KR900006763B1 - Floor construction using precast panel - Google Patents

Abstract

The multi-directional concrete floor comprises a precast reinforced concrete slab having flat upper and lower surfaces. The upper surface defines cylindrical cavities. A concrete layer is superimposed only on the slab upper surface. The layer has a flat lower surface formed with a multiplicity of cylindrical shears extending downwardly into interlocking contact with the slab cylindrical cavities. The shears prevent relative movement betwen the slab and layer in all horizontal directions under bending forces.

Description

Floor construction method using precast plate

1 is a partial perspective view showing an example of a precast version.

2 is an enlarged cross-sectional view of the recess.

3 is a partial perspective view of another example of a precast version.

4 is a cross-sectional view of the groove forming mold.

Figure 5 is a partial cross-sectional view of an example showing the installation state of the precast plate end.

6 is a partial cross-sectional view of another example showing the installation state of the precast plate end.

7 is a cross-sectional view of the synthesized bottom test piece.

8 is a graph showing the bending test results.

9 is a graph showing the state of migrating other surfaces.

10 is a graph showing the plane protection maintenance of the cross section.

* Explanation of symbols for main parts of the drawings

A: Precast 1: Empty name

2: PC steel wire 3: groove

4: round drum 5: protrusion

10,12 support base 11: rebar anchor

13: pillar 15: steel frame

The present invention relates to a floor construction method using a precast plate made of a synthetic floor by integrating a precast plate raised between the beams and the site-cast concrete placed on the upper surface thereof.

Conventionally, in the flooring method using a precast plate made of PC concrete, concrete is poured on the upper surface of a precast plate raised between beams.

It is also known that the stress of the concrete structure is generally proportional to the square of the thickness.

Therefore, when concrete is placed on the upper surface of the precast plate, the thickness of the two layers can be the thickness of one structure for the calculation of the stress level. You have to do sancheong.

In addition, when concrete is simply poured on the upper surface of the smooth precast plate, the thickness of the precast plate cannot be turned on in order to obtain the required stress due to insufficient coupling between the two.

With this in mind, when pre-integrating precast plate and in-situ concrete and calculating the stress level, the thickness of the entire structure can be considered as a structure. A synthetic flooring method was developed in which the surface of the precast plate was embedded in the inside and the other side was not exposed, and this was embedded in the cast-in-place concrete to integrate both.

However, the conventional method described above protrudes a part of the basic structure on the surface of the precast plate, and thus cannot be continuously formed in the precast plate, which is expensive in manufacturing, and moreover, the basic structure protrudes during storage, transportation and installation. Because it is easy to thrive, handling must be done carefully, and workability was also a problem.

The present invention uses a precast plate that is easy to mold and inexpensive in view of the above-described conventional problems, and furthermore, when constructing a floor, it can be easily constructed without adding any special member or process. It is an object of the present invention to provide a floor construction method using a precast plate that can ensure the integration of the precast plate and the cast-in-place concrete, and can obtain the required stress level at the same thickness as the floor where the whole is integrally formed.

The main point is that the above-mentioned precast method is used in the flooring method using a precast plate in which concrete precast plates are placed between steel or concrete support holes, and concrete is directly cast on the upper surface thereof. The plate uses a large number of grooves integrally on the surface, and the concrete is integrally typed in the grooves, thereby acting as an anchor, thereby integrating the precast plate and the cast-in-place concrete to form a mechanically synthesized floor. There is in the flooring method using a precast plate formed by characterized in that the.

Next, embodiments of the present invention will be described with reference to the drawings.

First, the concrete precast plate used for this invention based on FIG. 1 thru | or FIG. 4 is demonstrated.

FIG. 1 is a partial perspective view of an example of a precast plate used in the present invention. The precast plate A has a plurality of FC steel wires formed at the same time through a plurality of hollow holes 1 in the longitudinal direction. 2) This is buried tightly.

On the other hand, many grooves 3 are formed on the bottom surface.

As shown in Fig. 2, the recess 3 is formed in a tapered shape with a small diameter, and the size of the recess 3 is 25 mm for the open part diameter a, 17 mm for the bottom part diameter b, and depth. (h) is 5 mm and the taper angle (alpha) is 45 degrees.

In addition, the shape of the groove portion 3 may be triangular, tetragonal or other polygonal shapes in addition to the above-described circle, and the size may be modified to be large or small.

In addition to the above-mentioned, the precast plate used in the present invention has a hollow shape that does not have the hollow hole 1 like the precast plate A 'shown in FIG. 2) is buried in place and many grooves 3 are formed on the surface.

In the manufacture of these precast plates A and A ', for example, the FC steel wire 2 is stretched in a flat surface shape such as a bottom surface, and concrete is poured as if the PC steel wire 2 is embedded. As soon as the cylindrical frame is moved, it is formed by a demoulding method, the surface is flattened, and then many projections 5 are projected on the outer peripheral part of the circular drum 4 as shown in FIG. The yoke portion 3 is obtained by rotating the forming die for forming the yoke portion 3 formed therein.

In this way, after forming the recessed part 3 on the surface, it is left to harden, after reaching | attaining a certain intensity | strength or more, it cut | disconnects to a required length, and is made into the cut | disconnected precast board of the required length.

Next, the process of constructing a floor using the precast board A formed as mentioned above is demonstrated. First, the precast plate (A) is placed over the beam beams installed horizontally at regular intervals.

At this time, in the case where the beam is made of concrete at the end side of the precast plate A, the rebar anchor 11 is projected to the bottom surface of the beam 10, as shown in FIG. The end of the plate A is put over.

In addition, when the beam is a reinforcing bar, as shown in FIG. 6, the pillar 13 is set up in the center of the beam 12, and the edge part of the precast board A is raised on both sides.

In this manner, after placing a large number of precast plates (A), the reinforcing bars 15 for cast in place concrete are put on the upper surfaces thereof, and the cast-in-place concrete (B) is sandwiched between the precast plates (A) and its upper surface. Make a floor by pouring on the whole side of the.

The floor constructed in this way is hardened by inserting the cast-in-place concrete (B) between the grooves (3) on the surface of the precast plate (A), and the concrete in the grooves (3) acts as an anchor and precast plate. (A) and the cast-in-place concrete (B) are integrated, and are integrated and act on the load in the vertical direction.

In addition, the precast plates A are integrated with each other by using the cast-in-place concrete as a medium by the anchoring action of hardening of the concrete in the recess 3 described above.

[Test Example]

The recessed portion 3 of the size and shape indicated in FIG. 2 and its description on the surface of the PC precast plate A having a thickness h ₁ l00 mm and a width X: 500 mm as shown in FIG. Is formed in a zigzag shape at intervals of 35 mm in the width direction and 44 mm in the long direction, and concrete (B) having a thickness (h ₂ ) of 80 mm is placed on the upper surface to make the overall thickness (h ₂ ) 180 mm. The synthesized floor test piece was prepared, and the load test was carried out using only this and the PC precast plate (A) described above.

TABLE 1

In addition, the bending test was performed on the synthesized bottom test piece No. 1 shown in Table 1, which is similar to the graph of FIG. 8, and the slippage of the other interface is the same as that of FIG. It was like a graph.

(Review)

(1) The experimental value of the balanced load and the maximum load both exceeded the calculated value as a unit in the destructive state of strength, and the integrity of the bottom plate was confirmed in terms of strength. In addition, the destructive state is also normal bending or shear failure, the destruction of the take-up surface does not occur until the end, even in the destructive state, the integrity was confirmed.

(2) Regarding the load deflection curve, the elastic stiffness exceeded the calculated value in all the experimental values. In addition, the characteristics of the curves did not show a decrease in the integrity of the other interface. From these points, the integrity of the bottom plate was confirmed.

(3) Regarding the crack state, the division by the crack passes almost straight along the other interface, and progress is not recognized along the other interface. Thus, the integrity of the floor was confirmed in the cracked state.

(4) Sliding of the Other Interface The sliding of the other interface was 0 to 0.0 lmm or less, and it was confirmed that the integrity was maintained.

(5) The results of the float with the degree of torsion in the thick direction with regard to the planar protection holdability show that the cross section is generally flat. Therefore, the integrity of the synthesized bottom plate formed by integrally pouring in situ concrete on the upper surface of the concrete precast plate was confirmed.

(conclusion)

As described above, the structural integrity of the synthesized bottom plate was confirmed in all aspects of strength, stiffness, fracture property, cracking property, sliding of another interface, and planar protection of cross section.

The present invention is constructed as described above, and the experiment is provided by installing a large number of grooves on the surface of the precast plate, and by placing the concrete on the surface of the concrete cast on the surface to harden the concrete to perform the anchor role As shown in the example, firm integration is realized, and during construction, the overall thickness of the precast plate and the cast-in-place concrete can be calculated as the thickness of the integral structure, and as a result, in terms of cost and workability, It is extremely advantageous over the conventional method.

Claims (1)

In the floor construction method in which a concrete precast fern (A) is raised between steel frame or concrete beams (12) (12), and the concrete (B) is integrally cast in the field on the upper surface thereof, the above-mentioned free construction Cast plate (A) is used to arrange a plurality of grooves (3) in close proximity to each other in a zigzag form arrangement, the yoke (3) is formed in a tabular shape of the precast plate (A) The beam in the said precast plate A is made by injecting the concrete B into the surface and the recess part 3, and acting as an anchor, and integrating the precast plate A and the concrete B. 10) A flooring method using a precast plate, characterized by averaging distribution of shear stress in the longitudinal direction of (12).

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