KR101943202B1 - Construction method for Reinforcing conventional caisson with interlocking - Google Patents

Abstract

The present invention relates to a conventional caisson interlocking reinforcement construction method, and more particularly, to a construction method of a caisson interlocking reinforcement construction method by newly introducing the concept of an open cell and an intercell to a caisson, The present invention relates to an existing caisson interlocking reinforcement construction method capable of interlocking with a flexible stone so that each caisson can have individual flexibility in response to a differential settlement of the ground. The present invention relates to a closed type cell (12) which is open upward and whose side is provided by a wall (11); A filler (30) filling the closed type cell (12); And a block (40) installed on an upper portion of the caisson structure (1), the caisson structure (1) being installed on the sea floor while abutting side surfaces of the caisson (90). In order to construct the pre-closed type cell 12 as an open cell 13 having a side open form, the filling material 30 in the region to be made into the open cell 13 is removed, (10) by interlocking said closed caisson (90) by removing said open caisson (11); And filling the intercell filler (23) with the intercell (22) formed by the two open cells (13) facing each other, wherein the intercell filler (23) filled in the intercell cell (22) And interlocking the two adjacent open casings 10 to each other.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a caisson interlocking reinforcement construction method,

The present invention relates to a conventional caisson interlocking reinforcement construction method, and more particularly, to a construction method of a caisson interlocking reinforcement construction method by newly introducing the concept of an open cell and an intercell to a caisson, The present invention relates to an existing caisson interlocking reinforcement construction method capable of interlocking with a flexible stone so as to prevent breakage of the caisson due to stress concentration and to have flexibility that each caisson can individually cope with the uneven settlement of the ground.

Generally, a caisson is a structure that is essential for port construction. For example, it is applied to important facilities of port such as gravity type wall, breakwater.

In recent years, the sea level has been rising due to global warming. As a result, it is expected that invasion of abnormal waves with a wave height higher than design wave is expected. In the case of breakwaters, the size of the breakwaters is increasing due to the increase in the design wave height. However, in reality, it is the reality that the waves of design waves of 50 years or more are not invaded when they are invaded. In case of gravity type walls, .

Therefore, there is an urgent need for measures to actively cope with changes in port logistics conditions, such as increase in design wave and enlargement of vessels due to climate change.

In the case of a breakwater, the caisson must withstand the horizontal force of the wave with its own weight. However, blue is not always constant, and the horizontal force of blue is often concentrated on one of the caissons.

In order to reduce the required load of the caisson by interlocking the adjacent caissons and leveling the horizontal force of the waves acting on the caisson, a method is suggested. This is the case, for example, by putting an existing concrete block between two neighboring caissons.

However, it is very troublesome to carry concrete blocks to be inserted between the two caissons and to put them in a large quantity. In addition, since the concrete block acts as a rigid body, even if one caisson in which the horizontal force of the actual wave is concentrated is pushed backward and supported by the interlocked two-side caissons, The caisson can not support interlocking and is very likely to be destroyed. Moreover, since the concrete block is rigid, it is necessary to align the two adjacent caissons accurately in order to provide a space for fitting the concrete block.

In addition, a caisson construction method is disclosed in which an interlocking section in which reinforcing bars are woven between neighboring two caissons is formed, the space is isolated from seawater, and concrete is laid so that two neighboring caissons are integrally joined at a point where they meet. There is a bar. However, this construction method is not only difficult to construct itself, but also because the caissons are completely integrated by the concrete placed in the space where the two caissons meet after the construction, when the subsidence settlement of the ground occurs, It is very likely that the stress generated due to the failure of the caisson of the ultra-heavy load to concentrate on a specific site and cause the caisson to be destroyed.

Therefore, it is possible to support the adjoining caisson at the interlocking portion between the caissons, thereby making it possible to enlarge the structure, while maintaining the flexible state at the interlocking portion, Is required.

According to this demand, after removing the existing installed caisson, it is possible to interlock between the adjacent caissons without reinforcing the existing caisson without reinstalling the new caisson. If the interlocking part is capable of maintaining the flexible state, And the construction cost can be saved remarkably.

SUMMARY OF THE INVENTION The present invention has been conceived to solve the above-mentioned problems, and it is an object of the present invention to provide a closed cell type portable telephone which changes the closed type cell formed at the facing portion of two adjacent caisses to open cells, Interlocking caisson breakwaters are filled with fillets filled with stalactite filler in the intercells formed by the cells facing each other to prevent breakage of the interlocking area despite the uneven settlement of the wave or the ground, And to provide a reinforcement construction method.

In order to solve the above-mentioned problems, the present invention provides a closed type cell (12) having an open upper side and a side wall (11); A filler (30) filling the closed type cell (12); And a block (40) installed on an upper portion of the caisson structure (1), the caisson structure (1) being installed on the seabed while the side surfaces of the closed caisson (90) are aligned with each other. The filling material 30 in the area to be made into the open cell 13 is removed so that the closed cell 12 is formed as an open cell 13 having a side opened form, (10) by interlocking said closed caisson (90) by removing said open caisson (11); And filling the intercell filler (23) with an intercell (22) formed by two open cells (13) with openings facing each other, wherein the intercell filler (23) filled in the intercell (22) And interlocking the two adjacent open casings 10 to each other.

When the intercell filling material 23 is flexibly filled in the intercell 22 on the side surface of the intercell 22 before the intercell filling material 23 is filled in the intercell 22, And forming a shear key (18) for generating a frictional force on the interlocking reinforcement.

In addition, before the intercell filling material 23 is filled in the intercell 22, a reinforcing portion 22 for supporting a load applied between the crossing side surfaces of the intercell 22 is formed at a corner where the side surfaces of the intercell 22 intersect. And forming a hammock (15) as the first caisson interlocking reinforcement construction method.

The intercell 22 is filled with an intercell filler material 23 of a standard size of 0.015 m ³ / EA to 0.03 m ³ / EA, so that the intercell filler material 23 in the intercell 22 is flexible The present invention provides an interlocking reinforcement construction method for an existing caisson.

Before the intercell 22 is filled with the intercell filler 23, the overhang 24 (see FIG. 2) is formed at the boundary between the two open cells 13 constituting the intercell 22 among the side surfaces of the intercell 22 The present invention provides an existing caisson interlocking reinforcing construction method.

Here, the overlock member 24 is a flexible rubber or rigid body type panel, and provides an interlocking reinforcing method for a conventional caisson.

In order to reinforce the side surface of the intercell 22 before the intercell 22 is filled with the intercell filler 23, the structural reinforcing member 25 is provided on the side surface of the intercell 22 And then injecting the reinforcing mortar 26 into the caisson interlocking reinforcing construction method.

When the intercell filler material 23 is filled in the intercell 22, the intercell filler material 23 is filled in the flexible network to fill the intercell 22. Thereby providing a reinforcement construction method.

The method further includes the step of filling the intercell filling material 23 filling the intercell filling material 23 into the intercell 22 when the intercell filling material 23 is filled in the intercell 22 It provides an existing caisson interlocking reinforcement construction method.

The method of claim 1, further comprising the step of filling the intercell (22) with an intercell filler (23) and then installing a block (40) on the caisson structure (1) ≪ / RTI >

According to the existing caisson interlocking reinforcing construction method according to the present invention, it is possible to utilize a caisson already installed, which can greatly reduce material costs, and is simple in construction and easy to maintain.

According to the present invention, the maximum load acting on the port structure is dispersed due to the interlocking effect between adjacent caissons, thereby enhancing the stability of the structure, and the interlocking portion is filled with the filler material of the flexible stony- Structural safety is higher than conventional interlocking caissons.

Further, according to the present invention, since the interlocking portion is filled with the flexible filler material, even when the ground is unevenly settled, the caisson which is placed on the grounded floor can flexibly and independently move relative to the neighboring caisson, So that the caisson can be protected.

According to the present invention, it is possible to increase the resistance to horizontal force by smoothing the maximum horizontal force of the wave caused by interlocking.

Further, according to the present invention, it is possible to enhance the stability of the seawall breakwater, greatly reduce the maintenance-related budget, and design and utilize a new concept of harbor structure capable of coping with climate change.

Further, according to the present invention, since interlocking is made flexible, there is a strong point that the caisson structure can be disassembled without any difference from the caisson structure which is not interlocked when the caisson is disassembled.

The above and other objects, features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 shows an existing caisson structure with a closed caisson
2 is a view showing an embodiment of a caisson in which an open cell is formed by removing a side wall of a closed caisson,
3A is a view showing a state in which a block is removed from an existing caisson structure to be installed,
FIG. 3B is a view showing a state in which a filler in a closed type cell to be changed into an open cell is removed in FIG.
FIG. 3C is a view illustrating a state in which a closed-type cell is formed as an open cell by removing a part of a side wall of the closed caisson in FIG.
FIG. 3D is a view illustrating a state in which an intercell filler is filled in an intercell formed by two open cells in FIG. 3C,
Figure 4 is a top view of the caisson of Figure 2,
FIG. 5 is a view showing a state where an overlock member is provided at a boundary portion between two open cells forming an intercell,
6 is a view showing a state in which a shear key is formed on the side of the open cell,
7 is a view showing a state in which a horn is formed between crossing side surfaces of an open cell,
8A is a view showing a state in which a form-use structural stiffener is installed on a side surface of an open cell,
8B is a view showing a state in which a reinforcing mortar or the like is filled in FIG. 8A,
8C is a view showing a state in which the intercell filler is filled in FIG. 8B, and FIG.
FIG. 9 is a view showing a caisson structure constructed so as to be interlockable between caissons.

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

It is to be understood that the present invention is not limited to the disclosed embodiments, but may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to inform.

 [Structure of Caeson]

1, the closed caisson 90 forms a closed-type cell 12 having a width of 4 * 4. To this end, the closed caisson 90 has a side wall And five side walls formed in the left and right direction. In addition, reinforcing portions 19 are formed at the lower and rear sides of the front and rear surfaces, respectively, so that the bottom surface can be made wide to withstand the forces acting on the front and rear surfaces. According to the closed caisson 90 having such a structure and the method of construction thereof, each closed caisson 90 is provided with two adjacent closed caissons (not shown), as long as the closed side caissons 90 are aligned side- 90) can not be interlocked.

On the other hand, as for the structure of the open caisson 10 according to the present invention shown in FIG. 2, a rectangular parallelepiped shape is formed, and cells are formed in the hollow portion. The volume of each cell is defined by the walls 11.

The open caisson 10 is formed by removing the left and right side walls 11 of the closed caisson 90 to form open cells 13 having openings on the left and right side portions of the open caisson 10.

When the open casings 10 are aligned and fixed to the left and right sides, the intercell 22 is formed by two opposed open cells 13 of two adjacent open caissons 10. That is, since the two open cells 13 face the openings to form one closed partitioned space, the two open cells 13 facing each other function as one closed cell. The intercell 22 means that the two adjacent open caissons 10 function only as a cell until they are aligned. Since the volume of the intercell 22 is also defined by the wall 11, the interior of the intercell 22 can be filled with stones.

The intercell filler 23 is also filled in the intercell 22. The larger the specific gravity of the intercell filler 23 than the sea water, the better. As the filler, it is possible to use natural stones, slag generated in steel smelting and the like, and stones including bottom ash generated in a thermal power plant.

The intercell filler 23 filled in the intercell 22 not only increases the weight of the open caisson 10 but also increases the frictional force between the open caissons 10 within the intercell 22, Thereby enabling interlocking between the open caissons 10.

[Interlocking construction method of existing structure]

Referring to FIG. 3, a construction method for interlocking between caissons of existing structures will be described. The closed caissons 90, which constitute the caisson structure 1 already installed on the sea floor, are aligned side by side but neighboring closed caissons 90 are not connected to each other and act independently of each other in a separate structure. Therefore, each of the closed caissons 90 must withstand the horizontal force of the wave, but since the wave is not always constant, the horizontal force of the wave can be concentrated on the specific closed caisson 90. It is desirable to equalize the horizontal force of the wave focused on the particular closed caisson 90 corresponding to the horizontal force of the wave concentrated on the particular closed caisson 90 by interlocking the neighboring closed caisson 90, So that it is possible to support the adjacent closed caisson 90 in the longitudinal direction of the structure. At this time, in interlocking the neighboring closed caisson 90, it is preferable to maintain the flexible state in the interlocking portion so that the interlocking portion is not damaged by the stress concentrated on the interlocking portion specific portion.

However, it is not easy to interlock the adjacent closed caisson 90 while maintaining the closed caisson 90 for the first time, and also to be able to maintain the flexible state in the interlocking portion.

Therefore, as shown above, the open caisson 10 using the concept of the open cell 13 and the intercell 22 can form a structure that maintains the flexible state in the interlocking portion. However, the closed caisson 90 The effort and expense of replacing and reinstalling with an interlockable open caisson 10 can not be ignored. Therefore, it is desirable to find a construction method that can interlock the neighboring closed caissons 90 while maintaining the existing state of the installed closed caisson 90 as much as possible.

As described above, the largest difference between the closed caisson 90 and the open caisson 10 according to the present invention is the presence or absence of the open cells 13 present in the left and right side portions. When the left and right side walls 11 are removed, the closed caissons 90 installed on the left and right sides of the closed caisson 90 are opened to open cells 13, .

The closed cell 12 of the closed caisson 90 is filled with a filler 30 and the upper portion of the closed caisson 90 is covered with a block 40. The left and right side walls 11 of the closed caisson 90 are removed to make the closed cell 12 located at the right and left side portions of the closed caisson 90 into the open cell 13, The upper face block 40 covering the upper portion of the closed caisson 90 is removed. The entire block can be removed, but a part corresponding to the open cell changing construction work for interlocking may be removed. Then, as shown in FIG. 3B, the filler 30 filled in the closed cell 12 made of the open cell 13 is removed.

A portion of the left and right side walls 11 of the closed caisson 90 is removed to make the closed cell 12 open cell 13 as shown in Figure 3c, A diamond wire saw method may be used.

Diamond wire sawing technique is a disassembling technique that uses a series of pulleys to wind a diamond-embossed wire around a cutting object, turn it at a high speed with a driving device, and pull it back to cut the structure. It is suitable for removing the wall of the closed caisson 90 installed on the seabed since it is possible to construct in a bad condition such as an underwater work and shorten the working time by cutting the structure at a high speed.

At this time, the range of the closed cell 12 to the open cell 13 may vary depending on the range of the left and right side walls 11 of the closed caisson 90 to be removed as shown in FIG. As shown in FIG. 4A, all of the closed type cells 12 located on the right and left side portions are changed to the open cells 13 so that the closed type cells 12 are not provided on the front and rear sides of the open cells 13, Only a part of the closed type cells 12 located at the center portions of the left and right side portions can be changed to the open cells 13 so that the closed type cells 12 are located on the front and rear sides of the cells 13. [

When the left and right side walls 11 of the closed caissons 90 are removed, an open cell 13 having an opened side is formed. By the two open cells 13 facing each other, The intercell 22 is formed.

The intercell filler 23 is filled in the intercell 22 as shown in FIG. 3D to interlock the two adjacent open caissons 10.

However, this interlocking work is no different. The intercell filler 23 located inside the intercell 22 applies a distributed load to the caisson structure 1 due to its own weight. The distribution load acting on the caisson structure 1 by the intercell filler 23 can be divided into a vertical force acting on the bottom surface of the intercell 22 and a vertical force acting on the left and right sides of the intercell 22. At this time, the vertical drag acting on the bottom surface of the intercell 22 increases the frictional force between the open caisson 10 and the underside surface by adding weight to the open caisson 10, and the vertical drag force acting on the left and right sides of the intercell 22 Increases the frictional force between neighboring open caissons 10 to enable interlocking of the neighboring open caisson 10. Accordingly, the intercell 22 formed by the two neighboring open casings 10 is completed by filling the interstitial filler 23 in the form of a stagger.

However, as described above, the stones filled in the intercell 22 must resist the displacement of the two adjacent open caissons 10 in the forward and backward directions in different directions. Therefore, unlike the stones filled in the normal closed cell 12, It is preferable that they are intimately interfered with each other. For this purpose, the compaction process can be performed on the interstitial filler material 23 in the form of a stalactite filled in the intercell 22.

Meanwhile, in order to prevent the neighboring two closed caissons 90 from being contacted and damaged in the process of fixing the existing caisson structure, there is a certain gap between the neighboring two closed caissons 90. Therefore, a predetermined gap may exist at the boundary between the two open cells 13 constituting the intercell 22 on the side surface of the intercell 22. [ It is not possible to exclude the possibility that the intercell filler 23 filled in the intercell 22 through the gap flows out to the outside.

In consideration of this point, in the present invention, the diameter of the stones to be filled in the intercell 22 may be larger than the gap between the two open cells 13 constituting the intercell 22. At this time, even if all of the interstitial filler material 23 filled in the intercell 22 is not larger than the gap between the boundary portions of the two open cells 13 constituting the intercell 22, So that the leakage of stones can be prevented to a great extent. This is because even if the stones are intimately interfered with each other by compaction of the filled stencil-shaped intercell filler 23, and thus the diameter of all the stones is not larger than the gap between the two open cells 13 constituting the intercell 22 The leakage of stones can be prevented to a great extent.

However, considering the possibility of breakage of stones during the filling or compaction, the diameter of all the stones that are filled in the intercell 22 is larger than the diameter of the two open cells 13 constituting the intercell 22, It is preferable to configure it to be larger than the gap of the portion.

When the load is applied to the interlocking portion due to the application of a larger external force to the specific open caisson 10, the interlocking structure does not concentrate the load by the stones and acts as a definite distribution load. The possibility of breakage of the open caisson 10 can be greatly reduced.

As a result of the test, it is confirmed that filling the specimen with the standard of 0.015 m ³ / EA ~ 0.03 m ³ / EA as the intercell filler (23) acts as an obvious distribution load without being broken there was. In addition, the specification of 0.015 m ³ / EA to 0.03 m ³ / EA is unacceptably large, which is larger than 10 cm, which is the tolerance for the spacing between caissons.

If the intercell filler (23) has a standard of 0.03 m ³ / EA or more, the filler material cracks due to the concentrated load between the filler materials, which may lead to the outflow of the filler material. If the filler material (30) has a size of less than 0.015 m ³ / EA, it is not entangled with each other and causes external leakage when a load is given.

On the other hand, as shown in FIG. 5, an overlock member 24 may be utilized to prevent the stones filled in the intercell 22 from flowing out to the outside. That is, it is possible to fill the intercell 22 with the intercell filler 23 in the shape of a stagger after the interposing member 24 is interposed inside the boundary between the two open cells 13 constituting the intercell 22.

The overlock member 24 may be a flexible rubber or rigid body type panel. When the rubber is applied to the inner surfaces of the adjacent two front and rear surface members 14, a method of fixing the rubber to the front and rear surface members 14 by using an anchor or the like can be utilized.

The rigid panel may also be a concrete base panel. Such a panel can be simply padded without being fixed to the inner surface of the front and rear members. Since the present invention does not cure the concrete in the intercell 22, there is no need to isolate the outer space from the intercell 22 space, and there is no fear that the ready-made block, which is the overlock member, Because.

It is also possible to prevent the filler from flowing out to the outside of the intercell 22 by inserting the stones into a flexible network such as a gabion or geotextile.

6, one or more shear keys 18 protruding outwardly may be further formed on the left and right sides of the intercell 22 of the open caisson 10.

The shear keys 18 need not protrude outward by the same length as the length of the front and rear sides of the intercell 22 but protrude from the wall at a rate smaller than the length of the front and rear sides of the intercell 22. Also, the shear keys 18 are protruded from the wall 11 in a trapezoidal shape. If there is no shear key 18 on the side of the wall 11 when the adjacent two open caissons 10 are moved relative to each other in the forward and backward direction by a load externally applied by wave or the like, 23 of the intercell 22 transmit the entire load to the front and rear sides of the intercell 22, so that a high load is applied to the front and rear sides of the intercell 22.

However, in the case where the shear key 18 is formed, the shear-type intercell filler 23 can have a frictional force with respect to the left and right sides of the intercell 22 due to the shear key 18, The load applied to the front and rear sides of the intercell 22 can be significantly dispersed because the left and right side surfaces and the front and rear keys 18 and the front and rear surfaces of the intercell 22 are uniformly dispersed. If the protruding length of the shear-key 18 is the same as the length of the front and rear sides of the intercell 22, it is impossible to exclude the possibility that the load is concentrated on the shear- It is preferable to protrude from the wall at a small ratio.

A plurality of continuous cells 12 located along the left and right sides of the closed caisson 90 are removed and a plurality of open cells 13 positioned along the left and right sides of the closed caisson 90 A part of the wall 11 separating the closed closed type cells 12 may be left and used as the shear key 18.

On the other hand, when the horizontal force acts on the front and rear sides of the open caisson 10, the stress is concentrated on the corner portions between the front and rear sides of the intercell 22 and the left and right sides. In order to prevent the open caisson 10 from being damaged by the stress concentrated on the corner portions between the front and rear side surfaces and the left and right side surfaces of the intercell 22, A knife 15 for reinforcing the corner portion is formed. Since the front and rear side surfaces of the intercell 22 are mechanically similar to the cantilever, a method of reinforcing the tentacle 15 at the corner portion between the front and rear sides of the intercell 22 and the right and left side surfaces, As shown in Fig.

The formation of the hunting 15 here has particular significance when compared with the prior art. In the case where two open caissons 10 facing each other as in the conventional techniques (Japanese Patent Publication No. 2847694 and Japanese Patent Application Laid-open No. 2006-28981) are integrally made into a reinforced concrete block, There is no reason to use the intercell filling material 23 in the intercell filling material 23. When the intercell filling material 23 is filled in the intercell filling material 23 in a flexible state, When the two open casings 10 are moved relative to each other in the forward and backward directions by receiving forces of different sizes in the forward and backward directions, the interstitial filler material 23 in a staggered shape is distributed on the front and rear sides of the intercell 22 The load 15 is applied to the inner surface of the intercell 22 having the cantilever shape to prevent damage to the front and rear surfaces of the cantilever 22,

When there is no closed type cell 12 on the front and rear sides of the intercell 22 when the closed type cells 12 on the left and right side portions of the closed caisson 90 are changed to the open cells 13, It is more susceptible to breakage of the corner portions between the front and rear side surfaces and the left and right side surfaces of the intercell 22. [ 7A, when the closed type cells 12 are not provided on the front and rear sides of the intercell 22, the front and rear sides of the intercell 22 are composed only of the wall body 11, When the closed-type cell 12 is located on the front and rear sides of the cell 22, it can be considered that the front and rear sides of the intercell are composed of the closed-type cell 12. Therefore, in the case of constructing the structure as shown in FIG. 7A, it is preferable that the hatch 15 is formed to be larger at the corner between the front and rear sides of the intercell 22 and the left and right sides than the structure shown in FIG. 7B.

On the other hand, it is preferable to reinforce the side surface for the structural stability of the wall of the intercell 22 before filling the intercell filler 23 into the intercell 22. For example, the reinforcement material may be disposed on the side surface of the intercell 22, and the concrete, the reinforcement mortar 26, and the like may be filled.

After the filling of the intercell filler is completed, the upper block 40 may be installed on the upper face of the open caisson 10 at the position of the upper block.

According to this reinforcing method, the shear key 18 and the hunting 15 are formed integrally with the wall 11 in the horizontal direction, and the shear key 18, the hunting 15 and the wall 11 in the vertical direction, It can be formed integrally with the block 40 to sufficiently guarantee its strength.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the scope of the invention is not limited to the disclosed exemplary embodiments. It is obvious that a transformation can be made. Although the embodiments of the present invention have been described in detail above, the effects of the present invention are not explicitly described and described, but it is needless to say that the effects that can be predicted by the configurations should also be recognized.

1: Caisson structure
10: open casings
11: Wall
12: closed type cell
13: open cell
15: The hunting
16: side member
18: Shakhni
19:
22: Intercell
23: Intercell filler
24:
25: Formwork structural stiffener
26: Mortar for reinforcement
30: Filler
40:
90: closed caisson

Claims (10)

A closed-type cell 12 which is open upward and whose side is provided by a wall 11; A filler (30) filling the closed type cell (12); And a ceiling block (40) installed at an upper portion of the caisson structure (1), the caisson structure (1)
Removing at least a portion of the settling block (40) located above the mutually facing closed cells (12) of the neighboring closed caisson (90);
The filler 30 of the region to be made into the open cell 13 is removed and the closed type cell 12 is formed in the shape of the open cell 13, (12) to form an open caisson (10) capable of interlocking with said closed caisson (90) by opening said wall (11) to open to a neighboring caisson.
Filling an intercell filler (23) in an intercell (22) formed by two open cells (13) with openings facing each other; And
And inserting an intercell filler (23) into the intercell (22), and installing a block (40) on the caisson structure (1)
Wherein the intercell filler (23) filled in the intercell (22) interlocks the two adjacent open caissons (10).
The method according to claim 1,
Before the intercell filler 23 is filled in the intercell 22,
And forming a shear key 18 for distributing load and generating a frictional force when the intercell filler 23 is flexibly filled in the intercell 22 on the side surface of the intercell 22 Of the existing caisson interlocking reinforcement construction method.
The method according to claim 1,
Before the intercell filler 23 is filled in the intercell 22,
Further comprising the step of forming a hammock (15) as a reinforcing portion for supporting a load applied between the crossing side surfaces of the intercell (22) at the corner portions where the side surfaces of the intercell (22) intersect, Interlocking reinforcement construction method.
The method according to claim 1,
The intercell filling material 23 having a standard size of 0.015 m ³ / EA to 0.03 m ³ / EA is filled in the intercell 22 so that the intercell filling material 23 in the intercell 22 is in a flexible state In the case of the conventional caisson interlocking reinforcement construction method.
The method according to claim 1,
Before the intercell filler 23 is filled in the intercell 22,
Wherein an overlock member (24) is provided at a boundary portion between two open cells (13) constituting the intercell (22) in the side surface of the intercell (22).
The method of claim 5,
Wherein the overlock member (24) is a flexible rubber or rigid body panel.
The method according to claim 1,
Before the intercell filler 23 is filled in the intercell 22,
Further comprising the step of installing a reinforcing structural reinforcement member 25 on the side surface of the intercell 22 to reinforce the side surface of the intercell 22 and injecting the reinforcing mortar 26. [ Caisson interlocking reinforcement construction method.
The method according to claim 1,
When the intercell filler 23 is filled in the intercell 22,
And filling the intercell (22) with the intercell filler (23) filled in the flexible net.
The method according to claim 1,
When the intercell filler 23 is filled in the intercell 22,
Further comprising the step of filling the intercell filler (23) filled with the intercell filler (23) into the intercell (22).


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