JP2018178603A - Seismic isolation foundation formation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To secure safety at the time of placing concrete constituting a seismic isolation foundation and to improve the filling property and uniformity of concrete constituting the seismic isolation foundation. SOLUTION: A dam 101 arranged on a peripheral surface of concrete, a base plate 11 arranged on the upper surface of the seismic isolation foundation, and a base plate 11 which divides a concrete placing area forming a seismic isolation foundation to receive a seismic isolation device. The lids 121, 13 and 14 arranged around the base plate 11 are provided, and the area where the seismic isolation device is installed in the base plate 11 is removed and at least one of the lids 121, 13 and 14 is provided. An injection port 12a for injecting concrete is formed, and an opening G1 that is open to a part of the concrete casting area is formed. [Selection diagram] Fig. 1

Description

  The present invention relates to a seismic isolation foundation forming apparatus used in placing concrete forming a seismic isolation foundation receiving a seismic isolation device.

  The seismic isolation foundation forming device used when casting concrete that forms the seismic isolation foundation that receives seismic isolation devices includes a grate (formwork) that partitions the concrete casting area and a concrete casting area. And a base plate disposed on the upper surface (see Patent Documents 1 and 2). A seismic isolation system is installed on the base plate. That is, the base plate is disposed to fix the seismic isolation device on the seismic isolation foundation, and finally integrated with the cast concrete on the upper surface of the seismic isolation foundation.

Patent No. 5713710 (paragraph 0034, 0038, FIG. 2) Unexamined-Japanese-Patent No. 2001-12107 (Paragraph 0024-0027, FIG. 5)

  In patent document 1, the concrete injection port for inject | pouring concrete is provided in area | regions other than the area | region where the seismic isolation apparatus in a baseplate is installed. However, since the portion other than the concrete injection port of the base plate covers the entire casting area of the concrete, if it is intended to fill the concrete to every corner, the pressure acting on the base plate will increase and the seismic isolation foundation forming device will fail There is a risk of being

  On the other hand, in Patent Document 2, the base plate covers a part of the casting area of the concrete, and a part of the casting area of the concrete which is not covered by the base plate is open. However, since the part of the casting area of the concrete which is not covered with the base plate is all open, the concrete escapes upward from this part, so there is a possibility that the concrete can not be packed densely. As a result, the fillability and uniformity of the concrete that constitutes the seismic isolation foundation tend to deteriorate.

  From the above background, the present invention proposes a seismic isolation foundation forming device that ensures the safety of the concrete forming the seismic isolation foundation during the placing operation and enhances the filling property and uniformity of the concrete that constitutes the seismic isolation foundation. It is a thing.

  The base isolation device for forming a base according to the present invention divides a casting area of concrete forming the base for receiving the base isolation device, and arranges it on the upper surface of the base and the girder placed around the concrete. For pouring concrete into at least one of the region and the lid except for the installation region when the seismic isolation device is installed in the base plate and the lid disposed around the base plate It is characterized in that an opening is formed, and an opening is formed in which a part of the area partitioned by the weir is open.

  Since the injection port is formed in at least one of the area where the installation area is removed and the lid disposed around the base plate, a large defect such as the injection port is included in the installation area where the seismic isolation device is installed Can eliminate things. Therefore, the strength against the surface pressure of the installation area can be secured.

  Furthermore, since the lid is disposed around the base plate, when placing the concrete that constitutes the seismic isolation foundation, the concrete flowing in the placement area is pressed by the lid and the pressure in the concrete is increased. Therefore, it is possible to improve the uniformity and the filling property of the concrete and to suppress the deterioration of the quality of the seismic isolation foundation. Here, if the injection port is provided at the center of the installation area, the installation area is basically located at the center of the placement area, so concrete can be poured radially from the center of the placement area. Uniformity and packing are likely to increase.

  When the injection port is removed from the installation area in order to ensure the strength against the surface pressure of the installation area, the position of the injection port is separated from the center of the placement area. It is assumed that it tends to decrease. However, even in such a case, the presence of the lid can apply pressure to the concrete to compensate for the uniformity and the filling property of the concrete in which the position of the injection port is far from the center of the placement area.

  Moreover, since the opening opened to a part of area | region divided among the area | regions divided by the weir is formed, the cast concrete can be suitably released from an opening. As a result, it is possible to prevent excessive pressure from acting on the concrete, and to secure the safety at the time of placing concrete of the seismic isolation foundation.

  Furthermore, in the seismic isolation foundation forming apparatus of the present invention, a portion of the lid from which the base plate has been removed is made of a material that is less likely to be out-of-plane deformed than other portions (a lid 121 of the first embodiment And the high rigidity portion may be formed with an inlet (claim 2). Since the inlet is formed in the lid and the base plate and the lid are separated, the degree of freedom in the placement of the inlet is increased, and the workability of the seismic isolation foundation forming device is improved. In addition, since the injection port is formed in the high rigidity portion, it is possible to prevent the deterioration of the uniformity of the concrete due to the deformation of the injection port due to an impact from the feeding pipe at the time of placing concrete.

  Furthermore, in the seismic isolation foundation forming apparatus of the present invention, the overhang portion (the lid portion 221 of the second embodiment) projecting from the main body portion including the installation area is integrated with the base plate on a plane, A configuration requirement may be that the inlet is formed (claim 3). Since the overhang | projection part in which the injection port was formed is integrated from the main-body part containing an installation area | region, the number of processes in the assembly operation | work of a seismic isolation foundation formation apparatus can be reduced.

  Furthermore, in the seismic isolation foundation forming apparatus of the present invention, the opening may be formed on the opposite side of the installation area from the injection port (claim 4). According to this configuration requirement, the distance between the injection port and the opening can be maintained at a certain level or more. Because the concrete flows out through the opening, it is difficult to exert pressure on the concrete in the region opposite the inlet across the opening. Therefore, by securing a certain distance or more between the inlet and the opening, it is possible to uniformly apply high pressure to the concrete over a wide area, and to improve the uniformity and the filling property of the concrete.

  Furthermore, in the seismic isolation foundation forming apparatus of the present invention, the plurality of air vent holes may be dispersedly formed in the lid (claim 5). In this case, since the air vent hole is formed in the lid, it is possible to enhance the filling property of the concrete that constitutes the seismic isolation foundation. In addition, since the air vent holes are formed in a dispersed manner, it is possible to improve the uniformity of the concrete.

  Furthermore, in the seismic isolation foundation forming apparatus of the present invention, a spacing member for maintaining a spacing between the ground surface on which the siding plate is installed or a floor surface is connected to the lower surface of at least one of the lid and the base plate. May be a constituent requirement (claim 6). In this case, the spacer can prevent the lid from sinking due to the mass of the base plate.

  The base plate disposed on the upper surface of the seismic isolation foundation and the lid disposed around the base plate, and at least one of the region and the lid excluding the installation region when the seismic isolation device is installed in the base plate An injection port for injecting concrete is formed, and an opening that opens to a part of the cast-in area of the concrete is formed, so safety during the cast-in operation of concrete constituting the seismic isolation foundation While ensuring the fillability and uniformity of the concrete that constitutes the seismic isolation foundation.

(A) is a top view showing 1st Embodiment of the seismic isolation foundation formation apparatus of this invention, (B) is an AA line arrow directional view of FIG. 1 (A). It is sectional drawing showing a mode that the pumping pipe which pumps the concrete which comprises the seismic isolation foundation is being fixed to the seismic isolation foundation formation apparatus of FIG. 1 (B). It is a top view showing 2nd Embodiment of the seismic isolation foundation formation apparatus of this invention.

First Embodiment
The seismic isolation foundation forming apparatus 1 which is 1st Embodiment of the seismic isolation foundation forming apparatus of this invention is demonstrated using drawing. As shown in FIG. 1, the seismic isolation foundation forming apparatus 1 divides a casting area of concrete forming the seismic isolation foundation C receiving the seismic isolation device on the foundation concrete B, and is disposed on the circumferential surface of the concrete To attach the formwork 10, the base plate 11 disposed on the upper surface of the seismic isolation foundation C on which the seismic isolation device is installed, and the pressure transmission pipe P used when casting concrete forming the seismic isolation foundation C. Concrete placing jig 12 and a plurality of first lids 13 and a plurality of second lids 14 for holding the cast concrete in a region other than the base plate 11 in the casting region divided by the mold 10; Equipped with

  The “area other than the base plate 11” refers to the area surrounded by the mold 10 and the base plate 11 when the base isolation forming apparatus 1 is viewed in plan. The drawing shows an example in which the first lid 13 is four and the second lid 14 is three, but the number of the lids 13 and 14 is not limited. Although the drawing also shows an example in which the pressure feeding pipe P is used for pouring concrete, concrete may be cast from a concrete injection port 12a described later through a hopper or the like in addition to the pressure feeding pipe P. Hereinafter, a tool for placing concrete from the concrete inlet 12a is referred to as a pressure feeding pipe P or the like.

  The formwork 10 encloses the casting area of the concrete which forms the seismic isolation foundation C. The mold 10 has four draft plates 101. The four weirs 101 are assembled in a square frame shape in plan view, and are placed upright on the foundation concrete B in an upright state, and are erected substantially vertically. An area surrounded by the four base plates 101 is a concrete placing area.

  The shape of the form 10 having the shape in which the weir plate 101 is assembled is appropriately set according to the design of the building constructed on the seismic isolation foundation C, etc. In FIG. It is a state. Further, the number of the weir plates 101 is not limited to four, and the appropriate number of weir plates 101 may be appropriately joined to form the mold frame 10. Also, the material of the weir plate 101 is not limited as long as it has a certain strength that does not cause out-of-plane deformation during concrete placement, but mainly from the aspect of workability and economy of assembly and disassembly, wood such as plywood Or metal such as steel plate is preferable.

  The base plate 11 is made of a flat plate and is formed in a square shape. The length of each side of the base plate 11 is shorter than the length in the width direction (the length of the weir 101 in FIG. 1A) of the weir 101 erected in use. The base plate 11 is disposed so that the side surfaces of the base plate 11 and the inner side surface of each of the base plates 101 are parallel to each other with a distance from the base plate 101 at the inner center of the mold 10.

  In the first embodiment, since it is assumed that the bottom surface of the lower flange of the seismic isolation device is square, the base plate 11 is formed in a square. In the first embodiment, the length of one side of the base plate 11 is about 3⁄5 of the length in the width direction of the base plate 101 in use, and the distance between the base plate 11 and the base plate 101 is the base plate It is about 1/3 of the length of one side of 11. However, the shape and size of the base plate 11 are appropriately set according to the shape and size of the seismic isolation device. Further, the material of the base plate 11 is not limited as long as it has a necessary surface pressure capable of exhibiting a function as a joint for fixing the seismic isolation device of the base plate 11 to the seismic isolation foundation C, but metal such as steel is preferable.

  Furthermore, as shown in FIG. 1 (B), the base plate 11 is supported by eight spacing members 16 projecting from the surface of the base concrete B, and the spacing between the surface of the base concrete B and the base plate 11 is maintained. It is done. The spacing members 16 are joined to one corner of the bottom surface of the base plate 11 in a pair. The spacer 16 has a fixing portion 161 fixed to the base concrete B and a fixing portion 162 for fixing the seismic isolation device to the base plate 11.

  For example, a stud bolt is used for the fixing portion 161, and one end thereof is indirectly fixed to the base concrete B by screwing with a female anchor (not shown) embedded in the base concrete B. On the other hand, the fixing portion 162 is, for example, a coupler in which female threads are formed at both axial end portions along the axial direction, and one end portion of the fixing portion 161 on the side not connected to the base concrete B Are screwed together.

  A female screw portion on the side which is not screwed into the fixing portion 161 of the fixing portion 162 is finally screwed into a bolt (not shown) for joining the seismic isolation foundation C and the seismic isolation device. The tip of the fixing unit 162 is joined to the bottom surface of the base plate 11 so that the female screw portion of the fixing unit 162 that is not screwed into communication with the insertion hole 11 c described later. In addition, you may perform fixing of the space | interval maintenance material 16 to the foundation concrete B by embedding the stud bolt which comprises the fixing | fixed part 161 in the foundation concrete B directly, without using a female type anchor.

  Moreover, the confirmation hole 11a which confirms the setting condition of concrete is penetrated and provided in the thickness direction at the base plate 11. As shown in FIG. The confirmation holes 11a are dispersed and arranged in a 3 × 3 grid. In detail, one confirmation hole 11a disposed at the center of the base plate 11, four confirmation holes 11a disposed at four corners on the diagonal of the base plate 11, and the four confirmation holes 11a Four confirmation holes 11a disposed in the middle between each two adjacent confirmation holes 11a in the circumferential direction are provided. Each confirmation steel 11a is formed in a circle having a diameter of 20 mm. The number, position, size, and shape of the confirmation holes 11a are not limited to those in the first embodiment, and can be appropriately set in view of the surface pressure required for the base plate 11 and the application of the confirmation holes 11a.

  In addition, the base plate 11 is provided with an insertion hole 11 b penetrating in the thickness direction, through which a bolt (not shown) for fixing the seismic isolation device to the base plate 11 is inserted. A total of eight insertion holes 11 b are provided, for example, one on each side of four confirmation holes 11 a arranged at the four corners of the base plate 11. The insertion holes 11b are formed near the confirmation holes 11a formed at the four corners on the diagonal of the base plate 11 so that the base isolation device can be stably fixed to the base plate 11 at the four corners of the square lower flange. It is arranged so as to sandwich the diagonal. Furthermore, the insertion hole 11 b communicates with the female screw portion of the fixing portion 162 joined to the bottom surface of the base plate 11. The number, position, size and shape of the insertion holes 11b are not limited to those of the first embodiment, and can be set appropriately according to the number, position, size, shape and the like of the spacer 16.

  Furthermore, in the base plate 11, screw holes 11c for screwing together the fixing member 17 for reliably fixing the base plate 11 to the concrete forming the seismic isolation foundation C are provided penetrating in the thickness direction. . The screw holes 11 c are arranged to surround the confirmation holes 11 a arranged at the center of the base plate 11 in a square shape. In detail, eight screw holes 11c that form a square by being circumferentially connected are disposed so as to be located between the four corners of the square and each side. The fixing member 17 is composed of a stud bolt and a nut screwed to one end of the stud bolt. The fixing member 17 is disposed on the bottom surface side of the base plate 11, and is screwed into the screw hole 11c at an end on which the nut is not screwed.

  The number and positions of the screw holes 11c are not limited to those of the first embodiment, and can be appropriately set according to the number and positions of the fixing members 17. Further, the shape and size of the screw hole 11c are not limited to those of the first embodiment, and can be appropriately set according to the shape and size of the stud bolt constituting the fixing member 17. Furthermore, the fixing member 17 may be welded and joined to the bottom surface of the base plate 11 instead of being screwed and joined to the screw holes 11 c of the base plate 11. In this case, the fixing member 17 may not be configured by a stud bolt.

  The concrete placing jig 12 is disposed between any side (the right side in FIG. 1A) of the square-shaped base plate 11 and the dam plate 101 opposed thereto. The concrete placing jig 12 is composed of an independent single body, and a circular hole penetrating at the center is formed, and a lid 121 made of a steel plate or the like formed in a square shape and the periphery of the hole of the lid 121 And a mounting portion 122 formed of a cylindrical steel member or the like provided upright.

  The hole of the lid portion 121 and the hollow portion of the mounting portion 122 communicate with each other, and these constitute a concrete injection port 12 a for placing concrete that constitutes the seismic isolation foundation C. The concrete inlet 12a is formed in a cylindrical shape having a diameter of 150 mm. The mounting portion 122 is provided to fix a pressure feeding pipe P or the like for pumping concrete. As shown in FIG. 2, the outer diameter of the mounting portion 122 substantially matches the inner diameter of the pressure feeding pipe P or the like. The pressure feeding pipe P and the like are fixed to the mounting portion 122 by a predetermined fixing jig (not shown) in a state of being inserted into the mounting portion 122 from the front end. The lid portion 121 is provided so as to be located on substantially the same plane as the base plate 11. In addition, the length of one side of the lid 121 is about 1/3 of the length of one side of the base plate 11, and the lid 121 is fitted with almost no gap between the weir plate 101 and the base plate 11. .

  In the first embodiment, the concrete placing jig 12 is configured by welding the lid portion 121 and the attachment portion 122 mainly composed of independent members. However, the configuration of the concrete placing jig 12 is not limited to this, and the lid portion 121 and the attaching portion 122 may be integrally molded by casting. Moreover, the joining method between each member is not restricted to welding, You may join between each member using components for joining, such as a volt | bolt and a nut.

  In addition, for the material of the concrete placing jig 12, particularly the material of the lid 121 and the attaching part 122, the pressure feeding pipe P or the like is attached to the attaching part 122, and the tensile strength and It does not matter as long as it has compressive strength, but metal such as steel is preferable in terms of required strength and workability such as molding.

  The first lid 13 functions as a lid for pressing the concrete on the plane including the base plate 11 when placing the concrete forming the seismic isolation foundation C, and is supported at a height substantially flush with the base plate 11 ing. The first lid 13 is formed of a square-shaped veneer plate, and two in total of two each are disposed on both sides of the lid 121 along the side surface of the base plate 11 sandwiching the lid 121 in plan view and the inner surface of the weir plate 101. It is done. Further, the length of one side of the first lid 13 is about 1/3 of the length of one side of the base plate 11, and the first lid 13 is accommodated with almost no gap between the weir plate 101 and the base plate 11. There is.

  In addition, circular first air vent holes 13 a having a diameter of about 50 mm are provided at the four corners of the first lid 13. The first air vent hole 13 a is formed to penetrate in the thickness direction of the first lid 13. By means of the first air vent holes 13a, air can be vented when placing concrete, and the filling condition of the concrete can be confirmed.

  The material of the first lid 13 is not particularly limited, but is preferably wood, plastic or the like from the viewpoint of workability such as cutting and installation. The shape, size, number, and position of the first air vent hole 13a are not particularly limited, but the function of the first lid 13 as a lid and for filling air of the first air vent hole 13a and the filling condition of concrete It sets up suitably in the balance with the function as a hole for confirming.

  The second lid 14 also functions as a lid for pressing the concrete on the plane including the base plate 11 when placing the concrete forming the seismic isolation foundation C, and is supported at a height located substantially on the same plane as the base plate 11 ing. The second lid 14 is formed of a rectangular veneer plate, and is disposed between the three side surfaces of the base plate 11 where the lid portion 121 is not adjacent and the inner side surfaces of the three facing plates 101 opposed to the side surfaces. ing. Of the three second lids 14, one second lid 14 faces the lid 121 with the base plate 11 in between, and the remaining two second lids 14 face in between with the base plate 11 .

  In addition, the second lid 14 is arranged such that the side surface of the base plate 11 adjacent to the second lid 14 and the long side of the second lid 14 are parallel to each other. The length in the short side direction of the second lid 14 is substantially the same as the length of one side of the first lid 13, and the distance between the pace plate 11 and the weir plate 101 is almost zero. Further, the length in the long side direction of the second lid 14 is substantially the same as the length of one side of the base plate 11, and each second lid 14 is aligned with both ends of the side surface of the base plate 11 whose both ends in the long side direction are adjacent. It is arranged as. Therefore, the two second lids 14 in an opposing relationship are connected to the first lid 13 at one end.

  On a plane partitioned by two second lids 14 in an opposing relationship, a second lid 14 opposing the lid portion 121 with the base plate 11 interposed therebetween, and three baffle plates 101 opposing the second lid 14 The two square openings G1 are formed in the area of. In other words, among the frame-like openings formed between the four base plates 101 and the four base plates 11, the openings G1 are provided at two corner portions on the opposite side of the concrete placing jig 12 with the base plate 11 interposed therebetween. The other parts are basically closed by the lid 121, the first lid 13 and the second lid 14.

  In addition, at both ends in the short side direction of the second lid 14, a plurality of circular second air vent holes 14a each having a diameter of about 50 mm along the long side direction (four in FIG. 1A) are mutually It is provided at intervals. Here, the plurality of second air vent holes 14 a formed at one end in the short side direction of the second lid 14 is the other in the short side direction of the second lid 14 when viewed in the short side direction of the second lid 14. It is located in the middle between the second air vent holes 14a formed at the end of the. That is, the plurality of second air vent holes 14 a formed at one end in the short side direction of the second cover 14 and the short side direction of the second cover 14 so that the air removal from the second cover 14 is dispersed entirely. A plurality of second air vents 14a formed at the other end of the two are alternately arranged.

  The second air vent hole 14 a is formed to penetrate in the thickness direction of the second lid 14. By means of the second air vent holes 14a, air can be vented when placing concrete, and the filling condition of the concrete can be confirmed.

  The material of the second lid 14 is not particularly limited, but is preferably wood, plastic or the like from the viewpoint of workability such as cutting and molding. Further, the shape, size, number and position of the second air vent holes 14a are not particularly limited, but the function of the second lid 14 as a lid and for filling air of the second air vent holes 14a and the filling condition of concrete It sets up suitably in the balance with the function as a hole for confirming.

  As mentioned above, the seismic isolation foundation formation apparatus 1 divides the casting area of the concrete which forms the seismic isolation foundation C which receives seismic isolation apparatus, and arranges it on the upper surface of the seismic isolation foundation with the gravel board 101 arrange | positioned at the side of concrete. And a concrete pouring jig 12, a first lid 13 and a second lid 14 around the base plate 11. And since the concrete injection port 12a which needs a certain size in order to inject concrete is formed in the lid part 121 in the concrete injection jig 12, without lowering the surface pressure strength of the base plate 11, the base plate 11. While placing concrete from the concrete injection port 12a disposed around the 11th, placing concrete in a state where a certain pressure is applied by the lid portion 121, the first lid 13 and the second lid 14 and filling the concrete It is possible to ensure gender and uniformity.

  Moreover, since the opening G1 opened around the base plate 11 in the casting area of concrete is formed, excessive pressure is prevented from acting on the concrete to be cast, and the concrete placing operation of the seismic isolation foundation C is performed. While being able to secure the safety of the time, it is possible to confirm the setting situation of the concrete. Here, the opening G1 is formed on the opposite side of the concrete injection port 12a across the base plate 11, and the separation distance between the concrete injection port 12a and the opening G1 is secured. It can act to increase the uniformity and the filling of the concrete.

  Moreover, since the cover part 121 and the attaching part 122 of the concrete injection | pouring jig | tool 12 are steel and are high rigidity, it is hard to deform | transform out of plane. Therefore, the pressure feeding pipe P for concrete placement is attached to the attachment portion 122, and when placing the concrete, the stability regarding placement of the concrete is enhanced and the uniformity of the concrete constituting the seismic isolation foundation C is enhanced. be able to.

  Further, since the base plate 11 is supported by the spacing member 16 and the spacing between the base plate 11 and the surface of the base concrete B is maintained, the sinking of the first lid 13 and the second lid 14 due to the mass of the base plate 11 It is possible to prevent the trouble. Furthermore, since the plurality of first air vent holes 13a and the second air vent holes 14a penetrating in the thickness direction are dispersedly formed in the first lid 13 and the second lid 14, the seismic isolation foundation C is configured. The fillability of concrete can be improved. Further, since the plurality of confirmation holes 11a are formed in the thickness direction in a dispersed manner also in the base plate 11, the filling property of the concrete constituting the seismic isolation foundation C can be improved. Furthermore, since the plurality of confirmation holes 11a, the first air vent holes 13a, and the second air vent holes 14a are arranged with a two-dimensional spread, it is possible to effectively improve the uniformity of the concrete.

  In the seismic isolation foundation forming apparatus 1, four first lids 13 and three second lids 14 are disposed around the base plate 11 in order to enhance the filling property and uniformity of the concrete. Some of them may be arranged without arranging all. Further, the shape and the number of the openings G1 are not limited to those in FIG. 1. For example, any one of the four first lids 13 such as the two first lids 13 not adjacent to the concrete injection jig 12 in FIG. The opening G1 may open the area where the first lid 13 was disposed. Alternatively, the first lid 13 is disposed in the region of the two openings G1 in FIG. 1, and the second lid 14 disposed on the opposite side of the concrete injection jig 12 with the base plate 11 interposed therebetween is not disposed. The opening G1 may be used to open the area where the lid 14 was disposed.

  Also, the first lid 13 in which three second lids 14 are arranged in the long side direction of the second lid 14 may be replaced. In this case, since the types of members are reduced, the cost of the seismic isolation foundation forming apparatus 1 can be reduced. When the second lid 14 is replaced with the first lid 13, the first lid 13 disposed in the middle may not be disposed, and the region may be an opening G1.

  Furthermore, the two first lids 13 arranged side by side on both sides of the concrete injection jig 12 may be configured by one each. In this case, since the number of members is reduced, the installation work of the seismic isolation forming apparatus becomes easy. Also, the lid portion 121 of the concrete injection jig 12 may be formed large so as to cover the range of the two first lids 13 arranged side by side on both sides of the concrete injection jig 12.

Second Embodiment
Next, the seismic isolation foundation forming apparatus 2 which is 2nd Embodiment of the seismic isolation foundation formation apparatus of this invention is demonstrated using FIG. The same terms may be used for the terms of members or parts having the same or corresponding functions as those of the seismic isolation foundation forming apparatus 1 of the first embodiment, and the description thereof may be omitted.

  The seismic isolation foundation forming apparatus 2 divides the casting area of concrete forming the seismic isolation foundation C, and is disposed on the upper surface of the seismic isolation foundation C and the formwork 10 disposed on the circumferential surface of the concrete The concrete placing jig 22 is not disposed between the formwork 20 and the baseplate 21. The concrete placing jig 22 is disposed between the formwork 20 and the baseplate 21. The concrete placing jig 22 is not disposed between the formwork 20 and the baseplate 21. It has one first lid 23 and two second lids 24 arranged in the area.

  The shape and dimensions of the weir plate 201 and the base plate 21 constituting the form 20 are the same as the weir plate 201 and the base plate 21 of the first embodiment, but the relative positional relationship between the four weir plates 201 and the base plate 21 Are different from the first embodiment. Specifically, each side surface of the square base plate 21 in plan view is opposed to each vertex of the four base plates 201 arranged in a square frame shape. That is, the four guide plates 201 and the base plate 21 which are arranged in a rectangular frame shape are arranged so as to be shifted 45 degrees relative to each other.

  Further, the confirmation holes 21a for confirming the placement condition of concrete are provided at predetermined intervals in the circumferential direction at the center of the base plate 21, specifically, eight at 45 degree intervals, and at four corners of the base plate 21. A total of twelve of them are provided to penetrate in the thickness direction of the base plate 21. The four confirmation holes 21a provided at the four corners of the base plate 21 are provided closer to the corner of the base plate 21 than the confirmation holes 11a of the first embodiment.

  In addition, eight screw holes 21c for screwing together the fixing member for reliably fixing the base plate 21 to the concrete forming the seismic isolation foundation C are eight holes arranged at equal intervals in the circumferential direction on the outside, A total of 12 pieces of four arranged at equal intervals in the circumferential direction are provided inside the two screw holes 21c. Eight screw holes 21c arranged at equal intervals in the circumferential direction on the outer side are arranged in the middle of the confirmation 21a adjacent to the confirmation hole 21a in the circumferential direction. Further, four screw holes 21c arranged at equal intervals in the circumferential direction on the inner side are arranged at positions facing the middle of each side of the base plate 21 having a square shape in plan view.

  By the way, in the first embodiment, the concrete placing jig 12 is an independent single unit and is separated from the base plate 11, but the concrete placing jig 22 of the second embodiment is connected to the base plate 21. And is integrally configured with the base plate 21. In other words, the concrete placing jig 22 is configured to protrude outward from the center of one edge of the base plate 21 as a part of the base plate 21. The concrete placing jig 22 includes the lid 21 and the attaching portion 22 having the same shape and the same size as the lid 11 and the attaching portion 12 of the first embodiment.

  Although the base plate 21 and the concrete injection jig 22 are separated for convenience in the reference numerals, substantially, the base plate 21 and the lid portion 221 of the concrete injection jig 22 are integrally formed of a single flat plate member. It is done. In the flat plate-like member, the main body for securing the installation area where the seismic isolation device is actually installed is the base plate 21 and is formed projecting outward from the main body and the seismic isolation device is not installed. An overhanging portion for forming a concrete inlet for pouring concrete from the tip of P or the like is a lid 221 of the concrete injecting jig 22. The main body portion and the overhang portion are separated by a broken line drawn on the base plate 21 in FIG. Further, similarly to the lid portion 121, a circular hole is provided at the center of the lid portion 221, and a cylindrical attachment portion 222 is provided upright on the upper surface of the lid portion 221 along the circular hole. A concrete inlet 22 a is formed by the circular hole of the lid portion 221 and the hollow portion of the attachment portion 222.

  The two second lids 24 face each other with the base plate 21 interposed therebetween. Each second lid 24 has both side portions orthogonal to the sides of the base plate 21 on which the concrete placing jig 22 is provided, the dam plate 201 opposed to the both sides, and the cleps opposed to the both sides from both ends of the both sides It is formed in a pentagonal shape covering a region surrounded by and a perpendicular line directed to the plate 201. Further, from the end of the second lid 24 on the side in contact with the base plate 21 toward the apex portion facing the end, seven second air vent holes 24a, five of which are spaced along the direction of the end. The second air vent holes 24a, the three second air vent holes 24a, and the one second air vent hole 24a are provided at substantially equal intervals.

  In addition, the first lid 23 faces the side of the base plate 21 on which the concrete placing jig 22 is provided, the weir plate 201 facing the side, and both ends of the side from the both ends toward the weir plate 201 facing the side The pentagonal shape covering the area surrounded by the perpendicular line is formed in a shape in which the portion of the lid portion 221 protruding from the base plate 21 is cut out. Therefore, although the outer periphery of the planar view shape of one first lid 23 is the same as the second lid 24, the first lid 23 has approximately the same shape as the lid 221 so that it can be fitted to the lid 221. The notch is formed. The position of the first air vent hole 23a in the first lid 23 is the same as the position of the second air vent hole 24a in the second lid 24, but the first air vent hole 23a has the same shape as the lid portion 221. The air vent holes 23a are not formed.

  Further, the first lid 23 and the second lid 24 are not disposed on the opposite side of the concrete placing jig 22 sandwiching the base plate 21, and the opposite side of the concrete placing jig 22 sandwiching the base plate 21 is opened. doing. In other words, the area surrounded by the base plate 21, the end plate 20 opposite to the end of the base plate 21 opposite to the concrete placing jig 22, and the second lid 24 is opened, and the opening G2 is formed. There is.

  As described above, the seismic isolation foundation forming device 2 divides the casting area of the concrete forming the seismic isolation foundation C receiving the seismic isolation device, and the damping plate 201 disposed on the circumferential surface of the concrete; And a concrete injection jig 22, a first lid 23 and a second lid 24 around the base plate 21. And since the concrete injection port 22a for injecting concrete is formed in the concrete injection jig 22, the base plate 21 is formed without forming the concrete injection port in the base plate 21 and lowering the surface pressure strength of the base plate 21. Of concrete by placing a certain amount of pressure by the lid portion 221, the first lid 23 and the second lid 24 while pouring concrete from the concrete injection port 22a around it, and filling property and uniformity of the concrete Can be secured.

  In addition, since the open opening G2 is formed around the base plate 21 in the casting area of concrete, a surplus is formed to prevent deterioration of the quality of the seismic isolation foundation and ensure concrete casting situation. It can be confirmed. Here, the opening G2 is formed on the opposite side of the concrete injection port 22a across the base plate 11, and the separation distance between the concrete injection port 22a and the opening G2 is secured, so excessive pressure is applied to the cast concrete. While being able to ensure that the safety of the concrete on the seismic isolation foundation C is placed, the placement situation of the concrete can be confirmed.

  In addition, although the 1st lid 23 and the 2nd lid 24 which comprise the seismic isolation foundation formation apparatus 2 are each comprised by one sheet, even if comprised, for example, dividing | segmenting on the central line used as left-right symmetry, etc. is comprised. good. Also, the first lid 23 may be disposed instead of the second lid 24. In this case, a portion of the first lid 23 which has a shape substantially the same as the shape of the lid 221 is an open opening G2. Moreover, although the opening G2 open | released on the opposite side to the concrete injection jig 22 on both sides of the base plate 21 is formed, you may arrange | position the 1st cover 23 suitably in this part. Also in this case, the portion of the notch in the first lid 23 that has substantially the same shape as the lid 221 is the open opening G2. In addition, for example, a second lid 24 provided with a large hole penetrating in the vicinity of the center may be disposed at the portion of the opening G2. In this case, the large hole constitutes an open opening G2.

  Moreover, in the seismic isolation foundation forming apparatuses 1 and 2, there is almost no gap between the base plates 11 and 21 and the first lids 13 and 23 and the second lids 14 and 24, but for example, the first lids 13 and 23 and The length of the two lids 14 and 24 in the direction orthogonal to the side surfaces in contact with the base plates 11 and 21 is shortened to separate the base plates 11 and 21 from the first lids 13 and 23 and the second lids 14 and 24. , 21 and the first lids 13, 23 and the second lids 14, 24 may be provided with an open opening.

  Furthermore, in the seismic isolation foundation forming apparatuses 1 and 2, there is almost no gap between the backing plates 101 and 201 and the first lids 13 and 23 and the second lids 14 and 24, but, for example, the first lids 13 and 23 and Reduce the length of the second lids 14, 24 in the direction orthogonal to the side surfaces of the second lids 14, 24 in contact with the side plates 101, 201 to separate the wedges 101, 201 from the first lids 13, 23 and the second lids 14, 24 An open opening may be provided between the baffle plates 101 and 201 and the first lids 13 and 23 and the second lids 14 and 24. Note that only one of the first lids 13 and 23 and the second lids 14 and 24 may provide an opening between the base plates 11 and 21 and the backing plates 101 and 201, or a plurality of first lids 13, 23 or a part of the second lid 14 or 24.

1 ...... Seismic isolation foundation forming device, 2 ...... Seismic isolation foundation forming device,
B ...... Foundation concrete, C ...... Base isolation,
P: Pumping pipe,
10 ...... formwork, 101 せ weir,
11: Base plate,
12: Concrete injection jig, 12a: Concrete injection hole,
13 ... first lid, 13a ... first air vent hole,
14 ... 2nd lid, 14a ... 2nd air vent hole,
16: Spacer, G1: Opening,
20 ...... formwork, 201 せ weir,
21 ...... Base plate,
22 ...... concrete injection jig, 22 a ...... concrete injection hole,
23: first lid, 23a: first air vent hole,
24 ... 2nd lid, 24a ... 2nd air vent hole,
26: Spacer, G2: Opening.

Claims (6)

Partitioning area of concrete forming the seismic isolation foundation receiving the seismic isolation device, dividing the concrete board disposed on the circumferential surface of the concrete, the base plate disposed on the upper surface of the seismic isolation foundation, and the periphery of the base plate And a lid arranged on the
An injection port for injecting the concrete is formed in at least one of the lid and the region excluding the installation region when the seismic isolation device is installed in the base plate, and the region divided by the weir plate A seismic isolation foundation forming device characterized in that an opening is formed in which a part of the area is open.   A part of the portion of the lid from which the base plate is removed is a high rigidity portion formed of a material which is less likely to be deformed out of plane than the other portions, and the injection port is formed in the high rigidity portion. The seismic isolation foundation formation apparatus according to claim 1.   The seismic isolation system according to claim 1, wherein an overhanging portion projecting from the main body including the installation area is integrated with the base plate on a plane, and the injection port is formed in the overhanging portion. Foundation formation device.   The said opening is formed on the opposite side to the said injection port on both sides of the said installation area | region, The seismic isolation foundation formation apparatus as described in any one of the Claims 1 thru | or 3 characterized by the above-mentioned.   The seismic isolation foundation formation device according to any one of claims 1 to 4, wherein a plurality of air vent holes are dispersedly formed in the lid.   A space maintaining member is connected to the lower surface of at least one of the lid and the base plate, for maintaining a distance between the ground surface on which the siding plate is installed or a floor surface. The seismic isolation foundation formation apparatus as described in any one of 1 thru | or 5.

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