JP6703845B2 - Foundation structure - Google Patents

Description

The present invention relates to foundation structures.

BACKGROUND ART A basic structure of a building is known, which has a footing formed of cast-in-place concrete on a pile head of a pile buried in the ground. In such a basic structure, work such as formwork installation, bar arrangement, and concrete placement is required for footing construction, which requires a lot of construction work. For example, Patent Document 1 discloses a joint structure in which a footing is joined to a cast-in-place RC pile via a main reinforcing bar.

JP, 2006-299760, A

An object of the present invention is to reduce the time and effort required to construct a foundation structure in the field in consideration of the fact.

In the invention of the first aspect, a pile buried in the ground, a joint portion supported on an upper portion of the pile, a foundation beam joined to the joint portion, and a lower portion surrounding the pile head portion of the pile. With the upper part is located in the joint part, a steel pipe, a precast concrete cylinder, or a lower steel pipe surrounding the pile head and a precast concrete upper cylinder integrated with the lower steel pipe located in the joint part. It is a basic structure having a formed stress transfer tube and a filling material filled and cured inside the stress transfer tube.

In the invention of the first aspect, the stress due to the vertical load acting on the joint can be transmitted to the pile head through the stress transmission pipe and the hardened filler. Also, by installing a stress transmission pipe so as to surround the pile head and filling the inside of this stress transmission pipe with a filling material, it is possible to construct a foundation structure, thus reducing the construction work of the foundation structure on site. can do.

In a second aspect of the invention, in the basic structure of the first aspect, the stress transmission pipe is formed of a steel pipe, and a core rebar is provided from the pile head portion to the joint portion.

According to the second aspect of the invention, the stress due to the pulling load acting on the joint portion is transmitted to the pile via the core rebar, so that the pile can resist the pulling force acting on the joint portion.

According to a third aspect of the invention, in the basic structure of the first aspect, the stress transmission pipe is formed of a steel pipe, and a stress transmission means is provided on an inner peripheral surface of the steel pipe surrounding the pile head.

In the invention of the third aspect, the pulling load acting on the joint portion is transmitted by transmitting the stress due to the pulling load acting on the joint portion to the pile through the stress transmission pipe, the stress transmitting means, and the hardened filling material. You can resist the pile against.

Since the present invention has the above-described configuration, it is possible to reduce the time and labor required for constructing the foundation structure on site.

It is a front sectional view showing a basic structure concerning a 1st embodiment of the present invention. It is a front sectional view showing a variation of the basic structure according to the first embodiment of the present invention. It is a front sectional view showing a variation of the basic structure according to the first embodiment of the present invention. It is a front sectional view showing a basic structure concerning a 2nd embodiment of the present invention. It is a front sectional view showing a basic structure concerning a 3rd embodiment of the present invention. It is a front sectional view showing a variation of the basic structure according to the third embodiment of the present invention. It is a front sectional view showing a variation of the basic structure according to the third embodiment of the present invention. It is a front sectional view showing a variation of the basic structure according to the first embodiment of the present invention. FIG. 9 is a sectional view taken along line AA of FIG. 8. It is a front sectional view showing a variation of the basic structure according to the first embodiment of the present invention. It is a front sectional view showing a variation of the basic structure according to the first embodiment of the present invention.

An embodiment of the present invention will be described with reference to the drawings. First, the basic structure according to the first embodiment of the present invention will be described.

As shown in the front cross-sectional view of FIG. 1, the foundation structure 10 includes PHC piles 14 (Pretensioned Spun High Strength Concrete Piles) as piles buried in the ground 12, and precast tension high-strength prestressed concrete piles. It is configured to have concrete foundation beams 16A and 16B, a joint portion 18 supported on the upper portion of the PHC pile 14 and joined to the foundation beams 16A and 16B, and a footing 20.

The footing 20 is configured to have a cylindrical steel pipe 22 as a stress transmission pipe and a concrete V as a filling material that is filled and hardened inside the steel pipe 22 (hollow portion). The steel pipe 22 has a lower portion surrounding the pile head portion 24 of the PHC pile 14 and an upper portion positioned at the joint portion 18. That is, the upper portion of the footing 20 constitutes the joint portion 18. A rooting depth H1 of the steel pipe 22 with respect to the upper surface of the ground 12 is large. The steel pipe 22 may be a tubular steel pipe, and may be, for example, a rectangular steel pipe.

The connection part 18 supports a column 26 made of reinforced concrete. The foundation beams 16A and 16B are joined to the joint portion 18 by the concrete V cast in place on the joint portions 28A and 28B between the joint portion 18 and the foundation beams 16A and 16B. A floor slab 30 is provided on the foundation beams 16A and 16B.

A plurality of steel rods 34 as stress transmitting means functioning as a shear cotter are attached in the vertical direction in the circumferential direction of the inner peripheral surface of the lower portion of the steel pipe 22 surrounding the pile head 24. Further, in the circumferential direction of the outer peripheral surface of the pile head 24 of the PHC pile 14, the inner peripheral surface of the upper portion of the steel pipe 22 located in the joint portion 18, and the outer peripheral surface of the upper portion of the steel pipe 22 located in the joint portion 18, a shear cotter is formed. A plurality of steel rods 32, 36, 38 functioning as are attached in the vertical direction. The steel rods 32, 34, 36, 38 may be any one that functions as a shear cotter that transmits stress. For example, a reinforcing bar, a flat plate, a stud, or a groove may be used.

Inside the steel pipe 22, a rebar cage 40 is provided so as to surround the pile head 24 of the PHC pile 14, and a rebar cage 44 is provided so as to surround the column main bar 42 projecting downward from the column 26. The outer peripheral surface of the pile head 24 of the PHC pile 14 and the inner peripheral surface of the steel pipe 22 are separated from each other so that the outer peripheral surface of the pile head 24 and the inner peripheral surface of the steel pipe 22 can be completely distributed. All of the inside (hollow portion) of the steel pipe 22 is filled with concrete V and hardened. Thereby, the steel pipe 22, the pile head 24, the column main bar 42, the rebar cages 40 and 44, the steel rods 32, 34 and 36, and the concrete V are integrated. The rebar cages 40 and 44 may be provided appropriately, and the rebar cages 40 and 44 may not be provided as long as sufficient concrete strength is obtained.

As an example of the construction procedure of the foundation structure 10, first, the PHC pile 14 is driven on the ground 12. Next, the rebar cage 40 is installed, and then the steel pipe 22 is installed. Next, the rebar cage 44 is installed, and after that, the column main bar 42 of the column 26 is arranged. Next, concrete V is cast into the inside (hollow part) of the steel pipe 22 and the joints 28A and 28B by cast-in-place, and the concrete V of the floor slab 30 is cast to cure these concrete V, The foundation structure 10 is constructed. The steel pipe 22 may be provided with a device for transporting and setting the steel pipe 22. For example, a suspension ring for suspending with a crane or the like may be provided in the steel pipe 22, or a through hole for inserting the rod-shaped member such as a reinforcing bar and lifting the steel pipe 22 may be formed in the steel pipe 22.

Next, the operation and effect of the basic structure according to the first embodiment of the present invention will be described.

In the basic structure 10 of the first embodiment, as shown in FIG. 1, the steel rods 36 and 38 attached to the inner peripheral surface of the upper portion of the steel pipe 22 function as a shear cotter, and the inside (hollow portion) of the upper portion of the steel pipe 22 and Stress is transmitted between the concrete V that is filled and hardened outside and the steel pipe 22. Further, the steel rod 34 attached to the inner peripheral surface of the lower portion of the steel pipe 22 functions as a shear cotter, and the stress is transmitted between the steel pipe 22 and the concrete V hardened by filling the inside (hollow portion) of the lower portion of the steel pipe 22. To be done. Further, the steel rod 32 attached to the outer peripheral surface of the pile head 24 of the PHC pile 14 functions as a shear cotter, and the concrete V hardened by filling the inside (hollow portion) of the lower portion of the steel pipe 22 with the pile head 24. The stress is transmitted between the two.

By these, the stress due to the vertical load and the pulling load acting on the joint portion 18 from the pillar 26 and the foundation beams 16A and 16B is filled in the inside (hollow portion) and the outside of the upper portion of the steel pipe 22 and the hardened concrete V and the steel rod 36. , 38, the steel pipe 22, the steel rod 34, the concrete V hardened and filled in the lower portion of the steel pipe 22 (hollow portion), and the steel rod 32 are transmitted to the pile head 24 of the PHC pile 14 through this order, and The PHC pile 14 can be resisted against the vertical load and the withdrawal load acting on the joint portion 18 from the base plate 26 and the foundation beams 16A and 16B. Further, the stress due to the horizontal load acting on the joint portion 18 from the pillar 26 and the foundation beams 16A and 16B is transmitted to the pile head portion 24 of the PHC pile 14 through the footing 20, and the pillar 26 and the foundation beams 16A and 16B The PHC pile 14 can be resisted against the horizontal load acting on the joint portion 18.

Further, the depth H1 of the root of the steel pipe 22 with respect to the upper surface of the ground 12 is large, whereby the length of the lower portion of the steel pipe 22 in the vertical direction can be increased, and a large number of inner peripheral surfaces of the lower portion of the steel pipe 22 can be provided. Since the steel rod 34 of No. 1 is attached, the stress can be efficiently transmitted between the steel pipe 22 and the concrete V filled in the lower portion of the steel pipe 22 and hardened. Therefore, the PHC pile 14 can be effectively resisted against the pulling load acting from the pillar 26 and the foundation beams 16A and 16B to the joint portion 18.

Further, the steel rod 38 attached to the outer peripheral surface of the upper portion of the steel pipe 22 functions as a shear cotter, and stress can be efficiently transmitted between the steel pipe 22 and the joints 28A and 28B.

Further, in the foundation structure 10 of the first embodiment, as shown in FIG. 1, the steel pipe 22 is installed so as to surround the pile head portion 24 of the PHC pile 14, and the concrete V is placed inside (hollow portion) of the steel pipe 22. Since the foundation structure 10 can be constructed by filling, the labor of constructing the foundation structure 10 on site can be reduced.

The basic structure according to the first embodiment of the present invention has been described above.

In the basic structure 10 of the first embodiment, as shown in FIG. 1, on the inner peripheral surface of the upper portion of the steel pipe 22 located in the joint portion 18 and the outer peripheral surface of the upper portion of the steel pipe 22 located in the joint portion 18, Although the example in which the steel rods 36 and 38 functioning as the shear cotters are attached has been shown, the steel rods functioning as the shear cotter are the inner peripheral surface of the upper portion of the steel pipe 22 located in the joint portion 18, and the steel pipes located in the joint portion 18. 22 may be attached to at least one of the outer peripheral surfaces of the upper part.

Further, in the first embodiment, as shown in FIG. 1, an example is shown in which the depth of penetration H1 of the steel pipe 22 with respect to the upper surface of the ground 12 is increased, but the depth of penetration of the steel pipe 22 with respect to the upper surface of the ground 12 is It may be smaller or larger than the rooting depth H1.

For example, as in the basic structure 46 shown in the front cross-sectional view of FIG. 2, the rooting depth H2 of the steel pipe 22 with respect to the upper surface of the ground 12 may be smaller than the rooting depth H1.

The base structure 46 has a shorter length in the up-down direction of the lower portion of the steel pipe 22 as compared with the base structure 10, and accordingly, the number of the steel rods 34 as the stress transmitting means functioning as a shear cotter is reduced. .. Further, a core reinforcing bar 48 is provided from the pile head portion 24 of the PHC pile 14 to the joint portion 18.

In the foundation structure 46, the stress due to the pulling load acting on the joint portion 18 is transmitted to the PHC pile 14 via the steel pipe 22 and the core rebar 48, so that the PHC pile 14 is subjected to the pulling load acting on the joint portion 18. Can be resisted. That is, the core rebar 48 imparts a resistance force against a pulling load, which is insufficient because the number of the steel rods 34 functioning as the shear cotter decreases.

Further, in the foundation structure 46, since the rooting depth H2 of the steel pipe 22 with respect to the upper surface of the ground 12 is small, it is possible to reduce the time and labor required for excavating the ground 12 and carrying excavated soil.

In the basic structure 46, the steel rod 34 may be omitted as long as the pulling load acting on the joint portion 18 can be sufficiently borne by the core rebar 48.

Further, for example, as in the basic structure 50 shown in the front cross-sectional view of FIG. 3, the rooting depth H3 of the steel pipe 22 with respect to the upper surface of the ground 12 may be smaller than the rooting depth H2.

The base structure 50 has a shorter vertical length of the lower portion of the steel pipe 22 than the base structure 46. Further, a core rebar 52 is provided from the pile head portion 24 of the PHC pile 14 to the joint portion 18.

In the foundation structure 50, the stress due to the pulling load acting on the joint portion 18 is transmitted to the PHC pile 14 through the core rebar 52, so that the PHC pile 14 resists the pulling load acting on the joint portion 18. You can

Further, in the foundation structure 50, since the rooting depth H3 of the steel pipe 22 with respect to the upper surface of the ground 12 is small, it is possible to reduce the time and labor required for excavating the ground 12 and carrying excavated soil.

In the foundation structure 50, the core rebar 52 may be omitted if the PHC pile 14 is designed not to bear the pulling load.

Next, a basic structure according to the second embodiment of the present invention will be described. In the following description, the same structures as those of the basic structure according to the first embodiment of the present invention will be denoted by the same reference numerals and will be appropriately omitted for description.

As shown in the front sectional view of FIG. 4, the foundation structure 54 is supported on the PHC pile 14 as a pile buried in the ground 12, the foundation beams 16A and 16B made of precast concrete, and the upper portion of the PHC pile 14. In addition, the joint portion 18 to which the foundation beams 16A and 16B are joined and the footing 56 are configured.

The footing 56 has a hollow precast concrete tubular body 58 as a stress transfer tube, and concrete V as a filler that is filled inside the precast concrete tubular body 58 (hollow portion) and hardened. Has been done. That is, the entire outer peripheral portion of the footing 56 is configured by the precast concrete tubular body 58.

The precast concrete tubular body 58 has a lower portion surrounding the pile head portion 24 of the PHC pile 14 and an upper portion located at the joint portion 18. That is, the upper portion of the footing 56 constitutes the joint portion 18. A rooting depth H4 of the precast concrete cylinder 58 with respect to the upper surface of the ground 12 is small.

A plurality of grooves 60 functioning as sheer cotters are formed in the vertical direction in the circumferential direction of the inner peripheral surface of the precast concrete tubular body 58. As a result, the stress is transmitted between the precast concrete tubular body 58 and the concrete V filled and cured in the precast concrete tubular body 58. Further, a core rebar 62 is provided from the pile head portion 24 of the PHC pile 14 to the joint portion 18. The groove 60 may be any one that functions as a shear cotter that transmits stress. For example, a steel rod, a reinforcing bar, a flat plate, or a stud may be used.

The outer peripheral surface of the pile head 24 of the PHC pile 14 is separated from the inner peripheral surface of the precast concrete cylinder 58, and between the outer peripheral surface of the pile head 24 and the inner peripheral surface of the precast concrete cylinder 58. The entire interior (hollow portion) of the precast concrete tubular body 58 is filled with the concrete V so as to be completely spread and hardened. As a result, the precast concrete cylinder 58, the pile head 24, the column main bar 42, the reinforcing bar basket 44, the core reinforcing bar 62, and the concrete V are integrated.

Next, the operation and effect of the basic structure according to the second embodiment of the present invention will be described.

In the foundation structure 54 according to the second embodiment, as shown in FIG. 4, the stress due to the vertical load acting from the pillar 26 and the foundation beams 16A and 16B to the joint portion 18 is applied to the inside of the precast concrete tubular body 58 (hollow). Vertical) which is transmitted to the pile head 24 of the PHC pile 14 through the concrete V filled in the (part) and the hardened concrete tubular body 58 and acts from the pillar 26 and the foundation beams 16A and 16B to the joint portion 18. The PHC pile 14 can be resisted against the load.

Further, by transmitting the stress due to the pulling load acting from the column 26 and the foundation beams 16A and 16B to the joint portion 18 to the PHC pile 14 through the core rebar 62, the pulling load acting on the joint portion 18 is adjusted to PHC. The pile 14 can be resisted. Further, by transmitting the stress due to the horizontal load acting from the pillar 26 and the foundation beams 16A and 16B to the joint portion 18 to the pile head 24 of the PHC pile 14 through the footing 56, the pillar 26 and the foundation beam 16A, The PHC pile 14 can be resisted from the horizontal load acting from 16B to the joint portion 18.

Further, in the foundation structure 54 according to the second embodiment, as shown in FIG. 4, a precast concrete cylinder 58 is installed so as to surround the pile head 24 of the PHC pile 14, and the precast concrete cylinder 58 is Since the foundation structure 54 can be constructed by filling the inside (hollow portion) with the concrete V, it is possible to reduce the time and effort required to construct the foundation structure 54 on site.

For example, by making the precast concrete tubular body 58 a hollow member, it is possible to reduce the weight and reduce the time and effort required to carry the precast concrete tubular body 58. Further, by filling the inside (hollow portion) of the precast concrete tubular body 58 with concrete V, it is not necessary to separately install a formwork for placing the concrete V, and further, the concrete to be placed on site The amount of V can be reduced.

The basic structure according to the second embodiment of the present invention has been described above.

In addition, in 2nd Embodiment, as shown in FIG. 4, the example which made the rooting depth H4 of the precast concrete cylinder 58 with respect to the upper surface of the ground 12 small was shown, but the precast concrete cylinder with respect to the upper surface of the ground 12 was shown. The rooting depth of 58 may be larger or smaller than the rooting depth H4. In the foundation structure 54, since the rooting depth H4 of the precast concrete cylindrical body 58 with respect to the upper surface of the ground 12 is small, it is possible to reduce the time and labor required for excavating the ground 12 and carrying excavated soil. In the foundation structure 54, the core rebar 62 may be omitted if the PHC pile 14 is designed not to bear the pulling load.

Next, a basic structure according to the third embodiment of the present invention will be described. In the following description, the same structures as those of the basic structure according to the first embodiment of the present invention will be denoted by the same reference numerals and will be appropriately omitted for description.

As shown in the front sectional view of FIG. 5, the foundation structure 64 is supported on the PHC pile 14 as a pile buried in the ground 12, the foundation beams 16A and 16B made of precast concrete, and the upper portion of the PHC pile 14. In addition, it has a joint portion 18 to which the foundation beams 16A and 16B are joined, and a footing 66.

The footing 66 includes a hollow member 68 as a stress transmission pipe, and concrete V as a filler that is filled inside the hollow member 68 (hollow portion) and hardened. The hollow member 68 is located in the cylindrical lower steel pipe 70 surrounding the pile head 24 of the PHC pile 14 and the joint portion 18, and the lower end is joined to the upper end of the lower steel pipe 70 to form the lower steel pipe 70. It is configured to have an integrated hollow precast concrete upper cylinder 72. Further, the hollow portion of the lower steel pipe 70 and the hollow portion of the precast concrete upper tubular body 72 communicate with each other. That is, the upper portion of the footing 66 constitutes the joint portion 18. The depth H1 of insertion of the lower steel pipe 70 with respect to the upper surface of the ground 12 is large.

Further, a plurality of pile head reinforcing bars 74 are attached to the inner peripheral surface of the upper end portion of the lower steel pipe 70 in the circumferential direction, and the portion protruding upward from the lower steel pipe 70 of the pile head reinforcing bar 74 is a precast concrete upper cylinder. It is embedded in the body 72. Thereby, the stress is transmitted from the precast concrete upper tubular body 72 to the lower steel pipe 70 via the pile head reinforcing bar 74.

A plurality of steel rods 34 as stress transmitting means functioning as shear shears are attached in the vertical direction in the circumferential direction of the inner peripheral surface of the lower steel pipe 70 surrounding the pile head 24. Further, a plurality of steel rods 32 functioning as shea cotters are attached to the outer peripheral surface of the pile head 24 of the PHC pile 14 in the vertical direction. Further, in the circumferential direction of the inner circumferential surface of the precast concrete upper tubular body 72, a plurality of grooves 60 functioning as shea cotters are formed in the vertical direction. The steel rods 32 and 34 and the groove 60 may be anything that functions as a shear cotter that transmits stress. For example, it may be a steel rod, a reinforcing bar, a flat plate, a stud, or a groove.

The outer peripheral surface of the pile head 24 of the PHC pile 14 and the inner peripheral surface of the lower steel pipe 70 are separated from each other so that the outer peripheral surface of the pile head 24 and the inner peripheral surface of the lower steel pipe 70 can be completely spread. Then, the entire interior (hollow portion) of the hollow member 68 is filled with concrete V and hardened. Thereby, the hollow member 68 (the lower steel pipe 70, the precast concrete upper cylinder 72), the pile head 24, the column main bar 42, the rebar cages 40 and 44, the steel rods 32 and 34, and the concrete V are integrated. ..

As an example of the construction procedure of the foundation structure 64, first, the PHC pile 14 is driven on the ground 12. Next, the rebar cage 40 is installed, and then the hollow member 68 is installed. Next, the rebar cage 44 is installed, and after that, the column main bar 42 of the column 26 is arranged. Next, by casting the concrete V inside the hollow member 68 (hollow portion) and the joints 28A and 28B by cast-in-place, the concrete V of the floor slab 30 is cast, and these concrete V are hardened. , Build the base structure 64.

Next, the operation and effect of the basic structure according to the third embodiment of the present invention will be described.

In the basic structure 64 according to the third embodiment, as shown in FIG. 5, the groove 60 formed on the inner peripheral surface of the precast concrete upper cylinder body 72 functions as a shear cotter, and the precast concrete upper cylinder body 72 is The stress is transmitted between the concrete V that is filled in the interior (hollow portion) and hardened, and the precast concrete upper tubular body 72. Further, the steel rod 34 attached to the inner peripheral surface of the lower steel pipe 70 functions as a shear cotter, and stress is generated between the lower steel pipe 70 and the concrete V that is filled in the lower steel pipe 70 (hollow portion) and hardened. Transmitted. Further, the steel rod 32 attached to the outer peripheral surface of the pile head 24 of the PHC pile 14 functions as a shear cotter to fill the inside (hollow portion) of the lower steel pipe 70 with the hardened concrete V and the pile head 24. The stress is transmitted between the two. In addition, the pile head reinforcement 74 transmits stress from the precast concrete upper tubular body 72 to the lower steel pipe 70.

By these, the stress caused by the vertical load and the pulling load acting on the joint portion 18 from the pillar 26 and the foundation beams 16A, 16B is filled in the inside (hollow portion) of the precast concrete upper tubular body 72 and hardened concrete V, precast The concrete upper cylinder 72, the pile head reinforcement 74, the lower steel pipe 70, the steel rod 34, the concrete V filled in the lower steel pipe 70 (hollow part) and hardened, and the steel rod 32 in this order through the PHC pile 14 The PHC pile 14 can be resisted to the vertical load and the pulling load which are transmitted to the pile head 24 of the above and act on the joint 18 from the pillar 26 and the foundation beams 16A and 16B. Further, the stress due to the horizontal load acting on the joint portion 18 from the pillar 26 and the foundation beams 16A and 16B is transmitted to the pile head portion 24 of the PHC pile 14 through the footing 66, and the pillar 26 and the foundation beams 16A and 16B The PHC pile 14 can be resisted against the horizontal load acting on the joint portion 18.

Further, the depth H1 of the lower steel pipe 70 with respect to the upper surface of the ground 12 is large, whereby the vertical length of the lower steel pipe 70 can be increased, and the inner peripheral surface of the lower steel pipe 70 has many Since a number of steel rods 34 are attached, the stress can be efficiently transmitted between the lower steel pipe 70 and the concrete V filled in the inside (hollow portion) of the lower steel pipe 70 and hardened. Therefore, the PHC pile 14 can be effectively resisted against the pulling load acting from the pillar 26 and the foundation beams 16A and 16B to the joint portion 18.

Further, in the foundation structure 64 according to the third embodiment, as shown in FIG. 5, the hollow member 68 is installed so as to surround the pile head 24 of the PHC pile 14, and inside the hollow member 68 (hollow portion). Since the foundation structure 64 can be constructed by filling the concrete V, it is possible to reduce the construction labor of the foundation structure 64 in the field.

The basic structure according to the third embodiment of the present invention has been described above.

In addition, in the third embodiment, as shown in FIG. 5, an example in which the depth H1 of the lower steel pipe 70 with respect to the upper surface of the ground 12 is increased is shown. May be smaller or larger than the rooting depth H1.

For example, as in the basic structure 76 shown in the front sectional view of FIG. 6, the rooting depth H2 of the lower steel pipe 70 with respect to the upper surface of the ground 12 may be smaller than the rooting depth H1.

The base structure 76 has a shorter length in the vertical direction of the lower steel pipe 70 than the base structure 64, and accordingly, the number of the steel rods 34 as the stress transmitting means functioning as a shear cotter is small. .. Further, a core reinforcing bar 48 is provided from the pile head portion 24 of the PHC pile 14 to the joint portion 18.

In the foundation structure 76, the stress due to the pulling load acting on the joint portion 18 is transmitted to the PHC pile 14 via the precast concrete upper tubular body 72, the lower steel pipe 70, and the core rebar 48, whereby the joint portion 18 is formed. The PHC pile 14 can be made resistant to the pulling load that acts on the. That is, the core rebar 48 imparts a resistance force against a pulling load, which is insufficient because the number of the steel rods 34 functioning as the shear cotter decreases.

Further, in the foundation structure 76, since the rooting depth H2 of the lower steel pipe 70 with respect to the upper surface of the ground 12 is small, it is possible to reduce the time and labor required for excavating the ground 12 and carrying excavated soil.

In the basic structure 76, the steel rod 34 may be omitted if the pulling load acting on the joint portion 18 can be sufficiently borne by the core rebar 48. Further, in the foundation structure 76, when the PHC pile 14 is designed not to bear the pulling load, the core reinforcing bar 48 may be omitted.

In addition, in the third embodiment, an example in which the hollow member 68 in which the lower steel pipe 70 and the precast concrete upper tubular body 72 are integrated is installed in the construction of the foundation structure 76 is shown. After the lower steel pipe 70 and the precast concrete upper cylinder 72 are separately installed, as in the basic structure 78 shown in FIG. 1, the inside of the lower steel pipe 70 (hollow part) and the inside of the precast concrete upper cylinder 72 (hollow part) ) And concrete V may be filled and hardened to form a stress transmission pipe 80 in which the lower steel pipe 70 and the precast concrete upper cylinder 72 are integrated. In this way, the lower steel pipe 70 and the precast concrete upper cylinder 72, which are lighter than the hollow member 68, can be separately conveyed, so that the conveying performance can be improved.

The first to third embodiments of the present invention have been described above.

In the first to third embodiments, as shown in FIGS. 1 to 7, the steel pipe 22, the precast concrete tubular body 58, and the precast concrete upper tubular body 72 are connected to the precast via the joints 28A and 28B. Although an example in which the concrete foundation beams 16A and 16B are joined is shown, a cutout portion is formed in the steel pipe 22, the precast concrete cylinder 58, and the precast concrete upper cylinder body 72, and the precast concrete is formed in this cutout portion. The end portions of the base beams 16A, 16B made of steel are inserted into the steel pipe 22, the precast concrete tubular body 58, and the precast concrete upper tubular body 72, so that You may make it join an edge part.

For example, as in the front sectional view of FIG. 8 and the basic structure 82 shown in FIG. 9 which is an AA sectional view of FIG. A notch portion 86 is formed, and the ends of the precast concrete foundation beams 16A and 16B are inserted into the notch portion 86, and inside the steel pipe 84, the end portions of the foundation beams 16A and 16B are connected to the joint portion 18. You may make it join.

The ends of the foundation beams 16A and 16B are provided on the foundation beams 16A and 16B and protrude from the end faces of the foundation beams 16A and 16B, and the ends of the main bar 90 provided with the mechanical fixing tool 88 at the ends and the floor slab 30. By embedding the end portion of the main bar 92 provided with the mechanical fixing tool 88 at the end portion in the fiber reinforced concrete W that is filled and hardened in the inside (hollow portion) of the steel pipe 84, the joint portion 18 is provided. It is joined. The mechanical fixing tool 88 may not be provided at the ends of the main bars 90 and 92, and the ends of the main bars 90 and 92 may be connected by a mechanical joint. In this case, the inside (hollow portion) of the steel pipe 84 is filled with ordinary concrete (concrete V) and hardened. The arrangement pitch of a plurality of shear reinforcing bars embedded in the foundation beams 16A and 16B so as to surround the main bars 90 and 92 is the same as that of the foundation structures 10, 54 and 64 of the first to third embodiments.

The edge portion of the cutout portion 86 is joined to the fixed plate 94 embedded in the foundation beams 16A and 16B by welding. The edge of the cutout portion 86 may be joined to the fixing plate 94 with a bolt. Further, in the circumferential direction of the inner peripheral surface of the steel pipe 84 located at the joint portion 18, a plurality of steel rods functioning as shea cotters are attached in the vertical direction (not shown).

In addition, in the first to third embodiments, as shown in FIGS. 1 to 7, an example in which the joint portion 18 supports the column 26 is shown, but the steel pipe 22, the precast concrete cylinder 58, and the precast. A pillar may be directly connected to the concrete upper tubular body 72 to support the pillar.

For example, as in a basic structure 96 shown in the front sectional view of FIG. 10, a hollow member 102 as a stress transmission pipe is joined to a cylindrical steel pipe 98 and an upper end portion of the steel pipe 98, and the diameter is reduced upward. It may be configured to have the cylindrical connected steel pipe 100 and the lower end portion of the column 104 is joined to the upper end portion of the connected steel pipe 100 so that the joint portion 18 supports the column 104.

Furthermore, in the first to third embodiments, as shown in FIGS. 1 to 7, an example in which the filler that fills the inside (hollow part) of the steel pipe 22, the precast concrete cylinder 58, and the hollow member 68 is concrete V is used. However, the filler may be a cement-based solidifying material such as mortar as long as it can configure the joint portion 18 that can reliably transmit the stress after being hardened.

Moreover, in the 1st-3rd embodiment, as shown in FIGS. 1-7, although the example which made the pile the PHC pile 14 was shown, the pile is steel pile, concrete pile, ready-made pile, cast-in-place pile, etc. The pile may have any structure.

Further, in the first to third embodiments, as shown in FIGS. 1 to 7, the column 26 is made of reinforced concrete and the foundation beams 16A and 16B are made of precast concrete. However, the column 26 and the foundation beam 16A are shown. , 16B may be made of full precast concrete, may be formed of cast-in-place concrete, or may have any structure. For example, it may be a reinforced concrete structure, a steel frame structure, a steel frame reinforced concrete structure, a CFT structure (Concrete-Filled Steel Tube), a precast concrete structure, or a mixed structure thereof.

For example, as shown in the front sectional view of FIG. 11, a basic structure 106 in which steel-framed foundation beams 108A and 108B are joined to the side surface of a steel pipe 22 as a stress transmission pipe may be used. The joint portion 18 configured by filling the steel pipe 22 with concrete V supports the pillar 110.

Although the first to third embodiments of the present invention have been described above, the present invention is not limited to these embodiments, and the first to third embodiments may be used in combination. Needless to say, the present invention can be implemented in various modes without departing from the scope of the present invention.

10, 46, 50, 54, 64, 76, 78, 82, 96, 106 Foundation 12 Ground 14 PHC pile (pile)
16A, 16B, 108A, 108B Foundation beam 18 Portion 22, 84 Steel pipe (stress transfer pipe)
24 Pile head 34 Steel rod (stress transmission means)
48, 52 Core rebar 58 Precast concrete cylinder (stress transmission pipe)
68, 102 Hollow member (stress transmission tube)
70 Lower Steel Pipe 72 Upper Precast Concrete Cylinder 80 Stress Transfer Pipe V Concrete (Filler)

Claims (5)

Piles buried in the ground,
A joint supported on the upper part of the pile,
A foundation beam joined to the joint section,
A stress transfer tube in which the lower part surrounds the pile head of the pile and the upper part is located in the joint part,
A filler filled and cured inside the stress transfer tube,
Have a,
The pile head is located below the joint,
Foundation structure. A column is supported on the upper portion of the connection section,
Wherein the stress within transfer tube, column main bars protruding from said post downwards, and reinforcing bar cage surrounding the pile head is provided,
The basic structure according to claim 1. The stress transfer tube is formed by a steel pipe, the inner peripheral surface of the steel tube surrounding the pile head, and the outer peripheral surface of the steel pipe is located in the Joint portion stress transmission means are provided, according to claim 1 Or the basic structure according to 2 . The foundation structure according to claim 1, wherein the stress transmission pipe is formed with a cutout portion into which an end portion of the foundation beam is inserted. The stress transmission pipe is formed by a precast concrete cylinder, or a lower steel pipe surrounding the pile head and a precast concrete upper cylinder that is located at the joint and is integral with the lower steel pipe, The basic structure according to Item 1 or 2.