JP6378563B2 - Void material for concrete - Google Patents

Description

  The present invention relates to a void member embedded in a concrete structure such as a concrete slab.

In a concrete structure such as a concrete slab, it is known to embed a void member in order to reduce the amount of concrete placed and reduce the weight.
For example, the void member of Patent Document 1 has an octagonal horizontal cross-sectional shape in the middle portion in the vertical direction. Therefore, it is an octagon in plan view. Moreover, the upper surface and the lower surface are squares smaller than the horizontal cross section of the intermediate part. The four side surfaces of the intermediate portion and the four sides of the upper and lower surfaces are respectively connected by four rectangular inclined surfaces. The remaining four side surfaces of the intermediate portion and the four corner portions of the upper and lower surfaces are respectively connected by four triangular slopes. The upper four triangular slopes are triangular slopes that point toward the upper surface. The lower four triangular slopes are triangular slopes that point toward the lower surface.

Japanese Patent No. 5259465

The void member of the above-mentioned Patent Document 1 has the largest horizontal cross-sectional area at the intermediate portion, but the intermediate portion has an octagonal cross section, so the degree of weight loss of the concrete is small. On the other hand, there is a need to ensure the filling of concrete.
An object of this invention is to enlarge the weight reduction degree of concrete, ensuring the filling property of concrete.

In order to solve the above problems, the present invention is a void member for concrete embedded in a concrete structure,
An intermediate part having four laterally long sides and a horizontal section being a quadrangle;
A pair of upper and lower conical portions that protrude in the vertical direction from the intermediate portion and have a horizontal cross-section that decreases as the distance from the intermediate portion increases;
Each of the cones has a top surface facing away from the intermediate portion, four main slopes, and four triangular slopes,
The top surface is an octagon smaller than the horizontal cross-sectional area of the intermediate portion;
Each of the main slopes connects one corresponding side surface in the intermediate portion and one side parallel to the one side surface in the top surface,
Each of the triangular slopes is a triangle that is interposed between two adjacent main slopes and the top surface and has a triangular shape that widens in the horizontal direction toward the top surface. According to the member, by making the intermediate part into a square cross section, the degree of weight loss of the concrete can be increased as compared with an octagonal cross section. Further, by providing a triangular slope at the corner portion of the cone portion and making the top surface octagonal, it is possible to ensure the filling property of the concrete.

Each of the main slopes preferably has a hexagonal shape that intersects two main slopes on both sides in the width direction of the main slope, the one side face, the top face, and two triangular slope faces. .
As a result, since the portion on the top surface side of the conical portion has an octagonal cross section, the filling property of the concrete can be ensured. Moreover, since the part by the side of the said intermediate part of the said cone becomes a square cross section, the weight reduction degree of concrete can be enlarged.

  According to the void member for concrete according to the present invention, the degree of weight loss of the concrete can be increased while ensuring the filling property of the concrete.

FIG. 1 shows a concrete void member according to an embodiment of the present invention, where FIG. 1 (a) is a plan view thereof and FIG. 1 (b) is a bottom view thereof. FIG. 2 is a front view of the void member. FIG. 3 is a perspective view of the void member. FIG. 4 is a plan sectional view showing a concrete slab including the void member and taken along line IV-IV in FIG. 5. FIG. 5 is a front cross-sectional view of the concrete slab along the line V-V in FIG. 4. FIG. 6 is a side cross-sectional view of the concrete slab along the line VI-VI in FIG. 4.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
4 to 6 show a concrete slab 1 (concrete structure) used as a floor of a building, for example. The concrete slab 1 includes a concrete 2 and a reinforcing bar assembly 4. The reinforcing bar assembly 4 includes a main bar 40 and a distribution bar 41 that are orthogonal to each other. Further, a plurality of concrete void members 3 (hereinafter referred to as “void members 3”) are embedded in the concrete 2 for weight reduction. A plurality of void members 3 are arranged vertically and horizontally. These void members 3 are made of a lighter material than the concrete 2, and are preferably made of a foamed resin such as foamed polystyrene.

  As shown in FIGS. 1 to 3, each void member 3 includes an intermediate portion 10 and a pair of upper and lower cone portions 20 and 30. The intermediate part 10 has four side surfaces 11 and has a substantially square (quadrangle) horizontal cross section. The side surface 11 is a horizontally long rectangle (quadrangle). Here, the horizontal direction means that the horizontal dimension is larger than the vertical dimension. The horizontal dimension of the side surface 11 is, for example, about 100 mm to 500 mm, and preferably about 300 mm. The vertical dimension (height) of the side surface 11 is, for example, about 5 mm to 200 mm, and preferably about 100 mm. Moreover, the height of the whole void member 3 is about 100 mm-300 mm, for example, Preferably it is about 150 mm.

  The upper cone portion 20 is integrally provided above the intermediate portion 10, and the lower cone portion 30 is integrally provided below the intermediate portion 10. The upper cone portion 20 and the lower cone portion 30 have a vertically symmetrical cone shape with the intermediate portion 10 interposed therebetween. That is, the conical portions 20 and 30 protrude from the intermediate portion 10 in the vertical direction, and the horizontal cross section decreases as the distance from the intermediate portion 10 increases.

  Specifically, the schematic shape of the upper cone portion 20 is a square frustum. More specifically, the upper cone portion 20 has a shape in which the four corner portions at the top of the regular quadrangular pyramid are cut obliquely. Therefore, the upper cone portion 20 has an upper surface 21 (top surface), four main inclined surfaces 22, and four triangular inclined surfaces 23.

  The upper surface 21 faces the opposite side to the intermediate portion 10 in the upper cone portion 20, has four main sides 21 a and four oblique sides 21 b, and has an octagon smaller than the horizontal cross-sectional area of the intermediate portion 10. . Each main side 21 a is parallel to the corresponding one side surface 11. The oblique side 21b is shorter than the main side 21a and is inclined with respect to the adjacent main sides 21a and 21a. The angle (inner angle) formed by the main side 21a and the oblique side 21b is preferably about 135 °.

  A convex surface portion 24 is provided at the center of the upper surface 21. The convex part 24 is square (quadrangle) in plan view, and its thickness (projection height) is, for example, less than 2 cm, and preferably about 1 cm.

Each main slope 22 connects the corresponding one side surface 11 in the intermediate portion 10 and the main side 21 a parallel to the one side surface 11 in the upper surface 21. Each main slope 22 includes two main slopes 22 and 22 on both sides in the width direction (horizontal direction) of the main slope 22, the one side surface 11, the upper surface 21, and two triangular slopes 23 and 23. By crossing, it becomes a hexagon. The inclination angle α ₂₂ of the main slope 22 with respect to the horizontal plane is preferably about α ₂₂ = 30 ° to 60 °, and more preferably about α ₂₂ = 45 °.

The triangular slope 23 is a triangle that is interposed between two adjacent main slopes 22, 22 and the upper surface 21 and widens in the horizontal direction toward the upper surface 21. The inclination angle α ₂₃ of the triangular slope 23 with respect to the horizontal plane is smaller than the inclination angle α ₂₂ of the main slope 22 (α ₂₃ <α ₂₂ ), preferably about α ₂₃ = 20 ° to 40 °, more preferably α ₂₃ =. It is about 30 °. The upper side of the triangular slope 23 coincides with the oblique side 21 b of the upper surface 21. Three surfaces 22, 22, 23 intersect at the lower end of the triangular slope 23. This intersection 20c is located at the intermediate height of the upper cone 20. The horizontal cross section of the upper cone portion 20 above the intersection 20c is an octagon, and the horizontal cross section below the intersection 20c is a rectangle.

  The schematic shape of the lower cone 30 is an inverted quadrangular pyramid. More specifically, the lower cone 30 has a shape in which four corners of the downward apex of the inverted quadrangular pyramid are cut obliquely. Therefore, the lower cone 30 has a lower surface 31 (a top surface facing away from the intermediate portion 10), four main inclined surfaces 32, and four triangular inclined surfaces 33.

  The lower surface 31 has four main sides 31 a and four oblique sides 31 b, and is an octagon smaller than the horizontal cross-sectional area of the intermediate portion 10. Each main side 31 a is parallel to the corresponding one side surface 11. The oblique side 31b is shorter than the main side 31a and is inclined with respect to the adjacent main sides 31a and 31a. The angle (inner angle) formed by the main side 31a and the hypotenuse 31b is preferably about 135 °.

  A convex surface portion 34 is provided at the center of the lower surface 31. The convex portion 34 is square (quadrangle) in plan view, and its thickness (projection height) is, for example, less than 1 cm, preferably about 5 mm.

Each main slope 32 connects one corresponding side surface 11 in the intermediate portion 10 and a main side 31 a parallel to the one side surface 11 in the lower surface 31. Each main slope 32 has a hexagonal shape by intersecting the other two main slopes 32, 32, the one side surface 11, the lower surface 31, and the two triangular slopes 33, 33. . The inclination angle α ₃₂ of the main slope 32 with respect to the horizontal plane is preferably about α ₃₂ = 30 ° to 60 °, and more preferably about α ₃₂ = 45 °.

The triangular slope 33 is interposed between two adjacent main slopes 32, 32 and the lower surface 31, and has a triangular shape. The inclination angle α ₃₃ of the triangular slope 33 with respect to the horizontal plane is smaller than the inclination angle α ₃₂ of the main slope 32 (α ₃₃ <α ₃₂ ), preferably α ₃₃ = about 20 ° to 40 °, more preferably α ₃₃ =. It is about 30 °. The lower side of the triangular slope 33 coincides with the hypotenuse 31 b of the lower surface 31. Three surfaces 32, 32, 33 intersect at the upper end of the triangular slope 33. This intersection point 30 c is located at an intermediate height of the lower cone 30. The horizontal cross section of the part below 3c in the lower cone part 30 is an octagon, and the horizontal cross section of the part above the intersection 30c is a rectangle.

  As shown in FIGS. 4 to 6, in the concrete slab 1, the main reinforcement 40 and the distribution bar 41 are arranged between the adjacent void members 3 and 3. Each of the main reinforcing bars 40 and the distribution bars 41 has two levels in the vertical direction (thickness direction of the concrete slab 1). The upper main bar 40 and the distribution bar 41 are arranged at a height near the upper surface 21 of the void member 3. The lower main bars 40 and the distribution bars 41 are arranged at a height near the lower surface 31 of the void member 3. The upper and lower portions of the void member 3 with the intermediate portion 10 interposed therebetween are substantially quadrangular frustum-shaped cone portions 20 and 30, respectively, so that the arrangement space for the main reinforcement 40 and the distribution reinforcement 41 can be easily secured.

A plurality of void presser bars 42 and void receiving bars 43 are embedded in the concrete slab 1. The void presser bar 42 is arranged in the upper stage, extends in parallel with the upper main bar 40, and intersects the distribution bar 41. The void receiving bar 43 is arranged in the lower stage, intersects with the lower main bar 40, and extends in parallel with the distribution bar 41. Therefore, the void presser bar 42 and the void receiver bar 43 are directed in directions orthogonal to each other.
The void presser bar 42 may be parallel to the distribution bar 41, and the void receiver bar 43 may be parallel to the main bar 40.

  As shown in FIGS. 5 and 6, each void member 3 is sandwiched from above and below by two void presser bars 42 and two void receiver bars 43. Further, the upper convex portion 24 is inserted between the two void presser bars 42, and the lower convex portion 34 is inserted between the two void receiver bars 43. Thereby, when constructing the reinforcing bar assembly 4, the void member 3 can be stably arranged inside the reinforcing bar assembly 4. Further, the void member 3 can be easily and accurately positioned. Furthermore, when placing the concrete 2, the void member 3 can be held so as not to be moved by the flow pressure of the concrete 2 at the time of placing. Since the void presser bar 42 and the void receiving bar 43 are directed in directions orthogonal to each other, the swinging of the void member 3 can be reliably prevented.

The concrete 2 is filled between the void members 3 and 3 while wrapping along the peripheral surface of each void member 3. Since the top surfaces 21 and 31 of the void member 3 are octagonal, the concrete 2 can easily go around the void member 3 rather than being quadrangular. Furthermore, since the portions closer to the top surfaces 21 and 31 than the intersections 20c and 30c in the cone portions 20 and 30 have an octagonal cross section, the filling property of the concrete 2 can be further ensured.
On the other hand, when the intermediate portion 10 in which the horizontal sectional area of the void member 3 is maximized is a quadrangular cross section, the volume of the void member 3 can be increased and the concrete 2 can be sufficiently reduced. Furthermore, the volume of the void member 3 can be made sufficiently large and the amount of the concrete 2 can be further reduced by making the portion of the conical portions 20 and 30 closer to the intermediate portion 10 than the intersections 20c and 30c to have a rectangular cross section. .

The present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the present invention.
For example, the horizontal cross section of the intermediate portion 10 is not limited to a square, but may be another rectangle such as a rectangle.
The intersection 20c may extend to the boundary between the upper cone portion 20 and the intermediate portion 10 and reach the corner between the side surfaces 11 and 11. In this case, the main slope 22 is trapezoidal (square).
The intersection 30c may extend to the boundary between the lower cone portion 30 and the intermediate portion 10 and reach the corner between the side surfaces 11 and 11. In this case, the main slope 32 is trapezoidal (square).
The upper cone 20 and the lower cone 30 may be asymmetric.
The convex surface portion 24 may be omitted. The convex surface portion 34 may be omitted. A groove into which the void presser bar 42 or the void receiving bar 43 fits may be formed in the upper surface 21 or the lower surface 31 instead of the convex surface parts 24 and 34.

  The present invention can be applied to the construction of a reinforced concrete structure, for example.

1 Concrete slab (concrete structure)
2 Concrete 3 Void member 10 Middle part 11 Side surface 20 Upper cone part (cone part)
21 Top (top)
21a Main side (1 side)
22 Main slope 23 Triangular slope 30 Lower cone (cone)
31 Bottom (top)
31a Main side (1 side)
32 Main slope 33 Triangular slope

Claims (2)

A void member embedded in a concrete structure,
An intermediate part having four laterally long sides and a horizontal section being a quadrangle;
A pair of upper and lower conical portions that protrude in the vertical direction from the intermediate portion and have a horizontal cross-section that decreases as the distance from the intermediate portion increases;
Each of the cones has a top surface facing away from the intermediate portion, four main slopes, and four triangular slopes,
The top surface is an octagon smaller than the horizontal cross-sectional area of the intermediate portion;
Each of the main slopes connects one corresponding side surface in the intermediate portion and one side parallel to the one side surface in the top surface,
Each of the triangular slopes is a triangle that is interposed between two adjacent main slopes and the top surface and is widened in the horizontal direction toward the top surface, and is adjacent to the triangular slope portion. The intersection with two main slopes is located between the intermediate height of the cone part and the intermediate part, and the top surface side from the intersection point in the cone part, that is, at least the part on the top surface side from the intermediate height A void member for concrete, characterized in that the horizontal section of the is an octagon .   Each of the main slopes has a hexagonal shape that intersects two main slopes on both sides in the width direction of the main slope, the one side face, the top face, and two triangular slope faces. The void member for concrete according to claim 1.

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