KR20190131193A - Functional tetrapod and functional tetrapod manufacturing metho - Google Patents

Abstract

The present invention relates to a functional tetrapod and a manufacturing method for a functional tetrapod. The functional tetrapod is made of concrete and installed as a marine structure such as a breakwater by being piled by random coursed masonry or static coursed masonry. The tetrapod includes a tetrapod arm on both sides of a tetrapod body. The tetrapod arm has an upper arm, a front arm, and a rear arm, and two of the three arms are installed on the bottom. The lower part of the other tetrapod body is piled in a space unit installed on both sides of the upper part of the tetrapod body to have a random coursed masonry form or a static coursed masonry form. The functional tetrapod is manufactured by a divided sheathing board manufacturing step, a clip connection step, a divided sheathing board connecting step, a concrete placing and curing step, and a divided sheathing board separating step.

Description

Functional tetrapod and functional tetrapod manufacturing method {FUNCTIONAL TETRAPOD AND FUNCTIONAL TETRAPOD MANUFACTURING METHO}

The present invention relates to a method for producing functional tetrapods and functional tetradrapods, and in particular, tetrapod arms having tripods are provided on both sides of a tetrapod body having a horizontal shape, and the tetrapods are stacked to have a static or egg-shaped shape. It is to increase productivity through an easy manufacturing process.

Generally, a concrete block used for a blue sofa, tetrapod having four conical legs is used, and four conical legs are stacked in a static or turbulent shape to form marine structures such as breakwaters. It will be constructed.

These tetrapods can reduce wave pressure, rising of the waves and reflected waves, and reduce the energy of the waves, and can be stably constructed even in areas with poor environmental conditions such as steep slopes, and have low center positions and excellent stability. Compared to the sofa block, the weight can be lighter and there is no need for special care in construction.

However, the tetrapod is lifted by the wave force as the outer peripheral surface of the bridge is formed into a curved surface, thereby causing a problem that the leg portion is broken, due to the considerable lift force generated in the lower portion of the center where each leg meets the tetrapod There was a problem of lowering the structural stability by moving in an indeterminate form.

On the other hand, a concave sofa block for wave attenuation of Korean Utility Model Publication No. 20-0388821 (2005.06.27) has been proposed as a solution to solve this problem. When each wave is formed along the circumference, the waves come into contact with the concave curved surface to spread and dissipate, but the basic structural strength is lowered due to the damage to the tetrapod's appearance, and thus the leg part is frequently damaged. There was a problem that occurred.

In addition, such a sofa block has a problem that the productivity is lowered due to the increase in the number of processes as the form of the circumferential form in a plurality of directions is required in the manufacturing process complex form of various forms.

Utility Model Registration No. 20-0388821 (2005.06.27)

This invention is intended to facilitate the manufacture using three formwork while bringing increased stacking force in the process of stacking tetrapods in the form of static or turbulent to increase the structural stability of the marine structure.

This invention is made of concrete, in a functional tetrapod (A) that is stacked in a static or turbulent and provided as a marine structure, such as a breakwater, the tetrapod (A) on each side of the tetrapod body (10) having a horizontal form The tetrapod arm 20 is provided, the tetrapod arm 20 is provided with an upper arm 210 having an upright shape toward the upper side, the upper arm 210 of the tetrapod body 10 is started Two arms 210 'of three arms 210, 210' and 210 "are formed at the end by forming front and rear arms 210 and 210 'which are inclined toward the bottom of the front and the rear. ) 210 "is mounted on the floor, and the lower portion of the other tetrapod body 10 is stacked in a space SP provided to the upper side of the tetrapod body 10 so as to have a static or egg-shaped shape. .

형태를 갖도록 형성되어지고,In addition, the tetrapod arm 20

Formed to have a shape,

The outer side of the tetrapod arm 20 is formed with a vertical surface portion 201 having a vertical shape, the inner side is characterized in that the inclined surface portion 202 having a form inclined toward the tetrapod body 10 is formed.

형태를 갖도록 형성되어지고, 각각의 돌출된 부분은 원뿔형태를 갖도록 형성되어지고, 상기 원뿔형태의 외측 단부에 양력감쇠형 소파부(220)가 형성되어지되, 상기 양력감쇠형 소파부(220)는 단부링형 소파턱(221)과 내부링형 소파턱(222)이 일정 간격 유지되게 직선형 소파턱(223)에 의하여 연결되게 형성되어지고, 상기 원뿔형태의 외주연부에 지지돌기(230)가 형성됨을 특징으로 한다.In addition, the tetrapod arm 20

Is formed to have a shape, each protruding portion is formed to have a conical shape, the lift attenuated sofa 220 is formed on the outer end of the conical form, the lift attenuated sofa 220 The end ring-type sofa jaw 221 and the inner ring-type sofa jaw 222 is formed to be connected by a straight sofa jaw 223 to be maintained at a constant interval, and the support protrusion 230 is formed on the outer periphery of the conical shape It features.

On the other hand, the present invention is a method of manufacturing a functional tetrapod in which tetrapods (A) made of concrete are statically or randomly stacked to be provided as a marine structure such as a breakwater, wherein the tetrapods (A) have three sectors having a curved shape. The arm formwork 520 has a space S (S ') (S ") in which the upper and lower portions of the vertical formwork 510 are to form the tetrapod arms 210, 210' and 210", respectively. 520 ') and 520 "are provided to obtain a split formwork 50, the split formwork manufacturing step (S100); and the vertical formwork 510 and the arm formwork 520 of the split formwork 50 Clip joining step (S200) is coupled to the clip 530 to the edge of the (520 ') (520 "); A split formwork joining step (S300) for engaging the split formwork 50 to which the clip 530 is coupled, and then locking the clip 530 so that the split formwork 510 is coupled; Concrete pouring and curing step of curing by placing concrete (C) in the interior of the combined split formwork (510) (S400); And a split formwork separating step S500 in which the split formwork 50 is separated by unlocking the clip 530 of the divided formwork 50 in which the concrete C is cured.

And reinforcement step (S410) in which the reinforcing bar is reinforced before the concrete (C) is poured into the interior of the split formwork 50 of the concrete placing and curing step (S400).

The present invention allows the tetrapod arms formed on both sides of the tetrapod body to span the bottom or other tetraport bodies, so that the tetrapods can be stacked in the form of static or eggs.

In addition, through this it is possible to obtain the effect of increasing the stacking force of the tetrapod to increase the structural stability.

In addition, since tetrapod is manufactured using three dies, the manufacturing process can be simplified.

And this can be achieved to increase the productivity.

1 is a perspective view of a tetrapod according to the present invention.
2 is a perspective view showing a state in which tetrapods are stacked according to the present invention;
Figure 3 is a flow chart showing the manufacturing process of the tetrapod according to the present invention.
Figures 4a to 4c is a perspective view showing a state in which the tetrapod is manufactured by assembling the formwork before the concrete is poured in the manufacturing process of the tetrapod according to the present invention and separating the formwork after the concrete is poured.
Figure 5 is a perspective view of the tetrapod of another embodiment according to the present invention.

An embodiment of the present invention will be described below with reference to the accompanying drawings.

Figure 1 is a perspective view of the tetrapod according to the invention, Figure 2 is a perspective view showing a state in which the tetrapod according to the invention is laminated, Figure 3 is a flow chart showing the manufacturing process of the tetrapod according to the invention, 4a to 4c are perspective views showing a state in which tetrapods are manufactured by assembling the formwork before concrete is poured in the manufacturing process of tetrapod according to the present invention and separating the formwork after concrete is poured. 5 is a perspective view showing a state in which tetrapods of another embodiment according to the present invention are stacked.

Tetrapod (A) according to the present invention can be laminated in the form of static or turbulent to bring about an increase in the lamination force to increase the structural stability, and to simplify the manufacturing process to increase productivity 1 and 2, the tetrapod body 10 and the tetrapod arm 20 are provided to be made of integral concrete.

The tetrapod body 10 is formed to have a cylindrical shape, and the tetrapod arms 20 are symmetrically formed at both end portions thereof. At this time, the tetra body 10 is to have a horizontal form, but as shown in Figure 4c, depending on the laying direction may have a vertical form. This is to facilitate the demoulding of the split formwork 50 while allowing concrete to be easily poured into the split formwork 50 during the manufacture of the teslaford (A).

형태를 갖도록 형성된 것으로 상부를 향하여 직립된 형태를 갖는 상방 아암(210)이 구비되어지고, 상기 상방 아암(210)이 시작되는 테트라포드 몸체(10)의 단부에 전방과 후방의 바닥을 향하여 경사진 형태를 갖는 전,후방 아암(210')(210")이 형성되어 있다. The tetrapod arms 20 allow each arm to be hung on another neighboring tetrapod arm 20 to reduce the amount of material used while increasing the stacking force.

It is formed to have a shape and is provided with an upper arm 210 having a shape standing up toward the top, the inclined toward the bottom of the front and rear at the end of the tetrapod body 10, the upper arm 210 starts Front and rear arms (210 ') (210 ") having a.

The tetrapod arm 20 is formed with a vertical surface portion 201 having a vertical shape, the inner side is formed with an inclined surface portion 202 having a form inclined toward the tetrapod body 10 so that the strength can be reinforced It is provided.

The tetrapod arm 20 has two arms 210 ', 210 "of three arms 210, 210', and 210" mounted on the floor, so that construction can be easily performed. In the process, the lower portion of the other tetrapod body 10 may be stacked in a space SP provided on both sides of the upper portion of the tetrapod body 10 to have a static or turbulent shape.

Figure 3 is a flow chart showing the manufacturing process of the tetrapod according to the present invention.

The manufacturing process of the tetrapod according to the present invention, first, as shown in Figure 3, having a curved form in the divided formwork manufacturing step (S100) and the image of the sector-type vertical formwork 510 having a separated form The arm formwork 520, 520 ′, 520 ″ is provided to have spaces S, S ′, and S ″ in which the tetrapod arms 210, 210 ′, 210 ″ are respectively formed at the bottom. It is provided so that one divided formwork 50 is obtained.

Next, in the clip joining step (S200), the vertical formwork 510 of the split formwork 50 and the clip 530 provided at the edges of the arm formwork 520, 520 ', 520 "are combined. As shown in FIG. 4B, the clip 530 is joined to the three split molds 50 to each other, and then the clips 530 are locked to each other so that the split molds 510 are coupled to each other. (Splitting formwork combining step (S300)).

Next, the concrete (C) is poured into the interior of the combined split formwork 510 in a concrete pouring and curing step (S400) to cure for a predetermined period of time after the split formwork 50 cured by the concrete (C) A functional tetrapod (A), as shown in FIG. 4, is manufactured through a split formwork separating step (S500) in which the clips 530 are unlocked to separate the split formwork 50. At this time, it is preferable to further include a reinforcement step (S410) in which the reinforcing bar is reinforced before the concrete (C) is poured into the split formwork 50 during the concrete placing and curing step (S400). This is to further prevent breakage or deformation by increasing the tensile strength of the concrete (C).

5 is a perspective view showing a tetrapod of another embodiment according to the present invention.

형태를 갖도록 형성되어지되, 각각의 돌출된 부분은 원뿔형태를 갖도록 형성되어지고, 상기 원뿔형태의 외측 단부에 양력감쇠형 소파부(220)가 형성되어지도록 할 수 있다. 이때, 상기 양력감쇠형 소파부(220)는 단부링형 소파턱(221)과 내부링형 소파턱(222)이 직선형 소파턱(223)에 의하여 일정 간격 유지될 수 있게 연결된 형태를 갖도록 형성되어지고, 상기 원뿔형태의 외주연부에 지지돌기(230)가 형성되어지도록 할 수 있다.In the present invention, the vertical surface portion 201 is formed on the outer surface of the functional tetrapod A, and the tetrapod arm 20 on which the inclined surface portion 202 is formed facing the tetrapod body 10 has a cylindrical shape. It is to be provided at both ends of the tetrapod body 10 formed to have, but in addition to this form, as shown in Figure 5, the tetrapod arm 20

Is formed to have a shape, each protruding portion is formed to have a conical shape, the lift attenuated sofa 220 may be formed on the outer end of the conical shape. At this time, the lift attenuated sofa 220 is formed to have a form in which the end ring-type sofa jaw 221 and the inner ring-type sofa jaw 222 is connected to be maintained at a predetermined interval by the straight sofa jaw 223, The support protrusion 230 may be formed on the outer periphery of the cone shape.

In this case, while the amount of use of the material is increased, if the working line (S) is wound on the support protrusion 230 while preventing the breakage by protruding in a conical form to prevent the damage by extending the life, It is possible to prevent the position of the string S from changing. That is, it is possible to further prevent the engagement line S from peeling off or stretching.

 In addition, as the center of gravity is located in the netford body (10) can be made easier construction.

10: tetrapod body 20: tetrapod arm
50: split die 210: upper arm
210 ': front arm. 210 ": rear arm
510: sector vertical formwork 520, 520 ', 520 ": arm formwork
530: Clip A: Tetrapod
S100: Split formwork manufacturing step S200: Clip joining step
S300: Joining the split formwork S400: Concrete placing and curing step
S500: Split formwork separation step

Claims (5)

In the functional tetrapod (A) made of concrete, which is laminated statically or ovate and is provided as a marine structure such as a breakwater,
The tetrapod (A) is provided with a tetrapod arm 20 on each side of the tetrapod body 10 having a horizontal shape, the tetrapod arm 20 is an upper arm 210 having an upright shape toward the top And the front and rear arms 210 and 210 'are formed at the end of the tetrapod body 10 at which the upper arm 210 starts to be inclined toward the bottom of the front and rear sides. Two arms 210 'and 210 "of the arms 210, 210' and 210" are seated at the bottom, and another tetrapod is provided in the space portion SP provided to the upper side of the tetrapod body 10. Functional tetrapod, characterized in that the lower portion of the body 10 is laminated so as to have a static or egg-shaped form.
The method of claim 1,
The tetrapod arm 20

It is formed to have a shape, the outer side of the tetrapod arm 20 is formed with a vertical surface portion 201 having a vertical form, the inner side is inclined surface portion 202 having a form inclined toward the tetrapod body 10 is Functional tetrapod, characterized in that it is formed.
The method of claim 1,
The tetrapod arm 20

Is formed to have a shape, each protruding portion is formed to have a conical shape, the lift attenuated sofa 220 is formed on the outer end of the conical form, the lift attenuated sofa 220 The end ring-type sofa jaw 221 and the inner ring-type sofa jaw 222 is formed to be connected by a straight sofa jaw 223 to be maintained at a constant interval, and the support protrusion 230 is formed on the outer periphery of the conical shape Functional tetrapod characterized by the above-mentioned.
In the tetrapod (A) made of concrete is static or egg-laminated in the functional tetrapod manufacturing method that is provided as a marine structure such as a breakwater,
The tetrapod A is a space S in which the tetrapod arms 210, 210 ', 210 "are formed at the upper and lower portions of the three sectoral vertical formwork 510 having a curved shape. Arm formwork 520, 520 'and 520 "are provided to have a split formwork 50 so as to have a split formwork 50;
A clip joining step (S200) in which a clip 530 is coupled to an edge of the vertical formwork 510 and the arm formwork 520, 520 ′, 520 ″ of the split formwork 50;
A split formwork joining step (S300) for engaging the split formwork 50 to which the clip 530 is coupled, and then locking the clip 530 so that the split formwork 510 is coupled;
Concrete pouring and curing step of curing by placing concrete (C) in the interior of the combined split formwork (510) (S400); And
Functional tetrapod manufacturing characterized in that the concrete (C) is made of a split formwork separating step (S500) to be separated by the unlocking the clip 530 of the split formwork (50) cured split formwork (50) Way.
The method of claim 4, wherein
Functional reinforcement step (S410) is characterized in that the reinforcement step (S410) is further reinforced before the concrete (C) is poured into the interior of the split formwork 50 of the concrete placing and curing step (S400). .

Images