KR100959391B1 - Wave breaking underwater struture having function of seaweed bed reef - Google Patents

Abstract

PURPOSE: An underwater structure having a sea jungle function is provided, which improves sea jungle performance and reduces the fabrication cost of the underwater structure by simplifying elements. CONSTITUTION: An underwater structure having a sea jungle function comprises: a plurality of cylinder blocks(10) in which one penetration hole is formed in the center; a plurality of first square pillars(20) in which a penetration hole is formed in both ends; a plurality of second square pillars(30) in which a penetration hole is formed in both ends and middle portion; two bottom bars(40) in which a plurality of penetration holes are formed; two upper bars(50) in which a plurality of penetration holes are formed; two middle bars(60) in which a plurality of penetration holes are formed; and a plurality of pins having the same size and shape.

Description

Wave breaking underwater struture having function of seaweed bed reef}

The present invention relates to an underwater sofa structure having a seaweed forest function.

In general, coastal erosion has been progressed due to local occurrence factors due to weather conditions such as storms and long-term occurrence factors due to continuous wave energy and tidal difference.

Conventional underwater sofa structure to prevent the erosion of the coast is a first type that is installed in the water in the form of a mountain by irregularly stacking a plurality of concrete blocks having a geometric shape, and a weir shaped outer frame of wood or steel A second type which is installed in the water by irregularly stacking a concrete block or stone having a geometric shape in a partitioned space in the inside, a third type which is regularly installed in the water by regularly applying concrete to the outside of a weir-shaped outer frame made of wood or steel, Regularly stacks a plurality of outer frames of the fourth type of steel triangular prismatic bodies that are installed underwater by installing mesh nets on the steel framed outer frame regularly in the form of large weirs. There is a fifth type, which is installed in the water by forming a zigzag flow path by regularly mounting a concrete block having a shape.

All of these types of underwater sofa structures are installed on the sea floor by their own weight.

The underwater sofa structure of the first type among these types is excellent in sofa performance, but because of the fact that a plurality of concrete blocks having a geometric shape are irregularly stacked and circulated in the wave direction, the sofa performance is excellent, It is very likely that some of the concrete blocks that make up the escape from the bank, and the spaces partitioned by the concrete blocks are likely to be spaces with only entrances and no exits, so that seawater accumulates in these spaces and occupies decayed sediments. As a result, there is a problem of inducing abnormal currents by disturbing the currents.

The underwater sofa structure of the second type is not only excellent in sofa performance as the underwater sofa structure of the first type, but also some concrete blocks forming a dam in the waves different from the underwater sofa structure of the first type. It is less likely to escape from the bank, but the spaces partitioned by the concrete blocks are likely to be spaces with only entrances and no exits, so that seawater accumulates in these spaces, causing them to rot or occupy sediments, impeding abnormal currents. There is a problem of inducing current.

The underwater sofa structure of the third type has the same sofa performance as the underwater sofa structure of the second type, and the concrete floor, which is the outer surface constituting the dam in the big wave, is less likely to be separated from the dam, but the concrete layer is unilaterally. There is a problem in that it prevents waves and induces currents to the left and right sides of the bank, leading to abnormal currents.

The fourth type of underwater sofa structure does not interfere with the current, but has a problem that the sofa performance is lower than the above types.

The underwater sofa structure of the fifth type can sofa both longitudinal waves and transverse waves without disturbing the currents, so the sofa performance is superior to other tops, but a plurality of outer frames of steel triangular pillars are regularly stacked In the form of a bank having a single mountain or a bank having a plurality of mountains and valleys, each outer frame has a vertical frame and a horizontal frame for mounting a concrete block, so that algae or shellfish can inhabit Since it is impossible to provide a flat surface as an outer surface, there is a problem that the seaweed forest performance is low, and a large number of frames for the outer frame, the vertical frame, and the horizontal frame are required, thereby increasing the manufacturing cost.

The present invention has a problem in solving the above problem.

According to the present invention, a plurality of cylindrical blocks having one through hole, a plurality of first square pillars having through holes formed at both ends, a plurality of second square pillars having through holes formed at both ends and a middle portion, and a plurality of through holes formed therein Two bottom bars, two upper side bars formed with a plurality of through holes, two intermediate bars formed with a plurality of through holes, and a plurality of pins passing through the holes formed in the blocks and the bars and coupling them to each other; The above-described problem can be solved by having a sofa submerged structure having a square pyramid as a whole, arranging a plurality of small pyramid pyramids in a line, and forming a valley between the plurality of small pyramid pyramids.

According to the above-described problem solving means, it is possible to sofa the transverse waves by the zig-zag flow path without disturbing the current, and to make the longitudinal waves by the small pyramid pyramid. By providing a flat surface as an outer surface where shellfish can inhabit, the seaweed reef performance is improved, and the components are reduced than before, making it possible to lower the manufacturing cost of the sofa underwater structure.

1 is an assembled perspective view of this embodiment, and
Figure 2 is an exploded perspective view showing this embodiment in a state in which the overlapping components are omitted for clarity of illustration.

Hereinafter, the sofa underwater structure having the seaweed forest function of the embodiment according to the present invention will be described with reference to FIGS.

1 and 2, the sofa underwater structure having the seaweed forest function of this embodiment is indicated by the reference numeral 100.

The sofa underwater structure 100 includes a plurality of cylindrical blocks 10 having one through hole 1 formed in the center, a plurality of first square pillars 20 formed with through holes 2 at both ends, and both ends thereof. The middle portion includes a plurality of second square pillars 30 having a through hole 3 formed therein.

Both ends of the first square pillar 20 are formed with a first cylindrical portion 21 that can conform to the cylindrical block 10 in shape in parallel, and the first cylindrical portion 21 is the center Inner diameter of the through hole 1 has the same central axis as that of the through hole 1 of the cylindrical block 10 when the first cylindrical portion 21 and the cylindrical block 10 are in contact with each other. The through-hole 2 having the same inner diameter as the one is formed.

At both ends and the middle portion of the second square pillar 30 is formed a second cylindrical portion 31 which can be conformed in shape parallel to the cylindrical block 10, and the second cylindrical portion 31 In this center, the through-hole 1 has the same center axis as that of the through-hole 1 of the cylindrical block 10 when the second cylindrical portion 21 and the cylindrical block 10 are in contact with each other. The through hole 3 is formed to have the same inner diameter as the inner diameter.

The length of the first square pillar 20 is half of the length of the second square pillar 30.

In addition, the sofa underwater structure 100 includes two bottom side bars 40 having a plurality of through holes 4, two upper side bars 50 having a plurality of through holes 5, and a plurality of through holes ( 6) includes two intermediate bars 60 formed therein and a plurality of pins 70 having the same size and shape to penetrate through the holes formed in the blocks and the bars.

The sofa underwater structure 100 has a square pyramid 80 as a whole by the above-described components, a plurality of small pyramid pyramid 90 is arranged in a line in the square pyramid 80, the plurality of yarns Bone portions 91 are formed between the pyramids 90.

This will be described in detail as follows.

The inclined surface 92 of the small pyramid pyramid 90 is disposed so that the central axis of the through hole 3 formed in the second cylindrical portion 31 of the plurality of second square pillars 30 is on the same central axis line, and The through-hole 1 of the cylindrical block 10 corresponds between the second cylindrical portions 31 formed at the lower ends of the plurality of second square pillars 30 and the second cylindrical portions 31 formed at the middle portion thereof. In a state where the cylindrical block 10 is disposed in a state in which the central axis is the same as the central axis of the through hole 3 of the second cylindrical part 31, the bottom bar 40 and the intermediate bar 60 are interposed. ) And then the pins 70 pass through the through holes 1, 3, 4 or 1, 3, 6 to join them.

In addition, the upper surface 93 of the small pyramid pyramid 90 has the central axis of the through-holes 2 formed in the second cylindrical portion 31 of each end of the plurality of first square pillars 20 on the same central axis. The second rectangular pillar 30 is disposed to have the same central axis as the central axis of the through hole 3 of the second cylindrical part 31 constituting the inclined surface 92, and forms the inclined surface 92. In the state between the second square pillar 20), the upper side bar 50 is padded on both sides, and then the pin 70 penetrates the through-holes 3, 2, and 5 to join them. Is done.

In addition, between the second square pillars 30 forming the inclined surfaces 92 and 92 facing each other, the plurality of small pyramid pyramids 90 intersect with the letter X at the middle portion.

In addition, to match the steps on both sides of the plurality of small pyramids 90, to facilitate the coupling with the bottom bar 40, the top bar 50 and the middle bar 60, the cylindrical block 10 The through holes 1 are additionally padded in line with the corresponding through holes.

 For stable coupling of the small pyramid pyramid 90, both ends of the pin 70 may be screwed, and a nut may be fastened to the screwed end.

In the sofa underwater structure 100 configured as described above, a gap is formed on the inclined surface 92 and the upper surface 93, and the second square pillars 30 between the inclined surfaces 92 facing each other are alternately disposed. By forming a zigzag flow path between the (92), it is possible to sofa the transverse wave and the vertical wave without disturbing the current, and to provide a flat surface as the outer surface where seaweed or shellfish can inhabit the upper surface 93 of the small pyramid In addition, it is possible to reduce the manufacturing cost of the sofa underwater structure by improving the seaweed forest performance, and reducing and simplifying the type of components compared to the conventional one.

In the description of the above embodiment, the cylindrical block, the first and the second square pillar may be made of iron or general cement concrete, but may be made of steel slag concrete including blast furnace slag cement, steelmaking slag sand and steelmaking slag gravel.

The steel slag is a solid by-product generated in the steelmaking process, and roughly classified into blast furnace slag generated in the steelmaking process and steel slag generated in the steelmaking process, and are used differently according to chemical composition and properties.

Blast furnace slag can produce amorphous granules when rapidly cooled and solidified in a molten state, and when it is dried and pulverized into fine powder, it has a hydrophobicity similar to that of cement, so it is widely used as a cement and concrete admixture. You can do it as a substitute.

On the other hand, steelmaking slag has less silica component than blast furnace slag and has more free calcium oxide content, which has the property of expanding. Therefore, aging is essential for the specific use of steelmaking slag. This steel-making slag contains a lot of lime powder and is used as a raw material for cement clinker, and also contains a large amount of iron in the form of a single metal or an oxide, which is heavier than natural aggregate and can be used as a substitute for aggregate.

The material of the underwater sofa structure having a seaweed forest function may be made of steel slag concrete produced by using the blast furnace slag as a cement and the steelmaking slag as an aggregate.

Examples of the steel slag concrete include a mixture of steelmaking slag gravel that has undergone an aging process, steelmaking slag sand, blast furnace slag cement, and water in a ratio of 7: 4: 2: 1.

When the sofa structure having the seaweed forest function of the present invention is manufactured by using the steel slag concrete material, trace elements such as silicon, aluminum, calcium, and the like, which are not dissolved in the furnace, and the remaining iron components are eluted in the sea so that the seaweed and It helps the growth of fish and shellfish, and a large number of voids are formed on the surface of the block to aid in the implantation of algae.

1: penetrating hole, 2: penetrating hole, 3: penetrating hole, 4: penetrating hole, 5: penetrating hole, 6: penetrating hole, 10: cylinder block, 20: first square cylinder, 21: first cylinder, 30 : 2nd pillar, 31: 2nd cylinder, 40: bottom bar, 50: upper bar, 60: middle bar, 70: pin, 80: square pyramid, 90: square pyramid, 91: bone, 92: slope 93: top, 100: sofa underwater structure

Claims (6)

A plurality of cylindrical blocks 10 having one through hole 1 in the center, a plurality of first square pillars 20 having through holes 2 formed at both ends, and through holes 3 at both ends and the middle part thereof. And a plurality of formed second square pillars 30, and
Two bottom side bars 40 having a plurality of through holes 4, two upper side bars 50 having a plurality of through holes 5, and two intermediate bars 60 having a plurality of through holes 6 formed therein. And a plurality of fins 70 having the same size and shape to penetrate through the through holes formed in the blocks and the bars and to couple them to each other.
Both ends of the first square pillar 20 are formed with a first cylindrical portion 21 that can conform to the cylindrical block 10 in shape in parallel, and the first cylindrical portion 21 is the center Inner diameter of the through hole 1 has the same central axis as that of the through hole 1 of the cylindrical block 10 when the first cylindrical portion 21 and the cylindrical block 10 are in contact with each other. The through-hole 2 having an inner diameter equal to that is formed,
At both ends and the middle portion of the second square pillar 30 is formed a second cylindrical portion 31 which can be conformed in shape parallel to the cylindrical block 10, and the second cylindrical portion 31 In this center, the through-hole 1 has the same center axis as that of the through-hole 1 of the cylindrical block 10 when the second cylindrical portion 21 and the cylindrical block 10 are in contact with each other. The through hole 3 having an inner diameter equal to that of
The sofa underwater structure 100 has a quadrangular pyramid 80 as a whole, and a plurality of small pyramid pyramids 90 are arranged in a line on the square pyramid pyramid 80, and a valley portion 91 between the plurality of small pyramidal pyramids 90. Underwater sofa structure having a seaweed forest function, characterized in that is formed. The method of claim 1,
Underwater sofa structure having a seaweed reef function, characterized in that the length of the first square pillar 20 is half the length of the second square pillar (30). The method of claim 1,
The inclined surface 92 of the small pyramid pyramid 90 is disposed so that the central axis of the through hole 3 formed in the second cylindrical portion 31 of the plurality of second square pillars 30 is on the same central axis line. The through-hole 1 of the cylindrical block 10 corresponds between the second cylindrical portions 31 formed at the lower ends of the plurality of second rectangular pillars 30 and the second cylindrical portions 31 formed at the middle portion thereof. The cylindrical block 10 is interposed between the bottom bar 40 and the middle bar in a state in which the cylindrical block 10 is disposed to have the same central axis as the central axis of the through hole 3 of the second cylindrical part 31. 60) on both sides, the plurality of pins 70 are carried out by joining them through the through holes 1, 3, 4; or 1, 3, 6, and
The upper surface 93 of the small pyramid pyramid 90 has the central axis of the through-holes 2 formed in the second cylindrical portion 31 of each end of each of the plurality of first square pillars 20 on the same central axis. The second rectangular pillar 30 is disposed to have the same central axis as the central axis of the through hole 3 of the second cylindrical part 31 constituting the inclined surface 92, and forms the inclined surface 92. In the state between the second square pillar 20), the upper side bar 50 is padded on both sides, and then the pin 70 penetrates the through-holes 3, 2, and 5 to join them. Underwater sofa structure having a seaweed reef function, characterized in that carried out. The method of claim 3, wherein
Between the second square pillars 30 forming the inclined surfaces 92 and 92 facing each other, the plurality of pyramidal pyramids 90 intersect with an X-shape at the middle portion, and
The cylindrical blocks 10 are formed so as to fit the steps at both sides of the plurality of small pyramid pyramids 90 to facilitate engagement with the bottom bar 40, the top bar 50 and the middle bar 60. Underwater sofa structure having a seaweed reef function, characterized in that the through hole (1) is additionally padded in accordance with the through holes (1 to 6). The method of claim 1,
Underwater sofa structure having a seaweed reef function, characterized in that the screw is machined at both ends of the pin (70), the nut is fastened to the screwed end. The method according to any one of claims 1 to 5,
Underwater sofa structure with seaweed reef function made of steel slag concrete.

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