JP2002138574A - Building construction method and building - Google Patents

Abstract

PROBLEM TO BE SOLVED: To safely and rationally execute works using a reverse driving process while securing a moment reduction effect. SOLUTION: A foundation pile 2 is provided under a condition that it is integrated with at least the lower end part of the column member 5 while erecting the column member 5 constituting a basement part 3a. A floor structure comprising the upper structure 3 is constructed by being supported with the top end part of the column member 5. Then, the lower ground G of the floor structure is dug to form the basement part 3a. At the time, the column member 5 with an enlarged-diameter position 8 previously provided at center is used. The enlarged diameter portion 8 is formed such that the diameter size is made smaller than the foundation pile 2. At a time of erecting the column member 5, its lower end part is located so that it is integrated with the foundation pile 2, and its top end part is integrated with the basement part 3a of the upper structure 3.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for constructing a building such as a building, and a building.

[0002]

2. Description of the Related Art As is well known, in a building in which a superstructure is supported by a foundation pile, a stress transmission device having a pin mechanism is installed between the pile and the building foundation (the lower part of the superstructure), thereby making the upper part of the building higher. Techniques are being adopted to transmit the axial force from the structure to the foundation pile and prevent the transmission of bending moment from the foundation pile to the superstructure. By using such a stress transmission device, it is possible to reduce the bending stress of the pile and the stress of the foundation of the building, and to reduce the cost while improving the seismic safety of the building including the pile. it can.

[0003]

However, the construction method using the stress transmission device as described above increases the cost by using the stress transmission device, and requires a special material (ductile cast iron) to support the building's own weight. And molybdenum steel), it has not yet been widely used in society.

[0004] In particular, when constructing a building with a basement floor, it is effective to employ a reverse hitting method which is effective for shortening the construction period and reducing the working space. When the transmission device is used, it is necessary to cut a straight pillar (a steel column in an underground part) supported by a pile at a pillar position, jack up the upper skeleton, and insert a stress transmission mechanism. Therefore, a more rational construction method is required in terms of construction safety and workability.

The present invention has been made in view of the above circumstances, and secures a safe and rational method using a reverse striking method while ensuring the same moment reduction effect as when a stress transmitting device having a pin mechanism is used. An object of the present invention is to provide a building method and a building that can be constructed in a building.

[0006]

Means for Solving the Problems To solve the above problems, the present invention employs the following means. The building construction method according to claim 1, wherein the superstructure having the underground portion is a method for constructing a building having a configuration supported by foundation piles, wherein the underground portion is located in the ground at a building installation target position. The floor structure, in which the foundation pile is installed in a state of being integrated with at least the lower end portion of the pillar material while the pillar material constituting the pillar material is erected, and is supported by the upper end portion of the pillar material to constitute the upper structure Then, the ground below the floor structure is excavated, and the underground portion of the upper structure is formed below the floor structure. Using the one provided with the enlarged diameter portion in advance, the enlarged diameter portion,
The pillar is formed so that its diameter is smaller than that of the foundation pile, and when the pillar is erected, its lower end is integrated with the foundation pile, and its upper end is underground of the upper structure. It is characterized by being positioned so as to be integrated with the part.

[0007] With such a configuration, in this building construction method, after the work of erecting the pillars, the construction can be performed in the same procedure as that of the normal reverse striking method. In addition, the enlarged diameter part, which is located between the underground part of the superstructure and the pile head of the foundation pile after construction, has a smaller diameter than the foundation pile and has a smaller cross-sectional performance, so that it is completely rigid. It does not function as a joint, and the joint between the foundation pile and the superstructure is to be joined in a state close to the pin.

According to a second aspect of the present invention, there is provided a method of constructing a building according to the first aspect, wherein the pillar is provided with the enlarged diameter portion around a central portion of a pillar body. In addition, the enlarged diameter portion is formed of a steel pipe fitted around the pillar body and concrete filled between the steel pipe and the pillar body.

With such a configuration, the enlarged diameter portion can be stably coped with a high axial force. The concrete in the enlarged diameter portion can be poured in the air.

According to a third aspect of the present invention, there is provided a method of constructing a building according to the first or second aspect, wherein when the pillar is erected, a predetermined area around the enlarged diameter portion is provided. It is characterized in that a cushioning material is provided for preventing the enlarged diameter portion from adhering to the concrete forming the foundation pile.

[0011] With such a configuration, the flexible length of the enlarged diameter portion can be secured to a predetermined length.

According to a fourth aspect of the present invention, there is provided a building construction method according to any one of the second to third aspects,
It is characterized in that concrete filled between the steel pipe and the column main body is cast so that a central portion of a lower surface thereof is convex downward.

[0013] With such a configuration, it is possible to ensure the filling property of the pile concrete when the pile concrete is driven while the column material is standing.

According to a fifth aspect of the present invention, there is provided a building comprising a foundation pile installed in the ground and an upper structure supported by the foundation pile, and a pile head of the foundation pile and a lower surface of the upper structure are mutually connected. The pillar material, which is positioned vertically apart and forms at least the lower portion of the upper structure, has a lower end portion embedded in the pile head, and the pillar material includes the pile head and the lower surface of the upper structure. A region including a portion located between the enlarged pile portion is formed as a large diameter portion having a larger diameter size than other portions, and the larger diameter portion has a smaller diameter size than the foundation pile. It is characterized by being.

As described above, since the pile head of the foundation pile and the lower surface of the upper structure are separated from each other, it is possible to omit the extra pile work at the pile head. In addition, the enlarged diameter portion located between the lower surface of the upper structure and the pile head of the foundation pile has a smaller diameter than the foundation pile, and therefore,
Since the cross-sectional performance is small, it does not function as a complete rigid connection, and the connection between the foundation pile and the superstructure is performed in a state close to the pin. Further, the column material is positioned so as to penetrate from the pile head of the foundation pile to the lower surface of the upper structure, whereby it is possible to cope with a case where a tensile force is generated in the foundation pile.

According to a sixth aspect of the present invention, there is provided the building according to the fifth aspect, wherein the enlarged diameter portion is formed around a central portion of a pillar main body formed of a steel frame material. The enlarged diameter portion is formed of a steel pipe fitted around the pillar body and concrete filled between the steel pipe and the pillar body.

With such a configuration, in this building, the enlarged diameter portion can stably cope with a high axial force.

According to a seventh aspect of the present invention, in the building according to the sixth aspect, the steel pipe has an upper end buried in a lower surface of the upper structure.

With such a configuration, the shearing force acting on the pile can be transmitted to the upper structure.

[0020] The building according to claim 8 is the same as claim 6 or 7.
The building according to the above, wherein the steel pipe has a lower end portion buried in the concrete forming the pile head, and the steel pipe and the concrete forming the pile head have a lower end thereof. It is characterized in that a cushioning material for preventing adhesion between them is arranged.

According to such a configuration, the flexible length of the enlarged diameter portion can be secured to a predetermined length.

A ninth aspect of the present invention is the building according to any one of the sixth to eighth aspects, wherein the foundation pile is a cast-in-place concrete pile, and is provided between the steel pipe and the column body. As the filled concrete, a concrete having a higher strength than the concrete constituting the cast-in-place concrete pile is used.

With such a configuration, it is possible to secure the ability to hold the axial force in the enlarged diameter portion.

[0024]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 9 is a diagram illustrating a structure of a main part of a building 1 to which a construction method according to an embodiment of the present invention is applied. As shown in FIG. 9, this building 1 has a configuration in which an underground portion 3a of an upper structure 3 is located on a foundation pile 2 which is a cast-in-place concrete pile. Here, foundation pile 2
And the lower surface 3b of the underground portion 3a of the upper structure 3 are vertically separated from each other. Also, the pillar members 5 constituting the underground part 3a of the upper structure 3 are connected to the lower surface 3b of the upper structure 3.
By projecting further downward, the lower end 5 a is embedded in the foundation pile 2, so that the upper structure 3 is supported from the foundation pile 2 via the pillar 5.

The column member 5 is composed of a column member main body 7 and an enlarged diameter portion 8 formed around a position near a lower end portion 7a in the center of the column member main body 7. The configuration of the enlarged diameter portion 8 is shown in an enlarged manner in FIGS. 1 is an elevational sectional view showing a state near the enlarged diameter portion 8, FIG. 2 is a sectional view taken along the line II in FIG. 1, and FIG.
FIG. 4 is a perspective sectional view of the column member 5 including the enlarged-diameter portion 8.

As shown in the drawing, the pile head 4 of the foundation pile 2 and the lower surface 3b of the underground portion 3a of the upper structure 3 are spaced apart from each other. 3
, The upper end of which is located deeper than the pile head 4. In addition, the enlarged diameter portion 8 of the pillar 5 is a pile head 4 of the foundation pile 2.
It is arranged so that it may be located in a fixed area including the position between the lower structure 3a and the lower surface 3b of the upper structure 3, so that the load of the upper structure 3 is applied to the foundation pile 2 via the enlarged diameter portion 8. To be transmitted.

The enlarged diameter portion 8 is formed so as to have a smaller diameter than the foundation pile 2, and a steel pipe 11 fitted around the column body 7 made of H-shaped steel, and a steel pipe 11. And the concrete C1 filled between the column main bodies 7. In this case, the steel pipe 11 is arranged such that the upper end 11 a is embedded in the lower surface 3 b of the upper structure 3, and the lower end 11 b is embedded in the pile head 4. In a certain area around the steel pipe 11, a cushioning material 12 for preventing the steel pipe 11 and the pile concrete C2 constituting the pile head 4 from adhering to each other is arranged. This cushioning material 1
2 is made of, for example, rubber or an elastomer-based material. Moreover, the concrete C1 cast between the steel pipe 11 and the column body 7 is cast so that the center of the lower surface C1a in a plan view is convex downward.

An anchor bar 13 is disposed in the enlarged diameter portion 8 so as to surround the column body 7. The lower ends 13a of these anchor bars 13 are buried in the concrete C1 in the steel pipe 11 and the upper ends 1a thereof.
3b is disposed so as to protrude upward from the steel pipe 11 and reach into the upper structure 3. Further, stud bolts 14, 14,... Are provided in a protruding state at the lower end 7a of the pillar main body 7.

Next, a method for constructing the building 1 will be described. For this purpose, first, the pillar 5 is formed on the ground. In this case, for example, as shown in FIG. 5, a steel frame made of H-shaped steel divided into an upper member 14 and a lower member 15 is used as the column member main body 7, and the steel pipe 11 is used as the lower member 15.
And an anchor bar 13 is arranged inside the steel pipe 11. Then, concrete C1 is cast into the steel pipe 11 in this state, so that the enlarged diameter portion 8 is formed on the lower member 15. Further, by connecting the lower member 15 and the upper member 14 by welding or the like, the column member 5 is completed.

On the other hand, as shown in FIG. 6, an excavation pit 16 for excavating the ground G and installing the foundation pile 2 is formed.
In this case, muddy water 17 containing a stable liquid is injected into the excavation pit 16. Then, as shown in FIG. 7, a steel cage 18 constituting the foundation pile 2 is arranged below the excavation pit 16, and the column member 5 formed as shown in FIG.
It is arranged at a predetermined position inside. In this case, the enlarged diameter portion 8 of the pillar 5
In a certain area around the steel pipe 11, a cushioning material 12 is arranged over a predetermined length. When disposing the column member 5 in the excavation pit 16, the urethane foam or the cured rubber sheet is formed so as to cover the enlarged diameter portion 8 and a certain region above the enlarged diameter portion 8 of the steel pipe 11 and the column material main body 7. (Not shown) is provided so as to prevent the adhesion of the concrete and the slug at the time of placing the pile concrete C2 described later.

Next, as shown in FIG. 8, the excavation pit 16 is filled with pile concrete C2. In this case, the pile concrete C2 is cast to a level lower than the upper end portion 11a of the steel pipe 11 by a predetermined dimension, whereby the lower end portion 5a of the column member 5 and the foundation pile 2 are formed in an integrated state. You. In this case, it is assumed that extra pile processing of the pile concrete C2 is not performed. After that, the position above the pile head 4 of the foundation pile 2 in the excavation pit 16 is backfilled with the backfill soil 20.

Next, as shown in FIG. 9, the 1F floor structure 21 is constructed by being supported on the upper end 5b of the column member 5 continuously installed above the foundation pile 2. The ground G below the 1F floor structure 21 is sequentially excavated while being used as a work floor, and the B1F floor structure 22 and the B2F floor structure 23 are formed by being supported by the columns 7. Then, the lower surface 3b of the underground portion 3a is formed integrally with the upper end portion 11a of the steel pipe 11, thereby completing the underground portion 3a. That is,
The underground portion 3a is formed by the reverse driving method. Thereafter, the building 1 is completed by continuously constructing a portion of the building 1 above the 1F floor structure 21.

In the above-described construction method of the building 1, after the work of erecting the column members 5, the construction can be performed in the same procedure as the ordinary reverse hitting method. Further, an enlarged diameter portion 8 having a smaller diameter than the foundation pile 2 is provided for the column member 5, and after the construction, the enlarged diameter portion 8 allows the base portion 2 a of the upper structure 2 and the pile head of the foundation pile 2 to be formed. Since the connection with the section 4 is made, the enlarged diameter section 8 can function as a semi-rigid joint having a smaller sectional performance than the foundation pile 2. That is,
The reverse striking method can be adopted while securing the moment reducing effect by the enlarged diameter portion 8, and reasonable construction can be performed at low cost while maintaining the seismic performance. In addition, compared to the case where a pin device (stress transmitting device) is used, there is no need to adjust the device or control the accuracy, which is more advantageous in terms of the construction period and cost.

In the above-described construction method of the building 1, the enlarged diameter portion 8 is formed by connecting the steel pipe 1 fitted around the pillar main body 7.
1 and the concrete C1 filled between the steel pipe 11 and the column body 7, so that the enlarged diameter portion 8 is made of confined concrete covered with the steel pipe 11 so as to be able to stably cope with high axial force. Can be. Further, since the concrete C1 in the enlarged diameter portion 8 is cast in the air, it is easy to ensure the quality, which is advantageous in terms of construction management.

When the column member 5 is erected, a cushioning material 12 for preventing adhesion between the enlarged diameter portion 8 and the pile concrete C2 of the foundation pile 2 is provided in a certain area around the enlarged diameter portion 8. Because of the provision, the flexible length of the enlarged diameter portion 8 having a small rigidity can be adjusted to a predetermined length. As a result, it is possible to exhibit the predetermined performance as designed by eliminating the influence of a portion having a large variation depending on the construction condition such as excess concrete.

In forming the enlarged diameter portion 8,
Since the central portion of the lower surface C1a of the concrete C1 filled between the steel pipe 11 and the column material main body 7 is cast so as to be convex downward, as shown in FIG. 5
When the pile concrete C2 is cast while the pile is kept upright, the filling property of the pile concrete C2 below the enlarged diameter portion 8 can be secured, and the construction accuracy can be secured.

In the above-mentioned building 1, the foundation pile 2
Pile head 4 and the lower surface 3b of the upper structure 3 are vertically separated from each other, and the space between the foundation pile 2 and the upper structure 3 is
Since the column member 5 is connected by the enlarged diameter portion 8, the column main body 7, the steel pipe 11 of the enlarged diameter portion 8, and the concrete C 1
Will bear the axial force. Therefore, unlike the related art, there is no need to perform an extra filling process (hanging work) for securing the soundness of the pile concrete C2 of the pile head 4. This eliminates the hanging work, which has been a source of bad environments such as noise, vibration, and dust, which not only contributes to shortening the construction period and cost,
Environmentally friendly construction can be performed. Further, since there is no need to anchor the pile main bar to the superstructure, the construction can be rationalized and the cost can be reduced. Moreover, as described above, the diameter-enlarged portion 8 has a smaller diameter than the foundation pile 2 and therefore has a small cross-sectional performance, so that it does not function as a complete rigid joint. Are joined in a state close to the pin. Therefore, the same function as that of the conventional pin device (stress transmitting device) can be obtained.
Further, in this case, the column member 5 is located so as to penetrate from the pile head 4 of the foundation pile 2 to the lower surface 3b of the upper structure 3, whereby even when a tensile force is generated in the foundation pile 2. This makes it possible to contribute to improving the earthquake resistance of the building 1.

Further, in the above-mentioned building 1, the pillar 5
Is configured such that the steel pipe 11 is filled with the concrete C1. Therefore, it is possible to stably cope with a high axial force. Further, since the enlarged diameter portion 8 is sheared and reinforced by the steel pipe 11, a high degree of shear strength can be exhibited without a shear reinforcing bar, and the stability is good.

Further, since the upper end 11a of the steel pipe 11 constituting the enlarged diameter portion 8 is buried in the lower surface 3b of the upper structure 3, the shear force acting on the foundation pile 2 is reduced by the upper end 11a of the steel pipe 11. It can be treated as bearing stress and has high stability.

In the above-mentioned building 1, the foundation pile 2
The concrete C1 filled between the steel pipe 11 and the column body 7 can be cast in the air, whereas the pile concrete C2 is underwater concrete containing bentonite. High strength ones can be used easily. As a result, the ability of the enlarged diameter portion 8 to retain the axial force can be ensured.

Next, the results of numerical analysis performed to confirm the effects of the present embodiment will be described. The conditions simulated in this numerical analysis are as follows. -The foundation pile shall be a straight pile from the ground surface with a pile diameter: B = 1600 mm and a pile length: L = 20 m. -Provide a small pile diameter at the pile head of the foundation pile. (This portion corresponds to the enlarged diameter portion 8 in the above embodiment.) The length of this portion is 1 m, and the diameter is B = 800 mm. -The N value of the ground G is set to 10 in all areas. A horizontal force of 1.2 MN is applied to the pile head of the foundation pile (the upper end of the enlarged diameter portion 8 in the above embodiment) to restrict (fix) the pile head to rotation.・ The ground spring (k _h B) attached to the foundation pile is set as follows in accordance with the Architectural Institute of Japan basic structure design guidelines. That is, ^{_{k h B = 0.8E 0 B 1/4}} ( depth direction of the unit horizontal springs per length) where, k _h is the horizontal subgrade reaction coefficient (N / m ^3), B is
The diameter of the pile (m), E ₀ is the Young's modulus of the ground (N / m ² )
It is. The model diagram of the pile and the ground spring is shown in FIG.
(A).

FIG. 10 (b) shows a case where the pile head has a variable cross section (when the enlarged diameter portion 8 is provided as in the above embodiment).
In the case of the same cross section as the entire length (the enlarged diameter portion 8 in
And FIG. 6 shows a graph comparing the relationship between the horizontal displacement of the foundation pile (horizontal axis) and the depth from the ground surface (vertical axis). Fig. 10 (c) compares the relationship between the bending moment (horizontal axis) generated at the foundation pile and the depth from the ground surface (vertical axis) in the case of the modified cross section of the pile head and the case of the same length. The graph is shown.

As shown in these figures, as a result of numerical analysis, the following was found.・ When the cross section is narrowed at the pile head, the horizontal displacement of the pile head increased to about 1.6 times, but the difference between them is small when the pile diameter is 2 times or more in the underground direction.・ When the section is narrowed at the pile head, the pile head bending moment is 4
It was reduced to 0%, and the maximum underground bending moment was about the same as the pile head. As a result, the maximum stress generated in the pile body is drastically reduced to less than half. In addition, since the pile head bending is reduced, the stress acting on the superstructure frame of the building from the foundation pile is reduced, so that the foundation design can be rationalized. It is confirmed that these results show the same tendency even if the ground stiffness or the pile diameter changes. From this, by adopting the structure as in the above embodiment, It is understood that the safety of the vehicle is greatly improved.

In the above embodiment, another configuration may be adopted without departing from the spirit of the present invention. For example, when forming the pillar 5, the steel pipe 11, the concrete C 1, and the anchor bar 13 are integrated and manufactured as a precast member, and this is integrated with the pillar body 7 by grout or the like on site. You may.

Further, as the concrete C1 to be filled in the steel pipe 11, high-strength concrete may be used.

The anchor bars 13 arranged in the steel pipe 11 may be arranged concentrically in accordance with the steel pipe 11, but in accordance with the reinforcing bars of the foundation, the anchor bars 13 are arranged vertically and horizontally in a plan view in the same manner as the column having a rectangular cross section. It is also possible to make it. In addition, anchor bar 1
3 can also be directly welded to the steel pipe 11.

In the above embodiment, the steel pipe 11
May be extended further upward, and a steel pipe may be used as a column of the upper structure 3, and this may be integrated with the steel pipe 11. In this case, the bending stress generated in the pile head 4 can be easily transmitted to the upper structure 3.
Especially in soft ground or ground where liquefaction is expected during an earthquake,
When designing so as not to cause damage to the structural frame including the foundation pile 2 against the pile head bending stress, the steel pipe 11 is anchored in the upper structure 3 or integrated with the steel material of the column of the upper structure 3. It is effective.

Further, in the above-described embodiment, the reverse hitting method is employed, but the present invention is not limited to this.
You may make it employ a sequential driving method. In this case, the range of the column member 5 can be set only from the pile head 4 of the foundation pile 2 to slightly above the lower surface 3 b of the upper structure 3, and can be embedded in the foundation of the foundation pile 2 and the upper structure 3. . Further, in the above embodiment, the upper structure 3 may be configured not to have the underground portion 3a, and the foundation pile 2 may be constructed up to the ground surface.

[0049]

As described above, in the method for constructing a building according to the first aspect, after the work for erection of the pillars, the construction can be performed in the same procedure as that of the normal upside-down method. Furthermore, the semi-rigid joining function between the underground portion of the upper structure and the pile head of the foundation pile is exerted on the enlarged diameter portion provided for the column member, and the moment reduction effect can be secured. Therefore, reasonable construction can be performed at low cost while maintaining seismic performance while adopting the reverse striking method. In addition, compared to the case where a pin device (stress transmitting device) is used, there is no need to adjust the device or control the accuracy, which is more advantageous in terms of the construction period and cost.

In the building construction method according to the second aspect, the enlarged diameter portion is made of confined concrete covered with a steel pipe, so that it can stably cope with a high axial force. In addition, since concrete in the enlarged diameter portion can be cast in the air, the quality can be easily ensured, which is advantageous in terms of construction management.

In the building construction method according to the third aspect and the building according to the eighth aspect, the flexible length in the enlarged diameter portion is set to a predetermined value by the cushioning material provided in a fixed area around the enlarged diameter portion. The length can be adjusted, and thereby, the influence of a portion having a large variation depending on the construction condition, such as excess concrete, can be eliminated, and the predetermined performance as designed can be exhibited.

In the construction method of a building according to the fourth aspect, since the central portion of the lower surface of the concrete filled between the steel pipe and the pillar main body is cast so as to protrude downward. In addition, the filling property of the pile concrete below the enlarged diameter portion can be secured, and the construction accuracy can be secured.

[0053] In the building according to claim 5, the pile head of the foundation pile and the lower surface of the upper structure are vertically spaced apart from each other, and the space between the foundation pile and the upper structure is expanded. Because it is connected by the diameter part, the column body and the steel pipe and concrete of the enlarged diameter part will bear the axial force, and extra pile processing to secure the soundness of the pile head concrete (hanging work) There is no need to do. Therefore,
Since there is no longer a hanging work that has caused bad environments such as sound, vibration, and dust, it is possible to not only contribute to shortening the construction period and cost, but also to perform environment-friendly construction. Further, since there is no need to anchor the pile main bar to the superstructure, the construction can be rationalized and the cost can be reduced. Further, the enlarged diameter portion is made to function as a semi-rigid joint, and the same function as a conventional pin device (stress transmitting device) can be obtained. Further, when a tensile force is generated in the foundation pile, it can be applied to the column material, which can contribute to the improvement of the earthquake resistance of the building.

In the building according to the sixth aspect, since the enlarged diameter portion of the pillar is constituted by a steel pipe filled with concrete, it can stably cope with a high axial force. Further, since the enlarged diameter portion is sheared and reinforced by the steel pipe, a high degree of shear strength can be exhibited without a shear reinforcing bar, and the stability is good.

In the building according to the seventh aspect, the shear force acting on the foundation pile can be treated as the bearing stress at the upper end of the steel pipe, and the stability is high.

In the building according to the ninth aspect, the concrete in the steel pipe has higher strength than the pile concrete of the foundation pile, and the ability to retain the axial force in the enlarged diameter portion can be secured.

[Brief description of the drawings]

FIG. 1 is a vertical sectional view of a main part of a building, schematically showing an embodiment of the present invention.

FIG. 2 is a sectional view taken along line II in FIG.

FIG. 3 is a sectional view taken along line II-II in FIG.

FIG. 4 is a perspective sectional view of the column shown in FIGS. 1 to 3;

FIG. 5 is a view showing one step of the building construction method of the present invention, and is an elevational sectional view showing a situation when a pillar is manufactured on the ground.

FIG. 6 is an elevational sectional view showing a situation when an excavation pit is formed in the ground.

FIG. 7 is a view showing the next step of FIG. 6, and is an elevational sectional view showing a situation when a pillar is built in the excavation pit.

FIG. 8 is a view showing the next step of FIG. 7, and is an elevational sectional view showing a situation where a pile concrete has been poured into an excavation pit and the space above it has been backfilled.

FIG. 9 is a view showing the next step of FIG. 8, and is an elevational sectional view showing the situation when the underground portion of the upper structure is formed by being supported by the standing pillars.

10A and 10B are diagrams showing an outline of a numerical analysis performed to confirm the effect of the present invention, wherein FIG. 10A is a schematic diagram of a pile and a ground spring set in performing the numerical analysis, and FIG.
Is a graph comparing the relationship between the horizontal displacement of the foundation pile (horizontal axis) and the depth from the ground surface (vertical axis) in the case of the section of the pile head deformed section and the case of the same section of the entire length. It is the graph which compared the relationship between the bending moment (horizontal axis) generated in the foundation pile and the depth from the ground surface (vertical axis) in the case of the variable section of the pile head and the case of the same cross section in the entire length.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Building 2 Foundation pile 3 Upper structure 3a Underground part 3b Lower surface 4 Pile head 5 Column material 5a Lower part 7 Column material main body 7a Lower part 8 Large diameter part 11 Steel pipe 11a Upper part 11b Lower part 12 Buffer material

Claims (9)

[Claims] 1. A method for constructing a building in which a superstructure having an underground portion is supported by a foundation pile, comprising: a column member constituting the underground portion in a ground at a building installation target position. While standing upright, the foundation pile is installed in a state integrated with at least the lower end of the pillar, and the floor structure constituting the upper structure is supported by the upper end of the pillar, and thereafter, The ground below the floor structure is excavated to form an underground portion of the upper structure below the floor structure. The enlarged diameter portion is formed so that its diameter is smaller than that of the foundation pile, and at the time of erecting the column material, the lower end is formed with the foundation pile. So that its upper end is integrated with the underground part of the superstructure. Method for constructing a building, characterized in that to locate. 2. The method for building a building according to claim 1, wherein the pillar has a configuration in which the enlarged diameter portion is provided around a central portion of a pillar body, and the enlarged diameter portion includes: A method of constructing a building, comprising: a steel pipe fitted around the pillar body and concrete filled between the steel pipe and the pillar body. 3. The method for constructing a building according to claim 1, wherein the erecting part and the foundation pile are fixed in a certain area around the expanding part when the pillar is erected. A method for constructing a building, characterized by providing a cushioning material for preventing adhesion to concrete to be formed. 4. The method for constructing a building according to claim 2, wherein the concrete filled between the steel pipe and the column main body is directed downward at a central portion of a lower surface thereof. A method of building a building, characterized by being cast into a convex shape. 5. A foundation pile installed in the ground, and an upper structure supported by the foundation pile, wherein a pile head of the foundation pile and a lower surface of the upper structure are vertically separated from each other. A pillar constituting at least a lower portion of the upper structure has a lower end buried in the pile head, and the pillar is located between the pile head and the lower surface of the upper structure. Is formed as an enlarged diameter portion having a larger diameter dimension than other portions, and the enlarged diameter portion has a smaller diameter dimension than the foundation pile. Building. 6. The building according to claim 5, wherein the column member has a configuration in which the enlarged diameter portion is formed around a central portion of a column member main body formed of a steel frame material. The building is characterized in that the part is formed of a steel pipe fitted around the pillar body and concrete filled between the steel pipe and the pillar body. 7. The building according to claim 6, wherein an upper end of the steel pipe is embedded in a lower surface of the upper structure. 8. The building according to claim 6, wherein a lower end of the steel pipe is embedded in concrete forming the pile head, and the steel pipe and the pile head are connected to each other. A building characterized in that a cushioning material for preventing adhesion between them is arranged between the constituent concretes. 9. The building according to claim 6, wherein the foundation pile is a cast-in-place concrete pile, and concrete filled between the steel pipe and the column body is A building having a higher strength than the concrete constituting the cast-in-place concrete pile.