KR20130097263A - A precast slab with a pc strand holding apparatus, and the construction method thereof - Google Patents

Abstract

PURPOSE: A precast (PC) slab with a strand holding device and a one-way underflooring slab continuous construction method using the same are provided to reduce the amount of re-bars arranged in a slab, to decrease the deflection of a slab, and to suppress the cracks of a joint for joining a PC slab and a PC beam. CONSTITUTION: A PC slab (100) with a strand holding device comprises an upper plate, a pair of lateral plates, and a pair of lower plates into a module. The outer surface of a lateral plate is formed with the installation groove of a fixing unit (170) to fix the position of a strand (150). [Reference numerals] (AA) Stretching and installing prestressing strand

Description

Precise slab with a pc strand holding apparatus, and the construction method

The present invention increases the bending stiffness of the slab by installing a stranded wire and introduces a prestress, while sequencing a plurality of slabs sandwiched between beams, and improving resistance to parental moments at the point, suppressing cracks and sagging slab. The present invention relates to a slab structure and a construction method thereof, which can reduce the weight of the slab. More specifically, a PC slab capable of precisely and easily proceeding construction by easily disposing a strand for introducing prestress and a one-way joist slab using the same It relates to a continuous method of construction.

Reinforced concrete structure is not only excellent in durability, fire resistance, earthquake resistance, and wind resistance, but is also widely used in large buildings such as multi-family houses, officetels and underground parking lots due to its low construction cost and easy maintenance. Conventionally, the conventional wet method used for reinforcing concrete structures has been mainly used, but the main structures such as columns, beams, slabs, etc. can be used to prevent poor construction and shorten the construction period. The application of the dry method of pre-fabrication and simple assembly in the field is increasing.

However, since the construction by the pure dry method in the structure to stiffen each structure, such as a ramen structure, there is a fear that poor construction may occur because precision is required for construction at the connection to the joint.

Therefore, in recent years, after transferring the structure of the beam, slab, etc., only a part of the body PC column, PC beam, PC slab or deck plate made in the factory to the site, in the field to assemble the PC members and cast concrete Therefore, a method for ramen-structured bonding between the structures is widely used. In the above method, the PC-slab or deck plate is mounted on the upper surface of the half PC beam that protrudes the reinforcing bar, and then, the concrete of the upper part of the half PC beam and the upper surface of the PC slab or deck plate is poured to complete the beam-slab structure. .

Meanwhile, the PC slab may be a one-way slab or a two-way slab, but in the case of the two-way slab, it is advantageous to form the structure of the long span, but there is a problem in that the amount of construction and the load are increased accordingly. In addition, when the deck plate is used, the length of the span can be implemented only about 4 to 6m, and thus, a problem of reducing space efficiency occurs in a building requiring a long span. Therefore, in buildings such as underground parking lots that require longer spans of 8m or more, the one-way joist slab structure tends to be preferred.

The double tee slab method has been developed to install the reinforcing ribs in the lower part of the slab in the one-way joist slab structure type as described above, but since the double tee slab is installed in the form of a simple beam on the PC beam, the slab deflection increases as well. There was a problem such as a crack generated in the connection with the beam.

Recently, a number of methods for sequencing slabs have been proposed to improve the above problems. As an example, 'multi slab and a slab construction method using the same' have been proposed in application No. 10-2009-0009900 filed on Feb. 6, 2009.

The prior art is a panel portion 1, a plurality of ribs (2) protruding in the longitudinal direction relative to one side of the panel portion 1, as shown in Figure 1a, and the panel portion (1) It includes a support portion (3) extending in the transverse direction from both ends of the, the end of the support portion 3 is a fixing reinforcing bar 4 is formed to protrude in the 'b' shape.

On the other hand, the rib 2 of the multi slab is provided with a prestress steel wire 5 to increase the bending rigidity of the multi slab.

Figure 1b shows a state in which the multi-slab according to the prior art is mounted on a PC beam. As shown in FIG. 2A, the fixing bar 4 protruding at the end of the multi-slab support 3 serves as a prosthetic bar together with the fixing bar 4 of the multi slab mounted on the opposite side of the PC beam. Will form.

This prior art was able to somewhat compensate for the weakness of the joint between beams by sequencing the slab to some extent, but it is necessary to reinforce a lot of rebars in order for the upper reinforcement to bear the large parental force generated at the joint between the beam and the slab. In addition, since the multi-slab is manufactured in advance by the pre-tension method, there is a limit in increasing the rigidity of the joint because it is structurally disconnected from the joint between the beam and the slab.

The present invention is to solve the above-mentioned conventional problems, while reducing the amount of rebar reinforcement to the slab, to reduce the deflection of the slab, to suppress the cracks in the joints leading to PC slab-PCBO-PC slab, the installation work of the strand It is an object of the present invention to provide a structure of a PC slab that can improve economical efficiency, structural stability, durability, and ease of construction, and a construction method capable of continualizing them.

According to the most preferred embodiment of the present invention for solving the above problems, in the PC slab mounted on the half PC beam is concrete poured at the same time with the rest of the half PC beam so that the beam and the slab is integrally combined, the The PC slab has a top plate on which longitudinal and transverse bars are placed, a pair of side plates bent downward at both ends of the top plate, and a pair of side plates bent horizontally outward at each side plate and placed on the upper half of the PC beam. It consists of a lower plate to form a module, the outer surface of the side plate is provided with a PC slab having a strand line position fixing means characterized in that at least one installation groove of the fixing means for fixing the position of the strand.

According to another embodiment of the present invention, the installation groove is provided with a PC slab having a strand position fixing means, characterized in that a plurality of different heights are formed in the longitudinal direction of the side plate.

According to another embodiment of the present invention, the installation groove is a PC slab having a strand position fixing means, characterized in that the stepped groove formed in a plurality of regular intervals along the longitudinal direction of the side plate at the same height in the upper end of the side plate. Is provided.

According to another embodiment of the present invention, in the construction method of the slab to complete the slab by mounting the concrete after mounting the PC slab on the half PC beam, a) on any one of claims 1 to 3 on the half PC beam Mounting a plurality of PC slabs in series, b) installing fixing means for fixing the position of the strand in the installation grooves formed in the side plates of the PC slab, c) non-adhesive post tension coating on the fixing means. Fixed by mounting the strand or sheath pipe of the steel wire, the strand or sheath pipe to be installed over the entire slab and the beam to be continuous, d) placing the overlay concrete on the upper surface of the half PC beam and PC slab Step of curing, e) inserting the strand into the strand or sheath tube and then tensioning it to introduce prestress into the continuous PC slab. Step; Provided is a continuous construction method of a one-way joist slab comprising a.

According to the present invention, prestress is collectively introduced into the slab and the joining portion of the slab and the beam by the post-tension method, thereby reducing the amount of reinforcing bars, reducing the deflection of the slab, and suppressing the occurrence of cracks on the overlaid concrete at the joining portion of the slab. You can expect the effect to be made.

The present invention can increase the effect of post-tension to maximize the effect of the post-tension by forming a deep rib-shaped PC slab, not only can obtain a high-quality slab structure by precision construction, It can be expected that the economical construction can be achieved by shortening the air with speed and simplification of construction.

Figure 1a is a perspective view of a multi-slab according to the prior art, Figure 1b is a cross-sectional view of the state in which the concrete is poured by mounting the multi-slab of Figure 1a on a PC beam.
FIG. 2A is a perspective view of a PC slab of the present invention, and FIG. 2B is a perspective view of a state in which a plurality of PC slabs are continuously formed to form an uneven slab.
3 is a perspective view of an embodiment in which a strand is placed after placing a PC slab on a half PC beam.
4A to 4C are conceptual views illustrating a process of fixing the position of the strand.
5 is a cross-sectional view of an embodiment in which the position fixing means of the strand is formed on both side edge portions of the upper plate.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, however, it is to be understood that the present invention is not limited to the disclosed embodiments.

PC slab 100 of the present invention, which is placed on the upper surface of the half PC beam 200 to form a lower structure of the slab structure, as shown in Figure 2a, the upper plate 110 and the amount of the upper plate 110 It consists of a pair of side plates 130 bent downward at the side end, and a lower plate 120 bent horizontally outward from the side plate 130 to form a single module, a plurality of continuous to be as shown in Figure 2b It is characterized by forming a slab of the mold.

The PC slab 100 serves as a formwork for placing the upper structure of the slab structure, the top plate 110 is laid over the longitudinal reinforcing bars and transverse reinforcement (not shown) after forming the upper structure The slab structure is completed by pouring concrete (C).

The lower plate 120 of the PC slab 100 placed on the upper surface of the half PC beam 200 is combined with the lower plate 120 of the adjacent PC slab 100 to form downward unevenness, which is formed by the uneven shape. The upward space 140 is filled with the overlay concrete (C) to form a joist that serves as a small beam.

On the other hand, the present invention after placing the sheath pipe in the upward space 140 in advance and placing and curing the overlaid concrete (C), the tension line is settled by tension, or the non-attached steel wire lined with a coating in advance and overlay After placing and curing the concrete (C), prestress is introduced into the PC slab 100 in a post-tension manner to tension and fix the strand.

In general, when the prestress is introduced into the slab by the pre-tension method, the amount of reinforcing bars in the slab can be reduced and the deflection of the slab can be reduced to reduce the possibility of cracking. However, the effect of the post-tension is that the amplitude of the stranded wire 150 is placed. Compared with the larger slab, the conventional slab is only about 200 mm thick, so the amplitude of the strand 150 cannot be increased, and thus the effect of post-tension cannot be expected very much. However, the PC slab 100 of the present invention can maximize the effect of the post-tension due to the deep relationship of the depth formed by the upward space 140 of the concave-convex shape.

FIG. 3 illustrates an embodiment in which the strand wire 150 is disposed after the PC slab 100 is mounted on the half PC beam 200. The strand 150 is arranged with respect to the entire length of the PC slab-half PC beam-PC slab, as shown in FIG. As described above, the strand 150 disposed on the half PC beam 200 exerts a compressive force on the coupling portion between the PC slab 100 and the half PC beam 200 that are most susceptible to cracking of the overlaid concrete C due to the large parent. By introducing, it is possible to suppress the cracking of the coupling portion to improve the durability.

In addition, the present invention is because the PC slab-half PC beam-PC slab as described above, the strands are arranged integrally with respect to the entire continuous length, and thus the tension is collectively simplified, so that construction is not easy and structural breakage does not occur. The effect that can prevent the phenomenon which concentrates stress can be expected.

As described above, the PC slab 100 of the present invention has a concave-convex structure leading to the upper plate 110, the side plate 130, and the lower plate 120, thereby maximizing the effect of post tension while serving as a small beam of the slab, which is a unique function thereof. In addition to providing a new effect that can be made, the effect that cannot be expected in rib-type PC slab, that is, PC slab-half PC beam-PC slab is arranged collectively with the strands 150 over the entire length of continuous To create another new effect of tension.

Meanwhile, the strand 150 of the present invention is disposed according to the distribution of the stress generated in the slab and the beam. That is, as shown in Figure 3, the strand 150 is located in the lower portion of the upward space 140 in the center of the slab in which the maximum static moment occurs and is upward in the coupling portion of the beam and the slab in which the maximum parent moment occurs By being located above the space 140, it is possible to sufficiently cope with the tensile stress at each site. Therefore, it can be said that how accurately arranged the strand is the most important factor that determines the quality of the post-tension.

The PC slab 100 of the present invention is another important technical feature that further comprises a strand line position fixing means 170 to allow the strand to be fixed at a fixed position determined by the structural design.

The fixing means 170 is installed in the upward space 140 of the PC slab 100, and for this purpose, the outer surface of each side plate 130 of the PC slab 100 facing each other in the upward space 140 is symmetrical to each other. At least one installation groove 160 of the fixing means 170 is installed at each position.

The fixing means 170 is inserted into and fixed to the installation groove 160. The fixing means 170 may be composed of reinforcing bars, iron wires, or steel bars, and may be variously bent and formed as necessary.

4A to 4C are conceptual views illustrating a process in which the position of the strand is fixed. 4A is a partial cross-sectional view of the PC slab 100 in which the installation groove 160 is formed. FIG. 4B is a partial cross-sectional view of the PC slab 100 in which the fixing means 170 is installed in the installation groove 160. FIG. 4C. Is a partial cross-sectional view of the PC slab 100 showing a state in which the strand is placed on the fixing means 170.

When a plurality of installation grooves 160 are formed in the side plate 130, the installation grooves 160 may have different heights in accordance with the longitudinal direction of the side plate 130 so as to correspond to the positions where the strands are disposed. ) Can be formed.

In another embodiment, the plurality of installation grooves 160 are stepped grooves formed at regular intervals along the longitudinal direction of the upper space 140 on both side edge portions of the top plate 110, that is, the upper end of the outer surface of the side plate 130. 160 '. In this case, the shape of the fixing means 170 may be bent and formed so as to correspond to the position at which the strand is disposed so that the strand may be fixed at the correct position. FIG. 5 shows the second embodiment of the fixing means 170 inserted into the stepped groove 160 'formed at both corners of the upper plate 110. As shown in FIG.

The stranded wire or sheath pipe mounted on the fixing means 170 may be fixed by a binding line, or may form a seating portion (not shown) provided with an insertion groove in the fixing means 170 to insert and fix the stranded wire or the sheath pipe. .

As described above, the PC slab 100 of the present invention includes a means capable of fixing the position of the stranded wire, so that not only the construction of the high-quality slab structure can be formed by precise construction, but also the stranded wire or the sheath pipe on the fixing means 170. Precision installation is possible by simply mounting it, so the effect of air shortening can be expected by quick and simple construction.

Continuation of the one-way joist slab using the PC slab 100 of the present invention, a) mounting step of the PC slab 100, b) installation step of the fixing means 170, c) arrangement of the strand or sheath pipe, d) by the construction method, including the step of pouring and curing the overlaid concrete (C), and e) the introduction of prestress.

 a) mounting step of the PC slab (100)

PC slab 100 produced in the factory is transported to the site is mounted on the half PC beam 200 is already assembled using a lifting means. A plurality of PC slabs 100 mounted in the longitudinal direction of the half PC beam 200 are generally a downward space 140 'formed on the bottom surface of the upper plate 110 and an upward space formed on the upper surface of the lower plate 120 ( 140 has an uneven shape formed alternately.

At the end of the downward space 140 ′, the blocking member 180 is formed in advance when the PC slab 100 is manufactured, or the blocking member is fitted to the inner surfaces of the upper plate 110 and the side plate 130 of the PC slab 100. When manufacturing the PC slab 100 with only the grooves formed, and when mounting it on the half PC beam 200, inserting the membrane member 180 into the membrane member fitting groove in the future when the concrete concrete (C) Is prevented from leaking through the downward space 140 '.

In addition, when the PC slab 100 is manufactured, an insert or the like is inserted into the side plate 130 so that the installation groove 160 into which the fixing means 170 for fixing the position of the strand can be inserted in advance. The installation grooves 160 are formed at positions corresponding to the arrangement of the strands determined by the structural design as described above, or are installed at regular intervals on both side edge portions of the upper plate 110.

b) installation step of the fixing means 170

When the PC slab 100 is mounted on the half PC beam 200 and the assembly is completed, fixing means 170 for fixing the position of the strand in the installation groove 160 formed in the side plate 130 of the PC slab 100. Insert and install.

In the upward space 140 of the PC slab 100, reinforcing bars may be further disposed in addition to the strands described later. In this case, the reinforcing bars may be installed in advance before the installation step of the fixing unit 170. .

The fixing means 170 may be used as reinforcing bars, iron wires, steel bars, etc., when the installation groove 160 is formed on both side edges of the upper plate 110, the surface on which the strands are mounted by bending the iron wires, etc. It is to be located at the right position of the stranded ship.

c) arrangement of strands or sheath pipes;

The non-adhesive coated steel wire of the non-adhesive post tension is placed on the fixing means 170 installed on the PC slab 100 or the sheath pipe is mounted, and then fixed by using the binding line. A method of fixing a stranded wire or the like (ie, a stranded wire or sheath pipe of the coated steel wire) to the fixing means 170 may be performed in advance to form a seating portion provided with an insertion groove in the fixing means 170 itself in addition to the binding line. It may be. The strand or the like is integrally installed over the entire slab and the beam to be continuous.

d) pouring and curing step of coated concrete (C)

When the arrangement of the strand, etc. is completed, the overcast concrete (C) is poured on the upper surface of the half PC beam 200 and PC slab 100 to cure in a batch.

e) prestressing stage

When the overlaid concrete C is cured, both ends of the strand are tensioned and then fixed to the ends of the beam so that prestress is introduced into the continuous slab. When the sheath tube is installed, it is natural to tension the strand after inserting the strand into the sheath tube. After inserting the strand into the sheath tube and tensioning it, the non-contraction mortar is filled in the sheath tube to fill the strand. In addition to preventing corrosion, the strands can be integrated with the concrete.

The present invention has been described in detail above with reference to specific embodiments, but the above embodiments are merely examples for easy understanding of the present invention, and therefore, substitutions, additions, and modifications within the scope do not depart from the spirit of the present invention. Embodiments will also belong to the protection scope of the present invention as defined by the claims below.

100: PC slab 110: Top plate
120: bottom plate 130: side plate
140: upward space 140 ': downward space
150: stranded wire 160: mounting groove
160 ': step groove 170: fixing means
200: half PC beam C: concrete

Claims (5)

In the PC slab 100 is mounted on the half PC beam 200 to concretely cast with the rest of the half PC beam 200 so that the beam and the slab is integrally combined, the PC slab 100 is in the longitudinal direction The upper plate 110 on which reinforcing bars and transverse rebars are placed, a pair of side plates 130 bent downward at both side ends of the upper plate 110, and half PC beams which are horizontally bent outwardly from the respective side plates 130. (200) consists of a pair of lower plate 120 which is placed on the upper surface to form a module, the installation groove 160 of the fixing means 170 for fixing the position of the strand on the outer surface of the side plate 130 at least PC slab having the strand position fixing means, characterized in that one or more formed The PC slab of claim 1, wherein the installation grooves 160 are formed of a plurality of pieces having different heights according to the longitudinal direction of the side plates 130. The method of claim 1, wherein the installation groove 160 is characterized in that the stepped groove (160 ') formed in a plurality of regular intervals along the longitudinal direction of the side plate 130 at the same height in the upper end of the side plate (130). PC slab with strand position fixing means In the construction method of the slab to finish the slab by placing the PC slab on the half PC beam and then pour the concrete,
a) continuously placing a plurality of PC slab 100 of any one of claims 1 to 3 on the half PC beam 200,
b) installing the fixing means 170 for fixing the position of the strand in the installation groove 160 formed in the side plate 130 of the PC slab 100,
c) fixing to the fixing means 170 by mounting the strand of the non-adhesive coated post-stretched steel wire, the strand is to be installed over the entire slab and beam to be continuous,
d) curing by pouring the added concrete (C) on the upper surface of the half PC beam 200 and PC slab 100,
e) introducing prestress into the continuous PC slab by tensioning the strand;
Continuous construction method of one-way joist slab comprising a In the construction method of the slab to finish the slab by placing the PC slab on the half PC beam and then pour the concrete,
a) continuously placing a plurality of PC slab 100 of any one of claims 1 to 3 on the half PC beam 200,
b) installing the fixing means 170 for fixing the position of the strand in the installation groove 160 formed in the side plate 130 of the PC slab 100,
c) fixed to the fixing means 170 by mounting a sheath tube, the sheath tube is to be installed over the entire slab and the beam to be continuous
d) curing by pouring the additive concrete on the upper surface of the half PC beam 200 and the PC slab 100,
e) inserting the strand into the sheath tube, and tensioning the strand to introduce prestress into the continuous PC slab (100);
Continuous construction method of one-way joist slab comprising a

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