KR20060033969A - High functional steel artificial reef - Google Patents

Abstract

The present invention is a high functional forced reef that is installed in the sea for the creation of aquatic resources, the high functional forced reef 30 of the present invention by joining a plurality of horizontal members to each other upper and lower ends (320, 310) forming a polygonal border A main structure 300 including upper and lower ends 320 and 310 connected to each other at vertical intervals 330; A plurality of members are joined to each other at a narrower interval than a gap between the members forming the inner space of the main structure to have a dense structure, and a plurality of members installed in a symmetrical structure at a lower side of some space among the plurality of inner spaces of the main structure It consists of an auxiliary structure 350. Therefore, the present invention has the effect of providing a friendly marine environment habitat of fish by constructing a relatively dense space of the various places of the reef compared to other parts to create an ecological environment suitable for a variety of fish species.

Description

High Functional Steel Artificial Reef

1 and 2 are conceptual views showing the form of the high-functional forced reef, respectively, to which the concept of the present invention is applied,

Figure 3 is a perspective view showing the shape of the square pyramid-shaped high functional forced reef in accordance with a first embodiment of the present invention,

Figure 4 is a perspective view showing the shape of the hexahedral high-performance forced reef in accordance with a second embodiment of the present invention,

5 is a perspective view showing the form of the combined type high-performance forced reef in accordance with a third embodiment of the present invention,

6 and 7 are perspective views showing the shape of the high-rise high functional forced reef in accordance with the fourth and fifth embodiments of the present invention.

  ♠ Explanation of symbols on the main parts of the drawing ♠

30: square pyramid forced reef 300: main structure

310: lower portion 311: first horizontal member

312: beam member 313: second horizontal member

314: connecting member 315: first horizontal plate

316: inclined plate 317: second horizontal plate

318: vertical plate 320: upper portion

321: horizontal member 322: beam member

323: connection member 330: connection

331: vertical member 332: inclined member

333: grid member 340: connecting pillar

350: auxiliary structure 351: horizontal member

352: vertical member

The present invention relates to a forced reef that is installed in the sea for the creation of aquatic resources, in particular, a high-functional forced reef for creating an ecological environment suitable for a variety of fish species by relatively densely configuring several internal spaces of the reefs compared to other parts It is about.

In general, artificial reefs are artificial structures that are installed on the coast or near the sea in order to secure marine resources for coastal fishing grounds, to create spawning and habitat for marine life, and to provide shelter for fry. Artificial reefs are transformed into various forms, from sinking the first abandoned ships or dropping ground structures into the sea to create habitats, and those designed into hexahedral, cylindrical, and uneven structures to create more efficient habitats. Has been. There is also a variety of materials used to make artificial reefs, such as concrete, waste tires, and steel.

However, in the case of concrete reefs, the structural stability is excellent, but considering the weight, etc., it is not suitable for manufacturing high-rise reefs, and its structure is inevitably manufactured in a hemispherical shape or a box shape. In addition, the phenomena are causing pollution to the sea. In the case of the reefs using waste tires, only the aspect of recycling is considered, and the shape itself is difficult to be deformed, which does not satisfy the proper function of the reefs. Therefore, it is possible to form a complex internal space, which is relatively lighter than concrete, and a lot of forced reefs that provide a structure suitable for fish breeding are being manufactured as well as researches on it.

On the other hand, the fish visually detects the gap between members constituting the artificial reef and recognizes the existence of the artificial reef and the existence of space, and the size of the space visually detected by the fish differs depending on the growth state (size) and species. It is known that there is. In addition, the fish are fish species that inhabit irrelevant to the artificial reefs, fish species inhabited along the vortices and fish species formed along the vortices, fish species inhabiting between the artificial reefs, and inside the artificial reefs, depending on the species. There are many varieties, including the species that inhabit space. Some of these species are known to spawn, inhabit and rest or sleep within certain spaces of artificial reefs.

Therefore, in order to fully function as a reef, it must be designed to provide a suitable ecological space where several species can live together. However, at present, most mandatory reefs have the disadvantage that they cannot provide an ecological environment suitable for a variety of fish species since members of the reefs are provided at equal intervals with each other.

Accordingly, the present invention has been made to solve the problems of the prior art as described above, by forming a relatively dense relative internal space of the reefs compared to other parts to create an ecological environment suitable for a variety of fish species The purpose is to provide high-performance manure reefs that provide marine environmental habitats.

In addition, the present invention has another object to provide a high-functional forced reef to improve the structural stability by lowering the center of gravity by configuring the dense space inside the reef in a symmetrical structure at the bottom side.

Forced reef of the present invention for achieving the above object comprises a plurality of base parts to form a border of a polygonal shape by joining a plurality of horizontal members to each other, and one or more connecting parts connecting the base parts to each other at vertical intervals. A main structure; A plurality of members are joined to each other at a narrower interval than the interval between the members forming the inner space of the main structure has a dense structure, it is installed in a mutually symmetrical structure at the lower side of some spaces of the plurality of inner space of the main structure It characterized in that it comprises a plurality of auxiliary structures.

Hereinafter, the form of the highly functional forced reef applying the concept of the present invention will be described with reference to FIGS. 1 and 2.

1 and 2 are conceptual views showing the shape of the high functional forced reef to which the concept of the present invention is applied, respectively, FIG. 1 is a rectangular pyramidal high functional forced reef, and FIG. 2 conceptually shows a hexahedral high functional forced reef. will be.

As shown in Figures 1 and 2, the forced reef (10, 20) of the present invention is a hexahedral or square pyramid of a plurality of horizontal members (101, 201), vertical members (102, 202) and inclined members (203) The main structure (100, 200) and the plurality of horizontal members (151, 251) and vertical to have a smaller size than the inner space of the main structure (100, 200) configured to have a plurality of internal spaces of a predetermined size by joining each other in a large size It is composed of a plurality of auxiliary structures (150, 250) formed by densely joining the members (152, 252) to each other. At this time, the auxiliary structures 150 and 250 are adjacent horizontal members 101 and 201 and vertical members 102 so as to be disposed at positions having mutually symmetrical structures in some of the plurality of internal spaces of the main structures 100 and 200. , 202 is bonded and fixed. In addition, the auxiliary structure (150, 250) is bonded and fixed to be located at the lower side of the inner space of the main structure (100, 200).

Therefore, the forced reef (10, 20) of the present invention is configured to provide a variety of size space by relatively densely configured a plurality of predetermined internal space of the reef compared to other parts to create an ecological environment suitable for a variety of fish species. In addition, the forced reef (10, 20) of the present invention improves the structural stability by lowering the center of gravity because the dense space inside the reef is located in a symmetrical structure at the bottom.

In FIG. 1 and FIG. 2, the concept of the present invention has been described by taking an example of a main structure formed of a square pyramid shape or a hexahedron shape and a reef composed of an auxiliary structure formed of a cube shape, but the present invention is not limited thereto. . That is, the present invention constitutes the main structure in the form of a polygonal pyramid, a polygonal pyramid, a polyhedron and a combination of them, and a secondary structure consisting of a polygonal pyramid, a polygonal pyramid, a polyhedron or a hemisphere having a size smaller than the internal space of the main structure. It may be.

Hereinafter will be described in detail with reference to the accompanying drawings, preferred embodiments of a high-functional forced reef according to the present invention applying the above concept.

Figure 3 is a perspective view showing the shape of a square pyramid-shaped high functional forced reef in accordance with a first embodiment of the present invention. As shown in Figure 3, the square pyramid-shaped high functional forced reef 30 of the present invention is a main structure 300 and configured to have a plurality of internal spaces of a predetermined size by bonding a plurality of members to each other in a square pyramid, and the main structure It consists of a plurality of auxiliary structures 350 are formed by joining a plurality of members in a hexahedral shape to have a size smaller than the internal space of the (300). At this time, the auxiliary structure 350 is disposed in a position having a mutually symmetrical structure in some of the plurality of internal spaces of the main structure 300, and is also bonded and fixed to be located at the lower side of the inner space of the main structure 300.

First, the configuration of the main components constituting the present invention will be described in detail.

The main structure 300 has a lower end portion 310 having a rectangular shape having a predetermined size, an upper end portion 320 having a rectangular shape having a relatively smaller size than the lower end portion 310, and a lower end portion 310 and an upper end portion 320. It consists of a connecting portion 330 for connecting to each other with a predetermined vertical interval and a connecting column 340 for connecting the center of the lower end 310 and the upper end 320 with each other. At this time, the lower end 310 and the upper end 320 serves as a base.

The lower end 310 is formed by welding a plurality of first horizontal members 311 having a predetermined length in a rectangular shape to form a rectangular border, and are arranged radially toward the edge from the center of the space formed by the rectangular border, A plurality of beam members 312 are fixed to each other. At this time, the connection member 314 having a hole having a size that can be inserted into the connection pillar 340 is formed in the center of the rectangular frame, that is, one end of the beam member 312 is collected. Accordingly, the plurality of beam members 312 have one end fixed to each other along the circumference of the connection member 314, and the other end is fixed to the first horizontal member 311 constituting a radial edge. At this time, the other end of the beam member 312 is fixed to the corner of the rectangular border and the longitudinal center of the first horizontal member 311, respectively. Therefore, the lower end 310 has eight beam members connecting the corners of the four horizontal members 311 and the center of the four first horizontal members 311 and the connecting member 314 to each other at the corners of the first horizontal member 311 joined to each other. 312 is used. However, the number of the beam member 312 in the lower end 310 does not have a great meaning and can be configured by changing the number as necessary.

In addition, the lower end 310 further includes a plurality of second horizontal members 313 which connect the eight beam members 312 to each other in a horizontal direction to form an inner rectangular edge. Accordingly, the lower end 310 has two rectangular edges having different sizes based on the connecting member 314 as the center, and the corners of the rectangular edges and the center of the horizontal members 311 and 313 and the connecting member 314. It will have a stable structure to radially connect the beam member 312. At this time, the inner rectangular frame may be further configured through other horizontal members connecting the eight beam members 312 to each other in the horizontal direction.

The horizontal members 311 and 313 and the beam members 312 constituting the lower end 310 are preferably structurally stable, easy to combine, and excellent in strength.

The upper end 320 is configured in the same form as the lower end 310 is configured as described above, except that the size of the upper end 320 does not constitute an inner rectangular border. That is, the upper end 320 has a plurality of horizontal members 321 each of which constitutes a rectangular border, the corners of the rectangular border where the horizontal members 321 are bonded to each other, and the center of the horizontal member 321, and the connection pillar 340. It consists of a plurality of beam members 322 to radially connect the connecting member 323 having a hole that can be inserted. Thus, the upper end 320 has structural stability. At this time, it is preferable to configure the rectangular border of the upper end 320 and the inner rectangular border of the lower end 310 to have the same size.

In addition, the horizontal member 321 and the beam member 322 constituting the upper end 320 are preferably structurally stable, easy to bond, and using H-type steel having excellent strength. In addition, the upper end 320 may further include a plurality of other horizontal members constituting the inner rectangular border by connecting the plurality of beam members 322 to each other in the horizontal direction.

The connection part 330 is to connect the lower end 310 and the upper end 320 to each other at a predetermined up and down interval, and the vertical member 331 which vertically connects the lower end 310 and the upper end 320 and the lower end 310. And the inclined member 332 connecting the upper and lower ends 320 inclined, and the grid member 333 connecting the vertical members 331 and the upper and lower ends 320 and 310 adjacent to each other between the vertical members 331. It is composed.

At this time, the vertical member 331 is the center of the corner of the rectangular border and the horizontal member 321 of the upper end 320, the center of the inner rectangular border of the lower end 310 and the center of the second horizontal member 313 to each other Connect vertically. Therefore, eight vertical members 331 are used for the connecting portion 330. And the inclined member 332 is the center of the corner of the rectangular border and the horizontal member 321 of the upper end 320, the corner of the outer rectangular border of the lower end 310 and the center and both sides of the first horizontal member 311. Connect obliquely to each other. Therefore, sixteen inclined members 332 are used for the connection portion 330. However, the number of the vertical member 331 and the inclined member 332 in the connecting portion 330 does not have a great meaning and can be configured by changing the number as necessary.

The vertical member 331 uses a circular pipe that has a small load (fluid force) and hardly disturbs the flow of algae, the inclined member 332 uses H-shaped steel for structural stability, and a grid member 333 ), It is preferable to use a square pipe to enable a smooth coupling between each other.

The connecting column 340 connects the centers of the lower end 310 and the upper end 320 to each other, and is vertically vertically perpendicular to the holes of the connecting member 323 respectively formed at the center of the lower end 310 and the upper end 320. Inserted and welded together. Therefore, the connection column 340 serves as the central axis of the square pyramid-shaped forced reef 30 of the present invention. At this time, the connecting column 340 is preferably composed of a circular pipe or a solid cylinder that the load (fluid force) acts small and hardly disturbs the flow of algae.

Forced reef 30 of the present invention has a symmetrical structure of each component with respect to the connecting column 340 as a central axis. In addition, the forced reef 30 of the present invention is a central axis of the connecting column 340, the beam member (312, 322) of the lower end 310 and the upper end 320 on the basis of the connection column 340 is radial The array is composed. Therefore, the forced reef 30 of the present invention has a structural stability.

In addition, the main structure 300 of the present invention extends the first horizontal plate 315 and the first horizontal plate 321 to the inner side of the horizontal member 321 and the first horizontal member 311 so as to face the inner side of the upper and lower ends 320 and 310. Plates) are respectively extended and installed to extend the inclined plates 316 and the second extension plates, respectively, to have an inclination angle on the upper surface of the first horizontal member 311 so as to face the height direction of the edge of the lower end 310. At this time, the first horizontal plate 315 is horizontally bonded to the inner side of the lower end of the horizontal member 321 and the first horizontal member 311, the inclined plate 316 is the lower end of the first horizontal member 311 It is bonded to the upper surface and both ends are bonded to the inclined member 332, respectively.

In addition, the main structure 300 of the present invention is installed by extending the second horizontal plate 317 (third extension plate) on both sides of the second horizontal member 313 of the lower end 310, the second horizontal member 313 The vertical plate 318 (fourth extension plate) is extended to be installed in the height direction perpendicular to the upper surface of the c). At this time, the second horizontal plate 317 is bonded to both sides of the lower end of the second horizontal member 313 in the horizontal direction, the vertical plate 318 is the lower end is bonded to the upper surface of the second horizontal member 313 The ends are respectively joined to the vertical members 331.

Therefore, the main structure 300 of the present invention is compared to the ecological space of the fish formed due to its own shape (eg, H-shaped steel) of the first and second horizontal members 311 and 313, the first and second horizontal plates ( It provides a wider ecological space corresponding to the width of the 315, 317 and the height of the inclined plate 316 and the vertical plate 318. That is, the current flow is hindered by the inclined plate 316 and the vertical plate 318 so that plankton is clustered in the ecological space, and the first and second horizontal plates 315 and 317, the inclined plate 316, and the vertical plate 318. This can provide the greatest possible expansion of fish habitat, rest and sleeping ecology. Therefore, the main structure 300 of the present invention can be inhabited, rested and sleep in a more improved environment of fish species of various sizes as the ecological space is expanded.

And the main structure 300 of the present invention is suitable for the habitat of fish species that like the currents and vortices because the current flow is interrupted by the inclined plate 316 and the vertical plate 318 to form the water flow and vortices. In addition, the main structure 300 of the present invention is effective in soft ground as the area of contact with the ground is increased by the first and second horizontal plates 315 and 317. In addition, since the main structure 300 of the present invention provides a shading effect through the first and second horizontal plates 315 and 317, the inclined plate 316 and the vertical plate 318, the improved ecological environment of the fish is improved. to provide.

Next, the configuration of the auxiliary components constituting the present invention will be described.

The auxiliary structure 350 of the present invention is manufactured in a hexahedral shape by densely joining a plurality of horizontal members 351 and vertical members 352 to each other so as to have a smaller size than the inner space of the main structure 300. That is, the auxiliary structure 350 has a smaller size than a plurality of internal spaces constituting the interior of the main structure 300. In addition, the auxiliary structure 350 is the main structure 300 by joining the plurality of horizontal members 351 and the vertical member 352 with each other at a narrower interval than the interval between the members forming the internal space of the main structure 300 It has a relatively dense structure compared to At this time, the horizontal member 351 and the vertical member 352 constituting the auxiliary structure 350 is not limited to the shape and may use H-shaped steel, a circular pipe or a square pipe as necessary.

Forced reef 30 of the present invention is arranged in a position having a mutually symmetrical structure in some of the plurality of internal space of the main structure 300, the auxiliary structure 350 is configured as described above, and also the main structure 300 It is completed by joint fixing to adjacent members so as to be located at the bottom of the inner space of the. In addition, the forced reef 30 of the present invention is a plurality of inner space of the main structure 300 by joining a plurality of members to each other to have a relatively dense structure compared to other spaces in some spaces having a mutual symmetry structure of the plurality of internal spaces Auxiliary structures may also be constructed. That is, the forced reef 30 of the present invention is manufactured by installing the auxiliary structure 350 separately and installed in the internal space of the main structure 300, or joining a plurality of members in a predetermined internal space of the main structure 300 The auxiliary structure may be integrated into the main structure.

Therefore, the forced reef 30 of the present invention by installing the auxiliary structure 350 of a relatively dense structure in a certain internal space of the main structure 300 compared to other parts to provide a variety of fish species by providing a variety of sizes Create an ecological environment suitable for In other words, the forced reef 30 of the present invention is a complex and densely populated space of the secondary structure 350, childish inhabitants, in the space of the relatively large main structure 300, a large fish or sex food in the food chain system It is naturally formed to provide a friendly marine habitat. In addition, the forced reef 30 of the present invention has a more improved structural stability by lowering the center of gravity by configuring the auxiliary structure 350 inside the main structure 300 in a symmetrical structure at the bottom.

Figure 4 is a perspective view showing the shape of the hexahedral high-performance forced reef in accordance with a second embodiment of the present invention. As shown in FIG. 4, the hexahedral high functional forced reef 40 of the present invention is configured in the same shape as the lower end 410 and the upper end 420 constituting the main structure 400, and thus, the connection part 430. ) Is configured differently and the vertical plate 415 is used instead of the inclined plate 316, and is the same as the square pyramid-shaped high functional forced reef 30 of the first embodiment except that the installation position of the auxiliary structure 450 is slightly different. . Therefore, the description of the same components will be omitted here.

In the main structure 400 of the present invention, the lower end 410 and the upper end 420 are configured in the same form. Accordingly, the connection part 430 includes first and second vertical members 431 and 432 that vertically connect the outer and inner rectangular edges of the lower end 410 and the upper end 420, respectively, and the first and second vertical members 431. And first and second grating members 433 and 434 connecting adjacent first and second vertical members 431 and 432 and upper and lower ends 420 and 410 to each other. That is, the first vertical member 431 connects the corners of the outer rectangular edges of the upper and lower ends 420 and 410 and the centers of the first horizontal members 421 and 411 to each other vertically, and the second vertical member 432 is The corners of the inner rectangular edges of the upper and lower ends 420 and 410 and the centers of the second horizontal members 423 and 413 are vertically connected to each other.

And the main structure 400 of the present invention is installed by extending the first horizontal plate 414 to the inside of the first horizontal member 421, 411 of the upper and lower ends 420, 410, respectively, 1 The first vertical plate 415 extends in the height direction perpendicular to the upper surface of the horizontal member 411, respectively. At this time, the first horizontal plate 414 is horizontally bonded to the lower inner side of the first horizontal members 421 and 411, and the lower end of the first vertical plate 415 is the upper surface of the first horizontal member 411. Are bonded to both ends of the first vertical member 431.

In addition, the main structure 400 of the present invention is installed by extending the second horizontal plate 416 to both sides of the second horizontal member (423, 413) of the upper and lower ends (420, 410), 2 The second vertical plate 417 is extended and installed in the height direction perpendicular to the upper surface of the horizontal member 413. At this time, the second horizontal plate 416 is bonded to both sides of the lower end of the second horizontal member 423, 413 in the horizontal direction, the lower end of the second vertical plate 417 is the upper surface of the second horizontal member 413 Are bonded to both ends of the second vertical member 432.

In addition, the auxiliary structure 450 of the present invention densely joins the plurality of horizontal members 451 and the vertical member 452 to each other to have a size smaller than the inner space of the main structure 400, the auxiliary structure 350 of the first embodiment It is manufactured in the same cube shape as).

Forced reef (40) of the present invention is arranged in a position having a mutually symmetrical structure in some of the plurality of internal space of the main structure 400, the auxiliary structure 450 is configured as described above, and also the main structure (400) It is completed by joint fixing to adjacent members so as to be located at the bottom of the inner space of the. In addition, the forced reef 40 of the present invention is a plurality of inner space of the main structure 400 by joining a plurality of members to each other to have a structure that is relatively dense compared to other spaces in some spaces having mutual symmetry structure Auxiliary structures may also be constructed. That is, the forced reef 40 of the present invention is manufactured by installing the auxiliary structure 450 separately and installed in the internal space of the main structure 400, or joining a plurality of members in a predetermined internal space of the main structure 400 The auxiliary structure may be integrated into the main structure.

5 is a perspective view showing the form of the combined type high-performance forced reef in accordance with a third embodiment of the present invention. As shown in FIG. 5, the combined functional forced reef 50 of the present invention has a hexagonal main structure 400 arranged between the square pyramidal main structures 300 and 300A having different sizes so that the first-stage sandwich type main structure is arranged. Comprising (500), a plurality of hexahedral auxiliary structure 550 is manufactured in a form that is installed in a symmetrical structure in a part of the inner space of the square pyramidal main structure (300A). At this time, the square pyramid-shaped main structure 300 is configured in the same manner as the main structure of the first embodiment, the other square pyramid-shaped main structure 300A is configured in the same concept as the main structure 300 of the first embodiment, the size is As it grows, some components are added. And the hexagonal main structure 400 is configured in the same manner as the main structure of the second embodiment.

Combination type functional forced reef 50 of the present invention is configured as a sandwich form in which the hexahedral main structure 400 is arranged between the square pyramid-shaped main structure (300, 300A), each of the square border formed in the upper and lower ends up and down each other It is in contact with the structure. However, the forced reef (50) of the present invention may be configured such that the upper and lower ends are in contact by one rectangular border by removing one of the rectangular borders that are in contact with the vertical.

In addition, the auxiliary structure 550 of the present invention densely joins the plurality of horizontal members 551 and the vertical member 552 to each other to have a size smaller than the inner space of the main structure 500, the auxiliary structure 350 of the first embodiment It is manufactured in the same cube shape as).

Forced reef (50) of the present invention is to arrange the auxiliary structure 550 configured as described above in a position having a mutually symmetrical structure in some of the plurality of internal space of the main structure 500, and also the main structure 500 It is completed by joint fixing to adjacent members so as to be located at the bottom of the inner space of the. In addition, the forced reef (50) of the present invention by joining a plurality of members to each other to have a relatively dense structure compared to other spaces in some spaces having a mutual symmetry structure of a plurality of internal spaces of the main structure 500 Auxiliary structures may also be constructed. That is, the forced reef 50 of the present invention is manufactured by installing the auxiliary structure 550 separately in the interior space of the main structure 500, or joining a plurality of members in a predetermined internal space of the main structure 500 The auxiliary structure may be integrated into the main structure.

6 is a perspective view showing the shape of a high-rise, high-functional forced reef in accordance with a fourth embodiment of the present invention. As shown in Figure 6, the high-rise functional forced reef (60) of the present invention is a hexagonal main structure (400A) and a square pyramid-shaped main structure (300B) on the top of the combined functional forced reef (50) configured as shown in FIG. It is configured by sequentially further stacking. Therefore, the forced reef (60) of the present invention is located at the bottom and top of the square pyramid-shaped main structure, respectively, between the two-stage sandwich-type main structure 600, the hexahedral main structure and other square pyramid-shaped main structure sequentially located between ).

At this time, the hexahedral main structure 400A is configured in the same concept as the main structure 400 of the second embodiment, but is configured in such a way that some components are removed as the size is reduced. In addition, the square pyramid-shaped main structure 300B is configured in the same concept as the main structure 300 of the first embodiment, but is configured in a form that some components are removed as the size is reduced.

The forced reef 60 of the present invention has a structure in which square edges respectively formed at the upper and lower ends thereof contact each other up and down like the combined functional forced reef 50 of the third embodiment. However, the forced reef 60 of the present invention may be configured such that the upper and lower ends are contacted by one rectangular border by removing one of the rectangular borders which are in contact with the upper and lower sides.

7 is a perspective view showing the form of a high-rise, high-functional forced reef in accordance with a fifth embodiment of the present invention. As shown in FIG. 7, the high-rise high functional forced reef 70 of the present invention sequentially a plurality of hexahedral main structure 400A located at the upper end of the high-rise high functional forced reef 60 as shown in FIG. Laminated and constructed by stacking a square pyramidal main structure (300B) at the top. Therefore, the steel reef 70 of the present invention is located at the bottom and top of the square pyramid-shaped main structure, respectively, a plurality of hexahedral main structure and another square pyramid-shaped main structure is located between the two-stage sandwich long A mold main structure 700.

The forced reef 70 of the present invention has a structure in which square edges respectively formed on the upper and lower ends are in contact with each other up and down like the forced reef 60 of the fourth embodiment. However, the forced reef 70 of the present invention may be configured such that the upper and lower ends are contacted by one rectangular border by removing one of the rectangular borders which are in contact with each other.

As described in detail above, the present invention has an effect of providing a pro-oceanic habitat for fish by constructing a plurality of predetermined internal spaces of the reefs relatively densely than other parts to create an ecological environment suitable for various fish species.

In addition, the present invention has the effect of improving the structural stability by lowering the center of gravity by configuring the dense space inside the eocho in a symmetrical structure on the lower side.

In the above description of the technical details of the high-functional forced reef of the present invention with reference to the accompanying drawings, which illustrate the best embodiment of the present invention by way of example and not limit the present invention.

In addition, it is obvious that any person skilled in the art can make various modifications and imitations within the scope of the appended claims without departing from the scope of the technical idea of the present invention.

Claims (7)

As a high-functional forced reef that is installed in the sea to create aquatic resources, A main structure including a plurality of base parts joined together by a plurality of horizontal members to form a polygonal edge, and at least one connection part connecting the base parts to each other at vertical intervals; A plurality of members are joined to each other at a narrower interval than the interval between the members forming the inner space of the main structure has a dense structure, it is installed in a mutually symmetrical structure at the lower side of some spaces of the plurality of inner space of the main structure High-performance forced reef characterized in that it comprises a plurality of auxiliary structures. 2. The apparatus of claim 1, wherein the main structure comprises: a plurality of first extension plates extending and installed on one side of the horizontal member so as to face the inner side of the base portion; It is installed on at least the lowermost base portion of the plurality of base portion, characterized in that it further comprises a plurality of second extension plate which is installed to extend to each other side of the horizontal member so as to face the height direction of the edge of the base portion High functional forced reef. According to claim 1 or claim 2, The main structure is a high-performance forced reef, characterized in that the plurality of base portion is composed of two rectangular shape of the same size, respectively to form a hexahedral form by connecting up and down to the connecting portion. According to claim 1 or claim 2, The main structure is a high-performance forced reef characterized in that the plurality of base portion is composed of two rectangular shapes of different sizes, respectively by connecting up and down to the connecting portion to form a square pyramid . According to claim 1 or 2, wherein the main structure is a polygonal pyramid-shaped main structure constituting a lower end by connecting the two base parts of the polygonal shape of different sizes up and down with the connecting portion, and the polygonal pyramid-shaped main structure of The base portion having the same size as the base portion constituting the upper end up and down connecting the base portion to the connecting portion constituting the interruption, and the base portion having a size smaller than the base portion constituting the upper end of the polyhedral main structure High functional force reef characterized in that it comprises a different polygonal pyramidal main structure constituting the upper end by connecting up and down with the connecting portion. According to claim 5, The main structure is another polyhedron-shaped main structure and the other polyhedral structure configured by connecting the base portion having the same size as the base portion constituting the upper end of the other polygonal pyramid-shaped main structure up and down with the connecting portion, The high-performance forced reef characterized in that it further comprises another polygonal truncated main structure constituting the upper end by connecting the base portion having a smaller size than the base portion constituting the upper end of the main structure to the connecting portion. The method according to claim 6, wherein the main structure is a polyhedral main body consisting of a plurality of the base portion having the same size as the base portion constituting the upper end of the other polygonal pyramid-shaped main structure sequentially connected to the plurality of the connecting portion in the vertical direction It further comprises a structure and another polygonal pyramid-shaped main structure constituting the upper end by connecting the base portion having a size smaller than the base portion constituting the top of the other polyhedral main structures to the connecting portion up and down Functional Forced Reefs.

Images