JP6046984B2 - Seismic isolation construction method and precast concrete footing - Google Patents

Description

  The present invention relates to a base isolation construction method and a precast concrete footing.

  A precast PCa board with a plurality of anchor members projecting from the top surface is connected to the upper flange of the laminated rubber, and then the concrete is placed on the PCa board to construct the upper foundation. A construction method is known (see, for example, Patent Document 1).

JP 2012-067524 A

  However, in the technique disclosed in Patent Document 1, when a column is set up on a seismic isolation device, it is necessary to drive a post-construction anchor or the like into the upper foundation, or to incorporate a column anchor or the like when constructing the upper foundation. Therefore, it takes time to construct the pillar.

  In view of the above facts, an object of the present invention is to improve the workability of a column standing on a seismic isolation device.

The construction method of the seismic isolation foundation according to the first aspect is made of precast concrete in which an anchor member connected to a column or a column member constituting the column is provided on a seismic isolation device installed on a lower foundation. A footing installation step of installing a footing; and an upper foundation construction step of constructing an upper foundation by placing concrete on the footing so that the anchor member or the column member is exposed from the upper end. .

According to the construction method of the seismic isolation foundation according to the first aspect , first, in the footing installation process, the anchor member connected to the column on the seismic isolation device installed on the lower foundation, or the column member constituting the column A precast concrete footing is installed. Next, in the upper foundation construction step, concrete is placed on the footing, and the upper foundation is constructed so that the anchor member or the column member is exposed from the upper end.

  Thus, when a column is erected on the seismic isolation device, the column is connected to the anchor member exposed from the upper end of the upper foundation, or another column member is connected to the column member, so that the column is mounted on the seismic isolation device. Can stand. Therefore, the workability is improved.

  Further, by using the precast concrete footing provided with the anchor member or the column member, the concrete placement for footing on the seismic isolation device, the assembling work of the anchor member or the column member, or the like becomes unnecessary. Therefore, the workability is further improved.

The base-isolation foundation construction method according to the second aspect is the base-isolation base construction method according to the first aspect, before the footing installation step, around the anchor member or the column member as the upper foundation. It includes a beam bar reinforcement process that arranges the beam reinforcement of the foundation beam.

According to the construction method of the seismic isolation foundation according to the second aspect , the beam of the foundation beam as the upper foundation is arranged around the anchor member or the column member provided in the footing in the beam reinforcement arrangement process before the footing installation process. Arrange the main bars.

  As a result, the work of arranging the main bar of the beam on the seismic isolation device becomes unnecessary, so that the workability is further improved. Further, for example, by arranging the beam main reinforcement of the foundation beam on a wide work table or the like, the accuracy of the arrangement of the beam main reinforcement is improved.

The base isolation construction method according to the third aspect includes the footing manufacturing step of manufacturing the footing before the footing installation step in the base isolation base construction method according to the first aspect or the second aspect, In the footing manufacturing process, a plurality of U-shaped reinforcing bars opened upward are arranged in a lattice pattern around the anchor member or the column member, and the U-shaped reinforcing bars protrude from the upper surface. After placing the footing concrete in this manner, the upper reinforcing bar is passed between the opening-side end portions of the U-shaped reinforcing bar.

According to the construction method of the seismic isolation foundation according to the third aspect , in the footing manufacturing process before the footing installation process, a plurality of U-shaped reinforcing bars opened upwards around the anchor member or the column member in a plan view The concrete for footing is placed so that the bars are arranged in a lattice pattern and these U-shaped reinforcing bars protrude from the upper surface. Thereafter, the upper reinforcing bar is passed between the opening-side end portions of the U-shaped reinforcing bar protruding from the upper surface of the footing.

  By using the U-shaped reinforcing bar having an opening at the top in this way, the operator can easily put his hand through the opening. Therefore, compared with the case where the U-shaped reinforcing bar which the lower part opened is used, the reinforcement work of a U-shaped reinforcing bar becomes easy.

  Moreover, the reinforcement effect with respect to a footing and an upper foundation improves by passing an upper reinforcement bar between opening side edge parts in a U-shaped reinforcement bar, and making it frame shape.

  Further, after placing the footing concrete, the upper reinforcing bar is passed between the opening-side end portions of the U-shaped reinforcing bar, so that the U-shaped reinforcing bar can be opened even after the footing concrete is cast. The position of the side end can be easily adjusted.

The precast concrete footing which concerns on a 4th aspect comprises the concrete part in which the fixed surface fixed to the upper flange of a seismic isolation apparatus was formed, the anchor member provided in the said concrete part, and a pillar connected, or the said pillar And a main beam of the foundation beam arranged around the anchor member or the column member.

According to the precast concrete footing according to the fourth aspect , an anchor member to which a column is connected or a column member constituting the column is provided in the concrete part, and the main beam of the foundation beam is arranged around the anchor member or the column member. By arranging the lines, the work of assembling the anchor member or the column member on the seismic isolation device and the work of arranging the beam main bars of the foundation beam become unnecessary. Therefore, the workability is improved.

  Since this invention was set as said structure, it can improve the workability of the pillar standing on a seismic isolation apparatus.

It is a disassembled elevation view which shows the work bench | platform, the base plate, the mount frame, and the anchor bolt in one Embodiment of this invention. It is a top view which shows the baseplate shown by FIG. It is a decomposition | disassembly elevational view which shows the U-shaped reinforcement bar and upper reinforcement bar in one Embodiment of this invention. It is an elevational view showing upper and lower beam main bars and shear reinforcement bars of a foundation beam in an embodiment of the present invention. It is an elevation view which shows the state before installing the footing which concerns on one Embodiment of this invention on a seismic isolation apparatus. It is an elevation view which shows the state after installing the footing which concerns on one Embodiment of this invention on a seismic isolation apparatus, and the state which stood the pillar on the joint part of a foundation beam. It is a longitudinal cross-sectional view which shows the modification of the footing which concerns on one Embodiment of this invention.

  Hereinafter, a construction method and a precast concrete footing according to an embodiment of the present invention will be described with reference to the drawings.

  The base isolation construction method according to the present embodiment includes a footing manufacturing process, a beam main bar arranging process, a footing installation process, and an upper foundation construction process.

  First, the footing manufacturing process will be described. In the footing manufacturing process, a precast concrete footing (hereinafter simply referred to as “footing”) 10 made of precast concrete is manufactured. As shown in FIG. 6, the footing 10 according to the present embodiment is provided on the concrete portion 12 protruding from the lower surface of the foundation beam 80, the base plate 30 provided on the lower surface of the concrete portion 12, and the upper surface of the concrete portion 12. A plurality of anchor bolts 60 as a plurality of anchor members and upper and lower beam main bars 82A and 82B (see FIG. 5) arranged around the plurality of anchor bolts 60 are provided. The footing 10 is manufactured, for example, in a work space (site yard) secured in the site. The footing 10 can be manufactured at a factory or the like.

  Specifically, first, as shown in FIG. 1, a work table 20 constituting a scaffold is installed in a substantially horizontal position in a work space. The work table 20 secures a horizontal level and also functions as a formwork. The work table 20 is configured by laminating three veneer plates, and a recess 22 for accommodating the base plate 30 is formed on the upper surface thereof. The recess 22 is formed in a substantially rectangular shape in plan view according to the shape and size of the base plate 30, and the depth thereof is set to be substantially the same as the plate thickness of the base plate 30. Thereby, the upper surface of the base plate 30 is substantially flush with the upper surface of the work table 20 in a state where the base plate 30 is accommodated in the recess 22.

  Next, the base plate 30 is fitted into the recess 22 of the work table 20. Thereby, the base plate 30 is arranged substantially horizontally and the base plate 30 is positioned with respect to the work table 20.

  When manufacturing a plurality of footings 10 having different base plate 30 sizes, a recess 22 corresponding to the maximum size of the base plate 30 is formed in the work table 20 and a small base plate 30 is installed in the recess 22. The gap between the base plate 30 and the recess 22 may be filled with a plate-like spacer or the like. It is also possible to form a plurality of recesses 22 in the work table 20 and to manufacture a plurality of footings 10 in parallel.

  The base plate 30 forms a fixing surface of the footing 10 that is fixed to the upper flange 18A of the seismic isolation device 18 to be described later, and is formed of a rectangular steel plate in plan view as shown in FIG. . On the upper surface of the base plate 30, the center position is marked (centered) in a factory or the like, and a lifting jig nut 32, a seismic isolation device cap nut 34, a stud 36, and a mounting bracket (angle piece) 38) is attached by welding or the like. The suspension jig nut 32, the seismic isolation device cap nut 34, the stud 36, and the gantry bracket 38 are embedded in the concrete portion 12 at the lower end.

  The plurality of suspension jig nuts 32 are attachments to which suspension jigs 40 (see FIG. 1) to which a wire such as a lifting machine (not shown) is connected are attached, and are attached to the four corners of the base plate 30, respectively. The plurality of seismic isolation device cap nuts 34 are fasteners to which bolts 24 (see FIG. 5) for fixing the base plate 30 to the upper flange 18A of the seismic isolation device 18 described later are fastened, and are attached to the base plate 30 and the upper flange 18A. They are arranged in a circle according to a plurality of bolt holes (not shown) formed. The plurality of studs 36 are fixing tools that enhance the integrity of the concrete portion 12 and the base plate 30 and are appropriately arranged inside the plurality of seismic isolation device cap nuts 34 arranged in a circle. A plurality (four in this embodiment) of the gantry brackets 38 are attachments to which the gantry 50 to be described later is attached, and are arranged inside the seismic isolation device cap nuts 34 arranged in a circle.

  Next, as shown in FIG. 1, the gantry 50 is attached to the gantry bracket 38 on the base plate 30. The mount 50 as a support member adjusts the mounting height of the anchor bolt 60, and includes a rectangular frame portion 50A in plan view and four leg portions 50B that respectively support corner portions of the frame portion 50A. have. The base 50 is positioned with respect to the base plate 30 by attaching these leg portions 50B to the base bracket 38 by welding or the like.

  Next, a plurality (eight in this embodiment) of anchor bolts 60 are attached to the gantry 50 in an upright state. The plurality of anchor bolts 60 are for fixing a pillar 90 to be described later to the foundation beam 80, and a pillar base 62 is attached to the upper end of the pillar bolt 62 by a nut 64. The column base 62 as the connecting member is formed of a rectangular steel plate in plan view, and the column base (lower end) of the column 90 is joined by welding or the like.

  In addition, a lower frame body 66 that is rectangular in plan is attached to the lower ends of the plurality of anchor bolts 60 by nuts 68. A plurality of anchor bolts 60 are attached to the gantry 50 and held at a predetermined height by placing the lower frame body 66 on the frame portion 50A of the gantry 50 and joining them by welding or bolts (not shown). The The anchor bolt 60 may be appropriately provided with a fixing tool such as a fixing plate.

  Next, as shown in FIG. 3, a plurality of U-shaped reinforcing bars 70 whose tops are opened are arranged around the gantry 50 and the anchor bolt 60. The plurality of U-shaped reinforcing bars 70 are formed by bending reinforcing bars into a U-shape. Further, an opening-side end portion 70 </ b> A of each U-shaped reinforcing bar 70 is provided with a folded portion 70 </ b> B that is folded back inward. A folded portion 72B of an upper reinforcing bar 72 described later is connected to the folded portion 70B. These U-shaped reinforcing bars 70 are arranged in a lattice shape in plan view with the opening facing upward. That is, the plurality of U-shaped reinforcing bars 70 are arranged in a hook shape with an upper opening.

  Next, a mold frame (not shown) is temporarily installed so as to surround the base plate 30, the mount 50, and the U-shaped reinforcing bar 70, and concrete for the footing 10 is placed in the mold frame to form the concrete portion 12. At this time, the concrete for the footing 10 is placed in the mold so that the upper portion of each U-shaped reinforcing bar 70 protrudes upward from the upper surface of the concrete portion 12. Then, the concrete for the footing 10 is cured and the concrete portion 12 is formed, and then the formwork (not shown) is removed.

  Next, the upper reinforcing bars 72 are respectively passed between the opening-side end portions 70 </ b> A of the U-shaped reinforcing bars 70. The upper reinforcing bars 72 extend in the lateral direction, and both end portions 72A are bent downward. At the lower end portions of these both end portions 72A, a folded portion 72B that is folded inward is provided. The upper reinforcing bar 72 is connected to the U-shaped reinforcing bar 70 by binding the folded part 72B with a binding line or the like (not shown) in a state of being overlapped with the folded part 70B of the U-shaped reinforcing bar 70. As a result, a frame-shaped basic reinforcing bar 74 (see FIG. 4) is formed by the upper reinforcing bar 72 and the U-shaped reinforcing bar 70.

  Next, the beam main bar arrangement process will be described. In the beam main bar arrangement process, as shown in FIG. 4, a part of the upper and lower beam main bars 82A and 82B of the foundation beam 80 (see FIG. 6) is arranged around the plurality of anchor bolts 60. Specifically, upper and lower beam main bars 82A and 82B are arranged from both the left and right sides of the anchor bolt 60, and are joined by welding or the like at the center of the footing 10 and around the upper and lower beam main bars 82A and 82B. Shear reinforcement bars 84 are appropriately arranged. At this time, the end portion of the upper beam reinforcing bar 82 </ b> A is placed on the foundation reinforcing bar 74, and the upper beam reinforcing bar 82 </ b> A is supported by the foundation reinforcing bar 74. That is, in this embodiment, the foundation reinforcing bar 74 is used as a beam main bar gantry that supports the end of the upper beam main bar 82A. It is also possible to use a beam main bar stand different from the foundation reinforcing bar 74.

  Next, the footing placement process will be described. In the footing placement step, as shown in FIG. 5, the footing 10 is lifted and moved by a lifting machine (not shown) and the seismic isolation device 18 installed on the lower footing 16 protruding from the upper surface of the foundation slab 14. It is installed on the upper flange 18A. At this time, the base plate 30 of the footing 10 is placed on the upper flange 18A of the seismic isolation device 18, and the bolt 24 penetrating the upper flange 18A and the base plate 30 is fastened to the cap nut 34 for the seismic isolation device. As a result, the base plate 30 that forms the fixing surface of the footing 10 is fixed to the upper flange 18 </ b> A of the seismic isolation device 18.

  In this embodiment, the foundation slab 14 and the lower footing 16 are reinforced concrete. The seismic isolation device 18 is formed of a laminated rubber bearing, and a lower flange 18B thereof is fixed to the upper surface of the lower footing 16 as a lower foundation by a plurality of bolts 26. The seismic isolation device 18 is not limited to a laminated rubber bearing, and may be a sliding bearing, a rolling bearing, or the like.

  Next, the upper foundation construction process will be described. In the upper foundation construction process, as shown in FIG. 6, a formwork (not shown) is temporarily installed around the anchor bolt 60 and the upper and lower beam main bars 82A and 82B, and concrete for the foundation beam 80 is placed in the formwork. To do. At this time, the concrete for the foundation beam 80 is placed in the mold so that the upper end portion of the anchor bolt 60 and the column base 62 are exposed from the upper end of the joint portion 80A of the foundation beam 80 with the column 90. Then, after the concrete for the foundation beam 80 is cured and the foundation beam 80 is constructed, a formwork (not shown) is removed.

  In this embodiment, the recess 86 is formed on the upper surface of the joint 80A of the foundation beam 80, and the upper end of the anchor bolt 60 and the column base 62 are exposed in the recess 86, but the recess 86 is omitted. In addition, the anchor bolt 60 can be protruded from the upper surface of the joint portion 80A in the foundation beam 80. When the recess 86 is formed in the joint portion 80 </ b> A of the foundation beam 80, the bottom wall of the recess 86 becomes the upper end of the foundation beam 80.

  Next, the column building process will be described. In the column erection process, as shown in FIG. 6, an exposed column base type steel column 90 is erected on the column base 62 exposed from the upper end of the foundation beam 80, and the column base portion of the column 90 is mounted. The column base 62 is joined by welding or a bolt (not shown). As a result, the column base of the column 90 is connected to the anchor bolt 60 via the column base 62, and the column base of the column 90 is fixed to the joint 80 </ b> A of the foundation beam 80. Thereafter, the gap between the column base 62 and the bottom wall of the recess 86 is filled with mortar, grout or the like.

  As described above, according to the base isolation construction method according to the present embodiment, the precast concrete footing 10 provided with the anchor bolts 60 is manufactured in advance in the footing manufacturing process, so that the base isolation is achieved. It is not necessary to place concrete for the footing 10 on the device 18 or to install the anchor bolt 60. Therefore, the workability is improved.

  In the upper foundation construction process, the upper end portion of the anchor bolt 60 and the column base 62 are exposed in the formwork so that the upper end portion of the anchor bolt 60 and the column base 62 are exposed from the recess 86 formed on the upper surface of the joint portion 80A of the foundation beam 80. The foundation beam 80 is constructed by placing concrete. Therefore, the column 90 can be fixed to the joint portion 80 </ b> A in the foundation beam 80 by connecting the column base portion of the column 90 to the column base 62 exposed in the recess 86.

  Further, in the present embodiment, in the beam main bar arrangement process, a part of the upper and lower beam main bars 82A and 82B of the foundation beam 80 and the shear reinforcement bar 84 are arranged in advance around the plurality of anchor bolts 60. This arrangement eliminates the work of arranging the upper and lower beam main bars 82A and 82B and the shear reinforcement bar 84 on the seismic isolation device 18. Therefore, the workability is further improved. Further, in this embodiment, the upper and lower beam main bars 82A and 82B and the shear reinforcement bars 84 of the foundation beam 80 are arranged on the stable and wide work table 20, so that the upper and lower beam main bars 82A and 82B are arranged efficiently. In addition, the bar arrangement accuracy is improved, and the inspection work of the upper and lower beam main bars 82A and 82B is easier.

  Moreover, in the present embodiment, when the upper and lower beam main bars 82A and 82B are arranged, the base reinforcing bar 74 is used as a gantry for supporting the upper beam main bar 82A. This eliminates the need for a dedicated stand for supporting the upper beam main reinforcement 82A. Therefore, cost reduction can be achieved.

  Further, in the footing manufacturing process, a plurality of U-shaped reinforcing bars 70 opened upward are arranged around the mount 50 and the anchor bolt 60 in a lattice shape in plan view, and these U-shaped reinforcing bars 70 are arranged. The concrete part 12 is formed by placing concrete for the footing 10 so as to protrude from the upper surface of the concrete part 12. Thereafter, the upper reinforcing bars 72 are passed between the opening-side end portions 70 </ b> A of the U-shaped reinforcing bars 70 protruding from the upper surface of the concrete portion 12 to form the frame-shaped basic reinforcing bars 74.

  As described above, by using the U-shaped reinforcing bar 70 having an upper opening, an operator can easily put his hand inside the U-shaped reinforcing bar 70 from the upper opening. Therefore, compared with the case where the U-shaped reinforcement bar which the lower part opened is used, the arrangement | positioning work of the several U-shaped reinforcement bar 70 becomes easy.

  In addition, after placing the concrete for the footing 10, the U-shaped reinforcement bars 70 are passed through the upper reinforcing bars 72 between the opening-side end portions 70 </ b> A. The position adjustment of the opening side end portion 70A of the character-shaped reinforcing bar 70 can be easily performed. Therefore, the connection work between the folded portion 70B of the U-shaped reinforcing bar 70 and the folded portion 72B of the upper reinforcing bar 72 is facilitated.

  Furthermore, by forming the frame-shaped basic reinforcing bar 74 by the U-shaped reinforcing bar 70 and the upper reinforcing bar 72, the reinforcing effect on the joint 80A of the footing 10 and the basic beam 80 is improved.

  Furthermore, by producing the footing 10 in parallel with the construction of the foundation slab 14 and the like, compared with the case of constructing the footing 10 on the seismic isolation device 18, the work period is shortened and the work man-hours are leveled. be able to.

  Next, a modification of the above embodiment will be described.

  In the said embodiment, although the example which provided the anchor bolt 60 via the mount frame 50 was shown in the upper surface of the concrete part 12 of the footing 10 in the footing manufacturing process, it is not restricted to this. For example, the anchor bolt 60 may be integrated with the concrete portion 12 by embedding a part of the anchor bolt 60 (lower portion or lower end portion) in the concrete portion 12. That is, the anchor bolt 60 provided on the footing 10 in the above embodiment is protruded from the anchor bolt 60 supported by a support member such as the gantry 50 embedded in the concrete portion 12 or the upper surface of the concrete portion 12. The concept includes an anchor bolt 60 or the like partially embedded in the concrete portion 12.

  Further, in the footing manufacturing process, it is not always necessary to form the entire concrete part 12 (all). For example, a part of the concrete part 12 may be formed after the footing installation process, or the foundation in the upper foundation construction process. A part of the concrete portion 12 may be formed simultaneously with the construction of the beam 80.

  Moreover, in the said embodiment, although the example which connected the pillar 90 to the anchor bolt 60 via the pillar base 62 was shown, it is not restricted to this. The pillar 90 may be connected to the anchor bolt 60 via a connecting member different from the pillar base 62, or the pillar 90 may be directly connected to the anchor bolt 60.

  Moreover, in the said embodiment, although the anchor bolt 60 was demonstrated to the example as an anchor member, it is not restricted to this. The anchor member may be any member that is partially embedded in the joint portion 80A of the foundation beam 80 and that can fix (connect) the column 90 to the joint portion 80A. A concrete anchor may be used. Further, when a root-wrapped concrete portion is raised from the joint portion 80A of the foundation beam 80 and the column base portion of the column 90 is embedded in the root-wrap concrete portion, the root-wrap concrete portion and the joint portion 80A are spanned. A reinforcing bar or the like to be arranged may be used as the anchor member. Furthermore, as will be described later, when a column such as a reinforced concrete structure is erected on the joint portion 80A of the foundation beam 80, a part of the column main reinforcement of the column may be used as an anchor member.

  Moreover, in the said embodiment, although the beam main bar reinforcement process was implemented before the footing installation process, you may implement a beam main reinforcement arrangement process between a footing installation process and an upper foundation construction process.

  In the above embodiment, the example in which the base reinforcing bars 74 are arranged around the anchor bolt 60 in the footing manufacturing process is shown, but the method of arranging the basic reinforcing bars 74 can be changed as appropriate. For example, before forming the concrete portion 12, the upper reinforcing bar 72 may be passed to the opening-side end portion 70 </ b> A of the U-shaped reinforcing bar 70, or a U-shaped reinforcing bar having a lower opening around the anchor bolt 60. May be arranged. Further, the basic reinforcing bars 74 may be arranged around the anchor bolt 60 as necessary, and can be omitted as appropriate. Furthermore, it is possible to arrange a general reinforcing bar in place of the basic reinforcing bar 74.

  Moreover, although the said embodiment demonstrated to the example which constructed | assembled the reinforced concrete foundation beam 80 on the footing 10 in the upper foundation construction process, it is not restricted to this. The foundation beam 80 is not limited to a reinforced concrete structure, and may be a concrete structure, a steel frame concrete structure, a prestressed concrete structure, or the like. Moreover, as an upper foundation, foundation slabs, such as concrete structure and a reinforced concrete structure, may be sufficient, for example.

  Moreover, in the said embodiment, although the example in which the steel-structured pillar 90 was stood on the joint part 80A of the foundation beam 80 was shown in the pillar construction process, it is not restricted to this. The pillar is not limited to steel structure, but may be concrete structure, reinforced concrete structure, steel concrete structure, prestressed concrete structure, CFT (Concrete Filled Steel Tube) structure, or the like. In the case of a column such as a reinforced concrete structure, for example, the anchor bolt 60 and the column may be connected by embedding the upper portion of the anchor bolt 60 protruding upward from the joint 80A of the foundation beam 80 in the column. .

  Furthermore, although the example which provided the anchor bolt 60 as an anchor member in the footing 100 was shown in the said embodiment, it is not restricted to this. The footing 100 can be provided with a column member that constitutes a column that stands on the seismic isolation device 18.

  Specifically, as shown in FIG. 7, a column member 102 is provided on the upper surface of the concrete portion 12 of the footing 100 via a mount 50. The column member 102 constitutes a lower portion of a column base embedded column 92 in which the column base portion is embedded in the joint portion 80A of the foundation beam 80, and the other upper end of the column 92 is formed at the upper end portion thereof. Column members (not shown) are connected.

  The column member 102 has a main body portion 104 formed of a square steel pipe and a base plate 106 provided at the lower end of the main body portion 104. A plurality of studs 108 as stress transmission means are provided on the outer surface of the main body 104. These studs 108 enhance the integrity of the column member 102 and the joint 80A of the foundation beam 80.

  The column member 102 configured in this manner is attached in a state where the column member 102 stands on the mount 50 in place of the anchor bolt 60 in the above-described footing manufacturing process. In FIG. 7, illustration of the U-shaped reinforcing bar 70 is omitted. Then, after arranging the upper reinforcing bars 72 and beam main bars 82A and 82B (see FIG. 4) around the column member 102, the footing 100 is installed on the seismic isolation device 18 in the footing installation process, and the upper foundation The foundation beam 80 is constructed in the construction process.

  In the upper foundation construction step, the foundation beam 80 is constructed by placing concrete on the footing 100 so that the upper end of the column member 102 is exposed from the upper end of the joint 80A. Thereby, another column member can be connected to the upper end portion of the column member 102 exposed from the upper end of the joint portion 80A. Therefore, the workability of the column base embedded column 92 can be improved.

  The column member 102 may be integrated with the concrete portion 12 by embedding a part (lower portion or lower end portion) of the pillar member 102 in the concrete portion 12 in the same manner as the anchor bolt 60 in the above embodiment. That is, the pillar member 102 provided in the footing 100 is a part of the pillar member 102 supported by a support member such as the gantry 50 embedded in the concrete portion 12 or a part of the pillar member 102 so as to protrude from the upper surface of the concrete portion 12. This is a concept including a column member 102 and the like embedded in the concrete portion 12. Further, the various modifications described above can be applied as appropriate to the footing 100 provided with the column member 102.

  As mentioned above, although one embodiment of the present invention was described, the present invention is not limited to such an embodiment, and one embodiment and various modifications may be used in combination as appropriate, and the gist of the present invention will be described. Of course, various embodiments can be implemented without departing from the scope.

10 Precast concrete footing (footing)
12 Concrete part 14 Foundation slab (lower foundation)
16 Lower footing (lower base)
18 Base isolation device 18A Upper flange 30 Base plate (fixed surface)
50 Mount 60 Anchor bolt (anchor member)
70 U-shaped reinforcing bar 70A Open side end 72 Upper reinforcing bar 80 Foundation beam (upper foundation)
82A Beam main bar 82B Beam main bar 90 Column 92 Column 100 Footing 102 Column member

Claims (4)

A footing installation process in which an anchor member connected to a column or a precast concrete footing provided so that the column member constituting the column protrudes upward on the seismic isolation device installed on the lower foundation When,
An upper foundation construction step of constructing an upper foundation by placing concrete so that the anchor member or the column member is exposed from the upper end on the footing,
Construction method of seismic isolation foundation including Before the footing installation step, including a beam main bar reinforcement step of arranging the beam main reinforcement of the foundation beam as the upper foundation around the anchor member or the column member,
The construction method of the seismic isolation foundation of Claim 1. Before the footing installation step, including a footing production step for producing the footing,
In the footing manufacturing step, a plurality of U-shaped reinforcing bars opened upward are arranged in a lattice pattern around the anchor member or the column member, and the U-shaped reinforcing bars protrude from the upper surface. After placing the footing concrete so as to pass the upper reinforcing bar between the opening side end portions of the U-shaped reinforcing bar,
The construction method of the seismic isolation foundation of Claim 1 or Claim 2. A concrete part formed with a fixed surface to be fixed to the upper flange of the seismic isolation device;
An anchor member provided in the concrete part and connected to a column, or a column member constituting the column,
A beam main reinforcement of a foundation beam arranged on the concrete portion and arranged around the anchor member or the column member;
Precast concrete footing with

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