JP2003227200A - Embedded material unit, hollow slab using the same, its construction method, and precast concrete slab - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lightweight embedded material, which can be efficiently and economically arranged with high accuracy, a hollow slab using the same, its construction method, and a precast concrete slab. <P>SOLUTION: In an embedded material unit 1, the lightweight embedded materials 2, which are arranged at each proper interval, can be split into upper and lower parts; at least one of the upper and lower parts, into which the embedded material 2 is split, is coupled by a coupling material 3; the embedded material 2 includes a spherical shape or a capsule shape; and a cross-shaped notched groove 11 is formed in the upper part of the embedded material 2. Additionally, the embedded material 2 and the coupling material 3 are integrally molded, and a protrusion 14 is formed between the adjacent embedded materials 2. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an embedding material unit, a hollow slab using the same, a method for constructing the hollow slab, and a precast concrete board.

[0002]

2. Description of the Related Art In recent years, many hollow slabs having a light embedding material embedded therein have been constructed in order to reduce the weight. An example of the hollow slab 35 in which such a lightweight embedding material is embedded is shown in FIG.
The lightweight embedding material 36 is sandwiched between the upper reinforcing bar 37 and the lower reinforcing bar 38 to prevent the concrete 39 from rising when it is placed.

[0003]

However, the above hollow slab has the following problems. (1) It takes time and labor to install each lightweight embedding material. (2) Since it is necessary to arrange at least two reinforcing bars between the lightweight embedding materials, it may be excessive depending on the span of the slab. (3) A joint rebar for connecting the upper bar unit that holds down the lightweight embedding material was required, and the amount of rebar that could be attached to the slab was increasing.

The present invention has been made in view of the above problems, and an object thereof is a lightweight embedding material which can be arranged efficiently, economically, and accurately, a hollow slab using the same, and a method of constructing the same. And to provide precast concrete boards.

[0005]

[Means for Solving the Problems] The gist of an embedding material unit for solving the above problems is that a light weight embedding material arranged at appropriate intervals can be divided into upper and lower parts, and the lightweight embedding material can be divided into upper and lower parts. At least one of the embedding materials is connected by a connecting material. It also includes that the lightweight implant is spherical or capsule-shaped. It also includes that a cross-shaped cutout groove is formed in the upper part of the lightweight embedding material. It also includes that the lightweight embedding material and the connecting material are integrally molded. This includes the formation of protrusions between adjacent lightweight embedding materials.

Further, the gist of the embedding material unit is that light embedding materials arranged at appropriate intervals are connected by a connecting material, and a cross-shaped notch groove is formed on an upper portion of the light embedding material. And It also includes that the lightweight implant is spherical or capsule-shaped. It also includes that the lightweight embedding material and the connecting material are integrally molded. It also includes the formation of protrusions between adjacent lightweight embedding materials.

Further, the gist of the hollow slab is that the lightweight embedding materials arranged at appropriate intervals can be divided into upper and lower parts, and at least one of the vertically divided lightweight embedding materials is connected by a connecting material. It is characterized in that the embedding material unit is embedded in the concrete of the slab. It also includes that the lightweight implant is spherical or capsule-shaped. It also includes that a cross-shaped cutout groove is formed in the upper part of the lightweight embedding material. It also includes that the lightweight embedding material and the connecting material are integrally molded. This includes the formation of protrusions between adjacent lightweight embedding materials.

Further, in the method of constructing the hollow slab, the light-weight embedding materials arranged at appropriate intervals can be divided into upper and lower parts, and at least one of the light-weight embedding materials divided into the upper and lower parts is connected by a connecting material. The embedding material unit is installed in the slab formwork, the upper reinforcement of the slab arranged on the upper surface of the lightweight embedding material is fixed with a lifting prevention tool, and then concrete is placed in the slab formwork. And It also includes binding the connecting bar of the lightweight embedding material to the upper reinforcing bar or the lower reinforcing bar. It also includes that the lightweight implant is spherical or capsule-shaped. It also includes that a cross-shaped cutout groove is formed in the upper part of the lightweight embedding material. It also includes that the lightweight embedding material and the connecting material are integrally molded. This includes the formation of protrusions between adjacent lightweight embedding materials.

Further, the method of constructing the hollow slab is such that an embedding material unit in which lightweight embedding materials arranged at appropriate intervals are connected by a connecting material, and a cross-shaped notch groove is formed on an upper portion of the light weight embedding material. Is installed in the slab formwork, the upper reinforcing bar of the slab arranged on the upper surface of the lightweight embedding material is fixed by a lifting prevention tool, and then concrete is placed in the slab formwork. It also includes binding the connecting bar of the lightweight embedding material to the upper reinforcing bar or the lower reinforcing bar. It also includes that the lightweight implant is spherical or capsule-shaped. It also includes that the lightweight embedding material and the connecting material are integrally molded. This includes the formation of protrusions between adjacent lightweight embedding materials.

Further, the gist of the precast concrete board is that a light weight embedding material arranged at appropriate intervals can be divided into upper and lower parts, and at least one of the light weight embedding material divided into the upper and lower parts is connected by a connecting material. The embedded material unit is installed on the concrete board. It also includes that the lightweight implant is spherical or capsule-shaped. It also includes that a cross-shaped cutout groove is formed in the upper part of the lightweight embedding material. It also includes that the lightweight embedding material and the connecting material are integrally molded. This includes the formation of protrusions between adjacent lightweight embedding materials.

Further, the gist of the precast concrete board is that an embedding material unit in which lightweight embedding materials arranged at appropriate intervals are connected by a connecting material, and a cross-shaped notch groove is formed on an upper portion of the lightweight embedding material. However, it was installed on a concrete board. It also includes that the lightweight implant is spherical or capsule-shaped. It also includes that the lightweight embedding material and the connecting material are integrally molded. This includes the formation of protrusions between adjacent lightweight embedding materials.

The gist of the precast concrete board is that spherical or capsule-shaped lightweight embedding materials are installed in the concrete board at appropriate intervals so that the notches provided with the recesses or protrusions are buried. The insert material is connected by a connecting material.

It is possible to manufacture an embedding material unit which can be installed efficiently, economically and accurately. Since the lightweight embedding material is vertically separable, the embedding material unit can be easily manufactured. Since the protrusions are formed between the adjacent lightweight embedding materials, the movement of the lightweight embedding materials can be regulated by the concrete placed in the mold in which the embedding material unit is installed. A lattice-shaped hooking member can be fitted in the notch groove in the upper part of the lightweight embedding material. Lifting of the lightweight embedding material when pouring concrete into the formwork is suppressed by the hooking material with the upper slab reinforcement arranged on the upper surface, which can reduce the labor and cost of construction of the hollow slab. . By digging concrete into the cutout groove, it is possible to manufacture a precast concrete plate in which the embedding material unit cannot be pulled out from the concrete plate. Lightweight embedding material is easy to install on concrete boards,
It becomes difficult to pull out the lightweight embedding material from this concrete board.

[0014]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of an embedding material unit of the present invention, a hollow slab using the same, a method for constructing the same, and a precast concrete plate (hereinafter referred to as a PC plate) will be described in detail with reference to the drawings. explain. First, an embodiment of the embedding material unit will be described,
After that, a method of constructing a hollow slab and an embodiment of a PC plate will be described. Further, in each of the embodiments, the same configurations will be described with the same reference numerals, and different configurations will be described with different reference numerals.

FIG. 1 shows an embedding material unit 1 according to the first embodiment. This embedding material unit 1 is configured by integrally connecting lightly embedding materials (for example, polystyrene foam) 2 which can be divided into upper and lower parts by a connecting material 3 such as a welding wire mesh. This lightweight embedding material 2 is shown in FIG.
As shown in (2) and (2), the central part is divided into an upper hemisphere 4 and a lower hemisphere 5, and the fitting projection 7 of the lower hemisphere 5 is fitted into the groove 6 of the upper hemisphere 4 to form an integral body. The parts are integrally connected by a grid-shaped connecting member 3.

Since the lightweight embedding material 2 can be divided into the upper hemisphere 4 and the lower hemisphere 5 in this manner, the embedding material unit 1 can be easily manufactured. Further, by replacing the lower hemisphere 5 and changing the length of the lightweight embedding material 2 (see FIG. 3), it becomes possible to easily cope with slabs having different thicknesses. Also,
As shown in (3) of FIG. 2, since it can be used as the embedding material unit 1 having only the upper hemisphere 4 (which is connected by the connecting material 3) from which the lower hemisphere 5 is removed, the slab having a small thickness can be used. Can also be used for Further, as shown in (4) of the same figure, a lower hemisphere 5 of different length is installed in one embedding material unit 1, for example, the lower hemisphere 5 of one area and the lower hemisphere 5 of the other area. If you change the length of
It can also be used to build hollow slabs with steps. Also, by changing the length of the lower hemisphere 5,
The height of the step can be freely changed. In this way, the embedding material unit 1 can easily cope with slabs having different thicknesses and slabs having step portions.

Further, since the connecting material 3 is integrated with the lightweight embedding material 2, the embedding material unit 1 can be easily manufactured and can be easily installed on the slab formwork. Further, as shown in (3) of FIG. 3, when the lower hemisphere 5 and the connecting member 3 are integrally formed, the upper hemisphere 4 and the lower hemisphere 5 are joined or the lower hemisphere 5 is replaced (to a lower hemisphere having a different length). Can also be done easily.

FIG. 3 shows the embedding material unit 8 of the second embodiment in which the lightweight embedding material 8 is in the shape of a capsule, and the embedding material of the first embodiment except that the lower hemisphere 5 is elongated. It has the same configuration as the unit 1. When this embedding material unit 8 is used in combination with the embedding material unit 1, a hollow slab or a PC board having a step can be formed. Further, the slab thickness can be changed only by changing the lower hemisphere 5 of the lightweight embedding material 2. Further, (3) in the figure is a three-divided embedding material unit 8 in which the lower hemisphere 5 is further divided and the divided hemispheres 5 a are connected by the connecting material 3. That is, the embedding material unit 8 is divided into three parts as a whole, and the height of the lightweight embedding material 2 can be freely changed by changing the length of the central column 5b. Therefore, when forming a hollow slab having a step portion, the height of the step portion can be freely changed.

FIG. 4 shows an embedding material unit 9 according to the third embodiment. In this embedding material unit 9, an upper embedding material 2a in which upper hemispheres 4 are connected by a connecting material 3 and a lower embedding material 2b in which lower hemispheres 5 are connected by a connecting material 3 are fitted together. As shown in FIG. 5, the fitting projection 7 of the lower hemisphere 5 is fitted and joined to the groove 6 of the upper hemisphere 4. Further, in the upper hemisphere 4 of the upper embedding material 2a, a cross-shaped notch groove 1 into which a latching material 10 such as a lattice bar or a welding wire mesh is fitted.
1 is provided.

FIG. 6 shows an embedding material unit 12 of the fourth embodiment in which the latching material 10 is fitted in the notch groove 11. The third embodiment is different from the embedding material unit 12 in which the latching material 10 is fitted. It has the same configuration as the embedding material unit 9 of the form. By such a hooking member 10, it is possible to suppress the lifting of concrete when pouring.

FIG. 7 shows an embedding material unit 13 of the fifth embodiment. This embedding unit 13
The protrusions 14 provided on the lower hemisphere 5 of the lower embedding material 2b are in contact with each other to restrict the movement of the lightweight embedding material 2 in the lateral direction. It has the same configuration as the embedding material unit 1. The protrusion 14 has a role of preventing the lightweight embedding material 2 from being deformed by the placing force of concrete and maintaining a predetermined shape even if the upper portion of the lightweight embedding material 2 is connected by the connecting material 3. Furthermore, such a protrusion 14
In order to reduce the cross section loss of the concrete part even in the slab structure, the shear strength is not sacrificed. See also FIG.
Shows the embedding material unit 13 in which the lower hemispheres 5 are connected to each other by the integrally formed protruding portion 14.

FIG. 9 shows an embedding material unit 15 according to the sixth embodiment. This embedding material unit 15 is
The upper hemispheres 4 are connected to each other by the protrusions 14 and the upper embedding material 2a
Is formed, and the lightweight embedding material 2 is formed by the protrusions 14.
Regulates the lateral movement of the. Further, FIG. 10 shows an embedding material unit 15 in which the lower hemispheres 5 are connected to each other by the integrally formed protrusion 14.

FIG. 11 shows an embedding material unit 16 of the seventh embodiment. This embedding unit 16
Is a capsule-shaped lightweight embedding material 2 of the embedding material unit 13 of FIG. 7, and has the same configuration except that the lower hemisphere 5 is elongated. Further, this embedding material unit 16 can also be divided into three parts by further dividing the lower hemisphere 5 similarly to (3) of FIG.

FIG. 12 shows an embedding material unit 17 according to the eighth embodiment. This embedding unit 17
Is a capsule-shaped lightweight embedding material 2 of the embedding material unit 13 in FIG. 8, and has the same configuration except that the lower hemisphere 5 is elongated. In addition, this embedding material unit 17 can also be divided into three parts by further dividing the lower hemisphere 5 as in (3) of FIG.

FIG. 13 shows an embedding material unit 18 according to the ninth embodiment. This embedding material unit 18
Is a capsule-shaped lightweight embedding material 2 of the embedding material unit 15 of FIG. 9, and has the same configuration except that the lower hemisphere 5 is elongated. Further, this embedding material unit 18 can also be divided into three parts by further dividing the lower hemisphere 5 as in (3) of FIG.

FIG. 14 shows an embedding material unit 19 according to the tenth embodiment. This embedding material unit 19
Is a capsule-shaped lightweight embedding material 2 of the embedding material unit 15 of FIG. 10, and has the same configuration except that the lower hemisphere 5 is elongated. The embedding material unit 19 is also shown in FIG.
The lower hemisphere 5 can be further divided into three as in the case of (3).

FIG. 15 shows an embedding material unit 20 of the eleventh embodiment. This embedding material unit 20
Is the same as the embedding material unit 9 of FIG. 4 except that the light embedding material 2 which is not divided into upper and lower parts is connected by the connecting material 3. Lightweight embedding material 2 that does not divide vertically like this
The embedding material units 1, 8, 1 of FIGS.
It can also be used for 2, 13, 15, 16, 17, 18, 19.

FIG. 16 shows a hollow slab using the embedding material unit 1 of FIG. 1 and has a high porosity. A method of constructing a hollow slab using this embedding material unit 1 will be described. In this construction method, first, a fixture 23 is fixed to the bottom plate 22 of the slab form 21. Next, the embedding material unit 1 is installed on the slab formwork 21, and the fixture 2
The fixing pin 24 of No. 3 is inserted into the lightweight embedding material 2.

Next, the upper reinforcing bar 25 is laid on the embedding material unit 1, and a fastener 26 is screwed into the tip of the fixing pin 24 to fix the embedding material unit 1. And the slab formwork 2 to which this embedding material unit 1 is fixed
When concrete 27 is poured into 1, the floating of the lightweight embedding material 2 is suppressed by the fixture 23, and the hollow slab 28 is constructed. Further, after the embedding material unit 1 is fixed, the connecting material 3 can be bound to the upper reinforcing bar 26.

In addition to the embedding material unit 1, the embedding material units 8, 9, 12, 1 shown in FIGS.
Hollow slabs (not shown) using 3, 15, 16, 17, 18, 19 are also constructed in the same way. In this case as well, after the embedding material unit 1 is fixed, the connecting material 3 can be bound to the upper reinforcing bar 25 (or the lower reinforcing bar).

FIG. 17 shows the PC board 29 of the first embodiment.
That is, the PC board 29 using the embedding material unit 9 of FIG.
Is. This PC board 29 is one in which the lower part of the lightweight embedding material 2 is embedded in a concrete board 30 so that the cutout groove 11 is on the lower side, and the concrete cuts into the cutout groove 11, and the embedding material unit 9 is It cannot be pulled out from the concrete board 30. This embedding material unit 9 is
Not only the PC board 29 as described above, but also a so-called full PC board can be used. In addition to the embedding material unit 9, the embedding material unit 1 shown in FIGS.
It is also possible to form a PC board (not shown) using 8, 12, 13, 15, 16, 17, 18, and 19.

FIG. 18 shows a PC board 31 of the second embodiment. In this PC board 31, the notch 33 provided with the recess 32 is embedded, and the spherical lightweight embedding materials 2 are installed in the concrete board 30 at appropriate intervals, and these lightweight embedding materials 2 are the connecting materials 3. It is configured by being connected.
This cutout 33 facilitates installation of the lightweight embedding material 2, and the recess 3
2 bites into the concrete plate 30 and is difficult to pull out. It should be noted that the notch 33 may be provided with a protrusion instead of the recess 32, and the lightweight embedding material 2 may be in the shape of a capsule.

[0033]

The embedding material unit that can be installed efficiently, economically, and accurately can be manufactured.

Since the lightweight potting material can be divided into upper and lower parts, the potting material unit can be easily manufactured corresponding to various sizes.

A lattice-shaped hooking member can be fitted in the notch groove in the upper portion of the lightweight embedding material.

By integrally forming the upper part or the whole of the lightweight embedding material with the connecting material, a robust embedding material unit can be formed.

Since lifting of the lightweight embedding material when pouring concrete into the formwork is suppressed by the hooking material, it is possible to reduce the labor and cost for constructing the hollow slab.

By forming the protrusion between the adjacent lightweight embedding materials, it is possible to restrict the movement of the lightweight embedding material by the concrete cast in the formwork in which the embedding material unit is installed.

By precipitating the concrete into the notch groove, it is possible to manufacture a precast concrete plate in which the embedding material unit cannot be pulled out from the concrete plate.

The lightweight embedding material can be easily installed on a concrete board, and a precast concrete board from which the lightweight embedding material cannot be pulled out can be manufactured.

[Brief description of drawings]

1A is a plan view of an embedding material unit according to a first embodiment, and FIG. 1B is a side view of the same.

FIG. 2 is a sectional view of a lightweight embedding material obtained by dividing the lower hemisphere, FIG. 2 is a plan view of the divided lower hemisphere, and FIG. 2 is a side view of an embedding material unit having only the upper hemisphere. 4) is a side view of the embedding material unit in which the length of the lower hemisphere is changed.

3A is a plan view of an embedding material unit according to a second embodiment, FIG. 3B is a side view of the same, and FIG. 3C is a side view of an embedding material unit divided into three parts.

FIG. 4 (1) is a plan view of an embedding material unit according to a third embodiment, (2) is a sectional view taken along the line AA of (1), and (3) is an embedding material unit divided into upper and lower parts. FIG.

5A is a cross-sectional view of a lightweight embedding material, FIG. 5B is a cross-sectional view of a lightweight embedding material in which the lower hemisphere is divided, and FIG. 5C is a plan view of the divided lower hemisphere.

FIG. 6A is a plan view of an embedding material unit according to a fourth embodiment, and FIG. 6B is a side view of the same.

7A is a plan view of an embedding material unit according to a fifth embodiment, and FIG. 7B is a side view of the same.

FIG. 8 is a side view of an embedding material unit in which the lower hemisphere is divided. Is.

9A is a plan view of an embedding material unit according to a sixth embodiment, and FIG. 9B is a side view of the same.

FIG. 10 is a side view of an embedding material unit in which the lower hemisphere is divided.

FIG. 11 is a side view of an embedding material unit according to a seventh embodiment.

FIG. 12 is a side view of an embedding material unit according to an eighth embodiment.

FIG. 13 is a side view of an embedding material unit according to a ninth embodiment.

FIG. 14 is a side view of an embedding material unit according to a tenth embodiment.

15 (1) is a plan view of an embedding material unit according to an eleventh embodiment, and FIG. 15 (2) is a side view of the same.

FIG. 16 is a cross-sectional view showing a hollow slab and a method for constructing the hollow slab.

FIG. 17 is a cross-sectional view of the PC board according to the first embodiment.

FIG. 18 is a cross-sectional view of the PC board according to the second embodiment.

FIG. 19 is a cross-sectional view of a conventional hollow slab.

[Explanation of symbols]

1, 8, 9, 12, 13, 15, 16, 17, 18, 1
9, 20 Embedding material unit 2, 36 Lightweight embedding material 3 Connecting material 4 Upper hemisphere 5 Lower hemisphere 5a Hemisphere 6 Recessed groove 7 Fitting protrusion 10 Locking material 11 Notch groove 14 Projection 21 Slab form 22 Bottom plate 23 Fixed Tool 24 Fixing pin 25, 37 Upper reinforcing bar 26 Fastener 27, 39 Concrete 28, 35 Hollow slab 29, 31 PC board 30 Concrete plate 32 Recess 33 Notch 38 Lower reinforcing bar

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Masaki Takiguchi             Tochigi Prefecture Nasu-gun Nishinasuno-cho 4 Ward-cho 1534-1             Goyo Construction Co., Ltd. Technical Research Center (72) Inventor Yasuyuki Hosoi             Tochigi Prefecture Nasu-gun Nishinasuno-cho 4 Ward-cho 1534-1             Goyo Construction Co., Ltd. Technical Research Center (72) Inventor Yoshiyuki Murata             Tochigi Prefecture Nasu-gun Nishinasuno-cho 4 Ward-cho 1534-1             Goyo Construction Co., Ltd. Technical Research Center

Claims (11)

[Claims] 1. An embedding material unit, wherein the lightweight embedding material is vertically separable, and at least one of the vertically divided lightweight embedding materials is connected by a connecting material. 2. An embedding material unit, wherein light-weight embedding materials arranged at appropriate intervals are connected by a connecting material, and a cross-shaped notch groove is formed on an upper portion of the light-weight embedding material. 3. The embedding material unit according to claim 1, wherein a cross-shaped notch groove is formed in an upper portion of the lightweight embedding material. 4. The potting material unit according to claim 1, wherein the lightweight potting material has a spherical shape or a capsule shape. 5. The embedding material unit according to claim 1, wherein the lightweight embedding material and the connecting material are integrally molded. 6. The embedding material unit according to claim 1, wherein a protrusion is formed between adjacent lightweight embedding materials. 7. A hollow slab, wherein the embedding material unit according to claim 1 is embedded in concrete of a slab. 8. The embedding material unit according to any one of claims 1 to 6 is installed in a slab form, and the upper reinforcing bar of the slab arranged on the upper surface of the lightweight embedding material is fixed by a lifting preventive tool,
A method for constructing a hollow slab, which comprises placing concrete in a slab formwork. 9. The method for constructing a hollow slab according to claim 8, wherein the connecting bar of the lightweight embedding material is bound to the upper reinforcing bar or the lower reinforcing bar. 10. A precast concrete board, wherein the embedding material unit according to claim 1 is installed on a concrete board. 11. A spherical or capsule-shaped lightweight embedding material is installed in a concrete board at appropriate intervals so that a notch portion provided with a recess or a protrusion is embedded, and the lightweight embedding material is a connecting material. Precast concrete board characterized by being connected.