JP7252907B2 - Seismic isolation device, seismic isolation monitoring system and seismic isolation monitoring method - Google Patents

Description

The present invention relates to a seismic isolation device, a seismic isolation monitoring system, and a seismic isolation monitoring method.

Conventionally, it is possible to reduce the amount of kinetic energy transmitted from the lower structure to the upper structure by interposing a seismic isolation device between the lower structure such as the foundation of the building and the upper structure such as the building body. It is done. A building having such a structure is generally called a base-isolated building, and in this base-isolated building, it is possible to reduce shaking of the superstructure caused by an earthquake or the like (for example, Patent Document 1).

JP-A-11-172955

2. Description of the Related Art In recent years, there has been an increasing demand for confirming the safety of buildings within a relatively short time after an earthquake or the like occurs. However, in general, systems for confirming such safety tend to be bulky and expensive. In addition, seismic isolation devices are known for their high earthquake resistance, but there is no system that can monitor the damage of seismic isolation devices after an earthquake.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a seismic isolation device, a seismic isolation monitoring system, and a seismic isolation monitoring method that can confirm the safety of a building after an earthquake or the like occurs with a simple configuration. do.

In one aspect, a seismic isolation device of the present invention is a seismic isolation device comprising a laminate and at least one of a lower flange and an upper flange provided on the lower end side and the upper end side of the laminate, At least one of the side flange and the upper flange is provided with an acceleration sensor.

The term “lower flange” as used herein means a lower flange (indicated by reference numeral 2A2 in FIG. 1B) provided adjacent to the lower end side of the stack of the seismic isolation device, and the necessary a lower plate (designated 2A3 in FIG. 1B) fixed with the lower flange in accordance with and interposed between the lower flange and a substructure such as the foundation of a seismically isolated building. Thus, here the acceleration sensor can be provided on the lower flange or the lower plate, or both the lower flange and the lower plate.
Similarly, the term "upper flange" as used herein refers to an upper flange (designated 2B2 in FIG. a top plate (designated 2B3 in FIG. 1B) fixed with the top flange and interposed between the top flange and a superstructure such as a building body of a seismically isolated building. Thus, here the acceleration sensor can be provided on the top flange or the top plate, or both the top flange and the top plate.

In this specification, "relative displacement in the height direction and/or relative displacement in the horizontal direction between the lower flange and the upper flange" refers to any It means the relative displacement between the lower flange and the upper flange with the positional relationship between the lower flange and the upper flange as the base point in a state in which no deformation occurs.

In another aspect, the seismic isolation device of the present invention comprises:
A seismic isolation device comprising a laminated body and at least one of a lower flange and an upper flange provided on the lower end side and the upper end side of the laminated body,
said lower flange and said upper flange respectively have a lower plate and an upper plate, and are fixed to a lower structure and an upper structure via said lower plate and upper plate;
An acceleration sensor is provided on the lower plate and/or the upper plate.

In one aspect, the seismic isolation monitoring system of the present invention is a seismic isolation monitoring system for monitoring a seismic isolation building in which a seismic isolation device is installed, comprising a laminate, and a stack provided at the lower end side and the upper end side of the laminate. a seismic isolation device comprising: at least one of a lower flange and an upper flange mounted on a wall; and an acceleration sensor provided on at least one of the lower flange and the upper flange; and acceleration data transfer means for transferring to the outside of the seismic isolation pit where the is installed.

In another aspect, the seismic isolation monitoring system of the present invention comprises:
A seismic isolation monitoring system for monitoring a seismic isolated building in which a seismic isolation device is installed,
A laminate, at least one of a lower flange and an upper flange provided on the lower end side and the upper end side of the laminate, and an acceleration sensor, wherein the lower flange and the upper flange are respectively a lower plate and an upper plate a seismic isolation device having a plate and fixed to the lower structure and the upper structure via the lower plate and the upper plate;
an acceleration data transfer means for transferring the measured value by the acceleration sensor to the outside of the seismic isolation pit where the seismic isolation device is installed;
The acceleration sensor is provided on the lower plate and/or the upper plate.

In one aspect, the seismic isolation monitoring method of the present invention is a seismic isolation monitoring method for monitoring a seismic isolated building, comprising a laminate, a lower flange and an upper flange provided on the lower end side and the upper end side of the laminate. and an acceleration sensor provided on at least one of the lower flange and the upper flange to measure the acceleration at the lower flange and the upper flange using a seismic isolation device. and an acceleration data transfer step of transferring the measured value by the acceleration sensor to the outside of the seismic isolation pit where the seismic isolation device is installed.

In another aspect, the seismic isolation monitoring method of the present invention comprises:
A seismic isolation monitoring method for monitoring a seismic isolation building, comprising:
A laminate, at least one of a lower flange and an upper flange provided on the lower end side and the upper end side of the laminate, and an acceleration sensor, wherein the lower flange and the upper flange are respectively a lower plate and an upper plate An acceleration measuring step of measuring acceleration in the lower plate and/or the upper plate using a seismic isolation device having a plate and fixed to the lower structure and the upper structure via the lower plate and the upper plate. and,
an acceleration data transfer step of transferring the measured value by the acceleration sensor to the outside of the seismic isolation pit where the seismic isolation device is installed;
including
The acceleration sensor is provided on the lower plate and/or the upper plate.

ADVANTAGE OF THE INVENTION According to this invention, the seismic isolation apparatus, the seismic isolation monitoring system, and the seismic isolation monitoring method which can confirm the safety of the building after the occurrence of an earthquake etc. with a simple structure can be provided.

1 is a perspective view showing a seismic isolation device according to one embodiment of the present invention; FIG. 1 is a front view of a seismic isolation device according to an embodiment of the present invention; FIG. 1 is a schematic diagram illustrating a seismic isolation monitoring system according to an embodiment of the present invention; FIG. It is a flow diagram explaining a seismic isolation monitoring method according to an embodiment of the present invention. FIG. 5 is a flow diagram illustrating a seismic isolation monitoring method according to another embodiment of the present invention; FIG. 4 is a diagram showing an example of heights and positions of a laminate and an acceleration sensor;

Embodiments of a seismic isolation device, a seismic isolation monitoring system, and a seismic isolation monitoring method according to the present invention will be exemplified below with reference to the drawings. The same reference numerals are given to the members/parts that are common in each figure.

<Seismic isolation device>
FIG. 1A is a perspective view showing a seismic isolation device 1 as one embodiment of the present invention. FIG. 1B is a front view of a seismic isolation device according to one embodiment of the present invention. This seismic isolation device 1 is installed between a lower structure such as a building foundation (indicated by reference numeral 2A1 in FIG. 1B) and an upper structure such as a building body (indicated by reference numeral 2B1 in FIG. 1B). , a device for supporting the upper structure so as to be horizontally movable relative to the lower structure. The seismic isolation device 1 includes a laminate 3 and at least one of a lower flange 2A4 and an upper flange 2B4 provided on the lower end side (lower side in the drawing) and the upper end side (upper side in the drawing) of the laminate 3. In this example, the seismic isolation device 1 includes a lower flange 2A4 fixed to the lower structure, an upper flange 2B4 fixed to the upper structure, and a laminate interposed between the lower flange 2A4 and the upper flange 2B4. 3 and .

The lower flange 2A4 and the upper flange 2B4 are, for example, planar circular steel plates, and are arranged to face each other above and below the seismic isolation device 1 . The lower flange 2A4 and the upper flange 2B4 are each formed to have a diameter larger than the cross-sectional diameter of the laminate 3, and the outer peripheral portions of the lower flange 2A4 and the upper flange 2B4 extend over the entire circumference of the laminate 3. It protrudes outward in the cross-sectional radial direction.

In addition, the lower flange 2A4 and the upper flange 2B4 are plates fixed to the lower structure and the upper structure via, for example, anchor bolts. , 2B4 are formed with a plurality of bolt holes 20A and 20B spaced apart in the circumferential direction. The lower flange 2A4 and the upper flange 2B4 each have a lower plate 2A3 and an upper plate 2B3 (base plate), and are fixed to the lower structure and the upper structure via the lower plate 2A3 and the upper plate 2B3. good.

Although not shown, the laminated body 3 is a columnar body with a laminated structure formed by alternately laminating a plurality of hard layers and soft layers between the lower flange 2A4 and the upper flange 2B4. It is formed in a substantially cylindrical shape that is shear deformable. A covering rubber covering the outer periphery of the hard layer and the soft layer is formed over the entire periphery of the laminate 3 .

Although the hard layer in this embodiment is a steel plate, it may be a plate material other than a steel plate, for example, a plate material made of a hard resin. Moreover, although the soft layer described above is made of rubber, it may be made of a material other than rubber, for example, a soft resin.

In addition, the seismic isolation device 1 is provided with an acceleration sensor 4 on at least one of the lower flange 2A4 and the upper flange 2B4. In this embodiment, one acceleration sensor 4A is provided on the inner surface (surface facing the upper flange 2B4) 21A of the lower flange 2A4, and one sensor is provided on the inner surface (surface facing the lower flange 2A4) 21B of the upper flange 2B4. An acceleration sensor 4B is provided. That is, in this embodiment, acceleration sensors 4A and 4B are provided on each of the lower flange 2A4 and the upper flange 2B4.

The acceleration sensors 4A and 4B measure the acceleration of the lower flange 2A4 and the upper flange 2B4, respectively, when vibration is input to the seismic isolation device 1 due to an earthquake or the like.

In general, even for buildings constructed in the same location, the magnitude of shaking caused by an earthquake or the like differs depending on the type of foundation, the structure of the building, and the like. In the seismic isolation device 1 according to this embodiment, since the acceleration sensor 4 is provided in the seismic isolation device 1, it is possible to measure the acceleration in the building instead of the acceleration in the ground, and confirm the seismic intensity in the building. .

As described above, the seismic isolation device 1 has a simple configuration in which the acceleration sensor 4 is provided on at least one of the lower flange 2A4 and the upper flange 2B4, so that it is possible to confirm the safety of the building after an earthquake or the like occurs. can.

In this seismic isolation device 1, the acceleration sensors 4A and 4B are provided on both the lower flange 2A4 and the upper flange 2B4, but the acceleration sensor 4 is provided only on either the lower flange 2A4 or the upper flange 2B4. If provided, a simpler seismic isolation device can be configured.

However, as with this seismic isolation device 1, the seismic isolation device 1 includes both a lower flange 2A4 and an upper flange 2B4, and acceleration sensors 4A, 4B are attached to the lower flange 2A4 and the upper flange 2B4, respectively. If provided, absorption of vibration energy by the seismic isolation device 1 is performed by comparing the measured value by the acceleration sensor 4A installed on the lower flange 2A4 and the measured value by the acceleration sensor 4B installed on the upper flange 2B4. quantity can be evaluated. If the amount of vibration energy absorbed by the seismic isolation device 1 is known, the performance of the seismic isolation device 1 can be evaluated.

In this seismic isolation device 1, one acceleration sensor 4A is provided on the lower flange 2A4, but two or more acceleration sensors 4A may be provided on the lower flange 2A4. In this case, the seismic intensity of the lower structure to which the lower flange 2A4 is fixed can be estimated more accurately by averaging the measured values of the respective acceleration sensors 4A.

Similarly, in this seismic isolation device 1, one acceleration sensor 4B is provided on the upper flange 2B4, but two or more acceleration sensors 4B may be provided on the upper flange 2B4. In this case, the seismic intensity of the upper structure to which the upper flange 2B4 is fixed can be estimated more accurately by averaging the measured values of the respective acceleration sensors 4B.

When the acceleration sensors 4A and 4B are provided on both the lower flange 2A4 and the upper flange 2B4, the acceleration sensor 4A installed on the lower flange 2A4 and the acceleration sensor 4B installed on the upper flange 2B4 are arranged to face each other. It is preferable to provide In this case, the amount of vibration energy absorbed by the seismic isolation device 1 can be confirmed more accurately.

Furthermore, this seismic isolation device 1 is provided on at least one of the lower flange 2A4 and the upper flange 2B4 with a height direction (direction indicated by arrow Z in FIG. 1) between the lower flange 2A4 and the upper flange 2B4. A displacement meter 5 is provided for measuring relative displacement and/or relative displacement in the horizontal direction (directions indicated by arrows X and Y in FIG. 1). With this displacement gauge 5, it is possible to confirm the amount of residual displacement of the seismic isolation device 1 after the shaking of the building caused by an earthquake or the like subsides.

In addition, it is preferable to separately measure the displacement meter with a horizontal displacement meter and a vertical displacement meter. Only one horizontal displacement gauge is required. It is preferable that there are a plurality of vertical displacement gauges, preferably three or more. In this case, the rotation and inclination of the seismic isolation device 1 can also be evaluated.

Furthermore, from the viewpoint of grasping the amount of residual displacement more accurately, it is preferable to install three or more displacement gauges in the seismic isolation device. When installing three displacement gauges, install the three displacement gauges at a position where the total distance between the three displacement gauges in the horizontal direction of the seismic isolation device is maximum, and measure the three displacement gauges. By comparing the values, the residual displacement amount of the seismic isolation device 1 can be confirmed more accurately.

In the seismic isolation device 1, the acceleration sensor 4 and the displacement gauge 5 are provided on the lower flange 2A4 and the upper flange 2B4. If a lower plate 2A3 and an upper plate 2B3 are included as required, the acceleration sensors and/or displacement gauges may be provided on the lower plate 2A3 and/or the upper plate 2B3. That is, the acceleration sensor is provided on the lower flange 2A4 and/or the upper flange 2B4, and the displacement gauge is provided on the lower plate 2A3 and/or the upper plate 2B3, or the acceleration sensor is provided on the lower plate 2A3 and/or the upper plate 2B3. and a displacement gauge may be provided on the lower flange 2A4 and/or the upper flange 2B4.

In the seismic isolation device of the present invention, the displacement meter includes an image pickup unit, and the image pickup unit picks up images of the scale at predetermined time intervals. is preferably configured to measure This makes it possible to more easily confirm the safety of the building after the occurrence of an earthquake or the like. The scale can be arranged, for example, in the vicinity of the displacement meter (for example, just below in the height direction). The imaging unit can use any known camera or the like, and is arranged at a location where the scale can be imaged.
The above-mentioned relative displacement in the height direction and/or relative displacement in the horizontal direction may be, for example, the maximum displacement or the minimum displacement (residual displacement after shaking stops), or between Displacement may also be used.
When obtaining the minimum displacement, the displacement gauge determines whether the change in the amount of relative displacement in the height direction and/or the relative displacement in the horizontal direction of the laminate is equal to or less than a predetermined threshold based on images captured at predetermined time intervals. The amount of displacement at the point of time can be used as the measurement result of the relative displacement in the height direction and/or the relative displacement in the horizontal direction. The "predetermined time interval" can be arbitrarily set, for example, every 5 minutes, every 10 minutes, every 20 minutes, or the like. Then, the amount of displacement at the time when it becomes equal to or less than a predetermined threshold value can be used as the measurement result (for example, when the measurement result is obtained once a day, it can be used as the measurement result for that day). The above-mentioned "predetermined threshold value" can also be arbitrarily set, and can be set to 0 (measurement limit value), for example.

FIG. 5 is a diagram showing an example of the height and position of the laminate and the acceleration sensor.
Let δ be the maximum horizontal distance of the laminate that occurs during an earthquake, x be the shortest distance between the laminate and the acceleration sensor, h be the height of the laminate, and _hs be the height of the acceleration sensor. ₁ = δ/h, tan θ ₂ =h _s /x.
At this time, in the seismic isolation device of the present invention, the relational expression θ ₁ + θ ₂ ≤ 90°, that is, the relational expression
arctan (δ/h) + arctan ( _hs /x) ≤ 90°
is preferably satisfied.
This is because, by satisfying the above relational expression, it is possible to more reliably prevent the side surface portion of the deformed laminate from coming into contact with the acceleration sensor.

A seismic isolation device according to another aspect of the present invention includes a laminated body and at least one of a lower flange and an upper flange provided on the lower end side and the upper end side of the laminated body, wherein the lower flange and the upper flange: Each has a lower flange and an upper flange and is fixed to the lower structure and the upper structure via the lower plate and the upper plate, the lower plate and/or the upper plate being provided with an acceleration sensor. Even with this seismic isolation device, the safety of the building after an earthquake or the like occurs can be confirmed with a simple configuration.

<Seismic isolation monitoring system>
Next, FIG. 2 is a schematic diagram illustrating a seismic isolation monitoring system 100 (hereinafter also simply referred to as "system 100") according to an embodiment of the present invention. This seismic isolation monitoring system 100 has the above-described seismic isolation device 1 , and the seismic isolation device 1 is installed in a seismic isolation pit 10</b>P of a seismic isolation building (hereinafter also simply referred to as “building”) 10 . That is, in this example, the seismic isolation device 1 is installed on the lower structure 11, which is the foundation of the building 10, and supports the upper structure 10B, which is the main body of the building. Although a plurality of seismic isolation devices 1 are arranged in this embodiment, only two of them are shown in FIG. 2 for explanation.

More specifically, the system 100 includes the above-described seismic isolation device 1, an acceleration sensor 4 provided on at least one of the lower flange 2A4 or the upper flange 2B4 of the seismic isolation device 1, and the measurement value of the acceleration sensor 4. , and acceleration data transfer means 101 for transferring to the outside of the seismic isolation pit 10P in which the seismic isolation device 1 is installed.

In this example, the acceleration data transfer means 101 is installed in the seismic isolation pit 10P independently of the seismic isolation device 1, but in the system of the present invention, the acceleration data transfer means 101 is incorporated in the acceleration sensor 4. It may be Further, the acceleration data transfer means 101 may be installed outside the seismic isolation pit 10P.

Further, the system 100 can have an analysis means 102 that receives the measured values from the acceleration sensor 4 transferred by the acceleration data transfer means 101 and analyzes the measured values. In this system 100 , the measured value by the acceleration sensor 4 is transferred to the analysis means 102 by the acceleration data transfer means 101 .

The seismic isolation device 1 of this system 100 has both a lower flange 2A4 and an upper flange 2B4, and the lower flange 2A4 and the upper flange 2B4 have acceleration sensors 4A and 4B, respectively. Therefore, in this system 100, the measured values transferred from the acceleration sensors 4A and 4B are transferred to the analysis means 102 by the acceleration data transfer means 101. FIG.

Furthermore, the system 100 quantifies the seismic intensity of the superstructure 10B (for example, the bottom layer of the building 10) and/or the substructure 11 (and thus the ground) from the measured values transferred from the acceleration sensors 4A and 4B, respectively. building seismic intensity quantification means 102A.

In this system 100, the building seismic intensity quantification means 102A is included in the analysis means 102, and using the building seismic intensity quantification means 102A, the upper structure is determined from the transferred measurement values of the acceleration sensors 4A and 4B. The seismic intensity of 10B (for example, the lowest floor of the building 10) and the seismic intensity of the substructure 11 (and thus the ground) are quantified.

In this system 100, the amount of vibration energy absorbed by the base isolation device 1 is calculated by comparing the transferred measurement values of the acceleration sensors 4A and 4B using the analysis means 102. FIG. This makes it possible to evaluate the amount of vibration energy absorbed by the seismic isolation device 1 .

The system 100 also includes a laminate displacement history acquisition means 102B that acquires the displacement history of the laminate (seismic isolation rubber) 3 of the seismic isolation device 1 from the measured values transferred from each of the acceleration sensors 4A and 4B. can have

In this system 100, the laminate displacement history acquisition means 102B is included in the analysis means 102, and by using the laminate displacement history acquisition means 102B to verify the displacement history of the laminate 3, the seismic isolation device 1 damage degree can be confirmed.

Moreover, this system 100 can further include determination means 103 that determines the safety of the building 10 based on the transferred measured values of the acceleration sensors 4A and 4B.

In this system 100, by using the determination means 103, for example, by comparing the transferred measurement values of the acceleration sensors 4A and 4B with thresholds set in advance for each building in which the system 100 is installed, The safety of building 10 based on acceleration can be determined.

In addition, in this system 100, at least one of the seismic intensity of the upper structure 10B, the seismic intensity of the lower structure 11, and the displacement history of the laminate 3 is determined using the determination means 103 for each building in which the system 100 is installed. The safety of the building 10 based on the seismic intensity of the building 10 and/or the displacement history of the laminate 3 can be determined by comparing with a preset threshold value.

Furthermore, the system 100 can have a first communication means 105 for informing the residents 104 in the building 10 of the safety of the building 10 determined by the determination means 103 .

The first communication means 105 can be, for example, a monitor, and by displaying the judgment result (safety judgment result) by the judgment means 103 on the monitor using indicators that are easy for the resident 104 to understand, Residents 104 in the building 10 can be made aware of the safety of the building 10 after the occurrence of an earthquake or the like.

Also, the first communication means 105 can be a speaker, for example, and announces the determination result by the determination means 103 using an index that is easy for the resident 104 to understand, so that the building 10 can be restored after an earthquake or the like occurs. safety can be made known to the resident 104 in the building 10 . However, the first communication means in the present invention is not limited to these forms.

Furthermore, the system 100 can transfer the measured values of the acceleration sensors 4A and 4B and/or the seismic intensity of the upper structure 10B, the seismic intensity of the lower structure 11 and the lamination calculated from the measured values by the analysis means 102. It has a second communication means 107 for communicating at least one of the displacement histories of the body 3 to the exterior 106 of the building 10 .

The second communication means 107 can be, for example, a monitor, and by displaying the calculation result by the analysis means 102 on the monitor, the calculation result can be notified to the outside 106 of the building 10 . Here, the "outside 106 of the building 10" is, for example, the management company of the building 10, and the management company of the building 10 confirms the received numerical value, so that the building 10 can be operated without going to the building 10. It is possible to judge the necessity of 10 safety and emergency inspections.

In this system 100, the analyzing means 102 and the determining means 103 are arranged outside the building 10 (for example, on the cloud). Or it can be located outside 106 of building 10 .

In addition, in this system 100, at least one of the lower flange 2A4 and the upper flange 2B4 of the seismic isolation device 1 is provided with relative displacement in the height direction and/or relative displacement in the horizontal direction between the lower flange 2A4 and the upper flange 2B4. A displacement meter 5 for measuring relative displacement, and a relative displacement amount data transfer means (in this embodiment, acceleration (common with data transfer means) 101.

In this system 100, the measured value of the relative displacement in the height direction and/or the relative displacement in the horizontal direction between the lower flange 2A4 and the upper flange 2B4 by the displacement meter 5 is also transmitted by the relative displacement amount data transfer means 101. It is transferred to the analysis means 102 .

In this system 100, the analysis means 102 is used to calculate the amount of residual displacement of the seismic isolation device 1 from the transferred measurement value of the relative displacement. This makes it possible to easily calculate the displacement and inclination of the building.

In addition, in this system 100, by using the determination means 103, the calculated residual displacement amount is compared with a threshold value set in advance for each building in which the system 100 is installed, so that the building 10 based on the residual displacement amount is determined. can determine the safety of

In this system 100, the determination means 103 is based on the displacement history of the seismic isolation device 1 based on the measured value of the acceleration sensor 4 and the relative displacement amount of the seismic isolation device 1 based on the measured value of the displacement meter 5. In addition, it is also possible to judge the safety of a seismically isolated building. According to this configuration, even if the displacement history based on the measured value of the acceleration sensor 4 is within the assumed range, when the displacement history based on the measured value of the displacement meter 5 indicates an abnormality, the base isolated building can accurately determine the safety of

Further, in this system 100, the safety of the building 10 based on the amount of residual displacement of the seismic isolation device 1 determined by the determination means 103 is determined using the first communication means 105 by the resident 104 in the building 10. can be made known to

Furthermore, this system 100 uses the second communication means 105 to transmit the residual displacement amount of the seismic isolation device 1 calculated by the analysis means 102 and/or the comparison result between the residual displacement amount and the threshold value, The exterior 106 of the building 10 can be notified.

From the viewpoint of more accurately confirming the safety of the building 10 after the occurrence of an earthquake or the like, the system 100 of the present embodiment includes a lower flange, an upper flange, and a lower flange in the seismic isolation pit 10P. It is preferable that there are a plurality of seismic isolation devices each including a side flange and a laminate interposed between the upper flanges, and the above-described acceleration sensor is provided in each of the seismic isolation devices.

Since there may be cases where the measured values vary depending on the installation position of the acceleration sensor with respect to the building 10, etc., by collecting more measured values, the seismic intensity of the upper structure 10B of the building 10, the seismic intensity of the lower structure 11, and the lamination The displacement history of the body (seismic isolation rubber) 3 and the residual displacement amount of the seismic isolation device 1 can be calculated more accurately.

Further, from the viewpoint of more accurately confirming the safety of the building 10 after an earthquake or the like occurs, the acceleration sensor 4 is installed at a location other than the seismic isolation pit 10P in which the seismic isolation device 1 is installed in the building 10. Further, it is preferable to provide. In this case, the direct seismic intensity in the superstructure 10B can be confirmed.

As described above, the system of the present invention includes a lower flange, an upper flange, a laminate interposed between the lower flange and the upper flange, and at least one of the lower flange and the upper flange. a seismic isolation device comprising: an acceleration sensor provided in the seismic isolation device; It is possible to confirm the safety of the base-isolated building after the occurrence of an earthquake or the like.

Furthermore, in general, the acceleration sensor requires periodic inspection, but in the system of the present invention, the acceleration sensor is provided in the seismic isolation device, so it is possible to inspect the acceleration sensor together with the inspection of the seismic isolation device. can be done. In addition, since the inspection work of the acceleration sensor can be carried out simply by entering the seismic isolation pit, there is little burden on residents.

In the system of the present invention, the acceleration data transfer means, the relative displacement data transfer means, the first communication means, the second communication means, etc. are not limited to the forms described above, and may be appropriately changed according to the location where the system is used. can do.

In the seismic isolation monitoring system of the present invention, the displacement gauge includes an imaging unit, and the imaging unit captures images of the scale at predetermined time intervals, thereby detecting relative displacement in the height direction and/or relative displacement of the laminate in the horizontal direction. It is preferably configured to measure displacement. This makes it possible to more easily confirm the safety of the building after the occurrence of an earthquake or the like. The scale can be arranged, for example, in the vicinity of the displacement meter (for example, just below in the height direction). The imaging unit can use any known camera or the like, and is arranged at a location where the scale can be imaged.
The above-mentioned relative displacement in the height direction and/or relative displacement in the horizontal direction may be, for example, the maximum displacement or the minimum displacement (residual displacement after shaking stops), or between Displacement may also be used.
When obtaining the minimum displacement, the displacement gauge determines whether the change in the amount of relative displacement in the height direction and/or the relative displacement in the horizontal direction of the laminate is equal to or less than a predetermined threshold based on images captured at predetermined time intervals. It is also possible to use the amount of displacement at the point of time as the measurement result of the relative displacement in the height direction and/or the relative displacement in the horizontal direction. The "predetermined time interval" can be arbitrarily set, for example, every 5 minutes, every 10 minutes, every 20 minutes, or the like. Then, the displacement amount at the time when it becomes equal to or less than a predetermined threshold value can be used as the measurement result (for example, when the measurement result is obtained once a day, it can be used as the measurement result for that day). The above-mentioned "predetermined threshold value" can also be arbitrarily set, and can be set to 0 (measurement limit value), for example.

In the seismic isolation monitoring system of the present invention, the above relational expression θ ₁ + θ ₂ ≤ 90°, that is, the above relational expression
arctan (δ/h) + arctan ( _hs /x) ≤ 90°
is preferably satisfied.
This is because, by satisfying the above relational expression, it is possible to more reliably prevent the side surface portion of the deformed laminate from coming into contact with the acceleration sensor.

A seismic isolation monitoring system according to another aspect of the present invention is a seismic isolation monitoring system for monitoring a seismic isolated building in which a seismic isolation device is installed, comprising a laminate, and a stack provided at the lower end side and the upper end side of the laminate. and an acceleration sensor, the lower and upper flanges having lower and upper plates, respectively, through which the lower structure and a seismic isolation device fixed to the upper structure; provided on the plate and/or the top plate. The seismic isolation monitoring system of this aspect can also confirm the safety of the building after the occurrence of an earthquake or the like with a simple configuration.

<Seismic isolation monitoring method>
Next, FIG. 3 is a schematic diagram illustrating a seismic isolation monitoring method (hereinafter also simply referred to as "monitoring method") according to an embodiment of the present invention. In this monitoring method, the seismic isolation device 1 and system 100 described above are used.

That is, the monitoring method of the present embodiment includes a laminate (seismic isolation rubber) 3, a lower flange 2A4 and an upper flange 2B4 provided on the lower end side (lower side of the paper surface) and the upper end side (upper side of the paper surface) of the laminate 3. and an acceleration sensor 4 provided on at least one of the lower flange 2A4 and the upper flange 2B4, the acceleration in the lower flange 2A4 and/or the upper flange 2B4 is measured by It includes an acceleration measurement step (S101) for measuring, and an acceleration data transfer step (S102) for transferring the measured value by the acceleration sensor 4 to the outside of the seismic isolation pit 10P where the seismic isolation device 1 is installed.

In addition, this monitoring method can include an acceleration data analysis step (S103) of analyzing the acceleration data transferred in the acceleration data transfer step (S102) using any analysis means 102.

For example, the acceleration data analysis step (S103) of this monitoring method includes the following specific steps by providing acceleration sensors 4A and 4B on the lower flange 2A4 and upper flange 2B4 of the seismic isolation device 1, respectively. be able to.

For example, the acceleration data analysis step (S103) of this monitoring method uses the building seismic intensity quantification means 102A to quantify the seismic intensity of the building 10 from the measured values transferred from each of the acceleration sensors 4A and 4B. A building seismic intensity quantification step (S103a) can be included. In the building seismic intensity quantification step (S103a), using the building seismic intensity quantification means 102A included in the analysis means 102, from the transferred measured values of the acceleration sensors 4A and 4B, superstructure 10B (for example, the It is possible to quantify the seismic intensity of the bottom layer) and the seismic intensity of the substructure 11 (and thus the ground).

Further, for example, the acceleration data analysis step (S103) of this monitoring method uses the laminate displacement history acquisition means 102B to determine the lamination of the seismic isolation device 1 from the measured values transferred from the acceleration sensors 4A and 4B. A laminate displacement history acquisition step (103b) for acquiring a displacement history of the body (seismic isolation rubber) 3 can be included. In the laminated body displacement history acquisition step (103b), by verifying the displacement history of the laminated body 3, the degree of damage to the seismic isolation device 1 can be evaluated.

Further, for example, the acceleration data analysis step (S103) of this monitoring method calculates the amount of vibration energy absorbed by the seismic isolation device 1 by comparing the measured values transferred from the acceleration sensors 4A and 4B. A vibration energy absorption amount calculation step (S103c) can be included. This makes it possible to evaluate the amount of vibration energy absorbed by the seismic isolation device 1 .

Furthermore, this monitoring method can further include a safety determination step (S104) of determining the safety of the base isolated building 1 based on the transferred measurement values.

In this monitoring method, using an arbitrary determination means 103, for example, the transferred measurement values of the acceleration sensors 4A and 4B are compared with threshold values preset for each building in which the system 100 is installed. can determine the safety of the building 10 based on the acceleration.

Further, in this monitoring method, at least one of the seismic intensity of the upper structure 10B of the building 10, the seismic intensity of the lower structure 11, and the displacement history of the laminate 3 is set in advance for each building using the arbitrary determination means 103. The safety of the building 10 based on the seismic intensity of the building 10 and/or the displacement history of the laminate 3 can be determined by comparing with the set threshold.

Furthermore, this monitoring method further includes a first communication step (S105) of notifying the residents 104 in the building 10 of the safety (determination result) of the building 10 determined in the safety determination step (S104). can contain.

In addition, this monitoring method includes the transferred measured values by the acceleration sensors 4A and 4B and/or the seismic intensity (seismic intensity information) of the upper structure 10B and the seismic intensity of the lower structure 11 calculated from the measured values by the analysis means 102. (seismic intensity information) and at least one of the displacement history of the laminate 3 to the outside 106 of the building 10 (S106).

In the monitoring method of the present invention, the execution order of the building seismic intensity quantification step (103a), the laminate displacement history acquisition step (103b), and the vibration energy absorption amount calculation step (103b) is arbitrary. Also, any one or all of these steps can be performed.

Similarly, in the monitoring method of the present invention, the execution order of the first contact step (S105) and the second contact step (S106) is arbitrary. They can also run simultaneously. It is also possible to perform only one contact step.

As described above, in the monitoring method of the present invention, the laminate, at least one of the lower flange and the upper flange provided on the lower end side and the upper end side of the laminate, and at least one of the lower flange and the upper flange an acceleration sensor provided in the base isolation device to measure the acceleration in the lower flange and/or the upper flange using the seismic isolation device; and an acceleration data transfer step of transferring the data to the outside of the seismic isolation pit, the safety of the seismic isolated building after the occurrence of an earthquake or the like can be confirmed with a simple configuration.

Also, FIG. 4 is a flow diagram illustrating a monitoring method according to another embodiment of the present invention. This monitoring method also uses the seismic isolation device 1 and system 100 described above. In this monitoring method, description of steps similar to those of the monitoring method shown in FIG. 3 will be omitted.

In this monitoring method, a displacement gauge 5 is provided on at least one of the lower flange 2A4 and the upper flange 2B4, and the amount of relative displacement in the height direction and/or the relative displacement in the horizontal direction between the lower flange 2A4 and the upper flange 2B4 is measured. A relative displacement amount measurement step (S201) for measuring the displacement amount, and a relative displacement amount data transfer step (S202) for transferring the measured value by the displacement meter 5 to the outside of the seismic isolation pit where the seismic isolation device is installed. including.

In addition, this monitoring method may include a relative displacement amount data analysis step (S203) of analyzing the relative displacement amount data transferred in the relative displacement amount data transfer step (S202) using arbitrary analysis means 102. can.

For example, the relative displacement data analysis step (S203) of this monitoring method can include a step of performing the following analysis.

For example, the relative displacement amount data analysis step (S203) of this monitoring method includes a residual displacement amount calculation step (S203a) of calculating the residual displacement amount in the seismic isolation device 1 from the transferred horizontal relative displacement amount; and a residual displacement amount comparison step (S203b) of comparing the residual displacement amount with a predetermined threshold.

Further, for example, the relative displacement amount data analysis step (S203) of this monitoring method compares the transferred relative displacement amount in the height direction and/or the relative displacement amount in the horizontal direction with a predetermined threshold value. A step (S203c) can be further included.

Moreover, this monitoring method can further include a safety determination step (S204) of determining the safety of the base isolated building 1 based on the transferred measurement values.

In the safety determination step (S204) of this monitoring method, using the arbitrary determination means 103, for example, the transferred measured value of the displacement meter 5 is converted to a threshold value set in advance for each building in which the system 100 is installed. , it is possible to determine the safety of the building 10 based on the amount of relative displacement between the lower flange 2A4 and the upper flange 2B4 of the seismic isolation device 1.

Furthermore, this monitoring method further includes a first communication step (S205) of notifying the residents 104 in the building 10 of the safety (determination result) of the building 10 determined in the safety determination step (S204). can contain.

This monitoring method also informs the exterior 106 of the building 10 of the measured relative vertical displacement and/or relative horizontal displacement between the transferred lower flange 2A4 and the upper flange 2B4. , further comprising a second contact step (S206).

In the monitoring method of the present invention, the order of execution of the residual displacement amount comparison step (S203b) and the relative displacement amount comparison step (S203c) is arbitrary, and both of these steps may be executed. , can also be executed.

Similarly, in the monitoring method of the present invention, the execution order of the first contact step (S205) and the second contact step (S206) is arbitrary. They can also run simultaneously. It is also possible to perform only one contact step.

As described above, in the monitoring method of the present invention, at least one of the lower flange and the upper flange is provided with a displacement gauge, and the amount of relative displacement in the height direction and / or in the horizontal direction between the lower flange and the upper flange and a relative displacement data transfer step of transferring the measured value by the displacement meter to the outside of the seismic isolation pit where the seismic isolation device is installed. Therefore, the safety of the base-isolated building after the occurrence of an earthquake or the like can be confirmed with a simpler configuration.

It should be noted that the monitoring method of the present invention can include both the above-described steps shown in FIG. 3 and the above-described steps shown in FIG. In this case, the safety of the base-isolated building after the occurrence of an earthquake or the like can be determined in more detail.

Furthermore, although not shown, in a monitoring method according to still another embodiment of the present invention, an acceleration sensor 4 is further provided in a location other than the seismic isolation pit 10P where the seismic isolation device 1 is installed in the seismic isolated building 10, It may further include a first acceleration comparison step of comparing the measurement value of the acceleration sensor 4 provided in the seismic isolation pit 10P and the measurement value of the acceleration sensor 4 provided at a location other than the seismic isolation pit 10P. can. In this case, the above-described safety determination step (S104, S204) refers to the comparison result of the first acceleration comparison step to more accurately determine the safety of the base-isolated building after the occurrence of an earthquake or the like. can do.

Further, from the viewpoint of more strictly judging the safety of the base-isolated building after the occurrence of an earthquake or the like, in this monitoring method, the above-described safety judging steps (S104, S204) It is preferable to determine the safety of the building 10 based on the maximum measured value.

Furthermore, from a similar point of view, in this monitoring method, the above-described safety determination step (S104, S204) is based on the measurement value of the acceleration sensor 4 installed in the seismic isolation device 1 located closest to the center of gravity of the building 10. Preferably, the safety of the building 10 is determined based on.

Moreover, from the viewpoint of more accurately determining the safety of a base-isolated building after an earthquake or the like occurs, this monitoring method is based on the acceleration sensor 4 provided in the base-isolation device 1 closest to the center of gravity of the building 10. and the measured value of the acceleration sensor 4 provided in the seismic isolation device 1 farthest from the center of gravity of the building 10, further including a second acceleration comparison step for comparing the above-mentioned safety determination step ( S104, S204) preferably refer to this comparison result. In this case, the accuracy of determination can be mentioned above, and the number of installed acceleration sensors is preferably as large as possible.

In addition, in this monitoring method, based on the displacement history of the seismic isolation device 1 based on the measurement value of the acceleration sensor 4 and the relative displacement amount of the seismic isolation device 1 based on the measurement value of the displacement meter 5, can also determine the safety of According to this configuration, even if the displacement history based on the measured value of the acceleration sensor 4 is within the assumed range, when the displacement history based on the measured value of the displacement meter 5 indicates the above, etc., the base isolated building can accurately determine the safety of

In the seismic isolation monitoring method of the present invention, the displacement gauge includes an imaging unit, and the imaging unit captures images of the scale at predetermined time intervals, thereby detecting relative displacement in the height direction and/or relative displacement in the horizontal direction of the laminate. It is preferably configured to measure displacement. This makes it possible to more easily confirm the safety of the building after the occurrence of an earthquake or the like. The scale can be arranged, for example, in the vicinity of the displacement meter (for example, just below in the height direction). The imaging unit can use any known camera or the like, and is arranged at a location where the scale can be imaged.
In the above case, the displacement meter determines that the change in the amount of relative displacement in the height direction and/or the relative displacement in the horizontal direction of the laminate is equal to or less than a predetermined threshold based on the images captured at predetermined time intervals. The amount of displacement at that time can be used as the measurement result of the relative displacement in the height direction and/or the relative displacement in the horizontal direction. The "predetermined time interval" can be arbitrarily set, for example, every 5 minutes, every 10 minutes, every 20 minutes, or the like. Then, the displacement amount at the time when it becomes equal to or less than a predetermined threshold value can be used as the measurement result (for example, when the measurement result is obtained once a day, it can be used as the measurement result for that day). The above-mentioned "predetermined threshold value" can also be arbitrarily set, and can be set to 0 (measurement limit value), for example.

Also in the seismic isolation monitoring method of the present invention, the above relational expression θ ₁ + θ ₂ ≤ 90°, that is, the above relational expression
arctan (δ/h) + arctan ( _hs /x) ≤ 90°
is preferably satisfied.
This is because, by satisfying the above relational expression, it is possible to more reliably prevent the side surface portion of the deformed laminate from coming into contact with the acceleration sensor.

A seismic isolation monitoring method according to another aspect of the present invention is a seismic isolation monitoring method for monitoring a seismic isolated building, comprising a laminate, a lower flange and an upper flange provided on the lower end side and the upper end side of the laminate. and an acceleration sensor, the lower and upper flanges having lower and upper plates, respectively, fixed to the lower and upper structures via the lower and upper plates , an acceleration measurement step of measuring the acceleration in the lower plate and/or the upper plate using the seismic isolation device; and transferring the measured value by the acceleration sensor to the outside of the seismic isolation pit where the seismic isolation device is installed. and a data transfer step, wherein the acceleration sensor is provided on the lower plate and/or the upper plate. The seismic isolation monitoring method of this aspect also makes it possible to confirm the safety of the building after an earthquake or the like occurs with a simple configuration.

1: seismic isolation device, 2A4: lower flange, 2B4: upper flange, 3: laminate, 4, 4A, 4B: acceleration sensor, 5: displacement gauge

Claims (30)

A seismic isolation device comprising a laminated body and at least one of a lower flange and an upper flange provided on the lower end side and the upper end side of the laminated body,
An acceleration sensor is provided on at least one of the lower flange and the upper flange,
comprising both the lower flange and the upper flange;
The acceleration sensor is provided on each of the lower flange and the upper flange,
(1) The lower flange is further provided with a displacement meter for measuring the relative displacement in the horizontal direction between the lower flange and the upper flange, and the scale is in the height direction of the laminate, directly above the displacement gauge and/or
(2) The upper flange is further provided with a displacement gauge for measuring the horizontal relative displacement between the lower flange and the upper flange, and the scale is in the height direction of the laminate, Located directly below the displacement gauge,
The displacement meter includes an imaging unit,
The imaging unit is configured to measure the relative displacement in the horizontal direction by imaging the scale at predetermined time intervals,
A seismic isolation device, wherein the acceleration sensor provided on the lower flange is provided so as to face the acceleration sensor provided on the upper flange. Based on the images captured at the predetermined time intervals, the displacement meter calculates the displacement amount at the time when the change in the displacement amount of the horizontal relative displacement becomes equal to or less than a predetermined threshold value. 2. The seismic isolation device according to claim 1, which is used as a measurement result of . Let δ be the maximum horizontal displacement of the stack that occurs during an earthquake, x be the shortest distance between the stack and the acceleration sensor, h be the height of the stack, and _{hs be} the height of the acceleration sensor. , the relational expression,
arctan (δ/h) + arctan ( _hs /x) ≤ 90°
The seismic isolation device according to claim 1 or 2, which satisfies: A seismic isolation device comprising a laminated body and at least one of a lower flange and an upper flange provided on the lower end side and the upper end side of the laminated body,
said lower flange and said upper flange respectively having a lower flange and an upper flange adjacent said stack and a lower plate and an upper plate secured to said lower flange and upper flange;
secured to the lower and upper structures via the lower and upper plates;
an acceleration sensor is provided on the lower plate and/or the upper plate and/or on the lower flange and/or the upper flange;
comprising both said lower plate and said upper plate, comprising both said lower flange and said upper flange;
the acceleration sensor is provided on each of the lower plate and the upper plate, or on each of the lower flange and the upper flange;
(1) The lower plate is further provided with a displacement gauge for measuring the horizontal relative displacement between the lower plate and the upper plate , and the scale is in the height direction of the laminate, and the displacement gauge is and /or
(2) The upper plate is further provided with a displacement gauge for measuring the horizontal relative displacement between the lower plate and the upper plate, and the scale is in the height direction of the stack, and the displacement gauge is and / or
(3) The lower flange is further provided with a displacement gauge for measuring the horizontal relative displacement between the lower flange and the upper flange , and the scale is in the height direction of the laminate, and the displacement gauge is and /or
(4) The upper flange is further provided with a displacement gauge for measuring the horizontal relative displacement between the lower flange and the upper flange, and the scale is in the height direction of the laminate, and the displacement gauge is located directly below the
The displacement meter includes an imaging unit,
The imaging unit is configured to measure the relative displacement in the horizontal direction by imaging the scale at predetermined time intervals,
A seismic isolation device, wherein the acceleration sensor provided on the lower plate or the lower flange is provided so as to face the acceleration sensor provided on the upper plate or the upper flange. A seismic isolation monitoring system for monitoring a seismic isolated building in which a seismic isolation device is installed,
A laminated body, at least one of a lower flange and an upper flange provided on the lower end side and the upper end side of the laminated body, and an acceleration sensor provided on at least one of the lower flange and the upper flange;
comprising both the lower flange and the upper flange;
The acceleration sensor is provided on each of the lower flange and the upper flange,
(1) The lower flange is further provided with a displacement meter for measuring the relative displacement in the horizontal direction between the lower flange and the upper flange, and the scale is in the height direction of the laminate, a displacement gauge located directly above the displacement gauge and/or (2) on the upper flange for measuring relative horizontal displacement between the lower flange and the upper flange; , the scale is located directly below the displacement meter in the height direction of the laminate,
The displacement meter includes an imaging unit,
The imaging unit is configured to measure the relative displacement in the horizontal direction by imaging the scale at predetermined time intervals,
a seismic isolation device, wherein the acceleration sensor provided on the lower flange is provided so as to face the acceleration sensor provided on the upper flange;
Acceleration data transfer means for transferring the measured value by the acceleration sensor to the outside of the seismic isolation pit in which the seismic isolation device is installed. The seismic isolation device comprises both the lower flange and the upper flange, and has the acceleration sensors on each of the lower flange and the upper flange, measurements transferred from each of the acceleration sensors. 6. The seismic isolation monitoring system according to claim 5, further comprising building seismic intensity quantification means for quantifying the seismic intensity of said seismically isolated building. Laminate displacement, wherein the acceleration sensor is provided on each of the lower flange and the upper flange, and the displacement history of the laminate of the seismic isolation device is obtained from measured values transferred from each of the acceleration sensors. 7. The seismic isolation monitoring system according to claim 5, comprising history acquisition means. a displacement gauge on at least one of the lower flange and the upper flange for measuring relative horizontal displacement between the lower flange and the upper flange;
Relative displacement amount data transfer means for transferring the measured value by the displacement meter to the outside of the seismic isolation pit in which the seismic isolation device is installed;
The seismic isolation monitoring system according to any one of claims 5 to 7, further comprising: The seismic isolation pit has a plurality of seismic isolation devices each having a laminate and at least one of a lower flange and an upper flange provided on the lower end side and the upper end side of the laminate, and the acceleration sensor is connected to the seismic isolation device. The seismic isolation monitoring system according to any one of claims 5 to 8, provided in each seismic device. The seismic isolation monitoring system according to any one of claims 5 to 9, wherein the acceleration sensor is further provided in a location of the seismic isolated building other than the seismic isolation pit where the seismic isolation device is installed. Safety of the seismic isolated building based on the displacement history of the seismic isolation device based on the measurement value of the acceleration sensor and the amount of relative displacement of the seismic isolation device based on the measurement value of the displacement meter A seismic isolation monitoring system according to claim 8 when dependent on claim 7, comprising determining means for determining the . Based on the images captured at the predetermined time intervals, the displacement meter calculates the displacement amount at the time when the change in the displacement amount of the horizontal relative displacement becomes equal to or less than a predetermined threshold value. The seismic isolation monitoring system according to claim 11 , which is used as a measurement result of. Let δ be the maximum horizontal displacement of the stack that occurs during an earthquake, x be the shortest distance between the stack and the acceleration sensor, h be the height of the stack, and hs _be the height of the acceleration sensor. , the relational expression,
arctan (δ/h) + arctan ( _hs /x) ≤ 90°
The seismic isolation monitoring system according to any one of claims 5 to 12 , which satisfies A seismic isolation monitoring system for monitoring a seismic isolated building in which a seismic isolation device is installed,
A laminate, at least one of a lower flange and an upper flange provided on the lower end side and the upper end side of the laminate, and an acceleration sensor, wherein the lower flange and the upper flange are attached to the laminate, respectively. A seismic isolation having adjacent lower and upper flanges, lower and upper plates fixed to the lower and upper flanges, and fixed to the lower and upper structures via the lower and upper plates a device;
an acceleration data transfer means for transferring the measured value by the acceleration sensor to the outside of the seismic isolation pit where the seismic isolation device is installed;
the acceleration sensor is provided on the lower plate and/or the upper plate and/or is provided on the lower flange and/or the upper flange;
comprising both said lower plate and said upper plate, comprising both said lower flange and said upper flange;
the acceleration sensor is provided on each of the lower plate and the upper plate, or on each of the lower flange and the upper flange;
(1) The lower plate is further provided with a displacement gauge for measuring the horizontal relative displacement between the lower plate and the upper plate , and the scale is in the height direction of the laminate, and the displacement gauge is and /or
(2) The upper plate is further provided with a displacement gauge for measuring the horizontal relative displacement between the lower plate and the upper plate, and the scale is in the height direction of the stack, and the displacement gauge is and / or
(3) The lower flange is further provided with a displacement gauge for measuring the horizontal relative displacement between the lower flange and the upper flange , and the scale is in the height direction of the laminate, and the displacement gauge is and /or
(4) The upper flange is further provided with a displacement gauge for measuring the horizontal relative displacement between the lower flange and the upper flange , and the scale is in the height direction of the laminate, and the displacement gauge is located directly below the
The displacement meter includes an imaging unit,
The imaging unit is configured to measure the relative displacement in the horizontal direction by imaging the scale at predetermined time intervals,
A seismic isolation monitoring system, wherein the acceleration sensor provided on the lower plate or the lower flange is provided so as to face the acceleration sensor provided on the upper plate or the upper flange. A seismic isolation monitoring method for monitoring a seismic isolation building, comprising:
A seismic isolation comprising a laminated body, at least one of a lower flange and an upper flange provided on the lower end side and the upper end side of the laminated body, and an acceleration sensor provided on at least one of the lower flange and the upper flange an acceleration measurement step of using a device to measure acceleration at the lower flange and the upper flange;
an acceleration data transfer step of transferring the measured value by the acceleration sensor to the outside of the seismic isolation pit where the seismic isolation device is installed;
including
comprising both the lower flange and the upper flange;
The acceleration sensor is provided on each of the lower flange and the upper flange,
(1) The lower flange is further provided with a displacement meter for measuring the relative displacement in the horizontal direction between the lower flange and the upper flange, and the scale is in the height direction of the laminate, directly above the displacement gauge and/or
(2) The upper flange is further provided with a displacement gauge for measuring the horizontal relative displacement between the lower flange and the upper flange, and the scale is in the height direction of the laminate, Located directly below the displacement gauge ,
The displacement meter includes an imaging unit,
The imaging unit is configured to measure the relative displacement in the horizontal direction by imaging the scale at predetermined time intervals,
A seismic isolation monitoring method, wherein the acceleration sensor provided on the lower flange is provided so as to face the acceleration sensor provided on the upper flange. 16. The seismic isolation monitoring method according to claim 15, further comprising a safety determination step of determining safety of said base isolated building based on said transferred measurement values. The acceleration sensor is provided on each of the lower flange and the upper flange of a seismic isolation device that includes both the lower flange and the upper flange, and the seismic isolation is determined from measured values transferred from each of the acceleration sensors. The seismic isolation monitoring method according to claim 15 or 16 , further comprising a building seismic intensity quantification step of quantifying the seismic intensity of the building. Laminate displacement history acquisition, wherein the acceleration sensors are provided on each of the lower flange and the upper flange, and a displacement history of the laminate of the seismic isolation device is acquired from measurement values transferred from each of the acceleration sensors. The seismic isolation monitoring method according to any one of claims 15-17 , further comprising steps. a relative displacement measurement step of providing a displacement meter on at least one of the lower flange and the upper flange to measure the relative displacement in the horizontal direction between the lower flange and the upper flange;
a relative displacement data transfer step of transferring the measured value by the displacement gauge to the outside of the seismic isolation pit in which the seismic isolation device is installed;
The seismic isolation monitoring method according to any one of claims 15 to 18 , further comprising: a residual displacement amount calculating step of calculating a residual displacement amount in the seismic isolation device from the transferred amount of relative displacement in the horizontal direction;
a residual displacement amount comparison step of comparing the residual displacement amount with a predetermined threshold;
further comprising
A seismic isolation monitoring method according to claim 19 when dependent on claim 16 , wherein said safety determination step refers to the result of the comparison in said residual displacement amount comparison step. further comprising a relative displacement amount comparison step of comparing the transferred horizontal relative displacement amount with a predetermined threshold;
21. The seismic isolation monitoring method according to claim 20 , wherein said safety determination step refers to the result of comparison in said relative displacement amount comparison step. The acceleration sensor is further provided in the seismic isolated building at a location other than the seismic isolation pit where the seismic isolation device is installed, and the measured value of the acceleration sensor provided in the seismic isolation pit and the seismic isolation pit further comprising an acceleration comparison step of comparing the measured value by the acceleration sensor provided at a location other than
22. The seismic isolation monitoring method according to claim 21 , wherein said safety determination step refers to the result of comparison in said acceleration comparison step. 17. The seismic isolation monitoring method according to claim 16 , wherein said safety determination step determines safety of said base isolated building based on a maximum measured value among measured values of said acceleration sensor. 17. The safety determination step determines the safety of the base isolated building based on the measured value of the acceleration sensor installed in the base isolation device located closest to the center of gravity of the base isolated building. Seismic isolation monitoring method described in . In the safety determination step, the measurement value of the acceleration sensor provided on the base isolation device closest to the center of gravity of the base isolated building and the measurement value of the base isolation device provided on the base isolation device farthest from the center of gravity of the base isolated building. 17. The seismic isolation monitoring method according to claim 16 , wherein the safety of said seismically isolated building is determined based on the measured value of said acceleration sensor. In the safety determination step, based on the displacement history of the seismic isolation device based on the measured value of the acceleration sensor and the relative displacement amount of the seismic isolation device based on the measured value of the displacement meter, 19. A seismic isolation monitoring method according to claim 18 when dependent on claim 16 , for determining the safety of a seismically isolated building. 20. The seismic isolation monitoring method according to claim 19 , wherein said relative displacement amount measuring step measures said relative displacement in said horizontal direction by capturing images of said scale at predetermined time intervals by said imaging unit. In the relative displacement amount measuring step, based on the images captured at the predetermined time intervals, the amount of displacement at the time when the change in the amount of relative displacement in the horizontal direction becomes equal to or less than a predetermined threshold is measured as the amount of displacement in the horizontal direction . The seismic isolation monitoring method according to claim 27 , which is used as a measurement result of relative displacement of. Let δ be the maximum horizontal displacement of the stack that occurs during an earthquake, x be the shortest distance between the stack and the acceleration sensor, h be the height of the stack, and hs _be the height of the acceleration sensor. , the relational expression,
arctan (δ/h) + arctan ( _hs /x) ≤ 90°
The seismic isolation monitoring method according to any one of claims 15 to 28 , satisfying A seismic isolation monitoring method for monitoring a seismic isolation building, comprising:
A laminate, at least one of a lower flange and an upper flange provided on the lower end side and the upper end side of the laminate, and an acceleration sensor, wherein the lower flange and the upper flange are attached to the laminate, respectively. A seismic isolation having adjacent lower and upper flanges, lower and upper plates fixed to the lower and upper flanges, and fixed to the lower and upper structures via the lower and upper plates an acceleration measurement step of using a device to measure acceleration in the lower plate and/or the upper plate;
an acceleration data transfer step of transferring the measured value by the acceleration sensor to the outside of the seismic isolation pit where the seismic isolation device is installed;
including
the acceleration sensor is provided on the lower plate and/or the upper plate and/or is provided on the lower flange and/or the upper flange;
comprising both said lower plate and said upper plate, comprising both said lower flange and said upper flange;
the acceleration sensor is provided on each of the lower plate and the upper plate, or on each of the lower flange and the upper flange;
(1) The lower plate is further provided with a displacement gauge for measuring the horizontal relative displacement between the lower plate and the upper plate, and the scale is in the height direction of the laminate, and the displacement gauge is and /or
(2) The upper plate is further provided with a displacement gauge for measuring the horizontal relative displacement between the lower plate and the upper plate, and the scale is in the height direction of the stack, and the displacement gauge is and / or
(3) The lower flange is further provided with a displacement gauge for measuring the horizontal relative displacement between the lower flange and the upper flange , and the scale is in the height direction of the laminate, and the displacement gauge is and /or
(4) The upper flange is further provided with a displacement gauge for measuring the horizontal relative displacement between the lower flange and the upper flange, and the scale is in the height direction of the laminate, and the displacement gauge is located directly below the
The displacement meter includes an imaging unit,
The imaging unit is configured to measure the relative displacement in the horizontal direction by imaging the scale at predetermined time intervals,
A seismic isolation monitoring method, wherein the acceleration sensor provided on the lower plate or the lower flange is provided so as to face the acceleration sensor provided on the upper plate or the upper flange.

Images