JP2017210859A - Pile - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a pile that can be easily buried in an installation surface and has high workability.SOLUTION: A steel pipe pile 20 is fixed so that blades 40 are rotated around a diameter of a virtual horizontal cut surface of a main body 30, at a predetermined angle in opposite directions to each other in a direction in which a diameter of the blade 40 is orthogonal to the axis. When the steel pipe pile 20 is rotated and buried, a progress direction side of a pair of blades 40 disposed on both sides simultaneously drills the installation surface, thus the steel pipe pile 20 does not incline. A pair of column members 32 disposed on a tip side are buried in the installation surface in advance, and the steel pipe pile 20 is installed at a desired position and desired angle.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a pile.

  Conventionally, various types of piles are known as piles used by being screwed into the ground or the like as a foundation. For example, Patent Document 1 discloses a circular hollow main body part and a first bottom expansion plate provided on the bottom surface of the main body part, and has a first inclination angle with respect to a horizontal plane perpendicular to the axis of the main body part. A fan-shaped first bottom widening plate, a second bottom widening plate provided on the bottom surface of the main body, and a fan-shaped second bottom widening plate having a second inclination angle different from the first inclination angle; The steel pipe pile provided with the opening part provided between a board and a 2nd bottom expansion board is described. By carrying out like this, it is a steel pipe pile which has an expanded bottom part which has sufficient support power, Comprising: A steel pipe pile which can be manufactured easily and penetrates into the ground efficiently can be provided.

JP 2009-138487 A

  However, in such a steel pipe pile, since the excavation claw is located between the first bottom expansion plate and the second bottom expansion plate, the overall shape of the ground of the first bottom expansion plate and the second bottom expansion plate becomes an elliptical shape. When rotating and embedding into the ground, the problem is that the shaft when rotated is more likely to shake than when it is circular, the stability when embedding in the ground is low, and the workability is poor There is.

  This invention is made | formed in view of such a subject, and when it penetrates, it aims at providing a pile with high workability and high reliability by improving stability.

  The present invention adopts the following means in order to achieve the main object described above.

The pile of the present invention is
A pile that penetrates the ground from one end,
A cylindrical main body with the one end side open;
A pair of blades fixed in a state where a part is inserted in a groove provided on a side surface of the main body,
A pair of pillar members respectively fixed to the blade and the inner side surface of the main body and projecting toward the one end side;
With
The pair of blades is rotated by a predetermined angle in the opposite direction in the direction perpendicular to the axis, with the diameter of the virtual cutting surface that horizontally cuts the main body as the axis. Each is fixed,
Is.

  In this pile, the slats are fixed in a state where the diameters of the slats are rotated by a predetermined angle in the opposite direction in the direction perpendicular to the axis, with the diameter of the virtual cutting plane that horizontally cuts the main body part as the axis Has been. By doing so, the pair of slats are fixed in a state where they are inclined at the same angle in opposite directions with the main body portion interposed therebetween. In other words, it can be said that the blades are arranged in a positional relationship in which the upper surface sides of each other cross each other. For this reason, when the pile is rotated vertically and embedded, the lower part of the pair of first blades provided on both sides simultaneously excavates the installation surface, so the pile is easily embedded vertically. can do. Also, since a pair of pillar members are provided on the tip side, when the pile is embedded, the angle of the pile changes with respect to the installation surface, or the pile moves on the surface of the installation surface and the installation position Can be reduced in advance. At this time, since the front end side of the column member is located in the front end side direction of the main body part rather than the front end side of the slats, when the pile is rotated and penetrated, the pair of column members first rotate, The soil near the center is excavated, and then the pile body and blades are buried in the ground in order. At this time, since the soil in the vicinity of the center portion of the pile is excavated by the rotation of the pair of column members, the force applied from the soil to the main body portion can be reduced when the main body portion is penetrated. In addition, when the pair of slats rotate and penetrates into the soil, the slats are embedded in the soil from the center already softened by the pillar member, so the force applied to the slats from the soil is also reduced. can do. That is, when the pile is penetrated, the force applied from the soil to the main body part and the slats can be reduced, so that the workability is high. The possibility that the pile cannot penetrate vertically can be reduced.

  In the pile of the present invention, the position on the most end side of the pair of column members, the position on the one end side of the main body portion, and the position on the most end side of the pair of blade plates are located on the most end side of the pair of column members. The position may be in the order of the position, the position on one end side of the main body, and the position on the most end side of the pair of blades. By doing so, when the pile is rotated and embedded, it is embedded in the soil in the order of the pair of column members, the main body, and the pair of blades. When entering, the slats are buried in a softened state by excavation by rotation of a pair of column members, the slats are bent by hard soil, and the digging force by the slats is attenuated The possibility of doing this can be reduced in advance. In other words, the workability intended at the time of design can be maintained by preventing the blades from being bent.

  In the pile of the present invention, the pair of column members may be fixed to the inner side surface of the side surface of the main body portion. In this way, in addition to the case where the column member is fixed to the outer side surface of the side surface of the main body portion, in addition to the fixed portion where the main body portion and the column member are fixed when penetrating into the ground. Since the applied force can be reduced, the possibility that the column member is detached from the main body portion can be reduced in advance.

  In the pile according to the present invention, the pair of column members may be provided at a position that contacts both the surface of one blade plate and the side surface of the other blade plate, of the pair of blade plates. . By doing so, when penetrating the column member into the ground, the column member is supported by two surfaces of the surface of one blade plate and the side surface of the other blade plate, and therefore can be supported by only one of them. Compared with the case, the possibility that the column member is detached can be reduced in advance. Also, when digging the soil with the pillar member by rotating it, even if a large force is applied to the pillar member, it is supported by the two surfaces of the surface of one blade plate and the side surface of the other blade plate. In addition, since the possibility of the pillar member being deformed is reduced, the rotational force can be used for the force that the pillar member digs up.

  The column member has a connection recess that is thicker than the thickness of the side surface of the main body, and the column member is brought into contact with the vane plate and the main body by bringing the inner surface of the main body into contact with the connection recess. It may be fixed. In this way, when fixing the column member, since the front side surface and the inner side surface of the main body portion can be fixed to the connection recess, the column member is compared with the case without the connection recess. It can be fixed more firmly. The pile of this invention which employ | adopted this aspect WHEREIN: When the said column member is fixed to the said main-body part, the outer side surface of the said column member may be located outside the outer side surface of the said main-body part. As a result, a part of the column member is located outside the main body, so that when the body is rotated and penetrates into the ground, the main body is buried in the portion excavated by the rotation of the column member. Therefore, the force applied from the soil to the main body can be reduced, and the possibility that the main body is deformed or damaged can be reduced. Moreover, when embedding a main-body part, since the power to embed can be reduced, it has high workability.

  In the pile according to the present invention, the linear side surfaces of the pair of blades may have inclined surfaces. This makes it possible to increase the excavation force of the slats when penetrating into the ground as compared with the case where the straight side faces are perpendicular to the surface of the slats. When performing, high workability can be obtained. In addition, the whole linear side surface may be an inclined surface, and a part may be an inclined surface. By making a part into an inclined surface, the intensity | strength and excavation force of a slat can be kept in a high state.

  In the pile of the present invention, the surface on one end side of the column member may have an inclined surface. By carrying out like this, compared with the case where the surface of one end side does not have an inclined surface, when it embeds in the ground, high workability can be obtained.

FIG. 1 is a front view showing an outline of the configuration of the steel pipe pile 20. FIG. 2 is a side view schematically showing the configuration of the steel pipe pile 20. FIG. 3 is an AA cross-sectional view. FIG. 4 is a cross-sectional view taken along the line BB. FIG. 5A is a plan view schematically showing the configuration of the blade plate 40, and FIG. 5B is a bottom view showing a state in which the blade plate 40 is attached to the steel pipe pile 20. FIG. 6 is an explanatory diagram for explaining a method for embedding the steel pipe pile 20, FIG. 6 (A) shows a state before embedding the steel pipe pile 20, and FIG. 6 (B) shows a vane plate 40. FIG. 6 (C) shows a state where the steel pipe pile 20 is buried, respectively, in a state where is in contact with the installation surface. FIG. 7A is a plan view schematically showing the configuration of the blade plate 40 of the second embodiment, and FIG. 7B shows a state where the blade plate 40 of the second embodiment is attached to the steel pipe pile 20. It is a bottom view shown. FIG. 8A is a plan view showing an outline of the configuration of the blade plate 140 of the third embodiment, and FIG. 8B shows a state in which the blade plate 140 of the third embodiment is attached to the steel pipe pile 20. It is a bottom view shown.

  Next, the structure of the steel pipe pile 20 which is an example of embodiment of the pile of this invention is demonstrated in detail using FIGS. 1-4. Here, FIG. 1 is a front view illustrating the outline of the configuration of the steel pipe pile 20, FIG. 2 is a side view illustrating the outline of the configuration of the steel pipe pile 20, and FIG. 3 is a cross-sectional view taken along line AA. 4 is a cross-sectional view taken along the line BB. The steel pipe pile 20 which is an example of embodiment of this invention is provided with the cylindrical main-body part 30 and the blade board 40 (blade board 40a and blade board 40b) each provided in the side surface of the main-body part 30. Yes.

  As shown in FIG. 1, the main body 30 is a steel tubular member, and at one end side (the lower side in FIG. 1, the traveling direction side when penetrating into the installation surface), at one end side. A pair of protruding column members 32 a and column members 32 b (hereinafter also referred to as “column members 32”) are provided. The column member 32 a is fixed to one end side of the main body 30, the inner surface of the main body 30, the surface of the blade plate 40 a, and the side surface of the blade plate 40 b, and the column member 32 b is one end of the main body unit 30. It is fixed to the inner side surface of the main body 30, the surface of the blade plate 40b, and the side surface of the blade plate 40a (see FIG. 3). For this reason, when the steel pipe pile 20 is rotated and embedded in the installation surface, the column member 32 also rotates with the rotation of the steel pipe pile 20, and the installation surface is excavated around the rotation axis of the main body 30. By carrying out like this, the steel pipe pile 20 can be embedded easily.

  Here, the column member 32 will be described in more detail. As shown in FIGS. 1 and 2, the column member 32 has a shape in which one end side of a substantially rectangular column is obliquely cut, and has a connection recess 33 in which a part is recessed as shown in FIG. 4. ing. In other words, the column member 32 is a member having a substantially pentagonal appearance having the connection recess 33. Since the connection recess 33 has a protrusion larger than the thickness of the side wall of the main body 30, when the connection recess 33 is closely attached to the side surface of the main body 30 and fixed, the column member 32 has a larger height than the outer surface of the main body 30. It will be fixed in the state where a part protrudes outside. For this reason, when the main body 30 is embedded in the soil while rotating, the pillar member 32 excavates the outside of the main body 30, so that the main body 30 does not directly hit the hard soil and is embedded in the soil. can do. In other words, it has high workability. Thus, by providing the connection recess 33, the column member 32 and the main body 30 are adjacent to each other and the area that can be welded increases as compared with the case where the connection recess 33 is not provided. The main body 30 can be more firmly fixed. In other words, when the steel pipe pile 20 is rotated and embedded, the possibility that the column member 32 is detached from the main body 30 during soil excavation can be reduced in advance, and the rotational force of the steel pipe pile 20 is efficiently excavated. Can be used well.

  As shown in FIG. 5, the vane plate 40 is a steel plate-like member having a substantially semicircular shape with the central portion removed in a substantially semicircular shape, all having the same shape, and partly cut away. This is a fan-shaped member in a state (see FIG. 5A). This vane plate 40 is a plate member made of steel, and a semicircle having a diameter smaller than the outer diameter of the main body 30 is cut out at a position corresponding to the radius of the semicircle, and is fixed to the main body 30. Even when it is done, one end side of the steel pipe pile 20 is in a released state. Furthermore, since a part of the surface of the blade plate 40 appears also inside the main body portion 30, the pillar member 32 can be attached to the surface of the blade plate 40 inside the main body portion 30. This blade 40 is attached to one end side of the main body 30 by being welded to the main body 30 in a state where a part thereof is inserted into the groove 34 provided on the side surface of the main body 30 (see FIG. 3). . By doing so, even if a force from the soil is applied to the slats 40 at the time of embedding, by inserting a part into the groove 34 of the main body 30, the slats 40 can be curved at the time of embedding. The possibility of falling off the main body 30 can be reduced in advance. Moreover, by inserting the groove portion 34, it is possible to reduce the possibility that the attachment position and attachment angle of the blade plate 40 become unintended positions and angles during welding, as compared with the case where the groove portion 34 is not provided. . At this time, the vane plate 40 is attached to the virtual cross section that horizontally cuts the main body 30 with the vane plate 40a tilted by about 15 ° and the vane plate 40b inclined by −15 ° about the virtual cross section. ing. Further, as shown in FIG. 1, an inclined surface 42 inclined by about 45 ° is provided on the upper side of the linear side surface corresponding to the radius of the semicircle of the blade plate 40.

  Further, each of the substantially semicircular fan-shaped blade plate 40a and blade plate 40b is welded in a state where a part thereof is inserted into the groove portion 34 on the opposite side across the main body portion 30, and is shown in FIG. 5B. Thus, when viewed from the front end side, the rough shape appears to be circular due to the blade 40a and the blade 40b. At this time, the vane plate 40a and the vane plate 40b have a substantially semicircular shape with one of them cut out, and are provided on the opposite side of the main body 30, so there is no position where the vane plate 40a and the vane plate 40b overlap. By carrying out like this, even if it is a case where an upward force is applied with respect to the steel pipe pile 20 after installing the steel pipe pile 20 in the ground etc., the force from the ground is evenly applied to the upper surface side of the vane plate 40. Thus, the possibility that the steel pipe pile 20 rotates can be reduced in advance. In other words, the embedding is easy due to the notch passing through the soil at the time of embedding due to the notch, but is difficult to remove after embedding.

  Here, the positional relationship between the position on the most end side of the blade plate 40, the position on the one end side of the main body 30 and the position on the most end side of the column member 32 will be described in detail. As shown in FIG. 2, the position on the most end side of the vane plate 40 and the position on the one end side of the main body 30, the position on the most end side of the column member 32 are the position on the most end side of the column member 32, Are fixed so as to be in a positional relationship in the order of the position on the one end side and the position on the most end side of the blade plate 40. For this reason, when the steel pipe pile 20 is rotated and embedded, first, one end side of the column member 32 is rotated to excavate the soil, and then the main body 30 is embedded in the soil, and the blade 40 Will rotate and excavate the soil. In this way, the column member 32 first rotates with the smallest radius of rotation to excavate the ground, so that even in hard soil, the center portion is excavated by the column member 32, and the vane plate 40 is bent or damaged. The possibility of doing so can be reduced. At this time, since the outer side of the column member 32 is located outside the outer surface of the main body 30, the rotating column member 32 excavates soil in the vicinity of the main body 30, so that the main body 30 is smoothly embedded. be able to. In addition, the blade 40 that will excavate a wider area than the column member 32 is embedded in the soil with the latest delay, and the blade 40 can be bent or damaged. Can be greatly reduced.

  Then, the embedding method which embeds the steel pipe pile 20 in the ground is demonstrated using FIG. FIG. 6 is a schematic view schematically showing a method of embedding the steel pipe pile 20 in the ground. When embedding the steel pipe pile 20 in the ground, a flange (not shown) is attached to the other end side (the upper side in FIG. 6) of the steel pipe pile 20, and this flange is fixed to a heavy machine and rotated to thereby rotate the steel pipe pile. 20 is rotated and embedded in the ground (see FIG. 6A).

  Along with the rotation of the steel pipe pile 20, the column member 32 located on one end side (tip on the traveling direction side) of the steel pipe pile 20 rotates and excavates the ground. The soil softened by the rotation of the column member 32 is introduced into the steel pipe pile 20 on the cylinder as the steel pipe pile 20 is embedded.

  Subsequently, the blade 40 provided on one end side of the main body 30 also excavates the ground around the main body 30 as the steel pipe pile 20 rotates (see FIG. 6B). At this time, the blades 40 are attached to the same position at the same angle (for example, 15 °) in the one end side direction and the other end side direction with respect to the vertical cross section of the main body portion 30 respectively. The positions of the lowermost end portion of the blade plate 40a and the lowermost end portion of the blade plate 40b are located on a plane parallel to the vertical cross section of the main body portion 30 (position of a broken line C in FIG. 6A). By rotating the steel pipe pile 20 in this state, the side surface direction can be excavated uniformly, so that the steel pipe pile 20 can be embedded vertically without being inclined with respect to the ground.

  According to the steel pipe pile 20 of the present embodiment described in detail above, the diameter of the blade plate 40 is in a direction perpendicular to the axis, with the diameter of the virtual cutting surface where the blade plate 40 cuts the main body portion 30 horizontally as an axis. Since each of the blades 40 is fixed while being rotated by a predetermined angle in the opposite direction, the pair of blades 40 are fixed in a state where they are inclined at the same angle in opposite directions with the main body 30 interposed therebetween. By doing so, when the steel pipe pile 20 is rotated and embedded, the traveling direction side of the pair of blades provided on both sides simultaneously excavates the installation surface, so that the steel pipe pile 20 does not tilt. It can be easily embedded vertically and has high workability. At this time, since a pair of column members 32 are provided on the tip side, when this column member 32 is installed, it is easily embedded at a desired position and a desired angle by being embedded in the installation surface in advance. Can increase the sex. In addition, when the steel pipe pile 20 is rotated and embedded, since the column member 32 positioned closest to the traveling direction side excavates the soil first, the soil is excavated by the rotation of the column member 32, The labor when the main body 30 is embedded can be reduced. In addition, when the pair of slats 40 rotate and penetrate into the soil, the slats 40 are embedded in the soil from the central portion that has already been softened by the pillar member 32. Therefore, the force applied can be reduced. In addition, since the blade plate 40 has a partially cut-out shape, when the steel pipe pile 20 is embedded in the ground, the soil can pass through the cut-out portion. Unnecessary soil can be released. That is, when the steel pipe pile 20 is penetrated, the force applied from the soil to the main body 30 and the blade plate 40 can be reduced, so that the workability is high, and the possibility of being inclined and embedded when embeding is provided. It can be reduced in advance.

  Further, since the pair of column members 32 are fixed to the inner side surface of the side surface of the main body 30, when penetrating into the ground, compared to the case of being fixed to the outer side surface of the side surface of the main body 30, The possibility that the column member 32 is detached from the main body 30 by the force from the soil can be reduced in advance.

  Furthermore, since the column member 32 is provided at a position that contacts both the surface of the one blade plate 40 and the side surface of the other blade plate 40 in addition to the inside of the side surface of the main body 30, it penetrates into the ground. In this case, the force applied from the soil to the column member 32 is supported by either the surface of one blade plate 40 or the side surface of the other blade plate 40, and the force applied from the soil to the column member 32 is a steel pipe pile. Therefore, the possibility that the column member 32 is deformed or detached can be reduced. Further, when the steel pipe pile 20 is rotated, since a straight force is applied to the column member 32 from the side surface of the other vane plate 40, the rotation force can be effectively used as a force that the column member 32 digs up. .

  Furthermore, the column member 32 is provided with a connection recess 33 that is thicker than the thickness of the side surface of the main body 30, and this connection recess 33 is fixed in contact with the inner side surface of the main body 30. The column member 32 is fixed by the surface of the blade plate 40 and the inner side surface of the main body 30. By doing so, the pillar member 32 is firmly fixed, and the possibility that the pillar member 32 falls off can be reduced in advance.

  At this time, since a part of the column member 32 is located outside the outer surface of the main body 30, when the column member 32 rotates and penetrates into the ground, the column member 32 rotates to the portion excavated by the rotation. Since the main body 30 is embedded, the force applied from the soil to the main body 30 can be reduced, and the possibility that the main body 30 is deformed or damaged can be reduced. In addition, since the column member 32 is directly applied with the rotational force when the main body 30 rotates from the side surface of the other blade plate 40, the force around the main body 30 is excavated using the rotational force of the main body 30. can do. For this reason, since the rotational force at the time of embedding a main-body part can be utilized efficiently, it has high workability.

  And since the inclined surface 42 is formed in the upper part of the linear side surface of a pair of blade board 40, when the blade board 40 rotates at the time of embedding, the blade board 40 rotates with an inclined surface. Thus, the resistance during excavation can be reduced, and the steel pipe pile 20 can be embedded with less labor.

  And since the inclined surface is provided in the one end surface of the column member 32, when embedding the steel pipe pile 20, it is excavated by the one end surface of the column member 32, and the steel tube pile 20 can be embedded with little effort. it can.

  It should be noted that the present invention is not limited to the above-described embodiment, and it goes without saying that the present invention can be implemented in various modes as long as it belongs to the technical scope of the present invention.

  For example, in the above-described embodiment, the substantially semicircular blade plate 40 partially cut away is used. However, as shown in FIG. By doing so, even if a force is applied upward after being buried in the ground, the vane plate 40 is located entirely when viewed from the vertical direction, so that it is difficult to come off.

  In the above-described embodiment, at least a part of the column member 32 protrudes outward from the outer surface of the main body 30. However, even if the column member 32 is located on the same surface as the outer surface of the main body 30. It may be inside the outer surface of the main body 30. In any case, the same effect as the above-described embodiment can be obtained.

  In the above-described embodiment, the substantially semicircular blade plate 40 is used. However, as shown in FIG. 8A, the substantially fan-shaped blade plate is partially cut out as compared to the substantially semicircular shape. 140 may be used. At this time, when fixing the blade plate 140 to the main body 30, as shown in FIG. 8B, the part lacking compared to the substantially semicircular shape is positioned on one end side (the traveling direction side during embedding). In this manner, the blade plate 140 may be fixed. By carrying out like this, since the soil pushed away when embedding the steel pipe pile 20 can pass between a pair of blades 140, and the case where the blade plate 40 of substantially semicircular shape is used. In comparison, it is possible to reduce the possibility that the blades 140 are curved and to reduce the force required for embedding. In other words, high workability can be obtained as compared with the substantially semicircular blade plate 40.

  Here, the difference between the blade 40 and the blade 140 will be described. The vane plate 40 and the vane plate 140 are different from each other in a portion lacking when compared with a substantially semicircular shape. As shown in FIG. 8A, the vane plate 140 has a portion lacking in a straight line from the inner side surface to the outer side surface, but in the vane plate 40, as shown in FIG. 5A, a straight line shape from the inner side surface to the outer side surface. The side of is a state in which a part is bent. As shown in FIG. 5B, the vane plate 40 is bent at a position where it comes into contact with the outer surface of the main body 30 when attached to the main body 30. By doing so, when attaching the column member 32, it can be fixed at the same position as in the above-described embodiment. In addition, when attaching the column member 32, as shown to FIG. 5B, you may attach to the position which protrudes rather than a linear side surface. By carrying out like this, since the pillar member 32 will be located in the front side of a rotation direction when rotating and embedding the steel pipe pile 20, the force applied to the blade board 40 from soil can be reduced. By doing so, it is possible to reduce the possibility that the blade plate 40 is curved or the straight side surface of the blade plate 40 is damaged. Moreover, since parts other than the shape of the blade plate 240 are the same as those of the above-described embodiment, the same reference numerals are given, and description thereof is omitted here.

  In the above-described embodiment, the pair of blades 40 are inclined on the side surfaces of the main body 30 in opposite directions by 15 ° with respect to the horizontal cross section of the main body 30, but this angle is limited to 15 °. It may be an angle of 5 ° or more and less than 30 °, or an angle of 15 ° or more and less than 20 °. By increasing the angle at which the vane plate 40 is tilted, the force that the vane plate 40 receives from the soil when it is pulled out increases, so the resistance to the pulling force increases, but the load on the welded portion between the main body 30 and the vane plate 40 is increased. Therefore, the angle at which the vane plate 40 is tilted can be appropriately determined in consideration of the strength of the vane plate 40, the state of the soil, and the expected pulling force.

  As shown in the above-described embodiments, the pile can be used as a foundation pile for embedding in the ground, particularly when building a building.

  DESCRIPTION OF SYMBOLS 20 ... Steel pipe pile, 30 ... Main-body part, 32 ... Column member, 32a ... Column member, 32b ... Column member, 33 ... Connection recessed part, 34 ... Groove part, 40 ... Blade, 40a ... Blade, 40b ... Blade, 42 ... inclined surface, 140 ... slats.

Claims (8)

A pile that penetrates the ground from one end,
A cylindrical main body with the one end side open;
A pair of blades fixed in a state where a part is inserted in a groove provided on a side surface of the main body,
A pair of pillar members respectively fixed to the blade and the inner side surface of the main body and projecting toward the one end side;
With
The pair of blades is rotated by a predetermined angle in the opposite direction in the direction perpendicular to the axis, with the diameter of the virtual cutting surface that horizontally cuts the main body as the axis. Each is fixed,
Pile. The position of the one end side of the pair of column members, the position of the one end side of the main body portion, and the position of the one end side of the pair of blade plates are the positions of the one end side of the pair of column members, It is located in the order of the position on one end side and the position on the most end side of the pair of blades,
The pile according to claim 1. The pair of column members are fixed to the inner side surface of the side surface of the main body,
The pile according to claim 1 or 2. The pair of column members is provided at a position in contact with both the surface of one blade plate and the side surface of the other blade plate among the pair of blade plates,
The pile according to any one of claims 1 to 3. The column member has a connection recess that is thicker than the thickness of the side surface of the main body,
The column member is fixed to the blade plate and the main body part by bringing the inner surface of the main body part into contact with the connection recess,
The pile according to any one of claims 1 to 4. When the column member is fixed to the main body, the outer side surface of the column member is located outside the outer side surface of the main body.
The pile according to claim 5. The linear side surfaces of the pair of blades have an inclined surface,
The pile according to any one of claims 1 to 6. The one end side surface of the column member has an inclined surface,
The pile according to any one of claims 1 to 7.

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