JPH09197056A - Earthquake information grasping device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To gather and grasp detailed earthquake information in real-time by widely networking earthquake countermeasures introduced in building structure units. SOLUTION: This device comprises a number of earthquake sensors 10, a wide earthquake information gripping device 12, and a communication line 14 for electrically connecting these. The earthquake sensors are either earthquake sensors or acceleration meters which have been conventionally individually installed at an elevator 1 of a building structure 2. An output signal detected by the earthquake sensors 10 is centrally received by a wide earthquake information gripping device 12 via the communication line 14 as earthquake information. This device 12 has an external storage 16, a display means 18, an operation display control means 20, and an input means 22. The external storage 16 stores map data 16a and building data 16b. When an earthquake exceeding a certain scale occurs, earthquake information is inputted via the earthquake sensor 10 and the acceleration and the degree of earthquake are displayed by the display means 18.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a seismic information grasping device, and more particularly to a device capable of accurately grasping seismic information in a wide range in real time.

[0002]

2. Description of the Related Art Earthquake information in Japan is currently transmitted mainly through television broadcasting, and this earthquake information is usually obtained by seismic intensity, epicenter position, and earthquake It is the scale and so on. In order to obtain such earthquake information, seismographs are installed in each municipality or in an earthquake-prone area.

However, when a large earthquake occurs, it is necessary to grasp the damage situation promptly and accurately and to take appropriate measures. For this purpose, it is necessary to obtain accurate earthquake information in the area in real time in units smaller than the municipal level. However, the seismograph that collects seismic information is not necessarily installed in a necessary place due to its high price and data transmission / reception facilities, and in reality it is not possible to meet such a request. is there.

On the other hand, as is well known, most of the buildings of medium size or larger that are constructed in Japan have elevators installed therein, and the buildings provided with elevators usually have an elevator installed at the time of earthquake occurrence. As a safety measure, a vibration sensor or accelerometer is installed. FIG. 4 shows an example of the installation state of this type of elevator. In the elevator 1 shown in the figure, an elevator cage 5 hung via an elevating mechanism 4 is provided in an elevator shaft 3 that is provided so as to pass through substantially the center of a building 2 in the vertical direction. In the machine room 6 provided on the upper end side of the shaft 3, a seismoscope or an accelerometer 7 is installed, and the accelerometer 7 is connected to an operation control device 8 installed in another place. There is.

In the elevator 1 constructed in this way,
When an earthquake of a predetermined scale or more occurs and this is detected by the accelerometer 7, the earthquake information is transmitted to the operation control device 8,
The operation control device 8 that has obtained such earthquake information sends a control signal to the elevating mechanism 4 to stop the elevator cage 5 immediately or to stop at the nearest floor. However, in such an earthquake countermeasure for the elevator 1, each building is used as a unit of 2 units and is used only for operation control of the elevator 1.

In view of this, in the present invention, the earthquake countermeasures currently introduced in units of building structures are networked over a wide area, so that it is possible to collect and grasp detailed earthquake information in real time. It is intended for information graspers.

[0007]

In order to achieve the above object, the present invention relates to a large number of seismic sensors such as seismic sensors and accelerometers individually installed in a building structure, and communication with each seismic sensor. A wide-area seismic information grasping device connected via a line and centrally receiving the detection signal of the seismic sensor as seismic information. According to the seismic information grasping apparatus configured as described above, it is possible to effectively utilize the seismic information obtained in real time for each building structure. The wide area earthquake information grasping device is divided into a grid pattern at predetermined distance intervals and has a storage unit for storing map data which allows selection of expansion and contraction of a display range; and a display unit for displaying this map data,
The calculation and display control means may be configured to display the acceleration or seismic intensity for each of the sections on the map data displayed by the display means in different colors based on the detection signal of the seismic sensor existing in the section. According to the seismic information grasping apparatus configured as described above, since the acceleration or seismic intensity is color-coded and displayed in each of the sections partitioned in a grid pattern, it is possible to recognize the distribution state at a glance. In addition, the wide area earthquake information grasping device,
A storage means for storing building data such as the year of construction, the type of structure, the number of floors of the building structure existing in the section,
The calculation display means predictively calculates the degree of damage to the building structure based on the detection signal of the seismic sensor and the building data, and displays the degree of damage in color on the map data displayed by the display means. Can be made. According to the seismic information grasping phase configured in this way, the predicted damage level of the building structure is displayed in different colors, so that the predicted damage status can be recognized at a glance. In the seismic information grasping device, the information of the seismic sensor is estimated and calculated in the vicinity of the ground surface in consideration of the vibration response performance based on the structure of the building structure and the height of the installation position of the seismic sensor. Can be used as earthquake information.

[0008]

Embodiments of the present invention will be described below in detail with reference to the accompanying drawings. 1 to 3
Shows an embodiment of an earthquake information grasping apparatus according to the present invention. The seismic information grasping apparatus shown in the figure is roughly constituted by a large number of seismic sensors 10, a wide area seismic information grasping apparatus 12, and a communication line 14 electrically connecting them.

The seismic sensor 10 has conventionally been used for building structures 2
Is a seismograph or accelerometer individually installed in the elevator 1. When the sensor 10 detects an earthquake of a predetermined magnitude or more, the operation control device 8 executes a measure such as stopping. To be done. The output signals detected by the large number of seismic sensors 10 are intensively received by the wide area seismic information grasping device 12 as seismic information via a dedicated or public communication line 14.

Wide area seismic information grasping apparatus 12 of this embodiment
Is composed of a so-called computer, and has an external storage unit 16, a display unit 18, and an arithmetic display control unit 20.
And input means 22. The external storage means 16 stores and stores map data 16a and building data 16b. The map data 16a, as one example is shown in FIG. 3, is provided with data capable of displaying a section map A which is sectioned in a grid pattern at predetermined intervals, for example, every 500 m, and the map data 16a includes , Social facilities such as railways and roads, and rivers and lakes are included.

Further, the map data 16a includes various hierarchical maps such as map data showing each region such as the Kanto region and the Kansai region from a map of Japan, or data capable of displaying a unit of a municipality or a ward of a city. The data is included and can be enlarged or reduced at an arbitrary position while being displayed on the display unit 18. Building data 16
b includes the building structure 2 in which the seismic sensor 10 is installed, the building year of the main building existing in the section map A, the structural type (wooden, steel frame structure, rebar structure, etc.), the number of floors, etc. Information is stored and stored.

The arithmetic display control means 20 includes an arithmetic unit 20a.
A display control unit 20b, an internal memory 20c, and an input / output interface 20d, the external storage means 16 is connected via the input / output interface 20d, and one end of the communication line 14 is input / output. It is connected to the interface 20d. The display means 18 is composed of a liquid crystal display capable of color display, a CRT or the like, and is connected to the input / output interface 20d. The input means 22 includes a keyboard 22a and a mouse 22.
b, which are connected to the input / output interface 20d.

Next, an example of the operation of the wide area seismic information grasping apparatus 12 thus constructed will be described with reference to FIG. When an earthquake of a certain magnitude or more occurs, seismic information such as the acceleration is input through the seismic sensor 10. Therefore, for example, the arithmetic display control means 20 of the wide area seismic information grasping device 12 based on the input information from the first seismic sensor 10. Is started.

When the arithmetic display control means 20 is activated, first, in step s1, a map of Japan is displayed on the display means 18, and the input position of the seismic sensor 10 is also displayed on the map. The operator looks at this and the mouse 22
An appropriate scale is set by b, and the display content of the display means 18 is selected. FIG. 3A shows an example of the selected display content.

In the display contents shown in the figure, a division map A divided in a grid pattern at a predetermined interval is displayed on the display means 18, and the division map A shows the construction stored in the building data 16b. The structure is shown as a triangle. Further, in the figure, black triangles are buildings in which the earthquake sensor 10 is installed, and white triangles are buildings in which the earthquake sensor 10 is not installed. When the selection of such display contents is completed, in step s2, the acceleration of each unit section shown in the section map A is calculated based on the detection signal of each seismic sensor 10.

At this time, if the seismic sensor 10 is an accelerometer, the detection signal is used as it is, and in the case of a seismic sensor, the acceleration is calculated from its amplitude, frequency, etc. Further, for a blank section where the seismic sensor 10 is not installed, the acceleration of the blank section is obtained by applying, for example, proportional calculation of distance or load calculation based on the acceleration value of the peripheral section.

When the acceleration for each section is obtained, step s
The display is performed at 3. The display state at this time is a multi-stage display in which colors are different, and an example thereof is shown in FIG.
This is illustrated in (B). In step s3 described above, it is also possible to obtain the seismic intensity for each section from the calculated acceleration and display this on the section map A. In the following step s4, it is determined whether or not a request for displaying the building damage has been issued, and if not, the procedure ends.

On the other hand, if it is determined in step s4 that a request to display the building damage has been issued, a prediction calculation of the building damage degree is performed in step s5. The prediction calculation of the building damage degree at this time is obtained by the following calculation formula from the acceleration for each section calculated in step s2 and the content of the building data 16b existing in the section. Building damage level = Is × Es Is: Content of building data for each building (structure type, etc.) Es = 4.1 × √ (1 / (10 × T)) × acceleration for each section T: Number of floors of building is 1 0.14 for floors, 2 floors for building
When the number of floors is higher than or equal to 0.14 × (3 × (number of floors-1) ^1/4 , and when the number of floors is 0, it is excluded from the calculation target.
If> 1.0, there is no damage.

When the damage level of each building is obtained by the above calculation formula, in step s6, according to the size of the degree,
As shown in FIG. 3C, this is displayed in different colors, and the procedure ends. Now, according to the seismic information grasping apparatus configured as described above, it is possible to effectively utilize real-time seismic information obtained for each building structure. Further, in the case of the present embodiment, the accelerations are color-coded and displayed in the sections partitioned in a grid pattern, so that the distribution state of these can be recognized at a glance.

Further, in the case of the present embodiment, since the predicted damage level of the building structure is displayed in different colors, it is possible to recognize the predicted damage status at a glance. In addition, in the said Example, although the case where the seismic sensor 10 laid in the elevator of a building was utilized was illustrated, in implementation of this invention, other than the seismic sensor for controlling an elevator can be utilized. .

Further, the seismic sensor 10 is preferably located near the ground surface. When the seismic sensor 10 is provided on the upper part of the building as shown in FIG. 1, the vibration response performance and the seismic response based on the structure of the building are obtained. The acceleration near the ground surface is estimated and calculated in consideration of the height of the installation position of the sensor 10 before use.

[0022]

As described above in detail in the embodiments,
According to the seismic information grasping apparatus of the present invention, it is possible to effectively use the seismic information already introduced to the building structure. Also, according to the configuration of claim 2, since the acceleration or seismic intensity is displayed in different colors in a narrow area,
The magnitude of the earthquake can be recognized at a glance, and the damage can be predicted in detail.

Furthermore, according to the third aspect of the present invention, since the predicted building damage degree is displayed in different colors in a divided area, it is possible to quickly devise a countermeasure thereafter.

[Brief description of drawings]

FIG. 1 is a block configuration diagram showing an overall configuration of an embodiment of an earthquake information grasping apparatus according to the present invention.

FIG. 2 is a flowchart showing an example of a control procedure executed by the device shown in FIG.

3 is an explanatory diagram of contents displayed on a display unit of the earthquake information grasping device shown in FIG.

FIG. 4 is an explanatory diagram showing an example of a building in which an elevator is installed.

[Explanation of symbols]

 10 seismic sensor 12 seismic information grasping device 14 communication line 16 external storage means 16a map data 16b building data 18 display means 20 arithmetic display control section 20a arithmetic section 20b display control section 22 input means

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI Technical display location G01V 1/34 G01V 1/34

Claims (4)

[Claims] 1. A large number of seismic sensors, such as seismic sensors and accelerometers, which are individually installed in a building structure, are connected to each seismic sensor via a communication line, and the seismic sensor detects signals as seismic information. Earthquake information grasping device having a wide area seismic information grasping device which receives as a centralized information. 2. The wide area seismic information grasping device is divided into a grid pattern at predetermined distance intervals and stores a map data which allows selection of enlargement / reduction of a display range, and displays the map data. A display unit; and an arithmetic display control unit for displaying the acceleration or seismic intensity for each section on the map data displayed by the display section in different colors based on the detection signal of the seismic sensor existing in the section. The seismic information grasping device according to claim 1. 3. The wide area seismic information grasping device has a storage means for storing building data such as a building year, a structure type, and the number of floors of a building structure existing in the section, and the calculation display means is Based on the detection signal of the seismic sensor and the building data, predictive calculation of the damage level of the building structure,
3. The seismic information grasping apparatus according to claim 2, wherein the degree of damage is color-coded and displayed on the map data displayed by the display means. 4. An earthquake after estimating and calculating acceleration near the ground surface in consideration of the vibration response performance based on the structure of the building structure and the height of the installation position of the earthquake sensor, based on the information of the earthquake sensor. The earthquake information grasping apparatus according to claim 1, which is used as information.