JP2774066B2 - Floor slab made of PC version - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a floor slab in which a large number of PC plates are bridged between both beams in the longitudinal direction, and a floor group is constituted by the large number of PC plates.

[0002]

2. Description of the Related Art As a floor slab in which a floor surface is constituted by a large number of PC plates, a PC plate is bridged between two beams provided in parallel, and beams are supported only at both longitudinal ends of the PC plate. A so-called one-way plate is generally known.

[0003] In such a floor slab of a floor set,
Most of the floor load must be borne by the two beams on which each PC plate is mounted. Also, in this floor slab, since it is not integrated with each PC version,
There are problems such as the in-plane rigidity of the floor required during an earthquake is not secured.

[0004] As a solution to these problems, conventionally, at the floor slab construction site, the width direction of each PC plate is tensioned with a PC steel wire (steel rod, stranded wire) to be integrated. There is also a floor slab which is a so-called two-way board.

[0005] In the conventional floor slab which is such a floor group, the floor load is distributed to four beams around the floor slab including not only the beam in the longitudinal direction of the PC plate but also the beam in the width direction of the PC plate. Can be done. Further, since each PC plate is tensioned with a PC steel wire, the in-plane rigidity of the floor surface required during an earthquake can be maintained.

[0006]

However, in the above-mentioned conventional floor slab (bidirectional plate), P in the width direction of each PC plate is required.
Tension by the C steel wire is performed for each span (between the beams in the width direction of the PC plate) on the ground surface and beams at the slab construction site. In such a tension for each span, the fixing bracket or the fixing bracket for the tension is a pair of the fixed end and the tensioned end or the pair of the tensioned end and the tensioned end of the PC steel wire. Two locations are required for each. This means that a large number of fasteners are required for the entire floor slab.

On the other hand, a tension fixture (wedge type)
There is a problem that the efficiency of introducing prestress into the PC steel wire at the tension end is poor. In other words, this tension fixing bracket 20
(See FIG. 5) is that there is a set loss that the introduction force is reduced by the displacement in the direction opposite to the tensioning direction until the wedge 21 completely bites the PC steel wire 22, and the prestress introduction efficiency is poor. There is a problem.

[0008] Therefore, when the number of the fixing ends and the tensioned ends is increased and the number of the fixing brackets is increased, the above-mentioned problem of the fixing brackets per se is required. Become. As a result, the tensioning work on the entire floor slab extending over the plurality of beams in the width direction of the PC plate becomes very troublesome and time-consuming.

Further, when the number of the fixing brackets is large, the rust generation rate near the fixing brackets is high, so that the number of rust generating portions in the entire floor slab becomes extremely large.
The increase in the number of rust generating parts is a weak point of the PC steel wire, and requires a lot of labor and cost for the protection treatment. Therefore, the construction of the floor slab is troublesome and expensive.

[0010] The present invention has been made in view of the above-mentioned circumstances, and its purpose is to integrate a PC plate with a PC steel wire to form a two-way plate and to secure in-plane rigidity of a floor surface. Moreover, it is an object of the present invention to provide a floor slab made of a PC plate that can minimize the number of tensioned ends (fixing brackets) of the PC steel wire.

[0011]

SUMMARY OF THE INVENTION According to the present invention, when a slab is constructed at a construction site, the width direction of a large number of PC plates is united by being tensioned with a PC steel wire to produce a two-way floor slab. The tension in the steel wire is not performed for each span (between the beams in the width direction of the PC plate, see FIG. 2), and each PC plate over multiple spans is produced by simultaneously tensioning the same PC steel wire.

The floor slab of the present invention has the following two types. That is, the tension in the width direction of each PC plate over multiple spans is performed with the same PC steel wire,
After forming each PC plate into a bidirectional plate, a gap formed between the end faces of both PC plates when placed on a beam in the width direction of the PC plate (PC
It is formed by casting concrete for beams in the beam penetration where steel wire is exposed). Alternatively, after laying down each PC plate, concrete for a beam is poured into the gap where the PC steel wire on the beam is exposed (the beam penetrating portion of the PC steel wire) and cured.
There is a type in which a plate is tensioned in the width direction to form a bidirectional plate.

According to the floor slab of the present invention composed of such a floor set, each PC plate over multiple spans is simultaneously tensioned with the same PC steel wire, thereby reducing the number of fixed ends and tensioned ends (fixing brackets). In the whole floor slab extending over a plurality of beams in the width direction of the PC plate, there are two places only at both ends of the PC steel wire. This reduces the time and effort required for tension work. In addition, the fixing bracket (fixed end or tension end)
By reducing the number, the rust-producing portion near the fixing bracket is reduced, and the trouble of performing the protection treatment of the rust-producing portion is also reduced.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A floor slab made of a PC plate according to the present invention will be described below with reference to the illustrated embodiment.

The floor slab 1 (see FIGS. 1 and 2) has a large number of PC plates 2 spanned between both beams 3 in the longitudinal direction, and a large number of PC plates 2 penetrate in the width direction. PC steel wire 4 has been integrated. One end of the PC steel wire 4 is fixed to the beam 5 in the width direction of the PC plate 2, and the other end is formed of a large number of PC plates 2 and a plurality of beams 5 in the width direction of the PC plate 2.
, That is, the entire floor slab 1 is fixed to the beam 5 in the width direction of the PC plate 2.

The floor slab 1 composed of a large number of PC plates 2 applies its vertical load to the beams 3 at both ends in the longitudinal direction of each PC plate 2 by the PC plates 2 and the PC steel wires 4. And the beam 5 in the width direction, and the in-plane rigidity can be ensured by the PC steel wire 4.

As shown in FIG. 1, the PC plate 2 in this embodiment is formed in a substantially U-shaped cross section having ribs 2a provided at both ends in the width direction, as shown in FIG. Thus, a plurality of reinforcing ribs 2b extending between both rib portions 2a are formed at regular intervals in the longitudinal direction. The PC steel wire 4 passes through a sleeve (not shown) provided inside the reinforcing rib 2b.

Further, the configuration of the floor slab 1 in this embodiment is such that when the beam penetrating portion 6 of the PC steel wire 4 integrating a plurality of PC plates 2 is mounted on the beam 5, A gap 7 formed on the end face 2c of the second steel plate 2 to expose the PC steel wire 4, and a PC steel wire support 8 provided in advance on the beam 5 in the gap 7 in order to support the PC steel wire 4 in a tensioned position. And various reinforcing materials 9 for the beam 5 disposed in the gap portion 7 and after being cast into the gap portion 7 after tensioning the PC steel wire 4 in a state of being supported by the PC steel wire support portion 8. It is made of cast concrete 10.

The construction of the floor slab 1 composed of the PC plates 2 having such a configuration is performed as described below.

First, the beams 3 and 5 (large beams) made of cast-in-place concrete or precast concrete are erected, and both ends of the PC plate 2 in the longitudinal direction are fixed to the beams 3 so as to bridge between the beams 3. Then, this bridging work is repeated, and as shown in FIG.
Lay version 2.

Next, on the upper surface of the beam 5 in the width direction of the PC plate 2 which is the beam penetrating portion 6, a PC steel wire supporting portion 8 of a concrete block separate from the beam 5 is installed. In addition, a filler plate (iron plate) 11 is inserted into a gap between the PC steel wire support portion 8 and both PC plates 2. This filler plate 11 is made of PC
The purpose of this is to prevent the PC plate 2 from moving during tension due to the presence of a gap between the steel plate support portion 8. Note that the PC steel wire supporting portion 8 may be formed integrally with the beam 5 instead of a separate block or the like.

Next, a sleeve (not shown) of the reinforcing rib 2b
By inserting the PC steel wire 4 in the width direction of each PC plate 2
Is arranged. In addition, at the time of arranging this PC steel wire 4,
The PC steel wire 4 above the beam 5 which is the beam penetrating part 6 is shown in FIG.
As shown in (a) and (b), by being placed on the PC steel wire support portion 8, it is set above the beam 5 which is the beam penetrating portion 6. As a result, the PC steel wires 4 between the beams 5 are arranged in a downwardly convex curved line shape as shown in FIG.

By arranging the post-tensioning PC steel wire 4 in a downwardly convex curved line, the stress in the vertical direction generated when the PC plate 2 is hung over the beam 3 is reduced by the width. Can also be distributed in the direction.

Next, on the beam 5 that is the beam penetrating portion 6, a beam main reinforcing bar that is a reinforcing member 9 is arranged. In addition, before the tension of the PC steel wire 4, in order to surely introduce the axial force in the width direction of the PC plate 2,
As shown in FIG. 3, a steel pipe 12 filled with concrete can be provided on the reinforcing member 9 (main beam).

Next, the PC steel wire 4 penetrating the multiple PC plates 2 and the plurality of beams 5 and extending over the entire multi-span (see FIG. 2) floor slab 1 is tensioned. At the time of this tension, each PC plate 2 is tensioned by the PC steel wire 4 penetrating in the width direction thereof, so that the in-plane rigidity of the floor surface is secured and integrated.

Thereafter, a post-cast concrete 10 is cast on the beam 5 which is the beam penetrating portion 6. By the post-cast concrete 10, each PC plate 2 and the beam 5 located in the width direction thereof are completely integrated and tied. Then, the construction of the floor slab 1 is completed.

FIG. 4 shows another embodiment of the structure of the floor slab 1. In this embodiment, the beam penetrating portion 6 of the PC steel wire 4 in which a large number of PC plates 2 are integrated is formed by the PC steel wire 4 formed on the end faces of both PC plates 2 when placed on the beam 5. After setting the exposed gap portion 7, various reinforcing members 9 for the beam 5 disposed in the gap portion 7, and the PC steel wire 4 at the tension position on the beam 5 in the gap portion 7, It consists of post-cast concrete 10 which is cast into the part 7.

The floor slab 1 composed of the PC plate 2 having such a configuration is constructed as follows.

First, the beams 3 and 5 (large beams) made of cast-in-place concrete or precast concrete are erected, and both ends of the PC plate 2 in the longitudinal direction are fixed to the beams 3 so as to bridge between the beams 3. Then, this bridging work is repeated, and as shown in FIG.
Lay version 2.

Next, a sleeve of the reinforcing rib 2b (not shown)
By inserting the PC steel wire 4 in the width direction of each PC plate 2
Is arranged, and a beam main reinforcement as the reinforcing material 9 is arranged on the beam 5 as the beam penetrating portion 6. When the PC steel wires 4 are arranged, the PC steel wires 4 above the beams 5 which are the beam penetrating portions 6 are arranged in a curved line protruding downward between the beams 5 (see FIG. 1). It is set at a position where it can be set.

Next, after arranging the main reinforcement of the beam as the reinforcing material 9, a post-cast concrete 10 is cast on the beam 5 as the beam penetrating portion 6, and the post-cast concrete 10 is cured. By casting the post-cast concrete 10, the PC steel wire 4 is fixed on the beam 5 which is the beam penetrating portion 6.

When curing of the post-cast concrete 10 is completed, a number of PC plates 2 and a plurality of beams 5 have been penetrated.
The PC steel wire 4 over the entire multi-span floor slab 1 is tensioned and integrated.

The structure of the floor slab is shown in FIG.
In addition to the precast member of the PC plate 2 of the embodiment shown in FIG. 4, a cast-in-place concrete is cast on the upper surface of each PC plate that is laid out and integrated. It is also conceivable to combine them with a version.

[0034]

According to the floor slab of the present invention, a two-way floor slab is manufactured at a construction site by tensioning a plurality of PC plates in the width direction with a PC steel wire to produce a two-way plate floor slab. Is performed not at every span but at the same time by tensioning each PC plate over multiple spans with the same PC steel wire.

According to the floor slab of the present invention as described above, the number of fixed ends and tensioned ends (fixing brackets) is set to be equal to both ends of the PC steel wire in the entire floor slab extending over a plurality of beams in the PC plate width direction. By using only two places, it is possible to reduce the labor required for the tension work. In addition, by reducing the number of fixing brackets (fixed ends and tension ends) in this way, it is possible to reduce the rust generating portion near the fixing brackets,
The trouble of protecting the rust generating portion can be reduced.

[Brief description of the drawings]

1A is a schematic sectional view showing a floor slab of the present invention, and FIG. 1B is an enlarged sectional view taken along the line AA of FIG. 2, and FIG.
It is a B sectional view.

FIG. 2 is a schematic plan view showing a floor slab of the present invention.

3 (a) is a schematic sectional view of a beam penetrating portion in the floor slab of the present invention, and FIG. 3 (b) is a sectional view taken along line CC of FIG. 3 (a).

FIG. 4 is a schematic sectional view showing another embodiment of the floor slab of the present invention.

FIG. 5 is a schematic view showing a tension fixture.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Floor slab, 2 ... PC version, 2a ... Rib part, 2b ... Reinforcement rib, 2c ... End face, 3 ... Beam, 4 ... PC steel wire, 5 ... Beam, 6 ... Beam penetration part, 7 ... Gap part, 8 ... PC steel wire support, 9 ... Reinforcement, 10 ... Post-cast concrete, 11 ... Filler plate,
12 ... steel pipe.

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int.Cl. ⁶ , DB name) E04B 5/02 E04B 5/43

Claims (3)

(57) [Claims] 1. A floor slab in which a large number of PC plates are bridged between both beams in a longitudinal direction thereof, and the PC plates are integrally formed by introducing a PC steel wire penetrating in a width direction of the PC plates. The PC steel wire has one end fixed to a beam in the width direction of the PC plate, and the other end penetrates a number of PC plates and a plurality of beams in the width direction of the PC plate. Penetrates and is fixed to the beam in the width direction of the PC plate. The floor slab composed of the large number of PC plates transmits the vertical load to each PC plate by the PC plate itself and the PC steel wire. A floor slab made of a PC plate, which can transmit to beams at both ends in a longitudinal direction and beams in a width direction, and can secure in-plane rigidity by a PC steel wire. 2. A beam penetrating portion of a PC steel wire in which a large number of PC plates are integrated with a gap portion formed on the end faces of both PC plates when the PC steel wire is mounted on the beam and exposed. A PC steel wire support provided in advance on a beam in the gap to support the PC steel wire in a tensioned position, various reinforcing members for beams provided in the gap, 2. The floor slab made of a PC plate according to claim 1, wherein the steel slab is made of post-cast concrete poured into the gap after tensioning the PC steel wire in a support state by the wire support portion. 3. A beam penetrating portion of a PC steel wire in which a large number of PC plates are integrated, and a gap portion formed at the end faces of both PC plates when the PC steel wire is mounted on the beam is exposed. After setting the PC steel wire to various reinforcing members for beams disposed in the gap and the tension position on the beam in the gap,
2. The floor slab made of a PC plate according to claim 1, wherein the floor slab is made of post-cast concrete poured into the gap.