JP2014031700A - Base structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a base structure which enables elimination of bulkiness, improved stability at the time of being placed and weight saving so as to achieve improved handleability and cost reduction and to hardly cause frost heave problem; and to provide the base structure which has little possibility of destruction due to moisture freezing.SOLUTION: In a base structure at an angle relative to the height direction and extending in a different direction without interfering with each other, one end opens around the central part of one side of the hight direction while the other end is provided with two or more of through-holes opening to the other side of the height direction, and piles inserted and fitted in the through-holes are driven into the ground so that the base structure is established in the ground. The base structure 10 is provided with a body 10a shaped like an inverted cup so as to create inside an internal space 13 opening to the other side of the height direction, and a plurality of cylindrical bodies 10b cylindrically shaped and penetrated through the body so as to create the through-holes 12 with inside holes, at the circumferential part of the body.

Description

  The present invention belongs to the technical field of the foundation of a structure, and relates to a foundation structure installed on land by driving piles inserted into through holes into the ground.

  Patent Document 1 discloses a simple basis. This is a simple metal base for supporting the supported body, and one or more driven piles to be driven in an inclined state in the soil, and the driven pile are inserted, and the supported body is attached at the top. And a support portion having a mounting bracket for mounting, the support portion is a hollow substantially spherical shape or a substantially elliptical spherical shape, is placed so that the lower portion of the support portion is in contact with the ground, the driven pile is It inserts in the part inclined in the hook shape toward the part in which the said driving pile is inserted from the part which attaches the said to-be-supported body. Patent document 2 also discloses this type of simple basis. Patent document 3 is disclosing what filled the inside of the said support part of this kind of simple foundation.

Japanese Patent No. 4335958 JP 2007-247249 A US Pat. No. 5,039,256

  Since such a support portion is formed in a substantially spherical shape or a substantially elliptical spherical shape, it is bulky and has poor stability when placed on a flat surface.For example, during storage, transportation, etc. For example, they are forced to be housed in a dedicated pallet. Therefore, there is a problem that it takes time and cost. Moreover, the said support part which filled concrete inside like the said patent document 3 becomes heavy, for example, there exists a problem that handling property is not good at the time of storage, conveyance, etc., and cost starts.

  In addition, when the support part is constructed on a land that may be cold, the land may be frosted during the cold, which may cause a so-called frost heaving problem that the support part is pushed up. The problem arises that the position of the part is not stable. Further, when the support portion is constructed on a land that may be cold, the support portion in which concrete is filled as in Patent Document 3, the fine cracks formed on the concrete surface are used. The water sucked from the water freezes, and the concrete may be destroyed by repeating it. This is also called freeze-thawing.

  The present invention has been made paying attention to such points, the purpose of which belongs to the field of the conventional support part, for example, at least partly embedded in the ground, placed on the ground, An internal space that is open to the land side is formed inside the foundation structure that is installed on the ground by driving piles that are placed near the ground, such as floating from the land, and inserted into the through holes into the ground. In order to eliminate the bulkiness and improve the stability when placed on a flat surface, it is possible to further reduce the weight. It is possible to improve handling and reduce costs without necessarily having to be housed in a dedicated pallet etc. at times, etc., and when it is constructed on land that may be cold, it will be held by frost. The Therefore soil to provide a substructure comprising the heaving problem tends not be introduced into the internal space. Furthermore, as an example of the above-mentioned foundation structure, it is proposed to form it with, for example, metal, and even when it is constructed on land that may be cold, the above conventional support part filled with concrete is used. It is another object of the present invention to provide a foundation structure that is less likely to break due to freezing of the sucked moisture.

In order to achieve the above object, the first substructure of the present invention is:
An angle with respect to the height direction and extending in different directions without interfering with each other, with one end opening around the central portion on one side of the height direction and the other end opening on the other side of the height direction. In the foundation structure provided in the land by providing the above through holes and driving piles inserted into the through holes into the ground, the foundation structure is
A body formed in a saddle shape so that an internal space opened to the other side in the height direction is formed inside,
A plurality of cylinders that are formed in a cylindrical shape and are provided so as to penetrate the main body around the main body so that the through hole is formed by an internal hole.

  For example, at least a part of the foundation structure is embedded in the ground, placed on the ground, or floated from the ground, and each of the foundation structures is disposed near the ground, and the plurality of piles are respectively placed in the through holes of the foundation structure. Insert and drive into the ground to fix the foundation structure to the land. In that case, since the main body is formed in the shape of the laid down so as to form the internal space opened to the other side in the height direction, like the conventional support portion Compared to those formed in a substantially spherical shape or a substantially elliptical spherical shape, the bulkiness of the foundation structure is eliminated, and the stability when the foundation structure is placed on a flat surface is enhanced, Moreover, there is a possibility that the weight of the foundation structure will be reduced. Therefore, for example, when the foundation structure is stored or transported, it is not always necessary to house the foundation structure on a dedicated pallet, for example, and the handleability is improved, and cost reduction is realized. In addition, when the foundation structure is constructed on a land that may be cold, the frost heaving problem is less likely to occur by introducing soil lifted by frost into the internal space. Further, when the foundation structure is formed so that the internal space includes the one side portion in the height direction of the foundation structure, when the two foundation structures are stacked in the same direction, Since the above-mentioned foundation structure is stored in the internal space of the other foundation structure, when the plurality of foundation structures are stacked, these foundation structures can be compactly accommodated. If it does so, the handleability of the said foundation structure will improve further. In addition, when the foundation structure is formed of a material that does not absorb moisture from the surface, not concrete, or is a material that does not absorb moisture, such as metal or the like, the foundation structure may be cold. Even when it is constructed on land, it is less likely to break due to freezing of the sucked moisture compared to the conventional support portion filled with concrete inside. Furthermore, when the base structure is formed of, for example, a metal or other material that can be processed with higher accuracy than concrete, the gap between the through hole and the pile can be set smaller. After construction of the foundation structure, the gap becomes play and the length of displacement of the foundation structure with respect to the pile is shortened, and the construction accuracy of the foundation structure can be improved. And in order to prevent the said displacement, it is not necessary to lengthen the said through-hole so that the inclination angle with respect to the said through-hole of the said pile may not become large with the said clearance gap. Therefore, it is possible to set the overall length of the through hole, that is, the overall length of the cylindrical body relatively short, and the length of the cylindrical body protruding from the main body can be shortened.

The second substructure of the present invention is the above first substructure,
The foundation structure is made of metal.

  In this way, the foundation structure is made of a metal that is less likely to absorb moisture or does not absorb moisture than concrete, so the foundation structure was constructed on a land that could be cold. Even at times, the risk of breakage due to freezing of the sucked moisture is reduced or eliminated as compared with the above-mentioned conventional support portion filled with concrete. In addition, since the foundation structure is formed of a metal that can have higher processing accuracy than concrete or the like, the gap between the through hole and the pile can be set smaller, and the foundation structure After construction, the gap becomes play and the length of displacement of the foundation structure relative to the pile is shortened, and the construction accuracy of the foundation structure is improved. And in order to prevent the said displacement, it is not necessary to lengthen the said through-hole so that the inclination angle with respect to the said through-hole of the said pile may not become large with the said clearance gap. Therefore, it is possible to set the overall length of the through hole, that is, the overall length of the cylindrical body relatively short, and the length of the cylindrical body protruding from the main body can be shortened.

The third substructure of the present invention is the first substructure or the second substructure,
It is a foundation structure in which legs extending to the other side in the height direction are provided at a plurality of locations on the peripheral edge on the other side in the height direction in the main body.

  If it does in this way, the said foundation structure can be temporarily fixed to land by piercing the said leg in land. In that case, since the internal space is provided, the soil is introduced into the internal space as the foundation structure is pushed into the land, and therefore the pushing of the foundation structure into the land is easy. Then, for example, at least part of the foundation structure is embedded in the ground, placed on the ground, or floated from the land, and the like, and each of the plurality of piles is disposed in the through hole of the foundation structure. If each is inserted into the ground and driven into the ground, the foundation structure is fixed to the land.

  Since the first substructure of the present invention is formed in the shape of the above-mentioned hoop so that the internal space opened to the land side is formed inside, the bulkiness is eliminated and the flat surface is formed. Increases stability when placed, and has the potential to further reduce weight, for example, to improve handling without necessarily storing it in a dedicated pallet, for example, during storage, transportation, etc. Providing a foundation structure that can reduce costs and introduces soil that has been lifted by frost into the internal space, making it less likely to cause frost heaving problems when constructed on land that may be cold. We were able to. Moreover, when the said foundation structure is formed so that the said interior space may include the said one side part of the said height direction of the said foundation structure, the handleability of the said foundation structure can further be improved. Further, when the above-mentioned foundation structure is formed of a material that does not absorb moisture from the surface, not concrete, or a material that does not absorb moisture, such as metal or other materials, there is little risk of destruction due to freezing of the sucked moisture. . In addition, when the foundation structure is formed of, for example, a metal or other material that can be processed with higher accuracy than concrete, the construction accuracy of the foundation structure can be improved. In addition, the overall length of the through hole, that is, the overall length of the cylindrical body can be set relatively short, and the length of the cylindrical body protruding from the main body can be shortened.

  According to the second substructure of the present invention, in addition to obtaining the effect obtained by the first substructure, the substructure is further constructed on a land that may be cold. Even when this is done, it is possible to reduce or eliminate the possibility of breakage due to freezing of the sucked water as compared with the above-described conventional support portion filled with concrete. Moreover, the construction accuracy of the foundation structure of the foundation structure can be improved. In addition, it is not necessary to lengthen the through hole, the overall length of the cylinder can be set relatively short, and the length of the cylinder protruding from the main body can be shortened.

  According to the third foundation structure of the present invention, in addition to obtaining the effect obtained by the first or second foundation structure, the base structure is further pierced into the land. Objects can be temporarily attached to the land.

FIG. 1 is a perspective view showing a foundation structure according to a first embodiment of the present invention together with a plurality of piles. The representation of land is omitted. FIG. 2 is a plan view showing the foundation structure of the first embodiment together with a plurality of piles. The representation of land is omitted. FIG. 3 is an enlarged view of a main part of FIG. FIG. 4 is an enlarged plan view of the foundation structure of the first embodiment. FIG. 5 is an enlarged side view of the foundation structure of the first embodiment. A part of the cross section is taken along line V-V in FIG. The surface of the land after construction of the foundation structure is shown by imaginary lines. FIG. 6 is a perspective view showing a completed structure constructed using the foundation structure of the first embodiment. The representation of land is omitted. FIG. 7 is a perspective view showing another completed structure constructed using the foundation structure of the first embodiment. The representation of land is omitted. FIG. 8 is a perspective view showing the foundation structure of the second embodiment of the present invention together with a plurality of piles. The representation of land is omitted. FIG. 9 is a plan view showing the foundation structure of the second embodiment together with a plurality of piles. The representation of land is omitted. FIG. 10 is an enlarged view of a main part of FIG. FIG. 11 is an enlarged plan view of the foundation structure of the second embodiment. FIG. 12 is an enlarged side view of the foundation structure of the second embodiment. A part of the cross section is taken along line XII-XII in FIG. The surface of the land after construction of the foundation structure is shown by imaginary lines. FIG. 13 is a perspective view showing a completed structure constructed using the foundation structure of the second embodiment. The representation of land is omitted. FIG. 14 is a perspective view showing another completed structure constructed using the foundation structure of the second embodiment. The representation of land is omitted.

  1 to 5 show a first embodiment of the foundation structure of the present invention, and FIG. 6 shows one embodiment of a completed structure assembled using the foundation structure. A foundation assembly is constituted by the foundation structure 10 and the plurality of piles 20. The substructure 10 has two or more through holes 12. In the case of this embodiment, the four through holes 12 penetrate, but the number of the through holes may be two or more. Each through hole 12 has one end opened around the central portion 11 on one side of the foundation structure 10 in the height direction, and the other end opened on the other side in the height direction of the foundation structure 10. doing. In FIG. 5, the height direction is the vertical direction in the direction in which the reference numeral looks correct. The height direction includes a vertical direction but may form an angle with the vertical direction. The plurality of through holes 12 are at an angle of more than 0 degree and less than 90 degrees with respect to the height direction. The plurality of through holes 12 extend in different directions without interfering with each other. The through hole 12 is formed straight. In the case of this embodiment, the through hole 12 is formed in a circular shape when viewed in the direction in which the through hole 12 extends. However, the through hole 12 may have, for example, a polygonal shape or other shapes, and the through hole 12 extends. The shape may change along the direction. The foundation structure 10 is disposed near the ground. In this form of arrangement, for example, the foundation structure is arranged so that at least a part of the foundation structure is embedded in the ground, the foundation structure 10 is placed on the ground, and the foundation structure 10 is floated from the land. There are forms such as. In the case of this embodiment, at least the other side in the height direction of the foundation structure 10 is buried in the ground, whereby the foundation structure 10 is arranged near the ground. In FIG. 5, the surface G of the ground, that is, the surface of the land is indicated by imaginary lines, but the position of the surface G of the land with respect to the foundation structure 10 in the drawing is merely an example. The plurality of piles 20 are respectively inserted into the through holes 12 of the foundation structure 10 and driven into the ground.

  The pile 20 is formed straight. In the case of this embodiment, the pile 20 is formed so that the outer shape is circular when viewed in the extending direction of the pile 20 corresponding to the through hole 12. For example, the outer shape is polygonal or other It may be formed in a shape, and the outer shape may change along the direction in which the pile 20 extends. The pile 20 is made of steel, but may be formed of, for example, another metal, synthetic resin, or other material. In the case of this embodiment, the pile 20 is a hollow rod, that is, a pipe, but may be formed as a solid rod. The pile 20 is inserted into the through-hole 12 of the foundation structure 10 and the portion of the foundation structure 10 that has come out from the other side in the height direction is driven into the ground. The length is set so that it is driven with a sufficient length. For example, the pile 20 driven into the ground has a radially extending tip on the other side in the height direction as viewed from the height direction. For example, the width direction perpendicular to the height direction or the height Developed in an inverted V shape such that the distance increases toward the tip of the other side in the height direction as viewed from the direction orthogonal to the height direction, such as the depth direction orthogonal to both the direction and the width direction. . In FIG. 2, the width direction is the left-right direction in the direction in which the reference numerals are correctly viewed, and the depth direction is the vertical direction of the figure. Therefore, when the foundation structure 10 is arranged near the ground, the piles 20 are respectively inserted into the through holes, and these piles 20 are driven into the ground, the foundation structure 10 is installed on the land. In the case of this embodiment, a thin rubber cap is put on the portion of the pile 10 protruding from the foundation structure 10 to the one side in the height direction, and rainwater or the like enters the inside of the pile 10. However, the present invention includes embodiments that do not cover such caps.

  As shown in FIGS. 4 and 5, the foundation structure 10 includes a main body 10 a and a plurality of cylinders 10 b provided on the main body 10 a. The cylindrical body 10b is provided by the number of the through holes 12. The main body 10a is formed in a saddle shape so as to form an internal space 13 opened to the other side in the height direction. Here, the bowl is a hemispheric tableware serving food and drink, and is a ceramic. And the said saddle shape is the concept which extended it. That is, the main body 10a formed in the bowl shape is not limited to a hemispherical shape, and may be, for example, a shape obtained by dividing a hollow lump-like article into halves. The main body 10a may have a shape such as a thick-walled spherical shell. In addition, the material of the bowl is generally a material corresponding to ceramics, but the material of the foundation structure 10 is not limited thereto, and is formed of metal, synthetic resin, or other materials as will be described later. Has been. In addition, the expression “boiled” means that the bottom of the bowl-shaped object is placed on the one side in the height direction and the opening is on the other side in the height direction. Means to put it in the opposite direction in the height direction. The main body 10a is formed so that the outer shape becomes a square shape when viewed in the height direction, but the outer shape is formed, for example, in a circular shape, a polygonal shape, or other shapes when viewed in the height direction. May be. The main body 10a is formed in a plane in which the central portion 11 on the one side in the height direction faces the height direction, and a slope is provided around the center portion 11 so that the one side in the height direction has four sides. Although it is formed like a truncated pyramid, these surfaces may be formed by curved surfaces or other shapes. The main body 10a is formed so that the thickness of the peripheral portion is substantially constant, but the thickness may be different depending on the part. A top hole 11a penetrating in the height direction is provided in the central portion 11 of the main body 10a, and a bolt (not shown) passed through the top hole 11a from the inner space 13 side of the main body 10a. The screw portion can be coupled to a supported object or a connecting member described later. However, it is not necessary to provide such a top hole. For example, a stay or other connecting means may be provided in the central portion of the main body.

  The cylindrical body 10b is formed in a cylindrical shape, and is provided so as to penetrate the main body 10a around the central portion 11 of the main body 10a so that the through hole 12 is formed by a hole inside the cylindrical body 10b. . The cylindrical body 10b is formed in a cylindrical shape, but may be formed in, for example, a rectangular cylindrical shape, a polygonal cylindrical shape, or other shapes. The cylindrical body 10b extends both inside and outside the main body 10a, but may extend only to one side. The cylindrical body 10b is provided at a position farthest from the central portion 11 in the main body 10a when viewed in the height direction. In the case of this embodiment, the main body 10a is formed so as to have a quadrangular shape when viewed in the height direction. Therefore, the cylindrical body 10b is provided at the four corners of the main body 10a when viewed in the height direction. It has been. This is to make it difficult for the plurality of piles 20 inserted into the through holes 12 to interfere with each other on the other side in the height direction. However, this does not limit the arrangement of the cylinders in the main body, and the cylinders need only be provided so as to penetrate the main body around the central portion of the main body. The foundation structure may have a hole or the like.

  The substructure 10 is made of metal. In the case of this embodiment, the foundation structure 10 is formed of ductile cast iron which is a kind of cast iron. The foundation structure may be formed of other cast iron. And as for the said foundation structure 10, the said main body 10a and the said cylinder 10b are integrally formed by casting. The base structure may be formed of, for example, stainless steel, aluminum alloy, or other metal, and other than metal, for example, synthetic resin, ceramic, concrete, concrete mixed with resin fiber or steel fiber, stone, You may form with wood. Moreover, the material of the said main body and the said cylinder may differ. Further, the foundation structure may be formed by press forming a material, cutting out from the material, forming by welding the materials, or by other manufacturing methods, instead of casting.

  Legs 15 extending to the other side in the height direction are provided at a plurality of locations on the peripheral edge 14 on the other side in the height direction of the main body 10a. In the case of this embodiment, the leg 15 extends from the four corners of the peripheral edge 14 in the main body 10a to the other side in the height direction. The leg 15 is formed in an L shape when viewed in the height direction, but may be formed to have, for example, a circular shape, a square shape, a polygonal shape, or other shapes as viewed in the height direction. .

  And the to-be-supported object 40 is attached to the said center part 11 of the said main body 10a of the said foundation structure 10 in the attachment site | part of the said to-be-supported object 40. As shown in FIG. In the case of this embodiment, the attachment is performed by coupling the threaded portion of the bolt that has passed through the top hole 11a from the side of the internal space 13 of the main body 10a to the supported object 40. Moreover, the said foundation structure 10 may be provided with the connection member. That is, the connection member may be provided in the central portion 11 of the main body 10a of the foundation structure 10, and the supported object 40 may be attached to the connection member at the attachment site of the supported object 40. . The connecting member may be provided in the main body 10a with the top hole 11a as a clue, or may be provided integrally with the main body 10a when there is no top hole, or bolted, welded, or other means. May be provided. In that case, by the adjustment function of the connecting member or the like, at least of the positional deviation in the height direction between the supported object 40 and the foundation structure 10 and the positional deviation in the plane orthogonal to the height direction. One position shift may be provided so as to be absorbable. In the present invention, when the positional deviation in the plane orthogonal to the height direction is referred to, the positional deviation along the direction included in the above-described surface such as the width direction or the depth direction is also included.

  The substructure 10 is formed so as to be suitable for a manufacturing method by casting. That is, on the other side in the height direction of the portion protruding from the main body 10a of the cylindrical body 10b to the one side in the height direction, an outer fill 10c is placed between the main body 10a. Yes. Further, the main body 10a is located on the one side in the height direction of the portion protruding from the main body 10a of the cylindrical body 10b to the other side in the height direction, that is, the portion protruding to the inner space 13 side. The inner fill 10d is placed between the two. By configuring in this manner, the first mold on the one side in the height direction and the second mold on the other side in the height direction are poured together, and the molds are separated to When the foundation structure 10 is taken out, the first mold and the second mold can be easily removed while being prevented from being caught on the foundation structure 10.

  Next, the completed structure using the foundation structure 10 will be described. As shown in FIGS. 1 to 3, the plurality of foundation structures 10 are respectively arranged near the ground, and the plurality of piles 20 are respectively inserted into the through holes 12 of the foundation structures 10. Have been driven into the ground. In the form of the arrangement, for example, the foundation structure is arranged so that at least a part of the foundation structure is embedded in the ground, the foundation structure 10 is placed on the ground, and the foundation structure 10 is placed floating from the land. There are forms such as. In the case of this embodiment, at least the other side in the height direction of the foundation structure 10 is buried in the ground, whereby the foundation structure 10 is arranged near the ground. In the case of the foundation structure provided with the connecting member having the adjustment function, the supported object 40 in the foundation structure 10 having a deviation from the corresponding attachment site among the plurality of foundation structures 10. And at least one of the positional shift in the height direction between the base structure 10 and the positional shift in a plane orthogonal to the height direction can be absorbed.

  In the case of the completed structure shown in FIG. 6, the supported object 40 is a solar cell power generator. This solar cell power generation device includes a plate-shaped solar cell panel 41 that performs solar power generation, and a support structure 42 that is disposed on the other side of the solar cell panel 41 in the height direction and supports the solar cell panel 41. And. The support structure 42 has a vertical beam and a horizontal beam, is arranged on the other side in the height direction of the solar cell panel 41, and a frame 42a on which the solar cell panel 41 is placed, and the frame 42a A plurality of columns 42b that are arranged on the other side of the height direction and extend in the height direction to support the gantry 42a, and a direction that is oblique to the depth direction or the height direction, etc. A connecting member 42c that extends and connects the columns is provided with a beam 42d. The beam 42d is disposed on the other side in the height direction of the plurality of columns 42b, and receives the end of the other side in the height direction of the plurality of columns 42b. The other end in the height direction of each column 42b is bolted to the beam 42d. The other end of the beam 42d in the height direction is fastened to the central portion 11 of the foundation structure 10 with a bolt or the like. When the connection member is used, the other end of the beam 42d in the height direction is fastened to the connection member of the foundation structure 10 with a bolt or the like. The plurality of attachment sites are in the support structure 42. That is, a plurality of support portions provided at intervals on the other side in the height direction of the beam 42d of the support structure 42 correspond to the plurality of attachment portions. Strictly speaking, the surface on the other side in the height direction in the support portion corresponds to the plurality of attachment portions. And when the said foundation structure 10 is provided with the said connection member which has the said adjustment function, the said foundation structure which has a shift | offset | difference with the said beam 42d which is the said corresponding attachment site | part among these several foundation structures. 10, at least one of the positional deviation in the height direction between the beam 42 d of the supported object 40 and the foundation structure 10 and the positional deviation in a plane perpendicular to the height direction is detected. Can be absorbed.

  In the case of the other completed structure shown in FIG. 7, the supported object 40 is a deck. The deck includes a floor member 43 and a support structure 42 that is disposed on the other side of the floor member 43 in the height direction and supports the floor member 43. The support structure 42 has a vertical beam and a horizontal beam, and is disposed on the other side of the floor member 43 in the height direction so as to mount the floor member 43, and the height of the frame 42a. A plurality of columns 42b that are arranged on the other side in the vertical direction and extend in the height direction to support the gantry 42a, and extend in a direction that is inclined with respect to the depth direction, the height direction, or the like. And a connecting member 42c for connecting the columns to each other. The plurality of attachment sites are in the support structure 42. That is, the other end in the height direction of the plurality of support posts 42b of the support structure 42 corresponds to the plurality of attachment portions. The other end in the height direction of each column 42b is fastened to the central portion 11 of the main body 10a of the foundation structure 10 with a bolt. When the connection member is used, the other end in the height direction of each column 42b is fastened to the connection member of the foundation structure 10 with a bolt or the like. And when the said foundation structure 10 is equipped with the said connection member which has the said adjustment function, the said height direction of each said support | pillar 42b which is the said corresponding attachment site | part among these several foundation structures 10 In the foundation structure 10 having a deviation from the other end, the positional deviation in the height direction between the column 42b of the supported object 40 and the foundation structure 10 and the height direction are orthogonal to each other. It is possible to absorb at least one position shift among the positions in the plane.

  Therefore, for example, at least a part of the foundation structure 10 is embedded in the ground, placed on the ground, or floated from the land, and the like, and the plurality of piles 20 are placed on the foundation structure 10. The foundation structure 10 is fixed to the land by being inserted into the through holes 12 and driven into the ground. In that case, since the main body 10a is formed in the shape of the laid down so as to form the internal space 13 opened to the other side in the height direction, Thus, the bulkiness of the foundation structure 10 is eliminated and the stability when the foundation structure 10 is placed on a flat surface as compared with those formed in a substantially spherical shape or a substantially elliptical sphere shape. And the weight of the foundation structure 10 may be reduced. Therefore, for example, when the foundation structure 10 is stored or transported, it is not always necessary to house the foundation structure 10 in, for example, a dedicated pallet. In addition, when the foundation structure 10 is constructed on a land that may be cold, the frost heaving problem is less likely to occur by introducing soil lifted by frost into the internal space 13. Further, when the foundation structure 10 is formed such that the internal space 13 includes the one side portion of the foundation structure 10 in the height direction, the two foundation structures 10 are oriented in the same direction. When one of the substructures 10 is stored in the internal space 13 of the other substructure 10, the substructures 10 are compact when stacked. Fits in. Then, the handleability of the foundation structure 10 is further improved. Further, when the foundation structure 10 is formed of a material that does not absorb moisture from the surface, not concrete, or a material that does not absorb moisture, such as metal or the like, the foundation structure 10 may be cold. Even when it is constructed on a certain land, it is less likely to break due to freezing of the sucked moisture compared to the conventional support portion filled with concrete inside. Furthermore, when the foundation structure 10 is formed of, for example, metal or other material that can be processed with higher accuracy than concrete, the gap between the through hole 12 and the pile 20 can be set smaller. It becomes possible, after the construction of the foundation structure 10, the gap becomes play and the length of displacement of the foundation structure 10 with respect to the pile is shortened, and the construction accuracy of the foundation structure can be improved. . And in order to prevent the said displacement, it is not necessary to lengthen the said through-hole 12 so that the inclination angle with respect to the said through-hole 12 of the said pile may not become large with the said clearance gap. Therefore, it is possible to set the overall length of the through hole 12, that is, the overall length of the cylindrical body 10b, to be relatively short, and the length of the cylindrical body 10b protruding from the main body 10a can be shortened.

  The basic structure of the present invention is not limited to metal as described above. Among such various embodiments, the substructure 10 of the first embodiment is made of metal. In this way, since the foundation structure 10 is formed of a metal that is less likely to absorb moisture or does not absorb moisture than concrete, the foundation structure 10 is in a land that may be cold. Even when it is constructed, there is less or no risk of breakage due to freezing of the water sucked in compared to the conventional support portion filled with concrete inside. Further, since the foundation structure 10 is formed of a metal that can be processed with higher accuracy than concrete or the like, the gap between the through hole 12 and the pile 20 can be set smaller, and the foundation The length of the displacement of the foundation structure 10 relative to the pile 20 is shortened after the construction of the structure 10 is performed, and the construction accuracy of the foundation structure 10 is improved. And in order to prevent the said displacement, it is not necessary to lengthen the said through-hole 12 so that the inclination angle with respect to the said through-hole 12 of the said pile 20 may not become large with the said clearance gap. Therefore, it is possible to set the overall length of the through hole 12, that is, the overall length of the cylindrical body 10b, to be relatively short, and the length of the cylindrical body 10b protruding from the main body 10a can be shortened.

  The substructure of the present invention includes an embodiment in which the above-mentioned legs are not provided. Among such various embodiments, the foundation structure 10 of the first embodiment has the height direction at a plurality of locations on the peripheral edge 14 on the other side in the height direction of the main body 10a. A leg 15 extending toward the other side is provided. If it does in this way, the said foundation structure 10 can be temporarily fixed to land by piercing the said leg 15 in land. In that case, since the internal space 13 is provided, since the soil is introduced into the internal space 13 as the foundation structure 10 is pushed into the land, it is easy to push the foundation structure 10 into the land. is there. And, for example, as in the other side in the height direction of the foundation structure 10, the foundation structure 10 is embedded in the ground, placed on the ground, or floated from the ground. When the plurality of piles 20 are respectively inserted in the vicinity and inserted into the through holes 12 of the foundation structure 10 and driven into the ground, the foundation structure 10 is fixed to the land.

  Next, a second embodiment of the foundation structure of the present invention and a completed structure assembled using the same will be described with reference to FIGS. The foundation structure of the second embodiment and the completed structure assembled using the same are the same as those of the first embodiment and the modifications thereof, and the completed structure assembled using the same. And the configuration of the modified example together with their reference numerals, the basic structure of the first embodiment and the modified example, the completed structure assembled using the same, and the configuration different from the configuration of the modified example An additional explanation will be given. The foundation structure 10 of the first embodiment is formed of ductile cast iron, and the main body 10a and the cylinder 10b are integrally formed by casting so that the foundation structure 10 is suitable for a manufacturing method by casting. Formed. On the other hand, the substructure 10 of the second embodiment is formed of steel, and the main body 10a and the cylindrical body 10b are formed by welding, press-fitting, etc. a steel plate and a steel pipe, and the substructure 10 Is formed so as to be suitable for such a manufacturing method.

  8 to 12 show a second embodiment of the foundation structure of the present invention, and FIG. 13 shows one embodiment of a completed structure assembled using the foundation structure. The main configuration will be described below. The substructure 10 has two or more through holes 12. In the case of this embodiment, the four through holes 12 penetrate, but the number of the through holes may be two or more. One end of each through hole 12 opens around the central portion 11 on one side of the foundation structure 10 in the height direction, and the other end is on the other side of the foundation structure 10 in the height direction. It is open. The plurality of through holes 12 are at an angle of more than 0 degree and less than 90 degrees with respect to the height direction. The plurality of through holes 12 extend in different directions without interfering with each other. The through hole 12 is formed straight. In the case of this embodiment, the through hole 12 is formed in a circular shape when viewed in the direction in which the through hole 12 extends. However, the through hole 12 may have, for example, a polygonal shape or other shapes, and the through hole 12 extends. The shape may change along the direction. The foundation structure 10 is disposed near the ground. In this form of arrangement, for example, the foundation structure is arranged so that at least a part of the foundation structure is embedded in the ground, the foundation structure 10 is placed on the ground, and the foundation structure 10 is floated from the land. There are forms such as. In the case of this embodiment, at least the other side in the height direction of the foundation structure 10 is buried in the ground, whereby the foundation structure 10 is arranged near the ground. In FIG. 12, the ground surface, that is, the surface G of the land is indicated by imaginary lines, but the position of the surface G of the land with respect to the foundation structure 10 in the drawing is merely an example. The plurality of piles 20 are respectively inserted into the through holes 12 of the foundation structure 10 and driven into the ground.

  The pile 20 is formed straight. In the case of this embodiment, the pile 20 is formed so that the outer shape is circular when viewed in the extending direction of the pile 20 corresponding to the through hole 12. For example, the outer shape is polygonal or other It may be formed in a shape, and the outer shape may change along the direction in which the pile 20 extends. The pile 20 is made of steel, but may be formed of, for example, another metal, synthetic resin, or other material. In the case of this embodiment, the pile 20 is a hollow rod, that is, a pipe, but may be formed as a solid rod. The pile 20 is inserted into the through-hole 12 of the foundation structure 10 and the portion of the foundation structure 10 that has come out from the other side in the height direction is driven into the ground. The length is set so that it is driven with a sufficient length. The pile 20 driven into the ground has, for example, a tip of the other side in the height direction extending radially when viewed from the height direction, for example, the height direction such as the width direction or the depth direction. As viewed from the orthogonal direction, it develops in an inverted V shape such that the distance increases toward the tip on the other side in the height direction. Therefore, when the foundation structure 10 is arranged near the ground, the piles 20 are respectively inserted into the through holes, and these piles 20 are driven into the ground, the foundation structure 10 is installed on the land.

  As shown in FIGS. 11 and 12, the substructure 10 includes a main body 10a and a plurality of cylinders 10b provided on the main body 10a. The cylindrical body 10b is provided by the number of the through holes 12. The main body 10a is formed in the shape of the face down so that the internal space 13 opened to the other side in the height direction is formed inside. The main body 10a is made of steel. The main body 10a is integrally formed by press-molding a steel plate, but a plurality of steel materials may be joined together by welding to constitute the main body, or may be formed by cutting out from a steel material. Or may be formed by other manufacturing methods. The main body 10a is formed so that the outer shape becomes a square shape when viewed in the height direction, but the outer shape is formed, for example, in a circular shape, a polygonal shape, or other shapes when viewed in the height direction. May be. The main body 10a is formed in a plane in which the central portion 11 on the one side in the height direction faces the height direction, and is substantially orthogonal to the direction in which the through holes 12 pass therearound. One slope 10aa is provided, and a second slope 10ab is formed between the adjacent first slopes 10aa. Therefore, as shown in FIG. 11, when the one side of the main body 10a in the height direction is turned counterclockwise around the central portion 11, the first inclined surface 10aa and the second inclined surface 10ab are alternately arranged. The first inclined surface 10aa is inclined to the one side along the height direction, and the second inclined surface 10ab is inclined to the other side along the height direction. These slopes may be formed in a curved surface. The main body 10a is formed so that the thickness of the peripheral portion is substantially constant, but the thickness may be different depending on the part. The central portion 11 of the main body 10a is provided with a top hole 11a penetrating in the height direction so that the screw portion of the bolt described above can be passed therethrough. However, such a top hole need not be provided, and for example, the connecting means described above may be provided in the central portion of the main body.

  The cylindrical body 10b is formed in a cylindrical shape, and is provided so as to penetrate the main body 10a around the central portion 11 of the main body 10a so that the through hole 12 is formed by a hole inside the cylindrical body 10b. . In this embodiment, the cylindrical body 10b is a steel pipe. The cylindrical body 10b is formed in a cylindrical shape, but may be formed in, for example, a rectangular cylindrical shape, a polygonal cylindrical shape, or other shapes. The cylindrical body 10b extends both inside and outside the main body 10a, but may extend only to one side. The cylindrical body 10b is provided at a position farthest from the central portion 11 in the main body 10a when viewed in the height direction. In the case of this embodiment, the main body 10a is formed so as to have a quadrangular shape when viewed in the height direction. Therefore, the cylindrical body 10b is provided at the four corners of the main body 10a when viewed in the height direction. It has been. This is to make it difficult for the plurality of piles 20 inserted into the through holes 12 to interfere with each other on the other side in the height direction.

  The substructure 10 is made of metal. In the case of this embodiment, the foundation structure 10 is made of steel. You may form the said foundation structure with another metal. The base structure 10 has a mounting hole 10ac penetrating through the main body 10a, the cylindrical body 10b is inserted into the mounting hole 10ac, and the periphery of the mounting hole 10ac is welded to the cylindrical body 10b. Thus, the cylindrical body 10b is attached to the main body 10a. There is also a mounting form in which the cylindrical body 10b is press-fitted into the mounting hole 10ac so that the welding is not performed. In those cases, each attachment hole 10ac is formed in each said 1st slope 10aa. Instead of this, the base structure is drilled in the main body with a mounting hole penetrating the base body, and the cylindrical body 10b having a male screw on the outer periphery is screwed into the mounting hole. You may attach the said cylinder to the said main body by connecting to. Also in that case, each attachment hole 10ac is opened in each said 1st slope 10aa. The base structure may be formed of, for example, stainless steel, aluminum alloy, or other metal, and other than metal, for example, synthetic resin, ceramic, concrete, concrete mixed with resin fiber or steel fiber, stone, You may form with wood. Moreover, the material of the said main body and the said cylinder may differ. In those cases, the connection between the main body and the cylinder inserted into the mounting hole is performed by, for example, welding, press-fitting, brazing, adhesive application, or other methods.

  Legs 15 extending to the other side in the height direction are provided at a plurality of locations on the peripheral edge 14 on the other side in the height direction of the main body 10a. This invention includes the modification which does not provide the said leg in this embodiment. In the case of this embodiment, the leg 15 extends from the four corners of the peripheral edge 14 in the main body 10a to the other side in the height direction. The leg 15 is formed in an L shape when viewed in the height direction, but may be formed to have, for example, a circular shape, a square shape, a polygonal shape, or other shapes as viewed in the height direction. .

  And the to-be-supported object 40 is attached to the said center part 11 of the said main body 10a of the said foundation structure 10 in the attachment site | part of the said to-be-supported object 40. As shown in FIG. In the case of this embodiment, the attachment is performed by coupling the threaded portion of the bolt that has passed through the top hole 11a from the side of the internal space 13 of the main body 10a to the supported object 40. Further, a connecting member may be provided in the central portion 11 of the main body 10 a of the foundation structure 10, and the supported object 40 may be attached to the connecting member at an attachment site of the supported object 40. The connecting member may be provided in the main body 10a with the top hole 11a as a clue, or may be provided integrally with the main body 10a when there is no top hole, or bolted, welded, or other means. May be provided. In this case, at least one of the positional deviation in the height direction between the supported object 40 and the foundation structure 10 and the position in the plane perpendicular to the height direction by the adjustment function of the connection member or the like. Two positional shifts may be provided so as to be absorbable.

  The substructure 10 is formed so as to be suitable for a manufacturing method in which the main body 10a and the cylindrical body 10b are combined. That is, in the main body 10a, the first slopes 10aa are provided so as to be substantially orthogonal to the penetration direction of the through holes 12 passing therethrough. With this configuration, when the mounting hole 10ac is opened in the main body 10a, the tip of a drill or the like can be applied to the first inclined surface 10aa almost at a right angle, and the punch can be punched even when punched with a press, for example. It can be applied to each of the first slopes 10aa at a substantially right angle. Therefore, the workability when opening the mounting hole 10ac in the main body 10a can be improved.

  Next, the completed structure using the foundation structure 10 of the second embodiment will be described. As in the case of the foundation structure 10 of the first embodiment, as shown in FIGS. 8 to 10, the plurality of foundation structures 10 are arranged near the ground, and the plurality of piles 20 are Each of the substructures 10 is inserted into the through holes 12 and driven into the ground. In the form of the arrangement, for example, the foundation structure is arranged so that at least a part of the foundation structure is embedded in the ground, the foundation structure 10 is placed on the ground, and the foundation structure 10 is placed floating from the land. There are forms such as. In the case of this embodiment, at least the other side in the height direction of the foundation structure 10 is buried in the ground, whereby the foundation structure 10 is arranged near the ground. In the case of the foundation structure 10 provided with the connecting member having the adjustment function, in the foundation structure 10 having a deviation from the corresponding attachment site among the plurality of foundation structures 10, the supported object It is possible to absorb at least one position shift among the position shift in the height direction between 40 and the foundation structure 10 and the position shift in the plane orthogonal to the height direction.

  In the case of the completed structure shown in FIG. 13, the supported object 40 is a solar cell power generator. This solar cell power generation device includes a plate-shaped solar cell panel 41 that performs solar power generation, and a support structure 42 that is disposed on the other side of the solar cell panel 41 in the height direction and supports the solar cell panel 41. And. The structure of the support structure 42 is the same as that of the foundation structure 10 of the first embodiment, and the other end in the height direction of each column 42b is bolted to the beam 42d. . The other end of the beam 42d in the height direction is fastened to the central portion 11 of the foundation structure 10 with a bolt or the like. When the connection member is used, the other end of the beam 42d in the height direction is fastened to the connection member of the foundation structure 10 with a bolt or the like.

  In the case of the other completed structure shown in FIG. 14, the supported object 40 is a deck. The deck includes a floor member 43 and a support structure 42 that is disposed on the other side of the floor member 43 in the height direction and supports the floor member 43. The structure of the support structure 42 is the same as that of the foundation structure 10 of the first embodiment. The other end in the height direction of each column 42b is fastened to the central portion 11 of the main body 10a of the foundation structure 10 with a bolt. When the connection member is used, the other end in the height direction of each column 42b is fastened to the connection member of the foundation structure 10 with a bolt or the like. The basic structure of the second embodiment and its modification, the completed structure assembled using them, and the actions and effects obtained by the modification are the same as those of the first embodiment and modification. This is the same as the functions and effects obtained by the structure, and the above-described completed structure assembled using the structure and the modified example thereof.

  The basic structure of the present invention and the completed structure using the same include the embodiments described above and embodiments in which the features of modifications are combined. Furthermore, the above embodiment and the modification are only some examples of the basic structure of the present invention and the completed structure using the basic structure. Therefore, the description of these embodiments and modifications does not limit the basic structure of the present invention and the completed structure using the basic structure.

DESCRIPTION OF SYMBOLS 10 Substructure 10a Main body 10b Cylindrical body 11 Center part 11a Top hole 12 Through-hole 13 Internal space 14 Peripheral part 15 Leg 20 Pile 40 Supported object 41 Solar cell panel 42 Support structure 42a Mounting frame 42b Column 42c Connecting member 42d Beam 43 Floor Material G Land surface

Claims (3)

An angle with respect to the height direction and extending in different directions without interfering with each other, with one end opening around the central portion on one side of the height direction and the other end opening on the other side of the height direction. In the foundation structure installed in the land by providing the above through holes and driving the piles inserted into the through holes into the ground,
A body formed in a saddle shape so that an internal space opened to the other side in the height direction is formed inside,
A basic structure comprising a plurality of cylinders formed in a cylindrical shape and penetrating the main body around the main body so that the through-hole is formed by an internal hole. object.   The substructure according to claim 1, which is made of metal.   The foundation structure of Claim 1 or Claim 2 in which the leg extended to the said other side of the said height direction is provided in the several places of the peripheral part of the said other side of the said height direction in the said main body.

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