastal area of Korea has been polluted daily due to the inflow of pollutants such as factory wastewater and domestic sewage, various sea accidents, and abnormal climates. Algae disappear, and there is a lot of algae whitening (algae whitening), which is a type of red algae, which reproduces large amounts of algae.

The phenomena of the bleaching have not yet been identified, but they are rapidly spreading in coastal areas, causing coastal fish farms to be devastated, and seaweed forests such as seaweed and kelp are rapidly destroyed, resulting in changes in the food chain structure of abalone and sea urchins, and various fish. This has a significant impact on marine ecosystems, including spawning and habitat environments.

In such a realistic situation, methods for restoring fisheries have been sought, and in recent years, artificial sea forests have been considered important in terms of environmental conservation (Choi et al., 2000, Ohno, 1993).

It is a method of creating artificial sea forests and artificially attaching seaweed seedlings to artificial structures introduced into the sea. It is used a method of installing a spore bag, a method of winding a dummy line drawn by a conventional implantation method on an artificial structure, or connecting a dummy line between the artificial structure and another artificial structure by a dummy line.

However, according to the conventional method, the growth rate is low due to the fluctuation of imitation lines due to the influence of waves or algae in the early stage of transplantation, and the transplanted algae with the passage of time due to the loss of typhoons or waves and the damage caused by fishers' activities The dropout rate is about 50% or more, which causes a lot of budget and time to be wasted.

In addition, in order to prevent the imitation of the imitation line as much as possible, the imitation line installed on the artificial structure should be fixed in several places.In this case, the anchor bolt and the imitation line are fixed by drilling holes and anchoring the anchor bolts in various places of the artificial structure. Since it is necessary to bind one by one, the process is complicated and requires a lot of time and manpower.

The conventional method uses a method of engrafting fertilizers and fertilized eggs released from mature leaves on artificial substrates, winding the cultivated works on artificial substrates, or installing spore bags. There is a problem that the rate is low.

The present invention was created to improve the above problems, by transplanting algae in the water using an eco-friendly support and adhesive in the reefs or natural rock that is already installed in the sea area to create a marine forest, the transplantation work is fast and there is no damage to the marine environment The purpose is to provide a method of transplanting algae that can increase the rate.

Seaweed transplanting method of the present invention for achieving the above object is a sea area selection step of selecting a sea area to create a sea forest; An attachment substrate selection step of selecting an attachment substrate including natural rock or artificial reef distributed in the composition region; It is characterized in that it comprises a; an underwater transplant step of implanting the algae by fixing the support in water to support the algae on the surface of the adhesion substrate.

The support is a support network is a mesh woven with vegetable fibers, the underwater transplanting step is a cleaning step of cleaning the surface of the adhesion substrate, the collecting step of collecting the algae that is naturally in the composition area or surroundings, and the network Attaching the adhesive substrate to the adhesive substrate, and fixing the collected algae to the adhesive substrate with an adhesive to fix the stem to pass through the nose of the mesh so that the mesh supports the algae. It characterized in that it comprises a fixing step to.

In the attaching step, after preparing a plurality of rubber bands, one side of each rubber band is fixed to the attachment substrate at different positions, and the other side of each rubber band is connected to each corner of the mesh to tension the mesh. And adding a plurality of adhesive sites to the mesh and attaching the adhesive sites and surfaces of the adhesive substrate with the adhesive.

The underwater transplanting step is a binding step of pressurizing the net by fixing both ends of the binding rope to the attachment substrate in a state in which a binding rope is disposed between the seaweeds to prevent the flow of the net after completion of the fixing step. It further comprises.

The underwater transplanting step includes a cleaning step of cleaning the surface of the adhesion substrate, and an attachment step of attaching the support on which the algae is implanted to the adhesion substrate with an adhesive.

As described above, according to the present invention, by recycling the existing installed reefs, it is possible to maximize the recyclability and reproducibility of the costly and time-consuming artificial reefs, and to reduce the budget of the new business and the existing reefs. Eco-friendly sea forests can be created without installing artificial structures.

And since the algae is implanted using the support and the adhesive, unlike the conventional artificial sea forest composition, which requires a lot of cost and time, the transplanting operation is fast, and thus, the effect of low budget and high efficiency can be obtained.

In addition, by effectively preventing the flow of the support it can increase the adherence to the adhesion substrate and rooting root rooting rate, loss due to typhoons, waves, algae, etc., damage caused by fishers' fishing activities.

As described above, the present invention creates a sea forest without destroying or damaging the marine ecosystem through an eco-friendly seaweed transplantation method, and the young seaweeds grown by spore release of the transplanted algae are formed as adults to form a lush algae colony. It can restore the damaged marine environment and increase fishery productivity of fishermen.

1 is a block diagram showing a seaweed transplant method according to an embodiment of the present invention,
Figure 2 is a perspective view showing the attachment substrate implanted with seaweed by the method of Figure 1,
3 is a cross-sectional view of the main portion of Figure 2,
4 is a perspective view showing an attachment substrate implanted with seaweed according to another embodiment of the present invention,
Figure 5 is a block diagram showing a seaweed transplant method according to another embodiment of the present invention,
FIG. 6 is a perspective view illustrating an attachment substrate in which seaweeds are implanted by the method of FIG. 5.

Hereinafter, a seaweed transplanting method according to a preferred embodiment of the present invention with reference to the accompanying drawings will be described in detail.

1 to 3, the seaweed transplanting method according to an embodiment of the present invention includes a sea area selection step, an attachment substrate selection step, and an underwater transplantation step.

First, in the sea selection stage, select a sea area to create a sea forest based on sea monitoring. The main contents of marine monitoring include depth, water temperature, algae strength, natural rock distribution and foundation survey, rock area and cultivable area survey, fisheries distribution and characteristics survey, seaweed and benthic creature survey, and existing artificial reefs. The present state etc. are mentioned.

Based on this ocean monitoring, the location and area of the appropriate sea area to create a sea forest will be selected. For example, the location and area of the sea area may vary depending on the state of natural rock or artificial reef that can be used as an attachment substrate for transplanting algae.

Next, select the attachment substrate. Natural rock, artificial reefs, etc. may be used as the adhesion substrate. Adherent substrates to which algae can be transplanted are selected from natural rocks or artificial reefs distributed in the sea. The attachment substrate may be selected in consideration of the position, size, shape, distribution, and the like. 2 illustrates an example of using natural rock as the attachment substrate 10.

Use artificial reefs that are already installed in the sea area. In this way, the installed artificial reef can be recycled as an adhesive substrate, thereby reducing the cost and time required for manufacturing and installing the artificial reef. In particular, artificial reefs made of concrete that are put into the sea are harmful to the marine ecosystem of harmful toxic substances from the cement, so recycling the installed artificial reefs has the meaning of preventing environmental damage.

It is preferred that the natural rock has a specific gravity of 2.6 or more, a water absorption rate of less than 5.0%, a compressive strength of 100.0 N / mm ² , and a size of 50 to 100 × 50 to 100 × 50 to 100 cm (width × length × height).

 When the adhesion substrate is selected, a submerged transplantation step is performed by attaching a support that can support the seaweed on the surface of the adhesion substrate in water. This underwater transplantation step is carried out in the water in the compositional area by using a diver.

Underwater transplantation steps include, for example, a cleaning step of cleaning the surface of the adhesion substrate, a collecting step of collecting algae, an attachment step of attaching the support to the adhesion substrate, and fixing the adhesive seam by attaching the collected algae to the adhesion substrate. Consists of steps.

The cleaning step removes dirt and shellfish on the surface of the selected substrate. This cleans the surface of the adhesion substrate using an iron brush, hand scraping, high pressure grinder, and the like.

And during the gathering stage, seaweeds that are naturally inhabited in or around the sea area are collected. Algae refers to all kinds of algae such as green algae, red algae and brown algae that inhabit the sea. Seaweeds are preferably collected at least about 20 cm. This is because young algae have low engraftment rate due to the eating of breakfast animals at the beginning of transplantation.

It is desirable to collect species that have been previously distributed or are not currently in the current sea area so that they can grow in the sea area. In addition, appropriate algae are collected according to the depth of the sea area to be transplanted and the type of aquatic life.

In the present exemplary embodiment, the collecting step is described as being performed after the cleaning step. Alternatively, the collecting step may be performed before the cleaning step.

When the collection step is completed, the attachment step of attaching the support to the adhesive substrate with an adhesive is performed. In the example shown, a mesh 20 woven of vegetable fibers is used as a support. Coir fibers, jute fibers and the like can be used as the vegetable fibers. The mesh 20 is excellent in the moisture of the fiber itself to help germination and growth of the algae root and algae spores. In addition, it is a natural vegetable material, after a certain period of time naturally corroded in water, there is no fear of environmental pollution. Coir is naturally corroded after about three to four years and jute is about two to three years.

In this way, the mesh 20 woven with coir fibers or jute fibers may be directly attached to the surface of the adhesion substrate 10 using the adhesive 1. For example, a rectangular mesh 20 is prepared and spread on top of the attachment substrate 10, and then a plurality of adhesion sites are selected, and the adhesive 1 is applied to the adhesion sites to press the surface of the adhesion substrate 10. Attach. Depending on the type of adhesive 91), the adhesive part may be pressed for a few minutes. And in order to minimize the flow of the net due to the effects of algae, the adhesive sites are selected and bonded at a plurality of intervals. For example, the four edges of the net are bonded at regular intervals in the longitudinal and transverse directions.

It is preferable to use an inorganic water-based adhesive which can be cured in water for a short time as the adhesive 1. The adhesive 1 is selected to have excellent adhesiveness in water, no peeling phenomenon, low viscosity, and easy workability. In addition, there is no loosening phenomenon in water, so that it is not dissolved, and adhesiveness in water is 40kg / cm ² or more and hardness is about 70 / shore D.

As the adhesive 1, for example, the ceramic composition disclosed in Korean Patent No. 0994531 may be used. Since such a ceramic composition is cured in 1 to 2 minutes in water, it is easy to attach in water. In addition, eco-friendly materials such as ocher, kaolin, shell powder, etc. are added to reduce or purify the harmful substances discharged from the cement, so the toxicity is weak and does not affect the fish.

As such, since the mesh 20 is directly attached to the attachment substrate 10 using the adhesive 1, the installation work is quick and easy without damaging the artificial structure or natural rock.

When the attachment of the mesh 20 is completed, the collected seaweeds 5 are implanted into the attachment substrate 10. For the transplantation of the seaweed 5, after confirming the attachment portion of the attachment substrate 10 to which the seaweed 5 is to be attached, a predetermined amount of adhesive 3 is applied to the surface of the attachment substrate 10 in a lump form. Then, the root portion of the algae (5) collected from the outside of the mesh 20 is passed through the nose of the mesh 20, the root portion is placed on the adhesive (3) mass and pressed the root for 1 to 2 minutes, the adhesive (3 ) Harden. At this time, the stem of the algae penetrates the nose of the net, so that the stem and the root are naturally supported by the net. As such, when the support of the network structure is used, the fixing force of the algae can be increased, and thus the growth rate of the initial algae transplantation can be further improved. The adhesive 3 used for the attachment of the seaweed 5 is the same as the adhesive 1 used for the attachment of the net 20.

After about 20 days of transplanting the algae (5), the algae (5) is rooted in the adhesion substrate (10), and after 6 to 8 months, it is difficult to visually see whether the algae or the native algae is transplanted. Full length, stem width, stem length, and number of leaflets.

On the other hand, in the above-described embodiment, after the seaweed is attached with an adhesive, the binding step of fixing the net using a binding rope can be further performed to effectively prevent the flow of the net. This will be described in detail in the following embodiments.

In another embodiment of the present invention, the attaching step may be performed while the mesh 20 is fixed to the attaching substrate 10 before attaching the mesh 20 with the adhesive.

Referring to FIG. 4, after preparing a plurality of rubber bands 30, one side of each rubber band 30 is fixed to the attachment substrate 10. At this time, each rubber band 30 is fixed at different positions to be connected to the four corners of the mesh 20. Fixing the rubber band 30 may use a conventional fixing device (35). For example, the fixing device 35 is an anchor bolt installed in the attachment substrate 10, a bracket formed in a convex shape having a half arc shape, and a through hole into which anchor bolts are inserted at both sides, and a nut screwed to the anchor bolt. Is done.

One side of the rubber band 30 is fixed to the attachment substrate 10 using the fixing device 35 as described above. In the illustrated example, four rubber bands 30 are installed to support four corners of the mesh 20.

Next, connect the other side of each rubber band 30 and each corner portion of the net 20. At this time, the tension is applied to the mesh 20 to be connected to the mesh 20 in a state in which the rubber band 30 is extended. As such, the mesh 20 connected to the rubber band 30 is tensioned by the elastic force of the rubber band 30, so that the mesh 20 is supported on the surface of the attachment substrate 10 and the adhesive work of the seaweed 5 and the mesh 20 is performed. Easy attaching work

After the net 20 is supported by the rubber band 30, the net 20 is attached to the surface of the attachment substrate 10 by using an adhesive, and as shown in FIG. 5) After passing through the root of the seaweed (5) is attached to the surface of the adhesion substrate (10).

After performing the attaching step as described above, the binding step of fixing the mesh 20 using the binding rope 40 is further performed to effectively prevent the flow of the mesh 20. The binding rope 40 used in the binding step is formed by twisting vegetable fibers. As the vegetable fibers, coir fibers, jute fibers, and the like, which are the same materials as the mesh 20, may be used. Therefore, after a certain period of time, there is no fear of environmental pollution due to the natural corrosion with the net 20. The binding rope 40 installs a plurality of side by side at regular intervals. The binding rope 40 is disposed between the algae. Both ends of the binding rope 40 may be fixed to the attachment substrate 10 using the fixing device described above. Both ends of the binding rope 40 are located at the bottom of the attachment substrate.

By installing the binding rope 40 to surround the outside of the attachment substrate 10, the mesh 20 may be firmly supported to effectively prevent the flow of the initial mesh 20 to be implanted.

Meanwhile, another embodiment of the present invention is illustrated in FIGS. 5 and 6.

5 and 6, the seaweed transplanting method of the present invention is a seawater selection step of selecting the composition sea area to create a sea forest and the attachment substrate for selecting the attachment substrate including natural rock or artificial reef distributed in the composition sea area Substrate selection step, and the underwater transplantation step of implanting the algae by fixing the support in the water that can support the algae on the surface of the adhesion substrate. The sea area selection step and the attachment substrate selection step are the same as in the above-described embodiment.

The underwater transplantation step includes a cleaning step of cleaning the surface of the adhesion substrate and an attachment step of attaching the support on which the algae is implanted to the adhesion substrate with an adhesive.

The cleaning step is the same as the above-described embodiment. After completion of the cleaning step to prepare a support on which the seaweed (5) is implanted to perform the attachment step. In the illustrated example, the engagement rope 50 is used as the support. Seedlings of seaweed can be implanted into the engaged rope 50. On the contrary, of course, the mature seaweed can be transplanted into the engaged rope 50.

Engagement rope 50 is cut to a suitable length to fit the size of the attachment substrate (10). Engagement rope 50 is fixed to the surface of the attachment substrate 10 by applying the adhesive (1) at a predetermined interval after fixing both ends to the attachment substrate 10 by using the fixing device 35 described above. Although not shown, the rubber bands may be connected to both ends of the engagement rope 50, respectively, and the ends of the rubber bands may be fixed to the attachment substrate by using a fixing device. In addition, of course, the binding step of fixing the engagement rope 50 using a binding rope (not shown) may be further performed to effectively prevent the flow of the engagement rope 50.

As described above, the present invention can create a marine forest in an environmentally friendly way without destroying the marine ecosystem. In the cultivated waters, spores released by transplanted seaweeds grow into young adults, forming a lush algae colony. Eventually, this may form a spawning ground and a growth ground for fish and shellfish, thereby securing diversity of marine life, thereby allowing various fish and shellfish to coexist to revive marine ecology, and increase fishery productivity.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

5: algae 10: adhesion matrix
20: mesh 30: elastic band
40: Binding Rope

Claims (5)

A sea area selection step of selecting a sea area to create a sea forest;
An attachment substrate selection step of selecting an attachment substrate including natural rock or artificial reef distributed in the composition region;
A method for transplanting seaweed, comprising the step of implanting the seaweed by fixing a support in water to support the seaweed on the surface of the adhesion substrate. The method of claim 1, wherein the support is a mesh woven with vegetable fibers,
The underwater transplanting step includes a cleaning step of cleaning the surface of the adhesion substrate, a collecting step of collecting algae that is naturally in the composition area or the surrounding area, and an attachment step of attaching the mesh to the attachment substrate with an adhesive; And a fixing step of attaching and fixing the seaweeds with an adhesive to the attachment substrate, wherein the stems of the seaweeds pass through the noses of the nets to fix the nets to support the seaweeds. The method of claim 2, wherein the attaching step comprises preparing a plurality of rubber bands and fixing one side of each rubber band to the attachment substrate at different positions, and the other side of each rubber band and each corner portion of the mesh. Tensioning the mesh by connecting, selecting a plurality of adhesive sites on the mesh, and attaching the adhesive site and the surface of the attachment substrate with the adhesive. The method of claim 2, wherein the underwater transplanting step is fixed to both ends of the binding rope to the attachment substrate in a state in which a binding rope is disposed between the seaweeds so as to prevent the flow of the mesh after completion of the fixing step. Seaweed transplant method, characterized in that it further comprises a binding step of pressing. The method of claim 1, wherein the underwater transplanting step includes a cleaning step of cleaning the surface of the adherent substrate, and an attachment step of attaching the support on which the algae is implanted with an adhesive to the adherent substrate. .

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