KR20220159068A - Functional block for a submerged breakwater and artificial reef - Google Patents

Abstract

The present invention relates to an underwater breakwater structure combined with an artificial reef, capable of performing not only a fish reef function but also an underwater breakwater function for preventing coastal erosion and an underwater theme park function. That is, according to the present invention, an artificial reef block installed underwater is interconnected with a T- or H-shaped connection structure for stacking construction. Therefore, not only the fish reef function can be performed, but also the underwater breakwater function for preventing the coastal erosion and the underwater theme park function can be performed. The underwater breakwater structure combined with the artificial reef of the present invention comprises: a plurality of artificial reef blocks (100); the connection structure (200); and the underwater breakwater structure (300).

Description

{Functional block for a submerged breakwater and artificial reef}

The present invention relates to an underwater breakwater structure for both artificial reefs, and more particularly, to an underwater breakwater structure having artificial reef functions to perform not only an artificial reef function but also an underwater breakwater function for preventing coastal erosion and an underwater theme park function. it's about

In general, artificial fish reefs are artificial structures installed on the seabed or underwater in coastal waters for the purpose of protecting and fostering marine ecosystems and fishery resources. It refers to a structure to create a spawning and habitat space for marine life such as shellfish and seaweed, and to provide shelter for young fish.

Accordingly, in the past, artificial reefs were used by artificially sinking abandoned ships. Various types of artificial reefs are being installed.

Moreover, recent artificial reefs have been developed in various types, such as fish reefs targeting shellfish and algae in coastal waters or fish reefs targeting fish, depending on the type of marine life. It should be developed in consideration of not only the characteristics of the sea area, but also the ecological habits of target organisms and the maintenance and management of fish reefs.

On the other hand, a phenomenon in which a sandy beach or soil layer, including a rock layer in a coastal area, is eroded by repetitive waves flowing from the sea is seriously occurring.

Accordingly, as a breakwater structure made of concrete to prevent coastal erosion and control waves at the same time, a plurality of tetrapods in the form of four legs attached to each other are randomly stacked and constructed in the coastal area.

However, as the tetrapods are multi-layered over a large coastal area, there are problems in that installation costs increase and construction workability decreases, and people enter the area where the tetrapods are constructed for fishing and fall accidents. There are problems caused by

Therefore, there is a demand for a structure combining the function of the artificial reef and the function of an underwater breakwater for preventing coastal erosion.

Registration No. 10-0969232 (2010.07.02)

The present invention has been devised by solving the above-mentioned conventional problems, and connects artificial reef blocks installed underwater with a T- or H-shaped connection structure and laminated construction to perform not only the fish reef function but also the coastal waters. The purpose is to provide an underwater breakwater structure for both artificial reefs that can perform an underwater breakwater function and an underwater theme park function to prevent erosion.

In order to achieve the above object, the present invention provides: a reef body in which an inner bulkhead and an outer bulkhead are formed in an L-shaped arrangement on a bottom plate placed on the seabed and internal holes are formed through them in the forward and backward directions, and the inner bulkhead and the outer bulkhead are in contact with each other An upper plate body formed flat with a predetermined area on the upper side, a side wall body formed on both sides of the lower part where the outer bulkhead and the bottom plate come into contact with each other, an upper through hole and a lower through hole respectively formed in the outer partition wall and the side wall body, a plurality of artificial reef blocks including concavo-convex portions formed on outer surfaces of the outer bulkhead and the sidewall body; a connection structure provided in a structure that is selectively inserted into one or both of the upper through hole and the lower through hole of the artificial reef block to connect each artificial reef block to each other and to be supported on the sea floor; And an underwater breakwater structure that is laminated on the connection structure and disposed at a higher position than the artificial reef block to reduce and control the size and speed of waves; It provides an artificial reef combined underwater breakwater structure, characterized in that configured to include.

The connection structure according to one embodiment of the present invention includes: a support block on which the underwater breakwater structure is seated and constructed; Fastening bars integrally protruded from both sides of the supporting block and inserted into the lower through-hole; a support block integrally formed on the bottom surface of the support block and supported on the sea floor; It is characterized by consisting of.

The connection structure according to another embodiment of the present invention includes: an upper support block on which the underwater breakwater structure is seated and constructed; an upper fastening bar integrally protruding from both sides of the upper support block and inserted into an upper through hole; a connection block integrally formed on the lower surface of the upper support block; a lower supporting block integrally formed under the connecting block; a lower fastening bar integrally protruding from both sides of the lower support block and inserted into the lower through hole; It is characterized by consisting of.

The connection structure according to another embodiment of the present invention includes: a support block on which the underwater breakwater structure is seated and constructed; a fastening block integrally protruding from both sides of the supporting block and inserted into an upper through hole; a support block integrally formed on the bottom surface of the support block and supported on the sea floor; It is characterized by consisting of.

Preferably, the underwater breakwater structure is characterized in that it is manufactured in the same structure as the artificial reef block.

In addition, it is characterized in that two or more fastening rings are hinged at both sides of the sidewall of the artificial reef block, and locking pins to which the fastening rings are lockable are protruded at predetermined positions on both sides of the connection structure.

Through the above problem solving means, the present invention provides the following effects.

First, artificial reef blocks installed underwater are interconnected with a T- or H-shaped connection structure, and then an underwater breakwater structure such as an artificial reef block is stacked high on top of the connection structure, so that the artificial reef block performs the fish reef function. And, the underwater breakwater structure can reduce and control the size and speed of waves to perform the function of an underwater breakwater to prevent coastal erosion.

Second, when artificial reef blocks installed underwater are interconnected with a T-shaped connection structure with long legs, a pair of undersea caves are provided at the bottom of the connection structure, making it an underwater theme park for those who enjoy scuba diving. function can be provided.

1 is an exploded perspective view showing an underwater breakwater structure for combining artificial fish reefs according to an embodiment of the present invention;
2 is an assembled perspective view showing an underwater breakwater structure for combining artificial fish reefs according to an embodiment of the present invention;
Figure 3 is a side view showing the installation state of the artificial fish reef combined underwater breakwater structure according to an embodiment of the present invention;
4 is an exploded perspective view showing an underwater breakwater structure for combining artificial fish reefs according to another embodiment of the present invention;
5 is an assembled perspective view showing an underwater breakwater structure for combining artificial fish reefs according to another embodiment of the present invention;
Figure 6 is a side view showing the installation state of the artificial reef combined underwater breakwater structure according to another embodiment of the present invention;
7 is an exploded perspective view showing an underwater breakwater structure for combining artificial fish reefs according to another embodiment of the present invention;
8 is an assembled perspective view showing an underwater breakwater structure for combining artificial fish reefs according to another embodiment of the present invention;
9 is a side view showing an installation state of an underwater breakwater structure for combining artificial fish reefs according to another embodiment of the present invention;
10 and 11 are assembled perspective and side views showing an underwater breakwater structure for combining artificial fish reefs according to another embodiment of the present invention;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 3 are diagrams illustrating an underwater breakwater structure for combining artificial reefs according to an embodiment of the present invention, and reference numeral 100 indicates an artificial reef block.

The artificial reef block 100 has an inner bulkhead 112 and an outer bulkhead 113 formed in an L-shaped arrangement on a bottom plate 111 placed on the seabed, and a reef main body 110 through which internal holes 119 penetrate in the front and rear directions. ), and the upper plate body 114 formed flat with a predetermined area at the upper part where the inner partition wall 112 and the outer partition wall 113 come into contact with each other, and the outer partition wall 113 and the bottom plate 111 come into contact with each other The side wall 115 formed on both sides of the lower side, the upper through hole 116 and the lower through hole 117 formed on the outer partition wall 113 and the side wall body 115, respectively, the outer partition wall 113 and It is made of a concrete structure including the concave-convex portion 118 formed on the outer surface of the side wall 115.

The artificial reef block 100 manufactured as above not only provides a habitat and spawning place for sedentary fish, but also provides shelter for shellfish such as abalone and conch, including fry Arranged in a predetermined arrangement at a desired underwater bottom position do.

Accordingly, by digging a groove on the surface of the upper plate 114 of the artificial reef block 100, it is not only easy to transplant seaweed seedlings, but also can be used as seaweed reefs.

In addition, the side wall 115 of the artificial reef block 100 maintains the stability of the reef body 110 by smoothly inducing the flow of algae on the seabed, and prevents the artificial reef from overturning and leaving due to waves or currents.

In addition, the concave-convex portion 118 of the artificial reef block 100 functions to provide a habitat environment by increasing the adhesion of shellfish and seaweed.

In addition, the inner space of the artificial reef block 100 can also be used as a habitat and spawning place for fish so that various fry and fish and shellfish can move through the inner hole 119 of the artificial reef block 100.

The artificial reef combined underwater breakwater structure according to the present invention includes a connection structure 200 for interconnecting the artificial reef blocks 100, and the connection structure 200 is for stacking the underwater breakwater structure 300 upward. used as a supporting structure.

To this end, the connection structure 200 is selectively inserted into one or both of the upper through hole 116 and the lower through hole 117 of the artificial reef block 100 to connect each artificial reef block 100 to each other. At the same time, it is provided with a structure supported on the sea floor.

The connection structure 200 according to an embodiment of the present invention is a "T"-shaped structure with short legs, and the support block 210 on which the underwater breakwater structure 200 is seated and constructed, and both sides of the support block 210 It is composed of a fastening bar 220 integrally protruding and inserted into the lower through hole 117, and a support block 230 integrally formed on the bottom surface of the support block 210 and supported on the sea floor.

Accordingly, after the connection structure 200 according to an embodiment of the present invention is disposed between the artificial reef block 100 and the artificial reef block 100, fastening integrally protruded from both sides of the support block 210 By inserting and fastening the bar 220 into the lower through-hole 117 of each artificial reef block 100, the support block 210 is disposed between the artificial reef blocks 100 while connecting them, and the support block ( 230) is supported on the sea floor.

In this way, in a state in which the connection structure 200 according to an embodiment of the present invention is supported on the sea floor while connecting the artificial reef blocks 100, the underwater breakwater structure 300 is laminated on the support block 210 .

Preferably, the underwater breakwater structure 300 may be adopted as having the same structure as the artificial reef block 100, or may be adopted as a structure capable of reducing and controlling the size and speed of waves. can

Therefore, as the underwater breakwater structure 300 is laminated on the support block 210 of the connection structure 200 according to an embodiment of the present invention, as shown in FIG. 3, the underwater breakwater structure 300 is artificial fish By being placed at a higher position than the second block 100, the underwater breakwater structure 300 serves as a resistor for reducing and controlling the size and speed of waves, eventually facilitating the underwater breakwater function to prevent coastal erosion will perform

4 to 6 show an artificial reef combined underwater breakwater structure according to another embodiment of the present invention.

As shown in Figures 4 to 6, the artificial fish reef combined underwater breakwater structure according to another embodiment of the present invention is the same as the underwater breakwater structure according to the above-described embodiment, only the shape and structure of the connection structure 200 There is a difference in

The connection structure 200 according to another embodiment of the present invention is manufactured in a laid-down "H"-shaped cross-sectional structure, the upper supporting block 240 to which the underwater breakwater structure 200 is seated and constructed, and the upper supporting block An upper fastening bar 250 integrally protruding from both sides of the 240 and inserted and fastened into the upper through hole 116, and a connection block 260 integrally formed on the lower surface of the upper support block 240, A lower supporting block 270 integrally formed on the lower portion of the connection block 260 and integrally protruding from both sides of the lower supporting block 270 and inserted into the lower through hole 117 A lower fastening bar ( 280).

Therefore, after the connection structure 200 according to another embodiment of the present invention is disposed between the artificial reef block 100 and the artificial reef block 100, integrally protruding from both sides of the upper supporting block 240 The upper fastening bar 250 is inserted and fastened into the upper through hole 116 of each artificial reef block 100, and at the same time, the lower fastening bar 280 integrally protruding from both sides of the lower support block 270 is respectively By inserting and fastening the lower through-hole 117 of the artificial reef block 100, the upper and lower supporting blocks 240 and 270 connect the artificial reef blocks 100 and are disposed between them.

In this way, in the connection structure 200 according to another embodiment of the present invention, the upper support block 240 and the lower support block 270 are laminated by the connection block 260 to provide a stronger bearing capacity for the underwater breakwater structure 300 can exert

Therefore, as the underwater breakwater structure 300 is laminated on the upper support convex 240 of the connection structure 200 according to another embodiment of the present invention, as shown in FIG. 6, the underwater breakwater structure 300 Compared to the above-described embodiment, by being placed at a higher position than the artificial reef block 100, the underwater breakwater structure 300 acts as a resistor to reduce and control the size and speed of waves in deeper water. As a result, it easily performs the function of an underwater breakwater to prevent coastal erosion.

7 to 9 show an artificial reef combined underwater breakwater structure according to another embodiment of the present invention.

7 to 9, the artificial fish reef combined underwater breakwater structure according to another embodiment of the present invention is the same as the underwater breakwater structure according to the above-described embodiment, only the shape and shape of the connection structure 200 There is a difference in structure.

The connection structure 200 according to another embodiment of the present invention is manufactured in a "T"-shaped cross-sectional structure with longer legs than the above-described embodiment, and the support block 210 on which the underwater breakwater structure 200 is seated and constructed ), the fastening block 220 integrally formed on both sides of the support block 210 and inserted into the upper through hole 116, and integrally formed on the bottom surface of the support block 210 to the sea floor It is composed of a support block 220 supported

Therefore, after the connection structure 200 according to another embodiment of the present invention is disposed between the artificial reef block 100 and the artificial reef block 100, integrally protruding formed on both sides of the support block 210 By inserting and fastening the fastening bar 220 into the upper through hole 116 of each artificial reef block 100, the supporting block 210 is placed between the artificial reef blocks 100 while connecting them, and the above Compared to the embodiment, the longer support block 230 is supported on the sea floor.

In this way, in a state in which the connection structure 200 according to another embodiment of the present invention is supported on the sea floor while connecting the artificial reef blocks 100, the underwater breakwater structure 300 is laminated on the support block 210 do.

Similarly, the underwater breakwater structure 300 may be adopted as having the same structure as the artificial reef block 100, or may be adopted as a structure capable of reducing and controlling the size and speed of waves.

Therefore, as the underwater breakwater structure 300 is laminated on the support convex 210 of the connection structure 200 according to another embodiment of the present invention, as shown in FIG. 9, the underwater breakwater structure 300 Compared to the above-described embodiment, by being placed at a higher position than the artificial reef block 100, the underwater breakwater structure 300 acts as a resistor to reduce and control the size and speed of waves in deeper water. As a result, it easily performs the function of an underwater breakwater to prevent coastal erosion.

In addition, since the connection structure 200 according to another embodiment of the present invention has a long "T" shape, that is, the support block 230 integrated with the bottom surface of the support block 210 Compared to the embodiment, since it is manufactured in a longer structure and supported on the sea floor, a pair of undersea caves may be provided between the bottom surface of the support block 210 and the sea floor.

Accordingly, a pair of undersea caves between the bottom surface of the support block 210 and the sea floor can be utilized as an underwater theme park function for people who enjoy scuba diving.

On the other hand, in order to prevent the connection structure 200 interconnecting the artificial reef blocks 100 from being separated while moving in its longitudinal direction (fastening direction), both sides of the sidewall 115 of the artificial reef block 100 At least two fastening rings 290 are hingedly fastened to each other, and fastening pins 310 to which the fastening rings 290 are locked are protruded at predetermined positions on both sides of the connecting structure 200.

Therefore, by hanging two or more fastening rings 290 formed on both sides of the sidewall 115 of the artificial reef block 100 on the fastening pins 310 formed on both predetermined positions of the connection structure 200, It is possible to easily prevent the connection structure 200 interconnecting the artificial reef blocks 100 from being separated while moving in the longitudinal direction (fastening direction).

As seen above, after the artificial reef block 100 installed underwater is interconnected with a T- or H-shaped connection structure 200, an underwater breakwater structure such as an artificial reef block on the connection structure 200 ( 300) is highly laminated, the artificial reef block 100 performs a fish reef function, and the underwater breakwater structure 300 performs an underwater breakwater function to reduce and control the size and speed of waves, so that coastal erosion can be easily prevented. can

On the other hand, it is preferable to further increase the bonding force between the artificial reef block 100 and the connection structure 200 so as to be robust against algae.

To this end, as shown in FIGS. 10 and 11, a locking ring 222 is integrally extended and formed at the end of the fastening bar 220 of the connection structure 200, and the locking ring 222 is formed as an artificial reef block ( By inserting it into the upper through hole 116 of 100 and locking it so as to be caught on the inner surface, it is possible to further increase the bonding force between the artificial reef block 100 and the connecting structure 200.

Meanwhile, an antifouling coating layer made of an antifouling coating composition may be applied to the locking ring 222 to effectively prevent adhesion and removal of contaminants.

The antifouling coating composition contains tetraethyl ammonium hydroxide and methyl ethyl ketone (MEK) in a molar ratio of 1:0.01 to 1:2, and the total content of tetraethyl ammonium hydroxide and methyl ethyl ketone is the total aqueous solution It is 1 to 10% by weight relative to.

The molar ratio of the tetraethyl ammonium hydroxide and methyl ethyl ketone is preferably 1:0.01 to 1:2. If the molar ratio is out of the above range, the coating property of the locking ring 222 is reduced or moisture adsorption on the surface after application is reduced. There is a problem in that the coating film is removed due to the increase.

The tetraethyl ammonium hydroxide and methyl ethyl ketone are preferably 1 to 10% by weight in the total aqueous solution of the composition. If the amount is less than 1% by weight, the coating property of the locking ring 222 is reduced. If the coating film thickness is increased, crystal precipitation is likely to occur.

On the other hand, as a method of applying the antifouling coating composition to the locking ring 222, it is preferable to apply it by a spray method. In addition, the final film thickness of the locking ring 222 is preferably 700 to 2500 Å, more preferably 900 to 2000 Å. If the thickness of the coating film is less than 700 Å, there is a problem of deterioration in the case of high-temperature heat treatment, and if it exceeds 2500 Å, there is a disadvantage in that crystallization of the coated surface is easy to occur.

In addition, this antifouling coating composition can be prepared by adding 0.1 mol of tetraethyl ammonium hydroxide and 0.05 mol of methyl ethyl ketone to 1000 ml of distilled water, followed by stirring.

The reason why the ratio of the constituent components and the thickness of the coating film were numerically limited as described above was that the present inventors showed the optimal antifouling coating effect at the ratio as a result of analyzing the test results while repeating several failures.

In addition, the locking pin 310 may be made of a metal material, and a corrosion-preventing coating layer may be applied to the locking pin 310 to prevent corrosion of the metal surface.

The coating material of this anti-corrosion coating layer is aminobenzamide 12% by weight, phenyl benzimidazole 15% by weight, hafnium 20% by weight, emulsified molybdenum (MoS2) 13% by weight, titanium oxide (TiO2) 12% by weight, aluminum oxide ( It consists of 8% by weight of AIO2), 15% by weight of Daikan, and 5% by weight of caproic acid salt, and the coating thickness can be formed to 8㎛.

Aminobenzamide, phenylbenzimidazole, daikan, and caproic acid act to prevent corrosion and discoloration, and hafnium, as a transition metal element with corrosion resistance, plays a role to have excellent waterproofness and corrosion resistance.

Molybdenum emulsified plays a role in imparting sliding properties and lubricity to the surface of the coating film, and titanium oxide and aluminum oxide are added for the purpose of fire resistance and chemical stability.

The reason for limiting the ratio of the components and the coating thickness as described above is that the present inventors have repeatedly failed several times and analyzed the test results, and as a result, the ratio showed the optimal anti-corrosion effect.

In addition, a shock absorber made of rubber may be further provided on the lower surface of the fastening bar 220 in contact with the artificial reef block 100.

The shock absorbing part may be made of a rubber material, and the raw material content ratio of the shock absorbing part is 58% by weight of rubber, 6% by weight of diphenylguanidine, 6% by weight of thiocarbanilide, 3% by weight of zinc laurate, and 19% by weight of carbon black. %, 4% by weight of 3C (N-PHENYL-N'-ISOPROPYL-P-PHENYLENEDIAMINE) and 4% by weight of precipitated sulfur are mixed.

Diphenylguanidine and thiocarbanilide are added to improve acceleration, etc., zinc claurate is added to act as a softener, and carbon black is added to increase or improve wear resistance, thermal conductivity, and the like.

3C (N-PHENYL-N'-ISOPROPYL-P-PHENYLENEDIAMINE) is added as an antioxidant, and a precipitate is added to act as an accelerator.

Therefore, according to the present invention, elasticity, toughness, and rigidity of the shock absorbing portion are increased, so that durability is improved, and thus the life of the shock absorbing portion is increased.

The tensile strength of the rubber material is formed at 155Kg/㎠.

The reason for limiting the components and components of the rubber material and limiting the numerical values of the mixing ratio is that, as a result of the inventor's analysis through test results while repeating several failures, the optimal effect in the constituent components and numerically limited ratios showed up

100: artificial reef block
110: reef body
111: bottom plate
112: inner bulkhead
113: outer bulkhead
114: upper plate body
115: side wall body
116: upper through hole
117: lower through hole
118: uneven portion
119: inner hole
200: connection structure
210: support block
220: fastening bar
222: locking ring
230: support block
240: upper support block
250: upper fastening bar
260: connection block
270: lower support block
280: lower fastening bar
290: fastening ring
300: underwater breakwater structure
310: fastening pin

Claims (6)

The inner bulkhead 112 and the outer bulkhead 113 are formed in an L-shaped arrangement on the bottom plate 111 placed on the seabed, and the reef body 110 is formed through internal holes 119 in the forward and backward direction, and the inner bulkhead 112 The upper plate body 114 formed flat with a predetermined area at the upper part where the outer bulkhead 113 and the outer bulkhead 113 come into contact with each other, and the sidewall body formed on both sides of the lower part where the outer bulkhead 113 and the bottom plate 111 come into contact with each other ( 115), the upper through hole 116 and the lower through hole 117 formed in the outer partition wall 113 and the side wall body 115, respectively, and the outer surface of the outer partition wall 113 and the side wall body 115 a plurality of artificial reef blocks 100 including concave-convex portions 118 formed thereon;
It is selectively inserted into one or both of the upper through hole 116 and the lower through hole 117 of the artificial reef block 100 to connect each artificial reef block 100 to each other and to be supported on the sea floor at the same time. The provided connection structure 200; and
An underwater breakwater structure 300 that is laminated on the connection structure 200 and disposed at a higher position than the artificial reef block 100 to reduce and control the size and speed of waves;
An underwater breakwater structure for combining artificial reefs, characterized in that configured to include.
The method of claim 1,
The connection structure 200 is:
Support block 210 to which the underwater breakwater structure 200 is seated and constructed;
A fastening bar 220 integrally protruding from both sides of the support block 210 and inserted into the lower through hole 117;
A locking ring 222 formed at the end of the fastening bar 220 and caught on the inner surface of the upper through hole 116 of the artificial reef block 100 and locked;
a support block 230 integrally formed on the bottom surface of the support block 210 and supported on the sea floor;
An artificial reef combined underwater breakwater structure, characterized in that composed of.
The method of claim 1,
The connection structure 200 is:
An upper support block 240 on which the underwater breakwater structure 200 is seated and constructed;
an upper fastening bar 250 integrally protruding from both sides of the upper support block 240 and inserted and fastened into the upper through hole 116;
A connection block 260 integrally formed on the lower surface of the upper support block 240;
a lower support block 270 integrally formed under the connection block 260;
A lower fastening bar 280 integrally protruding from both sides of the lower supporting block 270 and inserted into the lower through hole 117;
An artificial reef combined underwater breakwater structure, characterized in that composed of.
The method of claim 1,
The connection structure 200 is:
Support block 210 to which the underwater breakwater structure 200 is seated and constructed;
a fastening block 220 integrally protruding from both sides of the support block 210 and inserted and fastened into the upper through hole 116;
a support block 220 integrally formed on the bottom surface of the support block 210 and supported on the sea floor;
An artificial reef combined underwater breakwater structure, characterized in that composed of.
The method of claim 1,
The underwater breakwater structure 300 is an artificial reef combined underwater breakwater structure, characterized in that produced in the same structure as the artificial reef block (100).
The method of claim 1,
Two or more fastening rings 290 are hinged at both sides of the sidewall 115 of the artificial reef block 100, and at predetermined positions on both sides of the connection structure 200, the fastening rings 290 are lockable An artificial fish reef combined underwater breakwater structure, characterized in that the fastening pin 310 is protruded.

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