KR102071825B1 - Precast concrete staircase frame construction method of core type - Google Patents

Abstract

The present invention provides a construction method for a core type PC staircase frame, capable of obtaining structural earthquake-proof stability of a joint unit between PC members while performing rapid construction and the reduction of construction periods for a core type staircase frame. According to the appropriate embodiment of the present invention, the construction method for a core type PC staircase frame comprises: a PC column installed at a corner; one or more PC walls installed between the PC columns adjacent; a PC beam supported on the PC column and installed in the upper part of the PC wall; a PC stair landing installed at different heights on the PC wall facing the PC stair landing; and PC stairs connected to the upper and lower PC stair landings alternate when closely facing each other. An insert having a screw hole is installed at a predetermined position along one side of the PC column at a part in which the PC column and the PC wall are in contact with each other. An insert connection iron embedded in the same height as that of the insert is embedded in the PC wall. After the connection iron and the insert are coupled by a coupling bolt inserted through a coupling pocket formed in the part in which the insert connection iron is embedded, non-shrinkage mortar is constructed by being filled in the coupling pocket. The insert having the screw hole is installed at each predetermined position along one side in the part in which the neighboring PC walls are in contact with each other. The insert connection wire embedded in the same height as that of the insert is embedded along the other side. An insert coupling bolt is installed by the coupling pocket formed in the part in which the insert connection iron is embedded. So, after the connection iron and the insert are coupled, the non-shrinkage mortar is filled in the coupling pocket so that the core type PC staircase frame is constructed.

Description

Precast concrete staircase frame construction method of core type}

The present invention relates to a method for constructing a core staircase frame, particularly to a method for constructing a core PC staircase frame structure, which is intended to shorten the air and rapid construction of the core type staircase frame structure and to secure structural seismic safety of joints between PC members. It is about.

As the seismic performance standards of buildings have recently been strengthened, existing precast concrete wall members have increased amount of vertical and horizontal bars. Accordingly, it is difficult to secure seismic splice details because it is difficult to continually reinforce the reinforcing bars by joining one by one when reinforcing the site.

In particular, the core (staircase, elevator shaft) part shall be provided with a lateral force resistance system which must be intensively resisted against earthquake loads. However, in order to precast concrete (PC), the seismic performance of the joint cannot be secured, and the core wall part was constructed by the existing cast-in-place concrete method. Therefore, the difficulty of shortening the air, which is an advantage of the PC method, was inevitable. For example, when the PC staircase and landing in the staircase room is installed by placing a bracket on the wall there is a problem that the PC volume is increased, the difficulty of producing the member is increased.

Therefore, there is a need for a construction method of core PC staircase frames that avoids the continuity of reinforcing bars, which makes it difficult to secure the details of seismic bonding, enables seismic performance of PC members, and shortens the air by easily joining the PC members. do.

As a background technology of the present invention, Korean Patent Registration No. 10-0628537 has been proposed, 'precast concrete structural wall system capable of securing seismic performance'. It is made of a PC and a plurality of PC unit walls are assembled and installed as a structural wall; A splice sleeve embedded in the PC unit wall; A vertical reinforcing bar which is bound to the splice sleeve and connects the PC unit walls in a vertical direction; High strength mortar for bonding between the PC unit wall; And a lower reinforcement stiffener installed at both lower ends of the PC unit wall installed at the lowermost end to fix the PC unit wall perpendicular to the base surface. However, the background art has a limitation in shortening the air in the field due to the bonding process between the PC unit wall through the high-strength mortar and the installation work of connecting the vertical reinforcing bars.

Korea Patent Registration No. 10-0628537

It is an object of the present invention to provide a construction method of a core PC staircase frame, which is intended to shorten the air and rapid construction of the core-type staircase frame, and to ensure structural seismic safety of the joints between the PC members.

According to a preferred embodiment of the present invention, a method of constructing a core PC staircase frame structure includes a PC pillar disposed at an edge, at least one PC wall disposed between neighboring PC pillars, and a PC pillar supported on the PC pillar. In the construction method of the core PC staircase framing, which is constructed with the PC beams, the PC landings arranged at different heights on the opposite PC wall sides, and the PC stairs contacting the upper and lower PC landings facing each other. In the part where the pillar and the PC wall contact each other, an insert having a screw hole is installed at every predetermined position along one side of the PC pillar, and the insert connecting hardware embedded at the same height as the insert is embedded in the PC wall. After the connecting hardware and the insert are fastened with the insert fastening bolt inserted through the fastening pocket formed in the buried part, the fastening pocket is filled with non-shrink mortar. Become; In the part where neighboring PC walls come into contact, inserts having screw holes are installed at predetermined positions along one side thereof, and insert connecting hardware embedded at the same height as the inserts is embedded along the other side, and the insert connection Insert fastening bolt is positioned through the fastening pocket formed in the part where the hardware is buried, the connection hardware and the insert is fastened, the fastening pocket is characterized in that the non-shrink mortar is filled.

In addition, the insert connecting hardware is made of a steel plate having a predetermined thickness of the iron joint portion having a lifting and insertion bolt insertion hole, bent to be inclined at both ends of the iron joint portion bent in the reinforcement wing and hardware reinforcement wing embedded in precast concrete It is characterized in that the connection hole is formed.

In addition, an insert having a screw hole is provided at a predetermined position along one side of the PC beam at a portion where the PC beam and the PC wall contact each other, and insert connection hardware is embedded in the PC wall at equal intervals from the insert. The insert fastening bolt is positioned through the fastening pocket formed in the part where the hardware is embedded, and then the insert connecting hardware and the insert are fastened, and the non-shrink mortar is filled in the fastening pocket.

In addition, the PC landing is mounted on the wall of the PC by a landing shoe installed in a plurality of at each end; The landing shoe is made of a square steel tube embedded in a PC wall, a fixing reinforcing bar bonded to both sides of the shoe to fix the shoe in precast concrete, and made of a square steel tube inserted into the shoe and protruded from both ends of the PC landing. The core is inserted into the stairway mounting groove of the PC wall and is inserted into the upper surface of the shoe is characterized in that consisting of the core screw is screwed to the core material.

In addition, at least two corner steel pipes for staircases are partially buried at each of the upper and lower ends of the PC stairs, and the protruding portions of the square steel pipes for the staircases are inserted into the pockets for the staircases of the PC landings. The level adjustment bolt is fastened to the square steel pipe and then horizontally adjusted, and the non-shrink mortar is filled in the pocket for the staircase.

According to the construction method of the core PC staircase frame of the present invention, the PC column and the PC wall, the PC beam and the PC wall, and the neighboring PC wall are all connected to each other through the same insert connecting hardware set, so that the joint of the rebar This becomes unnecessary. In the insert connecting hardware set, the insert and the insert connecting hardware are installed and installed, which has the advantage of not causing problems of interference in the construction process. In addition, fastening bolts tighten the insert joints and the inserts strongly to ensure structural safety with seismic joining of the frame.

In addition, PC pillars, PC walls, PC beams, PC landings and PC stairs are all made of precast concrete at the factory and assembled in the field, thereby reducing the air.

In addition, the insert connecting hardware installed on the PC wall can have the advantage of being used as a lifting hook because the hook can be hooked to the lifting and insertion bolt insertion hole.

The following drawings, which are attached in this specification, illustrate the preferred embodiments of the present invention, and together with the detailed description thereof, serve to further understand the technical spirit of the present invention. It should not be construed as limited.
BRIEF DESCRIPTION OF THE DRAWINGS The perspective view of the core-type PC staircase frame | frame of one embodiment of this invention.
2 is a front view showing a state in which a PC column and a PC beam are joined to a PC wall in a core PC staircase frame of one embodiment of the present invention.
Figure 3 is an exploded perspective view of the insert connecting hardware set applied to the core PC staircase frame of Figure 1;
Figure 4 is a state of fastening the insert fastening bolt shown in Figure 2 to the insert through the fastening bolt tool.
5 is a state of lifting the PC wall using the insert connecting hardware shown in FIG.
6 is an installation state diagram between the PC landing and PC stairs in the construction method of the core PC staircase room frame of one embodiment of the present invention.
7 is a perspective view of the PC landing shown in FIG.
8 is an installation state diagram of the PC landing shown in FIG.
Figure 9 is a state diagram before the core material is assembled to the shoe in the PC landing applied to the present invention.
Figure 10 (a), (b) is a perspective view before and after the core material is assembled to the landing shoe applied to the present invention.
Figure 11 is a perspective view of the PC stairs in the core PC staircase framing framework of one embodiment of the present invention and the main portion installation state.
12 is a plan view respectively showing a state that the PC landing and PC stairs applied to the present invention are manufactured and installed integrally with the one installed separately.

In the following the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the embodiments presented are exemplary for a clear understanding of the present invention is not limited thereto.

The core PC staircase frame 10 of one embodiment of the present invention includes one or more PC pillars 11 arranged at the edges and neighboring PC pillars 11 and 11 as shown in FIGS. 1 and 2. PC landings supported by the PC wall 12, the PC column 11 and arranged at different heights on the side of the PC beams 13 disposed on the upper part of the PC wall 12, and facing the PC walls 12 and 12. (14), the construction is composed of PC stairs (15) in contact with the shifted upper and lower PC landings (14 and 14) when facing each other close. In this case, 'PC' means Precast Concrete.

In the part where the PC pillar 11 and the PC wall 12 contact each other, an insert 21 having a screw hole 21a is provided at every predetermined position along one side of the PC pillar 11 as shown in FIG. Insert connection bolt 22 embedded at the same height as the insert 21 is embedded in the PC wall 12, and the insert fastening bolt inserted through the fastening pocket 121 formed in the part where the insert connecting hardware 22 is embedded. After the connection hardware 22 and the insert 21 are fastened to 23, the fastening pocket 121 is filled with non-shrink mortar to be constructed. The fastening bolt 23 may be fastened and manipulated through the bolt fastening tool T as shown in FIG. 4.

Here, the insert 21, the insert connecting hardware 22, the insert fastening bolt 23 will constitute the insert connecting hardware set 20. The insert connecting hardware set 20 may further include a washer 24. The washer 24 is inserted into the insert fastening bolt 23 fastened to the insert 21 is installed.

In addition, as shown in FIG. 2, the neighboring PC walls 12 and 12 may be coupled using the same insert connecting hardware set 20. That is, the insert 21 which has the screw hole 21a is provided in the part which the adjacent PC wall 12 and 12 contact | connects at each predetermined position along one side surface, and the insert 21 along the other side surface. Insert connection hardware 22 is embedded at the same height and embedded, and the insert fastening bolt 23 is positioned through the fastening pocket 121 formed in the embedded portion of the insert connection hardware 22 and the connection hardware 22 and After the insert 21 is fastened, non-shrink mortar is filled in the fastening pocket 121 may be constructed.

As shown in FIG. 3, the insert connecting hardware 22 is made of a steel plate having a predetermined thickness, and is bent at both ends of the hardware joint part 221 and the hardware joint part 221 having a lifting and using bolt insertion hole 221a to precast concrete. The iron reinforcing blade 222 embedded in the PC and the shear connection hole 222a penetrated through the hardware reinforcing blade 222 are formed.

Thus, when the insert connecting hardware 22 is embedded in the PC wall 12, the insert connecting hardware 22 is synthesized in the precast concrete by the shear connection hole (222a) to prevent departure from the PC wall 12 Can be.

Also, as shown in FIG. 2, the PC beam 13 and the PC wall 12 may also be combined using the same insert connecting hardware set 20. That is, in the part where the PC beam 13 and the PC wall 12 contact, the insert 21 which has the screw hole 21a is installed in every position along the one side surface of the PC beam 13, and the PC wall 12 is provided. The insert connecting bolt 22 is embedded at the same interval as the insert 21, and the insert fastening bolt 23 is positioned through the fastening pocket 121 formed at the part where the insert connecting hardware 22 is embedded. After the connecting hardware 22 and the insert 21 are fastened, the fastening pocket 121 is filled with a non-shrink mortar is constructed.

As described above, in the construction method of the core PC staircase frame structure of the present invention, the PC pillar 11 and the PC wall 12, the PC beam 13 and the PC wall 12, and the neighboring PC walls 12 and 12 are all By connecting to each other through the same insert connecting hardware set 20, the joint of the reinforcing bar is unnecessary as in the prior art. In addition, since the insert 21 and the insert connecting hardware 22 are embedded in the insert connecting hardware set 20, there is no problem of interference in the construction process. In addition, the insert fastening bolt 23 tightly tightens the insert connecting hardware 22 and the insert 21 to ensure structural safety with seismic bonding of the frame.

On the other hand, the insert connecting hardware 22 installed on the PC wall 12 is used as a double hook because it can hang the lifting hook 210 provided in the lifting cable 200 as shown in Figure 4 in the lifting and insertion bolt insertion hole (221a) It can have the advantage of being.

As shown in Figs. 6 to 9, the PC landing 14 is mounted on the PC wall 12 by a landing shoe 19 provided in plural or more at both ends. As shown in FIGS. 8 to 10, the landing shoe 19 is made of a square steel tube and embedded in the PC wall 12, and the shoe 191 is joined to both sides of the shoe 191 to connect the shoe 191 to precast concrete. It is made of fixing reinforcing bars 192 and square steel pipes to be fixed and inserted into the shoes 191 through the shoe pockets 141 of the PC landings 14, and then protrude from both ends of the PC landings 14 to the PC walls 12. A core fixing bolt 194 inserted into the core 193 and the upper surface of the shoe 191 to be inserted into the landing slot 122 of the screw threaded into the screw hole 193a of the core 193. It is constructed by). The shoe pocket 141 has a sufficient length to insert the core 193 into the shoe 191.

Therefore, the PC landing 14 has a core wall 193 installed in each of the four landing shoes 19 in this embodiment as shown in FIG. 12) It is mounted stably.

As illustrated in FIG. 11, the PC stairs 15 are mounted on the PC landings 14 adjacent to the upper and lower sides. To this end, the square steel pipes 16 for staircases are partially embedded in at least two places at each end of the upper and lower ends of the PC stairs 15, and the protruding portions of the square steel pipes 16 for the staircases are steps of the PC landings 14. After being inserted into the mounting pocket 142, the level adjusting bolt 17 is fastened to the square steel pipe 16 for staircase mounting, and the PC stairs 15 are horizontally adjusted, and then the non-shrinkage in the stair pocket 142. The mortar is filled and the PC stairs 15 are constructed. The square steel pipe 16 has a shear connection hole 161 for shear resistance and a screw hole 162 for fastening the level adjusting bolt 17.

As described above, in the construction method of the core PC staircase frame 10 of the present invention, the PC column 11, the PC wall 12, the PC beam 13, the PC landing 14, and the PC stairs 15 are all manufactured at the factory. Since it is made of precast concrete and assembled on site, it can shorten the air.

In the present embodiment, the PC landing 14 and the PC stairs 15 are manufactured and installed separately, but as shown in FIG. 12, the PC landing 14 and the PC stairs 15 may be manufactured and installed in one piece.

So far, the present invention has been described in detail with reference to the presented embodiments, but those skilled in the art may make various modifications and modifications without departing from the technical spirit of the present invention with reference to the presented embodiments. will be. The invention is not limited by the invention as such variations and modifications but only by the claims appended below.

11: PC pillar
12: PC wall
13: PC show
14: PC landing
15: PC staircase
17: Leveling bolt
19: landing shoe
20: Insert Connecting Hardware Set
21: Insert
22: insert connecting hardware
23: Insert tightening bolt

Claims (5)

PC pillar 11 disposed at the corner, one or more PC walls 12 disposed between neighboring PC pillars 11 and 11, supported on the PC pillar 11 and disposed on top of the PC wall 12. PC beams 13, PC landings 14 which are arranged at different heights on opposite PC walls 12 and 12 side, and PC stairs facing upper and lower PC landings 14 and 14 which are displaced when facing each other. In the construction method of the core-type PC staircase frame 10 to be constructed by (15),
In the part where the PC pillar 11 and the PC wall 12 contact each other, an insert 21 having a screw hole 21a is provided at each predetermined position along one side of the PC pillar 11, and the PC wall 12 is provided. The insert connecting hardware 22 embedded in the same height as the insert 21 is embedded, the insert connecting bolt 22 is connected to the insert fastening bolt 23 inserted through the fastening pocket 121 formed in the embedded portion After the hardware 22 and the insert 21 are fastened, the fastening pocket 121 is filled with non-shrink mortar to be constructed;
In the part where neighboring PC walls 12 and 12 contact, an insert 21 having a screw hole 21a is provided at each predetermined position along one side thereof, and the insert 21 is located along the other side. Insert connection hardware 22 embedded at the same height is embedded, and the insert fastening bolt 23 is positioned through the fastening pocket 121 formed in the part where the insert connection hardware 22 is embedded, thereby connecting the connection hardware 22 and the insert. After the 21 is fastened, the fastening pocket 121 is filled with non-shrink mortar, and is constructed.
PC landing 14 is mounted on the PC wall 12 by a landing shoe 19 installed in a plurality or more at each end;
The landing shoe 19 is made of a square steel tube and embedded in the PC wall 12, and a shoe 191 and a fixing rebar 192 bonded to both sides of the shoe 191 to fix the shoe 191 to precast concrete. And, the core material 193 and the shoe 191 is made of a square steel pipe is inserted into the shoe 191, and then protrudes from both ends of the PC landing 14 and inserted into the landing mounting groove 122 of the PC wall 12 Construction method of the core-type PC staircase frame, characterized in that made of a core material fixing bolt (194) is inserted into the upper surface of the core material is screwed to the core (193). The method of claim 1,
The insert connecting hardware 22 is made of a steel plate having a predetermined thickness to be bent at both ends of the hardware joint portion 221, the hardware joint portion 221 having a lifting and inserting bolt insertion hole 221a to precast concrete (PC) Core reinforcement wing 222 and the construction method of the core PC staircase room frame, characterized in that the shear connection hole (222a) penetrated to the iron reinforcement wing 222 is formed. The method of claim 1,
In the part where the PC beam 13 and the PC wall 12 contact each other, an insert 21 having a screw hole 21a is provided at each predetermined position along one side of the PC beam 13, and the PC wall 12 is provided. The insert connecting hardware 22 is embedded at the same interval as the insert 21, and the insert fastening bolt 23 is positioned through the fastening pocket 121 formed at the part where the insert connecting hardware 22 is embedded. After the hardware 22 and the insert 21 is fastened, the construction method of the core-type PC staircase framing, characterized in that the non-shrink mortar is filled in the fastening pocket 121. delete The method of claim 1,
A part of the stepped square steel pipe 16 is partially embedded in at least two places at the upper and lower ends of the PC stairs 15, and the protruding portion of the stepped square steel pipe 16 is used for the stepped floor of the PC landing 14 After being inserted into the pocket 142, the level adjustment bolt 17 is fastened to the stepped square steel tube 16, and the horizontal adjustment is performed. 15) is a construction method of the core PC staircase framing, characterized in that the construction.

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