KR101277467B1 - Constructing Method of Breakwater Structure using Tetrapod and Grout Bag - Google Patents

Abstract

The present invention is to provide a tetrapod (tetrapod) in the construction of a sofa structure to protect the breakwater or embankment from waves, etc., when the ends of the plurality of tetrapod legs are gathered in one point, a grout (bag) filled with a bag (bag) ) Is installed at the end of the tetrapod legs gathered at one point so that the mechanical bond between the plurality of tetrapod leg ends is achieved, thereby enhancing the interlocking effect between the plurality of tetrapods, so that the sofa structure is more firmly constructed, The present invention relates to a method of constructing a sofa structure by using a grout bag of a new method of constructing a sofa structure by stacking tetrapods in a plurality of layers so as to further improve the breaking effect, and by installing a multilayer of tetrapods.

Description

Constructing Method of Breakwater Structure using Tetrapod and Grout Bag

The present invention relates to a method for constructing a sofa structure for installing a tetrapod to protect a breakwater or embankment from waves, etc. Specifically, when a plurality of tetrapod leg ends are gathered at one point, grout An ash-filled bag ("grouse bag") is installed at one end of the tetrapod's leg where it is gathered at one point, so that a mechanical bond is formed between the ends of the plurality of tetrapod legs. To make the sofa structure more firmly, and to use the new grout bag to effectively build up the sofa structure by stacking the tetrapods in multiple layers so as to improve the breaking effect. It relates to a sofa structure construction method.

In order to protect breakwaters and embankments from waves and waves, the sofa structure is constructed by installing tetrapods. Korean Patent No. 10-0649137, which is introduced below as a prior patent document, introduces a conventional technique for constructing a breakwater using such a tetrapod.

In constructing a sofa structure by arranging a plurality of tetrapods having four leg portions, it may be necessary to build a sofa structure by stacking tetrapods in multiple layers. FIG. 1 discloses a drawing substitute photograph showing a state in which a sofa structure is formed by stacking tetrapods in two layers according to the prior art, and FIG. 2 shows a Korean Patent No. 10-0649137, which is introduced below as a prior patent document. As shown in the accompanying drawings of the specification has been disclosed a view showing a structure for stacking the tetrapod in three layers by the prior art. 1 and 2, conventionally, in stacking tetrapods in multiple layers, three legs are laid and the other leg is arranged by horizontally arranging a plurality of tetrapods adjacent to each other in a vertical direction. The first leg is formed, and the three legs of the tetrapod are laid down while the other leg is vertically inverted to face down with the tetrapod of the first layer. Between the sections, a second layer was formed in such a manner that the tetrapods of the second layer were arranged so that the vertically downward leg portions of the tetrapods of the second layer were located.

However, in this way, the tetrapod of the first layer is disposed so that one leg is vertically upward, and the tetrapod of the second layer is inverted so that one leg is vertically downward, and the tetrapod is laminated and installed in multiple layers so as to be sandwiched between the tetrapods of the first layer. In the method, the following problems arise.

First, tetrapods are easily broken. In the case of stacking tetrapods in multiple layers according to the prior art, the tetrapods of the second layer are located at the center of gravity of the second layer, whereas the tetrapod weight is vertically lowered with one leg, and the tetrapods of the first layer are adjacent to each other. It is a state supported by. Therefore, there is a problem in that the tetrapod is shaken by the waves, the possibility of breakage while leaving the position installed in the first place is very high.

Second, there is a limit that the breaking function is not large. In the case of stacking the tetrapods in multiple layers according to the prior art, the tetrapods of the second layer form the upper surface of the sofa structure with three leg portions forming one plane at one end thereof. In other words, the upper part of the tetrapod of the second layer is in a state where there is little protrusion on the surface as a whole. Therefore, when the waves invade, there is a limit that the wave easily rises on the upper surface of the second layer tetrapod with less protruding, and the breaking effect is insufficient. In particular, as shown in FIG. 2, when stacked in three layers, the tetrapods in the third layer are simply formed by the second layer of the teslapod without any mechanical bonding with the second one. There is a problem that only the third layer of the terrapod is lost during the wave invasion is placed on the top surface made.

Third, there is a limit of low risk and efficiency at work. When stacking tetrapods in multiple layers according to the prior art, the second layer tetrapods should be supported by the tetrapods of the first layer located adjacent to the center of gravity of the second layer tetrapods at the same time, and thus in this state. When installing the second layer tetrapod, there is a high risk of the tetrapod conducting, there is a problem that the efficiency of the installation work is lowered because of the difficulty in the work.

Fourth, there is a limitation that tetrapods cannot be laminated in three or more layers. That is, when the second layer tetrapod is stacked upside down as shown in FIG. 2, the upper surface of the sofa structure stacked and constructed is flat. Therefore, when the third layer of tetrapods are additionally stacked thereon, the third layer of tetrapods is not bound to the second layer of tetrapods at all and is simply placed on a flat surface, thereby preventing the breaking wave function. Therefore, in the case of stacking the second layer tetrapod upside down according to the prior art, there is a limit that the maximum stacking number of tetrapods can be laminated is limited to two layers.

Fifth, the biggest problem is that the binding force between the tetrapods is weak. The tetrapods of the first layer adhere to their position only by their own weight and their own weight acting from the tetrapods of the second layer, and the tetrapods of the second layer adhere only by their own weight. That is, since there is no binding between the tetrapods in each layer, there is a limit that the binding force and stability of the tetrapods are low.

See FIG. 4C of Korean Patent Registration No. 10-0649137 (November 27, 2006).

The present invention has been developed to solve the problems of the prior art as described above, specifically, in the construction by stacking tetrapods in multiple layers to build a sofa structure, the position of the center of gravity of the tetrapods installed in the second layer is high It prevents the positional displacement of the second layer tetrapod caused by the presence and the damage thereof, and further reduces the risk of the tetrapod falling when installing the second layer tetrapod, and makes the installation easy to perform. The purpose is to improve.

In addition, an object of the present invention is to improve the breaking performance by making the upper surface of the sofa structure in a rough state rather than a smooth state when installing the sofa structure by installing a tetrapod in a double layer.

In addition, an object of the present invention is to be able to freely build a sofa structure of the desired height by making a solid bond between the tetrapods of the upper and lower layers while stacking the tetrapod in a double layer as the desired number of layers.

In particular, it is an object of the present invention to improve the binding force between the tetrapods, thereby improving the stability of the sofa structure constructed by the tetrapods by making mechanical binding between the tetrapods of each layer.

In order to achieve the above object, in the present invention, tetrapods composed of members having four legs extending to have the same angle to each other are laminated in a plurality of layers, wherein three legs of the four legs are transverse. Installing the plurality of first layer tetrapods in the transverse direction so that each end thereof extends in a direction so that its ends touch the installation surface and the remaining one leg is vertically upward; And a plurality of second layer tetrapods are respectively lifted so that a second layer tetrapod is supported by three legs of the first layer tetrapod between the plurality of first layer tetrapods, and among the four legs of the second layer tetrapod. Inserting between the first layer tetrapods such that the three legs extend in the transverse direction and the other one is disposed vertically upward; There is provided a method of constructing a sofa structure using tetrapods, wherein the sofa structure is constructed by stacking tetrapods in a plurality of layers.

In the present invention, following the disposing step of the second layer tetrapod, the tetrapod of the additional layer is lifted so that three of the four legs of the additional layer tetrapod extend in the transverse direction and the other one leg. The part may be inserted and disposed between the plurality of second layer tetrapods in a state of being vertically upward, and the step of stacking additional layers of tetrapods on the second layer tetrapods may be repeatedly performed up to the height of the sofa structure.

Further, in the present invention described above, the tetrapods are formed with recesses recessed in the end faces of the respective leg portions, and when the tetrapods of the respective layers are installed, the grout is formed at the position where the leg ends of the plurality of tetrapods gather. The grout bag of the grout bag is cured with a portion of the outer surface of the grout bag filled with ashes respectively positioned to fill the recess formed at the end of the leg of the tetrapod, so that the end of the leg of the tetrapod is engaged with the cured grout bag in each layer of the tetrapod. It is also possible to have a structure in which the leg ends of the plurality of tetrapods are mechanically bound to each other by the grout bag.

According to the present invention, in stacking tetrapods in multiple layers, the stacked tetrapods are not inverted as in the prior art, but are disposed between the lower tetrapods with three leg portions positioned downward, so that the center of gravity of the upper tetrapods is inverted. Rather, it is located at the lower side, thereby preventing the occurrence of tetrapod conduction in the installation process of the upper layer tetrapod, and it is possible to install the upper layer tetrapod stably, safely and quickly, thereby improving the installation efficiency. Is exerted.

In addition, in the present invention, the upper surface of the sofa structure constructed by stacking tetrapods is made to be rougher than the prior art in which the upper layer tetrapods are placed upside down. The effect of further improving performance is exerted.

Particularly, in the present invention, the plurality of tetrapods arranged in each layer are mechanically bound to each other by the grout bag at the ends of the legs to be gathered in one place, so that the binding force between the tetrapods in each layer is greatly improved, and accordingly, the tetrapods The effect that the stability of the sofa structure to be constructed is also improved.

In addition, in the present invention, the tetrapods are repeatedly laminated in a plurality of layers without the inverted tetrapods, and thus the tetrapods of various layers can be stably stacked in accordance with the height of the desired sofa structure.

FIG. 1 is a drawing substitute photograph showing a state in which a sofa structure is formed by stacking tetrapods in two layers according to the prior art.
2 is a schematic view showing a structure in which tetrapods are laminated in three layers according to the prior art.
3A is a schematic perspective view of a tetrapod according to the present invention having a grout bag binding structure.
FIG. 3B is a schematic cross-sectional view of tetrapod along the line AA of FIG. 3A.
4A to 4C are schematic perspective views, schematic side views, and schematic plan views showing a state in which a plurality of first layer tetrapods are disposed on a slope of a levee in the tetrapod construction method according to the present invention.
FIG. 5 is a schematic enlarged view of a portion B of FIG. 4A.
6A to 6C are schematic perspective views, schematic side views, and schematic views showing a state in which a second layer tetrapod is installed according to the present invention on a first layer tetrapod installed in a tetrapod construction method according to the present invention, respectively. Top view.
FIG. 7 is a schematic enlarged perspective view of a circle D portion of FIG. 6A. FIG.
FIG. 8 is a view corresponding to FIG. 6B, in which one leg portion vertically disposed longer than the other leg portion is formed on the first layer tetrapod using the second layer tetrapod as a second layer tetrapod. FIG. A schematic side view.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Although the present invention has been described with reference to the embodiments shown in the drawings, it is to be understood that the technical idea of the present invention and its essential structure and operation are not limited thereby.

Prior to explaining the specific process of the sofa structure construction method according to the present invention, a tetrapod (1) having a grout bag binding structure newly proposed in the present invention and applied to the construction method of the present invention will be described. When describing the prior art for convenience, the same reference numeral (1) used to refer to the conventional tetrapod was used in the same way for the tetrapod of the present invention.

Fig. 3a shows a schematic perspective view of a tetrapod 1 having a grout bag binding structure for use in the construction method according to the invention, and in Fig. 3b a schematic cross sectional view of the tetrapod 1 along the line AA of Fig. 3a. Is shown. As shown in the figure, the tetrapod 1 according to the present invention is constituted by a member having four legs extending in the same shape as the conventional one to have the same angle to each other. However, unlike the prior art, each end of each leg is formed with a recess 11. That is, the recessed part 11 is formed in the form which recessed the end surface in the direction which a leg part extends from each leg end part concave. As will be described later, a portion of the bag filled with grout material such as underwater concrete is placed in the recess 11.

Next, a detailed process of the tetrapod construction method according to the present invention will be described with reference to FIGS. 4A to 4C, 5, 6A to 6C, and 7. 4A to 4C are views illustrating a state in which a plurality of first layer tetrapods are disposed on a slope of a levee in the tetrapod construction method according to the present invention, FIG. 4A is a schematic perspective view, and FIG. 4B is a schematic side view. FIG. 4C is a schematic plan view as seen from arrow C of FIG. 4B. 5 is a schematic enlarged perspective view of a circle B portion of FIG. 4A.

As shown in Figs. 4A to 4C, first, a plurality of tetrapods are disposed on the bank slope. In order to distinguish the tetrapod disposed as the first layer on the bank inclined plane, that is, the tetrapod disposed as the first layer, from the tetrapod disposed as another layer thereon, it is referred to herein as "first layer tetrapod 10" for convenience. As described later, tetrapods stacked on the first layer tetrapod 10 are referred to as "second layer tetrapod 20" for convenience. Of course, when the first layer tetrapod and the second layer tetrapod are collectively referred to as "tetrapod (1)".

As shown in Figs. 4A to 4C, the first layer tetrapod 10 has three leg portions extending in the transverse direction so that its ends touch the installation surface (the bank inclined surface in the drawing) and one leg portion is vertically upward. The plurality of first layer tetrapods 10 are densely installed so that there are no empty spaces in the lateral direction if possible. At this time, as shown in FIG. 5, the grout bag 12 filled with grout material such as general concrete or underwater concrete is located at the position where the leg ends of the plurality of first layer tetrapods 10 are gathered. Mechanically engaged with the end of the leg. That is, the grout material is filled in the grout bag 12, but the part of the outer surface of the grout bag 12 in the state where the grout material has not yet hardened is formed in the concave portion 11 of the leg end of the first layer tetrapod 10, respectively. Will be positioned to fill. Since the grout material is contained in the grout bag 12, the grout material can be prevented from being lost by the water.

As such, when the grout material is cured while a part of the grout bag 12 is filled in the recess 11 formed at the leg end of the tetrapod, the leg end of the first layer tetrapod 10 is the cured grout bag ( 12), so that the end portions of the legs of the plurality of first layer tetrapods 10 which are driven toward one position are mechanically bound to each other by the grout bag 12. As shown in FIG. That is, when an external force is applied to one first layer tetrapod 10, the external force is transmitted to the grout bag 12, which is hardened in engagement with the recess 11 at the end of the leg, and then continues to the grout bag. It is also transmitted to the other first layer tetrapod which is engaged in the same manner as in (12). Therefore, the external force is dispersed and the occurrence of the phenomenon in which the tetrapod leaves the originally installed position by the external force is suppressed. As shown in FIG. 4C, the position where the grout bag 12 is provided may be where the leg ends of the two first layer tetrapods 10 are gathered, and the leg ends of the three first layer tetrapods 10 are arranged. It may be a gathering place.

As described above, in the present invention, after the first layer tetrapod 10 is disposed, the grout bag 12 is installed at the end of the leg of the first layer tetrapod 10, and the grout is formed in the first layer tetrapod 10. When the position to install the bag 12 is underwater, the grout bag is filled in the grout bag 12 on land, and the diver then grouts the bag without curing the grout material. It is possible to work so that part of the grout bag 12 is filled in the recess 11 of the tetrapod at the place where the leg end of the first layer tetrapod 10 gathers. Of course, from the beginning, the diver may inject the grout material into the grout bag 12 to install the grout bag 12 as above. Thus, when grout is inject | poured into the grout bag 12 in water, it is also preferable to use superflow concrete as a grout material.

On the other hand, when the position where the grout bag 12 is to be installed is not in water but on land, general concrete may be used as the grout material. That is, underwater concrete may be used, but in general, general concrete may be used on land, so that ordinary concrete is injected into the grout bag 12, and the grout bag 12 is placed in the first layer tetrapod 10 before the grout material is still hardened. It is possible to work so that a portion of the grout bag 12 is located in the recess 11 of the tetrapod by placing it at the end of the leg. In contrast, the grout bag 12, which is not yet filled with grout material, is placed at the end of the leg end of the first layer tetrapod 10, and the grout material is injected into the grout bag 12, and the grout bag is injected by the grout material. It is also possible to allow a portion of the grout bag 12 to fit into the recess 11 of the tetrapod as the 12 expands. The expansion of the grout material by injecting and expanding the empty grout bag 12 in this manner can be applied when using superfluid concrete or the like as grout material not only on land but also in water.

In the present invention, the grout bag 12 as described above may be made of a rubber bag or a bag of fiber material having elasticity, but is not limited thereto, and is made of a material having an expandability, and if the grout material is contained therein, it is special to the material and shape. There is no limit.

4A-4C, with the first layer tetrapod 10 installed and the grout bag for the first layer tetrapod 10 installed thereafter, as shown in FIGS. 6A-6C, the second The layer tetrapod 20 will be installed. 6A to 6C are views corresponding to FIGS. 4A to 4C, respectively, and FIG. 6A shows a second layer tetrapod 20 installed thereon in a state where a plurality of first layer tetrapods 10 are installed. 6B is a schematic side view of the state in which the second layer tetrapod 20 is installed, and FIG. 6C is a schematic plan view viewed from the arrow E direction of FIG. 6B. FIG. 7 is a schematic enlarged perspective view of a circle D portion of FIG. 6A. FIG. For convenience, in order to distinguish the tetrapod 20 of the second layer from the tetrapod 10 of the first layer, gray shades are displayed on the tetrapod 20 of the second layer in FIGS. 6A to 6C.

As shown in Figure 6a to 6c, in installing the second layer tetrapod 20, in the present invention, rather than installing the tetrapod upside down, the three legs are located in the lower position and one leg is extended vertically upward The second layer tetrapod 20 is provided. That is, the 2nd layer tetrapod 20 is supported by the three leg parts of the 2nd layer tetrapod 20 itself similarly to the 1st layer tetrapod 10, and one leg part is perpendicular | vertical, so that it may be a crane etc. Lifted by the lifting device 100 of the, it is to be placed in the space between the first layer tetrapod 10 as shown in Figure 6b. At this time, as shown in Figure 6c, the second layer of the tetrapod 20 also the end of the leg portion of the second layer tetrapod 20 adjacent to each other in the lateral direction like the first layer tetrapod 10 is gathered to one point There will be a place.

As described above, the grout bag 12 filled with grout material such as general concrete or underwater concrete is formed at the position where the leg ends of the plurality of second layer tetrapods 20 are gathered in the same manner as the first layer tetrapod 10. ) Is provided in a state of being mechanically engaged with the leg end of the second layer tetrapod 10. That is, while the grout material is filled in the grout bag 12, but the grout material is not cured yet, a part of the grout bag 12 is formed in each of the recesses 11 formed in the end surface of the leg of the second layer tetrapod 20. When the grout material is hardened in this state, the end of the leg portion of the second layer tetrapod 20 is engaged with the hardened grout bag 12, and the plurality of second parts are driven toward one position. The leg ends of the layered tetrapods 20 are in a state in which the grout bags 12 are mechanically bound to each other. Therefore, when an external force is applied to the second layer tetrapod 20, the second layer is transmitted to the second layer tetrapod which is simultaneously engaged with the grout bag 12 via the grout bag 12, and the external layer is dissipated so that the external layer is subjected to the external force. The phenomenon that the tetrapod 20 is separated is suppressed. That is, the stability of the second layer tetrapod 20 is greatly improved.

In particular, in the present invention, since the second layer tetrapod 20 is not inverted as described above and is disposed between the first layer tetrapod 10 with the three leg portions positioned downward, the center of gravity of the second layer tetrapod 20. This is located below the inverted state, thereby preventing the occurrence of the tetrapod conduction in the installation process of the second layer tetrapod 20, and stably and safely and quickly the second layer tetrapod 20 ) Can be installed to improve the efficiency of installation work.

In addition, since one leg portion of the second layer tetrapod 20 is vertically disposed in a state in which the second layer tetrapod 20 is stacked on the first layer tetrapod 10, that is, the upper surface of the second layer tetrapod 20, namely, The upper surface of the stacked sofa structure is made rougher than the prior art in which the second layer tetrapod is placed upside down, thereby increasing the frictional resistance between the wave and the sofa structure when the wave is invaded, thereby further improving breaking performance. Effect is exerted.

In particular, in the case of the second layer tetrapod 20, one leg portion disposed vertically upward may be made longer than the remaining three leg portions. FIG. 8B is a view corresponding to FIG. 6B, in which one leg portion vertically disposed longer than the other leg portion is formed on the first layer tetrapod 10 using the second layer tetrapod 20. An embodiment of the invention is shown. As shown in the embodiment shown in Figure 8, when the vertically disposed leg portion is formed longer than the other leg portion of the tetrapod to be laminated on the first layer tetrapod 10 by using it as a second layer tetrapod, By increasing the roughness of the upper surface of the sofa structure is laminated to maximize the frictional resistance between the wave and the sofa structure can be significantly improved the breaking performance.

Furthermore, as described above, the plurality of tetrapods arranged in each layer are mechanically bound to each other by the grout bag 12 where the ends of the legs are gathered in one place, thereby greatly improving the binding force between the tetrapods in each layer, Thereby, the effect that the stability of the sofa structure constructed by tetrapod is also improved is exhibited.

On the other hand, as described above, after the second layer tetrapod 20 is laminated, the third layer tetrapod is additionally formed in the same manner as the second layer tetrapod, that is, the second layer tetrapod without the inverted tetrapod as necessary. Additional tetrapod layers can be formed in between, and by repeating this process, multiple layers of tetrapods can be stably stacked to suit the height of the desired sofa structure. That is, the additional layer tetrapod can be installed on the second layer tetrapod 20 in the same manner. According to the construction method of the present invention, since the three leg portions extending in the transverse direction of the second layer tetrapod 20 are interposed between the vertical leg portions of the first layer tetrapod 10, the first layer tetrapod It has a strong binding force against the external force in the horizontal direction between (10) and the second layer tetrapod 20, the third layer tetrapod can be provided in the same manner above the second layer tetrapod 20, a plurality of more Tetrapod can be laminated in a state having a strong binding force of the upper and lower layers, there is an advantage that can be constructed sofa structure of the desired height.

1: tetrapod
11: recess
12: grout bag

Claims (3)

The tetrapods composed of the members having four legs are laminated in a plurality of layers,
Of the four legs of the tetrapods, the three legs are extended in the transverse direction, respectively, so that the ends thereof reach the installation surface, and the other one leg is adjacent to the plurality of first layer tetrapods 10 in the horizontal direction so as to exist vertically upward. Installing; And
Each of the plurality of second layer tetrapods 20 is lifted, and the second layer tetrapod 20 is formed by three transverse legs of the first layer tetrapod 10 between the plurality of first layer tetrapods 10. The second layer between the first layer tetrapods 10 so that three of the four leg portions of the second layer tetrapod 20 extend in the transverse direction and the other one leg is disposed vertically upward. Inserting and placing the layered tetrapod 20; thereby forming a sofa structure by stacking tetrapods into a plurality of layers by a process including;
A concave portion 11 is formed in the tetrapod so as to be concavely recessed in each leg end surface;
In the step of installing the tetrapods of each layer, at the position where the leg ends of the plurality of tetrapods of each layer are gathered, a concave portion in which a portion of the outer surface of the grout bag 12 filled with grout material is formed on each of the leg end surfaces of the tetrapod 10 ( 11) allow the grout material of the grout bag 12 to cure in a position to fill;
In each layer of tetrapods, the leg ends of the tetrapods are engaged with the cured grout bag 12 so that the leg ends of the plurality of tetrapods in each layer have a structure that is mechanically bound to each other by the grout bags 12. Construction method of the sofa structure using tetrapods.
The method of claim 1,
Following the placement of the second layer tetrapod 20,
Lifting the tetrapod of the additional layer, three of the four legs of the additional layer of the tetrapod extends in the transverse direction, respectively, the remaining one leg is vertically upwards in the state of the plurality of second layer tetrapod 20 The method of constructing a sofa structure using tetrapods, characterized in that the step of inserting between, to repeat the step of stacking an additional layer of tetrapod over the second layer tetrapod 20 to the height of the sofa structure.
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