JP2020061981A - Pipe integrated type spiral pile, production method of pipe integrated type spiral pile and structure - Google Patents

Abstract

To provide a pipe integrated type spiral pile which can be easily screwed in a ground surface by only rotating the pile by a hand without using power of a vibration drill or the like, and which can be produced extremely inexpensively by only using an extremely inexpensive spiral pile and a pipe, the spiral pile and the pipe being available in the market.SOLUTION: A pipe integrated type spiral pile comprises: a steel spiral pile 10 formed of a spiral part 11, a straight line part 12 and a hook part 13; and a steel pipe 20 which is fixed to the hook part 13 of the spiral pile 10 in a coaxial state to the spiral pile 10 and whose outer diameter is smaller than that of the spiral pile 10. The hook part 13 of the spiral pile 10 is made to pass through a pair of notches 21, 22 which are provided on one of opposite side positions respectively related to a center axis of the pipe 20 on a side surface of one end part of the pipe 20, and a boundary part of the pipe 20 and the hook part 13 is welded.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a pipe-integrated spiral pile, a method for manufacturing a pipe-integrated spiral pile, and a structure, for example, a pipe-integrated spiral pile suitable for use in installing a pipe house such as an agricultural house on the ground, and a method for manufacturing the same. And a structure installed on the ground by using the pipe-integrated spiral pile.

  Conventionally, when installing a pipe house used to store agricultural equipment and harvests on a site, it is first necessary to screw a commercially available spiral pile as a foundation pile to the ground of the site at a predetermined arrangement and at an interval. It is common. The spiral pile is generally a steel helix pile having a spiral portion, a straight portion, and a hook portion bent into a circle. When screwing the helix pile into the ground, place the helix pile on the ground with the tip of the helix downward, pass the burl through the hook, and turn the bale by hand to make a large arc. After that, the hook portion of the spiral pile and the pipe forming the base of the pipe house are twisted and coupled with the number line.

  However, the work of turning the bar so as to draw a large arc and the work of twisting the hook part of the spiral pile and the pipe of the base of the pipe house with the number line are labor-intensive works, and when there are many spiral piles, It will be a huge burden. Particularly regarding the work of turning the burl, as the spiral pile gradually dives into the ground due to the rotation of the burl, the worker needs to bend the body to turn the burl near the ground, which is a very difficult work. Also, if the helix pile dives to the ground to some extent, the burl interferes with the base pipe that is built near the ground, so that the bale is attached to the hook part of the helix pile every time the helix pile is rotated 180 degrees or 60 degrees, for example. It needs to be replaced, which is very troublesome.

  On the other hand, a so-called spiral pile in which a pipe having substantially the same diameter as the spiral portion is coaxially attached to the upper portion of the spiral portion formed by twisting flat steel into a spiral shape has been proposed and is commercially available (Patent See Reference 1 and Non-Patent Reference 1.). When driving the spiral pile on the ground, a guide plate for driving the spiral pile is placed at a position on the ground where the spiral pile is driven, and the spiral portion of the spiral pile is aligned with the slit provided in the guide plate. Then, a washer is put on the upper end of the pipe on the upper part of the spiral pile, and the guide plate is held by the foot so that the guide plate does not shift, and it is placed by a vibration drill. After that, the guide plate is removed leaving about 10 cm of the spiral portion of the spiral pile and further hammered until the pipe portion of the spiral pile is filled with 5 to 10 cm.

JP-A-2016-108874 (paragraphs 0020 and 0021 and FIG. 1)

Construction manual for construction horticultural house using scaffolding materials, Agricultural Research Institute, West Japan Agricultural Research Center, published March 28, 2017 (pages 7 and 8)

  However, the pipe-integrated spiral pile described in Patent Document 1 and Non-Patent Document 1 is a special one in which a pipe is attached to the upper part of a spiral portion formed by twisting flat steel into a spiral shape, It is much more expensive than the more common spiral piles on the market. Moreover, in order to drive this pipe-integrated spiral pile to the ground, not only the complicated and complicated work as described above is required, but also a vibrating drill is required for the placement, which is inconvenient and costly. It has the drawback of being attached.

  Therefore, the problem to be solved by the present invention is to easily screw into the ground with a small amount of labor by turning it by hand regardless of the presence or absence of a pipe assembled near the ground without using power such as a vibration drill. A pipe-integrated spiral pile that can be manufactured at a very low cost by using commercially available extremely inexpensive spiral piles and pipes, and a manufacturing method that can easily manufacture such a pipe-integrated spiral pile And to provide a structure installed on the ground using such a pipe integrated spiral pile.

In order to solve the above problems, the present invention provides
Steel spiral pile consisting of spiral part, straight part and hook part,
The hook portion of the spiral pile has a steel pipe coaxially fixed to the spiral pile,
The hook portion of the spiral pile is passed through a pair of notches or holes provided at positions opposite to each other with respect to the central axis of the pipe on the side surface of the one end portion of the pipe, and the pipe and the hook portion. It is a pipe-integrated spiral pile in which the boundary part of is welded.

  In this pipe-integrated spiral pile, as the spiral pile, a commercially available general one can be used, and as the pipe, a commercially available general scaffolding single pipe can be used. It is not limited. By using a commercially available general spiral pile and a single pipe for scaffolding and welding these, the spiral pile with a pipe integrated can be constructed at an extremely low cost. The shape of the hook portion of the spiral pile is a shape that is bent in a round shape and is not particularly limited, but it is generally a horseshoe shape (or a substantially elliptical shape). The dimensions of each portion of the spiral pile and the pipe are appropriately selected according to the specifications of the structure constructed using the pipe integrated spiral pile. The outer diameter of the pipe is typically smaller than the outer diameter of the spiral pile (outer diameter of the spiral portion), but is not limited to this and may be equal to or larger than the outer diameter of the spiral pile if necessary. Suitably, on the side surface of the other end of the pipe, a pair of holes or notches through which a rod for rotation is passed when screwing the pipe-integrated spiral pile to the ground are located at positions opposite to each other with respect to the central axis of the pipe. It is provided. The shape of these holes or cutouts is such that a rod can be passed through these holes or cutouts, and both ends of this rod can be held by hand and rotated in a plane perpendicular to the central axis of the pipe. As long as it is possible to rotate the pipe-integrated spiral pile, basically any shape may be used. The rod may be a hollow rod, ie a pipe or a solid rod. The cross-sectional shape of the rod is typically circular, but is not limited to this. The rod is typically made of steel, but may be made of other materials as long as it has sufficient rigidity for the rotational force applied to the pipe-integrated spiral pile, for example, hard plastic. It may be.

Further, the present invention is
Steel spiral pile consisting of spiral part, straight part and hook part,
The hook portion of the spiral pile has a steel pipe coaxially fixed to the spiral pile,
The hook portion of the spiral pile is passed through a pair of notches or holes provided at positions opposite to each other with respect to the central axis of the pipe on the side surface of the one end portion of the pipe, and the pipe and the hook portion. A method for manufacturing a pipe-integrated spiral pile, in which the boundary part of is welded,
A step of preparing the spiral pile and the pipe, and inserting the spiral portion of the spiral pile into an axis-aligning pipe capable of accommodating the spiral portion of the spiral pile with almost no gap;
Passing the hook portion of the spiral pile through the pair of notches or holes of the pipe, and holding the shaft for pipe and the pipe coaxially,
A method for manufacturing a pipe-integrated spiral pile, comprising a step of welding a boundary portion between the pipe and the hook portion.

  In this method of manufacturing the pipe-integrated spiral pile, a conventionally known method can be used as a method of coaxially holding the pipe for axial alignment and the pipe, and is selected as necessary. For example, a device that can hold pipes at four positions with different heights by pushing the pressing members toward the central axis from three directions in the horizontal plane so that the central axes are held in the vertical direction is used. , The lower side two positions hold the centering pipe by moving the pressing member toward the central axis from three directions within the horizontal plane, and the upper two positions hold the pressing member from the three directions within the horizontal plane by the central axis. Hold the pipe to be fixed to the spiral pile by moving toward. In the invention of the method for manufacturing a pipe-integrated spiral pile, what is described in relation to the above-described invention of a pipe-integrated spiral pile is established unless the property thereof is contrary to the above.

Further, the present invention is
A structure installed by screwing a plurality of spiral piles onto the ground,
At least one of the above spiral piles,
Steel spiral pile consisting of spiral part, straight part and hook part,
The hook portion of the spiral pile has a steel pipe coaxially fixed to the spiral pile,
The hook portion of the spiral pile is passed through a pair of notches or holes provided at positions opposite to each other with respect to the central axis of the pipe on the side surface of the one end portion of the pipe, and the pipe and the spiral pile. Is a structure that is a pipe-integrated spiral pile to which is welded.

  The structure may be basically any structure as long as the pipe-integrated spiral pile can be applied. For example, various types of pipe houses (vinyl houses) such as agricultural houses and solar power generation facilities can be used. For example, a mount. In the invention of this structure, as to matters other than the above, what has been described in relation to the invention of the above-described spiral pile with pipe integrated type is established unless the property is violated.

  According to the present invention, without using power such as a vibration drill, a rod is passed through the pipe portion, held with both hands, and rotated, regardless of the presence or absence of a pipe assembled near the ground. It is possible to realize a pipe-integrated spiral pile that can be easily screwed into the ground and that can be constructed at an extremely low cost only by using a commercially available extremely inexpensive spiral pile and a pipe. Further, such a pipe-integrated spiral pile can be easily manufactured by welding the hook portion of the spiral pile and the pipe. Furthermore, the structure can be installed on the ground at low cost easily and in a short time by using such a pipe-integrated spiral pile.

It is the front view, right side view, and top view which show the pipe integrated spiral pile by the 1st Embodiment of this invention. It is a front view which shows the spiral pile which comprises the pipe integrated spiral pile by the 1st Embodiment of this invention. It is the front view and right side view which show the pipe which comprises the pipe integrated spiral pile by the 1st Embodiment of this invention. It is a front view which shows the manufacturing method of the pipe integrated spiral pile by the 1st Embodiment of this invention. It is a front view which shows the usage method of the pipe integrated spiral pile by the 1st Embodiment of this invention. It is a top view which shows the usage method of the pipe integrated spiral pile by the 1st Embodiment of this invention. It is a front view which shows the usage method of the pipe integrated spiral pile by the 1st Embodiment of this invention. 6 is a drawing-substituting photograph showing a state in which a pipe-integrated spiral pile according to Example 1 is screwed into the ground of a farm. It is the front view, right side view, and top view which show the pipe integrated spiral pile by the 2nd Embodiment of this invention. It is a front view which shows the usage method of the pipe integrated spiral pile by the 2nd Embodiment of this invention. 8 is a drawing-substituting photograph showing a state in which a pipe with a side plate for rotation is attached to an upper end portion of a pipe-integrated spiral pile according to Example 2. It is the front view, right side view, and top view which show the pipe integrated spiral pile by the 3rd Embodiment of this invention. It is a perspective view which shows the pipe house by the 4th Embodiment of this invention. It is a perspective view which shows the construction method of the pipe house by the 4th Embodiment of this invention.

  Hereinafter, modes for carrying out the invention (hereinafter, referred to as embodiments) will be described.

<1. First Embodiment>
[Pipe integrated spiral pile]
1A, B and C show a pipe integrated spiral pile according to the first embodiment, FIG. 1A is a front view, FIG. 1B is a right side view, and FIG. 1C is a plan view.

  As shown in FIGS. 1A, 1B, and 1C, the pipe-integrated spiral pile includes a spiral pile 10 and a pipe 20 coaxially integrated with the upper portion of the spiral pile 10. The outer diameter of the pipe 20 is smaller than the outer diameter of the spiral pile 10. FIG. 2 shows the spiral pile 10 used for the pipe-integrated spiral pile. As shown in FIG. 2, the spiral pile 10 is a general commercially available product, and includes a spiral portion 11, a straight portion 12 connected to one end of the spiral portion 11, and a hook bent into a substantially horseshoe shape connected to the straight portion 12. It consists of part 13. The straight line portion 12 is substantially on the central axis of the spiral portion 11. The pipe 20 used in this pipe-integrated spiral pile is shown in FIGS. 3A and 3B. As shown in FIGS. 3A and 3B, a pair of notches 21 and 22 are provided on the side surface of one end (lower end) of the pipe 20 at positions opposite to each other with respect to the central axis of the pipe 20. These notches 21 and 22 have an elongated, substantially rectangular shape extending in the direction of the central axis of the pipe 20, and have a circular bottom portion. The width of the notches 21 and 22 is selected to be slightly larger than the diameter of the steel bar that constitutes the hook portion 13 of the spiral pile 10. The other end (upper end) of the pipe 20 is provided with circular holes 23 and 24 penetrating the pipe 20 in its diameter direction. As shown in FIGS. 1A, B, and C, the hook portion 13 of the spiral pile 10 is passed through to the bottom of the notches 21 and 22 of the pipe 20, and the boundary portion between the pipe 20 and the hook portion 13 is welded. Reference numeral 25 indicates a welded portion.

[Manufacturing method of pipe-integrated spiral pile]
As shown in FIG. 4A, an axis-aligning pipe 30 having an inner diameter capable of accommodating the spiral portion 11 of the spiral pile 10 with almost no space is prepared, and the axis-aligning pipe 30 is used to weld the floor surface of the floor. Alternatively, stand on a stand installed on the floor. Next, the spiral portion 11 of the spiral pile 10 is inserted into the shaft-aligning pipe 30. The straight line portion 12 and the hook portion 13 of the spiral pile 10 are arranged so as to be exposed to the outside (upper side) of the axising pipe 30. Next, after the hook portion 13 of the spiral pile 10 is passed through the notches 21 and 22 of the pipe 20, the pipe 20 is held coaxially with the axis-aligning pipe 30. If necessary, the hook portion 13 of the spiral pile 10 may be inserted into the notches 21 and 22 of the pipe 20 and then the spiral portion 11 of the spiral pile 10 may be inserted into the axial alignment pipe 30.

  Next, as shown in FIG. 4B, the boundary portion between the hook portion 13 of the spiral pile 10 and the pipe 20 is welded to integrate the spiral pile 10 and the pipe 20. After that, the spiral portion 11 of the spiral pile 10 is pulled out from the axising pipe 30.

  As described above, the desired pipe-integrated spiral pile shown in FIGS. 1A, 1B and 1C can be manufactured.

[How to use spiral pile with pipe integrated]
Fig. 5 shows how to use the pipe-integrated spiral pile. As shown in FIG. 5, after the pipe 40 for rotation is passed through the holes 23, 24 at the upper end of the pipe 20 of the pipe-integrated spiral pile, the pipe-integrated spiral pile is screwed into the ground 50 at a position where the pipe-integrated spiral pile is screwed. Set up a stake. Next, as shown in FIG. 6, by holding both ends of the pipe 40 by hand and rotating clockwise in the horizontal plane as shown by the arrow, as shown in FIG. Screw the spiral part 11 of the pile 10 into the ground 50.

(Example 1)
A pipe-integrated spiral pile was produced. The total length of the produced pipe-integrated spiral pile is about 95 cm. As the helical pile 10, a commercially available product obtained by twisting a steel bar having a diameter of 13 mm is used. The overall length is 50 cm, the diameter of the spiral portion 11 is 8 cm, the length is 25 cm, the length of the straight portion 12 is 12 cm, and the width of the hook portion 13 is 8. It has a horseshoe shape of 5 cm and a length of 13 cm. As the pipe 20, a commercially available scaffolding single pipe is used and has a length of 50 cm and an outer diameter of 48.6 mm. The notches 21 and 22 of the pipe 20 have a length (depth) of 6 cm in the central axis direction from the one end surface of the pipe 20 and a width of 13.2 mm, and the bottoms are semicircular. The holes 23 and 24 of the pipe 20 are circular with a diameter of 8 mm provided at a position about 4 cm away from the other end surface of the pipe 20 in the central axis direction. Welding between the pipe 20 and the hook portion 13 of the spiral pile 10 was performed by arc welding.

  The pipe-integrated spiral pile thus produced was screwed into the ground of the farm. Specifically, the pipe-integrated spiral pile is erected at a screwing position on the ground of the farm, and a steel pipe for rotation having a length of 70 cm and an outer diameter of 6 mm is passed through the holes 23 and 24 of the pipe 20 at both ends of the pipe. The pipe-integrated spiral pile was screwed in by holding the part by hand and rotating the pipe clockwise. Figure 8 shows how the pipe-integrated spiral pile is screwed into the ground.

  According to the first embodiment, it is possible to easily screw it into the ground simply by turning it by hand using a rotating rod such as a pipe without using power such as a vibration drill, and it is extremely inexpensive on the market. It is possible to realize a pipe-integrated spiral pile which can be constructed at an extremely low cost only by using a simple spiral pile and a pipe. In this pipe-integrated spiral pile, the rotating rod is inserted into the holes 23 and 24 at the upper end of the pipe 20 even if it dive into the ground near the hook portion 13. Therefore, the height of the rotating rod is at most an operator. It's up to the knees and is easy to work with. Also, for the same reason, even if this pipe-integrated spiral pile dives to the ground to some extent, the rotating rod does not interfere with the base pipe assembled near the ground, etc. There is no need to replace the holes 23, 24 of 20.

<2. Second Embodiment>
[Pipe integrated spiral pile]
9A, B and C show a pipe-integrated spiral pile according to the second embodiment, FIG. 9A is a front view, FIG. 9B is a right side view, and FIG. 9C is a plan view.

  As shown in FIGS. 9A, B, and C, the pipe-integrated spiral pile does not have holes 23 and 24 formed at the other end of the pipe 20, but instead the other end surface of the pipe 20 extends in the central axis direction of the pipe 20. It differs from the pipe-integrated spiral pile according to the first embodiment only in that the notches 26 and 27 having a constant width extending in the direction are formed. The bottoms of the notches 26, 27 are semicircular. The width and depth (length) of the notches 26 and 27 allow the rod for rotation to pass through these notches 26 and 27, and the rod is in a plane perpendicular to the central axis of the pipe 20. There is no particular limitation as long as it can rotate the pipe-integrated spiral pile without hindrance. As the rod for rotation, a simple pipe or a solid rod, or a pipe with a side plate in which a side plate is attached to the side surface of the central portion of the pipe may be used. When a pipe with a side plate is used as a rod for rotation, the notches 25 and 26 are formed so that the side plate of the pipe with a side plate fits.

[Manufacturing method of pipe-integrated spiral pile]
The method for manufacturing the pipe integrated spiral pile is the same as the method for manufacturing the pipe integrated spiral pile according to the first embodiment, except that the notches 26 and 27 are formed on the side surfaces of the pipe 20.

[How to use spiral pile with pipe integrated]
FIG. 10 shows how to use the pipe-integrated spiral pile. As shown in FIG. 10, after fitting a rectangular side plate 61 at the center of a pipe 60 with a side plate for rotation into the notches 26 and 27 at the upper end of the pipe 20 of the pipe integrated spiral pile, the pipe integrated spiral pile is provided. Stands on the ground 50 at the screwed position. Next, the both ends of the pipe 60 with the side plate are held by hand and rotated clockwise in the horizontal plane, so that the spiral portion 11 of the spiral pile 10 of the pipe-integrated spiral pile is screwed into the ground 50.

(Example 2)
A pipe-integrated spiral pile was produced. The total length of the produced pipe-integrated spiral pile is about 95 cm. As the helical pile 10, a commercially available product obtained by twisting a steel bar having a diameter of 13 mm is used. The overall length is 50 cm, the diameter of the spiral portion 11 is 8 cm, the length is 25 cm, the length of the straight portion 12 is 12 cm, and the width of the hook portion 13 is 8. It has a horseshoe shape of 5 cm and a length of 13 cm. As the pipe 20, a commercially available scaffolding single pipe is used and has a length of 50 cm and an outer diameter of 48.6 mm. The notches 21 and 22 of the pipe 20 have a length (depth) of 6 cm and a width of 13 mm from the one end surface of the pipe 20 in the central axis direction, and the bottoms are semicircular. The notches 26 and 27 of the pipe 20 have a length (depth) of 3.5 cm and a width of 8 mm in the central axis direction from the other end surface of the pipe 20, and the bottoms are semicircular. Welding between the pipe 20 and the hook portion 13 of the spiral pile 10 was performed by arc welding.

  The pipe-integrated spiral pile thus produced was screwed into the ground of the farm. Specifically, the pipe-integrated spiral pile is erected at a position where it is screwed into the ground of the farm, the side plates 61 of the pipe 60 with side plates are fitted into the notches 26 and 27 at the upper end of the pipe 20, and both ends of the pipe 20 are touched by hand. He screwed in the pipe-integrated spiral pile by holding it and rotating the pipe clockwise. FIG. 11 shows a state where the side plate 61 of the produced pipe 60 with a side plate is fitted into the notches 26 and 27 of the pipe integrated spiral pile. The side plate-equipped pipe 60 is formed by welding a rectangular side plate made of steel having a length of 60 mm, a width of 40 mm and a thickness of 6 mm to the side surface of the central portion of a steel pipe having a length of 70 cm and an outer diameter of 6 mm.

  According to the second embodiment, the same advantages as those of the first embodiment can be obtained.

<3. Third Embodiment>
[Pipe integrated spiral pile]
12A, B and C show a pipe-integrated spiral pile according to the third embodiment, FIG. 12A is a front view, FIG. 12B is a right side view, and FIG. 12C is a plan view.

  As shown in FIGS. 12A, 12B, and 12C, the pipe-integrated spiral pile has a pipe-integrated type in which the ratio of the outer diameter of the pipe 20 to the outer diameter of the spiral portion 11 of the spiral pile 10 is the first or the second embodiment. Small compared to the spiral pile. A pair of notches 21 and 22 are provided on the side surface of one end (lower end) of the pipe 20 at positions opposite to each other with respect to the central axis of the pipe 20. The length in the direction of the central axis is smaller than that of the pipe-integrated spiral pile according to the first or second embodiment. A pair of circular holes 28, 29 are provided on the side surface on one end side of the pipe 20 on the opposite sides with respect to the central axis of the pipe 20 in the direction of the central axis and away from the bottoms of the notches 21, 22. . The widths of the notches 21 and 22 and the diameters of the holes 28 and 29 are selected to be slightly larger than the diameter of the steel bar constituting the hook portion 13 of the spiral pile 10. The width of the notches 21 and 22 may be constant in the direction of the central axis of the pipe 20, or may gradually decrease from one end surface of the pipe 20 toward the other end surface thereof, and is selected as necessary. Then, the hook portion 13 of the spiral pile 10 is passed through the holes 28 and 29 and the bottom portions of the notches 21 and 22, and the boundary portion between the pipe 20 and the hook portion 13 is welded. Reference numeral 25 indicates a welded portion. If necessary, in order to improve the joint strength between the spiral pile 10 and the pipe 20, the tip portion of the hook portion 13 of the spiral pile 10 and the root portion of the hook portion 13 may be welded. Except for the above, this pipe-integrated spiral pile is the same as the pipe-integrated spiral pile according to the first embodiment.

[Manufacturing method of pipe-integrated spiral pile]
First, a force is applied to the tip portion of the hook portion 13 of the spiral pile 10 to slightly widen the gap between the tip portion and the root portion of the hook portion 13. Next, the spiral pile 10 is held substantially at right angles to the pipe 20, the tip of the hook portion 13 of the spiral pile 10 is passed through the holes 29 and 28 of the pipe 20 in order, and then the pipe 20 is fixed to the spiral pile 10. The pipe 20 and the spiral pile 10 so that they are substantially coaxial with each other. Next, similarly to the first embodiment, an axis-aligning pipe 30 having an inner diameter capable of accommodating the spiral portion 11 of the spiral pile 10 with substantially no space is prepared, and the axis-aligning pipe 30 is welded. Stand on the floor or the table installed on the floor at the place where Next, the spiral portion 11 of the spiral pile 10 is inserted into the shaft-aligning pipe 30. If necessary, thereafter, a force is applied to the tip portion of the hook portion 13 of the spiral pile 10 to restore the gap between the tip portion and the root portion of the hook portion 13 to the original state.

  Next, the boundary portion between the hook portion 13 of the spiral pile 10 and the pipe 20 (for example, the boundary portion between the holes 28 and 29 of the pipe 20 and the hook portion 13, the cutouts 21 and 22 of the pipe 20 and the hook portion 13). The boundary) is welded to integrate the spiral pile 10 and the pipe 20. If necessary, the tip portion of the hook portion 13 and the root portion are also welded. After that, the spiral portion 11 of the spiral pile 10 is pulled out from the axising pipe 30.

  As described above, the intended pipe-integrated spiral pile shown in FIGS. 12A, 12B and 12C can be manufactured.

[How to use spiral pile with pipe integrated]
The method of using this pipe-integrated spiral pile is the same as in the first embodiment.

  According to the third embodiment, in addition to the same advantages as the first embodiment, the following advantages can be obtained. That is, depending on the application of the pipe-integrated spiral pile, it is necessary to use, as the pipe 20, a commercially available pipe having an outer diameter much smaller than the outer diameter of the spiral pile 10, for example, a pipe having an outer diameter of 25.4 mm or 22.2 mm. On the other hand, since the size of the commercially available spiral pile is limited, there is a case where the spiral pile 10 having an outer diameter much larger than that of the pipe 20 has to be used. However, the third embodiment According to this, such a case can be easily dealt with.

<4. Fourth Embodiment>
[Pipe House]
FIG. 13 shows a pipe house (a vinyl house) according to the fourth embodiment. This pipe house has a rectangular plan shape as a whole and is a single roof. As shown in FIG. 13, in this pipe house, the pipe-integrated spiral pile 100 according to the first, second or third embodiment surrounds the outer periphery of the rectangular installation area of the pipe house as the foundation pile. It is screwed into the ground 50. A support pipe 71 is connected to the pipe 20 of each pipe-integrated spiral pile 100. As the support pipe 71, for example, a scaffolding single pipe can be used. The pipe 20 and the strut pipe 71 may be connected by using a single pipe joint, or the strut pipe 71 having an inner diameter that allows the pipe 20 to be inserted into the strut pipe 71 without a gap, and then fitted into the pipe 20. But it's okay. The length of the pillar pipe 71 is the longest in the front and gradually becomes shorter toward the back so that a single roof can be formed. A joist pipe 72 is stretched over the long side of the installation area of the pipe house. Both ends of the joist pipe 72 are fixed to the base of the pipe 20 of the pipe-integrated spiral pile 100 with a wire or metal fitting. A horizontal pipe 73 is stretched at a height position midway of the pillar pipe 71 so as to surround the installation area of the pipe house. The horizontal pipe 73 and the support pipe 71 are fixed by a numbered wire or a metal fitting. A rafter pipe 74 is stretched over the upper end of the pillar pipe 71 in the short side direction of the installation area of the pipe house. A counter reinforcement pipe 75 is stretched between the rafter pipe 74 and the support pipe 71 stretched over the center of the installation area of the pipe house. Although illustration is omitted, a transparent film is stretched by using a film fastening material on the skeleton including the support pipe 71, joist pipe 72, lateral pipe 73, and rafter pipe 74 thus formed. Although not shown, the transparent film is provided with a doorway for people to enter and leave.

[Construction method of pipe house]
As shown in FIG. 14, first, the pipe-integrated spiral pile 100 is screwed into the ground 50 so as to surround the rectangular installation region of the pipe house. Next, the support pipe 71 is connected to the pipe 20 of the pipe-integrated spiral pile 100, and the joist pipe 72, the lateral pipe 73, the rafter pipe 74, and the stiffener reinforcing pipe 75 are stretched in order. After that, a transparent film is stretched on the skeleton including the support pipe 71, joist pipe 72, lateral pipe 73, and rafter pipe 74 using a film fastening material. In this way, the target pipe house shown in FIG. 13 can be constructed.

  According to the fourth embodiment, the pipe house can be installed on the ground at low cost easily and in a short time by using the pipe integrated spiral pile 100 according to the first, second or third embodiment. You can get the advantage that you can.

  The embodiments and examples of the invention have been specifically described above, but the invention is not limited to the above-described embodiments and examples, and various modifications based on the technical idea of the invention. Is possible.

  For example, the numerical values, shapes, structures, etc. described in the above-described embodiments and examples are merely examples, and different numerical values, shapes, structures, etc. may be used as necessary.

  10 ... Helical pile, 11 ... Helical part, 12 ... Straight part, 13 ... Hook part, 20, 40 ... Pipe, 21, 22, 26, 27 ... Notch, 23, 24, 28, 29 ... Hole, 25 ... Welding Part, 30 ... Pipe for centering, 50 ... Ground, 60 ... Pipe with side plate, 61 ... Side plate, 71 ... Strut pipe, 72 ... Joist pipe, 73 ... Horizontal pipe, 74 ... Rafter pipe, 5 ... Direction reinforcing pipe, 100… pipe integrated spiral pile

Claims (4)

Steel spiral pile consisting of spiral part, straight part and hook part,
The hook portion of the spiral pile has a steel pipe coaxially fixed to the spiral pile,
The hook portion of the spiral pile is passed through a pair of notches or holes provided at positions opposite to each other with respect to the central axis of the pipe on the side surface of the one end portion of the pipe, and the pipe and the hook portion. A pipe-integrated spiral pile whose boundary is welded.   On the side surface of the other end of the pipe, a pair of holes or notches through which a rod for rotation is passed when screwing the pipe-integrated spiral pile are provided at positions opposite to each other with respect to the central axis of the pipe. The spiral pile integrated with pipe according to claim 1. Steel spiral pile consisting of spiral part, straight part and hook part,
The hook portion of the spiral pile has a steel pipe coaxially fixed to the spiral pile,
The hook portion of the spiral pile is passed through a pair of notches or holes provided at positions opposite to each other with respect to the central axis of the pipe on the side surface of the one end portion of the pipe, and the pipe and the hook portion. A method for manufacturing a pipe-integrated spiral pile, in which the boundary part of is welded,
A step of preparing the spiral pile and the pipe, and inserting the spiral portion of the spiral pile into an axis-aligning pipe capable of accommodating the spiral portion of the spiral pile with almost no gap;
Passing the hook portion of the spiral pile through the pair of notches or holes of the pipe, and holding the shaft for pipe and the pipe coaxially,
A method for manufacturing a pipe-integrated spiral pile, comprising a step of welding a boundary portion between the pipe and the hook portion. A structure installed by screwing a plurality of spiral piles onto the ground,
At least one of the above spiral piles,
Steel spiral pile consisting of spiral part, straight part and hook part,
The hook portion of the spiral pile has a steel pipe coaxially fixed to the spiral pile,
The hook portion of the spiral pile is passed through a pair of notches or holes provided at positions opposite to each other with respect to the central axis of the pipe on the side surface of the one end portion of the pipe, and the pipe and the hook portion. A structure that is a pipe-integrated spiral pile in which the boundary part of is welded.