JP3824570B2 - Pile foundation structure - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a concrete footing (foundation of a structure) that is fixed to an architectural / civil engineering structure such as a building or a bridge, and embedded in the underground ground, and a deep layer such as a hard pile layer. It is related with the pile foundation structure supported by the pile head which is the upper end part of the tip support pile which is transmitted to and supported, and the friction pile between the outer peripheral surface of the pile and the ground soil).
[0002]
[Prior art]
In this type of pile foundation structure, generally, as shown in FIG. 13, a foundation pile 101 as a structural unit is placed in the underground ground, and is fixed to a column B and a foundation beam C on the upper structure side. Usually, the base footing 102 made of the base and the head (pile head) 101a of the foundation pile 101 are rigidly joined by embedding a plurality of pile rebars 103 in the both 101, 102.
[0003]
[Problems to be solved by the invention]
However, in such a rigid joint structure, when an excessive force due to an earthquake or the like (hereinafter referred to as “seismic force”) is applied, stress concentrates on the pile head joint that is the boundary between the two, and the pile head during a large earthquake The lower portions of the 101a and the footing 102 are easily damaged and broken, which may cause damage such as collapse of the upper structure. Moreover, since it is rigid joint, since the stress which acts on a pile head joint part becomes large, the number of embedding of the reinforcing bars 103 ... is increased more than necessary, or the cross-sectional shape (horizontal cross-sectional shape) of the pile 101 or the footing 102 is increased. It is necessary to enlarge. As a result, the construction is not only complicated, but the construction cost is increased due to an increase in the bar arrangement work. In addition, when the pile head joint is damaged or broken, it is necessary to restore the location, but the pile head joint is supported by a pile 101 placed concrete as a structural unit in the underground ground. Because of the substructure, the workability of the restoration work itself is very poor and enormous restoration costs are required.
[0004]
An object of this invention is to provide the pile foundation structure which can exhibit the outstanding seismic performance and seismic isolation performance, without producing such a problem.
[0005]
[Means for Solving the Problems]
  In order to achieve the above object, the present invention seals the upper bearing member attached to the lower part of the foundation footing and the lower bearing member attached to the head of the foundation pile between the upper and lower opposing surfaces of both bearing members. It is a pile foundation structure that is pin-bonded so as to be relatively rotatable through an incompressible flexible member, and has a bottomed cylindrical cylinder portion in which a lower support member opens upward, The upper support member can rotate freely within a specified range with respect to the axis of the cylinder.InsertionThe lower end of the piston part is formed at the lower end of the piston part so as to form a sealed space for hermetically filling the flexible member between the upper and lower opposing surfaces of the cylinder part and the piston part. A seal member is provided for sealing between the surface and the inner peripheral surface of the cylinder portion facing the surface, and at least the upper end portion of the annular gap formed between the opposed peripheral surfaces of the cylinder portion and the piston portion,The outer peripheral part is the inner peripheral surface of the cylinder part.Sticking toIn addition, the inner peripheral portion was pressed against the outer peripheral surface of the piston portion.With an annular scraper made of elastic materialDenseConfigured to close sealWhen the cylinder portion and the piston portion are relatively displaced, the scraper always seals the opening of the annular gap with an annular scraper that elastically deforms following the change in shape, and the inner peripheral portion of the scraper. The scraper function that moves relatively while rubbing the outer peripheral surface of the piston part with the relative displacement between the cylinder part and the piston part is exhibited.A pile foundation structure is proposed.
[0006]
In such a pile foundation structure, as the flexible member, it is possible to use a non-compressible material rubber (natural rubber, synthetic rubber, etc.) that is configured in a solid shape body such as a disk shape. preferable. In a preferred embodiment, the lower support member has a cylindrical cylinder portion that opens upward, and the upper support member is fitted to the cylinder portion so as to be rotatable within a predetermined range with respect to its axis. The piston section having a circular cross section is formed, and at the lower end of the piston section, a lower end outer peripheral surface of the piston section and this are formed in order to form a sealed space between the upper and lower opposing surfaces of the cylinder section and the piston section. A sealing member is provided for sealing between the inner peripheral surface of the cylinder portion facing the cylinder member, and a flexible member having a disk shape is hermetically filled in the sealed space.
[0007]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be specifically described below with reference to FIGS.
[0008]
In the pile foundation structure of the present invention, as shown in FIG. 1, the heads (pile heads) 1 a and 10 a of the foundation piles 1 and 10 and the foundation footing 2 arranged on the upper side thereof are joined by the pin joining means 3. Various embodiments will be described below. The foundation footing 2 is made of concrete and is embedded in the ground by being fixed to a pillar B and a foundation beam C that are integrally extended downward from a building A that is an upper structure.
[0009]
2 to 5 show the first embodiment, and the pile foundation structure according to the present invention in this embodiment (hereinafter referred to as “first pile foundation structure”) is a hollow foundation pile 1. The basic footing 2 is joined by the following pin joining means 3. The foundation pile 1 is a hollow cross-section structure (cylindrical structure) such as centrifugal reinforced concrete piles, pre-tension centrifugal high strength prestressed concrete piles (PHC piles), SC piles, ST piles, etc. As shown in FIG. 2, an annular metal end plate 1b is fixed to the pile head 1a.
[0010]
As shown in FIG. 2, the pin joining means 3 includes a lower support member 4 attached to the pile head 1 a and an upper support member 5 attached to the lower part of the foundation footing 2. , 51a are joined via a non-compressible flexible member 6 hermetically sealed between them in a predetermined range relative to the vertical axis.
[0011]
That is, as shown in FIGS. 2 and 3, the lower support member 4 includes a bottomed cylindrical cylinder portion 41 that opens upward, an annular flange portion 42 that protrudes horizontally from the outer periphery of the lower end thereof, and an annular flange portion 42. It is made of metal (in this example, made of steel) and includes a cylindrical positioning portion 43 that is suspended on the pile head 1a, and is attached to the pile head 1a via a reinforcing support plate 7.
[0012]
As shown in FIG. 3, the cylinder part 41 and the annular flange part 42 are integrally formed by concentrically welding a metal disc 4b having a larger diameter to the lower end part of the metal cylinder 4a. That is, the cylinder part 41 is comprised by the steel cylinder (steel pipe) 4a and the center part of the circular steel plate 4b which obstruct | occludes the lower end part, and the annular collar part 42 protrudes from the lower end outer peripheral part of the steel pipe 4a. It is comprised by the outer peripheral side part of the circular steel plate 4b. Moreover, the positioning part 43 is comprised with the steel cylinders (steel pipe) welded to the outer peripheral part (outer peripheral part of the annular collar part 42) of the circular steel plate 4b.
[0013]
As shown in FIG. 2, the reinforcing support plate 7 has a circular shape with a slightly larger diameter than the foundation pile 1 and does not bend even when a bearing load is applied to the central portion 7 a corresponding to the hollow portion of the pile 1. Thickness H sufficient to have strength₂Is a metal disk (in this example, a steel plate), and a cylindrical metal connection body (in this example, a steel pipe) 71 suspended from (welded to) the outer peripheral edge is connected to the outer periphery of the pile 1 from above. By being fitted (externally fitted), it is installed and fixed on the pile head 1a (more precisely, the end plate 1b). In addition, the length (fitting length to the pile head 1a) H of the coupling body 71₁At least, even when a pulling force due to seismic force or the like acts on the reinforcing support plate 7, the fitting form of the connecting body 71 and the pile head 1a is not released (the connecting body 71 does not come off the pile head 1a). Is set to about. Moreover, although the cross-sectional shape of the connection body 71 is similar to the cross-sectional shape of the pile head 1a, it should be made as small as possible within a range where the fitting to the pile head 1a can be easily performed. That is, it is preferable to set the gap between the two la and 71 as small as possible.
[0014]
Thus, as shown in FIG. 2, the lower support member 4 is attached to the pile head 1 a via the reinforcing support plate 7 by fixing the annular flange 42 on the reinforcing support plate 7 with the bolts 8. ing. At this time, positioning of the lower support member 4 is performed by fitting the positioning portion 43 to the reinforcing support plate 7. The thickness H of the reinforcing support plate 7₂Is set so that the central portion 7a corresponding to the hollow portion 1c of the foundation pile 1 has sufficient strength so as not to be bent by the bearing load acting on the central portion 7a via the pin joining means 3. Therefore, even if the foundation pile 1 to which the lower support member 4 is attached is a hollow prefabricated pile, the portion corresponding to the pile hollow portion 1c (the portion not subjected to the reaction force by the pile 1) is bent due to the support load. There is no worry that the pin joint function will be impaired.
[0015]
As shown in FIG. 2, the upper support member 5 includes a metal piston portion 51 that forms an upwardly open bottomed cylindrical body, and an annular seal member 52 that is provided at the lower end portion of the piston portion 51. As shown in FIG. 3, the piston portion 51 is formed by concentrically welding a circular steel plate 5b having a slightly larger diameter to a lower end portion of a steel cylinder (steel pipe) 5a. The lower bearing member 4 is fitted into the cylinder portion 41 from above. The outer diameter of the piston portion 51 allows the relative rotational displacement (relative rotational displacement to absorb seismic force) of both portions 41 and 51 between the opposed peripheral surfaces 41b and 51b of the piston portion 51 and the cylinder portion 41. In order to form a necessary and sufficient annular gap 3b, it is set smaller than the inner diameter of the cylinder part 41 by a predetermined amount. Further, the fitting length H of the piston portion 51 to the cylinder portion 41 is₃(Refer to FIG. 3), even when a pulling force due to seismic force or the like acts on the fitting portions of both the portions 41 and 51, the fitting form of both the portions 41 and 51 is not released (the piston portion 51 is released from the cylinder portion 41). (It cannot be pulled out).
[0016]
The annular seal member 52 is made of a synthetic resin made of filled PTFE or the like, and is engaged and held at the lower end outer peripheral portion of the piston portion 51, that is, the outer peripheral portion of the circular steel plate 5b, and the bottom surface of the cylinder portion 41, that is, the circular steel plate. In order to form a sealed space 3a between the upper surface 41a of 4b and the bottom surface of the piston portion 51, that is, the lower surface 51a of the circular steel plate 5b, the lower end outer peripheral surface of the piston portion 51 (the outer peripheral surface of the circular steel plate 5b) and the cylinder opposed thereto The space between the inner peripheral surface of the portion 41 (the inner peripheral surface of the steel pipe 4a) is sealed.
[0017]
Thus, the upper support member 5 is attached to the lower end portion of the footing 2 by filling a part 2a of the footing 2 into the piston portion 51 as shown in FIG. It is done. The vertical distance between the lower end portion of the footing 2 and the upper end surface of the cylinder portion 41 is set as appropriate as long as the relative rotation of the bearing members 4 and 5 due to an earthquake is not hindered. It is constructed so that the filling portion 2a into 51 protrudes downward from the footing lower end portion 2b and the upper end portion of the piston portion 51 (the upper end portion of the peripheral wall 5a) is immersed in the footing lower end portion 2b.
[0018]
As shown in FIGS. 2 and 3, the flexible member 6 is an elastic disk (solid disk) having a constant thickness whose outer diameter matches the inner diameter of the cylinder portion 41, and is closely packed in the sealed space 3a. Filled. As a constituent material of the elastic disc 6, a rubber elastic material such as natural rubber and synthetic rubber excellent in compression recovery characteristics or an elastomer material composed of a rubber base material is used. In this example, the weather resistance is excellent. Synthetic rubber is used.
[0019]
By the way, the annular gap 3b formed between the opposed peripheral surfaces 41b and 51b of the cylinder part 41 and the piston part 51 fitted thereto is inevitable in order to allow relative rotational displacement of both parts 41 and 51. However, there is a possibility that surrounding earth and sand or the like may enter and accumulate in the annular gap 3b when the pile foundation structure is constructed or when the upper and lower support members 4 and 5 are relatively displaced. And when earth and sand etc. penetrate | invade and accumulate in the cyclic | annular clearance gap 3b, the relative rotational displacement of both the supporting members 4 and 5 will not be performed smoothly, and there exists a possibility that the seismic isolation and earthquake resistance function by the pin joining means 3 may not be exhibited favorably. . Therefore, an annular scraper 9 made of an elastic material is arranged at least at the upper end (opening) of the annular gap 3b so as to prevent the intrusion and accumulation of earth and sand etc. into the annular gap 3b. That is, as shown in FIGS. 2 and 3, the upper end portion (inlet portion) of the annular gap 3b is fixed (by an adhesive or the like) to one of the opposing peripheral surfaces 41b and 51b of both the portions 41 and 51, and the opposing peripheral portion. It is hermetically sealed by an annular scraper 9 made of an elastic material that is in pressure contact with the surfaces 41b and 51b. In this example, the outer peripheral portion of the annular scraper 9 is fixed to the inner peripheral surface 41 b of the cylinder portion 41 with an adhesive, and the inner peripheral portion 9 a is pressed against the outer peripheral surface 51 b of the piston portion 51. The constituent material of the scraper 9 may be an elastic material that can be elastically deformed in accordance with the relative displacement of both the portions 41 and 51. In this example, sponge rubber is used.
[0020]
In the first pile foundation structure in which the pile head 1a and the footing 2 are pin-joined by the pin joining means 3 as described above, when the seismic force is applied, as shown in FIG. Due to the relative rotational displacement of the pile head 1a and the footing 2 in all directions due to the elastic deformation of the synthetic rubber disk 6 hermetically sealed between them, the energy due to the seismic force is effectively absorbed and relaxed. Therefore, since the stress concentration at the joint between the pile head 1a and the footing 2 when the seismic force is applied is significantly reduced, the cross section of the pile 1 and the footing 2 is reduced to the minimum necessary in strength, In addition, while reducing the amount of bar arrangement and making the construction easy and cost-effective, even when excessive horizontal force is applied, the pile head 1a and the footing 2 are prevented from being damaged and broken, and excellent in earthquake resistance. Performance and seismic isolation performance can be demonstrated.
[0021]
Further, the weight of the upper structure acts as a long-term vertical load through the footing 2 on the elastic member 6 interposed between the cylinder portion 41 and the piston portion 51 fitted to the cylinder portion 41. Further, the seismic force Is applied to the elastic member 6 in accordance with the relative rotational displacement between the pile head 1a and the footing 2, but the elastic member 6 is an incompressible material member (synthesized). Rubber disk), which is tightly filled in the sealed space 3a formed between the two portions 41, 51, and therefore, all the load acting on the pin joint portion is received by the elastic member 6. The load functions as a kind of rigid body. On the other hand, since the footing 2 is made of concrete, it is weaker than the elastic member 6 functioning as a rigid body in this way, but the footing portion 2a to which the load directly acts is filled in the piston portion 51. Since the deformation of the footing portion 2a in the lateral direction is completely prevented by the steel peripheral wall (steel pipe) 5a of the piston portion 51, the strength (compression strength) of the footing portion 2a is greatly increased. become. Therefore, from these points, it is possible to sufficiently counter the load acting with the relative rotational displacement between the pile head 1a and the footing 2, and the strength and durability of the pin joint portion are greatly improved. As a result, seismic performance and seismic isolation performance can be exhibited stably and satisfactorily over a long period of time, and the pin joint structure can be significantly reduced in size. That is, it is possible to reduce both the number of installed pin joints and reduce the size of each pin joint.
[0022]
Moreover, when the foundation pile 1 is an existing pile having a hollow cross-sectional structure, when the lower bearing member 4 is installed on the pile head 1a, a portion corresponding to the pile hollow portion 1c in the upper and lower bearing members 4 and 5 is removed from the pile 1. Therefore, it is necessary to enlarge the lower support member 4 (and the upper support member 5) more than necessary in order to secure the strength of the pin joining means 3 (otherwise). The portion corresponding to the pile hollow portion 1c is bent by the bearing load and the pin joining function is impaired), but the lower bearing member 4 is installed on the pile head 1a via the reinforcing support plate 7 described above. Thus, such a problem can be avoided, and in combination with the above, it is possible to reduce both the number of installed pin joints and to reduce the size of each pin joint.
[0023]
Moreover, since the reinforcing support plate 7 is fixed to the pile head 1a by fitting the connecting body 71 provided on the pile head 1a, the lower support member 4 and the reinforcement support plate 7 are bolted. 8..., 8 and so on, the pin joining means 3 can be installed and assembled easily and efficiently without requiring a welding operation that depends on the weather. That is, the installation and assembly of the pin joining means 3 is performed by firstly lowering the reinforcing support plate 7 with a crane and lowering it, and then fitting and fixing the lower support member 4 to the pile head 1a via the connecting body 71. A second step of hanging and lowering by a crane and placing it on the reinforcing support plate 7 fixed to the pile head 1a (the positioning of the lower support member 4 is performed by fitting the positioning portion 43 to the reinforcing support plate 7) The third step of connecting the lower support member 4 to the reinforcing support plate 7 with bolts 8... And the upper support member 5 is suspended and lowered by a crane to make the piston portion 51 of the upper support member 5 flexible. Although the fourth step of fitting the cylinder portion 41 of the lower support member 4 loaded with the member 6 is performed, these steps can be performed only by crane work except for the third step. The third process does not require skill Since it is an easy task Te because, in comparison with the case that requires welding, installation of the pin junction means 3, can be performed with good assembled very easily and efficiently.
[0024]
Further, in the annular gap 3b formed between the opposed peripheral surfaces 41b and 51b of the cylinder part 41 and the piston part 51 fitted to the cylinder part 41, when the pile foundation structure is constructed or the upper and lower support members 4 and 5 are When there is relative displacement, there is a possibility that surrounding earth and sand may invade and accumulate, but the invasion of such earth and sand into the annular gap 3b is ensured by the annular scraper 9 provided at the opening (upper end) of the annular gap 3b. Thus, smooth relative rotational displacement of both the supporting members 4 and 5 is ensured, and the seismic isolation and seismic functions by the pin joining means 3 are satisfactorily exhibited. That is, when the foundation structure is constructed and when the upper and lower support members 4 and 5 are relatively displaced, as shown in FIGS. 2 to 4, the opening of the annular gap 3 b is elastically deformed following its shape change. Since the scraper 9 is always closed (sealed), earth and sand do not enter the annular gap 3b.
[0025]
By the way, when the upper and lower support members 4 and 5 are rotated relative to each other, the cylinder portion 41 is exempted from the normal position (the position indicated by the solid line in FIG. 5) due to the occurrence of an earthquake with respect to the piston portion 51 as illustrated in FIG. Relative displacement (seismic isolation operation) to the seismic position (position indicated by a chain line in the figure), and after the earthquake calms down, the relative displacement (returning operation) from the seismic isolation position to the normal position will occur. Part 51c, 51d of the surface 51b relatively passes through the inner peripheral portion 9a of the annular elastic member (scraper) 9 and enters into the annular gap 3b. That is, in the seismic isolation operation, the outer peripheral surface portion 51c protruding upward from the annular elastic member 9 in the normal position relatively moves along the inner peripheral portion of the annular elastic member 9 with the displacement to the seismic isolation position. It passes through 9a and is displaced into the annular gap 3b. In the returning operation, the outer peripheral surface portion 51d protruding upward from the annular elastic member 9 at the seismic isolation position is relatively displaced with the inner peripheral portion 9a of the annular elastic member 9 in accordance with the displacement to the normal position. Is displaced to the annular gap 3b. Therefore, when the annular elastic member 9 has only a sealing function, the outer peripheral surface portions 51c and 51d are moved into the outer peripheral surface portions 51c and 51d as the outer peripheral surface portions 51c and 51d enter the annular gap 3b. There is a possibility that adhering earth and sand or the like may pass through the inner peripheral portion 9a of the annular elastic member 9 and enter the annular gap 3b. Further, in the returning operation, when the outer peripheral surface portion 51c that has once entered the annular gap 3b is displaced again outside the annular gap 3b, earth and sand adhering to and remaining on the outer peripheral surface portion 51c are removed from the annular elastic member 9. There is also a possibility that the inner peripheral portion 9a may be scraped off into the annular gap 3b.
[0026]
However, since the annular elastic member 9 is configured as a scraper in which the inner peripheral portion 9 a is press-contacted with the outer peripheral surface 51 b of the piston portion 51 as described above, the inner peripheral portion 9 a is a relative member of both the portions 41 and 51. A scraper function of relatively moving while rubbing the outer peripheral surface 51b of the piston portion 51 in accordance with the displacement is exhibited, and when the outer peripheral surface portions 51c and 51d advance into the annular gap 3b, the outer peripheral surface portion 51c. , 51d is not scraped off by the inner peripheral portion 9a of the scraper 9 and enters the annular gap 3b. That is, the outer peripheral surface portion 51c in the seismic isolation operation and the outer peripheral surface 51d in the return operation advance into the annular gap 3b while being rubbed by the scraper portion 9a that is the inner peripheral portion of the scraper 9. Thus, the earth and sand adhering to the outer peripheral surface portions 51c and 51d enter the annular gap 3b as a clean surface scraped off by the scraper portion 9a. Therefore, by providing the scraper 9 having the sealing function and the scraper function at the inlet portion of the annular gap 3b, sand and the like do not enter and accumulate in the annular gap 3b, and the relative rotation of both the portions 41 and 51 is prevented. It is performed smoothly and seismic isolation and seismic functions are demonstrated well. In order to exhibit the scraper function more effectively, the scraper portion (in this example, the inner peripheral portion of the scraper 9) 9a is preferably configured to have a pointed shape as shown in FIG. Further, the scraper 9 may be large so as to fill not only the inlet portion of the annular gap 3b but also the entire gap 3b.
[0027]
By the way, the present invention is not limited to the above-described embodiment, and can be appropriately improved and changed without departing from the basic principle of the present invention.
[0028]
For example, FIG. 7 shows a second embodiment. In the pile foundation structure according to the present invention in this embodiment (hereinafter referred to as “second pile foundation structure”), the reinforcing support plate 7 The pin joining means 3 including the reinforcing support plate 7 is further miniaturized by devising fixing means for the pile head 1a and positioning means for the lower support member 4. In addition, the structure and effect of a 2nd pile foundation structure are the same as a 1st pile foundation structure except the point described below.
[0029]
That is, the outer diameters of the reinforcing support plate 7 and the annular flange 42 of the lower support member 4 are the same, and are set to be the same as or slightly smaller than the outer diameter of the foundation pile 1. A concentric cylindrical metal connection body (steel pipe) 72 is suspended (welded) at the center of the lower surface of the reinforcing support plate 7, and the connection body 72 is connected to the inner peripheral part (hollow part) 1 c of the pile 1. The reinforcing support plate 7 can be installed and fixed on the pile head 1a (end plate 1b) by being fitted (internally fitted) from above. Further, the positioning of the lower support member 4 and the reinforcing support plate 7 is performed by engaging the positioning concave portion 44 formed at the center of the lower surface of the cylinder portion 41 with the positioning convex portion 73 formed at the center of the upper surface of the reinforcing support plate 7. Is configured to do so. Accordingly, since the lower support member 4 and the reinforcing support plate 7 do not protrude laterally from the pile head 1a, the outer peripheral portions (the positioning portion 43 and the connecting body 71) of the lower support member 4 and the reinforcing support plate 7 are provided. Compared to the first pile foundation structure that protrudes laterally from the pile head 1a, the pin joining means 3 including the reinforcing support plate 7 can be further downsized. In addition, the length (fitting length to the pile hollow part 1c) H of the coupling body 72₁In the same way as the connecting body 71 in the first pile foundation structure, the fitting form between the connecting body 72 and the pile head 1a is not released even when at least a pulling force due to seismic force or the like acts on the reinforcing support plate 7 ( The connecting body 72 is set to such an extent that it cannot be removed from the pile head 1a. Moreover, although the cross-sectional shape of the coupling body 72 is similar to the cross-sectional shape of the pile hollow portion 1c, it should be made as large as possible within a range where the fitting to the pile hollow portion 1c can be easily performed. That is, it is preferable to set the gap between the inner peripheral surface of the pile 1 and the outer peripheral surface of the coupling body 72 as small as possible.
[0030]
Further, the reinforcing support plate 7 can be attached to the pile head 1a by welding means, not by the engaging means by the coupling bodies 71 and 72. For example, in the pile foundation structure shown in FIG. 8 (hereinafter referred to as “third pile foundation structure”) and the pile foundation structure shown in FIG. 9 (hereinafter referred to as “fourth pile foundation structure”), the reinforcing support plate 7 is connected to the pile head. 1a, that is, the end plate 1b is welded 8a. In particular, in the fourth pile foundation structure, the lower support member 4 and the reinforcing support plate 7 are not connected at the site, and the both 4 and 7 are integrally connected in advance by welding 8b. In addition, the structure and effect of a 3rd and 4th pile foundation structure are the same as a 2nd pile foundation structure except an above-described point.
[0031]
Moreover, the attachment means and method to the pile head 1a of the lower support member 4 can be arbitrarily changed according to the form, form, etc. of a foundation pile. For example, when the foundation pile is a reinforced concrete pile (generally referred to as “placed pile” or “site-built pile”) 10 formed by cast-in-place construction on the underground ground, Since there is no hollow part 1c like the pile 1, it is not necessary to provide the reinforcing support plate 7 as in the first to fourth pile foundation structures. For example, as shown in FIGS. Can be attached directly to the pile head 10a.
[0032]
That is, in the pile foundation structure (hereinafter referred to as “fifth pile foundation structure”) shown in FIG. 10 and the pile foundation structure (hereinafter referred to as “sixth pile foundation structure”) shown in FIG. The main bar 10b is used for attachment. In the fifth pile foundation structure, as shown in FIG. 10, the exposed portion of the reinforcing bar (pile main bar) 10b extending vertically upward from the pile head 10a is inserted into each reinforcing bar insertion hole formed in the annular flange 42. In addition, the lower support member 4 is fixed to the pile head portion 10a by tightening a mounting nut 10c screwed onto the annular flange 42 to a screw portion formed in the exposed portion. The sixth pile foundation structure is suitable when the lower support member 4 is a general-purpose product and does not have the annular flange 42 or there is no space for forming the reinforcing bar insertion hole in the annular flange 42. As shown in FIG. 11, a mounting plate 45 having a reinforcing bar insertion hole formed in the lower support member 4 is welded 8c, and the mounting plate 45 is mounted on the pile head 1a in the same manner as in the fifth pile foundation structure. It is. By the way, when attaching the annular flange 42 in the fifth pile foundation structure or the mounting plate 45 in the sixth pile foundation structure to the pile head 10a, age hardening of a self-leveling material such as epoxy resin or a non-shrink mortar material in advance. It is preferable that a leveling layer having an upper surface as a horizontal surface is formed on the pile head portion 10a by a material, and the upper surface of the leveling layer is used as a mounting surface on which the annular flange 42 or the mounting plate 45 is installed. In addition, the structure and effect of a 5th and 6th pile foundation structure are the same as the 1st-4th pile foundation structure except an above-described point.
[0033]
When the foundation pile 10 is a cast-in-place pile, the lower support member 4 can be embedded and fixed to the pile head 10a as shown in FIG. That is, in the pile foundation structure shown in FIG. 12 (hereinafter referred to as “seventh pile foundation structure”), the entire lower bearing member 4 is embedded and fixed to the pile head 10 a when the cast-in-place pile 10 is constructed. The configuration and operational effects of the seventh pile foundation structure are the same as those of the fifth and sixth pile foundation structures except for the points described above.
[0034]
【The invention's effect】
As can be understood from the above description, according to the pile foundation structure of the present invention, it is possible to exhibit a good and stable seismic resistance and seismic isolation function over a long period of time without causing the problems described at the beginning.
[Brief description of the drawings]
FIG. 1 is a front view showing first to seventh pile foundation structures.
FIG. 2 is a longitudinal front view showing the main part of the first pile foundation structure.
3 is an enlarged detailed view showing a main part (a peripheral portion of the pin joining means) in FIG. 2;
4 is a longitudinal front view corresponding to FIG. 2, showing a state different from FIG. 2. FIG.
FIG. 5 is a schematic view corresponding to FIGS. 2 and 4 showing an operating state of the pin joining means.
FIG. 6 is a longitudinal front view corresponding to FIG. 3 and showing a modification of the first pile foundation structure.
FIG. 7 is a longitudinal front view corresponding to FIG. 2 and showing a main part of the second pile foundation structure.
FIG. 8 is a longitudinal front view corresponding to FIG. 2 and showing the main part of the third pile foundation structure.
FIG. 9 is a longitudinal sectional front view corresponding to FIG. 2 showing the main part of the fourth pile foundation structure.
FIG. 10 is a longitudinal sectional front view corresponding to FIG. 2 showing a main part of a fifth pile foundation structure.
FIG. 11 is a longitudinal front view corresponding to FIG. 2 and showing the main part of the sixth pile foundation structure.
FIG. 12 is a longitudinal front view corresponding to FIG. 2 and showing the main part of the seventh pile foundation structure.
FIG. 13 is a longitudinal front view showing a conventional pile foundation structure.
[Explanation of symbols]
  DESCRIPTION OF SYMBOLS 1,10 ... Foundation pile, 1a, 10a ... Pile head, 1c ... Hollow part, 2 ... Foundation footing, 2a ... Part (filling part) of footing, 3 ... Pin joining means, 3a ... Sealed space, 3b ... Ring Gap, 4 ... Lower support member, 5 ... Upper support member, 6 ... Flexible member, 7 ... Reinforcing support plate, 9 ... Scraper, 9a ... Scraper part( Scraper inner circumference )41 ... Cylinder part, 41a... Inner peripheral surface of cylinder part51. Piston part,51a ... outer peripheral surface of the piston part,52 ... Sealing member.

Claims (2)

Through an incompressible flexible member in which the upper bearing member attached to the lower part of the foundation footing and the lower bearing member attached to the head of the foundation pile are hermetically filled between the upper and lower opposing surfaces of both bearing members. Pile foundation structure that is pin-joined so as to be relatively rotatable,
The lower support member has a bottomed cylindrical cylinder portion that opens upward,
The upper support member has a piston portion that is rotatably fitted in a predetermined range with respect to the axis of the cylinder portion,
At the lower end of the piston portion, a lower end outer peripheral surface of the piston portion and an inner portion of the cylinder portion facing the piston portion are formed in order to form a sealed space for sealing and filling the flexible member between the upper and lower opposing surfaces of the cylinder portion and the piston portion. A sealing member that seals between the peripheral surface is provided,
Elasticity with at least the upper end of the annular gap formed between the opposed peripheral surfaces of the cylinder part and the piston part, with the outer peripheral part fixed to the inner peripheral surface of the cylinder part and the inner peripheral part pressed against the outer peripheral surface of the piston part configured to Rimitsu closed sealed by the annular scraper made of wood, when the cylinder portion and the piston portion is displaced relative to elastically deform the scraper follows the opening of the annular gap to the shape change The seal function that always seals with the annular scraper and the scraper function that the inner peripheral part of the scraper relatively moves while rubbing the outer peripheral surface of the piston part with relative displacement of the cylinder part and the piston part are exhibited. Pile foundation structure characterized by   The pile foundation structure according to claim 1, wherein the flexible member is a solid solid body made of rubber.

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