JP6024961B2 - Steel concrete floor structure - Google Patents

Description

  The present invention relates to the structure of a steel plate concrete floor.

  As is well known, steel plate concrete construction (SC structure) is made of steel plate with the outer shell of the structural frame (floor, wall, column, beam, etc.) filled with concrete and planted on the inner surface of the steel plate It is a structure in which steel plate and concrete are structurally integrated through a large number of studs, and it is possible to efficiently construct a robust housing with a large cross section in a large-scale structure such as a building in a nuclear facility. In recent years, it has become widespread (see, for example, Patent Documents 1 to 6).

  FIG. 5 shows an example of the floor structure of this type of steel plate concrete construction. This is based on a so-called full SC structure in which the upper surface and the lower surface (bottom surface) of the floor are both formed by the outer shell steel plate 1, and the outer shell steel plate is inserted through a number of studs 2 planted on the inner surface of the outer shell steel plate 1. By integrating 1 and the concrete 3 filled therein, the whole behaves structurally and integrally.

  In the example shown in FIG. 5, the wall is made of steel plate concrete similar to the floor. That is, both the inner and outer surfaces of the wall are formed of the outer shell steel plate 1, and the concrete 3 filled in the inner portion of the inner wall of the outer shell steel plate 1 through the studs 2 is formed by the outer shell. It is integrated with the steel plate 1.

JP 2012-132279 A JP 2012-132278 A JP 2012-117328 A JP 2012-63153 A JP 2011-69133 A Japanese Patent No. 4658826

  By the way, the conventional general steel plate concrete floor as shown in FIG. 5 has the following problems in its construction, and it is necessary to develop effective improvement measures in that respect.

That is, when the concrete 3 is cast and filled between the upper and lower outer shell steel plates 1 in the construction of the floor, the concrete is placed in the main portion of the upper shell steel plate 1 as shown in FIG. It is necessary to provide an opening 4 for air and an opening 5 for venting air, and there are cases where stiffening of cross-sectional defects by providing these openings 4 and 5 is required.
In addition, it cannot always be easily confirmed from the upper surface of the floor whether the concrete 3 is reliably filled in the entire space between the upper and lower outer shell steel plates 1, and the outer shell steel plate on the upper surface side due to shrinkage accompanying the hardening of the concrete 3. It is also assumed that a gap is formed at the boundary between 1 and concrete 3, and in that case, there is a concern that the stud 2 may not be able to obtain a predetermined yield strength. And advanced construction management is indispensable.

In order to avoid the above problem, it is also considered to form a so-called half SC structure in which only the lower surface (bottom surface) is formed of the outer shell steel plate 1 and the upper shell steel plate 1 is omitted. However, in that case, it is necessary to arrange reinforcing bars in place of the outer shell steel plate 1 on the upper surface side, and not only the required amount of reinforcement is enormous, but also the outer shell steel plate 1 for walls is not equipped with reinforcing bars. Complicated arrangements such as providing a through-hole for allowing penetration are required.
Therefore, in the case of the half SC structure, the construction work and cost are significantly disadvantageous compared to the case of the full SC structure, and the original advantages of steel plate concrete construction are greatly impaired. Unfavorable and unrealistic.

  In view of the above circumstances, an object of the present invention is to provide an effective and suitable steel plate concrete floor structure that can solve the above-described problems when constructing a conventional steel plate concrete floor. .

  The present invention is a steel plate concrete floor structure in which an upper surface and a lower surface are each formed of a shell steel plate, and concrete is filled and integrated between the shell steel plates, and the top surface of the floor is formed. The outer shell steel plate is a grid-like perforated steel plate in which a large number of openings are arranged between the vertical and horizontal belt-like portions, and the inner surface side of the belt-like portion in the perforated steel plate as the outer shell steel plate A perforated rib steel plate is provided.

  According to the present invention, by using a perforated steel plate having a large number of openings as an outer shell steel plate serving as an upper surface of the floor, the openings are used as openings for placing concrete or air vents at that time. Therefore, it is possible to perform the concrete placement and the air venting on the entire surface of the outer shell steel plate without any hindrance and surely, and it is possible to confirm the state of filling the concrete with respect to the whole floor without any hindrance.

In addition, the perforated rib steel plate provided on the lower surface side of the perforated steel plate as the outer shell steel plate functions as a stud and can transmit shear more than a mere stud, and the perforated steel plate and concrete can be connected to the perforated rib steel plate. It is possible to make it firmly and firmly integrated via
Furthermore, by appropriately adjusting the thickness and height of the perforated rib steel plate, it is possible to compensate for a cross-sectional defect due to the outer steel plate being a perforated steel plate due to its stiffening effect.

It is a top view which shows the structure of the floor which is embodiment of this invention. FIG. 2 is a cross-sectional view of the same, taken along line IIa-IIa in FIG. 1 and (b) is an enlarged view of a portion b in (a). (A), (b) is a figure which shows the example of a structure of the perforated steel plate as an outer shell steel plate, respectively. (A), (b) is a figure which shows the other structural example of a perforated steel plate as an outer shell steel plate, respectively. It is sectional drawing which shows the structure of the floor by the conventional general steel plate concrete structure.

An embodiment of the floor structure of the present invention will be described with reference to FIGS.
FIG. 1 is a plan view showing a part of the floor and surrounding walls of the present embodiment, FIG. 2 is a cross-sectional view thereof, (a) is a view taken along line IIa-IIa in FIG. It is an enlarged view of the b section in a). Note that, among the components in the structure of the present embodiment, elements common to the conventional structure shown in FIG.

The floor structure of the present embodiment is basically the same as the conventional general structure shown in FIG. 5, and the upper surface and the lower surface are formed by the outer shell steel plates 1 and the outer shell steel plates 1 are positioned between the upper and lower outer shell steel plates 1. The concrete 3 is filled and integrated.
That is, also in this embodiment, as in the conventional case, the outer shell steel plate 1 forming the lower surface (bottom surface) of the floor is the same as that shown in FIG. The concrete 3 is integrated with the outer shell steel plate 1 through a large number of studs 2 planted in 1. The wall is also configured in the same manner as shown in FIG.

However, in this embodiment, instead of using a conventional flat steel plate as the outer shell steel plate 1 forming the upper surface of the floor, a perforated steel plate 10 as shown in FIG. 1 is used, In addition, as shown in FIG. 2, the stud 2 is omitted from the perforated steel sheet 10 and a perforated rib steel sheet 15 is provided instead.
That is, in this embodiment, the outer shell steel plate 1 that forms the upper surface of the floor is a lattice-like perforated steel plate 10 in which a large number of openings 12 are arranged in an orderly manner between vertical and horizontal strips 11, In addition, the main object is to provide a perforated rib steel plate 15 on the inner surface side of the belt-like portion 11 in the perforated steel plate 10.

  In the present embodiment, the perforated steel sheet 10 used as the outer shell steel sheet 1 on the upper surface side may be constructed using, for example, a unit as shown in FIG. 3 or FIG.

The unit shown in FIG. 3 is formed in a state in which a large number of square-shaped and same-sized openings 12 are regularly arranged at equal intervals on a flat steel plate having a predetermined size, and the outer peripheral portion is half the size of the openings 12. By forming the notch 13, the vertical and horizontal strips 11 are left in a state where they are crossed in a lattice pattern, and these units are laid out at the position to be the upper surface of the floor and the notch 13 As a result, the perforated steel sheet 10 as the outer shell steel sheet 1 as shown in FIG. 1 can be formed as a whole.
It should be noted that the units shown in FIGS. 3A and 3B have substantially the same form except for the size. In other words, the unit shown in (a) has a configuration in which five belt-like portions 11 in the vertical direction and six belt-like portions 11 in the horizontal direction are combined in a lattice shape, and the unit shown in (b) is in the vertical direction. In this embodiment, two strips 11 and six strips 11 in the horizontal direction are combined in a lattice pattern.

The unit shown in FIG. 4A becomes a band-like portion 11 in the other direction (the same as the longitudinal direction) with respect to the side portion of the long steel plate that becomes the belt-like portion 11 in one direction (in the illustrated example, the horizontal direction). A steel plate is provided as the protrusion 14, and the units 12 are juxtaposed and the protrusions 14 are abutted and welded to form an opening 12 between them. As shown in FIG. A perforated steel sheet 10 as 1 is formed.
Furthermore, what is shown in FIG. 4B is a mere long steel material that becomes a strip-like portion 11 in one direction (lateral direction in the illustrated example) and a mere short length that becomes a strip-like portion 11 in the other direction (the same as the longitudinal direction). 1 are used as a whole and welded by combining them in a lattice shape as a whole, thereby forming an opening 12 between them and forming a perforated steel plate 10 as an outer shell steel plate 1 as shown in FIG. Is.

In any case, each unit as described above needs to be manufactured as having a function capable of functioning as the outer shell steel plate 1 in the steel concrete floor. The thickness, cross-sectional shape, and other specifications may be set as appropriate in consideration of the floor area and workability.
And it is good to weld the perforated rib steel plate 15 in advance to these units in advance, and such units are prefabricated in advance according to a predetermined standard, then carried to the site and sequentially laid. As a result, it is possible to easily and efficiently construct the perforated steel sheet 10 as the outer shell steel sheet 1 with substantially the same procedure and labor as in the past.

  The perforated rib steel plate 15 integrally welded to the inner surface (lower surface) of the band-like portion 11 in the perforated steel plate 10 as the outer shell steel plate 1 is a strip plate as shown in FIGS. 2 (a) and 2 (b). A large number of circular holes 16 are formed at a predetermined interval with respect to the plate-shaped steel plate. It is provided so as to form a lattice shape in a state of intersecting with.

  By providing such a perforated rib steel plate 15, when the concrete 3 is filled between the upper and lower outer shell steel plates 1 during construction of the floor, the entire perforated rib steel plate 15 is embedded in the concrete 3. At the same time, the concrete 3 is naturally filled into the holes 16 formed in the perforated rib steel plates 15. Therefore, the perforated rib steel plate 15 is provided with a shear resistance performance in the in-plane direction, and functions effectively as a stud for integrating the concrete 3 with the perforated steel plate 10 as the outer shell steel plate 1. Even if a gap is formed at the boundary between the perforated steel sheet 10 and the concrete 3 due to shrinkage accompanying the hardening of the concrete 3, the concrete 3 is filled in the holes 16 of the perforated rib steel sheet 15. Sufficient stress transmission is possible.

  According to the floor structure of the present embodiment having the above-described configuration, the perforated steel sheet 10 having a large number of openings 12 is used as the outer shell steel plate 1 serving as the upper surface of the floor, so that the openings 12 are made of concrete. It can be used as it is as an opening for installation or as an opening for venting at that time. Therefore, when using a simple flat steel plate as shown in FIG. 5, it is necessary to provide special openings 4 and 5 which are necessary. Therefore, it is possible to perform concrete placement and air venting on the entire surface of the outer shell steel plate 1 without any hindrance, and it is possible to confirm the filling state of the concrete 3 with respect to the whole floor surface from the top of the floor without any hindrance.

In addition, since the concrete 3 can be additionally piled on the upper portion of the opening 12, it is possible to place such that the piled concrete is allowed to settle following the contraction accompanying the hardening of the concrete 3. In that case, the surplus concrete may be scraped and removed when the concrete 3 is almost completely settled.
Although it is possible to level the surplus concrete as the floor finish surface, in that case, since the surplus concrete becomes a cover concrete for the outer shell steel plate 1, it is necessary to take measures against cracking.

Moreover, the perforated rib steel plate 15 provided on the lower surface side of the perforated steel plate 10 as the outer shell steel plate 1 and functioning as a stud is more resistant to shear transmission than the stud by adjusting the size and interval of the holes 16. In other words, it is possible to cover the strength of several studs with one hole 16.
Therefore, according to the floor structure of the present embodiment, it is possible to sufficiently ensure the transmission performance of bending stress and shearing force in the material axis direction at the boundary of the floor upper surface, and to connect the perforated steel sheet 10 and the concrete 3 with the perforated rib steel sheet 15. Therefore, although the perforated steel plate 10 is used as the outer shell steel plate 1, the structural performance equivalent to that of the conventional full SC structure can be ensured.

Furthermore, although the perforated steel plate 10 is used as the outer shell steel plate 1 in the present embodiment, the cross-sectional defect is caused by the aperture ratio of the perforated steel plate 10 (that is, the size and interval of the openings 12, that is, the band-like portion 11. By appropriately adjusting the height dimension and thickness of the perforated rib steel plate 15 according to the width dimension and interval), it is possible to reliably compensate without requiring any special stiffening means. is there.
Of course, it is not necessary to arrange reinforcing bars as in the case of the half SC structure in which the outer surface steel plate 1 on the floor upper surface side is omitted, and the perforated steel plate 10 as the outer surface steel plate 1 is unitized as described above. It is extremely reasonable as a floor structure of steel plate concrete structure (full SC structure) because mass production with a specified standard by the method can contribute to cost reduction, improvement of workability on site and improvement of construction accuracy. It is valid.

1 Outer steel plate 2 Stud 3 Concrete 4,5 Opening 10 Perforated steel plate (outer steel plate)
DESCRIPTION OF SYMBOLS 11 Band-shaped part 12 Opening part 13 Notch part 14 Protrusion part 15 Perforated rib steel plate 16 Hole

Claims (1)

The upper surface and the lower surface are each formed of a shell steel plate and filled with concrete between the shell steel plates to be integrated into a steel plate concrete floor structure,
The outer shell steel plate forming the upper surface of the floor is a grid-like perforated steel plate in which a large number of openings are arranged between vertical and horizontal strips,
A perforated rib steel plate is provided on the inner surface side of the belt-like portion of the perforated steel plate as the outer shell steel plate, and the floor structure of the steel plate concrete structure is provided.

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