JPH0478771B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a precast floor slab that is formed by pouring concrete onto the top.

Conventionally known floor slabs include those whose lower part is made of precast slab (hereinafter abbreviated as PC slab) and whose upper part is made of concrete cast on site. Such floor slabs are usually constructed by the following method. In other words, a PC near a factory or construction site
This is a method in which a slab is manufactured, the manufactured PC slab is set at the floor slab construction position, and then the set PC slab is used as a pouring formwork and concrete is poured on top of it.

By the way, the method of constructing the floor slab as described above has the advantage that it is not necessary to withdraw the formwork and can save labor and shorten the construction period. The joint strength of the joint with the concrete was weak, and the method of reinforcing this part remained an unresolved problem. In addition, by increasing the out-of-plane rigidity of the PC slab in the above-mentioned floor slab construction method, the need for shoring to support the PC slab can be reduced, which can be expected to further reduce labor and shorten the construction period. . Therefore, in the method for constructing the above-mentioned floor slab, it has been desired to increase the out-of-plane rigidity of the PC slab.

The present invention was made in view of the above circumstances, and
It is possible to increase the bonding strength between the PC slab and the upper concrete that will be cast later, and to sufficiently increase the out-of-plane rigidity of the PC slab without increasing the weight, reducing or eliminating the need for shoring to support the PC slab. The purpose is to provide a precast version that can further save labor and shorten the construction period.

Furthermore, the objective is to provide a precast slab that has increased rigidity during and after construction compared to conventional technology, can prevent downward deflection of the floor slab, and can also provide a large floor height. There is.

Next, regarding one embodiment of the present invention, the third
This will be explained using figures. Figure 3 pertains to this example.
It is a partial perspective view of the PC version.

The PC plate 11 shown in this figure has a flat part and a plurality of rib parts protruding from the upper surface of the flat part at a height greater than the thickness of the flat part and extending parallel to each other along the upper surface. 12, and is suitable for constructing relatively thick floor slabs.

As shown in the drawing, a shaped steel material (reinforcing material) 13 such as an I-shaped steel or an H-shaped steel is embedded inside the rib portion 12 and includes a web and upper and lower flanges. The shaped steel material 13 is provided so that the longitudinal direction of the shaped steel material is the same as the extending direction of the rib portion, that is, the same direction as the arrangement direction of the sheath pipe 16 into which the tension material described later is inserted. That's what happens.

Further, the shaped steel material 13 has reinforcing plates 14 arranged at predetermined intervals in the length direction of the shaped steel material 13.
reinforced by. This reinforcing plate 14 is provided between the upper and lower flanges of the shaped steel material 13 so as to be orthogonal to the surface of the web. Also, 1 in the same figure
Reference numeral 5 indicates an anchor plate, and reference numeral 16 indicates a sheath tube.

When prestress is introduced into the tendon inserted into the sheath tube 16, the PC plate 11 is bent so that the upper side becomes convex as shown in FIG. 4a, and at that time, as shown in FIG. Rib part 1 as shown in
A tensile stress occurs in the upper part of the rib part 12, and a compressive stress occurs in the lower part of the rib part 12 and the flat part 17. When concrete is poured on top of the PC slab 11 in such a state, the constructed slab will peel off as shown in Figure 5a due to the load of the concrete 18 poured afterwards. The slab has a flat shape, and a uniform compressive stress remains over the entire floor slab as shown in FIG. 5b.

Next, an example of a construction method using the PC version 11 according to this embodiment will be explained with reference to FIGS. 1 and 2.

The PC version 11 is made in a factory or a vacant lot near the site, and when the poured concrete has a predetermined strength, tension material is inserted into the sheath pipe 16. Prestress is applied. The PC slab 11 thus prestressed is then transported to the floor slab construction site and set at the lower position of the floor slab to be constructed, as shown in FIGS. 1 and 2. At this time, the rigidity of the PC plate 11 is increased by providing the rib portion 12 and introducing prestress, and therefore the PC plate 11 has increased rigidity.
It is sufficient to place the supports 7 for supporting the plate 11 only at four corners of the PC plate 11 as shown in the figure.

Figures 1 and 2 show an example in which the floor slab is installed across beams _H1 of a PC structure.

After the PC plate 11 is set in a predetermined position as shown in FIG. 2, reinforcing bars 8 are placed on top of the PC plate 11. At this time, if the rib portion of the PC plate 11 is set to a predetermined height in advance, the spacer for supporting the reinforcing bars 8 can be omitted. Also, the PC version 11 above
In parallel with the reinforcement work on the upper part of the beam _H1 , reinforcing bars 9 are also placed in the part that will become the beam H1. Next, the PC plate 11 arranged as described above is used as a pouring formwork, and concrete is poured integrally on the upper part thereof and the part that will become the beam _H1 .

In this way, a composite floor slab is obtained in which the PC slab 11 and the post-cast concrete 10 above it are integrated. In the floor slab constructed in this way, the rib portion 3 provided in advance on the PC slab 11 acts as a pouring key, so the PC slab 11 and the post-cast concrete 10 above it are firmly connected. The result is a floor slab with excellent strength.

FIGS. 6 and 7 show an example in which the floor slab is placed across the beams _H2 of the S structure.
In this example, an H-shaped steel 31 is placed in advance at a portion that will become the beam H ₂ , and a PC plate 32 is placed above the H-shaped steel 31 so as to straddle them. At this time,
The PC version 32 has high rigidity, so the PC version 3
There is no need to support the intermediate portion of the two with a support or the like.

Figures 8 to 10 show an example in which the floor slab is installed across beams _H3 of an SRC structure. In this example, _H
The H-shaped steel 41 is provided with reinforcing plates 42 at predetermined intervals in the length direction of the H-shaped steel 41.
is arranged, and the upper part of the part reinforced by the reinforcing plate 42 is made wider. On the other hand, PC version 4
3 is formed with a protrusion 44 that protrudes laterally at a predetermined location on the peripheral edge, and this protrusion 44 is connected to the H
The PC plate 43 can be easily set in a predetermined position by overlapping the top of the wide portion of the shaped steel. Then, concrete is poured over the PC slab 43 set in this way and around the H-shaped steel 41, thereby obtaining a floor slab that is integrated with the beam _H3 .

Note that in the above embodiments, a post-tension method is used as a method of applying pre-stress to the PC plate, but the method is not limited to this, and a pre-tension method may also be used.

As explained above, the precast plate according to the present invention has a flat part and a shape that protrudes from the upper surface of the flat part at a height equal to or greater than the thickness of the flat part and extends parallel to each other along the upper surface. A precast slab for constructing a floor slab by pouring concrete onto the flat part and the upper part of the rib part in an erected state, comprising a plurality of rib parts,
Inside the flat part of the precast plate, a tension material is provided along the extending direction of the rib part by introducing a prestress that causes the precast plate to bend upward in the erected state, and inside the rib part, A steel section comprising a web and flanges above and below the web is buried so that the longitudinal direction of the section steel is the same as the extending direction of the rib portion. It has a unique effect.

(b) Since the structure is such that a steel section made of I-section steel, H-section steel, etc., which has a web and flanges above and below the web, is embedded inside the rib part, this section steel material can be used like reinforcing bars, etc. Rather than simply reinforcing the concrete, it has a structure in which multiple small beams are buried within the precast slab, so the ribs are Precast plates reinforced with shaped steel are
It exhibits extremely high rigidity, including rigidity against torsion. Therefore, no shoring is required to erect this precast slab, and if the slab is constructed using this precast slab, multiple small beams can be installed inside the slab that is constructed with post-cast concrete. Since the structure is similar to a so-called synthetic floor slab, there is no need to install small beams under the floor slab as in the past, and the floor height can be increased accordingly. In other words, when the precast slab is erected, the precast slab itself exerts sufficient reinforcing action, which is necessary as a formwork member that does not require shoring, and after the slab is constructed, the reinforcing elements existing inside the slab itself are effective. It functions as a beam.

(b) Also, since the height of the rib part is set to be greater than the thickness of the flat part, it is possible to use a relatively large beam shape such as an I-beam as a section steel material inside the rib part, as shown in the figure. Steel materials can be buried,
Moreover, in this case, since the tendons are provided on the flat part and the tendons and the section steel are provided in the same direction, the precast version is created by the mutual reinforcing action of these tendons and the section steel. The structure can further enhance the reinforcing effect, especially the out-of-plane rigidity (rigidity that resists deflection).

(c) Furthermore, because the rib portion with a high protruding height plays the role of a pouring joint key and the joint area between the precast slab and post-cast concrete becomes large, the connection between the precast slab and post-cast concrete is The bonding strength is increased, and as a result, the rigidity of the floor slab is further improved.

(d) The out-of-plane rigidity of the precast slab itself is increased by the introduction of prestress and the action of the section steel embedded in the rib portion, making it possible to reduce or omit the need for shoring to support the precast slab;
Further labor savings and shorter construction times can be achieved.

(e) When pre-stressing is introduced, the precast slab will be bent once, but the bending will be canceled by the load of the post-cast concrete placed on top of it, and it will take on a flat shape.

Therefore, it is possible to apply only suitable compressive stress to the concrete and not to apply tensile stress to the precast slab itself, as well as to the post-cast concrete, thereby preventing problems such as cracks as a whole. can be prevented from occurring.

(F) When the floor slab is arranged in a twisted state between concrete beams, it is possible to construct an integral structure with the concrete beam, so it is possible to construct a floor slab with excellent strength.

(g) Furthermore, the rigidity during construction can be increased compared to the conventional technology, and downward deflection of the slab can be prevented.

[Brief explanation of the drawing]

Figures 1 and 2 and Figures 3 to 5b show one embodiment of the present invention. 2 is a sectional view taken along the - line in FIG. 1, FIG. 3 is a perspective view of the precast plate, and FIG. 4a shows a part of the precast plate with prestress introduced. cross-sectional side view,
Figure 4b is a stress distribution diagram of the same precast version, Figure 5
Figure a is a cross-sectional view showing concrete being placed on top of the precast slab, Figure 5 b is a stress distribution diagram of the same slab, and Figures 6 and 7 are bridges between the beams of the S structure. These are shown to explain the method of constructing the floor slab. Figure 6 is a plan view, and Figure 7 is a
Cross-sectional views along the - line in the figure, Figures 8 to 10
The figures are shown to explain the construction method of the floor slab that spans between the beams of an SRC structure. Figure 8 is a plan view, Figure 9 is a sectional view taken along the - line in Figure 8, and Figure 10 is a FIG. 9 is an enlarged view of the circular portion in FIG. 9; H ₁ ... Beam, 10... Post-cast concrete, 1
1...PC version, 12...rib part, 13...shape steel material,
16... Sheath tube, 17... Flat part, 21...
PC version, 22... Flat part, H ₂ ... Beam, 32... PC
Version, H ₃ ... Liang, 43 ... PC version.

Claims (1)

[Claims] 1 comprising a flat part and a plurality of rib parts protruding from the upper surface of the flat part at a height equal to or greater than the thickness of the flat part and extending parallel to each other along the upper surface, and in an erected state. A precast slab for constructing a floor slab by pouring concrete on the flat part and the upper part of the rib part, wherein inside the flat part of the precast slab, there is a wall extending upwardly when the precast slab is in an erected state. A tension member is provided along the extending direction of the rib portion, and a section steel member comprising a web and flanges above and below the web is provided inside the rib portion. A precast plate, characterized in that it is buried so that the longitudinal direction of the steel material is the same as the extending direction of the rib portion.