JP6461457B2 - Pile and pile construction method - Google Patents

Description

  The present invention relates to a pile and a method for constructing the pile.

  A small pile having a diameter of 300 mm or less called a micropile is known (for example, see Patent Document 1). The micropile described in Patent Document 1 has a configuration in which a round steel pipe in which a plurality of steel pipe segments are connected in the axial direction via steel pipe joints is fixed to the ground with grout.

Japanese Patent No. 4617315

  When connecting steel pipe segments, which are cylindrical steel materials, as in the micropile described in Patent Document 1, generally, a steel pipe joint has a screw-type joint structure, but a threaded portion is formed in the steel pipe segment. Expenses are high and cost is high. Further, when the steel pipe segments are screwed together and connected, the steel pipe segments having a diameter exceeding 200 mm must be lifted and rotated, and there is a problem in workability.

  The present invention has been made in view of the above circumstances, and in constructing a pile by fixing a connecting body formed by connecting steel materials in the axial direction to the ground with grout, the cost for processing the steel materials is reduced. At the same time, it is an object to improve workability when connecting steel materials.

In order to solve the above-mentioned problem, a pile according to the present invention has a connecting body formed by connecting a plurality of steel materials, which are square steel pipes, in a material axis direction, and is ground in a cylindrical excavation hole formed in the ground. A pile that is fixed to and resists a vertical load and a pull-out load, and in the connecting portion of the connecting body , both sides of the flat plate portion extend across the flat plate portion of each side of the square steel pipe to be connected to each other. The steel plate is fixed to the flat plate portion by a plurality of bolts arranged in a row in the longitudinal direction at the center portion in a plan view on each side of each square steel pipe side. They are connected to each other.

In the pile, the drilling diameter A of the excavation hole and the side length B of the square steel pipe may be in a relationship of A / B = 1.5 to 2.0.

Moreover, the construction method of the pile which concerns on this invention fixes the connection body formed by connecting the some steel materials which are square steel pipes to the ground with the grout in the cylindrical excavation hole formed in the ground. By constructing a pile that resists vertical load and pull-out load, an attachment plate is arranged on both sides of the flat plate portion so as to straddle the flat plate portion of each side of the square steel pipes connected to each other. The steel plates are connected to each other by fixing the attachment plate to the flat plate portion with a plurality of bolts arranged in a row in the vertical direction at the center portion in a plan view on each side of each square steel pipe side. Features.

  According to the present invention, in constructing a pile by fixing a connecting body formed by connecting steel materials in the axial direction to the ground with a grout, the cost for processing the steel materials is reduced and the steel materials are connected to each other. Workability can be improved.

It is an elevation view which shows the pile which concerns on one Embodiment. It is an elevation sectional view showing a joint part of a square steel pipe. It is a plane sectional view showing a joint part of a square steel pipe. It is a plane sectional view of the bottom of a pile. (A)-(G) are the elevational sectional views which show the construction procedure of a pile. It is an elevation sectional view showing the construction procedure of a pile. It is an elevation sectional view showing the construction procedure of a pile. It is an elevation sectional view showing a modification of a joint part of a square steel pipe. It is a plane sectional view showing the relation between the hole diameter of a pile and the length of the side of a square steel pipe. It is a plane sectional view showing the relation between the hole diameter of a pile and the length of the side of a square steel pipe. It is an elevation sectional view showing a modification of a joint part of a square steel pipe. It is a plane sectional view showing a modification of a pile. It is a plane sectional view showing a modification of a pile. It is an elevation view which shows the example which used the pile as a diagonal support pile.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is an elevation view showing a pile 10 according to an embodiment. As shown in this figure, the pile 10 includes a square steel pipe 20 in which a plurality of steel pipe segments 22 are connected in the axial direction, a grout 12 filled between the square steel pipe 20 and the ground, and a square type. And a head fixing portion 14 provided at the head of the steel pipe 20. The square steel pipe 20 is fixed to the ground 1 with a grout 12. The head of the square steel pipe 20 is embedded in the foundation 3 of the building 2 and is fixed to the foundation 3 by the head fixing unit 14. Furthermore, the upper and lower steel pipe segments 22 of the square steel pipe 20 are connected by a joint portion 21. This pile 10 is a vertical support pile that extends vertically from the foundation 3 of the building 2 to the support layer 5 beyond the soft layer 4 and resists the vertical load and pull-out load due to its own weight, earthquake, wind, It also resists bending loads.

  FIG. 2 is a vertical sectional view showing the joint portion 21 of the square steel pipe 20, and FIG. 3 is a plan sectional view showing the joint portion 21. As shown in these drawings, in the joint portion 21, the lower end of the upper steel pipe segment 22 and the upper end of the lower steel pipe segment 22 have the same cross-sectional shape and cross-sectional dimensions, and they are abutted in the axial direction. . Further, in the joint portion 21, a vertically long rectangular plate 24, 25 for each side of the steel pipe segment 22, and a plurality of bolts 26 and nuts 27 for fastening the plates 24, 25 to each side of the steel pipe segment 22. I have.

  The plate 24 is arranged inside the steel pipe segment 22 and the plate 25 is arranged outside the steel pipe segment 22 so as to straddle the upper and lower steel pipe segments 22, and the sides of the upper and lower steel pipe segments 22 are sandwiched between the plates 24 and 25. It is. A plurality of bolt holes 24A are formed vertically (in the longitudinal direction) in the inner plate 24, and a plurality of bolt holes 25A are formed vertically (in the longitudinal direction) in the outer plate 25. Further, a nut 27 is welded to the inner plate 24 for each bolt hole 25A. A plurality of bolt holes 22A are formed vertically (in the axial direction) at the upper and lower portions of each side of the steel pipe segment 22.

  The bolts 26 are threaded into the nuts 27 through the bolt holes 25A, 22A, 24A from the outside of the steel pipe segment 22, and the lower portions of the plates 24, 25 are lowered by the plurality of lower bolts 26 and nuts 27. Fastened to the upper part of each side of the steel pipe segment 22 on the side, and the upper parts of the plates 24, 25 are fastened to the lower part of each side of the upper steel pipe segment 22 by a plurality of bolts 26 and nuts 27 on the upper side. Thereby, each side of the upper and lower steel pipe segments 22 is connected to the plates 24 and 25 by the plurality of bolts 26 and nuts 27.

  FIG. 4 is a plan sectional view of the bottom of the pile 10. As shown in FIG. 1 and FIG. 1, the square steel pipe 20 extends to the bottom of the pile 10, and a plurality of adhesion reinforcing materials 28 for reinforcing adhesion to the grout 12 are provided on the outer wall of the bottom. Yes. The adhesion reinforcing material 28 is a member that protrudes from the outer wall surface of the square steel pipe 20, and is formed, for example, by welding a steel angle, L-shaped steel, or the like to the outer wall surface of the steel pipe segment 22.

  5 to 7 are elevational sectional views showing the construction procedure of the pile 10. First, as shown in FIGS. 5A and 5B, casing drilling is performed. In this step, a double pipe excavation type rotary percussion type drilling machine is used to drill a hole while adding a casing segment 52 to the head of the casing 50. After completion of the drilling, the drilling rod 54 is pulled out from the hole, while the casing 50 remains in the hole. Here, the casing 50 is a holed steel pipe having a cylindrical shape with an outer diameter of 245 mm and an inner diameter of 220.4 mm, and a bit provided at the tip.

  Next, as shown in FIGS. 5C and 5D, the square steel pipe 20 is inserted into the hole. In this step, the square steel pipe 20 is inserted so as to reach the bottom of the hole while adding a steel pipe segment 22 to the head thereof. As shown in FIG. 5C, the steel pipe segment 22 is connected to the head of the square steel pipe 20 with the head of the square steel pipe 20 held on the ground and the steel pipe segment 22 suspended above the head. .

  Here, the steel pipe segment 22 is carried into the site in a state where the plates 24 and 25 are fixed to one end in the axial direction by bolts 26 and nuts 27. Then, as shown in FIGS. 6 and 7, the steel pipe segment 22 is built with one axial end to which the plates 24 and 25 are fixed facing upward and the other axial end facing downward. At this time, the lower ends of the sides of the steel pipe segment 22 are inserted between the plates 24 and 25 at the heads of the sides of the square steel pipe 20. Then, the bolt 26 is threaded into the nut 27 through the bolt holes 25A, 22A, 24A from the outside of the upper steel pipe segment, and the bolt 26 and the nut 27 are used to connect the upper portions of the plates 24, 25 and the sides of the steel pipe segment 22 to each other. Tighten the bottom edge.

  Next, as shown in FIG. 5E, the casing 50 is pulled up to pull out one or a plurality of casing segments 52 from the hole, and the pulled out casing segment 52 is removed from the head of the casing 50. In this state, a hole wall in a predetermined range is exposed from the hole bottom. Next, as shown in FIG. 5 (F), grout is injected under pressure into the range where the hole wall is exposed. Finally, all the casing segments 52 are pulled out from the hole, and in this state, the grout 12 is pressure-injected to the upper end in the hole. Then, the square steel pipe 20 is filled with grout to complete the construction of the pile 10 (see FIG. 5G).

  FIG. 8 is an elevational sectional view showing a joint part 121 which is a modification of the joint part 21 of the square steel pipe 20. As shown in this figure, in the joint portion 121, the lower end of the upper steel pipe segment 22 and the upper end of the lower steel pipe segment 22 have the same cross-sectional shape and cross-sectional dimensions, and these are abutted in the axial direction. The joint portion 121 includes a square tube-shaped steel pipe 124 and a plurality of bolts 26 and nuts 27 that fasten the steel pipe 124 to each side of the upper steel pipe segment 22.

  The steel pipe 124 is arranged inside the steel pipe segment 22 so as to straddle the upper and lower steel pipe segments 22, and is welded to the upper end of the inner wall of the lower steel pipe segment 22. A plurality of bolt holes 124A are formed vertically (in the longitudinal direction) in the upper half range of the steel pipe 124, and the nut 27 is welded to each inner side surface of the steel pipe 124 for each bolt hole 124A. A plurality of bolt holes 22 </ b> A are formed vertically (in the axial direction) at the lower part of each side of the steel pipe segment 22.

  The bolt 26 is passed through the bolt holes 22A and 124A from the outside of the steel pipe segment 22 and screwed into the nut 27. By the plurality of bolts 26 and nuts 27, the upper side of the steel pipe 124 and the upper steel pipe segment are connected. The lower part of each side of 22 is fastened. Thereby, each side of the upper and lower steel pipe segments 22 is connected by the steel pipe 124 and the plurality of bolts 26 and nuts 27.

  FIG. 9 is a plan sectional view showing the relationship between the drilling hole diameter A of the pile 10 and the side length B of the square steel pipe 20, and FIG. 10 shows the relationship between the drilling diameter A of the pile 100 and the side of the square steel pipe 20. It is a plane sectional view showing the relationship with the length B. As shown in these drawings, the drilling hole diameter A is 245 mm for both the piles 10 and 100, and the inner diameter C of the casing 50 is 220.4 mm for both the piles 10 and 100. On the other hand, the length B of the side of the square steel pipe 20 is 125 mm for the pile 10 and 150 mm for the pile 100, and the length D from the head of one bolt 26 on the opposite side to the head of the other bolt 26 is D. Is 181 mm for both piles 10 and 100. Moreover, the thickness of the square steel pipe 20 of the pile 10 is 12 mm, and the thickness of the plates 24 and 25 is also 12 mm. Further, the bolt 26 is a 12-M20 high-strength bolt, and the length of the bolt 26 under the neck is 70 mm.

  Here, in both piles 10 and 100, there is a gap between the head of the bolt 26 and the inner wall of the casing 50, and sufficient to fill the grout between the hole wall and the head of the bolt 26. A gap is created. Therefore, if the plate 25 is provided outside the square steel pipe 20 as in the pile 10, the side length B of the square steel pipe 20 can be set as wide as about 125 mm, and the square steel pipe as in the pile 100. If the plate 25 is not provided on the outer side, the side length B of the square steel pipe 20 can be set as wide as about 150 mm.

  When the side length B of the square steel pipe 20 in the pile 10 is set to 125 mm, the hole diameter A and the side length B of the square steel pipe 20 have a relationship of A / B = 1.96. Moreover, when the side length B of the square steel pipe 20 is set to 150 mm in the pile 100, the hole diameter A and the side length B of the square steel pipe 20 have a relationship of A / B = 1.63. .

  Furthermore, in the pile 10, when the relationship between the drilling hole diameter A and the side length B of the square steel pipe 20 is A / B = 2.0, the side length B of the square steel pipe 20 is 122. The length D from the head of one bolt 26 on the opposite side to the head of the other bolt 26 is 178.5 mm. Even in this case, a sufficient gap for filling the grout between the hole wall and the head of the bolt 26 can be secured. On the other hand, in the pile 100, when the relationship between the drilling hole diameter A and the side length B of the square steel pipe 20 is A / B = 1.5, the side length B of the square steel pipe 20 is 163. The length D from the head of one bolt 26 on the opposite side to the head of the other bolt 26 is 194.3 mm. Even in this case, a sufficient gap for filling the grout between the hole wall and the head of the bolt 26 can be secured. That is, depending on whether or not the plate 25 is provided outside the square steel pipe 20, the relationship between the drilling diameter A and the side length B of the square steel pipe 20 varies as A / B = 1.5 to 2.0. To do.

  As described above, the pile 10 according to this embodiment has a configuration in which a square steel pipe 20 in which a plurality of steel pipe segments 22 are connected in the material axis direction is fixed to the ground 1 with a grout 12, and the square steel pipe In the 20 joint portions 21, the sides of the steel pipe segments 22 are connected to each other by using bolts 26 regardless of the screw-type joint structure. As a result, it is not necessary to form a threaded portion in the steel pipe segment 22, the processing cost can be reduced, and the cost of the steel pipe segment 22 can be reduced. In addition, the steel pipe segments 22 can be connected by a simple operation of tightening the bolts 26 on the respective sides of the upper and lower steel pipe segments 22, and the steel pipe segments 22 are lifted and rotated as in the case of connecting with screw type joints. Large work can be eliminated and workability can be improved.

  Moreover, in the pile 10 which concerns on this embodiment, in the joint part 21 of the square steel pipe 20, the plates 24 and 25 are distribute | arranged so that each upper and lower sides may be straddled, and this plate 24 and 25 is each upper and lower sides with the volt | bolt 26. The upper and lower sides are connected to each other. Here, when a splicing plate is used for connecting round steel pipes, the splicing plate must be bent in accordance with the curvature of the steel pipe, and it is difficult to ensure the accuracy. On the other hand, in this embodiment, by using the square steel pipe 20 having the flat plate portions (each side) extending in the material axis direction, the plates 24 and 25 which are flat plates are not in the square steel pipe 20 with no gap. It is possible to easily achieve contact and tighten with the bolt 26 and the nut 27.

  In addition, when connecting round or square steel pipe cements by tightening the flanges projecting outward in the direction of the material axis with bolts, the round or square length is equal to or longer than the bolt head diameter. The joint will overhang the outside of the mold steel pipe. On the other hand, in this embodiment, the length that goes out from the square steel pipe 20 is only the thickness of the plate 25 and the height of the head of the bolt 26, and is shorter than the former. Thereby, according to this embodiment, compared with the former, the head of bolt 26 becomes easy to fit in casing 50, and the length B of the side of square steel pipe 20 can be set up large. Therefore, by making the cross section of the square steel pipe 20 large, it is possible to improve the proof strength of the pile 10 against the vertical load and pull-out load due to the building 2 weight, earthquake, wind, and bending load.

  Furthermore, in this embodiment, when the head of the bolt 26 exhibits a node effect, the adhesion between the square steel pipe 20 and the grout 12 is enhanced, and the stress transmission performance of the pile 10 is enhanced. Here, in this embodiment, the joint part 21 can be increased by reducing the cost of the joint part 21 and the labor of construction, and thereby the stress transmission performance of the pile 10 can be improved.

  FIG. 11 is an elevational sectional view showing a joint part 221 which is a modification of the joint part 21 of the square steel pipe 20. As shown in this figure, in the joint portion 221, a small-diameter portion 224 having a rectangular tube shape protrudes from the head portion of the lower steel pipe segment 22. Each side of the small-diameter portion 224 is shorter than each side of the steel pipe segment 22 by the thickness, and the small-diameter portion 224 is inserted into the lower portion of the upper steel pipe segment 22.

  A plurality of bolt holes 224A are formed vertically (in the longitudinal direction) in the small diameter portion 224, and a nut 27 is welded to each bolt hole 124A. A plurality of bolt holes 22 </ b> A are formed vertically (in the axial direction) at the lower part of each side of the steel pipe segment 22.

  The bolts 26 are threaded into the nuts 27 through the bolt holes 22A and 224A from the outside of the steel pipe segment 22, and the upper portions of the small diameter portions 224 are connected to the upper steel pipe segments 22 by the plurality of bolts 26 and nuts 27. Fastened to the bottom of the side. Thereby, each side of the upper and lower steel pipe segments 22 is connected by the small diameter portion 224, the plurality of bolts 26, and the nuts 27.

  FIG. 12 is a plan sectional view showing a pile 300 which is a modified example of the pile 10. As shown in this figure, in the pile 300, a connecting body 320 formed by connecting steel segments 322 having a cross-shaped cross section in the material axis direction is fixed to the ground with the grout 12. In the joint portion 321 of the coupling body 320, plates 24 and 25, bolts 26, and nuts 27 are provided for each flat plate portion 322A of the steel material segment 322. The plates 24 and 25 are provided so as to straddle the upper and lower flat plate portions 322A and sandwich the upper and lower flat plate portions 322A, and the upper and lower flat plate portions 322A and the plates 24 and 25 are fastened by bolts 26 and nuts 27. Thereby, the flat plate portions 322A of the upper and lower steel material segments 322 are connected.

  FIG. 13 is a plan sectional view showing a pile 400 which is a modification of the pile 10. As shown in this figure, in the pile 400, a connecting body 420 formed by connecting steel material segments 422 having an H-shaped cross section in the material axis direction is fixed to the ground with the grout 12. In the joint portion 421 of the connecting body 420, the plates 24 and 25, the bolt 26, and the nut 27 are provided for each flat plate portion 422A of the steel material segment 422. The plates 24 and 25 are provided so as to straddle the upper and lower flat plate portions 422A and sandwich the upper and lower flat plate portions 422A, and the upper and lower flat plate portions 422A and the plates 24 and 25 are fastened by bolts 26 and nuts 27. Thereby, the flat plate portions 422A of the upper and lower steel material segments 422 are connected.

  FIG. 14 is an elevation view showing an example in which the pile 10 is used as an oblique support pile. As shown in this figure, in this embodiment, there are a plurality of piles 10 inclined downward from the foundation 3 to the left side in the figure and a plurality of piles 10 inclined downward from the foundation 3 to the right side in the figure. Built on ground 1. The plurality of piles 10 resists horizontal loads mainly caused by earthquakes and winds. It also resists vertical loads, pulling forces and bending loads.

  In addition, the above-mentioned embodiment is for making an understanding of this invention easy, and does not limit this invention. It goes without saying that the present invention can be changed and improved without departing from the gist thereof, and that the present invention includes equivalents thereof. For example, in the above-described embodiment, the bolt 26 is horizontally (perpendicular to the direction of the material axis), but when there is room in the space between the steel material segment and the casing, the bolt 26 is vertically (material) (Parallel to the axial direction).

  Moreover, although the pile 10 was constructed | assembled to the support layer 5 in the above-mentioned embodiment, this is not essential. For example, the soft layer 4 may be constructed so as to function as a friction pile.

1 ground, 2 buildings, 3 foundations, 4 soft layers, 5 support layers, 10 piles, 12 grouts, 14 head fixing parts, 20 square steel pipes, 21 joint parts, 22 steel pipe segments, 22A bolt holes, 24 plates, 24A Bolt hole, 25 plate, 25A Bolt hole, 26 bolt, 27 Nut, 28 Adhesive reinforcement, 50 Casing, 52 Casing segment, 54 Drilling rod, 100 Pile, 121 Joint part, 124 Steel pipe, 124A Bolt hole, 221 Joint part 224 Small diameter part, 224A Bolt hole, 300 pile, 320 connection body, 321 joint part, 322 steel segment, 322A flat plate part, 400 pile, 420 connection body, 421 joint part, 422 steel material segment, 422A flat plate part

Claims (3)

A connecting body formed by connecting a plurality of steel materials that are square steel pipes in the axial direction is fixed to the ground with grout in a cylindrical excavation hole formed in the ground, and resists vertical load and pull-out load. A pile,
In the connecting portion of the connecting body, an attachment plate is arranged on both surfaces of the flat plate portion so as to straddle the flat plate portion of each side of the square steel pipe to be connected to each other, and the attachment plate is arranged on each square steel tube side. In the side, the steel materials are connected to each other by being fixed to the flat plate portion by a plurality of bolts arranged in a row in a longitudinal direction in a central portion in a plan view. The pile according to claim 1, wherein the drilling hole diameter A of the excavation hole and the side length B of the square steel pipe are in a relationship of A / B = 1.5 to 2.0. Resistant to vertical load and pull-out load by fixing a connecting body made of a plurality of square steel pipes connected in the axial direction to the ground with a grout in a cylindrical excavation hole formed in the ground. A method of building a pile to
A splicing plate is arranged on both sides of the flat plate portion so as to straddle the flat plate portion of each side of the square steel pipes connected to each other, and the splicing plate is a central portion in plan view on each side of each square steel pipe A method for constructing a pile, characterized in that the steel materials are connected to each other by being fixed to the flat plate portion by a plurality of bolts arranged in a row in a vertical direction.

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