KR101199870B1 - construction of sea forest - Google Patents

Abstract

PURPOSE: A structure for constructing sea jungle is provided to secure a habitat for marine algae or fishes by artificially forming sea forest. CONSTITUTION: A structure for constructing sea jungle comprises an upper layer(10), a middle layer(20), and a lower layer(30). The upper layer is formed in the shape of a cube in which irregularities are repeatedly formed on the upper surface thereof. The middle layer is formed in the lower side of the upper layer and is formed in the shape of a cube in which a space is formed. In the side of the middle layer, a gateway communicating with the space is formed. The lower layer is formed in the lower side of the middle layer and has legs supporting the whole load of the structure.

Description

Construction for seaforest construction {construction of sea forest}

The present invention relates to a structure for the construction of a marine forest to artificially form a sea forest to provide habitats for seaweeds and fish.

Recently, coastal land reclamation is being actively carried out due to the advancement of industrial technology along with the establishment of coastal industrial complexes. In addition, coastal waters with easy reclamation projects are being gradually landed as land expansion projects. In addition, various industrial wastes, urban sewage, and factory wastewater are discharged to the ocean indiscriminately without going through sewage treatment, and the water pollution causes the rapid expansion of whitening phenomenon (greening of the sea: desertification of the sea). I'm going.

Because of the phenomena, the growth of the representative large algae on the coast such as Ecklonia cava, seaweed and maternal regurgitation is hardly seen. Therefore, the populations such as seashells, sea urchins and abalones that feed on them are reduced and growth is poor.

Although the cause of bleaching is not known in detail, changes in ecosystem structure, mass production of a few species, and water pollution may be one of the important factors.

In this environment, in order to meet the ever-increasing demand for aquatic products, it is inevitable that the production of aquaculture fisheries will be inevitably increased, and artificial sea forests are considered important in view of this reality.

For example, marine deforestation and artificial reefs are artificial structures that are used to increase the productivity of fisheries in coastal waters, and the organisms that inhabit the coasts are used as spawning or hiding places while inhabiting underwater reefs and sinking fishing vessels. will be. Artificial reefs and marine forests that are applied to the coast of Korea are being financed by government projects.

Artificial reefs are artificial structures mainly intended to serve as habitats for fish, and are often composed of a frame structure to provide a large amount of empty space in the structure. On the other hand, marine deforestation has a surface structure mainly to provide a lot of attachment surface for algae habitat.

That is, in the case of existing commercial artificial structures, artificial reefs, such as rectangular fishes and gimbal type fishes, rely solely on the design of the frame structure, which makes it easy to secure a fish habitat but is not suitable for attaching seaweeds. And seaweed forests such as overpasses, hemispherical fishes, and cruciferous seaweeds have their shortcomings, resulting in a lack of fish habitat.

On the other hand, to date, most of the materials used to produce marine deforestation and artificial reefs have been used cement concrete. The artificial reef made of cement concrete is manufactured using natural sand, natural crushed aggregate, and Portland cement as main materials. In the case of sand, domestic land streams are already depleted of resources and rely on sea sand. However, it is difficult to expand sand production due to concerns such as destruction of sea ecosystems when sand is collected. And in order to secure natural crushed aggregates, it is necessary to develop and provide quarries, which have many problems such as environmental destruction and civil complaints. In particular, Portland cement has recently been pointed out as a cause of social problems such as "garbage cement" or "atopy apartments," which is a negative trend against the use of artificial reefs used to restore marine ecosystems.

By the way, the artificial reef of the cement concrete material does not contain the iron (Fe) component that can promote the algae attachment form only serves as a simple structure material without functionality.

Accordingly, in recent years, steel structures or cement-concrete structures in which steel bars are inserted to provide iron are often provided. However, these structures are the most expensive of the artificial structures, but supply the iron to seawater. The algae attached while being corroded has the disadvantage of falling off with the dropping of the corrosion layer.

As such, the limited budget is not enough to restore the coast which is continuously devastated every year. However, since the price of artificial reefs and seaweeds that are currently commercialized and applied to the business is very expensive, it is difficult to properly respond to the situation where many facilities must be promoted with a small budget.

Accordingly, there is a need for continuous research on the structure for the construction of marine forests, which are cheaper and more effective than the existing marine forests and artificial reefs, and have excellent durability, resistance to blue waves and algae.

The present invention is to solve such a problem, an object of the present invention is to provide a structure for the construction of a marine forests that can be given at the same time the function of the artificial reefs in which the fish inhabit the seaweeds attached to the seaweeds.

Another object of the present invention is to develop an eco-friendly material suitable for the habitat of marine and aquatic organisms, and to construct a structure for creating a marine forest using slag, which is a by-product produced in the steelmaking process, so as to sufficiently contain iron and minimize costs. To provide.

In order to solve the above problems, the present invention is an upper layer portion to which the seaweed is attached; A middle layer provided at a lower side of the upper layer, having a hexahedron shape having a space therein, and having a doorway communicating with the space at each surface forming a circumference thereof; It is provided to be stepped on the lower side of the middle layer, protruding to form the lower side of each corner provided with a lower forest portion having a leg for supporting the structure of the overall load;

Here, a plurality of recesses and convex portions may be repeatedly formed on the upper surface of the upper layer portion, and the circumferences of the upper layer portion, the middle layer portion, and the lower layer portion may be formed to be inclined to gradually widen toward the lower side.

The structure for deciduous forest composition of the present invention includes 80 to 90% by weight of the steelmaking slag aggregate and 10 to 20% by weight of the slag cement containing fine blast furnace slag powder. At this time, the blast furnace slag fine powder may be contained 40% by weight or more based on the total weight of the slag cement.

According to the structure for the composition of the marine forests of the present invention has the following effects.

First, it has a high specific gravity that can stably withstand the effects of blue and algae without the use of reinforcing bars, and contains a large amount of iron (Fe) to promote the algae attachment format in comparison with existing structures. It is possible to increase the propagation effect of algae compared to the existing commercially available artificial reefs by manufacturing a structure using slag cement containing high specific gravity steel slag aggregate and blast furnace slag fine powder having excellent seawater resistance.

Second, in terms of price, it is cheaper than existing marine and artificial reefs, and economical and long-term effects can be sustained to restore coastal ecosystems more efficiently. This is possible.

1 is a perspective view of the structure for the composition of the sea forest according to the present invention.
Figure 2 is a plan view of the structure for the sea forests according to the present invention.
Figure 3 is a front view of the structure for the marine deforestation in accordance with the present invention.
Figure 4 is a side view of the structure for the formation of a sea forest according to the present invention.
Figure 5 is a bottom view of the structure for the composition of the sea forest according to the present invention.

Hereinafter, with reference to the accompanying drawings, the structure for the marine forests composition according to the present invention.

1 to 5 are a perspective view, a plan view, a front view, a side view, and a bottom view of the structure for the marine deforestation according to the present invention, respectively.

As shown in Figures 1 to 5, the structure for the marine deforestation according to the present invention consists of a three-layer structure of the upper layer portion 10, the middle layer portion 20, the lower layer portion 30.

The upper layer portion 10 is made of a hexahedron, and forms a surface structure so that algae can be attached. In particular, a plurality of recesses 11 and convex portions 12 are repeatedly formed on the upper surface of the upper layer portion 10 so that the seaweeds are more easily attached. For example, when there are many corners or curved portions, attachment of seaweed becomes easy.

The middle layer portion 20 is formed to be stepped on the lower side of the upper layer portion 10, and is made of a hexahedron like the upper layer portion 10. A predetermined space is formed inside the middle layer 20 so that swimming organisms such as fish can be inhabited, and the entrance 21 is formed on four sides, ie, front, rear, left, and right sides thereof, to communicate with the space.

The lower layer portion 30 is located below the middle layer portion 20. The lower layer portion 30 is formed to be stepped on the lower side of the middle layer portion 20, and has a leg 31 protruding downwardly under each corner to support the entire load of the structure. Like the middle layer 20, each leg 31 is preferably manufactured to have a sufficient height so that a sufficient space for habitation of swimming organisms such as fish can be secured under the lower layer 30.

In the structure of the present invention, as described above, the portion connected to the middle layer part 20 and the middle layer part 20 to the lower layer part 30 in the upper layer part 10 is formed stepwise so that a lot of corners or curved portions are formed.

In addition, the structure of the present invention is formed on the outer surface, that is, the circumferential four surfaces of the upper layer portion 10, the circumferential four surfaces of the middle layer portion 20 and each outer surface of the leg 31 is inclined outwardly downward. For example, the upper layer portion 10 and the middle layer portion 20 has a trapezoidal shape in any of front, rear, left, and right sides.

As described above, the present invention can increase the coverage of the seaweeds by forming the respective components constituting the structure stepped with respect to each other, and also forming the inclined outer surface thereof.

On the other hand, the iron (Fe) component is an important element that the seaweed has the highest absorption rate among the trace elements dissolved in the seawater, and promotes photosynthesis of the seaweed and plays an important role in the absorption of nutrients.

Accordingly, when manufacturing the structure of the present invention, it may include a slag cement containing steelmaking slag and blast furnace slag to ensure a sufficient iron component while reducing the manufacturing cost.

Steelmaking slag is used as aggregate after processing, and blast furnace slag is used as a binder or admixture for binders. At this time, since there are many kinds of steel slag, it is necessary to use slag that has been tested for hazard.

The structure of the present invention is made through steelmaking slag, slag cement, water and other additives are mixed with each other to be made of raw concrete (dough) and then formed and cured.

That is, the steelmaking slag generated in the steelmaking process is subjected to a particle size sorting process after crushing and removing impurities. Thereafter, through the curing process, the volume expansion ratio is appropriately adjusted, and then blended with slag cement, water, and additives to prepare a molding and curing process.

Steelmaking slag used in the present invention is generated in the steelmaking process of steel mills, and representative chemical components are shown in Table 1.

Chemical composition T-Fe SiO ₂ CaO Al ₂ O ₃ MgO MnO P ₂ O ₅ TiO ₂ content
(weight%) 12-25 8-15 30-45 2 ~ 7 5 to 10 3 to 5 1-7 0.5 to 2

As shown in Table 1 above, steelmaking slag contains somewhat more iron than ordinary rocks. Iron is a component that actively activates cells after the spores of the algae grow and germinate, and it is known that iron is involved in the formation of electron transport systems and pigment proteins required for photosynthesis during growth.

And for the growing conditions of plants, seawater lacks iron more than other ingredients. Therefore, steel-making slag containing a large amount of iron is useful as a material of marine deforestation and artificial reefs.

As described above, the structure for constructing the sea forests of the present invention is made of slag cement containing steelmaking slag and blast furnace slag, and has excellent stability and seaweed covering performance, and differentiates from existing fishes, as well as fishes for marine forests for the purpose of creating sea forests. Also, the shellfish-type fish may have excellent characteristics.

At this time, the steelmaking slag is preferably 50 to 90% by weight, the slag cement 10 to 20% by weight based on the total weight of the structure to ensure a high specific gravity and sufficient stability of the structure of the present invention. For example, when the steel slag is less than 50% by weight, its specific gravity is about 2.5, and there is no significant difference with existing concrete structures. When the steel slag is more than 90% by weight, a specific gravity of about 2.8 can be achieved, but the amount of blast furnace slag is exceeded. The content can be reduced, making the structure less vulnerable. In addition, when the slag cement is less than 10% by weight will affect the stability of the structure, if it exceeds 20% by weight is contrary to the original purpose for providing a high specific weight structure. At this time, the blast furnace slag fine powder contained in the slag cement is preferably included at least 40% by weight relative to the total weight of the slag cement to fully fulfill the role of the binder.

The effect of the structure for the marine forest composition of the present invention can be clearly seen through the following examples.

[Example]

In order to investigate the effects of the present invention, 150 structures of the present invention were installed in specific regions. The facility area has a typical fishing structure of fishing villages.

As a result of the effect test at the time of 4 months and 8 months, it was confirmed that the algae of about 1 ~ 5cm in size that can be observed with the naked eye are densely adhered to the surface of most dropped structures. There are also many shellfish that feed on it, and fish have been observed.

The results are shown in Table 2 below.

division After 4 months 8 months later Invention Existing seaweed forest Invention Existing seaweed forest Seaweed Coverage 50-80% 5-45% 80-97% 50-80% Seaweed biomass per unit area (㎏ / ㎡) 0.5 Estimated below 0.2
(Non-collection) 3.2 Estimated below 1
(Non-collection)

As shown in the results of Table 2 above, the structure for the marine forest composition of the present invention, it can be seen that the results of the sea forest composition effect, such as the algae coverage and biomass than the concrete reefs put in the same time in the adjacent waters.

10; Upper layer 11; waist
12; Convex 20; Mezzanine
21; Entrance 30; Lower tier
31; Bridge

Claims (5)

In the structure for the formation of the marine forest,
Seaweed is attached, the upper surface of the hexahedral shape is formed with a plurality of repetitions of the recess portion and the iron;
A middle layer provided at a lower side of the upper layer, having a hexahedron shape having a space therein, and having a doorway communicating with the space at each surface forming a circumference thereof;
It is provided to be stepped on the lower side of the middle layer, protruding to form the lower side of each corner having a lower portion having a leg for supporting the overall load of the structure;
80 to 90% by weight steelmaking slag aggregate and 10 to 20% by weight of the slag cement containing blast furnace slag powder, based on the total weight of the structure, wherein the blast furnace slag powder is 40% by weight relative to the total weight of slag cement A structure for marine deforestation, characterized in that it contains more than.
delete The method of claim 1,
The circumference of the upper layer, the middle layer and the lower layer is formed in the seaway forest composition, characterized in that formed to be inclined outward toward the lower side.
delete delete

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