JP5576954B1 - Spiral pile and its storage method - Google Patents

Abstract

A spiral pile that can be efficiently stacked and stored in a large amount is provided.
A spiral pile 1 is a pile embedded in a ground A by screwing a tip portion. The spiral pile 1 includes a hollow tube 2 that extends in the axial direction, and a screw blade 3 that is fixed to the distal end portion 2e of the hollow tube 2 in a substantially spiral shape. The screw blade 3 is formed with a notch 31 penetrating from the axial direction of the hollow tube 2 so as to open to the outer peripheral surface 3a. When the screw blade 3 is viewed from the axial direction of the hollow tube 2, the notch 31 has one circumferential end surface 31 a formed in the hollow tube 2 side direction from the outer end 3 c of the screw blade 3, and It is formed in a groove shape by the other circumferential end face 31b formed in the direction from the outer end 3d of the screw blade 3 toward the hollow tube 2 side.
[Selection] Figure 3

Description

  The present invention relates to a spiral pile installed in a state of being screwed into the ground in order to support a structure column and the like, and a method for storing the spiral pile.

  Conventionally, when a structure is provided on soft ground, a screwed spiral pile (also called “screw pile” or “screwed steel pipe pile”) is screwed into the ground to reinforce the ground. And the structure is installed on the spiral pile (for example, refer patent document 1).

FIGS. 16A and 16B are views showing a state when a conventional spiral pile is stacked, in which FIG. 16A is a front view of a main part, and FIG. 16B is a left side view.
As shown in FIGS. 16A and 16B, a general spiral pile 100 as disclosed in Patent Document 1 includes a metal hollow tube 200 with a sharp lower end, And a helical screw blade 300 welded to the outer periphery. Since the spiral pile 100 having the screw blades 300 is used in a large amount, when it is stored in a warehouse or transported by a container, in order to effectively use the storage space, FIG. 16 (a), (b) As shown in Fig. 4, the sheets are stored together in a stacked state.

For example, when storing horizontally, the outer peripheral surface of the screw blade 302 of the upper spiral pile 102 is placed on the hollow tube 201 of the lower spiral pile 101. That is, when the interval between the spiral piles 100 is L100, the outer diameter of the hollow tube 200 is D100, the radius of the hollow tube 200 is R100, and the radial length of the screw blade 300 is S100,
L100 = R100 × 2 + S100
And
L100 = D100 + S100
It becomes.

  As described above, in the spiral pile 100, when the radial length S100 of the screw blade 300 and the outer diameter D100 of the hollow tube 200 are large, the interval L100 between the spiral piles 100 is increased in proportion to the size. Become.

JP-A-11-200377

  As described above, when the conventional spiral pile 100 is stored in a warehouse or transported by a ship, a trailer, or the like, as shown in FIGS. Since it is stored in the box, the screw blade 300 is bulky to a certain extent, and thus there is a problem that it cannot be stored efficiently.

  Therefore, the spiral piles 100 can be efficiently stacked in a predetermined storage space and stored in large quantities, or a large number of spiral piles 100 can be efficiently stored and transported in a predetermined size container or spiral pile storage box. There was a need for a spiral pile that could be used.

  Further, when the spiral piles 100 are stacked, for example, the piles are loaded in a state in which the outer peripheral surface of the circular screw blade 300 and the outer peripheral surface of the cylindrical hollow tube 200 are in contact with each other, so that the stable state is achieved. There was a problem that they could not be stacked and easily collapsed.

  Then, this invention was created in order to solve the said subject, and it aims at providing the spiral pile which can be piled up efficiently and stored in large quantities, and its storage method.

The spiral pile according to the present invention is a spiral pile that is embedded in the ground by screwing the tip portion into the ground, and is fixed to the tip portion of the hollow tube in a spiral manner extending in the axial direction. A screw blade, and a flange welded to a proximal end portion of the hollow tube, and the screw blade has a V-shaped notch portion penetrating from the axial direction of the hollow tube on the outer peripheral surface. The flange has a recess formed on the outer periphery, and the recess is disposed at a position in phase with the notch when viewed from the axial direction of the hollow tube. The spiral pipe is formed in a groove having a width larger than the outer diameter of the hollow tube, and is cut into a size that allows the hollow tube of another spiral pile of the same shape to be inserted. When piles are stacked, the hollow pipe of the other spiral pile And supported by being engaged with and supported by the notch and the recess respectively, and the outer peripheral surface of the hollow pipe of the other spiral pile is in contact with the V-shaped inclined surface of the notch It is characterized by being.

According to such a configuration, the spiral pile is formed by inserting the hollow pipe of another spiral pile into the cutout portion of the screw blade arranged horizontally, and stacking the other spiral spiral from the outer periphery of the screw blade into the cutout portion. As the hollow tube of the pile is sunk and engaged, the space between the piles and the other spiral piles is narrowed, and the screw blades can be arranged in a compact manner while maintaining the strength of the screw blades.
For this reason, since spiral piles can be efficiently stacked at narrow intervals, it is possible to store a larger number of spiral piles than in the past in a predetermined space or to store and transport them in a spiral pile storage box or the like. it can.
Moreover, since each pile piled up is piled up with the hollow pipe of the other spiral engaged with the notch of each screw blade, each pile pile can be piled up in a stable state without rattling. .
Further, according to such a configuration, the spiral pile is different from the spiral pile because the concave portion of the flange is disposed at the same phase as the notch portion with respect to the outer peripheral surface of the hollow tube as viewed from the axial direction. When the spiral piles are stacked, the hollow pipes of the other spiral piles are engaged with the notches on the distal end side and the recesses on the proximal end side of the spiral piles and are supported in a parallel state. Each spiral pile can be piled up in a stable state without collapsing. In addition, since the spiral pile can be arranged in a state close to the axial direction by engaging the hollow tube of the other spiral pile with the notch and the recess, it is more than the width of the screw blade. Many spiral piles can be loaded in a well-balanced manner in a predetermined space by stacking at a narrow interval.

Further, the notch is formed in a groove shape cut from the outer peripheral surface of the screw blade when the screw blade is viewed from the axial direction of the hollow tube, and the screw blade from the inner bottom of the notch. It is preferable that the slit part is formed over the inner periphery .

According to such a configuration, the notch portion of the spiral pile is formed in a groove shape cut from the outer peripheral surface of the screw blade when viewed from the axial direction, so that the screw blade is formed in a spiral shape in the axial direction. Even if it is made, when the hollow tube of the other spiral pile of the same shape is engaged with the groove | channel of the screw blade | wing, another spiral pile can be hold | maintained firmly.
Further, the screw blade can be formed in a spiral shape by forming a slit portion from the inner bottom portion of the notch portion to the inner peripheral edge of the screw blade.

Moreover, it is preferable that the structure of a solar panel is mounted on the said flange .

According to this structure, the spiral pile can mount the structure of a solar panel on a flange.

The spiral pile storage method according to the present invention is a spiral pile storage method for storing a spiral pile in a warehouse, a container, or a spiral pile storage box, wherein the spiral pile includes the cutout portion and the spiral pile. The concave portion is housed in a state in which the hollow pipe of the other spiral pile is engaged.

According to such a configuration, when the spiral pile is stored in a warehouse, a container, or a spiral pile storage box, the spiral pile is in a state where the hollow pipe of another spiral pile is engaged with the notch. By storing, each spiral pile is efficiently stacked at an interval narrower than the width of the screw blades, and each spiral pile is held in a stable state that does not collapse, stored and stored, Or can be transported.

  Moreover, it is preferable that the spiral pile is bundled by a bundling member in a state where the hollow pipe of the other spiral pile is engaged with the notch.

  According to this configuration, the spiral pile is bundled with the other spiral piles by the binding member, so that when the operator carries the spiral pile, the spiral pile can be carried by hand with a plurality of spiral piles at a time. Therefore, the workability of the carrying work can be improved. Further, since the plurality of spiral piles bound by the binding member do not rattle each other, they are easy to carry and can be stacked so as not to collapse even when stacked.

  In addition, the spiral pile and the other spiral pile are stored in a spiral pile storage box by stacking them in different directions in a state where the hollow tube and the cutout portion are engaged with each other. In the spiral pile storage box, it is preferable that orthogonal spiral piles arranged in a direction orthogonal to the spiral pile and the other spiral piles are stored.

  According to this configuration, the spiral pile and other spiral piles are stacked in a state where the hollow tube and the notch are engaged with each other, and are stored in the spiral pile storage box, so that a large amount of spiral piles are stored in the spiral pile. It can be stored in a storage box. By storing orthogonal spiral piles in the spiral pile storage box, more spiral piles can be stored, and the transport efficiency can be improved.

  The present invention can provide a spiral pile that can be efficiently stacked and stored in a large amount and a storage method thereof.

It is an expanded side view of the mount frame which shows the installation state of the spiral pile which concerns on embodiment of this invention. It is a front view of the mount frame which shows the installation state of the spiral pile which concerns on embodiment of this invention. It is an expansion perspective view which shows an example of the spiral pile which concerns on embodiment of this invention. It is a figure which shows the installation state of a screw blade | wing, (a) is an enlarged plan view, (b) is an enlarged side view. It is a figure which shows the installation state of a flange, (a) is an enlarged plan view, (b) is a principal part expansion center longitudinal cross-sectional view. It is a figure which shows the installation state of a blade board, (a) is a principal part expansion center longitudinal cross-sectional view, (b) is a principal part expansion side view. It is a front view which shows a state when four spiral piles are bound with a binding member. It is a figure which shows a state when four spiral piles are bundled with a binding member, (a) is a side view, (b) is a top view. It is a schematic side view showing a state when a set of four spiral piles is stored in a spiral pile storage box. It is a schematic front view which shows a state when accommodating one set of four spiral piles in a spiral pile storage box. It is a schematic plan view which shows a state when a set of four spiral piles is stored in a spiral pile storage box. It is a figure which shows the 1st modification of the spiral pile which concerns on embodiment of this invention, and is a principal part expansion schematic side view which shows the arrangement | positioning state of the spiral pile placed horizontally in the spiral pile storage box. It is a figure which shows the 1st modification of the spiral pile which concerns on embodiment of this invention, and is a schematic side view which shows the arrangement | positioning state of the spiral pile placed horizontally in the spiral pile storage box. It is a figure which shows the 1st modification of the spiral pile which concerns on embodiment of this invention, and is a schematic plan view which shows the arrangement | positioning state of the spiral pile vertically installed in the spiral pile storage box. It is a perspective view which shows the 2nd modification of the spiral pile which concerns on embodiment of this invention. It is a figure which shows a state when the conventional spiral pile is piled up, (a) is a principal part front view, (b) is a left view.

Hereinafter, with reference to FIGS. 1-11, the spiral pile which concerns on embodiment of this invention, and its storage method are demonstrated.
As shown in FIG. 1, the spiral pile 1 is a screw-in type steel pipe pile that is embedded by screwing the tip portion into the ground A by a pile mounting device (not shown), and the usage is not particularly limited. The spiral pile 1 is, for example, a foundation work for supporting a stand 70 on which a solar panel 6 or the like standing on the ground A is mounted, a column 73 for supporting the stand 70, and other various structures 7 from below. It is a pile used for. That is, the object installed on the spiral pile 1 may be the structure 7 installed on the ground A. Hereinafter, an example in which the mount 70 for the solar panel 6 is installed on the ground A will be described. The embodiments of the present invention will be described. Before describing the spiral pile 1, the solar panel 6, the gantry 70, and the support column 73 will be described.

≪Solar panel configuration≫
As shown in FIG. 1, the solar panel 6 is a solar panel unit that converts solar energy into electricity to generate solar power, and is a so-called solar panel (also referred to as “solar battery”). The solar panel 6 is bolted onto the gantry 70. The solar panel 6 is disposed on the top of the pedestal 70 in a state where the light receiving surface of the rectangular thick flat panel that receives sunlight is inclined obliquely downward from one end portion to the other end portion. It arrange | positions in the state which condenses light easily. In addition, although the inclination angle of the solar panel 6 changes with areas to install, for example, it inclines and arrange | positions at the inclination angle of about 10 degree | times to the south direction. As shown in FIG. 2, a large number of solar panels 6 are arranged, for example, in a two-row formation.

≪Configuration of the base≫
As shown in FIGS. 1 and 2, the pedestal 70 and the column 73 are structures 7 that are mounted on the spiral pile 1. The gantry 70 is a metal frame that is installed under the solar panel 6 and holds the solar panel 6. The gantry 70 includes, on the solar panel 6, side frames 71 arranged in a plurality of rows in the longitudinal direction in a plan view and cross frames 72 arranged in a plurality of rows in a short direction perpendicular to the side frames 71. Along the frame, it is diagonally constructed and connected with bolts.

The side frame 71 is made of an aluminum frame extending in the longitudinal direction, is interposed between the solar panel 6 and the cross frame 72 and is bolted to both.
The cross frame 72 is made of an aluminum frame extending in the short direction, and is interposed between the side frame 71 and a mounting bracket 77 provided at the upper end of each column 73 and is bolted to both. .

≪Composition of props≫
The column 73 is a metal frame member that supports the gantry 70 from below, and is formed of, for example, an aluminum member. The support column 73 includes support column bodies 74, 75, 76, a mounting bracket 77 connected to the upper end portions of the support column main bodies 74, 75, 76, and a connecting flange connected to the lower end portions of the support column bodies 74, 75, 76. 78, 79 are connected.

The column main body 74 is a member arranged at a position near the front side in the front-rear direction below the gantry 70 and has the shortest length among the three types of column main bodies 74 to 76. The column body 74 is erected vertically on the front connecting flange 79.
The column main body 75 is a member disposed at the center in the front-rear direction below the gantry 70 and is installed on the rear connection flange 78 so as to be inclined obliquely forward.
The column main body 76 is a member disposed at a position closer to the rear side in the front-rear direction below the gantry 70, and is erected vertically on the rear connection flange 78.

The mounting bracket 77 is a member for connecting the column 73 and the gantry 70, and column bodies 74 to 76 are bolted to the lower end portion, and the cross frame 72 is bolted to the upper end portion.
The connecting flanges 78 and 79 are metal plate members for connecting the flange 4 of the spiral pile 1 and the lower end portion of the column 73.
The front connection flange 78 is made of a substantially triangular metal plate, and is bolted onto the flange 4 of the front spiral pile 1.
The rear connecting flange 79 is made of a rectangular metal plate and is bolted onto the flange 4 of the rear spiral pile 1.

≪Structure of spiral pile≫
As shown in FIG. 1, the spiral pile 1 is an anchor bolt-shaped steel pipe pile for mounting a structure 7 such as a solar panel on the flange 4, for example. When the blade 5 side of the hollow tube 2 is screwed into the ground A and installed, the spiral pile 1 is erected in a state of being exposed to the ground from about 100 mm to 300 m from the upper end.
As shown in FIG. 3, the spiral pile 1 includes a hollow tube 2 extending in the axial direction, a screw blade 3 fixed to the outer peripheral surface 2 a of the distal end portion 2 e of the hollow tube 2 in a substantially spiral shape, The flange 4 welded to the upper end 2c (base end portion 2f) of the hollow tube 2 and the blade plate 5 welded to the lower end 2b of the hollow tube 2 are joined together and galvanized. Yes. In addition, the material of the spiral pile 1 is not specifically limited.

<Configuration of hollow tube>
The hollow tube 2 is a member that forms the main body of the spiral pile 1, and is made of, for example, a cylindrical steel pipe having a hollow portion 2d. The hollow tube 2 is formed of, for example, a steel tube having an outer diameter of 48.6 mm, a thickness of 5.1 mm, and a length of 1,750.0 mm. These lengths are merely examples, and may be changed as appropriate according to the installation state and the one used.

<Configuration of screw blade>
As shown in FIG. 3, when the screw blade 3 is embedded in the ground while rotating the spiral pile 1, the screw blade 3 is easily embedded by a propulsion force based on the principle of the screw propeller, and the vertical supporting force of the embedded spiral pile 1. And in order to improve horizontal support force, it is a metal plate material welded to the outer peripheral surface 2a of the hollow tube 2. Since the spiral pile 1 includes the screw blades 3 and the blade plate 5, the spiral pile 1 can be buried in the ground by rotating the spiral pile 1. In the hollow tube 2, the screw blade 3 is installed at a position shifted in the axial direction from the flange 4.

  As shown in FIG. 4 (a), the screw blade 3 includes a notch 31 formed in a notch so as to open to the outer peripheral surface 3a of the plate formed in a ring shape in plan view, And slit portions 31d and 31e formed from the peripheral edge 3b to the inner bottom portion 31c of the cutout portion 31. In other words, the screw blade 3 is spirally formed with a notch 31 that can enter the outer peripheral surface 2a of the hollow tube 2 of another spiral pile 11 and the screw blade 3 as viewed from the axial direction of the hollow tube 2. The slits 31d and 31e are formed at the same position (phase angle).

  As shown in FIG. 4 (b), the screw blade 3 is formed by continuously forming a ring-shaped metal plate member from the inner peripheral edge 3b to the outer peripheral surface 3a with the notch 31 and the slits 31d and 31e. In addition, one circumferential end surface 31a and the other circumferential end surface 31b of the notch 31 are shifted in the axial direction by one pitch P from the outer circumferential surface 2a of the hollow tube 2 in a spiral shape (screw shape). Is formed. For this reason, the upper and lower surfaces of the screw blade 3 are formed obliquely when viewed from the side.

  The notch 31 is a groove that supports the spiral pile 2 by inserting the hollow tube 2 of the other spiral pile 11 when the spiral pile 1 is stacked with another spiral pile 11 having the same shape. When the screw blade 3 is viewed from the axial direction, the notch 31 includes one circumferential end surface 31a formed in the direction from the outer end 3c of the outer peripheral surface 3a of the screw blade 3 toward the hollow tube 2 and the screw It consists of a substantially V-shaped groove having an outer end portion 3d of the blade 3 and the other circumferential end surface 31b formed in the hollow tube 2 side direction. That is, the notch 31 is formed in a groove shape cut from the outer peripheral surface 3 a of the screw blade 3 when viewed from the axial direction.

  As shown in FIG. 4A, one circumferential end surface 31a of the notch 31 is a part that forms one inclined portion of the V-shaped notch 31 in plan view. It is formed to be inclined at an angle of θ1 (for example, 30 °) from the inner bottom 31c with respect to 31e. As shown in FIG. 4B, the one circumferential end surface 31 a is disposed so as to be the uppermost portion in the side view of the screw blade 3.

  As shown in FIG. 4A, the other circumferential end surface 31b is in relation to one circumferential end surface 31a so as to form an inclined portion on the other side of the V-shaped cutout portion 31 in plan view. It is a part arranged symmetrically. For this reason, the other circumferential end surface 31b is formed to be inclined with respect to the slit portions 31d and 31e from the inner bottom portion 31c at an angle θ1 (for example, 30 °). As shown in FIG. 4B, the other circumferential end surface 31 b is arranged in the screw blade 3 so as to be the lowest part when viewed from the side.

As shown in FIG. 4A, the inner bottom portion 31c is a portion that becomes a bottom portion of the cutout portion 31 in a plan view, and is arranged so that one circumferential end surface 31a and the other circumferential end surface 31b are in contact with each other. Has been.
The slit portions 31d and 31e are portions cut in a straight groove shape from the inner bottom portion 31c to the inner peripheral edge 3b in plan view. As shown in FIG. 4B, the one slit portion 31d is continuously formed on the one circumferential end surface 31a, and is arranged so as to be the uppermost portion in a side view in the screw blade 3. The other slit portion 31e is continuously formed on the other circumferential end surface 31a, and is disposed on the screw blade 3 so as to be the lowest portion when viewed from the side.
In the present embodiment, in the screw blade 3, the cutout portion 31 and the slit portions 31 d and 31 e are formed at the same position when viewed from the axial direction of the hollow tube 2 from the viewpoint of reducing the number of processing steps. However, the present invention is not limited to this, and the slit portion may be separately formed at a position different from the notch portion.

<Flange configuration>
As shown in FIGS. 5A and 5B, the flange 4 is a metal flat plate member on which the connecting flanges 78 and 79 (see FIG. 1) of the structure 7 are mounted. The outer end 2c is externally fitted and joined. The flange 4 will be described by taking a square shape as an example in plan view, but the shape thereof may be circular or polygonal and is not particularly limited. The flange 4 can be positioned by recesses 4a and 4b formed in the outer peripheral portion, a hollow tube installation hole 4c drilled in the center, and bolts (not shown) for fixing the coupling flanges 78 and 79 to the flange 4. And a long hole 4d to be inserted.

  The recesses 4a and 4b are a plurality of grooves formed in the center of the outer periphery of the flange 4, and are notched so as to allow the hollow pipe 2 of the other spiral pile 11 to enter. The recesses 4a and 4b are grooves each having a width larger than the outer diameter of the hollow tube 2, and are formed in an arc shape, for example. At least one of the plurality of formed recesses 4 a and 4 b is arranged such that the recess 4 a is in the same phase as the notch 31 with respect to the outer peripheral surface of the hollow tube 2 when viewed from the axial direction of the hollow tube 2. Has been.

As shown in FIG. 5B, the hollow tube installation hole 4c is inserted into the hollow tube 2 so that the weld beads B are arranged on the upper and lower peripheral edges of the hollow tube installation hole 4c. Are joined.
The long hole 4d is composed of four holes formed so that the connecting flanges 78 and 79 can be bolted to the flange 4 so that the position thereof can be adjusted.

<Configuration of blade plate>
As shown in FIGS. 6 (a) and 6 (b), the blade plate 5 is placed on the ground A (see FIG. 1) when the spiral pile 1 is put on the ground A and rotated by a pile mounting device (not shown). It is an excavating blade that excavates so as to be twisted inside, and is made of a metal plate member having a pointed thickness of about 6 mm. The blade plate 5 has a triangularly sharpened blade portion 5a for excavating the ground A, and a hollow tube fitting portion 5b formed on the base end side of the blade portion 5a.

The blade portion 5a is composed of an acute angle blade protruding in an isosceles triangle shape from the lower end 2b of the hollow tube 2.
The hollow tube inner fitting portion 5b is inserted into the lower end 2b of the hollow tube 2, and the weld bead B shown in FIGS. 6A and 6B is welded. The hollow tube inner fitting portion 5b is engaged with an attachment 90 at the tip of an arm 9 provided on a pile mounting device including a work machine such as a backhoe, and the attachment 90 is rotated by a hydraulic motor or the like. When driven, the entire spiral pile 1 is rotated together with the blade plate 5 and twisted into the ground.

≪Bundling member configuration≫
As shown in FIGS. 7 and 8A and 8B, the binding member 8 is a member for binding a plurality of (for example, four) spiral piles 1, and the shape and material thereof are not particularly limited. . The binding member 8 is made of, for example, a band member that can be attached to and detached from the spiral pile 1, a belt-like member, a tape-like member, a wire, or the like.

  The pile mounting device, the arm 9, the attachment 90, etc. may be any mechanical type or sliding type as long as the spiral pile 1 can be installed on the ground A. It does not matter.

≪Action≫
Next, with reference to FIGS. 1-11, the effect | action of the spiral pile which concerns on embodiment of this invention and its storage method is demonstrated. First, the manufacturing method of spiral pile 1 is demonstrated.
As shown in FIG. 3, when manufacturing the spiral pile 1, the flange 4 is fitted on the upper end 2 c of the hollow tube 2 and both are welded. Next, the blade plate 5 is fitted into the lower end 2b of the hollow tube 2 and both are welded. A screw blade 3 having a spiral ring is fitted to a position near the lower end 2b side of the hollow tube 2 and both are welded. By doing in this way, the spiral pile 1 shown in FIG. 3 is formed. The spiral pile 1 is completed by galvanizing.

Next, an example in the case of transporting the spiral pile 1 by a ship, a vehicle, etc. is demonstrated. In that case, first, the spiral pile 1 is stored in the spiral pile storage box 91, and the spiral pile storage box 91 is stored in one container (not shown) as a set of three boxes and transported by a ship or the like. .
The container is a so-called 20-foot container, and its dimensions, strength, and outer shape are standardized by an international standardization mechanism having outer dimensions of 6,058 mm in length, 2,438 mm in width, and 2,591 mm in height. As shown in FIGS. 9 to 11, the spiral pile storage box 91 stored in the container has, for example, a length CL1 of 2,340 mm, a width CL2 of 1,900 mm, and a height CL3 of 2,272 mm. It consists of a metal box formed in the size.

  As shown in FIGS. 7 and 8 (a) and 8 (b), before storing in the spiral pile storage box 91, four spiral piles 1, 11, 12, 13 (when referring to each spiral pile, "Spiral pile 1") are bundled in parallel and bundled by two binding members 8. In this case, for example, the two spiral piles 1 and 11 on the lower left and right sides have the notches 31LL and 31LR on the upper side, and the screw blades 3LL, 3LR, 3UL, and 3UR are the outer peripheral surfaces of the hollow tubes 2, 21, 22, and 23. 2a is arranged in a horizontal direction so as to be in contact with 2a. Next, the notch 31UL of the upper left spiral pile 12 is engaged with and supported by the hollow tube 2 of the lower left spiral pile 1. Subsequently, while the hollow pipe 21 of the lower right spiral pile 11 is engaged with and supported by the notch 31UR of the upper right spiral pile 12, the screw blade 3UR of the upper right spiral pile 13 is supported by the upper left spiral pile 12. The hollow tube 22 is placed in contact with the outer peripheral surface 2a. In this state, when the two front and rear portions of the four hollow tubes 2 and 21 to 23 are bound by the binding member 8, they are bundled into a set of four as shown in FIGS.

That is, when the interval in the vertical direction (vertical direction) of each spiral pile 1, 11-13 is L2, and the interval in the horizontal direction (horizontal direction) of each spiral pile 1, 11-13 is L3,
L2 <L3
Thus, the four spiral piles 1 and 11 to 13 bound by the binding member 8 can be bound by narrowing the interval L2 in the vertical direction. For example, the interval L2 is 100 mm, and the interval L3 is 150 mm. For this reason, the four spiral piles 1 and 11-13 bound together are the conventional spiral pile 100 (FIG. 16 (a), (b)) provided with the screw blade 300 which does not have the notch part 31UL, 31UR, 31LL, 31LR. The bundling members 8 for bundling the four hollow tubes 2, 21 to 23 can be arranged at a position interval that forms a rectangle at an interval L 2 that is 50 mm narrower in the vertical direction than when bundling (see).

As shown in FIG. 8 (a), the spiral piles 12 and 13 disposed on the upper side with respect to the lower spiral piles 1 and 11 in a side view are reversed in direction from each other, and the flange 4 (screw blade 3) It is shifted in the axial direction by the thickness of. As shown in FIG. 8 (b), the spiral piles 11 and 13 arranged on the right side with respect to the spiral piles 1 and 12 on the left side in plan view are opposite to each other, and the flanges 4 and the screw blades 3 are the same. Are arranged slightly shifted in the axial direction so that they do not contact each other.
By arrange | positioning in this way, the four spiral piles 1 and 11-13 are arrange | positioned so that the flange 4 comrades and the screw blade 3 comrades may not contact | abut each other, and it may not be attached.

  As shown in FIG. 9 to FIG. 11, when the spiral piles 1, 11 to 13 bundled into a set of four pieces by the bundling member 8 are transported by a ship or the like, In a state where the binding members 8 that bind the spiral piles 1, 11 to 13 are arranged so as to form a horizontally long rectangle when viewed from the front, each pair is stacked horizontally and stacked in the front-rear direction. Then, one spiral pile 1 that is not bound is placed in an upright direction.

  For example, spiral piles 1 and 11-13 having a length L4 (for example, 1800 mm) in the spiral pile storage box 91 are spaced apart in the horizontal (left and right) direction by a distance T1 (for example, 150 mm) and vertically spaced by a distance T2 (for example, 100 mm). The four members are bundled together by the bundling member 8 and stored. In this case, as shown in FIG. 9, the screw blades 3 of the upper spiral piles 12 and 13 of each set abut against the hollow tubes 2 of the upper spiral piles 12 and 13 of each set, and the lower side of each set. In the state where the screw blades 3 of the spiral piles 1 and 11 are in contact with the hollow tubes 2 of the upper spiral piles 12 and 13 of each set, the interval T4 (for example, 40 mm) in the right direction and the interval T5 in the left direction The sheets are sequentially stacked at an interval T3 (150 mm) in the vertical direction with a shift (for example, 110 mm).

  When four sets of spiral piles 1, 11 to 13 are stacked in two stages, a vertical orthogonal in the vertical direction with the flange 4 on the upper side and the blade plate 5 on the lower side between the sets. One spiral pile 14 is loaded in the radial direction of the screw blade 3 at intervals of a length S1 (for example, 250 mm).

As shown in FIG. 10, one set of four spiral piles 1 housed in the spiral pile storage box 91 is a total of 56 sets (224 sets) of 7 sets in the left-right direction and 8 sets in the up-down direction when viewed from the front. ) Stored.
As shown in FIG. 11, the rectangular cross-shaped spiral pile 14 disposed in the spiral pile storage box 91 in the vertical direction has a length S <b> 1 in the radial direction of the screw blade 3 in the front-rear direction, as shown in FIG. 11. , 300 mm), 5 in the left-right direction, 6 in the radial direction of the screw blade 3 in the radial direction, and a length S 1, for a total of 30.
That is, when adding the above-mentioned four sets of four sets of 224 spiral piles 1, 11 to 13 to the vertically oriented orthogonal spiral pile 14,
(5 pieces × 6 rows) + (4 pieces × 56 sets) = 254 pieces, and a total of 254 spiral piles 1 are stored in the spiral pile storage box 91.
When the spiral pile storage box 91 is transported in a container, the spiral pile storage box 91 is stored in the container in a line in the longitudinal direction. Therefore, in the container,
254 spirals × 3 boxes = 762 spiral piles 1 are stored and can be transported at a time.

  In this way, by storing the spiral pile 1 in a container of a predetermined size and transporting it by ship, trailer or truck, a large amount of the spiral pile 1 can be carried at one time, so that the transportation capacity is improved. Transportation costs can be significantly reduced.

  Moreover, as shown in FIGS. 9 to 11, the spiral pile 1 is less likely to collapse a large amount of the spiral pile 1 in a predetermined space by stacking four bundles and storing them in a warehouse or the like. Can be loaded and stored in a state.

[First Modification]
The present invention is not limited to the above-described embodiment, and various modifications and changes can be made within the scope of the technical idea. The present invention extends to these modifications and changes. Of course. In addition, the already demonstrated structure attaches | subjects the same code | symbol and abbreviate | omits the description.
FIG. 12 is a view showing a first modified example of the spiral pile according to the embodiment of the present invention, and is an enlarged schematic side view of a main part showing an arrangement state of the spiral pile placed horizontally in the spiral pile storage box. FIG. 13: is a figure which shows the 1st modification of the spiral pile which concerns on embodiment of this invention, and is a schematic side view which shows the arrangement | positioning state of the spiral pile placed horizontally in the spiral pile storage box. FIG. 14: is a figure which shows the 1st modification of the spiral pile which concerns on embodiment of this invention, and is a schematic plan view which shows the arrangement | positioning state of the spiral pile vertically installed in the spiral pile storage box.

  In the embodiment, as an example of the spiral pile 1, as shown in FIG. 4A, the notch 31 of the screw blade 3 has a size in which the hollow tube 21 of the other spiral pile 11 completely enters and is flat. The description has been given by taking as an example what is formed in a V-shaped groove as viewed, but is not limited thereto. Further, the binding member 8 may not be provided.

As shown in FIG. 12, when the spiral pile 1A is stored in the spiral pile storage box 91, the plurality of spiral piles 1 are not bundled by the binding member 8 (see FIG. 8), but one by one in the vertical direction. You may arrange it vertically.
Further, the cutout portion 31A of the spiral pile 1A may be any as long as the hollow tube 21A of the other spiral pile 11A can enter the cutout portion 31A and be close to the axis, and the hollow tube 21A is cutout. It may be slightly inserted into the portion 31A. Also in this case, since the hollow tube 21A is arranged close to the axial center as much as the hollow tube 21A of the other spiral pile 11A enters the notch 31A, the spiral pile 1A is placed between the spiral piles 1A and 11A. The spiral pile 1A can be stored in the spiral pile storage box 91 or the like by reducing the distance.

Further, the cutout portion 31A is formed in a shape in which one circumferential end surface 31Aa and the other circumferential end surface 31Ab are asymmetric and have different inclinations in plan view, and the inner bottom portion 31Ac has a left-right non-uniform shape. It doesn't matter.
Moreover, in the said embodiment, the one circumferential direction end surface 31a, the other circumferential direction end surface 31b, and the inner bottom part 31c are mentioned as an example, and the notch part 31 formed in the substantially Y shape by planar view is mentioned as an example. Although described, the cutout 31A may be of a shape that can accommodate at least a part of the hollow tube 21A of the other spiral pile 11A, and the shape and size thereof are not particularly limited. The cutout 31A may be, for example, a circular groove, a U-shape, or a recess shape in plan view.

  In this case, compared with the embodiment, the interval T2A (for example, 115 mm) between the hollow tube 21A of the spiral pile 1A and the hollow tube 21A of the other spiral pile 11A disposed on the upper side of the spiral pile 1A. ) Is increased by the amount by which the distance that the hollow tube 21A has entered the notch 31A is reduced (48.6 mm of the outer diameter of the hollow tube 21A).

As shown in FIG. 12, the third, fifth, eighth, eleventh and fourteenth stages (see FIG. 13) of the spiral piles 12A loaded on the other spiral piles 11A are connected to other hollow tubes 22A. The spiral pile 11A may be arranged by shifting the distance T6A (for example, 40 mm) in the right direction from the hollow tube 21A. If it does in this way, hollow tube 22A of spiral pile 12A of the 3rd, 5th, 8th, 11th, 14th stage, and hollow tube 23A of spiral pile 13A of other stages, for example, the 4th stage, etc. Since the distance T4A (for example, 110 mm) is the same height as the distance L5A (for example, 115 mm) in the oblique direction, it can be shortened to, for example, 5 mm. In this case, the interval T3A between the hollow tube 21A of the other spiral pile 11A and the hollow tube 22A of the third-stage spiral pile 12A thereon is, for example, 150 mm, which is the same as in the above embodiment. . The interval TA between the first-stage spiral pile 1A and the fourth-stage spiral pile 13A is:
TA = T2A + T3A + TA = 375mm
It is.

As shown in FIG. 13, the horizontal interval T1A of each spiral pile 1A is, for example, 155 mm. The spiral piles 1 </ b> A, 11 </ b> A, 12 </ b> A, 13 </ b> A at each stage are arranged in the spiral pile storage box 91 side by side in the horizontal direction. In this case, the spiral piles 12A in the third, fifth, eighth, eleventh and fourteenth stages from the bottom are T6A (40 mm) in the right direction compared to the first, second and fourth spiral piles 1A, 11A and 13A. They are offset. In the spiral pile storage box 91, a set of three spiral piles 1A, 11A, 12A from the first stage spiral pile 1A to one set (the third stage spiral pile 12A and the fourth stage The spiral piles 1A, 11A, and 12A are ordered through one set of the fourth-stage spiral piles 13A for convenience of engaging the notches 31 of the spiral piles 13A with the hollow tubes 2). Four sets of three reversed 1 sets are sequentially directed upward, and a total of 5 sets + spiral piles 1A for the first stage are stacked and stored in 16 stages.
For this reason, in the spiral pile storage box 91, a set of spiral piles 1A, 11A, 12A arranged in a horizontal direction,
14 x 16 stages = 224 are stored.
Even in this case, the interval T2A between the spiral piles 12A and 13A arranged above and below is shortened by the amount that the hollow tube 21A of the other spiral pile 11A enters the cutout portion 31A, so that a large amount is provided in a predetermined space. It becomes possible to load the spiral pile 1A.

In addition, as shown in FIG. 14, in the spiral pile storage box 91, 13 orthogonally arranged vertical spiral piles 14A in the left-right direction and six rows in the front-rear direction are arranged in plan view. For this reason, in the spiral pile storage box 91,
13 × 6 rows = 78 orthogonal spiral piles 14A are stored. As a result, a total of 302 pieces can be stored in the spiral pile storage box 91 by adding 224 pieces of the horizontal piles 1A, 11A, 12A, 13A. If three spiral pile storage boxes 91 are stored in a container and transported, 906 spiral piles 1A can be transported at a time.

[Second Modification]
FIG. 15 is a perspective view showing a second modification of the spiral pile according to the embodiment of the present invention.
In the embodiment, the case where one screw blade 3 is provided in the hollow tube 2 as an example of the spiral pile 1 has been described as an example. However, as illustrated in FIG. 15, the screw blades 3 and 3B are hollow tubes. 2 may be provided in plural.

  In this case, the spiral pile 1 </ b> B is formed such that the increased screw blade 3 </ b> B is formed in the same shape with respect to the screw blade 3 and is separated from the flange 4 side. The screw blade 3B has a position where the cutout portion 31B coincides with the cutout portion 31 of the screw blade 3 and the concave portion 4a of the flange 4 when viewed from the axial direction (the concave portions 4a and 4b are located with respect to the outer peripheral surface 2a of the hollow tube 2). And at the same phase as the notches 31 and 31B.

  When the spiral pile 1 thus formed is transported by vehicle or ship or stored in a warehouse or the like, as shown in FIG. 15, the orientation is changed by 180 degrees on the hollow tube 2 of the spiral pile 1B. In addition to engaging the notches 31 and 31B of the screw blades 3 and 3B of the other spiral pile 11B and the recess 4b of the flange 4, the lower spiral pile 1B is engaged with the hollow tube 2 of the other spiral pile 11B. The notches 31 and 31B of the screw blades 3 and 3B and the recess 4b of the flange 4 are engaged.

In this way, the distance L1 between the spiral piles 1B and 11B is shorter than the length S2 (for example, 250 mm) in the radial direction of the screw blades 3 and 3B. The space L1 is narrowed and the spiral pile 1B is stacked upward by an amount corresponding to the hollow tube 2 entering the notches 31, 31B than the length S100 (see FIGS. 16A and 16B). , Can be arranged continuously in the horizontal direction.
For this reason, it is possible to arrange a large amount of spiral piles 1B at a predetermined location in the warehouse, or to store a large amount of spiral piles 1B while storing them in a container of a predetermined size.

[Other variations]
In addition, in the said embodiment, as shown in FIGS. 9-11, although the case where the set of four spiral piles 1 was stored in the box-type spiral pile storage box 91 was described as an example, spiral pile storage The box 91 may be disposed between the columns of a so-called flat rack container shape.

  In that case, the flat rack container is composed of a rectangular floor plate and a support column erected upward from four corners on the front, rear, left and right sides of the floor plate. The set of four spiral piles 1 bound by the binding member 8 may be loaded between the two front pillars and the two rear pillars. By doing so, a large amount of spiral piles 1 can be loaded and transported in a narrow space, or stored (temporarily placed) in a warehouse or work site.

1,1A, 1B Spiral pile 2,21,21A, 22,22A, 23,23A Hollow tube 2a Outer peripheral surface 2e Tip 2f Base end 3, 3B Screw blade 3a Outer peripheral 3c, 3d Outer end 4 Flange 4a , 4b Recessed part 5 Blade plate 11, 11A, 11B, 12, 12A, 13, 13A Spiral pile 14, 14A Orthogonal spiral pile (spiral pile)
31, 31A, 31B Notch 31a, 31Aa One circumferential end face 31b, 31Ab The other circumferential end face 31d, 31e Slot 91 Spiral pile storage box A Ground

Claims (6)

A spiral pile that is embedded in the ground by screwing the tip,
A hollow tube extending in the axial direction;
A screw blade fixed to the tip of the hollow tube in a substantially spiral shape;
A flange welded to the proximal end of the hollow tube ,
The screw blade is formed so that a V-shaped notch penetrated through the hollow tube as viewed from the axial direction opens to the outer peripheral surface ,
The flange is formed with a recess on the outer periphery, and the recess is disposed at the same phase as the notch when viewed from the axial direction of the hollow tube,
The recess is formed of a groove having a width larger than the outer diameter of the hollow tube, and is notched to a size that allows the hollow tube of another spiral pile of the same shape to enter,
When the other spiral piles are stacked, the hollow pipes of the other spiral piles are supported by being engaged with the cutout portions and the recesses, respectively, and the spiral piles of the other spiral piles are supported. A spiral pile characterized in that an outer peripheral surface of a hollow tube is supported in a state of being in contact with a V-shaped inclined surface of the notch . When the screw blade is viewed from the axial direction of the hollow tube , the notch is formed in a groove shape cut from the outer peripheral surface of the screw blade, and the inside of the screw blade is formed from the inner bottom of the notch. The spiral pile according to claim 1, wherein a slit portion is formed along the periphery . The spiral pile according to claim 1 or 2, wherein a solar panel structure is placed on the flange . A spiral pile storage method for storing the spiral pile according to any one of claims 1 to 3 in a warehouse, a container, or a spiral pile storage box ,
The spiral pile is stored in a state in which the hollow pipe of the other spiral pile is engaged with the notch and the recess .   The spiral pile storage method according to claim 4, wherein the spiral pile is bundled by a bundling member in a state in which the hollow pipe of the other spiral pile is engaged with the notch. The spiral pile and the other spiral pile, in a state where the engagement between the hollow tube and the notch together, along with being accommodated in the spiral pile in a storage box stacked with alternating orientation, the spiral pile The orthogonal spiral pile arrange | positioned toward the orthogonal direction with respect to the said spiral pile and said other spiral pile is accommodated in the storage box, The Claim 4 or Claim 5 characterized by the above-mentioned. Storage method for spiral piles.

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