JP2018084038A - Seismic isolator replacement method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a seismic isolator replacement method capable of efficiently replacing a seismic isolator.SOLUTION: A seismic isolator replacement method, a seismic isolator replacement method for replacing an existing seismic isolator 10 installed between an upper structure 3 and lower structure 2 with a new seismic isolator, includes replacing the existing seismic isolator 10 with a new seismic isolator while installing a jack device 41 around the existing seismic isolator 10 and adjusting the height of the jack device 41. In installing the jack device 41, at least one of a gap between the jack device 41 and upper structure 3 and a gap between the jack device 41 and lower structure 2 is filled with grout material 43 and a sheet 40 is disposed between the grout material 43 and upper structure 3 and between the grout material 43 and lower structure 2.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a method for exchanging seismic isolation devices.

  Traditionally, seismic isolation devices installed in buildings have been regularly inspected and replaced with new seismic isolation devices when damage, deterioration, etc. occur. For example, as shown in Patent Document 1 below, a jack device is installed around the seismic isolation device provided between the upper structure and the lower structure, and the height of the jack device is changed, and the seismic isolation is performed. The device has been replaced.

Japanese Patent Laying-Open No. 2015-194077

  By the way, a grout material may be injected into a gap between the upper structure (or the lower structure) and the jack device in order to adjust the unevenness of the upper structure (or the lower structure). In this case, when removing the jack device after exchanging the seismic isolation device, the grout material adheres to the upper structure (or lower structure), and thus the work of scoring the grout material occurs. There is a problem that noise is generated during the work of grouting the grout material.

  Then, this invention is made | formed in view of the said situation, and provides the replacement | exchange method of the seismic isolation apparatus which can replace | exchange a seismic isolation apparatus efficiently.

In order to achieve the above object, the present invention employs the following means.
That is, the seismic isolation device exchanging method according to the present invention is a seismic isolation device exchanging method for exchanging an existing seismic isolation device provided between an upper structure and a lower structure with a new seismic isolation device. When installing the jack device by replacing the existing seismic isolation device with the new seismic isolation device while installing a jack device around the seismic isolation device and adjusting the height of the jack device, At least one of between the device and the upper structure and between the jack device and the lower structure is filled with a grout material, between the grout material and the upper structure, and between the grout material and the lower structure. A sheet is arranged between the two.

  In the seismic isolation device replacement method configured as described above, a sheet is disposed between the grout material and the upper structure (or the lower structure). Therefore, when the existing seismic isolation device is replaced with a new seismic isolation device and the jack device is removed, the grout material adheres to the jack device side and does not adhere to the upper structure (or lower structure). Therefore, work such as rolling the grout material from the upper structure (or lower structure) does not occur, and the seismic isolation device can be efficiently replaced.

  In the seismic isolation device exchanging method according to the present invention, a plurality of the existing seismic isolation devices are provided, and a bolt for loosening a fixing bolt that fixes the plurality of existing seismic isolation devices to the upper structure or the lower structure. The jacking device is installed around each of the existing seismic isolation devices in the loosening process, and the jacking up of all the jacking devices allows the upper structure to be deformed and the upper The first temporary filler plate is inserted into the first jack-up process for raising the total amount of the lash and the gap between the existing seismic isolation device and the upper structure or the lower structure. A first jack for lowering the upper structure so that the existing seismic isolation device supports the upper structure by a first temporary filler plate insertion step and jackdown of all the jack apparatuses. In the down-step and the one existing seismic isolation device, the upper structure is raised by an amount equivalent to the amount jacked down in the first jack-down step by jacking up the jack device around the one seismic isolation device. Installing the new seismic isolation device between the upper structure and the lower structure, and a second jack-up process for removing the existing temporary seismic isolation device for removing the first temporary filler plate and the existing seismic isolation device. New seismic isolation device installation step, second temporary filler plate insertion step of inserting a second temporary filler plate between the new seismic isolation device and the upper structure or the lower structure, and jackdown of the jack device, A second jack-down step of lowering the upper structure so that the new seismic isolation device supports the upper structure; a second jack-up step; Repeating step of sequentially performing the seismic isolation device removal step, the new seismic isolation device installation step, the second temporary filler plate insertion step and the second jack down step for all the existing seismic isolation devices, and all the jack devices A third jack-up process for raising the upper structure so that the jack apparatus supports the upper structure, and between all the new seismic isolation devices and the upper structure or the lower structure. The second temporary filler plate removing step of removing the inserted second temporary filler plate and jacking down all the jack devices, so that the new seismic isolation device supports the upper structure. And a third jackdown step of lowering.

In the seismic isolation device replacement method configured as described above, the period in which the jack apparatus supports the building is the period of the first jack up process, the first temporary filler plate insertion process, and the first jack down process, It is a period of a 3rd jack up process, a 2nd temporary filler plate removal process, and a 3rd jack down process. Since these periods are each about one day without exchanging the seismic isolation device, the period during which the building is supported by the jack device can be reduced in a short time.
Moreover, in the first jack-up process and the third jack-up process, since all jack devices installed around all the seismic isolation devices are jacked up, they are locally applied to structures such as beams around the seismic isolation device. Stress does not act. In the second jack-up process, the jack apparatus around the one seismic isolation device is jacked up, and the jack-up amount is equivalent to the jack-down amount in the first jack-down process. Here, in the first jack-up process, the height of the sum of the deformation amount of the existing seismic isolation device and the work-over amount is jacked up, and in the first temporary filler plate insertion process, the first temporary filler plate is inserted. In the first jack-down process, the thickness of the first temporary filler plate is calculated from the jack-up amount in the first jack-up process (the sum of the amount of deformation of the existing seismic isolation device and the amount of upward work). It is jacked down to the height minus the height. The amount of jack-up in the second jack-up process is the amount of deformation of the existing seismic isolation device, and the stress acting on structures such as beams around the seismic isolation device can be suppressed.

  The seismic isolation device replacement method according to the present invention fixes the existing seismic isolation device and the upper structure or the lower structure in the first temporary filler plate insertion step and the second temporary filler plate insertion step. The first temporary filler plate and the second temporary filler plate each formed in a strip shape in plan view may be inserted so as to avoid interference with the fixing bolt.

  In the seismic isolation device replacement method configured as described above, in the first temporary filler plate insertion step and the second temporary filler plate insertion step, the first temporary filler plate and the second temporary filler respectively formed in a strip shape in plan view. By inserting the plate, interference between the existing seismic isolation device and the fixing bolt that fixes the upper structure or the lower structure can be avoided.

  According to the seismic isolation device replacement method of the present invention, it is possible to efficiently replace the seismic isolation device.

BRIEF DESCRIPTION OF THE DRAWINGS It is a part of top view of the 1st basement floor of a building which shows arrangement | positioning of the seismic isolation apparatus used as the object of implementation of the replacement method of the seismic isolation apparatus which concerns on one Embodiment of this invention. It is typical sectional drawing which shows the materials and equipment carrying-in process of the replacement | exchange method of the seismic isolation apparatus which concerns on one Embodiment of this invention. It is typical sectional drawing which shows the jack and the displacement measuring device installation process of the replacement method of the seismic isolation apparatus which concerns on one Embodiment of this invention. It is typical sectional drawing which shows the seismic isolation apparatus bolt loosening process of the replacement method of the seismic isolation apparatus which concerns on one Embodiment of this invention. It is typical sectional drawing which shows the 1st jack-up process and the 1st temporary filler plate insertion process of the replacement method of the seismic isolation apparatus which concerns on one Embodiment of this invention. It is a typical top view which shows the 1st temporary filler plate insertion process of the replacement method of the seismic isolation apparatus which concerns on one Embodiment of this invention. It is typical sectional drawing which shows the 1st jackdown process of the replacement | exchange method of the seismic isolation apparatus which concerns on one Embodiment of this invention. It is typical sectional drawing which shows the 2nd jackup process of the replacement | exchange method of the seismic isolation apparatus which concerns on one Embodiment of this invention. It is a typical top view which shows the existing seismic isolation apparatus removal process of the replacement method of the seismic isolation apparatus which concerns on one Embodiment of this invention. It is typical sectional drawing which shows the insertion process of the new seismic isolation apparatus installation process of the seismic isolation apparatus which concerns on one Embodiment of this invention, and the upper main filler plate. It is typical sectional drawing which shows the insertion process of the permanent filler plate of the lower side of the replacement method of the seismic isolation apparatus which concerns on one Embodiment of this invention, a 2nd temporary filler plate insertion process, and a 2nd jackdown process. It is typical sectional drawing which shows the 3rd jack-up process of the replacement | exchange method of the seismic isolation apparatus which concerns on one Embodiment of this invention. It is typical sectional drawing which shows the 3rd jackdown process of the replacement | exchange method of the seismic isolation apparatus which concerns on one Embodiment of this invention. It is typical sectional drawing which shows the jack and displacement measuring device removal process of the replacement method of the seismic isolation apparatus which concerns on one Embodiment of this invention. It is typical sectional drawing which shows the materials and equipment removal process of the replacement | exchange method of the seismic isolation apparatus which concerns on one Embodiment of this invention.

  A method for replacing a seismic isolation device according to an embodiment of the present invention will be described with reference to the drawings.

FIG. 1 is a part of a plan view of the first basement floor of a building 1 showing an arrangement of a seismic isolation device 10 to be subjected to a method for replacing a seismic isolation device according to an embodiment of the present invention. FIG. 2 is a schematic cross-sectional view illustrating the material / equipment carrying-in process.
As shown in FIG. 1, in the building 1, the upper structure 3 is provided above the foundation slab 2 (lower structure) via a seismic isolation device 10. Here, for the sake of convenience, one direction of the building 1 (vertical direction on the paper surface shown in FIG. 1, the first direction) is referred to as the X direction, and the horizontal direction orthogonal to one direction of the building 1 (the horizontal direction on the paper surface shown in FIG. 1, The second direction) is referred to as the Y direction.

  The upper structure 3 includes columns 4 arranged with an interval in the X direction and the Y direction, and a beam 5 that joins the columns 4 to each other. In order from the row of the columns 4 on one side of the building 1 in the Y direction, the rows are called X1, X2,..., And the rows orthogonal to these X1, X2, X3, and X4 rows are Y1 in order from the upper side of the drawing shown in FIG. Columns, Y2 columns, Y3, Y4.

  As shown in FIG. 2, the seismic isolation device 10 includes an upper flange 11 and a lower flange 12 formed in a substantially octagonal shape in plan view, and a laminated rubber 13 provided between the upper flange 11 and the lower flange 12. Become. The laminated rubber 13 is obtained by alternately laminating a steel sheet (not shown) and a rubber sheet (not shown), for example.

The seismic isolation device 10 includes the pillar 4 and the foundation slab 2 and fixing bolts 16 and 17 (see FIG. 3).
same as below. ). The fixing bolts 16 and 17 are screwed into nuts 18 and 19 embedded in the column 4 and the foundation slab 2, respectively. The seismic isolation device 10 contracts by δ1 mm (vertical deformation amount, not shown) in the vertical direction due to the load of the supporting upper structure 3.

Next, a method of exchanging seismic isolation devices that replaces all seismic isolation devices 10 of the building 1 with new seismic isolation devices 20 will be described.
First, the equipment and materials import process is performed.
After curing the work area on the first floor, a loading device 32 such as a chain block with an electric trolley for loading materials and equipment is installed on a horizontal member 31 such as H-shaped steel arranged horizontally in the building 1. Then, a new seismic isolation device 20, a hydraulic jack device 41 (see FIG. 3), a displacement measuring device (see FIG. 3) 46, etc. are suspended and carried.

FIG. 3 is a schematic cross-sectional view showing a jack / displacement measuring device installation step.
Next, as shown in FIG. 3, a jack / displacement measuring device installation step is performed.
The installation location of the jack device 41 is determined around all the seismic isolation devices 10 on the first basement floor. At the installation location, sheets 40 are installed on the upper surface of the foundation slab 2 and the lower surface of the beam 5, respectively. A sliding plate 42 is installed on the sheet 40 provided on the foundation slab 2, and a jack device 41 is installed on the sliding plate 42. Further, the grout material 43 is injected into the gap between the sliding plate 42 and the sheet 40 provided on the foundation slab 2 and the gap between the jack device 41 and the sheet 40 provided on the beam 5. Thereby, the unevenness of the upper surface of the foundation slab 2 and the unevenness of the lower surface of the beam 5 can be absorbed. Further, a displacement measuring device 46 for measuring the jack-up amount of the jack device 41 is installed.
As the sheet 40, a sheet made of a resin such as polyethylene or polyvinyl chloride having a thickness of about 0.1 mm, a fluororesin sheet having a thickness of about 1 mm or less, or one side (the upper surface of the basic slab 2 and the lower surface of the beam 5) Adhesive layer provided, moisture-proof sheet for soil with a thickness of about 0.15mm, adhesive tape, long sheet for floor with a thickness of about 2.0mm, asphalt roofing sheet, polyvinyl chloride resin Can be used in the form of a sheet, a veneer plate having a thickness of about 2.0 to 3.0 mm, cardboard, and the like.
Further, by providing irregularities on the upper surface of the foundation slab 2 and the lower surface of the beam 5, the sheet 40 is less likely to slide along the upper surface of the foundation slab 2 and the lower surface of the beam 5.
As the sliding plate 42, a stainless steel plate or the like can be employed. If the rolling bearing is used, the friction coefficient of the lower surface of the jack device 41 can be further reduced.
By installing the sliding plate 42, it is possible to follow a horizontal displacement caused by an earthquake or the like during the construction period.
In addition, it is preferable that the jack device 41 selects the type of the jack device 41 and adjusts the number of installation places so that the load capacity of the pillar 4 can be 1.5 times or more. Further, the displacement measuring device 46 is preferably capable of measuring the jackup amount in units of 0.1 mm.

FIG. 4 is a schematic cross-sectional view showing a seismic isolation device bolt loosening step.
Next, a seismic isolation device bolt loosening step is performed as shown in FIG.
In all the seismic isolation devices 10, the fixing bolt 17 that fixes the seismic isolation device 10 to the foundation slab 2 is loosened. The fixing bolt 17 may be replaced with a temporary mounting bolt (not shown) having a higher strength than the fixing bolt 17. Thereby, the seismic isolation device 10 can move relative to the foundation slab 2 in the vertical direction. In this embodiment, the fixing bolt 17 is loosened by about 20 mm.

FIG. 5 is a schematic cross-sectional view showing a first jack-up process and a first temporary filler plate insertion process.
Next, as shown in FIG. 5, a first jack-up process is performed.
While the jack-up amount is measured by the displacement measuring device 46, all the jack devices 41 are jacked up, and the upper structure 3 is raised. The jack-up amount δe is a case where the vertical deformation amount δ1 mm of the seismic isolation device 10, the construction upward amount α mm, and the new seismic isolation device 20 to be replaced (see FIG. 10) are higher than the existing seismic isolation device 10. Is the height obtained by adding βmm to the difference in height.

FIG. 6 is a schematic plan view showing the first temporary filler plate insertion step.
Next, as shown in FIGS. 5 and 6, a first temporary filler plate insertion step is performed.
The first temporary filler plate 51 is inserted into the gap generated between all the seismic isolation devices 10 and the foundation slab 2. The first temporary filler plate 51 is formed in a strip shape in plan view and is arranged with a plurality of intervals. Between each 1st temporary filler plate 51, the fixing bolt 17 which has fixed the seismic isolation apparatus 10 to the foundation slab 2 is arrange | positioned. As a result, the first temporary filler plate 51 and the fixing bolt 17 do not interfere with each other. That is, since the first temporary filler plate 51 can be inserted without removing the fixing bolt 17, the seismic isolation device 10 can function effectively even if an earthquake occurs at any time during the construction period. In the present embodiment, the first temporary filler plate 51 has a total thickness of 17 mm, in which three plates 51A having a thickness of 5 mm and one plate 51B having a thickness of 2 mm are stacked. Further, the first temporary filler plate 51 is preferably made of a material having high strength and high compression rigidity, and a steel plate or the like can be adopted, but a lightweight acrylic plate is optimal in construction.

FIG. 7 is a schematic cross-sectional view showing the first jackdown process.
Next, as shown in FIG. 7, a first jackdown process is performed.
The safety nuts of all the jack devices 41 are loosened, the jack device 41 is jacked down while the jack down amount is measured by the displacement measuring device 46, and the upper structure 3 is lowered. The jack unit 41 is jacked down to a height at which the column 4 can be supported. The fixing bolt 17 that fixes the seismic isolation device 10 to the foundation slab 2 is temporarily tightened. In the present embodiment, the jackdown amount is δ1 mm (vertical deformation amount), which is 3 mm.
The first jack-up process to the first jack-down process can be performed in about one day.

FIG. 8 is a schematic cross-sectional view showing a second jackup process.
Next, as shown in FIG. 8, a second jack-up process is performed.
The work from here is performed for each row of the predetermined pillars 4. In the present embodiment, first, it is assumed that one column 4 in the X1 row is performed.
While measuring the jack-up amount with the displacement measuring device 46, the jack device 41 is jacked up and the upper structure 3 is raised. The jack-up amount in this step is equivalent to the jack-down amount in the first jack-down step. In the present embodiment, the jackdown amount in the first jackdown step is δ1 mm (vertical deformation amount), which is 3 mm, so the jackup amount is 3 mm. Moreover, since the span between the pillars 4 is 6 m at the shortest, the maximum value of the deformation angle between the spans is set to 1/2000. When the deformation angle between the spans exceeds 1/2000, it is preferable to perform the second jack-up process for the columns 4 in the adjacent rows (columns 4 in the X2 row).

FIG. 9 is a schematic plan view showing an existing seismic isolation device removal step.
Next, as shown in FIG. 9, an existing seismic isolation device removal step is performed.
The first temporary filler plate 51 is removed, and the fixing bolt 16 that fixes the seismic isolation device 10 to the column 4 and the fixing bolt 17 that fixes the seismic isolation device 10 to the foundation slab 2 are removed. Using a chain block (not shown) and a nylon sling (not shown), the seismic isolation device 10 is laterally pulled in a direction that does not interfere with the jack device 41. When the seismic isolation device 10 is moved about half, the temporary support column 52 is inserted between the foundation slab 2 and the column 4. Thereby, during the construction period, an earthquake or the like occurs, and in the unlikely event that the jack device 41 falls down, the fail-safe function of supporting the column 4 with the temporary support column 52 is exhibited. And the jack apparatus 41 is supporting the pillar 4 in the state which removed the seismic isolation apparatus 10 completely, and removed.

FIG. 10 is a schematic cross-sectional view showing a new seismic isolation device installation step and a main filler plate insertion step. FIG. 11 is a schematic cross-sectional view illustrating a lower permanent filler plate insertion step, a second temporary filler plate insertion step, and a second jackdown step.
Next, as shown in FIG. 10, a new seismic isolation device installation step and an upper permanent filler plate insertion step are performed.
Similar to the seismic isolation device 10, the new seismic isolation device 20 includes an upper flange 21 and a lower flange 22 formed in a substantially octagonal shape in plan view, and a stack provided between the upper flange 21 and the lower flange 22. Made of rubber 23.

Here, the height of the existing seismic isolation device 10 and the new seismic isolation device 20 may vary due to product errors or the like. Based on the measured height of the existing seismic isolation device 10 and the new seismic isolation device 20 at the time of product delivery, the existing seismic isolation device 10 is calculated from the height (measurement value) of the new seismic isolation device 20 at each replacement location. The difference (height difference) of the height (measured value) is calculated. Of the height differences at all replacement locations, the replacement location that is the maximum value (the maximum height difference) is used as a reference. Then, when the height difference at each replacement location is smaller than the maximum height difference, the permanent filler plates 61 and 62 having a thickness corresponding to the difference between the maximum height difference and the height difference at the location (see FIG. 11). ) To adjust.
In the exchange location shown in the present embodiment, the difference between the maximum height difference and the height difference at the location is 12 mm, so that a new filler plate 61 having a thickness of 6 mm on the upper side of the new seismic isolation device 20 and a lower side. It is assumed that a permanent filler plate 62 having a thickness of 6 mm is installed. Further, the permanent filler plates 61 and 62 are formed in an octagonal shape in plan view, like the upper flange 11 and the lower flange 12 of the seismic isolation device 20. In addition, what is necessary is just to install this installation filler plate only in the upper side or only the lower side of the seismic isolation apparatus 20, when the difference of the maximum height difference and the height difference in the said location is small.
Further, when the height adjustment is not necessary, the installation of the permanent filler plates 61 and 62 is unnecessary.

  The seismic isolation device 20 with the permanent filler plate 61 placed on the upper side is inserted between the foundation slab 2 and the column 4. After moving the seismic isolation device 20 by about half, the temporary support column 52 is removed from between the basic slab 2 and the column 4 and fine adjustment is performed so that the seismic isolation device 20 is disposed at the position where the seismic isolation device 10 was disposed. To do. If it can arrange | position in a predetermined position, both the seismic isolation apparatus 20 and the permanent filler plate 61 will be temporarily tightened with the fixing bolt 16 (refer FIG. 11) fixed to the pillar 4. FIG. The permanent filler plate 61 may be adhered to the upper side of the seismic isolation device 20 with an adhesive or the like.

Next, as shown in FIG. 11, a lower permanent filler plate insertion step and a second temporary filler plate insertion step are executed.
A permanent filler plate 62 and a second temporary filler plate 63 are inserted between the foundation slab 2 and the seismic isolation device 20. The permanent filler plate 62 is disposed above the second temporary filler plate 63. As the permanent filler plate, for example, a steel plate or the like can be employed. As with the first temporary filler plate 51, the second temporary filler plate 63 is preferably made of a material having high strength and high compression rigidity, and a steel plate or the like can be adopted. It is formed in a strip shape and is arranged so as not to interfere with the fixing bolt 17 that fixes the seismic isolation device 20 to the foundation slab 2. The second temporary filler plate 63 temporarily tightens the seismic isolation device 20 and the main filler plate 62 together with the fixing bolt 17. In the present embodiment, the second temporary filler plate 63 is formed by laminating a plate 63A having a thickness of 5 mm and a plate 63B having a thickness of 3 mm to have a total thickness of 8 mm. The permanent filler plate 62 may be bonded to the lower side of the seismic isolation device 20 with an adhesive or the like. Further, the second temporary filler plate 63 may be disposed above the permanent filler plate 62 (between the seismic isolation device 20 and the permanent filler plate 62).

Next, a second jackdown process is performed.
The jack device 41 is jacked down so that the seismic isolation device 20 supports the column 4 and the upper structure 3 is lowered. The fixing bolt 17 that fixes the seismic isolation device 20 is temporarily tightened again.

Next, a repeating process is performed.
From the second jack-up process to the second jack-down process, the other columns 4 in the X1 row are also performed. Thereafter, in the other columns (X2, X3,...), The seismic isolation devices 10 are sequentially replaced for each column, and finally all the seismic isolation devices 10 are replaced.

FIG. 12 is a schematic cross-sectional view showing a third jackup process and a second temporary filler plate removal process.
Next, as shown in FIG. 12, a third jack-up process and a second temporary filler plate removal process are performed.
In all the seismic isolation devices 20, the fixing bolt 17 that fixes the seismic isolation device 20 to the foundation slab 2 is loosened. Even in this state, since the fixing bolt 17 is screwed into the nut 19 embedded in the foundation slab 2, the seismic isolation device 20 can function effectively even if an earthquake occurs during the construction period.
While measuring the jackup amount with the displacement measuring device 46, all the jack devices 41 are jacked up, and the upper structure 3 is raised so that the jack devices 41 support the pillars 4. Then, the first temporary filler plate 51 is pulled out and removed. The jack-up amount is δ1 mm (vertical deformation amount), which is a height at which the second temporary filler plate 63 can be removed in the second temporary filler plate removal step in the subsequent step, that is, δ1 mm (vertical deformation amount). 3 mm. If the permanent filler plate 62 is adhered to the lower side of the seismic isolation device 20 with an adhesive or the like, when the jack device 41 is jacked up, the permanent filler plate 62 is lifted together with the seismic isolation device 20, so that the second It is easy to pull out the temporary filler plate 63. In addition, if the second temporary filler plate 63 is arranged on the upper side of the main filler plate 62, when the jack device 41 is jacked up, the second temporary filler plate 63 made of an acrylic plate or the like is made of a steel plate or the like. Since a gap is generated between the seismic isolation device 20 and the second temporary filler plate 63 in a state of being placed on the upper side of the configured permanent filler plate 62, the second temporary filler plate 63 is easily pulled out.

FIG. 13 is a schematic cross-sectional view showing a third jackdown process.
Next, as shown in FIG. 13, a third jackdown process is performed.
While the jack-down amount is measured by the displacement measuring device 46, the jack device 41 is jacked down, and the upper structure 3 is lowered. In the present embodiment, the jackdown amount is an amount obtained by adding 8 mm of the thickness of the second temporary filler plate 63 (plate 63A and plate 63B) to δ1 mm (vertical deformation amount), and is 11 mm. All (existing) fixing bolts 16 and 17 are replaced with new fixing bolts 66 and 67 and finally tightened.

Next, a jack / displacement measuring device removal step is performed.
FIG. 14 is a schematic cross-sectional view showing a jack / displacement measuring instrument removing step.
As shown in FIG. 14, when the jack device 41 is jacked down, the grout material 43 adheres on the jack device 41, and the sheet 40 is attached to the lower surface of the beam 5. When the jack device 41 to which the grout material 43 is attached is removed, the grout material 43 is attached to the sliding plate 42 and the sheet 40 is adhered to the upper surface of the foundation slab 2. The sliding plate 42 to which the grout material 43 is attached is removed, the sheet 40 attached to the lower surface of the beam 5 and the upper surface of the foundation slab 2 is peeled off, and the displacement measuring device 46 is removed.

Next, the material and equipment removal process is performed.
FIG. 15 is a schematic cross-sectional view showing the material / equipment removal step.
As shown in FIG. 15, the work is completed when materials and equipment such as the seismic isolation device 10 (see FIG. 14), the jack device 41, and the displacement measuring device (see FIG. 14) are suspended and carried out by the carry-in device 32.

  In the seismic isolation device replacement method configured as described above, the seat 40 is disposed between the grout material 43, the beam 5, and the foundation slab 2. Therefore, when the existing seismic isolation device 10 is replaced with the new seismic isolation device 20 and the jack device 41 is removed, the grout material 43 adheres to the jack device 41 or the sliding plate 42 side, and the beam 5 and the foundation slab. 2 does not adhere. Therefore, work such as rolling the grout material 43 from the beam 5 and the foundation slab 2 does not occur, and the seismic isolation device can be efficiently exchanged.

Moreover, the period when the jack apparatus 41 is supporting the building 1 is the period of the 1st jack up process, the 1st temporary filler plate insertion process, and the 1st jack down process, the 3rd jack up process, and the 2nd temporary filler. This is the period of the plate removal process and the third jackdown process. Since these periods are each about one day without any work for exchanging the seismic isolation device 10, the period in which the building 1 is supported by the jack device 41 can be suppressed in a short time.
Further, in the first jack-up process and the third jack-up process, since all the jack devices 41 installed around all the seismic isolation devices 10 and 20 are jacked up, A local stress does not act on the structure such as the beam 5. In the second jack-up process, the jack devices 41 around the seismic isolation devices 10 and 20 in a predetermined row are jacked up. The jack-up amount is equal to the amount of jack-down in the first jack-down process. It is equivalent. Here, in the first jack-up process, the height of the sum of the deformation amount of the existing seismic isolation device 10 and the work-over amount is jacked up, and in the first temporary filler plate insertion process, the first temporary filler plate 51 is added. In the first jack-down process, the first temporary filler is calculated from the jack-up amount in the first jack-up process (the sum of the amount of deformation of the existing seismic isolation device 10 and the amount of upward movement in construction). It is jacked down by the height obtained by subtracting the thickness of the plate 51. The amount of jack-up in the second jack-up process is the amount of deformation of the existing seismic isolation device 10, and the stress acting on the structure such as the beam 5 around the seismic isolation device 10 can be suppressed.

  Further, in the new seismic isolation device installation process, the height difference that is the difference obtained by subtracting the height of the seismic isolation device 10 from the height of the seismic isolation device 20 is calculated at all exchange locations where the seismic isolation device 10 is replaced, The exchange point where the height difference becomes the maximum value (maximum height difference) is used as a reference. In the permanent filler plate insertion process, when the height difference at each replacement location is smaller than the maximum height difference, the permanent filler is inserted between the new seismic isolation device 20 and the column 4 and the foundation slab 2 at each replacement location. The plates 61 and 62 are inserted. Even if there is a variation in the height of the existing seismic isolation device 10, it can be adjusted by installing the permanent filler plates 61 and 62 for height adjustment.

  Further, in the first temporary filler plate insertion step and the second temporary filler plate insertion step, the existing temporary seismic isolation is inserted by inserting the first temporary filler plate 51 and the second temporary filler plate 63 each formed in a strip shape in plan view. Interference with the fixing bolt 17 connecting the device 10 and the foundation slab 2 can be avoided.

  In addition, in the existing seismic isolation device removing step, the existing seismic isolation device 10 is moved, and a temporary support column 52 that supports the column 4 of the upper structure 3 is installed on the lower structure. Therefore, since the jack apparatus 41 and the temporary support column 52 can support the upper structure 3 in a state in which the existing seismic isolation device 10 is moved, safety in the event of an earthquake or the like can be ensured.

  In addition, since the permanent filler plate is bolted to the foundation slab 2 and the pillar 4 together with the new seismic isolation device 20, if the permanent filler plate is thick, it is bent to the fixing bolts 16 and 17 when receiving a horizontal force. May occur. However, in the present embodiment, the main filler plate is divided into a main filler plate 61 installed on the upper side and a main filler plate 62 installed on the lower side, and the thickness of each of the main filler plates 61 and 62 is set to be different. Since it restrains, the load which arises in each fixing bolt 16 and 17 can be restrained.

  The various shapes and combinations of the constituent members shown in the above-described embodiments are merely examples, and various modifications can be made based on design requirements and the like without departing from the gist of the present invention.

  For example, the sheet 40 and the grout material 43 are provided in both the gap between the jack device 41 and the foundation lab 2 and the gap between the jack device 41 and the beam 5, but the sheet 40 and the grout material 43 are provided only in one of the gaps. The grout material 43 should just be provided.

  In the embodiment described above, the case where all the seismic isolation devices 10 of the building 1 are replaced with new seismic isolation devices 20 has been described as an example, but the present invention replaces all the seismic isolation devices 10. The present invention is not limited to this case, and the present invention can also be applied when only a few of all the seismic isolation devices 10 are replaced. Further, only one seismic isolation device 10 is installed in the building 1, and the present invention can also be applied to the case where the seismic isolation device 10 is replaced.

  Moreover, in embodiment shown above, although the fixing bolt 17 which is fixing the seismic isolation apparatus 10 and the foundation slab 2 is loosened, this invention is not limited to this. The fixing bolt 16 that fixes the seismic isolation devices 10 and 20 and the beam 5 is loosened, and the first temporary filler plate 51 and the second temporary filler plate 63 are inserted between the seismic isolation devices 10 and 20 and the beam 5. May be. In addition, when the superstructure is constructed of a steel structure and the seismic isolation devices 10 and 20 and the upper steel support portion are fastened with a high tension bolt, the seismic isolation device 10 and the foundation are used rather than loosening the high tension bolt. It is preferable to loosen the fixing bolt 17 that fixes the slab 2.

  Moreover, in embodiment shown above, after replacing | isolating the seismic isolation apparatus 10 installed in X1 row | line | column by the repetition process, the seismic isolation device 10 of another row | line | column (X2 row | line | column, X3 row ...) is replaced | exchanged sequentially. However, the present invention is not limited to this, and the order of replacement can be selected as appropriate. For example, after the predetermined seismic isolation device 10 in the X1 row is replaced, the predetermined seismic isolation device 10 in the X2 row is replaced. Good.

  When the jack-up amount is large, the fixing bolt 17 that fixes the seismic isolation device 10 to the foundation slab 2 is loosened in the bolt loosening process, and a temporary mounting bolt (not shown) having a higher strength than the fixing bolt 17 is used. The same shall apply hereinafter). In this case, since the temporary mounting bolts have high strength, the seismic isolation device 10 can function effectively even if an earthquake or the like occurs during the construction period.

DESCRIPTION OF SYMBOLS 1 ... Building 2 ... Foundation slab 3 ... Superstructure 4 ... Column 5 ... Beam 10 ... Seismic isolation device (existing seismic isolation device)
20 ... Seismic isolation device (new seismic isolation device)
DESCRIPTION OF SYMBOLS 11 ... Upper flange 12 ... Lower flange 13 ... Laminated rubber 16, 17 ... Fixing bolt 31 ... Horizontal member 32 ... Loading device 40 ... Sheet 41 ... Jacking device 42 ... Sliding plate 43 ... Grout material 46 ... Displacement measuring instrument 51 ... First Temporary filler plate 52 ... Temporary support 61, 62 ... Main filler plate 63 ... Second temporary filler plate

Claims (3)

A method of exchanging a seismic isolation device that replaces an existing seismic isolation device provided between an upper structure and a lower structure with a new seismic isolation device,
While installing a jack device around the existing seismic isolation device and adjusting the height of the jack device, the existing seismic isolation device is replaced with the new seismic isolation device,
When installing the jack device, at least one of the jack device and the upper structure and between the jack device and the lower structure is filled with a grout material, and the grout material and the upper structure are filled. And a seismic isolation device exchanging method characterized by disposing a sheet between the grout material and the lower structure. A plurality of the existing seismic isolation devices are provided,
A bolt loosening step of loosening a fixing bolt fixing a plurality of the existing seismic isolation devices to the upper structure or the lower structure;
The jack devices are respectively installed around all the existing seismic isolation devices, and by jacking up all the jack devices, the upper structure is made to have a deformation amount of the existing seismic isolation device and a work-over amount. A first jack-up process for increasing the combined height,
A first temporary filler plate insertion step of inserting a first temporary filler plate into a gap formed between all the existing seismic isolation devices and the upper structure or the lower structure;
A first jackdown step of lowering the upper structure so that the existing seismic isolation device supports the upper structure by jackdown of all the jack apparatuses;
In the one existing seismic isolation device, a second jack that raises the upper structure by an amount equivalent to the amount jacked down in the first jackdown process by jacking up the jack device around the one seismic isolation device. Up process,
An existing seismic isolation device removing step of removing the first temporary filler plate and the existing seismic isolation device;
A new seismic isolation device installation step of installing the new seismic isolation device between the upper structure and the lower structure;
A second temporary filler plate insertion step of inserting a second temporary filler plate between the new seismic isolation device and the upper structure or the lower structure;
A second jackdown step of lowering the upper structure so that the new seismic isolation device supports the upper structure by jackdown of the jack apparatus;
The second jack up step, the existing seismic isolation device removal step, the new seismic isolation device installation step, the second temporary filler plate insertion step, and the second jack down step are sequentially performed for all the existing seismic isolation devices. An iterative process;
A third jack-up step of raising the upper structure so that the jack apparatus supports the upper structure by jacking up all the jack apparatuses;
A second temporary filler plate removing step of removing the second temporary filler plate inserted between all the new seismic isolation devices and the upper structure or the lower structure;
The third jackdown step of lowering the upper structure so that the new seismic isolation device supports the upper structure by jackdown of all the jack apparatuses. How to replace the seismic isolation device.   In the first temporary filler plate insertion step and the second temporary filler plate insertion step, in order to avoid interference between the existing seismic isolation device and the fixing bolt fixing the upper structure or the lower structure, respectively. The seismic isolation device replacement method according to claim 2, wherein the first temporary filler plate and the second temporary filler plate formed in a strip shape in plan view are inserted.

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