KR20200072544A - Elevator system - Google Patents

Abstract

As an elevator system 100 having an earthquake sensor 220 and an elevator system 100 having a monitoring center 300, the elevator 20 is configured to generate a high acceleration that the earthquake sensor 220 exceeds a driving stop threshold. When it senses, it stops driving, sends a high acceleration detection signal and a stop signal to the monitoring center 300, and the monitoring center 300 is an elevator customer storing the ground amplification factor of the earth where the elevator 20 is installed. With the data 450, when the high acceleration detection signal and the operation stop signal are received from the elevator 20, the magnitude of the earth on which the elevator 20 is installed is less than the intensity threshold, and the ground amplification rate of the earth is less than the predetermined threshold. In this case, a signal for executing the automatic recovery diagnosis operation is sent to the elevator 20.

Description

Elevator system

The present invention relates to an elevator system capable of automatically recovering an elevator when it is assumed that the elevator is hardly damaged even when the earthquake sensor detects high acceleration.

In the case of an earthquake, the elevator is subjected to earthquake control operation. Seismic control operation, for example, when the acceleration of the ground surface detected by the seismic sensor exceeds a predetermined low threshold, stops at the nearest floor and automatically recovers by performing an automatic recovery diagnosis, and when the acceleration exceeds a predetermined high threshold For example, stop at the nearest floor and stop driving. When the operation is stopped due to seismic control operation, a human engineer is dispatched to the elevator to perform human recovery (for example, see Patent Document 1).

JP 2016-23044 A

On the other hand, even when the earthquake sensor detects high acceleration, the elevator may hardly be damaged depending on the magnitude of the earthquake or the area where the elevator is installed. However, in seismic control operation, even when the elevator is unlikely to be damaged, many elevators may be stopped at the same time, and there is a problem that it takes time to recover the elevator.

Thus, an object of the present invention is to enable automatic recovery of an elevator when it is assumed that the elevator is hardly damaged even when the earthquake sensor detects high acceleration.

The elevator system of the present invention is an elevator system including an elevator having an earthquake sensor for sensing acceleration of the ground surface and a monitoring center monitoring the elevator in communication with the elevator, wherein the earthquake sensor stops driving. When a high acceleration exceeding a threshold is detected, the operation is stopped, and a high acceleration detection signal and a stop operation signal are sent to the monitoring center, and the monitoring center increases the ground amplification rate of the earth where the elevator is installed. With the elevator customer data stored, when the high acceleration detection signal and the operation stop signal are received from the elevator, the progress of the district where the elevator is installed is less than a progress threshold, and the ground amplification factor of the district is a predetermined threshold. If less than, it characterized in that it sends a signal to execute the automatic recovery diagnosis operation to the elevator.

In the elevator system of the present invention, the monitoring center acquires seismic information of the district where the elevator is installed from a plurality of seismic information providing organizations after an earthquake, and at least two seismic intensity thresholds in the acquired seismic information In the case below, a signal for executing an automatic recovery diagnosis operation may be sent to the elevator.

In the elevator system of the present invention, the monitoring center acquires progress information of a region in which the elevators are installed from a plurality of earthquake information providing organizations after an earthquake occurs, and the progress above the threshold is not observed in the region. In the case, in the elevator installed in the area, the high acceleration detection signal and the operation stop signal are transmitted to the monitoring center, and the elevator is automatically restored to the elevator in which the ground amplification factor of the district is less than a predetermined threshold. The signal for executing the diagnostic operation may be transmitted.

The present invention can enable automatic recovery of the elevator when it is assumed that the elevator is hardly damaged even when the earthquake sensor detects high acceleration.

1 is a system diagram showing the configuration of an elevator system of an embodiment.
FIG. 2 is a functional block diagram of the elevator system of the embodiment shown in FIG. 1.
3 is a diagram showing an example of a high-acceleration detection elevator list, elevator customer data, an automatic recovery diagnosis execution judgment table, and earthquake information.
4 is a view showing an example of the automatic recovery diagnostic command transmission list.
FIG. 5 is an overall view of a flowchart showing the operation of the elevator system of the embodiment shown in FIG. 1.
FIG. 6 is the second half of the flowchart showing the operation of the elevator system of the embodiment shown in FIG. 1.
7 is another functional block diagram of the elevator system of the embodiment shown in FIG. 1.
8 is a diagram showing another example of whether or not to perform an auto-recovery diagnosis execution table for each region and earthquake information.
FIG. 9 is a diagram showing another example of a high-acceleration detection elevator list, elevator customer data, an automatic recovery diagnosis execution list for each region, and an automatic recovery diagnosis recovery command transmission list.
10 is an overall view of a flow chart showing another operation of the elevator system of the embodiment shown in FIG. 1.

<Configuration of elevator system>

Hereinafter, the elevator system 100 of the embodiment will be described with reference to the drawings. As shown in FIG. 1, the elevator system 100 includes an elevator 20 having an earthquake sensor 220 for sensing the acceleration of the surface, and a monitoring center monitoring the elevator 20 in communication with the elevator 20. It is equipped with 300.

The elevator 20 is installed in the hoistway 11 of the building 10 and controls the control panel 200 for driving control of the elevator 20 and the operation status data of the elevator 20 input from the control panel 200. It has a communication device 210 for transmitting to the communication network (30). The control panel 200 and the communication device 210 are computers that include a CPU and memory therein. The communication device 210 receives the command signal from the information processing device 310 of the monitoring center 300 via the communication device 320 and the communication network 30 and outputs the command signal to the control panel 200. The communication devices 210 and 320 may be devices that perform wireless communication or devices that perform wired communication. Further, the communication network 30 may be an Internet communication network or a telephone line network. In Fig. 1, reference numeral 22 denotes a car, reference numeral 26 denotes a door of the car 22, reference numeral 27 denotes a floor of the car 22, reference numeral 12 denotes a floor of the platform, 13 ) Indicates the door of the platform.

The monitoring center 300, via the communication devices 210 and 320, the control panel 200 of the elevator 20 and the information processing device 310 and the monitoring panel 330 for receiving the operation status data, the elevator customer data It is equipped with 450. The information processing device 310 is a computer including a CPU and a memory therein, and outputs the operation status data input from the control panel 200 of the elevator 20 to the monitoring panel 330, and also controls the control panel of the elevator 20. A command signal is generated and output based on the driving condition data input from (200). The command signal output from the information processing device 310 is transmitted to the control panel 200 of the elevator 20 via the communication device 320 and the communication network 30. The monitoring panel 330 is provided with a display 331 on which the operation status of the elevator 20, a notification from the information processing device 310, and the like, and a switch 332 for manipulating the display on the display 331 are provided. . In addition, the monitoring panel 330 is provided with a telephone 333 that communicates with the service center 340 via a communication network 35.

As shown in Fig. 3, the elevator customer data 450 includes the identification number of the elevator 20, the address of the installation site indicating the district or region where the elevator 20 is installed, the name of the installation building, and installation. It is a database stored in relation to the ground amplification rate of a place. The ground amplification factor is a measure of the degree of amplification of the seismic wave from the engineered base, which is a stable hard layer, to the surface. This is a measure of the magnitude of the shaking at the time of an earthquake on the surface ground, and indicates that the larger the value, the more easily the surface ground is shaken. In Japan, the Earthquake Research Research Promotion Headquarters (Seismic and Disaster Prevention Research Division of the Ministry of Education, Culture, Sports, Science and Technology) releases numerical data for each 250m mesh ground. If the ground amplification factor exceeds 1.6, it may be of interest. The elevator customer data 450 in FIG. 3 extracts the earthquake amplification rate at the address where each elevator 20 is installed from the public data and correlates the data with the elevator 20.

In addition, as shown in FIG. 1, the information processing apparatus 310 is connected to the organizations A and B which are a plurality of earthquake information providing organizations via the communication network 35, and when there is an earthquake, the organizations A and B From the seismic information is input as earthquake information 410 and 420, respectively.

<Operation of the elevator system>

Next, the operation of the elevator system 100 when an earthquake occurs is described with reference to FIGS. 2 to 6. In the following description, as shown in FIG. 3, from the organization A and the organization B, the earthquake information 410 and 420 including the epicenter and earthquake magnitude information of each prefecture as well as the epicenter and earthquake scale are information. It will be described as being input to the processing device 310.

As shown in step S101 of FIG. 5, the control panel 200 monitors the acceleration of the ground surface input from the earthquake sensor 220, and when the earthquake detection acceleration (LL), for example, exceeds about 30 gal, the earthquake It is determined that it has occurred and proceeds to step S102 of FIG. 5 to determine whether the acceleration input from the earthquake sensor 220 has exceeded the driving stop area value L. Here, the driving constant area value L is larger than the earthquake detection acceleration LL, and may be, for example, about 80 gal. If the acceleration does not exceed the driving stop area value L, the process proceeds to step S103 in FIG. 5, and the control panel 200 stops the car by stopping the car 22 of the elevator 20 on the nearest floor, After a predetermined time, for example, after 3 minutes have elapsed, normal operation of the elevator 20 is resumed. In addition, when the acceleration exceeds the driving stop area value L in step S102 of FIG. 5, the process proceeds to step S104 of FIG. 5, and the control panel 200 determines whether the acceleration exceeds the driving area value H. Judge. Here, the area value H during operation is larger than the operation constant area value L, and may be, for example, about 120 gal. If the acceleration does not exceed the area value H during operation, the control panel 200 jumps to step S111 in FIG. 6, resets the earthquake sensor 220, and performs an automatic recovery diagnosis operation. This will be described later.

On the other hand, when the acceleration exceeds the operating area value H, the control panel 200 determines to be YES in step S104 of FIG. 5 and proceeds to step S105 of FIG. 5, as shown in FIG. The operation of the elevator 20 is stopped, and a stop operation signal and a high acceleration detection signal are output. 2, the operation stop signal and the high acceleration detection signal output by the control panel 200 are input to the communication device 210. The communication device 210 transmits a stop operation signal and a high acceleration detection signal to the communication network 30. The transmitted operation stop signal and the high acceleration detection signal are received by the communication device 320 of the monitoring center 300 and input to the information processing device 310 of the monitoring center 300.

In the information processing device 310, a driving stop signal and a high acceleration detection signal are input from the elevators 20 in various places. As shown in step S106 in FIG. 5, the information processing device 310 generates the high acceleration sensing elevator list 500 shown in FIG. 3 based on the received signal. The high-acceleration detection elevator list 500 is a list of identification numbers and installation locations of the elevators 20 that have transmitted high-acceleration detection signals.

Next, as shown in Figs. 2 and 3, the information processing device 310 generates the auto-recovery diagnosis execution judgment table 510 in step S107 of Fig. 5. The information processing device 310 displays the progress information for each district of each prefecture in the earthquake information 410 and 420 from the organization A and the organization B in the high acceleration sensing elevator list 500 and the ground amplification factor of the elevator customer data 450. For reference, an auto-recovery diagnosis execution judgment table 510 is generated as follows.

When the progress information from the organization A of the district including the installation location of the elevator 20 that senses the high acceleration is less than the intensity threshold, the information processing device 310 is the elevator 20 in the high acceleration detection elevator list 500 ) Enter "OK" in the field of earthquake information for organization A. Conversely, when the progress information from the organization A of the earth including the installation location of the elevator 20 detecting the high acceleration is equal to or higher than the intensity threshold, the information processing device 310 seismic information of the organization A of the elevator 20 Enter "NG" in the box. The same is true for earthquake information from organization B. Here, the magnitude threshold is a magnitude at which the elevator 20 is not damaged, and may be, for example, a magnitude of 5 or the like. In this case, the information processing device 310, the elevator A of the identification numbers S1001 and S1002 installed in Saitama Prefecture with a magnitude of 3 or 4, the organization A of the auto-recovery diagnosis execution availability judgment table 510, Enter "OK" in the earthquake information column of B, and enter "NG" in the earthquake information column of organization A and B in the elevator 20 of identification number C1001 installed in Chiba Prefecture including magnitude 5. do.

In addition, the information processing device 310 extracts the ground amplification factor of the elevator 20 listed up in the high acceleration sensing elevator list 500 with reference to the elevator customer data 450, and the ground amplification factor is less than a predetermined threshold. In the case, "OK" is entered in the ground amplification factor field in the auto-recovery diagnosis execution judgment table 510. Conversely, when the ground amplification factor is equal to or greater than a predetermined threshold, the information processing device 310 inputs "NG" into the field of the ground amplification factor of the elevator 20. Here, the predetermined threshold value is a value assumed to not cause the elevator 20 to be greatly shaken by amplification of the seismic wave by the ground, and is 1.6 in the present embodiment. In this case, the information processing device 310, in the elevator 20 of the identification numbers S1001 and S1002 installed in Saitama Prefecture, where the ground amplification rate is less than 1.6, "OK" in the column of the ground amplification rate of the auto-recovery diagnosis execution judgment table 510 Enter, and in the elevator 20 of the identification numbers C1001 installed in Chiba Prefecture with a ground amplification factor of 1.6 or higher, and the identification numbers T1001 and T1002 installed in Tokyo, "NG" is entered in the field of the earthquake amplification factor.

Then, the information processing device 310, in step S108 of FIG. 5, "OK" is entered in the two earthquake information fields in the auto-recovery diagnosis execution judgment table 510, and furthermore, the auto-recovery diagnosis is executed. The elevator 20 in which "OK" is input in the column of the ground amplification factor of the admissibility determination table 510 is selected, and the automatic recovery diagnostic command dispatch list 520 as shown in FIG. 4 is generated. In this embodiment, as shown in Fig. 4, it is possible to issue an automatic recovery diagnostic command for three elevators 20 of identification numbers S1001, S1002, and K1001, and for other elevators 20, automatic recovery diagnostics The sending of orders is disabled. Then, the information processing device 310 outputs the automatic recovery diagnostic command as shown in steps S109 and FIG. 2 of FIG. 5 based on the automatic recovery diagnostic command dispatch list 520.

As described above, the information processing device 310 acquires the progress information of the district where the elevator is installed from the tissues A and B after the earthquake, and two of the acquired progress information are less than the magnitude threshold, and the ground of the district When the amplification factor is less than a predetermined threshold, a signal for executing the automatic recovery diagnosis operation is output to the elevator 20.

The output of the information processing device 310 is transmitted from the communication device 320 to the communication network 30 as shown in FIG. 2, and is received by the communication device 210 as shown in step S110 of FIG. 5 and FIG. do. The communication device 210 outputs the received automatic recovery diagnostic command to the control panel 200.

When the automatic recovery diagnostic command is input from the communication device 210, the control panel 200 resets the earthquake sensor 220, as shown in steps S111 and 2 of FIG. 6, and then shows in step S112 of FIG. After confirming the presence or absence of a passenger in the car 22 as shown in the figure, an automatic recovery diagnosis operation is executed as shown in step S113 of FIG. 6. The reset of the earthquake sensor 220 in step S111 in FIG. 6 may be performed after confirming the presence or absence of a passenger in the car 22 in step S112 in FIG. 6 and determining that there are no passengers in the car 22.

The control panel 200, as shown in step S112 of Fig. 6, for example, from the output of the weight sensor of the car 22, the camera in the car 22, the human body sensor in the car 22, etc. ), it is checked whether there is a passenger inside the car 22. When there are passengers in the car 22, the control panel 200 skips the automatic recovery diagnosis operation, proceeds to step S115 in FIG. 6, and outputs a determination result in step S115 in FIG. Here, for the sake of convenience, the passenger is checked, but the door open button is lit even when there is a passenger inside the car 22, and the door can be opened by pressing the door open button.

Then, in step S116 of FIG. 6, the control panel 200 sends the determination result of “not recoverable” to the monitoring center 300 via the communication device 210, and then stops the elevator 20 from driving. As shown in step S117 of Fig. 6, the communication device 320 of the monitoring center 300 receives this determination result and outputs it to the information processing device 310. The information processing device 310 displays the result of the determination on the display 331. Based on this indication, the monitor 334 determines to be "non-recoverable" in the recovery confirmation in step S118 in Fig. 6, and as shown in step S119 in Fig. 6, to the service center 340 to the elevator 20. The dispatch of the technician 350 is instructed.

On the other hand, when the control panel 200 determines that there are no passengers in the car 22 in step S111 of FIG. 6, the control panel 200 proceeds to step S112 of FIG. 6 to perform an automatic recovery diagnosis operation. The diagnostic contents of the automatic recovery diagnosis operation include, for example, checking for a torque abnormality of the hoisting motor (motor) during driving, and checking for abnormal sounds during driving. The automatic recovery diagnosis operation is, for example, the following operation. First, the control panel 200 performs a slow speed running diagnosis in which the car 22 is driven at a slow speed of about 1 m/min, for example. If there is no abnormality in the slow speed running diagnosis, the stop running diagnosis of each floor is stopped by stopping at each floor by a low-speed driving faster than the slow speed. If there is no abnormality in the stop running diagnosis on each floor, the control panel 200 performs constant speed running diagnosis running at the rated speed. When there is no abnormality in the constant speed running diagnosis, the control panel 200 performs door opening and closing diagnosis to open and close the doors 13 and 26 on each floor. If there is no abnormality in the door opening and closing diagnosis, the control panel 200 determines that there is no abnormality and ends the automatic recovery diagnosis operation. Then, the control panel 200 proceeds to step S115 in FIG. 6, and outputs a determination as "recovery success" in step S115 in FIG. 6.

Then, in step S116 of FIG. 6, the control panel 200 sends the determination result of “recovery success” to the monitoring center 300 via the communication device 210, and then resumes normal operation of the elevator 20. . As shown in step S117 of Fig. 6, the communication device 320 of the monitoring center 300 receives this determination result and outputs it to the information processing device 310. The information processing device 310 displays the result of the determination on the display 331. In step S118 of FIG. 6, if the monitor 334 confirms this indication and determines that "recovery is successful", the automatic recovery of the elevator 20 ends.

In addition, when an abnormality occurs during the automatic recovery diagnostic operation, the control panel 200 proceeds to step S120 of FIG. 6, and the control panel 200 stops the automatic recovery diagnostic operation. Then, the process proceeds to step S115 in FIG. 6, and a determination result of "recovery impossible" is output. Then, in step S116 of FIG. 6, the control panel 200 outputs the determination result of “not recoverable” to the monitoring center 300 via the communication device 210, and then stops the elevator 20 from driving. .

As described above, the elevator system 100 of the present embodiment is automatically operated when the elevator 20 is assumed to be hardly damaged even when the earthquake sensor 220 detects high acceleration. Recovery can be enabled. Thereby, the number of the elevators 20 which are stopped when an earthquake occurs can be reduced.

In the above description, it is assumed that a signal for executing the automatic recovery diagnosis operation is output to the elevator 20 when the two magnitudes of the acquired plurality of magnitude information are less than the magnitude threshold and the ground amplification factor of the district is less than a predetermined threshold. Explained. However, the present invention is not limited to this, and when the magnitude threshold is set to a magnitude 4 smaller than the magnitude 5 described above, one of the acquired magnitude information is less than the magnitude threshold, and automatic recovery when the ground amplification factor of the earth is less than a predetermined threshold. The diagnostic command originating list 520 may be generated.

<Other behaviors of the elevator system>

Next, another operation of the elevator system 100 of this embodiment will be described with reference to FIGS. 7 to 10. First, parts identical to those described with reference to FIGS. 1 to 6 are given the same reference numerals, and descriptions thereof are omitted.

In summary, the operation is as follows. First, the information processing device 310 of the monitoring center 300 acquires earthquake information of an area where a plurality of elevators 20 are installed from a plurality of earthquake information providing organizations after an earthquake. Then, the information processing device 310, if the intensity is not observed above the intensity threshold in the area, in the elevator 20 installed in the area, the high acceleration detection signal and the operation stop signal monitoring center (300) ), and generates a signal for executing an automatic recovery diagnosis operation in the elevator 20 in which the ground amplification factor of the installed place is less than a predetermined threshold.

When an earthquake occurs, as shown in step S106 of FIG. 10, the information processing device 310 generates a high acceleration sensing elevator list 500. In addition, when an earthquake occurs, as shown in Fig. 8, the information processing device 310 inputs the magnitude information from the tissues A and B. In step S201 of FIG. 10, the information processing device 310 generates an auto-recovery diagnosis execution availability judgment table 515 for each region as shown in FIG. The information processing apparatus 310 determines whether or not there is a district in which a magnitude exceeding a magnitude of 5, which is a magnitude threshold, is observed in a specific region, for example, Saitama Prefecture, from the progress information of each district of the organization A. As shown in FIG. 8, since the progress exceeding the magnitude of the intensity threshold of 5 is not observed in Saitama Prefecture based on the progress information of the organization A, the Saitama Prefecture of the auto-recovery diagnosis execution by region judgment table 515 Enter "OK" in the earthquake information column of organization A. Likewise, the information processing device 310 "OK" in the field of earthquake information of organization B in Saitama if there is no district with a magnitude exceeding 5 in Saitama Prefecture from the progress information of each district in Organization B Enter Conversely, when a magnitude of 5 is observed even in one district, such as Chiba Prefecture, "NG" is entered in the field of earthquake information of Organization A and Organization B of Chiba Prefecture.

The information processing device 310, as shown in step S202 of FIGS. 7 and 10, based on the auto-recovery diagnostic execution availability judgment table 515 of FIG. 8, the auto-recovery diagnostic execution availability list of each region shown in FIG. 9 (530). The automatic recovery diagnosis execution list 530 for each region is in the automatic recovery diagnosis execution determination table 515 for each region in FIG. 8, in which two earthquake information is “OK”. The automatic recovery diagnosis can be performed on the sub-county and prefecture, and even the state, province, prefecture and prefecture that contain "NG" in the earthquake information cannot be automatically diagnosed. In other words, it is a list of whether or not to perform automatic recovery diagnosis by region, province, province, or prefecture.

Next, the information processing device 310, as shown in step S108 of Figs. 9 and 10, the elevator customer data 450, the automatic recovery diagnosis execution list by region 530, and the high-acceleration detection elevator list 500 ), an automatic recovery diagnostic command originating list 540 is generated. This list, among the elevators 20 installed in the provinces, provinces, prefectures and prefectures that can be executed in the auto-recovery diagnosis execution list 530 for each region, monitors the high-acceleration detection signal and the operation stop signal 300 To the elevator 20 where the ground amplification rate of the installed place is less than a predetermined threshold (1.6 in this embodiment), and executes the automatic recovery diagnosis execution list 530 for each region. An automatic recovery diagnostic command is not sent to elevators 20 installed in disabled provinces, provinces, prefectures and prefectures, and to elevators 20 having a ground amplification factor of more than a predetermined threshold (1.6). .

The information processing device 310 lists up the high-acceleration detection elevator list 500 among the prefectures, for example, Saitama Prefecture, which are determined to be capable of performing auto-recovery diagnosis by referring to the auto-recovery diagnosis execution list 530 for each region. For the two elevators 20 of the identification numbers S1001 and S1002, the elevator customer data 450 is referred to, and the ground amplification factor of the installed place is checked. Then, for the identification numbers S1001 and S1002, since the ground amplification rates are less than 1.5, 1.3, and 1.6, "send" is input to the automatic recovery diagnostic command in the automatic recovery diagnostic command sending list 540. On the contrary, for the prefecture, such as Chiba Prefecture, in the auto-recovery diagnosis execution list 530 for each region, the pre-amplification rate of the installed place, such as the elevator 20 of the identification number C1002, is set for the prefecture that is not automatically recoverable. Even if it is less than the threshold value of (1.6), "NG" is input to the automatic recovery diagnostic command in the automatic recovery diagnostic command sending list 540. In addition, even if it is installed in an area where automatic recovery diagnosis can be executed in the automatic recovery diagnosis execution list 530 for each region, such as identification numbers T1001 and T1002, the ground amplification factor of the installed location is equal to or greater than a predetermined threshold (1.6). In the case, "NG" is input to the automatic recovery diagnostic command in the automatic recovery diagnostic command transmission list 540.

As described above, the information processing apparatus 310 monitors the high-acceleration detection signal and the operation stop signal among the elevators 20 installed in the area, when the progress level higher than the intensity threshold is not observed in a specific area. ), and an automatic recovery diagnosis operation is executed in the elevator 20 in which the ground amplification factor of the installed place is less than a predetermined threshold (1.6).

The output of the information processing device 310 is transmitted from the communication device 320 to the communication network 30 as shown in step S109 in Figs. 7 and 10, and is shown in steps S109 and 7 in Figs. As is received by the communication device 210. The communication device 210 outputs the received automatic recovery diagnostic command to the control panel 200.

First, as in the operation described with reference to FIGS. 1 to 6, when the automatic recovery diagnostic command is input from the communication device 210, the control panel 200 executes the automatic recovery diagnostic operation as shown in step S113 of FIG. 6.

As described above, since this operation collectively determines whether or not to perform an automatic recovery diagnosis operation for each specific region such as province, province, prefecture, etc., not for each elevator 20, multiple elevators (such as Tokyo) 20) can be carried out in a short time in the area where the installation is installed, it is possible to restore a number of elevators 20 that are assumed to have been hardly damaged in the event of an earthquake in a short time.

In the above embodiments, each province, province, prefecture, and prefecture is described as one specific area, but it is not limited to this, for example, Chiyoda-ku in Tokyo, Shinjuku-ku, etc. It is also possible to collectively decide whether or not to perform an automatic recovery diagnosis operation for each region by using the ward as one specific region.

10: building, 11: hoistway, 12, 27: floor, 13, 26: door, 20: elevator, 22: car, 30, 35: communication network, 100: elevator system, 200: control panel, 210: communication device, 220 : Earthquake Detector, 300: Monitoring Center, 310: Information Processing Device, 320: Communication Device, 330: Monitoring Panel, 331: Display, 332: Switch, 333: Telephone, 334: Watcher, 340: Service Center, 350: Technician, 410 , 420: earthquake information, 450: elevator customer data, 500: high-acceleration detection elevator list, 510: auto-recovery diagnostic execution availability judgment table, 515: regional auto-recovery diagnostic execution availability judgment table, 520, 540: auto-recovery diagnostic command sent List, 530: Automatic recovery diagnosis list by region.

Claims (3)

An elevator equipped with an earthquake sensor for sensing the acceleration of the ground surface,
An elevator system comprising a monitoring center for monitoring the elevator in communication with the elevator,
The elevator stops driving when the earthquake sensor detects a high acceleration exceeding a driving stop threshold, and sends a high acceleration detection signal and a driving stop signal to the monitoring center,
The monitoring center has the elevator customer data storing the ground amplification factor of the earth where the elevator is installed, and when the high acceleration detection signal and the operation stop signal are received from the elevator, the elevator is installed. If the magnitude of the earth is less than the intensity threshold, and the ground amplification rate of the earth is less than a predetermined threshold, sending a signal to execute the automatic recovery diagnosis operation to the elevator.
Elevator system characterized by. According to claim 1,
The monitoring center,
After the earthquake, the earthquake information of the district where the elevator is installed is acquired from a plurality of earthquake information providing organizations,
When at least two of the acquired progress information are less than the progress threshold, sending a signal to execute the automatic recovery diagnosis operation to the elevator.
Elevator system characterized by. The method according to claim 1 or 2,
The monitoring center,
After the earthquake, the earthquake information of the regions where the elevators are installed is acquired from a plurality of earthquake information providing organizations.
If no progress is observed above the intensity threshold in the area,
Among the elevators installed in the area, the high acceleration detection signal and the operation stop signal are transmitted to the monitoring center, and an automatic recovery diagnosis operation is performed on the elevator where the ground amplification factor of the district is less than a predetermined threshold. Sending a signal to trigger
Elevator system characterized by.

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