KR101326168B1 - Concrete structure construction method using tension or compression steel shear key - Google Patents

Abstract

The present invention relates to a concrete structure manufactured by connecting multiple divided concrete structures to each other and a manufacturing method thereof. Provided are the efficient divided concrete structure and the manufacturing method thereof by improving the connection performance when the divided concrete structures are connected to each other using tensile and compressive shear keys and effectively controlling cracks after the manufacture and installation.

Description

Concrete structure manufacturing method using tensile or compression shear key {CONCRETE STRUCTURE CONSTRUCTION METHOD USING TENSION OR COMPRESSION STEEL SHEAR KEY}

The present invention relates to a method for manufacturing a concrete structure using a tensile or compression shear key. More specifically, the present invention relates to a method for manufacturing a concrete structure by connecting a plurality of segmented concrete structures to each other.

FIG. 1A illustrates an example of manufacturing a conventional PSC girder by connecting five segmented girders A, B, C, D, and E in the longitudinal direction.

That is, the connection surfaces of the girder segmented to produce the PSC girder having a predetermined length to the concave-convex portions (11, 12, 21, 22), but the connection surface of the segmented girder to be compressed by the tension member (13) The method of completing a PSC girder is disclosed.

The reason why the PSC girders are manufactured by segmenting and connecting them is that the extension of the PSC girders exceeds a certain limit, making them difficult to manufacture, and their own weight increases, making them difficult to transport and construct.

However, in connecting the segmented girders, the connection site is inevitably vulnerable to the working load, so a lot of defects occur at the connection site.

In the case of Figure 1a by forming a concave-convex portion (11, 12, 21, 22) on the connection surface of the segmented girders and by using a pre-stressed compression prestress by the tension material in the state that the concave-convex portions are mechanically engaged It can be seen that the connection performance of the segmented girders is to be secured.

Furthermore, as shown in FIG. 1B, separate connection blocks 30 are separated from each other in the connection parts of the precast segmented girders A, B, and C to serve as formwork, and additional formwork is provided between the connection blocks. After setting up, rebars, sheaths and tensioning materials are placed inside the formwork, and concrete is poured to produce integrated PSC girders. This method can be said to overcome when segmented girders are unable to secure enough connection performance.

At this time, after the actual PSC girders are introduced into the compression prestress at the manufacturing stage, after the completion of manufacture, they are placed on the alternating and pier, and when used, the tensile and compressive stresses may occur in the PSC girders due to their own weight and working load. These cracks must be controlled within a certain range.

In particular, in the production of segmented concrete structures such as segmented girders, the quality and maintenance is possible only when the cracks can be controlled while securing the connection performance at each connection portion.

In addition, a method using a kind of compressive force, that is, prestressing by installing additional tension members and connecting bolts at the connection part of the segmented concrete structure has been introduced, but this method is merely for securing the connection performance of the segmented concrete structure. The method of controlling the tensile and compression cracks that occur during the fabrication and installation process is not introduced otherwise.

Accordingly, the present invention provides a compact and stable segment type to have the same performance as that of a concrete structure that is integrally manufactured by enabling effective control of cracking after fabrication and installation while securing connection performance in connection fabrication of the segmented concrete structure. The technical problem to solve the concrete structure and the method of manufacturing the same.

In order to solve the above problems,

First, when tensile stress predominantly occurs at the connection part of the segmented concrete structure manufactured by introducing the compression prestress, the tensile resistance steel is installed to extend in the longitudinal direction inside the segmented concrete structure so that the tensile crack does not occur. In the connection part of the concrete structure, a tensile shear key is installed, but the tensile shear key allows the tensile resistance steel to be effectively connected.

As a result, unlike the conventional method, the concrete shear key having only the shear resistance function is used to the tensile shear key made of steel to sufficiently resist the tensile stress and the shear stress acting on the connection end surface of the segmented concrete structure at the same time. In addition to ensuring the connection of the tensile resistance steel, which is installed to prevent tension cracking, it also ensures less defects such as damage to the connection end surface compared to the connection of the segmented concrete structure by the uneven part and the tension material. Efficient and optimized quality control is possible due to the dense concrete structure having the same performance as integrated casting without cracking by securing more reliable connection performance.

Second, if compressive stress predominantly occurs at the joints of the segmented concrete structures produced by introducing compressive prestress, compressive reinforcements are installed around the joints of the segmented concrete structures and compressed at the joints of the segmented concrete structures. The shear key is installed, but the compressive shear key is able to sufficiently resist the compressive stress acting on the connection end surface of the segmented concrete structure to ensure sufficient connection performance, while connecting the compressive stiffener and the compressive shear key to each other to compress the compressive stress. It can effectively resist.

Third, the tensile resistance and compression resistance shear keys are all connected to each other by female, male tension and compression shear keys, and in particular, the tensile resistance shear keys must resist tensile stress, so using a pull-out bolt to restrain the tensile stress more efficiently To ensure that.

In the present invention, in a concrete structure in which a compression prestress is introduced and connected to a connection portion of a segmented concrete structure, it is possible to effectively control the crack according to the tensile stress and the compressive stress, while effectively connecting the segmented concrete structure by the tension member. .

At this time, the drawing and compression shear keys used are made of steel so that they can effectively resist the tensile and compressive stresses acting on them. Effective quality control of the concrete structure is possible by securing less and more reliable connection performance.

1a and 1b is a connection diagram of a conventional segmented concrete structure,
2a and 2b is a configuration of the tensile shear key according to the present invention,
2c and 2d is a block diagram of a compression shear key according to the present invention,
3a and 3b is a connection diagram according to embodiments 1 and 2 of the segmented concrete structure using the tensile and compression shear key of the present invention,
Figures 4a, 4b and 4c is a construction sequence diagram according to embodiments 1,2,3 of the segmented concrete structure using the tensile and compression shear key of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, except to exclude other components unless otherwise stated.

[Tension and Compression Shear Keys (100,200) of the Invention]

2a, 2b, 2c and 2d is a tensile shear key (100, 2a and 2b) and a compression shear key 200, 2c and 2d installed at the connection of the segmented concrete structure 300 of the present invention ) Is a perspective view of the composition.

[Tensile Shear Key (100)]

First, the tensile shear key 100 is made of a steel material consisting of a female and a male shear key, each embedded in the connection end surface of the segmented concrete structure 300, which is basically a precast member.

As the name indicates that when the tensile stress acts on the connection end surface, the adjacent segmented concrete structure 300 has a function to prevent separation from each other.

The tensile shear key 100 may be installed on the neutral axis of the segmented concrete structure 300, for example.

The tensile shear key 100 is divided into a female tensile shear key (100a) and a male tensile shear key (100b) as shown in Figure 2b is a female tensile shear key (100a) is installed on the connection end surface of the one-sided segmented concrete structure 300 A male tension shear key 100b corresponding to the female tension shear key 100a is installed at the connection end surface of the other segmented concrete structure 300.

First, referring to the female tension shear key 100a, as shown in FIG. 2A, the bolt head-shaped fixing part 110a and the hollow hole 120a are formed to extend in the longitudinal direction. It can be seen.

Accordingly, the fixing part 110a can be seen that the fastening hole S1 is formed in the shape of a groove that is recessed in the longitudinal direction so that the tensile resistance steel 400 to be described below can be inserted and fastened to the expansion flange part 111a. It can be seen that it is formed to include a fixed body portion 112a having a diameter smaller than the expansion flange portion 111a to be able to resist drawing.

In this case, it is understood that the fastening hole S1 is formed in an open shape in the expansion flange part 111a by penetrating the expansion flange part 111a to have an extension length smaller than the extension length of the fixed body part 112a. The tensile resistance steel 400 may be fastened to the fastening hole S1.

Next, the hollow body portion 120a is inserted into the insertion hole 120b of the male tension shear key 100b, which will be described later, as a tubular body portion having a diameter of the enlarged flange portion in series with the hollow body portion 120a. It can be seen that the hole S2 is formed in the longitudinal direction therein.

It can be seen that the insertion hole (S2) is also formed in the groove shape that is dug in the longitudinal direction. Can be.

When the drawing resistance bolt 130 is fastened to the through-hole S3 and serves as a passage for extending into the insertion hole S2, the drawing resistance bolt 130 is inserted into the insertion hole 120b of the male tensile shear key 100b. Is to act as a fastener (junction) to be caught in the insertion hole (S2).

The extension length of the hollow body portion 120a is to be formed in accordance with the extension length of the insertion hole 120b of the male tension shear key 100b, but the extension length of the insertion hole 120b of the male tension shear key 100b is sufficient for tensile stress. What is necessary is just to form enough to resist.

Next, the male tensile shear key 100b is inserted into the female tensile shear key 100a described above and has a function of resisting tensile stress. For this purpose, the male tensile shear key 100b is inserted into the female tensile shear key 100a. It is to be formed so as not to be affected by the tensile stress.

To this end, looking at the male tensile shear key 100b, as shown in FIG. 2A, it can be seen that the locking head 110b and the outer circumferential surface are formed with the insertion hole 120b formed to extend in the longitudinal direction. .

Accordingly, the fixing part 110b can be seen that the fastening hole S1 is formed in the shape of a groove formed in the longitudinal direction so that the tensile resistance steel 400, which will be described later, can be inserted and fastened. It can be seen that it is formed to include the fixed body portion 112b having a diameter smaller than the expansion flange portion 111b to resist the drawing by.

In this case, it is understood that the fastening hole S1 is formed in an open shape in the expansion flange part 111b by penetrating the expansion flange part 111b to have an extension length smaller than the extension length of the fixed body part 112b. The tensile resistance steel 400 may be fastened to the fastening hole S1.

Next, the insertion hole 120b is a rod member having a diameter of the expansion flange portion 111b that is substantially continuous by the hollow body portion 120a and the expansion flange described above, and is formed through the hole in the longitudinal direction along the outer circumferential surface (S4). It can be seen that is formed.

It can be seen that the locking through hole (S4) is formed to penetrate through the insertion hole (120b). The locking through hole (S4) passes through the through hole (S3) of the hollow body portion (120a) of the above-mentioned female tension shear key. As the pullout resistance bolt 130 is inserted, the male tensile shear key 100b is inserted into the female tensile shear key 100a to have a function of being constrained by the pullout resistance bolt 130.

Thus, as shown in FIG. 2A, the male tensile shear key 100b is constrained by the pull-out resistance bolt 130 to the female tensile shear key 100a so that the adjacent segmented concrete structures 300 can be prevented from being separated from each other.

In addition, as the male tensile shear key 100b is fastened to the fastening holes S1 formed in the female tensile shear key 100a as shown in FIG. 2B, the tensile resistance steel 400 is fastened, so that the tensile resistance steel 400 is connected at the connection end surface. It can be seen that they are connected to each other. Accordingly, the male tensile shear key 100b of the present invention can be seen that the female tensile shear key 100a also has a tensile resistance steel 400 connection function.

The tensile resistance steel 400 is to use a steel bar or reinforcing bar to form a screw-shaped fastening portion at the end is to be installed by fastening the male tensile shear key (100b) to the fastening hole (S1) of the female tensile shear key (100a). .

The tensile resistance steel 400 is buried in the upper portion of the neutral shaft of the segmented concrete structure connected to each other, for example, the tensile stress predominantly prevents the tensile cracking due to the tensile stress when the tensile stress occurs in the segmented concrete structure To have.

Since the tensile resistance steel 400 is easily connected to the male tensile shear key 100b by the female tensile shear key 100a at the connection end surface, it is found that it is very advantageous for tensile crack control, especially in a segmented concrete structure. Can be.

[Compression shear key 200]

Compression shear key 200 of the present invention is also made of a steel material consisting of a female, male shear key embedded in each of the connection end surface of the segmented concrete structure 300, which is basically a precast member, like the tensile shear key 200 described above Using the same is the same.

In this case, when the compressive stress acts on the connection end face as described above, the adjacent segmented concrete structures 300 have a function to prevent damage due to excessive concentrated stress on the connection end face when they are compressed together.

The compression shear key 200 is installed below the neutral shaft of the segmented concrete structure 300, for example, in which compressive stress predominantly occurs.

Accordingly, the compression shear key 200 is also divided into the female compression shear key 200a and the male compression shear key 200b as shown in FIG. 2d, and the female compression shear key 200a is installed on the connection end surface of the one-sided segmented concrete structure 300. A male compression shear key 200b corresponding to the female compression shear key 200a is installed at the connection end surface of the other segmented concrete structure 300.

First, referring to the female compression shear key 200a, as shown in FIG. 2C, the bolt head-shaped fixing part 210a and the hollow hole 220a formed to extend in the longitudinal direction are formed in the hollow body part 220a. It can be seen.

Thus, the fixing part 210a can be seen that the fastening hole S1 is formed in the shape of a groove formed in the longitudinal direction so that the compressive resistance steel 500 to be described later can be inserted and fastened to the expansion flange part 211a. It can be seen that it is formed to include a fixed body portion 212a having a diameter smaller than the expansion flange portion (211a) to be able to resist compression.

At this time, the fastening hole (S1) is also formed through the expansion flange portion (211a) to have an extension length smaller than the extension length of the fixed body portion (212a) is formed in an open shape in the expansion flange portion (211a). It can be seen that the compression resistance steel 500 is fastened to the fastening hole (S1).

Next, the hollow body portion 220a is inserted into the insertion hole 220b of the male compression shear key 200b, which will be described later, as a tubular body portion having a diameter of the enlarged flange portion in series with the expansion flange portion 211a described above. It can be seen that the hole S2 is formed in the longitudinal direction therein.

It can be seen that the insertion hole S2 is also formed in the shape of a groove that is dug in the longitudinal direction. The extension length of the hollow body portion 220a is to be formed in accordance with the extension length of the insertion port 220b of the male compression shear key 200b, but the extension length of the insertion hole 220b of the male compression shear key 200b is sufficient for the compressive stress. What is necessary is just to form enough to resist.

Next, the male compression shear key 200b is inserted into the female compression shear key 200a described above and has a function of resisting the compressive stress. For this purpose, the male compression shear key 200b is inserted into the female compression shear key 200a. It is formed so as not to be affected by the compressive stress.

For this purpose, the male compression shear key 200b can be seen that it is formed of a bolt head-shaped fixing portion 210b and an insertion hole 220b extending in the longitudinal direction as shown in FIG. 2B.

Thus, the fixing part 210b can be seen that the fastening hole S1 is formed in the shape of a groove formed in the longitudinal direction so that the compressive resistance steel 500, which will be described later, can be inserted and fastened. It can be seen that it is formed to include a fixed body portion 212b having a diameter smaller than the expansion flange portion 211b to resist compression.

In this case, the fastening hole S1 penetrates the expansion flange portion 211b to have an extension length smaller than the extension length of the fixed body portion 212b. The compressive resistance steel 500 may be fastened to the fastening hole S1.

Next, the insertion hole 220b is a rod member having a diameter of the roughly extended flange portion 211b that is continuously formed by the hollow body portion 220a and the extended flange as described above.

Accordingly, as shown in FIG. 2D, the insertion hole 220b of the male compression shear key 200b is inserted into and supported by the hollow body portion 220a of the female compression shear key 200a (bonded), so that the adjacent segmented concrete structures 300 are compressed together. Even if it is, it can be seen that it is possible to prevent damage such as cracks around the connection end surface. In other words, the compression of the shear shear key 200 is made of steel, so that the compression of the segmental concrete structure 300 is distributed and supported so as to protect the connection end surface of the segmented concrete structure 300.

It can be seen that the insertion hole 220b is formed with a shorter length than the insertion hole 120b described above. In the case of the compressive stress, the tensile stress is not significantly affected by the length of the insertion hole, and the tensile stress increases when the number of drawing resistance bolts 130 is increased. This is because the binding performance increases.

In addition, the compressive resistance steel 500 may be formed using a steel bar or reinforcing bar, and a screw-shaped fastening portion is formed at an end thereof so as to be installed by fastening to the fastening hole S1 of the female compression shear key 200a and the male compression shear key 200b. .

The compressive resistance steel 500 has an extension head 510 at the end opposite to the fastening part as shown in FIG. 2C. The diameter of the extension head 510 is larger than the largest diameter of the compression shear key 200. It can be seen that it is formed to have.

This is because the compression-resistant steel 500 is to resist the compressive stress, unlike the tensile resistance steel 400 is formed so as not to extend in the longitudinal direction is a fixture function to be more securely fixed to the segmented concrete structure 300 To have.

In other words, the tensile resistance steel 400 serves to reinforce concrete vulnerable to tensile cracking by making the area in contact with the segmented concrete structure 300 large by the extension length, whereas the compressive resistance steel 500 is connected. The extension head 510 is used because the extension length does not have to be long because the compressive stress acts intensively on the end surface.

[Segmented concrete structure 300 using tensile and compression shear keys 100,200 of the present invention]

3A and 3B are connection diagrams of the segmented concrete structure using the tensile shear key 100 and the compression shear key 200 described above.

First, FIG. 3A is a connection diagram of the segmented concrete structure 300 using both the tensile shear key 100 and the compression shear key 200.

3b is a connection diagram of the segmented concrete structure 300 using only the compression shear key 200.

This division is that the segmented concrete structure 300 according to FIG. 3a has a relatively large cross-sectional height (when not in conflict with the height limit), so that the tensile stress is generated by the prestress by the tension material on the segmented concrete structure 300. Is the case,

The segmented concrete structure 300 according to FIG. 3b may have a relatively small cross-sectional height (when the height limit is exceeded) and a compressive stress predominantly acts on the entire cross section of the segmented concrete structure 300.

Example 1: FIG. 3A

Referring to FIG. 3A, it can be seen that the segmented concrete structure 300 is a PSC girder having an I-shaped cross section so that the two segmented concrete structures 300 are connected to each other.

In the upper part of the neutral shaft (upper flange) of the segmented concrete structure 300 adjacent thereto, it can be seen that the tensile resistance steel 400 installed with the female tensile shear key 100a and the male tensile shear key 100b described above is embedded. The tensile resistance steel 400 is fastened to the female tensile shear key 100a and the male tensile shear key 100b, respectively, and the female tensile shear key 100a and the male tensile shear key 100b are connected to the adjacent segmented concrete structure 300. It can be seen that the surface is exposed.

At this time, the tensile resistance steel 400, the female tensile shear key (100a) and the male tensile shear key (100b) is to be pre-installed when manufacturing the one and the other segmented concrete structure 300.

That is, the male tensile shear key (100a) is adjacent to the one-sided segmental concrete structure 300, the male tensile shear key (100b) is disposed in the adjacent segmented concrete structure 300, respectively,

It can be seen that the hollow body portion 120a of the female tension shear key 100a is exposed to the connection end surface, and the insertion hole 120b of the male tension shear key 100b is horizontally exposed to the connection end surface. Can be.

Accordingly, it can be seen that the insertion hole 120b is inserted into the insertion hole S2 of the hollow body part 120a so that one side and the other segmented concrete structure 300 are constrained by the pull-out resistance bolt 130.

The two segmented concrete structure 300 is compressed by being introduced over the entire extension length by the tension material not shown to be connected to each other.

Furthermore, according to FIG. 3A, the compression shear key 200 described above is exposed to the connection end surface of the adjacent segmented concrete structure 300 at the lower portion of the neutral shaft (the lower part and the lower flange) of the adjacent segmented concrete structure 300. Can be.

That is, the female compression shear key 200a and the male compression shear key 200b are to be pre-installed when manufacturing the one side and the other segmented concrete structure 300.

Accordingly, it can be seen that the male compression shear key 200a is disposed at the one side segmented concrete structure 300 and the male compression shear key 200b is disposed at the adjacent segmented concrete structure 300, respectively.

It can be seen that the hollow body portion 220b of the female compression shear key 200a is exposed to the connection end surface, and the insertion hole 220b of the male compression shear key 200b is exposed to the connection end surface horizontally. Can be.

As a result, the insertion hole 220b is inserted into the hollow body portion 220b to be supported (bonded) so that the segmented concrete structure 300 is bonded to each other.

The two segmented concrete structure 300 is compressed by being introduced over the entire extension length by the tension material not shown to be connected to each other.

Example 2: FIG. 3B

Next, according to FIG. 3b, the segmented concrete structure 300 is also a PSC girder having an I-shaped cross section so that the two segmented concrete structures 300 may be connected to each other. It can be seen that only the compression shear key 200 is installed at the connection end surface of the 300.

According to FIG. 3b, only the compression shear key 200 described above is exposed to the connection end surface of the adjacent segmented concrete structure 300 over the entire cross-section of the adjacent segmented concrete structure 300 (upper flange, abdomen and lower flange). It can be seen that.

That is, the female compression shear key 200a and the male compression shear key 200b are to be pre-installed when manufacturing the one side and the other segmented concrete structure 300.

At this time, it is also found that the female compression shear key 200a is adjacent to the one-sided segmental concrete structure 300, and the male compression shear key 200b is exposed to the connection end surface, respectively. It can be seen that the insertion hole 220b of 200b is horizontally exposed on the connection end surface.

That is, the two segmented concrete structures 300 are not shown in the state in which the insertion hole 220b of the male compression shear key 200b is inserted into the insertion hole S2 of the female compression shear key 200a to be supported (bonded). The tension member is introduced over the entire extension length so as to be compressed and connected to each other.

[Manufacturing method of the segmented concrete structure 300 using the tensile and compression shear keys (100,200) of the present invention]

4A is a flowchart illustrating a method of manufacturing the segmented concrete structure 300 according to Example 1 (FIG. 3A), and a method of manufacturing the segmented concrete structure 300 according to Example 2 (FIG. 3B). 4b is a flowchart illustrating a method of manufacturing the segmented concrete structure 300 according to the third embodiment.

[Production method of segmented concrete structure according to Example 1]

Looking at the basis of Figure 4a,

First, a plurality of segmented concrete structures 300 are manufactured and connected to each other to produce one concrete structure Q. This concrete structure Q will be described in the case of a PSC girder.

First, as shown in FIG. 4a, the factory manufactures the segmented concrete structure 300 in advance, which can be seen that it is manufactured in three pieces, which can be seen that two places of connection are generated.

Accordingly, it can be seen that the tensile shear keys 100 and 200 to which the compression and tensile resistance steel 400 are connected are formed on the connection end surfaces of the adjacent segmented concrete structures 300, respectively.

The segmented concrete structure 300 having such compression and tensile shear keys 100 and 200, respectively, is transported from the factory to the site and set to be adjacent to the floor.

Next, epoxy is applied to each connection end surface, and each segmented concrete structure 300 is bonded to each other using a lifting device not shown.

Accordingly, the male tensile shear key and the female tensile shear key of the tensile shear key 100 are bonded to each other, and the male tensile shear key and the female tensile shear key of the compression shear key 200 are bonded to each other, so that each segmented concrete structure 300 is bonded.

At this time, the connection end surface is compressed using the crimping jack 600 so that the epoxy is cured. When inserted into the male tension and compression shear key inside the female tensile shear key and the female compression shear key, the epoxy is injected after the injection of the epoxy by the amount of voids first, thereby eliminating the voids and air in the interior, thereby achieving integrity and corrosion resistance of the shear key.

The compression jack 600 is installed to face each other in the left and right symmetrical C-shaped jack support 610 on the surface via the connection portion of the adjacent segmented concrete structure 300, but both legs 611 of the C-shaped jack support Is to be fixed to the adjacent segmented concrete structure 300.

When the jacks are installed between the vertical portions 612 between the two leg portions 611 of the c-jack support 610 facing each other to extend the jack, the segmented concrete structures 300 adjacent to each other are the c-jack support 610. ) To be pressed against each other.

Next, as described above, the male tensile shear key of the tensile shear key 100 is constrained to the female tensile shear key by using the drawing resistance bolt 130.

Next, a compression prestress is introduced in the longitudinal direction using a tension member installed inside the entire adjacent segmented concrete structure 300 to connect each other.

The tension member (PS strand) may be installed in a manner of fixing the two ends to both end surfaces of the segmented concrete structure 300 by inserting them into a sheath arranged in advance when fabricating each adjacent segmented concrete structure 300.

[Manufacturing method of the segmented concrete structure according to Example 2]

Looking at the basis of Figure 4b,

Also, first, a plurality of segmented concrete structures 300 are manufactured and connected to each other to produce one concrete structure Q. Such a concrete structure Q is a PSC girder.

First, as shown in FIG. 4b, the factory is manufacturing the segmented concrete structure 300 in advance, but it can be seen that the three pieces are manufactured, but two connection parts are generated.

Accordingly, it can be seen that the compression shear keys 200 described above are formed on the connection end surfaces of the adjacent segmented concrete structures 300, respectively.

Segmented concrete structures 300, each of which the compression shear key 200 is formed is transported from the factory to the site and set to be adjacent to the floor.

Next, epoxy is applied to each connection end surface, and each segmented concrete structure 300 is bonded to each other using a lifting device not shown.

Accordingly, the male tensile shear key and the female tensile shear key of the compression shear key 100 are bonded to each other, and each segmented concrete structure 300 is bonded.

At this time, the epoxy is cured in a state in which the connection end surface is compressed by using the C-shaped jack support 610 and the crimping jack 600.

Next, as shown in FIG. 4B, compression prestresses are introduced in the longitudinal direction to connect each other by using a tension member installed inside the entire adjacent segmented concrete structure 300.

The tension member (PS strand) may also be installed in a manner of fixing the two ends to both end surfaces of the segmented concrete structure 300 by inserting the sheath pre-arranged at the time of manufacturing each adjacent segmented concrete structure 300.

PSC girder, which is a concrete structure (Q) according to the present invention manufactured as described above, may be installed between shifts and piers to construct a slab to complete the bridge.

That is, it can be seen that the PSC segment made of the segmented concrete structure 300 in advance in the factory to be connected to each other in the field and mounted integrally between the alternating and pier constructions.

Furthermore, the concrete structure Q may be naturally applied to a structure such as a box section in addition to the PSC girder of the I-type cross section.

[Manufacturing method of the segmented concrete structure according to Example 3]

Referring to FIG. 4C, in the case of the third embodiment, the tensile resistance steel 400 is connected to the coupler 700 instead of the tensile resistance key 100 as a modification of the first and second embodiments, and the compression resistance key 200 is used. This is an example of using.

This also produces a plurality of segmented concrete structure 300 is connected to each other to produce one concrete structure (Q), this concrete structure (Q) is the case of a PSC girder.

First, as shown in FIG. 4c, the factory is manufacturing the segmented concrete structure 300 in advance, and it can be seen that the production is made of three pieces.

Accordingly, it can be seen that the compression shear keys 200 described above are formed on the connection end surfaces of the adjacent segmented concrete structures 300, respectively.

Segmented concrete structures 300, each of which the compression shear key 200 is formed is transported from the factory to the site and set to be adjacent to the floor.

Next, epoxy is applied to each connection end surface, and each segmented concrete structure 300 is bonded to each other using a lifting device not shown.

Accordingly, the male tensile shear key and the female tensile shear key of the compression shear key 100 are bonded to each other, and each segmented concrete structure 300 is bonded.

In this case, the epoxy is hardened in a state where the connection end surface is compressed by using the C-shaped jack support 610 and the crimping jack.

Furthermore, the tensile resistance steels 400 installed on the segmented concrete structure are connected to each other using the coupler 700 installed on the connection end surface.

Next, as shown in FIG. 4C, compression prestresses are introduced in the longitudinal direction to connect each other by using a tension member installed inside the entire adjacent segmented concrete structure 300.

The tension member (PS strand) may also be installed in a manner of fixing the two ends to both end surfaces of the segmented concrete structure 300 by inserting the sheath pre-arranged at the time of manufacturing each adjacent segmented concrete structure 300.

PSC girder, which is a concrete structure (Q) according to the present invention manufactured as described above, may be installed between shifts and piers to construct a slab to complete the bridge.

That is, it can be seen that the PSC segment made of the segmented concrete structure 300 in advance in the factory to be connected to each other in the field and mounted integrally between the alternating and pier constructions.

Furthermore, the concrete structure Q may be naturally applied to a structure such as a box section in addition to the PSC girder of the I-type cross section.

The foregoing description of the present invention is intended for illustration, and it will be understood by those skilled in the art that the present invention may be easily modified in other specific forms without changing the technical spirit or essential features of the present invention. will be. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is shown by the following claims rather than the above description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. One

100: tensile shear key
100a: female tensile shear key
110a: fixed part
111a: expansion flange 112a: fixed body
120a: hollow body
100b: male tensile shear key
110b: fixed part
111b: expansion flange 112b: fixed body
120b: insertion hole
130: drawing resistance bolt
200: compression shear key
200a: female compression shear key
210a: fixing part
211a: expansion flange portion 212a: fixed body portion
220a: hollow body
200b: male compression shear key 210b: fixed part
211b: expansion flange portion 212b: fixed body portion
220b: insertion hole
300: segmented concrete structure
400: tensile resistance steel 500: compression resistance steel
510: expansion head 600: compression jack
S1: Fastening hole
S2: Insertion Hole
S3: Through Hole
S4: Jamming through hole Q: Concrete structure

Claims (8)

delete delete delete delete Prepare a plurality of precast member segmented concrete structure 300,
The prepared segmented concrete structure 300 includes a step of manufacturing by pressing the connection to each other with a tension material,
Compression shear acts to install the compression shear key 200 on the connection end surface of the segmented concrete structure 300 to be bonded to each other,
The compression shear key 200 is respectively installed as a female compression shear key 200a and a male compression shear key 200b which are installed to be exposed to the connection end surface of an adjacent segmented concrete structure, and the male compression shear key is inserted into the female compression shear key segment. Type concrete structures to be joined together,
The female compression shear key 200a may include a fixing part 201a to which the compressive resistance steel 500 is fastened to one side; And a hollow body part 220a having an insertion hole S2 formed in the longitudinal direction in succession with the fixing part, and the male compression shear key 200b is fastened to one side of the compressive resistance steel 500. Fixing part 210b; And an insertion hole 220b having a rod shape formed in succession with the fixing portion; Male compression shear key (200b) is inserted into and supported,
In the step of manufacturing by pressing the segmented concrete structure 300 by pressing the tension material with each other, the pressing is using a pressing jack 600,
The crimping jack 600 is installed so as to face each other in a left-right symmetrical C-shaped jack support 610 on the surface to pass through the connecting portions of the adjacent segmented concrete structure 300, both legs 611 of the U-shaped jack support Is fixed to the adjacent segmented concrete structure 300,
When the jacks are stretched by installing jacks between the vertical portions 612 between the two legs 611 of the c-jack support 610 facing each other, the segmented concrete structure 300 adjacent to each other is the c-jack support 610. Concrete structure manufacturing method using a tensile shear key or a compression shear key, characterized in that to be compressed to each other by). 6. The method of claim 5,
By further installing a tensile shear key 100 on the connection end surface of the segmented concrete structure 300 to be bonded to each other,
The tensile shear key 100 is
The female tensile shear key 100a and the male tensile shear key 100b respectively installed to be exposed to the connection end surface of the adjacent segmented concrete structure are installed so that the male tensile shear key is inserted into the female tensile shear key so that the segmented concrete structures are joined to each other. ,
The female tensile shear key (100a) is a fixed portion (110a) to which the tensile resistance steel 400 is fastened to one side; And a hollow body part (120a) having an insertion hole (S2) formed in the longitudinal direction in succession with the fixing part. Government 110b; And a rod-shaped insertion hole 120b in which a hooking hole S4 is formed in succession with the fixing part. Fabrication of a concrete structure using a tensile shear key or a compression shear key, characterized in that the male tensile shear key (100b) inserted into the female tensile shear key (100a) is caught and restrained by the pull resistance bolt 130 penetrating the hole (S4) Way. 6. The method of claim 5,
The adjacent segmented concrete structure is further provided with a tensile resistance steel 400 and a coupler 700,
The tensile resistance steel 400 is a concrete structure manufacturing method using a tensile shear key or a compression shear key, characterized in that to be connected by a coupler in the block-out space 710 formed on the connection end surface. delete

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