KR102155298B1 - Form for tetrapod and tetrapod thereof - Google Patents

Abstract

The multifunctional tetrapod according to the present invention is provided on four legs and four legs each extending from the center of the triangular pyramid in the direction of the four apex of the triangular pyramid, and is formed protruding outward while dividing the circumference of the leg into three equal parts And a plurality of first protruding jaws provided to connect two adjacent legs to each other, and a plurality of second protruding jaws formed to protrude outward between the plurality of first protruding jaws and spaced apart from each other. In addition, it may include an anchor bolt inserted between the plurality of first protruding jaws and a vegetation rope connected to the anchor bolt.
According to an embodiment of the present invention having the configuration as described above, since the cross-sectional area of the tetrapod is not reduced, it is excellent in durability, vegetation of marine life is easy, it is stable when the tetrapod is mounted on a breakwater, and a fall accident occurs when a person climbs above the tetrapod. prevent.

Description

Tetrapod manufacturing die and tetrapod manufactured using the same {FORM FOR TETRAPOD AND TETRAPOD THEREOF}

The present invention relates to a tetrapod for manufacturing a tetrapod, and to a tetrapod manufactured using the same, and more specifically, to a form used to manufacture a tetrapod with improved durability, reduced wave energy, and increased structural stability, and a tetrapod manufactured using the same. About.

In general, waves entering the port from the open sea can be reduced by properly arranging the breakwater, and waves breaking beyond the ceiling of the breakwater can be reduced by increasing the ceiling. Breakwater is an offshore structure designed to cover the waves of the open sea, prevent overbreaking into the inland sea, maintain the calm temperature of the inland sea, and protect the anchored ships, and protect the water body and port facilities in the port from waves. There are several types of breakwater structures, such as sloped and upright, depending on the nature or size of the ground or waves.

There is a need for a tetrapod having a structure that is convenient to construct and protect facilities adjacent to the coast by effectively sofaing the waves invading from the open sea, and there is also a need to develop a structure of a tetrapod that can coexist with marine animals and plants with beautiful scenery.

Since the surface of the tetrapod is generally smooth, fall accidents of anglers occur frequently and there is a problem. In addition, as the weight of the tetrapod increases and the swell wave increases, the problem of destruction of the tetrapod occurs frequently. According to domestic and foreign papers, the destruction of the tetrapod occurs at the joint of the tetrapod leg, and shear failure is often caused by the weight of the tetrapod supported by both ends of the leg and the load applied from the loaded tetrapod.

In addition, tetrapods are destroyed as they flow underwater by wave energy while installed in the ocean. Research and development of a tetrapod structure that effectively reduces the wave energy and increases the durability of the tetrapod itself is required.

(Document 0001) Korean Patent Registration No. 10-1697171 (Document 0002) Korean Patent Registration No. 10-1674383 (Document 0003) Korean Patent Registration No. 10-1786811 (Document 0004) Korean Registered Office No. 20-0398037 (Document 0005) Korean Patent Application Publication No. 10-2016-0036538

An object of the present invention in consideration of the above points is to provide a formwork for manufacturing a tetrapod that reinforces a weak part when loading a tetrapod to increase strength, while stably loading and preventing flow after loading through an interlocking structure.

The formwork for manufacturing a tetrapod according to an embodiment of the present invention is provided between a body portion, four legs radially connected to the body portion, a first protruding jaw and a first protruding jaw provided with a plurality of lengthwise spaced apart on the outer surface of the leg, In the formwork used to manufacture the tetrapod including the second protruding jaw protruding along the circumferential direction of the leg, a plurality of formwork bodies that can be arranged to cover the outer surface while dividing the body part and the leg equally, and the connection position of the adjacent formwork bodies The first insertion groove is provided in the longitudinal direction of the leg and sinks inward to determine the shape of the first protruding jaw, the fixture provided on the outer surface of the first insertion groove and connecting the adjacent formwork to each other, and the adjacent first insertion groove It includes a second insertion groove provided between and settles inward to determine the shape of the second protruding jaw, and the first insertion groove is not formed at the end of the formwork body surrounding the outer surface of the end of the leg.

Also, the first insertion groove may communicate with the second insertion groove.

In addition, the plurality of second insertion grooves may be provided to be radially spaced apart from each other by a predetermined distance from the center of the formwork body.

In addition, it further comprises a joint reinforcing groove settled inward while dividing the form body into three from the center of the formwork body, and the joint reinforcing groove may be located at the joint of the leg.

In addition, a protruding jaw provided inside the first insertion groove or the second insertion groove and protruding outward may be further included.

In addition, tetrapods may be manufactured using the above formwork.

When using the formwork for manufacturing a tetrapod according to an embodiment of the present invention, it is easy to mass-produce tetrapods that are provided with a first protruding jaw and a second protruding jaw to increase wave scattering, structural stability, fall prevention, and strength.

In addition, a first insertion groove for determining the shape of the first protruding jaw and a second insertion groove for determining the shape of the second protruding jaw are provided, so that the shape of the first protruding jaw and the second protruding jaw can be easily changed. , It is easy to disassemble and disassemble the formwork as a plurality of formwork bodies are combined across the first insertion groove.

1 is a perspective view showing a formwork for manufacturing a tetrapod according to an embodiment of the present invention.
2 is an exploded perspective view showing a formwork and a tetrapod according to an embodiment of the present invention.
3 to 6 are detailed views showing a formwork body according to an embodiment of the present invention.
7 and 8 are detailed views showing cross-sectional shapes of a first insertion groove, a second insertion groove, and a joint reinforcing groove according to an embodiment of the present invention.
9 is a perspective view showing the inner side of the formwork body according to an embodiment of the present invention.
10 to 12 are perspective views showing a tetrapod manufactured by a formwork according to an embodiment of the present invention.
13 and 14 are images showing the structural analysis of a tetrapod manufactured by a formwork according to an embodiment of the present invention.

In describing the present invention, if it is determined that the detailed description of the related known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted.

Since the embodiments according to the concept of the present invention can apply various changes and have various forms, specific embodiments will be illustrated in the drawings and described in detail in the present specification or application. However, this is not intended to limit the embodiments according to the concept of the present invention to a specific form of disclosure, and it should be understood that all changes, equivalents, and substitutes included in the spirit and scope of the present invention are included.

The terms used in the present specification are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this specification, the "inclusive" or "gajida" and the terms are staking the features, numbers, steps, operations, elements, parts or geotyiji to be a combination thereof specify the presence, of one or more other features, integers It is to be understood that the possibility of addition or presence of, steps, actions, components, parts, or combinations thereof is not preliminarily excluded.

Hereinafter, the present invention will be described in detail.

1 is a perspective view showing a formwork for manufacturing a tetrapod according to an embodiment of the present invention, Figure 2 is an exploded perspective view showing the formwork 1000 and the tetrapod (T) according to an embodiment of the present invention.

1 and 2, the formwork for manufacturing a tetrapod according to an embodiment of the present invention includes a body part, four legs 100 radially connected to the body part, and a plurality of longitudinally on the outer surface of the leg 100 A tetrapod (T) provided between the first protruding jaw 200 and the first protruding jaw 200 provided spaced apart from each other and including a second protruding jaw 300 protruding along the circumferential direction of the leg 100 In the formwork used to manufacture, a plurality of formwork bodies 1100 that can be arranged to surround the outer surface while dividing the body part and the leg 100 equally, is provided at a connection position of the adjacent formwork body 1100, and the leg A first insertion groove 1110 that sinks inward along the longitudinal direction of 100 to determine the shape of the first protrusion 200, and is provided on the outer surface of the first insertion groove 1110, and is adjacent to the formwork body A second insertion groove (1120) provided between the fixture (1130) connecting the (1100) to each other and the adjacent first insertion groove (1110) and settles inward to determine the shape of the second projection (300). Include.

The formwork body 1100 is a plurality, a plurality of formwork bodies 1100 are connected to each other to form a formwork 1000, and a receiving space in which concrete, etc. can be poured is formed inside the formwork body 1100 connected to each other. . When concrete or the like is poured into the receiving space, the inner surface of the formwork body 1100 determines the formation of the outer surface of the tetrapod (T).

In one embodiment of the present invention, the form body 1100 may be formed of four and the outer sides are connected to each other to form a triangular pyramid shape. In this case, one of the four formwork bodies 1100 is connected to the remaining three formwork bodies 1100.

3 to 6 are detailed views showing a formwork body 1100 according to an embodiment of the present invention. 3 to 6 show positions and shapes of the first insertion groove 1110 according to the present invention, respectively.

3 to 6, the first insertion groove 1110 provided in the formwork body 1100 is provided at a position where the formwork body 1100 is connected to each other. The first insertion groove 1110 has a shape settled from the inner surface of the formwork body 1100 to the inside, and the first protrusion of the tetrapod (T) when concrete, etc. is poured and cured in the first insertion groove 1110 The jaw 200 is formed. Specifically, the first insertion groove 1110 extends in the longitudinal direction and determines the shape of the first protrusion 200 extending in the longitudinal direction while connecting the legs 100 of the tetrapod T to each other. The cross-sectional shape of the first protruding jaw 200 may be various, and the first protruding jaw 200 from the degree of sinking into the inner side of the first insertion groove 1110 or the inner shape of the first insertion groove 1110. The cross-sectional shape of) is determined.

The first insertion groove 1110 may be formed as the adjacent formwork bodies 1100 are connected to each other. That is, half of the first insertion groove 1110 is provided in one formwork body 1100, and the other half is provided in another formwork body 1100 connected to the formwork body 1100, so that the formwork body 1100 As they are connected to each other, the first insertion groove 1110 may be formed. In this case, the first insertion groove 1110 may be divided in half along the length direction of the leg 100.

The first insertion groove 1110 may be plural, and in one embodiment of the present invention, three first insertion grooves 1110 are provided in the formwork body 1100. The tetrapod (T) formed according to the present invention having the above shape is provided with a total of three first protruding jaws 200 on each leg 100, and the first protruding jaws 200 provided of each leg 100 are Are connected to each other.

The fixture 1130 provided outside the first insertion groove 1110 is formed along the longitudinal direction of the first insertion groove 1110, and is provided with a plurality of holes to facilitate connection between the adjacent formwork bodies 1100 Let's do it. The fixture 1130 has an a shape at the end of the formwork body 1100 and is bent outward, and protrudes outward from the formwork body 1100 when adjacent formwork bodies 1100 are connected to each other. In this case, the fixture 1130 may be formed while adjacent formwork bodies 1100 are connected to each other.

A plurality of holes are formed in the fixture 1130, and screws or pins are fastened to the holes to fix and connect the form body 1100. The fixture 1130 is preferably formed integrally with the formwork body (1100).

The second insertion groove 1120 of the present invention has a shape that is settled into the inside of the formwork body 1100 while forming a predetermined angle with the first insertion groove 1110. The second insertion groove 1120 may extend in the circumferential direction of the tetrapod (T) leg 100.

The shape of the second insertion groove 1120 may vary, and the cross-sectional shape of the second protruding protrusion 300 of the tetrapod T is determined according to the shape of the second insertion groove 1120.

The second insertion groove 1120 may be plural, and each of the plurality of second insertion grooves 1120 may be provided to be radially spaced apart from the center of the formwork body 1100 by a predetermined distance. In this case, a total of three second insertion grooves 1120 may be provided in the formwork body 1100.

In an embodiment of the present invention, the first insertion groove 1110 may communicate with the second insertion groove 1120. The tetrapod T having a first protruding jaw 200 and a second protruding jaw 300 formed by the first insertion groove 1110 and the second insertion groove 1120 communicated with each other is a first protruding jaw 200 ) The second protruding jaw 300 supports and distributes the load applied to the second protruding jaw 300, or the first protruding jaw 200 supports and disperses the load applied to the second protruding jaw 300 to increase the durability of the tetrapod (T). And the interlocking structure is better. In addition, the depth of the first insertion groove 1110 and the second insertion groove 1120 settled may be the same. As the first insertion groove 1110 and the second insertion groove 1120 communicate with each other, the first protruding jaw 200 and the second protruding jaw 300 of the tetrapod T formed by the formwork 1000 are They can communicate with each other. In this case, the second insertion groove 1120 is located between the first insertion groove 1110 and the adjacent first insertion groove 1110.

In addition, the second insertion groove 1120 may be provided to connect ends of the first insertion groove 1110 to each other. In this case, damage of the first insertion groove 1110 may be further prevented by the second insertion groove 1120 connecting the ends of the first insertion groove 1110 to each other.

7 and 8 are detailed views showing cross-sectional shapes of the first insertion groove 1110, the second insertion groove 1120, and the joint reinforcing groove 1140 according to an embodiment of the present invention.

As shown in FIG. 7, both ends of the first insertion groove 1110, the second insertion groove 1120, or the joint reinforcing groove 1140 may be formed to be inclined from top to bottom, and formed to be inclined. The first insertion groove 1110, the second insertion groove 1120, or the joint reinforcing groove 1140 has an effect of increasing durability by effectively distributing external force caused by collision with waves or adjacent tetrapods.

In addition, as shown in FIG. 8, both ends of the first insertion groove 1110, the second insertion groove 1120, or the joint reinforcing groove 1140 are inclined downward, but may form a gentle curve, In this case, the durability is further increased.

9 is a perspective view showing the inner surface of the formwork body 1100 according to an embodiment of the present invention.

Referring to FIG. 9, a stepped step 1150 provided inside the first insertion groove 1110 or the second insertion groove 1120 and protruding outward may be further included. For example, the stepped jaw 1150 has a shape protruding outward on an inner side of the first insertion groove 1110, and when adjacent formwork bodies 1100 are connected to each other, one stepped jaw 1150 is formed. I can. It is preferable that the stepped jaw 1150 is located at a central portion along the longitudinal direction of the first insertion groove 1110 or the second insertion groove.

In the present invention provided with a stepped jaw 1150, a part of the first protruding jaw 200 or the second protruding jaw 300 of the tetrapod T formed by the formwork 1000 has a shape in which zeolite or polysaccharide By attaching a back, it can play a role of providing a place for marine life.

In an embodiment of the present invention, further comprising a joint reinforcing groove 1140 settled inward while dividing the form body 1100 from the center of the form body 1100 into three, and the joint reinforcing groove 1140 May be located at the joint of the leg 100.

The joint reinforcing groove 1140 is formed extending in the direction of the center point of each first insertion groove 1110 from the center point of the formwork body 1100 and has a shape that has settled inward, so that it is easy to reinforce the weak part of the tetrapod (T). Do. The tetrapod (T) has a weak joint that connects the legs 100 to each other due to its own weight, etc., but in the present invention, since the joint of the leg 100 has a cross-sectional increase effect, the durability of the tetrapod (T) itself is improved. Can be expected.

The joint reinforcing groove 1140 may have various shapes, but is preferably formed to gently settle in the inner direction of the form body 1100. In this case, the inner surface of the formwork body 1100 and the joint reinforcing groove 1140 may form an obtuse angle with each other.

The tetrapod (T) is manufactured according to the formwork 1000 of the present invention as described above, and the tetrapod (T) has its own weight to reduce wave energy or act as an ecological block.

Hereinafter, the tetrapod (T) manufactured by the present invention will be described.

10 to 12 are perspective views showing a tetrapod (T) manufactured by a formwork according to an embodiment of the present invention.

Referring to Figure 10, the tetrapod (T) according to an embodiment of the present invention is provided with a body portion, four legs 100 radially connected to the body portion, a plurality of longitudinally spaced apart from the outer surface of the leg 100 The first protruding jaw 200 and the second protruding jaw 300 are provided between each of the first protruding jaws 200 and protruding along the circumferential direction of the leg 100. The first insertion groove 1110 of the above-described formwork 1000 forms the first protruding jaw 200, and the second insertion groove 1120 of the formwork 1000 forms the second protruding jaw 300 do.

The mounting portion 120 can be formed by adjusting the length of the first insertion groove 1110 provided in the formwork 1000 so that the first protruding jaw 200 is not provided at the distal end of the leg of the tetrapod T. have. The mounting portion 120 reduces the flow of the tetrapod (T) to ensure structural stability. The circumference of the distal end of the leg 100 of the tetrapod T may be formed in a polygonal shape, and accordingly, the mounting portion 120 may have a polygonal shape. It is preferable in terms of mounting a plurality of tetrapods (T) that the end circumference of the leg 100 of the tetrapod (T) having a polygonal shape has a hexagonal shape.

The tetrapod (T) consisting of the four legs (100) may have a triangular pyramid shape as a whole, and the four legs (100) are connected to each other at the body portion and gradually circumferentially from the center of the body portion toward the end of the leg (100). May decrease. Each of the four legs 100 may have a hollow shape. The hollow bridge 100 has a receiving space inside and an additive that attracts and settles fish, etc. is inserted to serve as a habitat for marine life. In addition, there is an effect of reducing the cost of materials such as concrete filling the interior of each of the legs 100 during the manufacturing process of the tetrapod (T).

The first protruding jaw 200 may be provided on each of the four legs 100. The first protruding jaw 200 may be formed to protrude from the surface of the leg 100 along a longitudinal direction in which the leg 100 is formed. In one embodiment of the present invention, one leg 100 of the four legs 100 is provided with three first protruding jaws 200, and the three first protruding jaws 200 are the legs 100 It forms an angle of 120ㅀ around the circumference of the leg 100 can be divided into three equal parts.

The first protruding protrusion 200 may be extended by half the length of the leg 100, and the first protruding protrusion 200 may have various lengths.

According to the present invention having the first protruding jaw 200, when a plurality of tetrapods (T) are mounted on a breakwater, the first protruding jaws 200 are hooked to each other to increase the support, and above the tetrapod (T) on the water surface. When an angler or tourist goes up, the first protruding jaw 200 serves as a scaffold to prevent a fall accident.

Although not shown in the present invention, the first protruding jaw 200 is an intaglio rail 210 (not shown) extending in the longitudinal direction of the first protruding jaw 200 and having a groove inwardly, and the first protruding jaw 200 It may include an embossed rail 220 (not shown) extending in the longitudinal direction of 200 and protruding outward.

The engraved rail 210 is provided on the first protruding protrusion 200 and may be a plurality of submerged inwardly of the first protruding protrusion 200, and the embossed rail 220 is the positive portion of the engraved rail 210. A shape forming a side wall may be plural. The plurality of engraved rails 210 and embossed rails 220 may be repeatedly arranged. In one embodiment of the present invention, the relief rail 220 is provided on both sides of the intaglio rail 210, and the intaglio rail 210 is repeatedly arranged on both sides of the relief rail 220 And, by configuring the arrangement as described above, the surface area of the first protruding jaw 200 is widened, so that the vegetation and reproduction of marine organisms such as seaweed are more facilitated.

The intaglio rail 210 may be provided with nutrients to facilitate propagation and self-growth of marine organisms. The nutrients may vary depending on the type of marine organisms and the installation environment.

Referring to FIG. 11, in an embodiment of the present invention, the first protruding jaw 200 or the second protruding jaw 300 may include an inner jaw 230 and an outer jaw 240.

One side of the inner jaw 230 is connected to the leg 100 and the other side of the inner jaw 230 is connected to the outer jaw 240. In one embodiment of the present invention, since the inner jaw 230 and the outer jaw 240 have different cross-sectional areas, the surface area of the first protruding jaw 200 is widened, thereby facilitating vegetation of marine organisms. There is one effect. For example, the inner jaw 230 may be formed to be wider or narrower than the cross-sectional area of the outer jaw 240. In addition, the inner jaw 230 and the outer jaw 240 may be formed of different materials.

Each of the plurality of first protrusions 200 may be provided with a locking groove. When mounting the tetrapod (T), a wire, etc. can be hung on the tetrapod (T) using a crane or the like, spaced apart from it, and moved to a predetermined position before loading. The locking groove may be provided to cross the longitudinal direction of the plurality of first protruding protrusions 200 for moving and loading the tetrapod T as described above, and each of the first protruding protrusions 200 It may be provided in plurality. In addition, the locking groove may have various shapes and may be formed at various positions of the first protruding protrusion 200. It is preferable that the engaging grooves formed in each of the plurality of first protruding protrusions 200 are formed such that an extension line extending adjacent engaging grooves is perpendicular to the longitudinal direction of the first protruding protrusion 200. When the tetrapod (T) is moved or mounted, a wire such as a crane is caught in the locking groove.

According to an embodiment of the present invention provided with the locking groove, since a wire such as a crane is caught in the locking groove, a more stable operation is possible when the tetrapod (T) is transported and mounted. In addition, even after a plurality of tetrapods (T) are mounted, vegetation ropes or wires can be connected to connect the locking grooves provided in each of the plurality of tetrapods (T), so it is more effective in the standing and breeding of marine organisms. The tetrapods (T) can be supported with each other, and the vegetation rope or wire connecting the plurality of locking grooves can be combined with a net to prevent a person from falling from the top or to play a role of a fishweed. It works.

In an embodiment of the present invention, the plurality of first protruding jaws 200 protrude outwardly and may further include a second protruding jaw 300. The second protruding jaw 300 is provided between the first protruding jaw 200 and increases the surface area of the tetrapod (T) to facilitate vegetation of marine organisms, while the second protruding jaw (T) is mounted The protruding jaw 300 is hooked with the first protruding jaw 200 or the second protruding jaw 300 to assist in stable support, and when a person rises above the tetrapod T on the water surface, it acts as a scaffold to prevent a fall accident. do.

In one embodiment of the present invention, the second protruding jaw 300 may be plural, and the plurality of second protruding jaws 300 may be provided to be spaced apart from each other by a predetermined distance. In addition, the plurality of second protruding jaws 300 are provided with one second protruding jaw 300 above or below a pair of second protruding jaws 300 that are spaced apart from each other by a predetermined distance. A total of 9 second protruding jaws 300 provided on any one of the legs 100 may be provided. According to the embodiment of the present invention having the above arrangement, the scattering effect of waves is more excellent.

The second protruding jaw 300 may extend in a horizontal direction and have a predetermined angle with the first protruding jaw 200. The second protruding jaw 300 may extend along the circumference of the leg 100 to form 90° with the first protruding jaw 200.

Six or more of the second protruding jaws 300 may be provided on one leg 100, but two or more may be provided between the first protruding jaws 200 of the leg 100. In addition, a plurality of second protruding jaws 300 provided between the first protruding jaws 200 may be spaced apart at a predetermined interval, and a vegetation rope 500 to be described later may be provided between the second protruding jaws 300.

In another embodiment of the present invention, the second protruding jaw 300 may have a U or V shape, and the U or V shape may have an inverted shape according to a viewing angle. The second protruding jaw 300 having the above shape can attach nutrients or zeolite for vegetation to the inner concave portion, so that the vegetation effect of marine organisms is more excellent. One or more second protruding jaws 300 having the above shape may be provided between the plurality of first protruding jaws 200.

In addition, the second protruding jaw 300 may be provided with a relief rail 220 and an intaglio rail 210, and the relief rail 220 and the intaglio rail 210 provided on the second protruding jaw 300 Corresponds to the embossed rail 220 and the embossed rail 210 provided on the first protruding jaw 200.

Referring to FIG. 12, an anchor bolt 400 and a vegetation rope 500 connected to the anchor bolt 400 may be provided between the first protruding jaws 200.

The anchor bolt 400 may be integrated with the leg 100 by placing the anchor bolt 400 in a preset position when placing concrete or the like during the manufacturing process of the tetrapod (T). After fabrication, a penetration hole may be formed in the leg 100, and then the penetration hole may be penetrated.

A plurality of anchor bolts 400 may be provided, and a connector 410 may be provided on all or part of the plurality of anchor bolts 400 to connect a plurality of tetrapods T. The anchor bolt 400 may include an insertion part inserted into the inner side of the leg 100 and a connection part connected to the vegetation rope 500, and different tetrapods T among a plurality of tetrapods T and A connector 410 may be included to enable mutual connection, or the connector may serve as the connector 410.

The connector 410 may be formed to surround a part of the outside of the vegetation rope 500 to have a shape rolled inward along the circumference of the vegetation rope 500, and the connector 410 is the tetrapod (T) It may have a ring shape formed to protrude outward of the. The connector 410 having a ring shape may be an eye bolt.

A plurality of tetrapods (T) connected to each other through the connector 410 are supported with each other above and below the water surface, thereby improving structural stability. The plurality of tetrapods (T) may be connected with wires, ropes, cables, etc., and may be connected with the vegetation rope 500. If a plurality of tetrapods (T) are connected to the vegetation rope 500, there is an advantage that the propagation of marine organisms can be more actively performed.

In addition, although not shown in the drawing, a net may be provided between a plurality of tetrapods T that are connected to each other through the connector 410. In this case, the plurality of tetrapods (T) connected to each other are coupled to each other, such as a wire connecting the connector 410 provided at a corresponding position to each other, and a net is coupled to the wire. While the net facilitates vegetation of marine organisms, when a person falls from the upper part of the tetrapod (T), it may be caught in the net and prevent injury due to a fall accident. The net may be formed of the same material as the vegetation rope 500 or the vegetation cover 520 to be described later.

The shape and configuration of the anchor bolt 400 may be various. As an example, the anchor bolt 400 may be provided with a receiving portion into which the vegetation rope 500 is inserted, and may be formed to protrude outward when penetrated into the tetrapod (T). The number of anchor bolts 400, insertion positions, etc. may vary, and may be inserted into the first protrusion 200 or the second protrusion 300.

The anchor bolt 400 has an insertion portion inserted into the leg 100 and a connection portion protruding outward of the leg 100, and a vegetation rope 500 may be connected to the connection portion. The anchor bolt 400 may be provided between the first protruding protrusions 200, and may be provided between the second protruding protrusions 300 when there are a plurality of second protruding protrusions 300. In this case, an anchor bolt 400 may be additionally provided at the ends of each of the four legs 100, and a vegetation rope 500 is coupled between the connecting portions of the anchor bolts 400. According to the present invention having the configuration as described above, the vegetation rope 500 may be provided with three per leg 100.

A plurality of anchor bolts 400 are provided on both sides of the first protruding jaw 200 along the longitudinal direction of the first protruding jaw 200, and the vegetation rope 500 is the first protruding jaw It may be provided to connect the anchor bolt 400 along the longitudinal direction of 200.

In detail, the vegetation rope 500 is provided on both sides of the first protruding jaw 200, and the anchor bolt 400 includes an insertion part and a connection part, but the connection part of the leg 100 It is bent to have a convex shape outward and is a structure in which the vegetation rope 500 is accommodated inside the convex shape. The vegetation rope 500 is partially wrapped around the outer circumferential surface by the connecting portion of the anchor bolt 400 and is fixed to the leg 100. As described above, the vegetation rope 500 is provided on both sides of the first protruding jaw 200 to induce reproduction in the longitudinal direction of the first protruding jaw 200 when seaweed, etc. is propagated on the vegetation rope 500. I can.

The vegetation rope 500 may be formed of cotton, hemp, synthetic fibers, etc., and may be formed by twisting a plurality of strands with each other. The vegetation rope 500 facilitates spore propagation such as seaweed, and facilitates vegetation and reproduction of seaweeds in the sea or on the surface.

The vegetation rope 500 includes a main rope 510 extending in the longitudinal direction and a vegetation cover 520 formed to surround the outer circumferential surface of the main rope 510 and formed to have a greater permeability than the main rope 510 can do.

The vegetation cover 520 may be formed of a foamed plastic, fiber, synthetic fiber, etc. as a porous material, and may have a lattice shape formed by crossing lines in different directions. The water permeability of the vegetation cover 520 is formed larger than that of the main rope 510 and surrounds the outer circumferential surface of the main rope 510 to increase the surface area of the vegetation rope 500. According to the present invention in which the vegetation cover 520 is provided, the propagation of spores such as seaweed becomes easier, and a connector 510 is formed in the anchor bolt 400 so that when a plurality of tetrapods (T) are connected to each other, a plurality of tetrapods (T) When connecting the connector 510 provided in each of the vegetation rope 500 to each other, the main rope 510 supports each other and serves as vegetation at the same time, and the main rope ( The vegetation cover 520 surrounding the outer surface of the 510) makes vegetation such as seaweed more active, so that an excellent artificial reef function can be secured.

Further, although not shown in the drawing, between the plurality of first protruding jaws 200, between the plurality of second protruding jaws 300, or between the first protruding jaws 200 and the second protruding jaws 300 The vegetation rope 500 may be connected. The anchor bolt 400 may be formed on the first protruding jaw 200 or the second protruding jaw 300.

A reinforcing member 140 for reinforcing a cross section of the connection location may be provided at a connection location where two of the four legs 100 are connected to each other. Destruction of the tetrapod (T) may occur when the connection position at which the two legs 100 are connected to each other among the four legs 100 is crushed, and in the present invention, the tetrapod (T) itself Increase the durability of the product.

The reinforcing member 140 may be formed by the joint reinforcing groove 1140 of the above-described formwork 1000.

A zeolite or a zeolite-containing material may be provided in the leg 100, the first protrusion 200, the second protrusion 300, the mounting portion 120, the vegetation rope 500, and the like. The zeolite is known to be effective in the growth of animals and plants as a mineral that is an aluminum silicate hydrate of alkali and alkaline earth metals. The zeolite or zeolite-containing material may be attached to the surface of any one or more of the legs 100, the first protrusion 200, the second protrusion 300, the mounting portion 120, and the vegetation rope 500, , The multifunctional tetrapod (T) of the present invention to which the zeolite is attached further promotes the propagation of spores of marine plants through the adsorbing property of selectively adsorbing unsaturated hydrocarbons or polar substances of the zeolite. In addition, the growth of marine life is better.

The zeolite or zeolite-containing material is clinoptilolite, analcime, chabazite, mordenite, erionite, heulandite, and philipsite ( phillipsite) and ferrienrite may be each or a mixture thereof, and it is preferable to contain at least one of clinoptilolite and mordenite.

In one embodiment of the present invention, the zeolite or zeolite-containing material may be replaced with stone powder. The stone powder is a powder of feldspar and may be a powder of limestone.

13 and 14 are images showing a structural analysis of a tetrapod (T) manufactured by a formwork according to an embodiment of the present invention.

As shown in (b) of FIG. 14, the stress distribution of the tetrapod (T) manufactured according to the present invention is the first protruding jaw 200 reinforcing the joint of the leg 100 and the second protruding jaw 300. It can be seen that by distributing a certain load, the maximum tensile load at the joint of the leg 100 is reduced by 2 MPa or more than that of Fig. 14(a) which is a comparison target.

The tetrapod (T) having the above configuration scatters the wave energy acting in the longitudinal and circumferential directions of the leg 100 through a combination of the first protruding jaw 200 and the second protruding jaw 300, When tetrapods (T) are loaded and mounted, interlocking with each other is actively performed, thereby increasing structural stability. In addition, the joint part of the leg 100, which is a weak part of the tetrapod (T), is reinforced with the first protruding jaw 200, while the first protruding jaw 200 and the second protruding jaw 300 provide the Since the external load is distributed, the durability and safety of the tetrapod (T) are improved. In addition, a fall accident may be prevented through the first protruding jaw 200 and the second protruding jaw 300.

In the present invention, the tetrapod (T) can be easily manufactured through the above-described formwork 1000, and it is easy to produce in large quantities. In addition, it is easy to connect and fix the form body 1100 through the form body 1100 that is connected to each other by the first insertion groove 1110 and it is easy to change the shape of the first insertion groove 1110. In addition, the joint portion of the leg 100 of the tetrapod T may be further reinforced through the joint reinforcing groove 1140.

100: leg 120: mount
140: reinforcing member 200: first protruding jaw
210: engraved rail 220: embossed rail
230: inner jaw 240: lateral jaw
300: second protruding jaw 400: anchor bolt
410: connector 500: vegetation rope
510: main rope
520: vegetation cover
1000: formwork
1100: formwork body 1110: first insertion groove
1120: second insertion groove 1130: fixture
1140: joint reinforcement groove 1150: stepped
T: tetrapod

Claims (6)

The body portion, four legs radially connected to the body portion, a first protruding jaw provided with a plurality of longitudinally spaced apart from the outer surface of the leg, and each provided between the first protruding jaw and protruding along the circumferential direction of the leg In the formwork used to manufacture a tetrapod comprising a second protruding jaw,
A plurality of formwork bodies that can be arranged to surround the outer surface while dividing the body portion and the leg equally;
A first insertion groove provided at a connection position of the adjacent formwork body and sinking inward along the length direction of the leg to determine the shape of the first protruding jaw;
A fixture provided on the outer surface of the first insertion groove and connecting the adjacent formwork bodies to each other; And
Includes; a second insertion groove provided between the adjacent first insertion groove and settled inward to determine the shape of the second protruding jaw,
The first insertion groove is not formed at the end of the formwork body surrounding the outer surface of the end of the leg,
The first insertion groove is a formwork for manufacturing a tetrapod, characterized in that in communication with the second insertion groove.
delete The method of claim 1,
The plurality of second insertion grooves are each formed to be radially spaced apart from the center of the formwork body by a predetermined distance.
The method of claim 3,
Further comprising a joint reinforcing groove settled inward while dividing the formwork body into three from the center of the formwork body,
The joint reinforcing groove is a formwork for manufacturing a tetrapod, characterized in that located at the joint of the leg.
The method of claim 3,
Formwork for manufacturing a tetrapod, characterized in that it further comprises a stepped step provided inside the first insertion groove or the second insertion groove and protruding outward.
A tetrapod prepared using the die for producing a tetrapod according to claim 1.

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