JP2015190302A - Pile head base isolation joint structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a pile head base isolation joint structure which can reduce construction labor, which is excellent in dynamic performance, and which has sufficient strength.SOLUTION: In a pile head base isolation joint structure, a base-isolating device 5 for base-isolating and supporting a skeleton 7 is joined via a base plate 6 onto a concrete pedestal 2 provided in such a manner as to cover a pile head 1a of a foundation pile 1 having an outer peripheral part made of a steel pipe 12. A bearing implement 13 for transferring vertical stress by an almost horizontal plate surface between itself and the concrete pedestal 2 is attached to an outer peripheral surface of the steel pipe 12 of the pile head 1a.

Description

  The present invention relates to a structure in which a frame is isolated and supported on a pile head of a foundation pile in a building via a seismic isolation device.

  In various buildings, seismic isolation support is provided to the pile heads of foundation piles via a seismic isolation device to attenuate the vibrations transmitted from the ground to the building's structure due to the earthquake, thereby reducing the stress and deformation generated in the structure. It is known.

  FIG. 8 shows a conventional pile head seismic isolation structure according to the prior art, wherein reference numeral 101 is a steel pipe pile as a foundation pile placed on the ground G, and 102 is formed so as to cover the pile head of the steel pipe pile 101. A concrete base having a reinforced concrete structure, 103 is a foundation slab, 104 is a base plate 105 made of a steel plate and the like, and a laminated rubber attached on the concrete base 102 via an anchor bar 106 fastened to the base plate 105 with a cap nut 106a. A base isolation device 105 is a building frame supported on the base isolation device 104. Moreover, the pile head anchor reinforcement 107 is being fixed to the pile head of the steel pipe pile 101 (for example, refer the following patent document).

  That is, according to this pile head seismic isolation structure, vertical load and stress due to earthquake are transmitted between the steel pipe pile 101 and the frame 105 via the concrete pedestal 102 and the seismic isolation device 104.

JP 2011-226066 A

  However, according to the above structure, the stress transmission is performed by the adhesion between the anchor bars 106 and the pile head anchor bars 107 and the concrete pedestal 102, so that the number of the anchor bars 106 and the pile head anchor bars 107 is increased and the accommodation is complicated. There is a problem of becoming. Further, since stress transmission is performed through the anchor bars 106 and the pile head anchor bars 107 and the concrete pedestal 102, the level difference between the pile head of the steel pipe pile 101 and the base plate 105 becomes large. The problem that construction labor is required due to an increase in the amount of excavated soil in the vicinity of the root cutting and an increase in the number of welded portions of the pile head anchor bars 107 to the steel pipe pile 101 is pointed out.

  The present invention has been made in view of the above points, and the technical problem is a pile that can reduce the labor of construction, has excellent mechanical performance, and has sufficient proof stress. It is to provide a head-isolated joint structure.

  As a means for effectively solving the technical problem described above, the pile head seismic isolation structure according to the invention of claim 1 is a concrete pedestal provided so that the outer peripheral portion covers a pile head of a foundation pile made of a steel pipe. In the pile head seismic isolation structure formed by connecting a base isolation device for base isolation to the base via a base plate, a substantially horizontal surface between the steel pipe outer peripheral surface of the pile head and the concrete pedestal Is attached with a supporting jig for transmitting the stress in the vertical direction.

  According to the configuration of claim 1, since the bearing jig attached to the outer peripheral surface of the pile head of the foundation pile performs vertical stress transmission from the concrete pedestal to the foundation pile by a substantially horizontal surface, It is possible to efficiently transmit the stress in the vertical direction with a small number as compared with the case where the anchor bars are used. Therefore, even when the steel pipe is attached to the steel pipe in the field, the work can be greatly reduced.

  The pile head seismic isolation structure according to the invention of claim 2 is the structure according to claim 1, wherein the concrete pedestal is an outer cylindrical body comprising a pile head of a foundation pile and a steel pipe surrounding the pile head from the outer peripheral side. A second supporting jig is mounted on the inner peripheral surface of the outer cylindrical body to transmit a stress in the vertical direction with a substantially horizontal surface between the outer wall and the concrete base.

  According to the configuration of the second aspect, the second bearing jig attached to the inner peripheral surface of the outer cylindrical body transmits the stress in the vertical direction to the concrete base by the substantially horizontal surface. It is possible to efficiently transmit the stress in the vertical direction with a smaller number than in the case of using it. Therefore, even when it is attached to the steel pipe on the site by welding, the work can be greatly reduced.

  The pile head seismic isolation joint structure according to claim 3 is the structure according to claim 1, wherein the anchor bar coupled to the base plate of the base isolation device via a cap nut for attaching the base isolation device is It is arranged adjacent to the jig.

  According to the configuration of the third aspect, the vertical stress transmitted from the base plate to the concrete pedestal via the cap nut and the anchor bar is transmitted from the bearing jig to the pile head of the foundation pile.

  The pile head seismic isolation structure according to the invention of claim 4 is the structure according to claim 1, wherein a plurality of cap nuts for fixing the seismic isolation device to the base plate are positioned on the outer peripheral side of the pile head in the circumferential direction. Are attached at appropriate intervals, and reinforcing bars are arranged between the cap nut and the supporting jig.

  According to the structure of Claim 4, the reinforcement with respect to the horizontal stress by an earthquake etc. can be improved with the reinforcing bar arrange | positioned between a cap nut and a bearing jig.

  The pile-head seismic isolation structure according to the invention of claim 5 is the structure according to claim 2, wherein the support pressure jig and the second support pressure jig are such that a part of their vertical projection regions overlap each other. The circumferential widths of the vertical projection regions of the bearing jig are provided at a plurality of locations in the circumferential direction, respectively, and are smaller than the circumferential width between the second bearing jigs adjacent in the circumferential direction.

  According to the structure of Claim 5, since the vertical projection area | region of the bearing pressure jig and the 2nd pressure bearing jig has mutually overlapped, the stress transmission of a perpendicular direction is efficient between a concrete base and a pile head. Often done. During construction, the second pile bearing jig attached to the inner circumferential surface of the outer cylinder is not interfered with the bearing bearing jig attached to the outer circumferential surface of the pile head. After extrapolating the outer cylinder body to the outer periphery, the outer cylinder body can be rotated as appropriate so that the vertical projection areas of the bearing pressure jig and the second bearing pressure jig partially overlap each other. And then, a concrete pedestal can be constructed by filling the space with concrete between the pile head and the outer cylinder.

  According to the pile head seismic isolation structure according to the present invention, it is possible to efficiently transmit stress with a small number of bearing jigs, so it is possible to reduce on-site welding work during construction and extend in the vertical direction. Since the level difference between the pile head and the base plate is reduced as compared with the structure in which stress is transmitted via the anchor bars, the amount of excavated soil at the root cutting near the pile head can be reduced during construction.

1 shows a first embodiment of a pile head seismic isolation structure according to the present invention, in which (A) is a vertical sectional view of an essential part, (B) is a sectional view taken along line BB ′ in (A), (C). FIG. 6 is a cross-sectional view taken along the line CC ′ in FIG. The 2nd embodiment of the pile head seismic isolation structure which concerns on this invention is shown, (A) is principal part vertical sectional drawing, (B) is BB 'sectional drawing in (A), (C). FIG. 6 is a cross-sectional view taken along the line CC ′ in FIG. The 3rd embodiment of the pile head seismic isolation structure which concerns on this invention is shown, (A) is principal part vertical sectional drawing, (B) is BB 'sectional drawing in (A), (C). FIG. 6 is a cross-sectional view taken along the line CC ′ in FIG. The 4th Embodiment of the pile head seismic isolation structure which concerns on this invention is shown, (A) is principal part vertical sectional drawing, (B) is B-B 'sectional drawing in (A). The 5th Embodiment of the pile head seismic isolation structure which concerns on this invention is shown, (A) is principal part vertical sectional drawing, (B) is B-B 'sectional drawing in (A). The 6th embodiment of the pile head seismic isolation structure concerning this invention is shown, (A) is principal part vertical sectional drawing, (B) is B-B 'sectional drawing in (A). The 7th embodiment of the pile head seismic isolation structure which concerns on this invention is shown, (A) is principal part vertical sectional drawing, (B) is B-B 'sectional drawing in (A). An example of the pile head seismic isolation structure which concerns on the prior art is shown, (A) is a partial vertical sectional view, (B) is a B-B 'sectional view in (A).

  Hereinafter, preferred embodiments of a pile head seismic isolation structure according to the present invention will be described with reference to the drawings.

  First, in the first embodiment shown in FIG. 1, reference numeral 1 is a foundation pile made of a steel pipe concrete pile placed on the ground G, that is, a composite structure in which a steel pipe 12 is integrated on the outer periphery of a concrete pile 11. It has become. Reference numeral 2 is a concrete pedestal formed so as to cover the pile head 1a of the foundation pile 1, 3 is an outer cylindrical body made of a steel pipe surrounding the pile head 1a from the outer peripheral side, 4 is the foundation slab of the building, 5 is the upper and lower The seismic isolation device composed of the flanges 51 and 52 and the laminated rubber 53 between them, 6 is a base plate composed of a steel plate or the like welded to the upper end of the outer cylindrical body 3, and 7 is a building frame supported on the seismic isolation device 5. .

  The concrete pedestal 2 is formed by filling concrete between the steel pipe 12 in the pile head 1a and the outer cylindrical body 3 on the outer peripheral side thereof. The upper part of the concrete pedestal 2 (the portion covering the upper side of the pile head 1a). An upper reinforcing bar 31 is embedded in the lower part, and a lower reinforcing bar 32 is embedded in the lower part. Further, the lower flange 52 of the seismic isolation device 5 is fastened to the base plate 6 by a plurality of bolts 54 in the circumferential direction and a cap nut 55 screwed on the bolts 54.

  On the outer peripheral surface of the steel pipe 12 in the pile head 1a of the foundation pile 1, support bearing jigs 13 are attached at a plurality of locations in the circumferential direction (four locations at intervals of 90 degrees in the illustrated example). This bearing jig 13 is made of a metal plate such as a steel plate, and has a substantially horizontal plate-like bearing flange 13a and a reinforcement provided so as to be orthogonal to the bearing flange 13a from above and below. It consists of ribs 13b and is fixed to the outer peripheral surface of the steel pipe 12 by welding or the like.

  On the other hand, on the inner peripheral surface of the outer cylindrical body 3, a second supporting jig 33 is located at a height different from the supporting jig 13 (below the supporting jig 13 in the illustrated example). It is attached at a plurality of places in the circumferential direction (in the example shown, four places at intervals of 90 degrees). The second bearing jig 33 is made of a metal plate such as a steel plate, and is provided with a substantially horizontal plate-shaped bearing flange 33a and perpendicular to the bearing flange 33a from above and below. It consists of reinforcing ribs 33b and is fixed to the outer peripheral surface of the inner peripheral surface of the outer cylindrical body 3 by welding or the like.

  Here, the circumferential width of the vertical projection region of the bearing jig 13, specifically, the horizontal width W 1 of the bearing flange 13 a in the bearing jig 13 is the second bearing pressure adjacent in the circumferential direction. It is smaller than the circumferential width W2 between the bearing flanges 33a and 33a of the jigs 33 and 33, and the bearing flange 13a of the bearing jig 13 and the bearing flange 33a of the second bearing jig 33. Are substantially in phase with each other so that parts of the vertical projection areas overlap each other.

  In the above configuration, when the construction is performed, the foundation pile 1 is first placed on the ground G, and then the ground around the pile head 1a is excavated to a necessary depth, and abandoned concrete (not shown) is placed. To do. Moreover, the bearing jig 13 is welded to the outer peripheral surface of the steel pipe 12 in the pile head 1a of the foundation pile 1 at predetermined intervals in the circumferential direction.

  Next, after arranging the lower reinforcing bars 32 as necessary, the outer cylinder 3 is extrapolated to the outer peripheral space of the pile head 1 a of the foundation pile 1. A second bearing jig 33 is welded to the inner peripheral surface of the outer cylinder 3 in advance at the factory, and a base plate 6 is welded to the upper end, and a bolt 54 and a cap nut 55 screwed to the bolt 54 are fitted. Is temporarily fixed to the base plate 6 and an upper reinforcing bar 31 is provided as necessary.

  When the outer cylinder 3 is extrapolated to the outer peripheral space of the pile head 1a of the foundation pile 1, the second support jig 33 is positioned so as not to interfere with the support jig 13 of the pile head 1a. The outer cylinder 3 is lowered from above the pile head 1a. When the second support jig 33 passes between the support jigs 13 and 13 and falls to a predetermined height, the second support jig 33 is positioned just below the support jig 13 (support The outer cylinder 3 is appropriately rotated so that the vertical projection regions of the pressure jig 13 and the second bearing jig 33 overlap each other), and the outer cylinder 3 is temporarily fixed.

  Next, concrete is poured into the space between the pile head 1 a and the outer cylindrical body 3 from the inner peripheral hole 6 a of the base plate 6. And this concrete hardens | cures with time, the pile head 1a of the foundation pile 1, the bearing jig 13, the outer cylinder 3, the base plate 6, the second bearing jig 33 (and the upper reinforcing bar 31, the lower reinforcement) When the concrete pedestal 2 integrated with the bars 32) and the like is constructed, the seismic isolation device 5 is mounted on the base plate 6 by the bolts 54 and the cap nuts 55 screwed into the bolts 54.

  According to the first embodiment, the stress due to the vertical load from the upper structure such as the casing 7 acting on the base plate 6 via the seismic isolation device 5 is transmitted from the base plate 6 to the concrete pedestal 2, and the base plate 6. Is transmitted to the concrete pedestal 2 also from the second bearing jig 33 provided on the outer cylindrical body 3 integrated with the base pile 1 and further transmitted from the concrete pedestal 2 to the foundation pile 1 via the bearing jig 13.

  In this configuration, the bearing flange 13a of the bearing jig 13 and the bearing flange 33a of the second bearing jig 33 have a wide stress transmission area, and the bearing flange 13a of the bearing jig 13 Since the bearing flange 33a of the second bearing jig 33 is positioned so as to overlap vertically, stress transmission with the concrete pedestal 2 is efficiently performed. Therefore, the level difference between the pile head 1a and the base plate 6 can be reduced as compared with the case where stress is transmitted only through the anchor bars, and as a result, the ground G around the pile head 1a during construction is reduced. The amount of excavated soil for root cutting can be reduced.

  Next, FIG. 2 shows a second embodiment of a pile head seismic isolation structure according to the present invention. In this second embodiment, the difference from the first embodiment described above is that the bearing jig 13 extends downward from the bearing flange 13c in the form of a fan concentric with the pile head 1a and the inner peripheral edge thereof. The second support pressure jig 33 has a substantially horizontal support flange 33c concentric with the outer cylindrical body 3, and a lower side from the outer periphery thereof. The curved support plate 33d is welded to the steel pipe 12 of the pile head 1a. In this case, the same effect as that of the first embodiment is obtained.

  FIG. 3 shows a third embodiment of a pile head seismic isolation structure according to the present invention. This embodiment is only a flange in which the support jig 13 forms a fan shape concentric with the pile head 1a. The inner peripheral edge is welded to the steel pipe 12 of the pile head 1a, and the second bearing jig 33 is composed only of a flange concentric with the outer cylindrical body 3, and the outer peripheral edge is the outer cylindrical body. In this case, the same effect as that of the first embodiment is obtained.

  2 and 3 show a case where the upper reinforcing bar 31 and the lower reinforcing bar 32 in the first embodiment are not provided.

  Next, FIG. 4 shows a fourth embodiment of a pile head seismic isolation structure according to the present invention. The fourth embodiment differs from the first to third embodiments described above on the base plate 6 instead of providing the second bearing jig 33 on the inner peripheral surface of the outer cylinder 3. An anchor bar 34 is provided via a cap nut 55 that is screwed to a bolt 54 that fastens the lower flange 52 of the seismic isolation device 5, and the outer cylinder 3 and the base plate 6 are not welded in advance, and are independent members. There is in point. The upper end of the anchor bar 34 is screwed to the lower part of the cap nut 55 and extends in a substantially vertical direction through a position between the supporting jigs 13 and 13.

  In the construction in this case as well, after the foundation pile 1 is first placed on the ground G, the ground around the pile head 1a is excavated to a necessary depth, and abandoned concrete (not shown) is placed. . Moreover, the bearing jig 13 is welded to the outer peripheral surface of the steel pipe 12 in the pile head 1a of the foundation pile 1 at predetermined intervals in the circumferential direction. And after arrange | positioning a lower reinforcement (not shown) as needed, the outer cylinder 3 is extrapolated to the outer peripheral space of the pile head 1a of the foundation pile 1, and it positions to predetermined | prescribed height and temporarily fixes.

  Next, the base plate 6 is placed on the upper end of the outer cylindrical body 3 and temporarily fixed. A bolt 54 and a cap nut 55 screwed into the bolt 54 are attached to the base plate 6 in advance, and an anchor bar 34 is attached via the cap nut 55. When the base plate 6 is placed on the upper end of the outer cylindrical body 3, the base plate 6 is provided so that the anchor bars 34 inserted into the inner periphery of the outer cylindrical body 3 do not interfere with the bearing jig 13 of the pile head 1a. Positioning is performed while appropriately rotating.

  Next, concrete is poured into the space between the pile head 1 a and the outer cylindrical body 3 from the inner peripheral hole 6 a of the base plate 6. And if this concrete hardens | cures with time, the concrete base 2 integrated with the pile head 1a of the foundation pile 1, the bearing jig 13, the outer cylinder 3, the anchor reinforcement 34, the base plate 6, etc. will be constructed. The base isolation device 5 is mounted on the base plate 6 with bolts 54 and cap nuts 55 screwed into the bolts 54.

  According to the fourth embodiment, the stress due to the vertical load from the upper structure such as the casing 7 acting on the base plate 6 via the seismic isolation device 5 is transmitted from the base plate 6 to the concrete pedestal 2, and the base plate 6. In addition, the anchor bar 34 that is tightly coupled to the concrete base 2 is also transmitted to the concrete base 2, and further transmitted from the concrete base 2 to the foundation pile 1 via the bearing jig 13.

  And in this structure, since the bearing flange 13a in the bearing jig 13 has a wide stress transmission area, the stress transmission between the concrete pedestals 2 is performed efficiently. Therefore, the level difference between the pile head 1a and the base plate 6 can be reduced as compared with the case where stress is transmitted only through the anchor bars, and as a result, the ground G around the pile head 1a during construction is reduced. The amount of excavated soil for root cutting can be reduced.

  Further, since the anchor bars 34 are attached by screwing them into the cap nuts 55 for attaching the seismic isolation device 5, it is possible to reduce welding work at the site. Further, since the outer cylinder 3 and the base plate 6 are not welded in advance and are independent members, the number of man-hours in the factory can be reduced.

  Next, FIG. 5 shows a fifth embodiment of a pile head seismic isolation structure according to the present invention. In the fifth embodiment, an outer peripheral reinforcing bar 35 is embedded in the vicinity of the outer periphery of the concrete base 2 instead of the outer cylindrical body 3 in the fourth embodiment described above. The outer circumferential reinforcing bar 35 includes a plurality of vertical hoop bars 35a and a plurality of circumferential reinforcing bars 35b extending in a substantially vertical direction perpendicular to the hoop bars 35a.

  In the construction in this case as well, after the foundation pile 1 is first placed on the ground G, the ground around the pile head 1a is excavated to a necessary depth, and abandoned concrete (not shown) is placed. . Moreover, the bearing jig 13 is welded to the outer peripheral surface of the steel pipe 12 in the pile head 1a of the foundation pile 1 at predetermined intervals in the circumferential direction.

  And after performing necessary reinforcement arrangement | positioning, such as the outer periphery reinforcement bar | burr 35, in the excavation hole around the pile head 1a, the base plate 6 is mounted on the said excavation hole and temporarily fixed. A bolt 54 and a cap nut 55 screwed into the bolt 54 are attached to the base plate 6 in advance, and an anchor bar 34 is attached via the cap nut 55. When the base plate 6 is placed, alignment is performed while appropriately rotating the base plate 6 so that the anchor bar 34 inserted into the excavation hole does not interfere with the bearing jig 13 of the pile head 1a.

  Next, concrete is cast from the inner peripheral hole 6a of the base plate 6 into the excavation hole around the pile head 1a. And if this concrete hardens | cures with time, the concrete base 2 integrated with the pile head 1a of the foundation pile 1, the bearing jig 13, the anchor reinforcement 34, the outer periphery reinforcement 35, the base plate 6, etc. will be constructed. The base isolation device 5 is mounted on the base plate 6 with bolts 54 and cap nuts 55 screwed into the bolts 54.

  And the said 5th form can also implement | achieve the effect similar to the 4th form demonstrated previously.

  Next, FIG. 6 shows a sixth embodiment of a pile head seismic isolation structure according to the present invention. In the sixth embodiment, instead of the anchor bars 34 and the outer periphery reinforcing bars 35 in the fifth embodiment described above, the cap nut 55 attached to the base plate 6 and the outer peripheral surface of the steel pipe 12 of the pile head 1a are attached. The reinforcing bar 36 is disposed between the support jigs 13. In this embodiment, a steel pipe pile is adopted as the foundation pile 1.

  The reinforcing bar 36 includes a hoop bar 36a provided so as to bind the cap nuts 55, 55,... Arranged in the circumferential direction, and a plurality of hoop bars 36b extending concentrically with the hoop bar 36a. It consists of a plurality of longitudinal reinforcing bars 36c in the circumferential direction that form a substantially rectangular shape along a vertical plane passing through the axis of the pile head 1a. The vertical reinforcing bar 36c includes a portion extending in the radial direction at a position sandwiching each cap nut 55 from both sides in the circumferential direction, a portion extending from the inner diameter end of this portion and extending the inner periphery of the foundation pile 1 in the vertical direction, It has a portion that extends from the outer diameter end of the portion extending in the radial direction and extends the outer peripheral portion of the concrete pedestal 2 in the vertical direction and a portion that extends from the lower end toward the inner diameter side. It is orthogonal to 36a, 36b.

  In the construction in this case, the foundation pile 1 is first placed on the ground G, and then the ground around the pile head 1a is excavated to a necessary depth, and abandoned concrete (not shown) is placed. Moreover, the bearing jig 13 is welded to the outer peripheral surface of the steel pipe 12 in the pile head 1a of the foundation pile 1 at predetermined intervals in the circumferential direction. After the reinforcing bars 36 including the hoop bars 36a and 36b and the vertical reinforcing bars 36c are disposed, the outer cylinder 3 is extrapolated to the outer peripheral space of the pile head 1a of the foundation pile 1 and positioned at a predetermined height. Fix it.

  Next, the base plate 6 to which the bolt 54 and the cap nut 55 screwed in advance are mounted is placed on the upper end of the outer cylinder 3 and temporarily fixed. At this time, alignment is performed while appropriately rotating the base plate 6 so that the cap nut 55 inserted into the inner periphery of the outer cylinder 3 is positioned between the longitudinal reinforcing bars 36c and 36c.

  Then, concrete is placed from the inner peripheral hole 6 a of the base plate 6 into the space between the pile head 1 a and the outer cylinder 3. And if this concrete hardens | cures with time, the concrete base 2 integrated with the pile head 1a of the foundation pile 1, the bearing jig 13, the outer cylinder 3, the reinforcing bar 36, the base plate 6, etc. will be constructed. The base isolation device 5 is mounted on the base plate 6 with bolts 54 and cap nuts 55 screwed into the bolts 54.

  And also in the said 6th form, while using the bearing pressure jig 13, construction becomes easy, stress transmission is performed efficiently and the level difference between the pile head 1a and the base plate 6 can also be made small. .

  Next, FIG. 7 shows a seventh embodiment of a pile head seismic isolation structure according to the present invention. In the seventh embodiment, the outer cylindrical body 3 in the sixth embodiment described above is abolished, the volume of the concrete base 2 is increased, and a rectangular parallelepiped shape is obtained.

  In the construction in this case, the foundation pile 1 is first placed on the ground G, and then the ground around the pile head 1a is excavated to a necessary depth, and abandoned concrete (not shown) is placed. Moreover, the bearing jig 13 is welded to the outer peripheral surface of the steel pipe 12 in the pile head 1a of the foundation pile 1 at predetermined intervals in the circumferential direction.

  A reinforcing bar 36 including hoop bars 36a and 36b and a vertical reinforcing bar 36c is disposed in the excavation hole around the pile head 1a, and further, a hook bar 37 is disposed on the outer periphery of the reinforcing bar 36. The base plate 6 to which the screwed cap nut 55 is attached is placed on the excavation hole and temporarily fixed. At this time, alignment is performed while appropriately rotating the base plate 6 so that the cap nut 55 inserted into the excavation hole is positioned between the vertical reinforcing bars 36c and 36c.

  Next, concrete is cast from the inner peripheral hole 6a of the base plate 6 into the excavation hole around the pile head 1a. And if this concrete hardens | cures with time, the concrete base 2 integrated with the pile head 1a of the foundation pile 1, the bearing jig 13, the outer cylinder 3, the reinforcing bar 36, the base plate 6, etc. will be constructed. The base isolation device 5 is mounted on the base plate 6 with bolts 54 and cap nuts 55 screwed into the bolts 54.

  The seventh embodiment can achieve the same effect as the sixth embodiment described above.

DESCRIPTION OF SYMBOLS 1 Foundation pile 1a Pile head 11 Outer shell steel pipe 13 Bearing jig 2 Concrete base 3 Outer cylinder 33 Second bearing jig 34 Anchor reinforcement 35 Outer reinforcement reinforcement 36 Reinforcement reinforcement Kamabashi 5 Seismic isolation device 54 Bolt 55 Bag Nut 6 Base plate 7 Housing

Claims (5)

  In the pile head seismic isolation joint structure formed by joining the base isolation plate with the seismic isolation device that supports the seismic isolation on the concrete pedestal provided so that the outer periphery covers the pile head of the foundation pile made of steel pipe, A pile head seismic isolation structure, wherein a support bearing jig for transmitting a stress in a vertical direction is attached to a steel pipe outer peripheral surface of the pile head with a substantially horizontal plate surface between the pile head and the concrete base.   A concrete pedestal is filled between a pile head of a foundation pile and an outer cylindrical body made of a steel pipe surrounding the pile head from the outer peripheral side, and is substantially horizontal between the inner peripheral surface of the outer cylindrical body and the concrete pedestal. The pile head seismic isolation structure according to claim 1, wherein a second bearing jig for transmitting a stress in a vertical direction is attached by a flat plate surface.   The pile head seismic isolation according to claim 1, wherein an anchor bar coupled to a base plate of the seismic isolation device via a cap nut to which the seismic isolation device is attached is disposed adjacent to the support jig. Junction structure.   A plurality of cap nuts that fix the seismic isolation device are attached to the base plate on the outer periphery of the pile head at appropriate intervals in the circumferential direction, and reinforcing bars are arranged between the cap nuts and the supporting jig. The pile-head seismic isolation structure according to claim 1.   The support bearing jig and the second support jig are provided at a plurality of locations in the circumferential direction so that parts of the vertical projection area overlap each other, and the circumferential width of the vertical projection area of the support jig The pile head seismic isolation joint structure according to claim 2, wherein is smaller than the circumferential width between the second bearing jigs adjacent in the circumferential direction.

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