JP2018193820A - Slab structure - Google Patents

Abstract

To provide slab structure which can make weight of the slab light and reduce time and labor for formwork.SOLUTION: Slab structure includes beam members 32, 42 each formed by H-shaped steel, panel members 52 bridged between lower flanges 32FB, 42FB of beam members 32, 42 adjacent to each other, and concrete members 70 that are installed on top faces of the panel members 52 and are heavier than the panel members 52.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a slab structure.

  The following Patent Document 1 discloses a floor method in which slab concrete is placed on-site above a reinforced concrete beam.

JP 7-207800 A

  However, when the slab is formed only from on-site concrete as in Patent Document 1, the weight of the slab is large compared to the case where the slab is formed using a material such as an ALC panel, and the beam is burdened. In addition, a slab formwork is required, which takes time and labor for formwork construction.

  In view of the above facts, an object of the present invention is to provide a slab structure that can reduce the weight of the slab and reduce the labor of the formwork.

  The slab structure according to claim 1 includes a beam member formed of an H-shaped steel, a panel member bridged between lower flanges of the beam members adjacent to each other, and an upper surface of the panel member. A concrete member heavier than the member.

  According to the slab structure of claim 1, the slab is formed by the panel member and the concrete member heavier than the panel member. That is, the slab is formed of a panel member and a concrete member that are lighter than the concrete member. For this reason, a slab can be reduced in weight compared with the case where it forms only with a concrete member. Moreover, since the panel member can be used as a formwork, it is not necessary to remove it, and the formwork can be reduced.

  In the slab structure of claim 2, the web and upper flange of the beam member are covered with the concrete member, and a through-hole through which a pipe can pass is formed in the concrete member and the web.

  According to the slab structure of claim 2, the pipe passes through the web of the beam member and the through hole of the concrete member. For this reason, the piping can be laid in the direction in which the beam extends, or in the direction intersecting with the direction in which the beam extends. As a result, the piping can be bridged in the space on both sides of the beam member, so that the facility planning is easy. Further, since the web is coated with the concrete member, it is not necessary to reinforce the web around the through hole if the concrete member is reinforced.

  According to the slab structure according to the present invention, the slab can be reduced in weight, and the labor for the formwork can be reduced.

It is a top view which shows the column beam frame to which the slab structure which concerns on embodiment of this invention is applied, and has shown the state which spanned the panel member which forms a part of slab between a beam and a small beam. It is the 2-2 sectional view taken on the line in FIG. 1 which showed the slab structure which concerns on embodiment of this invention. It is the 3-3 sectional view taken on the line in FIG. 1 which showed the slab structure which concerns on embodiment of this invention. (A) is a partial cross-sectional view showing a modification in which the joining member according to the embodiment of the present invention is replaced with a reinforcing bar, (B) is a partial cross-sectional view showing a modification in which the joining member is replaced with an angle member, (C) is a partial sectional view showing a modification in which a joining member is inserted into a through hole formed in a beam member instead of a reinforcing bar.

(Frame)
The slab structure according to this embodiment is a configuration of a floor slab installed on a column beam frame 10 shown in FIG. The column beam frame 10 includes a steel reinforced concrete column 20, a steel reinforced concrete beam 30 spanned over the column 20, and a steel reinforced concrete small beam 40 spanned over the beam 30 ( SRC).

  The beam 30 includes a beam member 32 formed of H-shaped steel and a concrete 34 that covers the beam member 32. Similarly, the small beam 40 includes a beam member 42 formed of H-shaped steel and a concrete 44 that covers the beam member 42. In FIG. 1, the state before placing the concrete 34, 44 is shown by a solid line, and the concrete 34, 44 is shown by a two-dot chain line.

(Slab structure)
As shown in FIG. 2, a CLT panel member 52 is bridged between the beam member 32 in the adjacent beam 30 and the beam member 42 in the small beam 40. Specifically, both end portions of the panel member 52 are placed on the lower flange 32FB of the beam member 32 and the lower flange 42FB of the beam member 42, respectively. Similarly, the panel member 52 is bridged between the beam members 42 in the adjacent small beams 40.

  As shown in FIG. 1, the panel member 52 is bridged so that the longitudinal direction extends along the direction (arrow X direction) orthogonal to the material axis direction (arrow Y direction) of the beam 40. Both end portions in the direction (that is, portions close to the corners of the panel member 52) are joined to the beam member 32 or the beam member 42 via the joining member 60.

(Joining member)
As shown in FIG. 3, the joining member 60 is configured by reinforcing an unequal side angle 62 having an L-shaped cross section with a rib 64.

  In the joining member 60, the short side of the unequal side angle 62 is bolted to the web 32 </ b> W of the beam member 32, and the long side of the unequal side angle 62 is fixed to the panel member 52 with a lag screw. Thereby, the end of the panel member 52 is rigidly joined to the beam member 32. Although not shown, one bolt is provided on each side of the rib 64, and four lag screws are provided on each side of the rib 64, and slanted against the panel member 52 (the surface of the panel member 52). It is driven incline with respect to).

  The joining member 60 is similarly fixed to the beam member 42. That is, in the joining member 60, the short side of the unequal side angle 62 is bolted to the web 42W of the beam member 42, and the long side of the unequal side angle 62 is fixed to the panel member 52 with a lag screw. As a result, the end of the panel member 52 is rigidly joined to the beam member 42.

(Concrete member)
As shown in FIG. 2, concrete 54 is cast on the upper surface of the panel member 52 to form a slab 50. Above the concrete 54, the concrete 34 covering the web 32W and the upper flange 32FU of the beam member 32 in the beam 30 and the concrete 44 covering the web 42W and the upper flange 42FW of the beam member 42 in the small beam 40 are hit. It is installed.

  Moreover, the concrete 54 and the concrete 34 are integrated, and the concrete 54 and the concrete 44 are integrated. As a result, the column beam frame 10 has an inverted beam structure in which the steel reinforced concrete beam 30 and the small beam 40 protrude in a convex shape from the upper surface of the slab 50 in the portion where the slab structure according to the present embodiment is applied. It has become. In the following description, a member in which these concretes 34, 44, 54 are integrated may be referred to as a concrete member 70.

  A slab bar (not shown) is arranged above the panel member 52 before the concrete 54 is placed, and the beam members 32 and 42 are shown before the concrete 34 and 44 are placed. The main beam bars and stirrups are not arranged. That is, the concrete member 70 has a configuration in which reinforcing bars are arranged inside the concrete.

  Here, the concrete member 70 has a larger weight per unit volume than the panel member 52 made of CLT. In other words, the concrete member 70 has a higher density than the panel member 52. For this reason, compared with the case where a slab is formed using only the concrete member 70 without using the panel member 52, the slab 50 is light.

(Through hole)
As shown in FIG. 2, a through hole 32 </ b> H is formed in the web 32 </ b> W of the beam member 32, and a through hole 34 </ b> H is formed in the concrete 34. Further, the through hole 32H and the through hole 34H are in communication with each other, and form the through hole 30H of the beam 30.

  Similarly, a through hole 42H is formed in the web 42W of the beam member 42, and a through hole 44H is formed in the concrete 44. Further, the through hole 42H and the through hole 44H communicate with each other, and form the through hole 40H of the small beam 40.

(Action / Effect)
According to the slab structure according to the present embodiment, as shown in FIG. 2, the slab 50 is formed of a panel member 52 made of CLT and a concrete member 70 heavier than the panel member 52. For this reason, compared with the case where a slab is formed using only the concrete member 70 without using the panel member 52, the slab 50 is lighter and the burden on the small beam 40 or the beam 30 is small.

  Moreover, since the panel member can be used as a formwork, it is not necessary to remove it, and the formwork can be reduced. For this reason, workability is high.

  The slab structure according to the present embodiment is a reverse beam structure in which a steel reinforced concrete beam 30 and a small beam 40 protrude from the upper surface of the slab 50 in a convex shape. For this reason, by laying a floor finishing material 82 (a floor finishing surface is indicated by FL in FIG. 2) via a bundle material or the like above the beam 30 and the small beam 40, the floor finishing material 82 and the slab 50 are separated from each other. An underfloor space V is formed between them. In this underfloor space V, a water supply / distribution pipe, electrical wiring, a gas pipe, etc. can be laid.

  Further, the underfloor space V is smaller than the forward beam structure in which the beam 30 and the small beam 40 do not protrude from the surface of the slab 50 (the distance from the lower surface of the floor finish 82 to the upper surface of the slab 50). ) Is large. For this reason, even if the horizontal pulling distance of the pipe is increased, it is easy to secure a water gradient, and the facility planning around the water is easy.

  The beam 30 is formed with a through hole 30H, and the small beam 40 is formed with a through hole 40H. For this reason, piping can be penetrated to these through-holes 30H and 40H. As a result, the piping can be laid in the extending direction of the small beam 40 (Y direction in FIG. 1), and can be bridged over the space on both sides of the beam 30 and the space on both sides of the small beam 40, so that the facility plan Is even easier.

  Further, the through hole 30H is a through hole in which the through hole 32H of the beam member 32 made of H-shaped steel and the through hole 34H of the concrete 34 are communicated. Since the beam member 32 around the through hole 32H is covered with the concrete 34, a reinforcing ring for reinforcing the beam member 32 can be omitted. The same applies to the through hole 40H.

  The beam members 32 and 42 are covered with concrete 34 and 44, respectively. When the concrete 34, 44 functions as a fireproof coating, it is difficult for heat to propagate between the upper and lower sides of the beams 30, 40 in a fire or the like, and it is possible to suppress the spread of fire.

  In addition, since the slab structure according to the present embodiment has a reverse beam structure, the beam 30 and the small beam 40 are unlikely to protrude from the lower surface of the slab 50. Specifically, as shown in FIG. 2, the lower flanges 32FB and 42FB of the beams 30 and 40 protrude from the lower surface of the panel member 52 of the slab 50 by the respective thicknesses.

  As a result, the ceiling finishing material 84 is laid under the slab 50 while securing only a pocket size (distance from the upper surface of the ceiling finishing material 84 to the lower surface of the slab covering plate 56) necessary for electrical wiring or the like. Thus, it is possible to form a living space in which the beams 30 and 40 do not protrude downward from the ceiling surface. For this reason, for example, an opening can be formed up to the ceiling surface CL to make it easier to obtain lighting. Moreover, since it is not necessary to pay attention to the interference between the beams 30 and 40 and the kitchen equipment, the unit bath, etc., equipment planning is easy. The slab coating plate 56 is a non-combustible coating in which a plaster board and a calcium silicate plate are laminated.

  Further, according to the slab structure according to the present embodiment, as shown in FIG. 3, the panel member 52 forming the slab 50 is attached to the beam member 32 or the beam member 42 using the joining member 60, the bolt and the lag screw. It is “joined”. For this reason, compared with the case where the panel member 52 is not joined to the beam member 32 or the beam member 42, the bending moment which generate | occur | produces in the span center part of the panel member 52 can be made small. Thereby, the bending of the slab 50 can be suppressed. Moreover, the amount of reinforcing bars in the concrete 54 of the slab 50 can be reduced.

  In the present embodiment, the joining member 60 joins the end portion in the longitudinal direction (X direction) of the panel member 52 and the beam member 32 or the beam member 42 as shown in FIG. The embodiment is not limited to this. For example, the joining member 60 may be provided at the end of the panel member 52 in the short direction (Y direction) as in the joining member 60 indicated by a dotted line in FIG. In this case, three sides of the panel member 52 adjacent to the beam member 32 along the X direction are fixed to the beam member (the beam member 32 or the beam member 42). As a result, the shearing force can be easily transmitted between the beam member 32 and the panel member 52.

  In the present embodiment, the end of the panel member 52 is “rigidly joined” to the beam member 32 or the beam member 42, but the embodiment of the present invention is not limited to this. For example, when the span between the adjacent beam 30 and the small beam 40 and the span between the adjacent small beam 40 and the small beam 40 (hereinafter referred to as a support span) are short, the diameter of the lag screw is reduced or lengthened. The fixing strength between the panel member 52 and the beam member 32 (or the beam member 42) may be reduced by shortening the length or reducing the number (for example, three or less on each side of the rib 64). Semi-rigid ").

  Alternatively, the fixing strength between the panel member 52 and the beam member 32 (or the beam member 42) can also be controlled by adjusting the number and arrangement of bolts that join the panel member 52 to the web 32W of the beam member 32. That is, if the number of bolts is increased, the fixing strength can be increased, and if a plurality of bolts are arranged along the vertical direction, the fixing strength can be increased as compared with the case where they are arranged along the horizontal direction.

  Moreover, it replaces with the joining member 60 in this embodiment, and a ready-made rebar or steel material may be used. For example, as in a reinforcing bar 72 shown in FIG. 4A, one side of a reinforcing bar bent in an L shape is welded to a web 42W of a beam member 42 (or a beam member 32 not shown), and the other side is connected to concrete 44. It can be set as the structure made to adhere. In this case, the panel member 52 is sandwiched and held between the lower flange 42FB of the beam member 42 and the concrete 44. For example, when a bending moment due to a loading load acts on the panel member 52, an upward force is applied to the end of the panel member 52, but the bending moment is transmitted to the beam member 42 through the concrete 44 and the reinforcing bars 72. .

  Note that the side of the reinforcing bar 72 to be welded to the web 42W may be downward, or may be upward like a reinforcing bar 72A indicated by a dotted line in FIG. In the case of facing downward, for example, the reinforcing bar 72 is partially welded to the web 42W in advance before the panel member 52 is placed on the lower flange 42FB of the beam member 42, and the reinforcing bar 72 is bent after the panel member 52 is installed. In the upward direction, after the panel member 52 is installed, the rebar 72A bent in advance is welded to the web 42W. Thus, the choice of construction methods can be expanded by using a material that is more flexible than the joining member 60.

  Moreover, it can be set as the structure using the ready-made equilateral angle | corner in which the length of 2 sides is equal like the angle material 74 shown to FIG. 4 (B). One side of the angle member 74 is fixed to the web 42W by bolts or welding. The other side may or may not be fixed to the panel member 52. In the case of fixing, a lag screw, a screw, an adhesive or the like can be used. Thus, by using the angle member 74 that is shorter than the joining member 60 in which the length of the side on the panel member 52 side is an unequal side angle, the fixing degree of the panel member 52 can be lowered. That is, the degree of fixation between the panel member 52 and the beam member 42 (or the beam member 32 (not shown)) can be arbitrarily set.

  In addition, as an embodiment using an existing steel material, a CT steel material (so-called cut T) or the like can be used. In this case, the end surfaces of the web and the flange of the CT steel material are welded to a steel plate material, and this plate material is fixed to the web 42W of the beam member 42 with bolts or the like. And the flange lower surface of CT steel material is made to oppose to the panel member 52, and it is fixed or non-fixed with respect to the panel member 52 similarly to the angle member 74.

  Moreover, it can be set as the structure which penetrates a linear reinforcing bar to the through-hole formed in the web 42W like the reinforcing bar 76 shown in FIG.4 (C). The reinforcing bar 76 is not directly fixed to the web 42W, but the vertical movement is restricted by being locked to the through hole. By doing in this way, the bending moment which acts on the panel member 52 can be transmitted to the beam member 42, without using welding like the reinforcing bar 72 shown to FIG. 4 (A). For this reason, workability is high.

  If the support span is short, the panel member 52 and the slab 50 are unlikely to bend, so that even if the fixing degree of the end of the panel member 52 is reduced, a problem does not easily occur.

  Further, in the slab structure according to the present embodiment, the panel member 52 is made of CLT, but the embodiment of the present invention is not limited to this. For example, a wooden floor slab using LVL or the like may be used. When LVL is used as the wooden floor slab, it is preferable that the fiber direction of the wood is installed along the installation direction (the direction perpendicular to the extending direction of the small beams 40).

  Alternatively, in addition to the wooden floor slab, a concrete plate material such as an ALC panel or a hollow precast concrete plate may be used. In the case of using a concrete-based plate material, it is sufficient that the weight of the plate material is lighter than the weight of dense concrete having the same volume.

  In the slab structure according to the present embodiment, the beam members 32 and 42 in the beam 30 and the small beam 40 are covered with the concrete 34 and 44, but the embodiment of the present invention is not limited thereto. For example, only the concrete 54 covering the panel member 52 may be placed above the panel member 52 to expose the web 32W of the beam member 32, the upper flange 32FU or the web 42W of the beam member 42, and the upper flange 42FU. . By doing in this way, concrete construction can be simplified. In this case, the concrete 54 corresponds to the concrete member in the present invention.

  Moreover, in this embodiment, the floor finishing material is laid above the beam 30 and the small beam 40, but the embodiment of the present invention is not limited to this. The floor finishing material may be formed at a position lower than the upper surfaces of the beam 30 and the small beam 40 as long as the pocket size necessary for arranging the pipes can be secured above the concrete 54 of the slab 50. In this case, the part which protruded from the floor finishing material in the beam 30 and the small beam 40 is utilized as a wall body (a waist wall and a handrail are included). Alternatively, a step is provided on the flooring. Thereby, the ceiling height of the living space above the floor finish can be increased.

  Moreover, in this embodiment, although the column beam frame 10 is made into SRC structure, embodiment of this invention is not restricted to this. For example, when only the beams 30 and 40 on which the panel member 52 is installed have a reverse beam structure and the other beams have a forward beam structure, it is not necessary to cover the beams of the forward beam structure with concrete. Also, the column 20 can be a steel column that does not use concrete. That is, the column beam frame 10 can be made of steel in a portion other than the portion where the panel member 52 is installed.

32, 42 Beam members 32FB, 42FB Lower flange 52 Panel member 54 Concrete (concrete member)
70 Concrete member 32W, 42W Web 32FU, 42FU Upper flange 30H, 32H, 34H Through hole

Claims (2)

A beam member formed of H-shaped steel;
A panel member spanned between the lower flanges of the beam members adjacent to each other;
A slab structure having a concrete member placed on an upper surface of the panel member and heavier than the panel member.   2. The slab structure according to claim 1, wherein a web and an upper flange of the beam member are covered with the concrete member, and a through-hole through which a pipe can pass is formed in the concrete member and the web.