JP7381781B2 - pile foundation structure - Google Patents

Description

The present invention relates to a pile foundation structure in which a foundation pile and a steel column are joined.

At the joint between the foundation pile, the foundation beam connected to the head of the foundation pile, and the steel column installed on the foundation pile, the force generated in the superstructure is efficiently transmitted to the foundation pile, and the It is desired to ensure toughness and bond strength. It is also desired to facilitate the construction of joints and shorten the construction period.

For example, Patent Document 1 discloses a configuration in which an integrated cross gusset having a cross-shaped cross section is placed on a foundation pile, and a foundation beam is joined to the cross gusset.
In the configuration disclosed in Patent Document 1, the cross gusset must be joined to a setting plate that is welded and fixed to the outer circumferential surface of the pile, and it takes time and effort to install the cross gusset, and construction is not easy.

Furthermore, Patent Document 2 discloses that a truncated conical cap member placed over the head of the foundation pile and a precast concrete foundation member placed above the foundation pile are used to A configuration for joining foundation beams is disclosed.
In the configuration disclosed in Patent Document 2, since the cap member is interposed between the foundation pile and the foundation member, there is a possibility that force is not sufficiently transmitted from the upper structure side to the foundation pile.

Further, Patent Document 3 discloses a configuration including a steel pipe surrounding the pile cap of a pile, a steel foundation beam welded and fixed onto the steel pipe, and filled concrete filling the steel pipe to form a footing. ing.
In the configuration disclosed in Patent Document 3, there is room for improvement in terms of efficiently transmitting the force generated in the superstructure to the foundation pile and further increasing the toughness and joint strength at the joint.

Japanese Patent Application Publication No. 5-287763 Japanese Patent Application Publication No. 2016-186154 JP 2017-8543 Publication

The purpose of the present invention is to facilitate the construction of the joint between the steel column and the foundation pile, shorten the construction period, and to smoothly transmit the force generated in the superstructure to the foundation pile. The purpose is to provide a pile foundation structure that is joined together.

In order to solve the above problems, the present invention employs the following means.
That is, the pile foundation structure of the present invention is a pile foundation structure in which a foundation pile and a steel column are joined, and includes a concrete foundation pile, a steel joint material provided at the lowest end of the steel column, A foundation concrete part is provided between the foundation pile and the steel joint material, and connects the foundation pile and the steel joint material, and the steel joint material has an outer part of the foundation pile. It is characterized by being provided with a lower plate that exceeds the diameter dimension.
According to such a configuration, the force generated in the steel column can be smoothly transmitted from the steel column to the foundation pile via the steel joint material.
In addition, because the foundation piles and steel joints are connected at the foundation concrete part, the erection position of the steel joints placed on the foundation piles and the steel columns connected to the steel joints can be controlled. Easy to adjust. In particular, steel frame joint materials are equipped with a lower plate that exceeds the outer diameter of the foundation pile, so the lower plate can be supported outside the foundation pile while adjusting its height. It is easy to adjust the height of the joint material.
In particular, since it is possible to support the lower plate outside the foundation pile while adjusting the height, it is possible to erect a steel column on top of the steel joint material while it is fixedly supported. After a roof is erected on top, a foundation concrete section can be placed between the foundation piles and the steel joint material. In this case, since the influence of weather can be suppressed during concrete pouring, construction is facilitated, and process control is stabilized, so that it is possible to prevent the construction period from becoming too long.
Moreover, since the pile foundation structure that connects the foundation pile and the superstructure can be formed with a relatively simple joint structure, the construction period can be shortened.
As a result, it becomes possible to easily construct the joint between the steel column and the foundation pile, shorten the construction period, and provide a pile foundation structure that can smoothly transmit the force generated in the superstructure to the foundation pile.

According to the present invention, the foundation pile and the steel column can be easily constructed to shorten the construction period by facilitating the construction of the joint between the steel column and the foundation pile, and can smoothly transmit the force generated in the superstructure to the foundation pile. It becomes possible to provide a pile foundation structure to be joined.

It is a sectional view showing the composition of the pile foundation structure concerning this embodiment. FIG. 2 is a plan view of a steel joint material used in the pile foundation structure of FIG. 1. FIG. It is a figure which shows the construction method of the pile foundation structure of FIG. 1, and is a sectional view which shows the state in which the foundation pile was provided in the ground. It is a figure which shows the construction method of the pile foundation structure of FIG. 1, and is a sectional view which shows the state where the reinforcing bar joint material is arrange|positioned above the foundation pile. It is a figure which shows the construction method of the pile foundation structure of FIG. 1, and is a sectional view which shows the state in which the foundation concrete part was formed. (a) is an explanatory diagram showing the transmission of shear force and bending moment in the case where there is no connecting member in the pile foundation structure, and (b) in the case where the connecting member is provided. It is a top view which shows the structure of the steel frame joint material in the 1st modification of the pile foundation structure based on this embodiment. It is a sectional view showing the composition in the 2nd modification of the pile foundation structure concerning this embodiment. It is a top view which shows the structure of the steel frame joint material in the 3rd modification of the pile foundation structure based on this embodiment. It is a sectional view showing the composition in the fourth modification of the pile foundation structure concerning this embodiment.

The present invention is a pile foundation structure in which a foundation pile and a steel column are joined. A pile foundation structure includes a foundation pile and a steel column having a steel joint member with a connecting member protruding from the lower side, and a foundation concrete part that connects the connecting member, the foundation pile, and the steel joint member. are joined with.
EMBODIMENT OF THE INVENTION Hereinafter, with reference to an accompanying drawing, the form for implementing the pile foundation structure by this invention is demonstrated based on a drawing.
A cross-sectional view showing the configuration of the pile foundation structure according to this embodiment is shown in FIG. FIG. 2 is a plan view of the steel joint material used in the pile foundation structure of FIG. 1.
As shown in FIG. 1, the pile foundation structure 10 mainly includes a foundation pile 11, a steel joint material 20, and a foundation concrete part 30.
The foundation pile 11 supports the superstructure of a building or the like. A predetermined number of foundation piles 11 are constructed in the ground G, and each of them extends in the vertical direction. The foundation pile 11 is made of concrete. In this embodiment, the foundation pile 11 is a cylindrical precast concrete pile that is continuous in the vertical direction. The foundation pile 11 is not limited to a ready-made concrete pile, but may be a steel pipe pile or a steel pipe-filled concrete pile in which the steel pipe pile is filled with concrete.

A foundation beam 13 is joined to the head 11t of the foundation pile 11 via a steel joint material 20. In this embodiment, four foundation beams 13 extending in all directions along the horizontal direction are joined to the head 11t of the foundation pile 11. The foundation beam 13 is made of reinforced concrete, for example, and includes a beam concrete portion 18 and beam reinforcing bars 19 buried within the beam concrete portion 18. The beam reinforcing bars 19 include a plurality of beam main reinforcements 19a extending in the extending direction of the foundation beam 13, and a hoop reinforcement 19b arranged so as to surround the plurality of beam main reinforcements 19a. This foundation beam 13 is supported on the ground plane Gf.
These plurality of foundation piles 11 and foundation beams 13 provided on the foundation piles 11 form a foundation portion 14 that supports an upper structure such as a building.

Further, as shown in FIG. 3, a recess 15 is formed on the outer peripheral side of the head 11t of the foundation pile 11, which is depressed below the ground surface Gf that supports the foundation beam 13. The recess 15 has a bottom surface 15a formed on the outer peripheral side of the foundation pile 11, and an inclined surface 15b formed on the outer peripheral side of the bottom surface 15a. The bottom surface 15a is formed at a position lower than the head portion 11t of the foundation pile 11. The inclined surface 15b gradually extends diagonally upward from the bottom surface 15a toward the outer circumferential side, and is continuous with the ground surface Gf. A level concrete portion 16 having a predetermined thickness is formed on the bottom surface 15a of the recess 15 and the inclined surface 15b.

The steel joint material 20 is arranged above the head 11t of the foundation pile 11. The steel frame joint material 20 includes a lower plate 21, a connecting member 25, a joint body 22, and an upper plate 23.
As shown in FIGS. 1 and 2, the lower plate 21 has a rectangular flat plate shape in plan view, and has an outer diameter larger than the outer diameter of the head 11t of the foundation pile 11 (outer diameter of the head 11t). larger than the diameter dimension). The lower plate 21 is provided by a plurality of supporting members 26 so as to be located in a horizontal plane at the level of the lower surface of the foundation beam 13. The plurality of support members 26 are arranged, for example, at the four corners of the lower plate 21. Each support member 26 is made of, for example, a steel material having an L-shape in plan view, and its upper end is welded to the lower end surface 21b of the lower plate 21. Each support member 26 extends downward from the lower plate 21, and its lower end is grounded on the level concrete portion 16 within the recess 15.

As shown in FIG. 1, the connecting member 25 is provided below the lower plate 21. As shown in FIG. The connecting member 25 is made of, for example, a steel material, a steel pipe, or a general shaped steel having an H-shaped cross section, and its upper end is welded to the lower end surface 21b of the lower plate 21. The connecting member 25 protrudes downward from the lower end surface 21b of the lower plate 21, and its lower part is inserted into the head 11t of the foundation pile 11. The outer diameter of the connecting member 25 is smaller than the inner diameter of the foundation pile 11. In the head portion 11t of the foundation pile 11, a pile concrete portion 31 formed as a part of a foundation concrete portion 30, which will be described later, is provided by pouring and filling concrete. The connecting member 25 is buried in the pile concrete portion 31 within the head portion 11t of the foundation pile 11.

The main body part 22 is provided on the upper part of the lower plate 21. The main body part 22 is welded to the upper surface of the lower plate 21. As shown in FIG. 2, the joint main body part 22 is made of steel and has a beam joint part 24 extending toward each foundation beam 13 connected via the steel joint material 20. As shown in FIG. Each beam joint 24 has a substantially T-shape in plan view, and includes a base 24a extending in the axial direction of each foundation beam 13, and a fixing plate integrally provided at the tip of the base 24a and perpendicular to the axial direction of the foundation beam 13. It has a portion 24b. In this embodiment, four foundation beams 13 extending in all directions are joined to the steel frame joint material 20. For this reason, the main body part 22 is provided with beam joint parts 24 extending in all directions. The main body part 22 is made of a cross-sectional steel material that is formed by welding a plurality of steel materials in a cross shape.
The upper plate 23 has, for example, a rectangular flat plate shape when viewed from above, and is welded to the upper surface of the main body portion 22 . The upper plate 23 is provided at the upper surface level of the foundation beam 13. The lower end of the steel column 12 is joined onto the upper plate 23. The upper plate 23 is formed with a through hole 23h for joining the lower end of the steel column 12.

As shown in FIG. 1, the steel frame joint material 20 is further provided with stud materials 27 and 29. The stud members 27 and 29 are provided on the lower end surface 21b of the lower plate 21 and the side surface 25s of the connecting member 25.
A plurality of stud members 27 are provided below the lower plate 21 at intervals in the horizontal direction. Each stud member 27 has a base end welded to the lower end surface 21b of the lower plate 21 and projects downward. An enlarged diameter portion 27a is formed at the tip of each stud member 27. The stud material 27 is embedded in a foundation concrete section 30, which will be described later, so that horizontal force can be transmitted between the lower plate 21 and the foundation concrete section 30.
A plurality of stud members 29 are provided on the side surface 25s of the connecting member 25 at intervals in the vertical direction. The base end of each stud member 29 is welded to the side surface 25s of the connecting member 25, and projects laterally. At the tip of each stud member 29, an enlarged diameter portion 29a is formed. The stud material 29 is buried in the foundation concrete part 30, particularly in the pile concrete part 31 located inside the foundation pile 11. Thereby, the stud member 29 can transmit vertical axial force between the connecting member 25 and the pile concrete portion 31.

The foundation concrete part 30 joins the foundation pile 11 and the steel joint material 20. The foundation concrete part 30 is integrally formed so as to straddle the inside of the recess 15 and the inside of the foundation pile 11 as already explained as the pile concrete part 31. Thereby, the foundation concrete part 30 is arranged below the ground plane Gf. The foundation concrete part 30 is formed by pouring concrete into the recess 15 and the foundation pile 11 up to the ground surface Gf level.
Foundation reinforcing bars 35 are buried within the foundation concrete section 30. The foundation reinforcing bar 35 has a reinforcing bar main part 35a disposed along the bottom surface 15a of the recess 15, and a connecting bar part 35b extending diagonally upward from the reinforcing bar main part 35a toward the outer circumferential side. The connecting muscle portion 35b is arranged along the inclined surface 15b of the recess 15. The connecting reinforcement portion 35b protrudes above the foundation concrete portion 30 and is buried within the beam concrete portion 18 of the foundation beam 13. The foundation reinforcing bars 35 increase the joint strength between the foundation concrete section 30 and the foundation beam 13.

Steel columns 12 constitute a superstructure. The steel columns 12 are connected to the foundation piles 11 and foundation beams 13 of the foundation section 14 via steel joints 20. Steel column 12 extends upward from top plate 23. A joining plate 12p provided at the lower end of the steel column 12 is joined by a bolt B through a through hole 23h formed in the upper plate 23.

(Method of constructing foundation structure)
Next, a method of constructing the pile foundation structure 10 will be explained.
FIG. 3 is a diagram showing a construction method of the pile foundation structure of FIG. 1, and is a sectional view showing a state in which foundation piles are provided in the ground. FIG. 4 is a sectional view showing a state in which reinforcing bar joint material is placed above the foundation pile. FIG. 5 is a sectional view showing the state in which the foundation concrete part is formed.
First, as shown in FIG. 3, a recess 15 is formed at a predetermined position on the ground surface Gf. Next, the foundation pile 11 is driven into the ground G from the bottom surface 15a of the recess 15. After driving the foundation pile 11, concrete is poured to a predetermined thickness on the outer peripheral side of the head 11t of the foundation pile 11 to form a level concrete portion 16.
Next, as shown in FIG. 4, a steel joint material 20 is placed above the foundation pile 11. At this time, the lower plate 21, the joint body 22, the upper plate 23, the support member 26, the connecting member 25, the stud members 27, 29, etc. of the steel joint material 20 are joined together in advance at the factory or on-site yard. has been done. The steel frame joint material 20 is arranged above the foundation pile 11 by grounding a plurality of supporting members 26 on the level concrete part 16. At this time, the lower part of the connecting member 25 is inserted into the head 11t of the foundation pile 11. In addition, the level of the lower plate 21 is adjusted by adjusting the length of the supporting member 26 or inserting a spacer between the lower end of the supporting member 26 and the level concrete part 16, and the lower plate 21 is adjusted to the ground surface Gf. be placed at the same level.
Here, since the lower plate 21 has an outer diameter larger than the outer diameter of the head 11t of the foundation pile 11, the support members 26 disposed at its four corners are It can be grounded on the level concrete part 16 formed on the bottom surface 15a of the recessed part 15 on the outer peripheral side. Therefore, the level of the lower plate 21 can be easily adjusted. Further, since the outer diameter of the connecting member 25 is smaller than the inner diameter of the foundation pile 11, the position of the steel frame joint member 20 in the horizontal plane can be easily adjusted without interfering with the connecting member 25 on the foundation pile 11. be able to. Therefore, even if the foundation pile 11 is constructed so that the pile center CB of the foundation pile 11 deviates from the axis CA of the column, as shown in FIG. The erection position of the pillars 12 can be easily adjusted.
Subsequently, the foundation reinforcing bars 35 are placed in the recess 15.

Thereafter, as shown in FIG. 5, the steel columns 12 are erected on the upper plate 23, and a roof (not shown) is installed on the steel columns 12. Then, concrete is poured into the foundation piles 11 and the recesses 15, and the foundation concrete part 30 is integrally formed so as to include the pile concrete part 31.
On the other hand, as shown in FIG. 1, the beam reinforcing bars 19 of each foundation beam 13 are arranged on the ground plane Gf. Thereafter, a formwork (not shown) is assembled, and concrete is poured into the formwork to form the beam concrete portion 18. Thereby, the foundation beam 13 is formed.
In this way, the pile foundation structure 10 is realized.

According to the pile foundation structure 10 as described above, the steel frame joint material 20 provided at the lowermost end of the steel column 12 is provided between the foundation pile 11 and the steel frame joint material 20, and the steel frame joint material 20 is provided between the foundation pile 11 and the steel frame joint material 20. A foundation concrete part 30 is provided to join the joint material 20, and a lower plate 21 having an outer diameter exceeding the outer diameter of the foundation pile 11 is disposed on the steel joint material 20.
According to such a configuration, the force generated in the steel column 12 can be smoothly transmitted from the steel column 12 to the foundation pile 11 via the steel joint material 20.
In addition, since the foundation pile 11 and the steel frame joint material 20 are joined by the foundation concrete part 30, the steel frame joint material 20 placed on the foundation pile 11 and the steel frame joint material 20 connected to the steel frame joint material 20 are connected. The position of the pillar 12 can be easily adjusted. In particular, since the lower plate 21 larger than the outer diameter of the foundation pile 11 is disposed on the steel frame joint material 20, the lower plate 21 is used as the support member 26 on the outside of the foundation pile 11, for example. As shown, it is possible to support the steel frame joint material 20 while adjusting its height, and therefore the height of the steel frame joint material 20 can be easily adjusted.
In particular, since the lower plate 21 can be supported on the outside of the foundation pile 11 while adjusting its height, as explained using FIG. After the steel columns 12 are erected on top of the roof and the roof is constructed, the foundation concrete part 30 can be poured. In this case, since the influence of weather can be suppressed during concrete pouring, construction is facilitated, and process control is stabilized, so that it is possible to prevent the construction period from becoming too long.
Moreover, since the pile foundation structure 10 that connects the foundation pile 11 and the superstructure can be formed with a relatively simple joint structure, a short construction period is possible.
As a result, the joint between the steel column 12 and the foundation pile 11 can be easily constructed, shortening the construction period, and has excellent toughness and high joint strength that can smoothly transmit the force generated in the superstructure to the foundation pile 11. It is possible to realize a pile foundation structure with

Here, other effects related to the transmission of shear force due to the provision of the connecting member 25 will be explained. FIG. 6(a) is an explanatory diagram showing the transmission of shear force and bending moment when the connecting member 25 is not provided in the pile foundation structure. FIG. 6(b) is an explanatory diagram showing the transmission of shear force and bending moment when the connecting member 25 is provided in the pile foundation structure. In both these cases, the lower plate 21 is provided with anchor bolts 40. The anchor bolt 40 is buried in the foundation concrete part 30.
When a shear force Qp and a bending moment Mp act on the column base of the steel column 12 when the connecting member 25 is not provided, these are transmitted to the foundation by the shear force Qa and tensile force Na of the anchor bolt 40. . For this reason, a large diameter anchor bolt 40 is used.
On the other hand, when the connecting member 25 is provided in the pile foundation structure and the lower end of the connecting member 25 is buried in the foundation pile 11, the shear force Qp generated at the base of the steel column 12 is transferred to the foundation. and is transmitted to the pile (shear force Qc in FIG. 6(b)). Therefore, the anchor bolt 40 only needs to bear the tensile force Na exerted by the bending moment Mp.
In this way, by providing the connecting member 25, when the anchor bolt 40 is used, the anchor bolt 40 can be rationalized.

Moreover, at least a portion of the foundation concrete part 30 is arranged below the ground plane Gf.
According to such a configuration, when an earthquake load acts in the horizontal direction between the foundation pile 11 and the superstructure including the steel columns 12, the connection buried in the foundation pile 11 The displacement of the material 25 in the horizontal direction is restrained by the surrounding foundation piles 11. Moreover, the foundation concrete part 30 arranged below the ground surface Gf is restrained from displacement in the horizontal direction by the surrounding ground G. In this way, the connecting material 25 constituting the steel frame joint material 20, the foundation concrete section 30, and the ground G around the foundation concrete section 30 function as a transmission resistance body for earthquake load. In this way, while simplifying and downsizing the structure of the connecting member 25 or the foundation concrete part 30, the force is smoothly transmitted from the upper structure to the foundation pile 11 and the foundation concrete part 30 in the event of an earthquake, and the resistance to earthquakes is increased. can be increased.
Moreover, by arranging at least a portion of the foundation concrete part 30 below the ground plane Gf, the height of the pile foundation structure 10 can be made lower than when all the foundation concrete parts 30 are arranged above the ground plane Gf. Therefore, a large number of building floors can be provided under the building height restrictions based on the Building Standards Law for each construction site.
Furthermore, by arranging at least a portion of the foundation concrete section 30 below the ground plane Gf, the ground G in contact with the foundation concrete section 30 can also serve as a formwork.

Furthermore, stud members 27 and 29 are provided protruding from the lower end surface 21b of the lower plate 21 and the outer peripheral surface of the connecting member 25.
According to such a configuration, force can be efficiently transmitted from the lower plate 21 to the foundation concrete part 30 and from the connecting member 25 to the foundation pile 11 via the stud members 27 and 29. .

(First modification of the embodiment)
Note that the pile foundation structure of the present invention is not limited to the above-described embodiment described with reference to the drawings, and various modifications can be made within the technical scope thereof.
For example, in the above embodiment, the four foundation beams 13 extending in all directions are joined to the head portion 11t of the foundation pile 11 via the steel joint material 20, but the present invention is not limited to this. For example, as shown in FIG. 7, two foundation beams 13 may be joined to the head 11t of the foundation pile 11 via a steel joint material 20B. In this case, the main body part 22B includes two beam joint parts 24 extending toward each foundation beam 13. Since each beam joint 24 has a T-shape in a plan view, the shigouchi main body portion 22 having the two beam joints 24 can also be formed of an H-shaped steel material that has a substantially H shape in a plan view.

(Second modification of embodiment)
In the above embodiment, the foundation beam 13 is made of reinforced concrete, but it is not limited to this. For example, as shown in FIG. 8, the foundation beam 13C may be a steel frame structure. In this case, the beam steel frame forming the foundation beam 13C is bolted via the join plate 28 to the beam joint portion 24C of the joint main body 22C, which has the same cross-sectional shape as the beam steel frame in the steel joint material 20. Ru.

(Third modification of embodiment)
Further, in the above embodiment, the joint main body portion 22 has a cross shape in plan view, but the shape is not limited to this. As shown in FIG. 9, the joint main body 22D of the steel joint material 20D is rectangular in plan view and has a cylindrical shape extending in the vertical direction, and the beam steel frames constituting each foundation beam 13D are connected to the outer peripheral surface of the joint main body 22D of the steel frame joint material 20D. You can do it like this.

(Fourth modification of the embodiment)
Further, in the above embodiment, the lower end of the steel column 12 is directly bolted to the upper plate 23, but the present invention is not limited to this. For example, as shown in FIG. 10, a joint fitting 60 having, for example, a T-shaped or L-shaped cross section is provided on the upper plate 23, and the joint fitting 60 is bolted to the upper plate 23 through the through hole 23h of the upper plate 23. Additionally, the steel column 12 may be bolted to the joint fitting 60.

(Other variations)
Further, in the above embodiment, the stud members 27 and 29 are provided on the lower end surface 21b of the lower plate 21 and the side surface of the connecting member 25, respectively, but it is preferable to provide only one of the stud members 27 and 29. You can also do this.
In addition to this, it is possible to select the configurations mentioned in the above embodiments or to change them to other configurations as appropriate, without departing from the gist of the present invention.

10 Pile foundation structure 21b Lower end face 11 Foundation pile 25 Connecting material 12 Steel column 27, 29 Stud material 15 Recess 30 Foundation concrete portion 20, 20B, 20C, 20D Steel joint material G Ground 21 Lower plate Gf Ground surface

Claims (2)

A pile foundation structure in which a foundation pile and a steel column are joined,
concrete foundation piles,
a steel joint material provided at the lowest end of the steel column;
A foundation concrete part provided between the foundation pile and the steel joint material, and connecting the foundation pile and the steel joint material,
A lower plate having a diameter larger than the outer diameter of the foundation pile is disposed on the steel joint material ,
A plurality of supporting members are arranged such that their upper ends are joined to the lower end surface of the lower plate and extend downward from the lower plate, and their lower ends are grounded on a level concrete section provided on the outer peripheral side of the head of the foundation pile. A pile foundation structure characterized by being provided . A recess is formed on the outer peripheral side of the head of the foundation pile, and is recessed below the ground surface that supports the foundation beam to be joined to the steel joint material, and the recess has a bottom surface and a bottom surface. an inclined surface formed on the outer circumferential side, extending obliquely upward from the bottom surface toward the outer circumferential side and continuous with the ground surface, and the level concrete part is formed on the bottom surface and the inclined surface. ,
Foundation reinforcing bars are buried in the foundation concrete part, and the foundation reinforcing bars include a main part of the reinforcing bars arranged along the bottom surface of the recess, and a main part of the reinforcing bars disposed along the bottom surface of the recess, and a main part of the reinforcing bars disposed along the bottom surface of the recess from the main part of the reinforcing bars toward the outer circumferential side. a connecting reinforcement portion extending diagonally upward along the slope, the connecting reinforcement portion protruding upward from the foundation concrete portion and being buried within the beam concrete portion of the foundation beam.
The pile foundation structure according to claim 1, characterized in that:.

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