KR101010540B1 - Half-precast coping construction method - Google Patents

Abstract

The present invention relates to a method for constructing a half precast coping part, in which a coping part is manufactured in a factory in advance in a column structure, and the coping part is installed on an upper part of the column structure, so that the coping part construction can be completed by concrete pouring. The body of the columnar structure relates to a method for constructing a columnar structure to be constructed in a simple stacking manner using a precast column unit.

Precast, Column Structure, Coping Part

Description

Half precast coping part construction method {HALF-PRECAST COPING CONSTRUCTION METHOD}

The present invention relates to a half precast coping part construction method. More specifically, in constructing a column structure such as a bridge constituting the bridge substructure, the coping part, which is the upper end of the column structure, is manufactured in a precast manner, but the coping part itself is manufactured at the factory, and the coping part reinforcing assembly and finishing disposed therein. Concrete relates to the construction method of the half precast coping part to be constructed in the field.

FIG. 1A illustrates a state diagram in which a pier structure is laminated in a conventional precast method (Korean Patent No. 549649).

That is, the pillar structure 10 is first constructed, and the precast reinforced concrete unit 20 is laminated on the upper part, but the steel wire through-hole 21 is formed in the precast reinforced concrete unit, to the final height After stacking the precast reinforced concrete unit 20 up and down

The steel wire 30 is inserted into the steel wire through hole 21, but the tip end is fixed to the lower part of the column structure, the upper end is fixed to the cover plate and settled, the pier that the precast reinforced concrete unit 20 is pressed together Structure construction method is disclosed.

This method may be an effective method for compressing the precast reinforced concrete unit 20 up and down, but since the tension material (steel wire, 30) such as steel wire must be used, the tension material and fixing work are required, and the workability and economic efficiency are required. There was a problem that this must fall.

Therefore, when the pier structure is constructed by stacking the precast reinforced concrete unit without crimping it, its workability is excellent, but it is difficult to secure the safety of the structure because the connection or coupling performance of the precast reinforced concrete unit may be degraded. there was.

FIG. 1B illustrates a coping part reinforcing assembly 70 installed at the top of a precast reinforcement concrete unit, in which the coping part reinforcing assembly 70 is composed of a coping part reinforcing bar 71 and a lower reinforcing bar 72. , This coping rebar assembly 70 is manufactured separately in the field.

Accordingly, as shown in FIGS. 1C and 1D, the coping part reinforcing assembly 70 is connected to each other using a coupler 81 to the column pier reinforcing bar 80 protruding from the top of the precast reinforced concrete unit, and the concrete to the coping part formwork. The final coping part 90 will be constructed by pouring the (Korean Patent No. 547591).

However, the coping part 90 is installed only by pre-coupling reinforcing bar assembly 70 only to install the coping part formwork on the top of the precast reinforced concrete unit in the field, and it is inevitable that the work to pour concrete It could be somewhat disadvantageous in terms of economics.

Of course, the coping part 90 may be manufactured and constructed in a precast manner, but when the coping part 90 is large in size, the coping part 90 has a large weight as a reinforced concrete member and requires a large vehicle for its transportation. It might have been limited.

Figure 1e shows a sleeve (40, Republic of Korea Patent 616531) for the connection of the deformed reinforcing bar related to the present invention.

The sleeve inserts the deformed steel bar 50 into the hollow sleeve through the inclined surface attachment reinforcement insertion hole 41 formed at the end of the sleeve, and then mortar 60 into the empty space S formed in the deformed steel bar and the sleeve body. As a reinforcing bar connection device connecting two deformed bars by filling and hardening

One end of the deformed rebar is fastened to the inclined surface attachment reinforcement 51 having an outer diameter larger than the outer diameter of the deformed rebar,

The sleeve 40 has an inclined surface attachment reinforcement insertion opening 41 which is open in the longitudinal direction,

The mortar outlet 42 and the mortar inlet 43 formed at both ends of the sleeve are formed, and the mortar-filled reinforcing bar connection device is characterized in that the sleeve and the inclined surface attachment reinforcement are formed in pairs.

These sleeves have a load on the deformed bar

By attaching the inclined surface attachment reinforcement 51 having an outer diameter larger than the outer diameter of the deformed rebar to the end of the deformed rebar, when a direct pull fracture occurs, a reliable reinforcing bar joint device capable of withstanding any tensile force can be realized.

By forming a plurality of annular protrusions projecting in the circumferential direction on the inner wall of the sleeve, there is an advantage that the fracture crack prevents the propagation along the inner wall of the sleeve and thus no breakage occurs.

In addition, the inclined surface reinforcement insertion hole of the sleeve is provided with an annular projection protruding more protruding than the annular projection, so that the fracture crack propagating through the annular projection is no longer exposed to the outside so that the split fracture occurs completely. Prevent,

A first inclined surface is formed at the end of the sleeve coupled to the deformed reinforcement, and a second inclined surface corresponding to the inclined surface is formed in the inclined attachment port of the sleeve so that the edge of the deformed rebar is inserted into the sleeve. The advantage of being able to enter the inside of the sleeve naturally along the inclined surface even if it hits the sleeve,

Since the sleeve 40 can be filled with mortar by the mortar outlet and the mortar inlet, it is almost impossible to use such a sleeve while stacking a precast reinforced concrete unit for pillar construction such as a pier. There was this.

Accordingly, the present invention overcomes the usability limitations in the construction of the coping part by allowing the coping part having a large size and weight to be manufactured and constructed in a half-precast manner in a column structure such as a pier.

Precast column units, such as precast reinforced concrete units, can be stacked to ensure column construction and economic feasibility.

It is a technical object of the present invention to provide a method of constructing a half precast coping part capable of securing the joint performance between the precast pillar units and also securing the safety of the column structure.

The present invention to achieve the above technical problem

First, in manufacturing the coping portion of the columnar structure, the precast coping portion in which the inner hollow portion blocked out is formed in the trunk portion 310 and the pier insertion portion 320 formed by blocking out the bottom thereof is formed ( 300),

The precast coping part 300 is installed on the top of the column structure, and the coping part may be constructed by placing the coping part concrete in the inner hollow so that the coping part may be constructed in a half precast manner.

Second, when installing the precast coping portion in the column structure, it extends downward from the inside of the pier insertion portion 320 formed on the bottom of the precast coping portion, that is, extending from the trunk portion 310 into the pier insertion portion 320 Rebar 330 having the reinforcing insertion hole 331 formed at the lower end thereof is inserted into the hollow sleeve 140 embedded in the upper surface of the column structure such that the precast coping part is installed on the upper surface of the column structure.

In addition, by lifting the pre-assembled coping part reinforcement assembly in the vicinity of the site so that the coping part reinforcement assembly is installed in the inner hollow portion of the body portion, so as to be integrally connected with the reinforcing bars reinforced to the trunk portion of the inner hollow portion.

Next, the construction of the coping part was completed by pouring the coping part concrete into the trunk part constituting the final coping part connected to each other.

Third, the hollow sleeve 140 is installed on the upper end of the column structure cast iron (connecting material of the uppermost precast pillar unit), and the mortar 150 is filled in the hollow sleeve 140, the pier insert portion 320 Extending downward from the inside, the reinforcing insertion hole 331 of the reinforcing bar 330 is inserted into the hollow sleeve 140 while the mortar is hardened so that the pillar structure and the coping portion can be directly connected to each other integrally.

Fourth, the column structure is constructed by stacking the respective precast column unit 100, but to be installed by burying the connection member 120 to serve as a reinforcing bar in the precast column unit, the mortar is filled in the connecting material By simply inserting the hollow sleeve 140, the precast pillar units were combined with each other to be constructed.

Fifth, the precast column unit 100 is to be constructed by the sleeve 210 and the connection member 120 in the lower column structure 200.

Sixth, the hollow sleeve 140 and the sleeve 210 is inserted into the connecting member 120 to be integrally coupled when the mortar 150 is hardened, but can ensure very strong resistance to direct pull fracture, split fracture and fracture cracking It is very advantageous for the safety of the column structure, and the construction can be completed simply by inserting each connecting member into each sleeve.

According to the present invention, the coping part of the columnar structure is constructed in a half precast manner, and the body of the pillar structure is secured to each other by simply inserting a connecting material into the mortar-filled sleeve using a precast pillar unit. In addition, the construction is very excellent and the pillar structure can be safely and economically constructed in the shortest time.

In particular, in the construction of the coping portion of the column structure in the connection construction of the reinforcing bar assembly and the main reinforcing bar of the column structure can ensure the construction properties and safety can be more efficient column structure coping portion construction.

An embodiment of the present invention described above and shown in the drawings should not be construed as limiting the technical idea of the present invention. The protection scope of the present invention is limited only by the matters described in the claims, and those skilled in the art can change and change the technical idea of the present invention in various forms. Accordingly, such improvements and modifications are within the scope of the present invention as long as they are obvious to those skilled in the art.

BRIEF DESCRIPTION OF THE DRAWINGS In order to describe the present invention more clearly and easily, the following describes the best embodiments of the present invention in detail with reference to the accompanying drawings. Is not limited to the embodiments described below.

2 first shows a precast coping unit 300 according to the present invention.

First, the precast coping part 300 may be divided into a body part 310 and a pier insertion part 320.

The body part 310 is a precast reinforced concrete structure having an inner coping part shape (eg, a trapezoidal cross-sectional shape) but having an inner hollow part S2 so that the inside thereof is emptied.

The pier insertion portion 320 formed by blocking the upper portion of the uppermost precast pillar unit 100a, which will be described later, is inserted into the bottom surface of the central lower portion thereof.

Accordingly, the precast coping part 300 is very advantageous in transportation and construction because its weight is not large so that the inside of the precast coping part 300 is later. The coping part concrete 500 is cured after pouring so that the final coping part may be completed.

3a to 3f schematically illustrate the construction of the column structure in order to combine the precast column unit 100 including the uppermost precast column unit (100a) of the present invention up and down with each other in order.

First, as shown in Figure 3a, the columnar structure 200 is constructed on the ground (D). According to Figure 3a it can be seen that the column structure made of reinforced concrete in the form of a rectangular parallelepiped 200 is being constructed, the upper surface is to be coupled to the precast column unit 100 in the form of a hollow circular tube have.

In particular, a method such as FIG. 5A is possible to couple the precast column unit 100 and the column structure lower portion 200.

That is, a blockout part S is formed on the upper surface of the columnar structure 200 so that the precast column unit 100 may be stably initially mounted, and the sleeve 210 is formed on the blockout part S. Let landfill.

The sleeve 210 is installed to be exposed to the upper surface of the block-out part (S) according to the installation position and the number of the connection member 120 to be described later.

In the case of Figure 5a it can be seen that two rows of sleeves 210 are installed in a circular shape, one end (bottom, reinforcement) of the connecting member 120 of the precast column unit 100 to be described later in each of the sleeves 210 Insertion portion and a connector portion projecting from the body end face) are inserted.

The sleeve 210 is closed at its lower end (one end), and at its upper end (the other end), an annular protrusion is formed on the inner side thereof, and a taper is formed at the beginning of the upper end to open the hollow member. The reason for having this shape is that the sleeve 210 is coupled only to the precast column unit 100 coupled from above.

In addition, the mortar 150 is filled in the sleeve 210.

Thus, the reinforcement insertion hole 130 constituting the connecting member 120 of the precast column unit 100 is inserted into the sleeve 210 and the mortar 150 is cured while the precast column is lowered in the final column structure 200. The unit 100 can be combined.

As such, in the present invention, it can be seen that the precast column unit 100 can be easily coupled to the upper surface of the column structure simply by inserting the connecting member 120 into the sleeve 210.

In addition, since the structurally secure coupling can be secured by the reinforcement insertion hole 130 of the connecting member 120 of the sleeve 210 and the precast lifting unit 100 to be described later, the construction property is excellent in construction and thus It can be seen that economic pillar construction is possible.

The precast pillar unit 100 constitutes a body of a column structure which is generally divided into a column structure lower portion, a body, and a coping portion, and is basically made of a reinforced concrete member.

The precast pillar unit 100 will be referred to as a precast product in the sense that its height and thickness are determined in advance in a factory.

In addition, the precast column unit 100 may be made of a reinforced concrete member in the form of a hollow tube and may be made of a reinforced concrete member of the form filled with a closed chamber inside the present invention will be described based on the reinforced concrete member of the hollow tube form. .

In the present invention, such a precast pillar unit 100 is largely divided into a body portion 110 and a connecting member 120 as shown in FIG.

The body part 110 is to constitute a body made of a reinforced concrete member of the column structure, it may be formed in a circular or square cross-section according to the body cross-sectional shape of the column structure, the inside of the main reinforcement in the vertical direction It will be produced as possible. At this time, the main reinforcing bars will usually use a deformed reinforcing bar.

In the present invention, such a main reinforcing bar basically has the role of a connecting member for coupling the precast column unit 100 to each other while functioning as a reinforcement bar of the precast column unit (100).

Accordingly, the cast iron is referred to as a connecting member 120 in the present invention.

Therefore, the connecting member 120 is installed so as to be embedded in the body portion, such as cast iron, so that the end is formed so as to protrude through the body portion to have the function of the connecting material on the body end surface.

Accordingly, one end of the connecting member 120 protrudes from one end surface (lower end surface in the case of FIG. 5B) of the end portion of the body so that the reinforcing insertion hole 130 larger than the outer diameter of the connecting member 120 is formed at the tip thereof.

Although described later, the reinforcement insertion hole 130 is inserted into the hollow sleeve 140 of another precast column unit 100 and set to be fixed to the hollow sleeve 140 by hardening the mortar 150 filled in the hollow sleeve 140. do.

The reinforcement insertion hole 130 is a stopper shape larger than the outer diameter of the main reinforcing bar can be made of steel of the same material as the main reinforcing bar, it is preferable to form a groove formed in the middle portion to sufficiently resist the pullout force.

In addition, the front end portion of the tapered portion is formed to prevent the edges from being broken when inserted into the insertion portion 142 formed at the beginning of the hollow sleeve 140 and to be inserted while sliding in the initial installation in the hollow sleeve 140.

The reinforcement insertion hole 130 may be formed in a manner that is welded to one end of the connecting member, it may be produced integrally when manufacturing the connecting member 120.

The hollow sleeve 140 is formed at the other end of the connecting member 120.

At this time, one end of the hollow sleeve 140 is connected to the other end of the connecting member 120, the other end of the hollow sleeve 140 is set to open in accordance with the other end surface of the body (lamination).

The hollow sleeve 140 is one end of the fastening portion 141, the female screw portion is formed on the inner surface; And an inserting portion 142 having a larger outer diameter than the fastening portion integrally with the fastening portion, but an annular protrusion 143 is formed on the inner side of the inserting portion 142 and the end surface thereof is opened. The mortar 150 is filled in the insertion portion 142. (Same as the insertion portion of the sleeve 210.)

In the case of the insertion portion 142, as described above, the tapered portion inclined inward is formed at the initial insertion so that the reinforcement insertion hole 130 of the connection member can be easily inserted.

The annular protrusion 143 has a function of preventing the fracture crack from progressing along the inner wall of the hollow sleeve and thus preventing breakage when a load such as a pulling force is applied to the connecting member to be inserted.

Thus, the other end portion of the connecting member 120 may be formed with a male screw portion to be connected to each other by being fastened to the female screw portion formed on the inner side of the fastening portion 141 of the hollow sleeve 140.

As a result, the connecting member 120 protrudes from one end surface (lower end surface) of the trunk portion (lamination) to expose the reinforcement insertion hole 130, and a hollow sleeve (upper end surface) on the other end surface (upper end surface) of the trunk portion (lamination). It can be seen that the insertion portion 142 of the 140 is set to be open and exposed.

According to Figure 5b it can be seen that the connecting member 120 has a function of the reinforcing bar by allowing a plurality of rows in the second peripheral line on the outer peripheral surface of the body portion (lamination) to be installed.

The precast pillar unit 100 composed of such a body part (lamination) and the connecting member 120 is constructed to be laminated while being coupled to each other up and down, and simply a hollow sleeve filled with the mortar 150 of the precast pillar unit 100. The connecting member 120 of the other precast pillar unit 100 is inserted into the 140 to allow the mortar 150 to harden and to be structurally securely coupled to each other.

When the first precast pillar unit 100 described above is installed in the lower pillar structure 200 as described above, the precast pillar unit 100 is further coupled to the precast pillar unit 100.

This coupling is as shown in Figure 5c by inserting the connection member 120 of the upper and lower precast pillar unit 100 into the hollow sleeve 140 filled with mortar 150, the two precast pillar unit 100 to each other It can be seen that it can be combined.

When the precast column unit 100 is laminated by stacking the precast column unit 100 by assembling the precast column unit 100 as the height of the planned column structure as described above, the precast column unit 100a which will be described later on the top is installed as shown in FIG. 3A. .

Unlike the precast pillar unit 100 described above, the uppermost precast pillar unit 100a allows the connecting member 120, which is the main reinforcing bar, to protrude upward and extends to the other end thereof (upper), and to the upper portion of the connecting member 120. The hollow sleeve 140 described above is formed, and the mortar 150 is filled in the hollow sleeve 140.

As described later, in the case of the uppermost precast pillar unit 100a, the connecting member 120 as the main reinforcing bar is inserted into the precast coping part 300 and installed to be connected to the lower reinforcing bar of the coping part reinforcing assembly 400. To do this.

Next, as shown in FIGS. 3b and 3c, the precast coping part 300 shown in FIG. 2 is lifted and installed in the top precast pillar unit 100a.

Accordingly, it can be seen that the reinforcing bars 330 of the pier insertion part 320 of the precast coping part 300 are inserted into the hollow sleeve 140 of the uppermost precast column unit 100a to be combined and integrated with each other.

Next, as shown in FIG. 3d, the coping part reinforcing assembly 400 is lifted so as to be installed in the inner hollow part S2 of the precast coping part 300.

4 shows the coping part reinforcing assembly 400 separately.

The coping part reinforcing assembly 400 may be referred to as a reinforcing bar assembly required because the coping part is a reinforced concrete member, and manufactured in the shape of the precast coping part 300.

The coping part reinforcing assembly 400 is formed with a lower reinforcing bar 410 protruding downward to be connected to the reinforcing bars inside the body portion of the coping part.

That is, as shown in FIGS. 3e and 3f, the reinforcing insertion hole of the pier insert 320 is formed at the tip of the hollow sleeve 140 filled with the mortar 150 of the top frets column unit 100a of the column structure. 330 is inserted to directly connect the coping portion to the columnar structure.

In particular, according to FIG. 3f, it can be seen that the coping part concrete 500 is poured into and finished inside the final precast coping part 300, and it can be seen that the concrete 600 can be filled in the column structure. .

Furthermore, when connecting the reinforcing bars 330 of the pier insertion portion 320 and the main reinforcing bars of the columnar structure, as shown in Figure 1c, may be connected to each other using a conventional coupler. That is, after forming the male thread portion without forming a hollow sleeve on the upper end of the cast iron protruding from the top of the column structure, and also formed the male thread portion on the reinforcing bar 330, using a conventional coupler for connecting the reinforcing bar formed with a female thread on the inner surface You can connect them directly.

Figure 1a shows a construction state diagram of a bridge structure of the conventional precast method.

Figure 1b shows a conventional coping rebar assembly.

FIG. 1C illustrates a method of connecting a main reinforcing bar assembly and a main reinforcing bar of a column structure using a coupler.

1B illustrates a conventional sleeve.

2 illustrates a precast coping unit according to the present invention.

3a, 3b, 3c, 3d, 3e and 3f is a schematic view showing the construction of the column structure using the precast coping part, precast column units according to the present invention in a schematic order.

Figure 4 shows the coping rebar assembly according to the present invention.

Figures 5a, 5b and 5c shows the construction state of the column structure lower portion and the precast column unit according to the present invention.

<Description of the symbols for the main parts of the drawings>

100: precast column unit

110: body 120: connecting material

130: insertion reinforcement 140: hollow sleeve

150: mortar 200: lower pillar structure

300: Precast coping part 310: The trunk part of the precast coping part

320: pier insert 400: coping reinforcing bar assembly

410: bottom reinforcement 500: coping part concrete

Claims (6)

In the method of constructing the precast coping part 300 is installed on the top of the columnar structure, Forming a hollow sleeve 140 on the top of the connecting member 120 which is the main reinforcing bar of the upper pillar structure so that the hollow sleeve is filled with mortar, but exposed to the outside; An inner hollow part S2 which blocks out to allow the coping part reinforcing assembly 400 to be installed is formed inside the body part 310, and the pier insertion part 320 formed by blocking out the bottom of the body part 310. Forming a precast coping part 300 having a reinforcing bar 330 extending from the body part 310 to the pier insertion part 320 to be inserted into the hollow sleeve 140; Inserting the reinforcing bar 330 into the hollow sleeve 140 to install the precast coping part 300 on an uppermost column structure; Connecting the coping part reinforcing bar assembly to the inner part of the inner hollow body with the inner part of the body part; And Half precast coping part construction method comprising the step of finishing by pouring the coping part concrete 500 in the inner hollow. The method according to claim 1, wherein the coping reinforcing bar assembly 400 is to lift the pre-assembled reinforcing bar assembly in advance, so that the lower reinforcing bar (410) is connected to the inner reinforcing bar portion. According to claim 1 or 2, The hollow sleeve 140 is one end of the fastening portion 141, the female screw portion is formed on the inner surface; And an insertion part 142 having an outer diameter greater than that of the fastening part integrally with the fastening part, but having an annular protrusion formed on the inner side of the inserting part, the end surface of which is formed to open. According to claim 3, wherein the top columnar structure And a connecting member including a reinforcing bar embedded in the body portion and installed to penetrate the body end surface as a body part and a cast iron, and one end of the connecting material is formed from one end surface (lower end) of the body end surface. A protruding reinforcement opening larger than the outer diameter of the connecting member is formed at the tip thereof, The other end of the connecting member is a half precast coping unit construction method using a protruding from the other end surface (top) of the body portion made of a precast pillar unit (100a) with a hollow sleeve formed at its tip. The column structure of claim 4, wherein the column structure connected to the bottom of the uppermost column structure The lower end is closed and the inner surface is formed with an annular projection, the upper surface is a hollow member formed to open, the upper surface at the beginning of the tapered portion formed to be inclined inward so that a plurality of sleeves are installed on the upper surface, but the open end surface Installing a lower column structure manufactured to be exposed to the outside; Filling mortar into the sleeve; And And a connecting member including a reinforcing body embedded in the body and the body and penetrating the body end surface, wherein one end of the connecting member protrudes from one end surface of the body end surface and has an outer diameter of the connecting material. A larger insertion reinforcing hole is formed at the tip thereof, and the other end of the connecting member is formed with a hollow sleeve having no mortar inlet and an outlet opening, but one end of the hollow sleeve is connected to the other end of the connecting member, and the hollow Comprising the step of the other end of the sleeve is coupled to the lower portion of the column structure precast column unit made to open to the other end of the body end surface, A half precast coping part construction method is constructed so that one end of the connecting member constituting the precast pillar unit is inserted into the mortar-filled sleeve so that the mortar is cured and the precast pillar unit is coupled to the lower part of the column structure. . The method of claim 5, wherein the precast column unit is a plurality of stacked to be installed below the top precast column unit, the laminated precast column unit is Filling mortar into a hollow sleeve of a precast column unit located below; And repeating the step of allowing one end of the connection member of the other precast pillar unit to be inserted into the hollow sleeve filled with the mortar. The construction method of the half precast coping unit for the precast pillar unit and the other precast pillar unit located on the bottom while the mortar is hardened to be stacked up and down each other.

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