JP2018017041A - Foundation structure, and foundation construction method for the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a foundation structure and a foundation construction method for the same that reduce a risk associated with a scaffold at a construction site, at the same time preventing an adverse effect on buildings in a neighborhood.SOLUTION: A foundation structure is constructed on a ground at a lowermost part of a building, and includes: a concrete slab 4 formed by concrete of a prescribed thickness on the ground at the lowermost part of the building, the concrete slab having a flat bottom surface; a horizontal steel 21 embedded horizontally in the concrete slab 4 and disposed leaving a prescribed interval at least in a peripheral part of the concrete slab 4; a connection reinforcement part 3bc that is a reinforcement cage erected between the horizontal steels 21 disposed in the concrete slab 4, for connecting the horizontal steels 21 to each other; and a column base part 23 formed by a steel connected perpendicularly to the horizontal steel 21 in the concrete slab 4.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a foundation structure constructed on the ground at the bottom of a building and a foundation construction method thereof.

  Conventionally, as a method of fixing a column base for connecting a column base of a steel column and a foundation structure of a building in a steel frame structure, there is a method of connecting a foundation concrete and a steel column with an anchor bolt. In this method, since anchor bolts must be planted in concrete, the steel column cannot be set up until the foundation is completed, which may be a bottleneck in the construction process. Also, with this method, since a bending moment is generated at the fixed part of the column base, an excessive bending moment is added to the foundation in addition to the conventional axial force and horizontal force, and the foundation must be constructed firmly. there were.

  On the other hand, a method has been proposed in which the bending moment is reduced by semi-fixing the column base of the steel column, and the steel frame work is discarded and can be started immediately after the concrete work (for example, see Patent Document 1). . In the construction method disclosed in Patent Document 1, two or more second foundation steel beams that resist the bending moment of the steel column at the upper part of the concrete cast in the ground excavation part, and the second foundation steel beam A first foundation steel beam in which a beam flexible region is formed by a gap or the like between the concrete placed in the excavation part at a position where the steel column is sandwiched between the first foundation steel beam and the upper surface of the first foundation steel beam Each foundation steel beam is embedded in concrete.

JP 2002-121747 A

  However, in the construction method disclosed in the cited reference 1, the excavation groove for embedding the second foundation steel beam and the connection between the second steel beams in the upper part of the second foundation steel beam are provided. The bottom structure of the foundation structure is complicated, such as forming a beam flexible region for embedding the first foundation steel beam, and is deep enough to assemble and embed the two foundation steel beams vertically There was a problem of having to form a drilling groove.

  In the construction of excavating such a complicated deep excavation groove, there is a problem that the scaffolding of the construction site becomes complicated and the excavation groove is deep, which increases the risk of an accident such as a fall of a worker or a fall. . Also, at the site where the buildings are close, it is necessary to excavate the ground close to the boundary line with neighboring buildings, and excavating too deep grooves will cause the excavated surface to collapse, the neighboring ground to sink, There may be adverse effects such as tilting. Accordingly, there is a problem that such construction work as the neighboring earth retaining is required, the work process becomes complicated, the construction cost increases, and the construction period is prolonged.

  Therefore, the present invention solves the above problems, and relates to a foundation structure built on the ground at the bottom of the building, and reduces the risk of scaffolding at the construction site, and for neighboring buildings The object is to provide a foundation structure and its foundation method capable of avoiding adverse effects.

In order to solve the above problems, the present invention is a basic structure constructed on the ground at the bottom of the building,
A concrete slab formed of concrete having a predetermined thickness on the ground at the bottom of the building, and having a flat bottom surface.
A steel frame horizontally embedded in the concrete slab, at least at a peripheral edge of the concrete slab and disposed at a predetermined interval, and a horizontal steel frame,
Reinforcing rods built between the horizontal steel frames arranged in the concrete slab, the connecting reinforcing bars connecting each other between the horizontal steel frames,
It is provided with the column base part formed with the steel frame connected perpendicularly | vertically with respect to the said horizontal steel frame in the said concrete slab.

The present invention is a foundation method for constructing a foundation structure,
(1) a step of excavating the ground by the thickness of the concrete slab to form a flat excavation portion having a bottom surface that matches the shape of the concrete slab;
(2) A plurality of the horizontal steel frames are supported and arranged at a predetermined distance from the bottom surface of the excavation portion, and the column base portions are respectively connected perpendicularly to the horizontal steel frames, and between the horizontal steel frames. A step of constructing a connecting reinforcing bar portion for mutually connecting the horizontal steel frames by building a reinforcing bar,
(3) including a step of placing concrete in the excavation groove to form the concrete slab.

  According to the present invention, in order to embed a horizontal steel frame arranged horizontally and a column base connected perpendicularly to the horizontal steel in a concrete slab, axial force generated in the peripheral portion of the foundation, Since sufficient resistance against horizontal force and bending moment can be obtained, the amount of reinforcing bars at this part can be reduced and the concrete thickness can be reduced. In addition, since the horizontal steel frames are connected to each other by the connecting reinforcing bars, the amount of steel frames between them can be reduced, the ratio of the concrete can be increased, and the resistance against compression force and the weight reduction can be improved.

  In addition, at least at the peripheral edge of the concrete slab, the horizontal steel frame is connected to the connecting reinforcing bars so that the structure is simple and strong against bending moments. And since the depth of a foundation can be made shallow, the operation | work which forms a digging groove can be simplified and it can be made safe. As a result, according to the present invention, it is not necessary to deeply excavate the ground close to the boundary line with the neighboring building even at the site where the building is close, and the excavation surface collapses or the neighboring ground sinks. In addition, it is possible to prevent adverse effects such as or tilting the building, and further, work such as earth retaining in the excavation trenches is unnecessary, the work process can be simplified, the work cost can be reduced, and the work period can be shortened.

  In the above invention, the horizontal steel frame is a steel frame connected to the horizontal steel frame in the concrete slab, and preferably includes an inner beam portion that protrudes inward in the horizontal direction from a peripheral edge portion of the concrete slab. . In this case, by forming the inner beam part toward the inside of the concrete slab, it is possible to secure not only the peripheral part of the concrete slab but also the internal strength, and the bending moment from the column is distributed throughout the concrete slab. Can be made.

  In the above invention, the connecting reinforcing bar portion is arranged in the horizontal region in the region from the end portion of the steel frame constituting the horizontal steel frame connected to the end portion of the connecting reinforcing bar portion to the column base portion connected to the horizontal steel frame. It is preferable to have an overlap part that encloses a steel frame constituting the steel frame. In this case, by providing a horizontal steel frame or a steel frame of the inner beam and an overlap part that is arranged to contain this, the connection part between the steel frame and the connection rebar can be strengthened, and the horizontal steel The axial force, horizontal force and bending moment generated in the beam can be smoothly transmitted to the connecting rebar.

  In the above invention, it is preferable to further include a surrounding reinforcing bar portion that surrounds the column base portion of the horizontal steel frame and that connects a plurality of overlapping portions including the end portions of each steel frame constituting the horizontal steel frame. . In this case, the overlapping rebars surrounding the horizontal steel frames and the steel beams of the inner beam can be connected to each other by the surrounding reinforcing bars that surround the column bases. The load from the leg can be smoothly transmitted from the horizontal steel frame or the steel beam of the inner beam to the surrounding connecting reinforcing bars, and the flexibility of the foundation structure can be maintained.

  In the above invention, the steel plate further includes a bottom surface support portion that supports the horizontal steel frame by being separated from the bottom surface of the concrete slab by a predetermined distance, and the bottom surface support portion is a cross section of a reinforcing bar arranged at the bottom of the connection reinforcing bar portion. It is preferable to secure the predetermined distance longer than the diameter. In this case, before placing the concrete slab, a bottom surface support portion is arranged on the bottom surface of the excavation groove, and a horizontal steel frame or an inner beam steel frame is placed on the bottom surface support portion. It is possible to arrange the connecting reinforcing bars to connect. When the steel frame is placed, the bottom support portion is arranged so as to maintain the diameter of the connecting reinforcing bar, so that the construction work of the steel frame and the reinforcing bar arrangement work can be performed in parallel. .

  As described above, according to these inventions, with respect to the foundation structure built on the ground at the bottom of the building, sufficient resistance to axial force, horizontal force and bending moment generated in the concrete slab of the foundation can be obtained. Therefore, the amount of steel frames or reinforcing bars can be reduced, and the resistance to compressive force acting on the concrete slab can be improved to reduce the concrete thickness. In addition, since the foundation structure of the present invention is simple and strong in bending moment, the bottom surface of the concrete slab can be flattened, the thickness of the concrete slab can be reduced, and the depth of the foundation can be reduced. Therefore, the work of forming the excavation groove can be simplified and can be made safe.

  As a result, even if the site is close to the building, there is no need to deeply dig the ground near the boundary line with neighboring buildings, the excavation surface collapses, the neighboring ground sinks, or the building tilts. It is possible to prevent adverse effects such as the above, and further, work such as earth retaining in the excavation groove is unnecessary, the work process can be simplified, the work cost can be reduced, and the work period can be shortened.

It is a top view which shows the whole structure of the basic structure which concerns on embodiment. It is a perspective view which shows the internal steel frame and internal reinforcement of the foundation structure which concern on embodiment. It is a three-view figure which shows the internal steel frame and internal reinforcement of the foundation structure which concern on embodiment, (a) is a top view, (b) is a front view, (c) is a side view. It is a perspective view of the steel structure concerning an embodiment. It is a perspective view which shows the steel frame structure and reinforcement structure which concern on embodiment. It is a perspective view which shows the bar arrangement structure which concerns on embodiment. It is a top view which shows the steel frame structure and reinforcement structure which concern on embodiment. It is a front view which shows the steel frame structure and bar arrangement structure which concern on embodiment. It is explanatory drawing which shows the procedure of the basic construction method which concerns on embodiment.

(Overall structure of basic structure)
Embodiments of a basic structure according to the present invention will be described below in detail with reference to the accompanying drawings. FIG. 1 is a top view showing the overall configuration of the foundation structure according to the embodiment.

  As shown in the figure, the foundation structure 1 according to the present embodiment is a foundation structure constructed on the ground 5 at the bottom of the building, and a concrete slab 4 constructed on the ground 5 and a concrete slab 4 schematically includes a steel structure 2 (2a, 2b, 2c) and a reinforcing bar structure 3 (3ab and 3bc).

  The concrete slab 4 is formed of concrete having a predetermined thickness on the ground 5 at the bottom of the building, and the bottom surface thereof is formed flat. Steel frame structures 2a are arranged at the four corners of the peripheral part of the concrete slab 4, and the steel frame structures 2b are arranged at predetermined intervals between the steel frame structures 2a at the peripheral part. In the peripheral part of this concrete slab 4, between the steel structure 2a, 2b is mutually connected by the connection reinforcing bar part 3ab. Further, the steel structure 2b has a portion protruding inward of the concrete slab 4, and has a T shape in a top view. Inside the concrete slab 4, a steel structure 2c that can be connected in all directions is arranged. By connecting the steel structure 2c and the surrounding steel structure 2b to each other by a connecting reinforcing bar 3bc, the entire structure is formed. A lattice shape is formed.

  As shown in FIG. 4, the steel structure 2 includes only the horizontal steel frames 21 and 21 and the inner beam portions 22 that are spaced apart from each other in the concrete slab 4 by a predetermined distance in the present embodiment. The column base 23 is connected to the base 21 vertically. 2 to 7 exemplify a steel structure 2b arranged at the peripheral edge of the concrete slab 4 as an example of the steel structure.

  The horizontal steel frame 21 is a steel frame that is arranged at a predetermined interval at least at the peripheral edge of the concrete slab 4 and is horizontally embedded in the concrete slab 4. In this embodiment, H steel is used.

  The inner beam portion 22 is a steel frame connected to the horizontal steel frames 21 and 21 in the concrete slab 4, and is a structural material that protrudes inward in the horizontal direction from the peripheral edge portion of the concrete slab 4. The inner beam portion 22 is also disposed so as to abut against the H steel web portion constituting the column base 23 and is firmly connected and fixed to the column base 23 by welding or the like. The inner beam portion 22 constitutes a part of the horizontal steel frame, whereby the horizontal steel frame portion of the steel structure is T-shaped.

  The column base part 23 is a structural material formed of a steel frame that is vertically connected to the horizontal steel frame 21 in the concrete slab 4. In this embodiment, H steel is used. The connection between the column base 23 and the horizontal steel 21 is arranged such that the horizontal steel 21 is abutted from both sides of the H steel web portion at the lower part of the vertically arranged column base and welded. The connection is fixed by etc. Note that a column member 24 made of H steel of the same size is connected to the column base 23 in the vertical direction. The column member 24 and the column base 23 are firmly connected by welding or bolting the connecting plate 234.

  As shown in FIG. 4, a bottom surface support portion 25 that supports the horizontal steel frames 21, 21 at a predetermined distance from the bottom surface 51 a of the concrete slab is provided at the lower end portion of the column base portion 23. The bottom surface support portion 25 secures a predetermined distance longer than the cross-sectional diameter of the lower reinforcing bar 33 arranged at the lowermost part of the connecting reinforcing bar portion 3bc, and the horizontal steel frames 21 and 21 and the inner beam portion are provided on the bottom surface 51a. 22 steel frames are placed, and the connecting reinforcing bars 3ab or 3bc connecting these steel frames are arranged to secure the concrete thickness around the lower reinforcing bars 33.

  As shown in FIGS. 5 and 6, the reinforcing bar structure 3 is connected to the connecting steel bars 3 ab and 3 ab that are built between the horizontal steel frames 21 and 21 and the inner beam part 22, and the column base part 23. The part 3ab, 3ab or the surrounding reinforcing bar part 31 connecting the connecting reinforcing bar part 3bc to each other is roughly configured.

  The connecting reinforcing bar portions 3ab and 3bc are reinforcing bar rods configured by combining reinforcing bars, and are arranged inside the concrete slab 4, and the connecting reinforcing bar portion 3ab is extended along the peripheral edge of the concrete slab 4, and connected. The reinforcing bar portion 3bc is extended inside the concrete slab 4 so as to connect the steel frames of the inner beam portion 22 to each other. Further, the connecting rebar portions 3ab and 3bc are connected to the horizontal steel frames 21 and 21 connected to the respective end portions or the horizontal steel frames 21 in the region from the end portion of the steel frame constituting the inner beam portion 22 to the column base portion 23. , 21 or the inner beam portion 22 includes the overlap portions 32, 32 containing the steel frame.

  The surrounding reinforcing bar 31 surrounds the lower periphery of the column base 23, and is a reinforcing bar that connects a plurality of overlapping portions 32 and 32 that enclose each steel frame connected to the column base 23. By surrounding the column base portion 23 with the surrounding reinforcing bar portion 31, the overlap portions 32, 32 are included while including the steel frames of the horizontal steel frames 21, 21 and the inner beam portion 22 around each column base portion 23. Are connected to each other, and the load from the column base part 23 is transmitted to the surrounding connecting reinforcing bar parts 3ab and 3bc through the horizontal steel frame 21 and the steel frame of the inner beam part 22.

(Basic construction method)
Next, the foundation method of the present invention for constructing the foundation structure described above will be described. FIG. 9 is an explanatory diagram showing the procedure of the foundation method according to the embodiment.

  First, the ground 5 is excavated to form excavation grooves 51 as shown in FIG. The excavation groove 51 has a depth corresponding to the thickness of the concrete slab 4 described above, and is excavated into a shape that matches the shape of the concrete slab 4 to be placed later. It is flat. In this ground 5, the area where the excavation groove 51 is excavated is close to the boundary line with the neighboring area, and the stability of the ground around the boundary line is required. Next, as shown in FIG. 2B, after excavating the excavation groove 51, a discarded concrete 52 having a predetermined thickness is placed on the bottom surface 51a of the excavation groove 51.

  Then, the bottom surface support part 25 is installed in the location which constructs the steel structure 2a-2c. In the installation of the bottom surface support portion 25, anchors, pins or the like are driven into the concrete 52 to fix the bottom surface support portion 25. Next, as shown in FIG. 4C, the concrete 52 and the bottom support portion 25 are spaced apart from the bottom surface 51a of the excavation groove 51 by a predetermined distance, and installed while supporting the horizontal steel frame 21, and each steel frame 21, The column bases 23 are respectively connected to the 21 and 22 perpendicularly. At the same time, by constructing a reinforcing bar rod between the horizontal steel frames 21 and 21, the connecting steel bars 3ab and 3bc for connecting the horizontal steel frames 21 and 21 or the inner beam portion 22 to each other are constructed.

  And as shown in the figure (d), concrete is cast in the excavation groove 51, and the concrete slab 4 is formed.

(Action / Effect)
According to the embodiment described above, the horizontal steel frame 21 and the inner beam part 22 arranged horizontally and the column base part 23 connected perpendicularly to the horizontal steel frame 21 are embedded in the concrete slab 4, Since sufficient resistance against the axial force, horizontal force and bending moment generated in the peripheral portion of the foundation can be obtained, the amount of reinforcing bars in this portion can be reduced and the concrete thickness of the concrete slab 4 can be reduced. Further, since the horizontal steel frames 21 are connected to each other by the connecting reinforcing bar portions 3bc, the amount of the steel frames between them can be reduced, the ratio of the concrete can be increased, and the resistance against the compression force and the weight reduction can be improved.

  In addition, since the horizontal slab is connected at the peripheral edge of the concrete slab 4 with a connecting reinforcing bar 3bc, the bottom surface 51a of the concrete slab 4 can be flattened. Therefore, the work of forming the excavation groove 51 can be simplified and can be made safe. As a result, according to the present embodiment, it is not necessary to deeply excavate the ground close to the boundary line with the neighboring building even at the site where the building is close, and the excavation surface collapses or the neighboring ground sinks. Therefore, it is possible to prevent adverse effects such as dripping or tilting of the building, and further, work such as earth retaining in the excavation trenches is unnecessary, the work process can be simplified, the work cost can be reduced, and the work period can be shortened.

  In the present embodiment, by forming the inner beam portion 22 toward the inside of the concrete slab 4, not only the peripheral portion of the concrete slab but also the strength in the inside can be secured, and the bending moment from the column can be increased. It can be dispersed throughout the slab 4. In particular, in the present embodiment, by providing the steel frames of the horizontal steel frame 21 and the inner beam portion 22 and the overlap portions 32 and 32 that are arranged so as to contain the steel frames, the connection portion between the steel frame and the connection rebars is further increased. In addition to being strong, the axial force, horizontal force, and bending moment generated in the horizontal steel frame 21 and the inner beam portion 22 can be smoothly transmitted to the connecting reinforcing bar portions 3ab and 3bc. In addition, with the surrounding reinforcing bar 31 surrounding the column base part 23, the overlapping parts 32, 32 including the steel frames of the horizontal steel frame 21 and the inner beam part 22 are connected to each other around the column base part 23. The load from the column base 23 can be smoothly transmitted from the horizontal steel 21 or the steel of the inner beam 22 to the surrounding connecting reinforcing bars 3ab and 3bc, and the flexibility of the foundation structure can be maintained. Can do.

  Furthermore, in this embodiment, before placing the concrete slab 4, the bottom surface support portion 25 is disposed on the bottom surface of the excavation groove 51, and the horizontal steel frame 21 and the steel beam of the inner beam portion 22 are placed on the bottom surface support portion 25. While placing, the connecting reinforcing bars 3ab and 3bc connecting these steel frames can be arranged. When the steel frame is placed, the bottom support 25 is arranged so as to maintain the diameter of the connecting reinforcing bars 3ab and 3bc, so that the steel building work and the reinforcing bar arranging work are performed in parallel. Can proceed.

  As described above, according to the present embodiment, sufficient resistance to axial force, horizontal force and bending moment generated in the foundation concrete slab can be obtained, so that the amount of steel frame or reinforcing bar can be reduced, and the concrete slab 4 It is possible to reduce the concrete thickness by improving the resistance against the compressive force acting on the. In addition, since the foundation structure of the present embodiment is simple and strong in bending moment, the bottom surface of the concrete slab can be flattened, the thickness of the concrete slab 4 is reduced, and the depth of the foundation is reduced. Therefore, the operation of forming the excavation groove 51 can be simplified and can be made safe.

DESCRIPTION OF SYMBOLS 1 ... Foundation structure 2 ... Steel structure 2a-2c ... Steel structure 3 ... Reinforcement structure 3ab, 3bc ... Connection reinforcement part 4 ... Concrete slab 5 ... Ground 21 ... Horizontal steel frame 22 ... Inner beam part 23 ... Column base part 24 ... Column member 25 ... Bottom support portion 31 ... Go rebar portion 32, 32 ... Overlap portion 33 ... Lower rebar 51 ... Excavation groove 51a ... Bottom surface 52 ... Discard concrete 234 ... Connection plate

Claims (6)

A foundation structure built on the ground at the bottom of the building,
A concrete slab formed of concrete having a predetermined thickness on the ground at the bottom of the building, and having a flat bottom surface.
A steel frame horizontally embedded in the concrete slab, at least at a peripheral edge of the concrete slab and disposed at a predetermined interval, and a horizontal steel frame,
Reinforcing rods built between the horizontal steel frames arranged in the concrete slab, the connecting reinforcing bars connecting each other between the horizontal steel frames,
A foundation structure comprising: a column base portion formed of a steel frame connected perpendicularly to the horizontal steel frame in the concrete slab.   The horizontal steel frame is a steel frame connected to the horizontal steel frame in the concrete slab, and includes an inner beam portion projecting inward in the horizontal direction from a peripheral portion of the concrete slab. 1. The basic structure according to 1.   The connecting reinforcing bar portion constitutes the horizontal steel frame in a region extending from an end portion of the steel frame constituting the horizontal steel frame connected to an end portion of the connecting reinforcing bar portion to the column base portion connected to the horizontal steel frame. The foundation structure according to claim 1, further comprising an overlap portion including the steel frame.   It further includes a surrounding reinforcing bar portion that surrounds the column base portion of the horizontal steel frame and that interconnects a plurality of the overlapping portions including the end portions of the steel frames constituting the horizontal steel frame. Item 4. The basic structure according to Item 3. Further comprising a bottom support portion that supports the horizontal steel frame by being spaced apart from the bottom surface of the concrete slab by a predetermined distance;
The foundation structure according to claim 1, wherein the bottom surface support portion secures the predetermined distance longer than a cross-sectional diameter of a reinforcing bar arranged at a lowermost portion of the connecting reinforcing bar portion. A foundation construction method for constructing the foundation structure according to claim 1,
Excavating the ground by the thickness of the concrete slab and forming a flat excavation portion with a bottom surface that matches the shape of the concrete slab;
A plurality of the horizontal steel frames are supported and spaced apart from the bottom surface of the excavation part, and the column bases are connected to each horizontal steel frame vertically, and a reinforcing bar is provided between the horizontal steel frames. Constructing a connecting rebar part for connecting the horizontal steel frames to each other by building,
And a step of placing concrete in the excavation groove to form the concrete slab.