KR102002626B1 - Structure for connecting concrete and method for constructing the same - Google Patents

Abstract

The present invention relates to a concrete connecting structure. According to the present invention, the concrete connecting structure includes: a pair of basic concretes provided to be adjacent to each other while having a separation space therebetween and having a dented space at a facing area; an elastic block mounted in the separation space; and a pair of reinforcing concretes respectively installed in the dented space of the pair of basic concretes. According to the present invention, the concrete connecting structure is possible to improve durability and maintain water tightness even during thermal deformation of the concrete.

Description

Concrete connecting structure and construction method thereof {STRUCTURE FOR CONNECTING CONCRETE AND METHOD FOR CONSTRUCTING THE SAME}

The present invention relates to a concrete connection structure and a construction method thereof, and to a concrete connection structure and a construction method thereof that can effectively connect the space between the concrete.

In facilities such as water purification plants and sewage treatment plants, sedimentation basins are set up to settle suspended solids in raw water.

On the other hand, concrete itself has a problem of expansion or contraction by thermal deformation in accordance with the change in ambient temperature due to its own characteristics, it prevents the cracks due to thermal deformation by providing a separation space by partially separating the sections without placing the concrete continuously. The sealant was filled in the space to form a joint to block water from leaking into the concrete.

However, in the case of repeated thermal deformation of concrete, the joint is easily separated from or separated from the space, and there is a big problem that the water tightness is degraded.

On the other hand, facilities such as water purification plants and sewage treatment plants not only cause enormous obstacles to civil life and industrial activities due to water supply interruption, but also have a huge impact on accident damage. Therefore, it is very necessary to prevent such accidents in advance.

In view of this, there is an urgent need for a technology that can maintain the watertightness while improving the durability of concrete.

Korean Utility Model Publication No. 20-0394983

Accordingly, an object of the present invention is to solve such a conventional problem, and to provide a concrete connection structure and a construction method thereof that can improve durability while maintaining watertightness even in thermal deformation of concrete.

The object is, according to the present invention, a pair of basic concrete disposed adjacent to each other with a space between them, the recessed space is formed in the opposing area; An elastic block mounted in the separation space; It is achieved by a concrete connection structure comprising a; a pair of reinforcement concrete each installed in the recessed space of the pair of basic concrete.

In addition, the basic concrete and the reinforcement concrete may be provided with concrete of different materials.

In addition, an epoxy adhesive may be applied to the contact surface between the elastic block and the basic concrete.

The apparatus may further include an index plate spaced upward from the elastic block, and both ends of which are inherently embedded in neighboring reinforcement concrete.

In addition, it is mounted between the pair of reinforced concrete, it may further include a finish for closing the play space.

The apparatus may further include an elastic support mounted between the support member and the index plate to support the side surfaces of the pair of reinforcement concrete.

In addition, the elastic support has a circular cross section and may support the finish in a fixed state between a pair of reinforcement concrete.

In addition, the above object, according to the present invention, the first pouring step of placing a pair of the base concrete with a space between; A removal step of forming a recessed space by removing an area of the basic concrete facing the spaced space; An elastic block mounting step of mounting an elastic block in the separation space; A second placing step of placing reinforcement concrete in each of the pair of basic concrete recessed spaces; An elastic support installation step of installing an elastic support in the clearance space between the reinforced concrete; It is achieved by a method for constructing a concrete connection structure, comprising a; finish installation step of installing the finish by applying a sealant to close the play space.

In addition, the second pouring step, the step of pouring a polymer mortar cement in the recessed space; Placing the index plate on the poured polymer mortar; And adding polymer mortar cement in the recessed space to form reinforcement concrete in a state in which the index plate is insulted.

In addition, in the elastic block mounting step, after applying an epoxy adhesive to the basic concrete surface in contact with the elastic block may be mounted to the elastic block.

According to the present invention, by providing an elastic block that is opposed to the thermal deformation of the basic concrete in the space space, there is provided a concrete connection structure and a construction method thereof that can maintain watertightness.

In addition, by arranging the basic concrete with cement having excellent durability in a region other than the connecting portion, and arranging a separate reinforcement concrete with cement which may have a cushioning characteristic in the region adjacent to the connecting portion, rigidity and durability can be maintained at the same time.

In addition, by arranging multiple component watertight structures on the concrete connection portion, it is possible to prevent the problem of watertightness even if any one does not operate.

In addition, the lower part of the connecting part maintains rigidity and watertightness by using only the combined structure of the basic concrete and elastic block, which is excellent in rigidity, while the lower part of the connecting part uses the composite structure of the basic concrete and reinforcement concrete to reduce the possibility of cracking. Blocking can enhance watertightness. In other words, by dividing the connection area into two areas to reinforce the different properties in combination, there is an advantage that can enhance the durability and watertightness, without deteriorating the rigidity of the concrete.

1 is a schematic process flowchart of a method for constructing a concrete connection structure according to an embodiment of the present invention;
FIG. 2 schematically illustrates a first pouring step process of the method for constructing a concrete connection structure of FIG. 1;
Figure 3 schematically shows the removal step of the method of construction of the concrete connection structure of Figure 1,
Figure 4 schematically shows the elastic block mounting step process of the concrete connection structure construction method of Figure 1,
FIG. 5 schematically illustrates a second pouring step process of the method of constructing a concrete connection structure of FIG. 1;
Figure 6 schematically shows the step of installing the elastic support of the concrete connection structure construction method of Figure 1,
FIG. 7 schematically illustrates the finishing step installation process of the concrete connecting structure construction method of FIG. 1;
Figure 8 illustrates a cross section of the concrete connection structure according to an embodiment of the present invention,
9 is a cross-sectional view for explaining the structural features of the concrete connection structure of FIG.

Hereinafter, with reference to the accompanying drawings, a concrete connection structure construction method (S100) according to an embodiment of the present invention will be described in detail, and the construction of the concrete connection structure 110 will be described later.

1 is a schematic process flowchart of a method for constructing a concrete connection structure according to an embodiment of the present invention.

As shown in Figure 1, the concrete connection structure construction method (S100) according to an embodiment of the present invention is the first pouring step (S110) and removal step (S120) and elastic block mounting step (S130) and the second pour Step (S140) and the elastic support installation step (S150) and finish unit installation step (S160).

FIG. 2 schematically illustrates a first pouring step process of the method for constructing a concrete connection structure of FIG. 1.

Referring to FIG. 2, the first pouring step S110 is a step of forming and curing concrete to form the basic concrete 110. In this step, in order to prevent the self-deformation is caused by the expansion or contraction of the basic concrete 110 in accordance with the temperature change, it is poured in a predetermined space, that is, spaced apart space 111, without pouring continuously.

Specifically, in this step, but is not limited to, the basic concrete 110 is formed in a manner that is cured after pouring Portland Cement generally used widely.

On the other hand, in the present invention, it is described that a pair of basic concrete 110 is disposed on both sides with the separation space 111 therebetween, but the pair here is completely intermittently separated between the basic concrete (110) It does not mean that, it means that at least a portion of the space is formed by intermittent space 111 is included.

The width of the separation space 111 is preferably determined in consideration of the total area of the basic concrete 110, the temperature conditions of the construction site, the thermal expansion characteristics of the material itself, and the like.

Figure 3 schematically shows a step removal process of the construction method of the concrete connection structure of FIG.

As shown in Figure 3, the removing step (S120) is to remove a portion of the basic concrete 110, a recessed space that is a space where the reinforcement concrete 130 formed in the second pouring step (S140) will be described later Step 112 is formed.

Specifically, in this step, the recessed space 112 is formed by cutting a portion of the upper end of the region of the basic concrete 110 facing the spaced space 111 with a cutter.

When the cutting is completed in this step, the cut surface of the basic concrete 110 is washed with high pressure water and dried for the process described later.

Figure 4 schematically shows the elastic block mounting step process of the concrete connection structure construction method of FIG.

As shown in FIG. 4, the elastic block mounting step S130 is a step of mounting the elastic block 120 in the space 111.

In this step, the elastic block 120 is mounted in the end space where the step of the basic concrete 110 is formed, that is, the space in which the recessed space 112 starts.

On the other hand, the elastic block 120 in the present embodiment is made of a material having a greater elasticity than the basic concrete 110 so that it can be expanded and contracted in response to the increase and decrease of the width of the separation space 111 due to the expansion and contraction of the basic concrete 110 It is preferable that the elastic block 120 is provided as a rubber material in the present invention, but the material is not limited thereto.

Specifically, first, an epoxy adhesive is uniformly applied to the surface on which the elastic block 120 of the basic concrete 110 is to be bonded and the adhesive surface of the elastic block 120, respectively.

When the application of the epoxy adhesive is completed, the elastic block 120 is inserted into the spaced space 111 to be in close contact with and bonded to the basic concrete 110 on both sides. At this time, it is preferable to determine the size of the elastic block in consideration of the temperature distribution of the construction site.

In more detail, after calculating the volume of the heat-deformed basic concrete 110 and the width of the separation space 111 based thereon at a specific temperature, the elastic block 120 is finely compressed and spaced apart from the calculated width. It is preferable to have such a size that the adhesion to the space 111 is maintained.

For example, the width of the separation space 111 at the lowest predicted temperature is calculated in advance, and the elastic block 120 is designed to have a width that is equal or finely compressed, and then inserted into the separation space 111. As a result, even if the width of the separation space 111 decreases in accordance with the temperature change, the possibility of the elastic block 120 leaving the separation space 111 may be minimized. This is a method that may be utilized when the elastic block 120 has superior compression characteristics than expansion characteristics.

Alternatively, the width of the separation space 111 at the average temperature of the construction environment may be calculated in advance, and the elastic block 120 may be designed to have the same width as that of the same or finely extruded and inserted into the separation space. . This is a method that the elastic block 120 can utilize when the expansion characteristics and compression characteristics are uniform.

That is, after considering the compression and expansion characteristics of the elastic block 120 to be used, the width of the separation space 111 at a specific temperature is calculated, and the elastic block 120 has a size corresponding thereto, thereby making the elastic block ( 120 may be more flexibly responded to the increase and decrease of the separation space 111 according to the temperature change.

FIG. 5 schematically illustrates a second pouring step process of the method for constructing a concrete connection structure of FIG. 1.

The second pouring step (S140) is a step of forming the reinforcement concrete 130 in the recessed space 112 formed by cutting the basic concrete 110. At this time, the reinforcement concrete 130 formed in this step is provided with a material different from the basic concrete 110, specifically, a polymer mortar material.

That is, the reinforcement concrete 130 is excellent in corrosion resistance, water resistance, and the like, and should be firmly bonded to the index plate 140, the elastic support 160, the finishing unit 150, etc., as well as excellent bonding to the dissimilar material, It should be able to elastically respond to physical deformation caused by the basic concrete (110). Therefore, it is preferable to manufacture the reinforced concrete 130 with polymer mortar having excellent corrosion resistance, waterproofness, elasticity, dissimilar material bonding properties, and the like, compared to the Portland cement used as the basic concrete 110 in the present embodiment.

First, as shown in FIG. 5 (a), the polymer mortar is poured into the recessed space 112 to a degree of filling. In this case, the clearance space 131 may be formed in the space extending upward of the separation space 111 without filling the polymer mortar.

Next, as shown in FIG. 5 (b), the index plate 140 is disposed on the poured polymer mortar. The index plate 140 is a structure for enhancing the bonding force between the reinforcement concrete 130 separated by the play space 131, and to reinforce the sealing performance of the play space 131 and the space space 111, and has excellent durability. It may be made of a material such as metal, plastic.

When the arrangement of the index plate 140 is completed, as shown in FIG. 5 (c), the polymer mortar is additionally poured onto the index plate 140 and cured to completely fill the polymer mortar in the recessed space 112. .

Therefore, according to the above-described step, a pair of reinforcement concrete 130 is formed in the recessed space 112 with the clearance space 131 interposed therebetween, and the structure in which the water stop plate 140 is embedded in the reinforcement concrete 130 is provided. Have

On the other hand, in the step of pouring the polymer mortar in the step of constructing the formwork using plywood, etc., which is general in the art, so a detailed description thereof will be omitted.

FIG. 6 schematically illustrates a step of installing an elastic support of the method of constructing a concrete connection structure of FIG. 1.

As shown in Figure 6, the elastic support installation step (S150) is a step of installing the elastic support 160 in the play space of the reinforcement concrete 130 is completed casting and curing.

In this embodiment, the elastic support 160 is provided with a material having elasticity, it is preferable that the shape of the cross section is provided in a circular shape, as a whole in a cylinder structure. Accordingly, the elastic support 160 is installed at a position spaced apart from the index plate 140 in the play space 131 by a predetermined interval upward, and both sides of the elastic support 160 are in close contact with the inner wall surface of the reinforcement concrete 130, It is fixed.

FIG. 7 schematically illustrates a finishing step installation process of the concrete connecting structure construction method of FIG. 1.

As shown in FIG. 7, the finishing step installing step S160 is to install a finishing part 150 having elastic properties on the upper side of the elastic support 160 to finally close the clearance space 131 to seal it. At the same time, the upper exposed surface of the base concrete 110, the upper exposed surface of the reinforcement concrete 130, the exposed surface of the finish portion 150 exposed to the outside is a step to make the entire surface flat and continuous.

In this step, the finishing portion 150 for closing the clearance space 131 is formed by filling the elastic sealant at the end of the clearance gap 131 above the elastic support 160.

Hereinafter, the concrete connection structure 100 to be constructed by the concrete connection structure construction method (S100) according to an embodiment of the present invention described above in more detail.

8 is a cross-sectional view of the concrete connection structure according to an embodiment of the present invention.

Referring to FIG. 8, the concrete connection structure 100 according to the embodiment of the present invention includes the basic concrete 110, the elastic block 120, the reinforcement concrete 130, the index plate 140, and the finish 150. It is configured to include an elastic support 160.

The present invention is composed of a concrete structure of two materials, one of the basic concrete 110 is provided with a cement material excellent in rigidity and durability in order to perform the function of the basic structure of the present invention.

When the basic concrete 110 is formed as a continuous structure without an intermittent section, durability may be weakened or physical cracks may occur due to repeated thermal deformation due to temperature increase or decrease. Forming a spaced apart space 111.

The elastic block 120 is for tightly sealing the space 111, which is a buffer space, and is provided of a material having elastic properties such as rubber.

At this time, the width of the elastic block 120, as described above, is determined in consideration of the amount of change in the separation space width according to the temperature, the thickness of the elastic block 120 is the width of the separation space 111, the base concrete 110 It is preferable to determine in consideration of the thickness of the), the material of the elastic block 120, and the like.

The reinforcement concrete 130 is provided with a material having elasticity so as to be able to deform to a property opposite to the heat deformation of the base concrete in response to the heat deformation of the base concrete 110 according to the temperature change. In the present invention, the reinforced concrete 130 is preferably composed of a polymer mortar cement material excellent in elasticity and corrosion resistance, dissimilar material bonding.

The index plate 140 is a structure installed in the reinforcement concrete 130 to improve durability and watertightness.

The finish part 150 is for finishing the uppermost end of the play space 131 between the reinforcement concrete 130, it is installed in a manner to apply an elastic sealant. The finish part 150 primarily blocks the inflow of water into the concrete structure.

The elastic support 160 is installed in the clearance space 131 between the reinforcement concrete 130 to support the lower end of the finish portion 150, and to block water from flowing into the concrete structure. On the other hand, the width of the elastic block 120 is formed to be wider than the width of the elastic support 160, the separation space 111 that both sides of the elastic block contact than the width of the clearance space that both sides of the elastic support 160 touch. It is preferable that the width of is formed wide.

Therefore, since both the reinforcement concrete 130 and the elastic support 160 are provided with a material having elastic force, the reinforcement concrete and the elastic support are elastically deformed at the same time in response to thermal deformation, so that the concrete concrete into the concrete structure Excellent leakage barrier properties and the possibility of cracking can be minimized.

Therefore, according to the structure of the present invention described above, because the space between the concrete is tightly blocked using a plurality of structures, not only the watertightness is improved, but also the material having elastic force effectively copes with the thermal deformation of the basic concrete. Durability can be improved.

9 is a cross-sectional view for explaining the structural features of the concrete connection structure of FIG.

9, the structural advantages of the concrete connection structure 100 according to an embodiment of the present invention will be described in more detail.

When the temperature of the outside air rises or decreases, the concrete structure is thermally expanded or thermally contracted. According to the existing structure, the joint is separated from the spaced space or the seal is broken due to the difference in the coefficient of thermal expansion between the joints filling the spaced space between the concrete and the concrete. There is a problem that water is introduced into the space.

However, as shown in FIG. 9 (a), even when the basic concrete 110 is deformed, the reinforced concrete 120 made of polymer mortar buffers using its own elasticity to maintain a relatively constant width of the clearance space. By doing so, deformation of the elastic support 160 and the finishing unit 150 mounted in the clearance space can be minimized, and watertightness can be maintained.

In particular, as shown in FIG. 9B, even when the base concrete 110 is thermally deformed to increase or decrease the width of the space 111, the elastic block 120 installed in the space 111 may have its own elasticity. By compressing or expanding to the opposite characteristics of the behavior of the basic concrete 110 to flexibly respond to the change in the width of the space, it is possible to maintain a tight contact state.

In addition, as described above, by properly mounting the elastic block 120 in consideration of the elastic characteristics and air temperature in the construction process, the base concrete 110 is contracted to the maximum, the width of the separation space 111 is the maximum value Even in this case, the elastic block 120 is restored to a circle within a range not to lose the elastic force is able to closely maintain the state of close contact in the space.

The scope of the present invention is not limited to the above-described embodiment, but may be embodied in various forms of embodiments within the scope of the appended claims. Without departing from the gist of the invention claimed in the claims, it is intended that any person skilled in the art to which the present invention pertains falls within the scope of the claims described in the present invention to various extents which can be modified.

110: basic concrete 120: elastic block
130: reinforced concrete 140: index plate
150: finish 160: elastic support

Claims (10)

A pair of basic concrete disposed adjacent to each other with a separation space therebetween, and a recessed space formed in an opposite area;
An elastic block mounted in the separation space, the elastic block being compressed or expanded in a property opposite to the behavior characteristic of the basic concrete to flexibly respond to a change in the width of the separation space;
And a pair of reinforcement concrete, each of which is installed in a recess of the pair of basic concrete.
The basic concrete and the reinforcement concrete are provided with concrete of different materials, the reinforcement concrete is composed of an elastic material so that it can be deformed to the characteristics opposite to the heat deformation of the basic concrete in response to the thermal deformation of the basic concrete,
The side surface of the elastic block has a rectangular block shape, both sides are provided in a flat shape and are in close contact with the basic concrete,
Epoxy adhesive is applied to the contact surface between the elastic block and the base concrete,
An index plate spaced upward from the elastic block, and both ends of which are embedded in neighboring reinforcement concrete,
A finishing part mounted between the pair of reinforcing concrete and closing the play space and filling the elastic sealant;
Further comprising an elastic support mounted between the finish and the index plate to support the side of the pair of reinforced concrete,
The elastic support has a circular cross section and supports the finish in a fixed state between a pair of reinforced concrete,
Both sides of the elastic support is in direct contact with the side of the reinforcement concrete is in close contact,
The upper exposed surface of the basic concrete, the upper exposed surface of the reinforcement concrete, and the exposed surface of the finish are continuity and are generally flat.
The index plate is placed after the part of the reinforcement concrete is placed thereon, and the remaining part of the reinforcement concrete is poured again on the index plate to completely fill the recessed space, so that the index plate is embedded inside the reinforcement concrete,
The index plate is supported only by reinforced concrete,
It is separated by the clearance space and takes the structure to improve the bonding force of the reinforced concrete at the top and bottom of the index plate,
The width of the elastic block is formed wider than the width of the elastic support,
A concrete connection structure, characterized in that the width of the space spaced between the two sides of the elastic block is wider than the width of the space spaced between both sides of the elastic support. delete delete delete delete delete delete A first placing step of placing a pair of basic concrete with a space between them;
A removal step of forming a recessed space by removing an area of the basic concrete facing the spaced space;
An elastic block mounting step of mounting an elastic block in the spaced space, the elastic block being compressed or expanded with a property opposite to the behavior of the basic concrete to flexibly respond to a change in the width of the spaced space;
A second placing step of placing reinforcement concrete each of which is made of an elastic material so as to correspond to thermal deformation of the basic concrete in a pair of basic concrete recessed spaces so as to be deformed to a property opposite to that of the basic concrete;
An elastic support installation step of installing an elastic support in the clearance space between the reinforced concrete;
To finish the installation space by applying a sealant to close the clearance space installation step of installing;
The second pouring step,
Pouring polymer mortar cement into the recessed space; Placing the index plate on the poured polymer mortar; And adding reinforcing polymer mortar cement in the recessed space to form reinforcement concrete in a state in which the index plate is embedded.
In the elastic block mounting step, the epoxy block is applied to the basic concrete surface in contact with the elastic block, and then the elastic block is mounted, and the elastic block is formed in a rectangular block shape on both sides thereof so that both sides are provided in a flat shape. Interviewing and contacting the basic concrete
In the second pouring step, the index plate is disposed on the part after the reinforcement concrete is poured, and the remaining part of the reinforcement concrete is poured again on the index plate to completely fill the recessed space, whereby the index plate is inside the reinforcement concrete. Internally, the index plate is supported only by reinforcement concrete, and is separated by the play space to take a structure to improve the bonding force of the reinforcement concrete on the upper and lower portions of the index plate,
The elastic support has a circular cross section and supports the finish in a fixed state between a pair of reinforcement concrete, and both sides of the elastic support come into direct contact with the side of the reinforcement concrete and are in close contact with each other.
In the finishing step installation step, the upper exposed surface of the base concrete, the upper exposed surface of the reinforcement concrete, the exposed surface of the finish is a continuity to form a generally flat surface,
The width of the elastic block is formed wider than the width of the elastic support,
A method of constructing a concrete connection structure, characterized in that the width of the space spaced between the sides of the elastic block is wider than the width of the space spaced between the sides of the elastic support.
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