JP2015131728A - Elevator widespread disaster restoration support system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an elevator widespread disaster restoration support system capable of accurately predicting elevator stop due to an earthquake.SOLUTION: The present invention comprises: an observation-site locating unit 12 comparing observation site information acquired from an earthquake and seismic intensity information distribution service 1 with an elevator installation location, and locating a closest observation site to the elevator; a seismic-intensity identifying unit 13 identifying a seismic intensity of the closest observation site to the elevator located by the observation-site locating unit 12 as a seismic intensity of the elevator while referring to seismic information acquired from the earthquake and seismic information distribution service 1; an earthquake-caused-elevator-stop information recording unit 17 recording earthquake-caused elevator stop information; and a stopped elevator identifying unit 14 identifying whether the elevator is to be stopped by the earthquake on the basis of the earthquake-caused-elevator-stop information recorded in the earthquake-caused-elevator-stop information recording unit 17 and the seismic intensity of the elevator identified by the seismic intensity identifying unit 13.

Description

  The present invention relates to a wide area disaster recovery support system for an elevator that supports the recovery of an elevator when an earthquake occurs.

  Conventionally, an earthquake sensor has been installed in the elevator to prevent the passenger from being trapped in the elevator car due to an earthquake and damage to the elevator equipment. At the same time, a control method for raising and lowering the elevator car to the nearest floor and stopping the elevator is incorporated. When the elevator stops due to an earthquake, a maintenance worker who performs maintenance management of the elevator patrols the site and confirms the operation of the stopped elevator to proceed with the restoration work of the elevator.

  In such elevator maintenance management in the event of an earthquake, a remote monitoring system is applied to grasp the elevator that has stopped due to the earthquake. This type of remote monitoring system includes, for example, a monitoring device that detects the operation of the elevator, and a monitoring center that is connected to the monitoring device through a public network and remotely monitors the elevator, and the seismic detector operates. Then, the monitoring device notifies the monitoring center that the elevator has stopped, or the monitoring center reads the operation state of the elevator.

  However, since the area affected by the earthquake is wide, it takes time to grasp the total number of elevator stops. In addition, in the case where it is not possible to confirm the site remotely from the monitoring center due to congestion in the public network connecting the monitoring device and the monitoring center, maintenance personnel must contact all elevators in the affected area. Although it is necessary to make a patrol, it has become a problem for an elevator that is operating normally without stopping even if an earthquake occurs, resulting in a wasteful patrol. In particular, even if the installation location of the elevator is within the same disaster-stricken area, the actual status of whether the elevator is stopped due to differences in the characteristics of the ground and buildings varies from elevator to elevator. Although there are elevators that stop, the number of elevators that stop due to an earthquake of this magnitude is limited, and there has been a problem that the maintenance staff's useless patrols increase in elevator maintenance management.

  Therefore, we collect earthquake data, earthquake damage data, and elevator structure data from earthquakes that occurred in advance, and calculate the rate of damage that occurs in the elevators when an earthquake occurs from these data to reduce elevator damage due to earthquakes. An earthquake damage estimation system that can perform a quick restoration activity by predicting has been proposed as one of the prior arts (see, for example, Patent Document 1). Therefore, when maintenance personnel perform maintenance management of an elevator in the event of an earthquake, it is possible to predict the stoppage of the elevator due to an earthquake using a conventional earthquake damage estimation system, thereby preventing the maintenance personnel from wasting around the elevator maintenance management. It can be avoided.

Japanese Patent Application Laid-Open No. 11-049448

  Here, in the conventional earthquake damage estimation system disclosed in Patent Document 1, in order to predict the stop of an elevator due to an earthquake, damage data associated with information such as past epicenter position and magnitude as earthquake data is used. As a minimum, an elevator stop record is required. Therefore, even if an earthquake of the same magnitude as that of a past earthquake occurs, if the location of the earthquake is not the same as the case of the past earthquake data collected, the elevator will stop correctly due to the earthquake. The problem is that it cannot be predicted and the maintenance and management of the elevator in the event of an earthquake cannot be performed efficiently.

  The present invention has been made based on the actual situation of the prior art, and an object of the present invention is to provide a wide area disaster recovery support system for an elevator that can accurately predict the stop of the elevator due to an earthquake.

  In order to achieve the above object, the elevator wide area disaster recovery support system of the present invention is connected to a seismic intensity information distribution service that distributes position information and seismic intensity information of a plurality of observation sites where the seismic intensity of the earthquake is measured, Based on the position information and seismic intensity information acquired from this seismic intensity information distribution service, in the elevator wide area disaster recovery support system that supports the recovery of elevators stopped by an earthquake, the seismic intensity of the elevator installation location due to past earthquakes And a recording unit in which stop information indicating whether or not the elevator is stopped is compared with the position information acquired from the seismic intensity information distribution service and the installation location of the elevator, The observation site identification unit that identifies the nearest observation site of the elevator from the inside, and this observation site identification unit A seismic intensity identifying unit that identifies the seismic intensity of the observation site closest to the elevator identified as the seismic intensity of the location where the elevator is installed with reference to the seismic intensity information, and the stop information recorded by the recording unit, and A stop elevator specifying unit that specifies whether or not the elevator has been stopped by an earthquake based on the seismic intensity of the installation location of the elevator specified by the seismic intensity specifying unit.

  According to the elevator wide area disaster recovery support system of the present invention, it is possible to accurately predict the stop of the elevator due to an earthquake. Problems, configurations, and effects other than those described above will become apparent from the following description of embodiments.

It is a figure which shows the structure of one Embodiment of the wide area disaster recovery assistance system of the elevator which concerns on this invention. It is a figure which shows the structure of the observation place information delivered from the seismic intensity information delivery service which concerns on this embodiment. It is a figure which shows the structure of the seismic intensity information delivered from the seismic intensity information delivery service which concerns on this embodiment. It is a figure which shows the structure of the elevator installation information before the update of the elevator installation information recording part which concerns on this embodiment. It is a figure which shows the structure of the elevator installation information after the update of the elevator installation information recording part which concerns on this embodiment. It is a figure which shows the structure of the elevator seismic intensity information created by the seismic intensity specific | specification part which concerns on this embodiment. It is a figure which shows the structure of the elevator earthquake stop information before the update of the elevator earthquake stop information recording part which concerns on this embodiment. It is a figure which shows the structure of the elevator earthquake stop prediction information produced by the stop elevator specific | specification part which concerns on this embodiment. It is a figure which shows the structure of the elevator earthquake stop information after the update of the elevator earthquake stop information recording part which concerns on this embodiment. It is a flowchart explaining operation | movement of the seismic intensity information receiving part of the seismic intensity information delivery service and wide area disaster recovery support system which concerns on this embodiment, an observation site specific part, a seismic intensity specific part, a stop elevator specific part, and a stop elevator information output part. is there. It is a flowchart explaining operation | movement of the monitoring information communication part of the wide area disaster recovery assistance system which concerns on this embodiment.

  EMBODIMENT OF THE INVENTION Hereinafter, the form for implementing the wide area disaster recovery assistance system of the elevator which concerns on this invention is demonstrated based on figures.

  As shown in FIG. 1, the elevator wide area disaster recovery support system 10 according to the present embodiment distributes position information and seismic intensity information of a plurality of observation sites where seismometers are installed in each area and the seismic intensity of the earthquake is measured. The seismic intensity information distribution service 1 is connected via a communication network 2. The seismic intensity information distribution service 1 is composed of a public organization such as the Japan Meteorological Agency that distributes information on earthquakes.

  The position information of each observation site distributed from the seismic intensity information distribution service 1 includes, for example, an observation site column in which the name of the observation site is entered and a latitude in which the latitude / longitude of the observation site is entered as shown in FIG. / Longitudinal field information, which is periodically distributed regardless of the occurrence of an earthquake. Further, the seismic intensity information distributed from the seismic intensity information distribution service 1 is measured by the observation site column in which the name of the observation site is entered and the seismometer of the observation site, for example, as shown in FIG. This is information composed of a seismic intensity column in which the seismic intensity is entered, and this seismic intensity information is immediately distributed when an earthquake occurs.

  The wide area disaster recovery support system 10 according to the present embodiment supports the recovery of an elevator (not shown) stopped by an earthquake based on the observation site information and the seismic intensity information acquired from the seismic intensity information distribution service 1. It is. Hereinafter, the configuration of the wide-area disaster recovery support system 10 according to the present embodiment will be described in detail with reference to FIGS.

  The wide-area disaster recovery support system 10 has information on the location of the elevator serving as an object to support recovery and the seismic intensity information receiving unit 11 that receives the observation site information and seismic intensity information distributed from the seismic intensity information distribution service 1 in advance. Observation that identifies the nearest observation location of the elevator from a plurality of observation locations by comparing the recorded observation location information acquired from the elevator installation information recording portion 16 and the seismic intensity information receiving portion 11 with the installation location of the elevator A seismic intensity specifying unit 13 that refers to the seismic intensity information acquired from the ground specifying unit 12 and the seismic intensity information receiving unit 11 and specifies the seismic intensity of the nearest observation site of the elevator specified by the observation site specifying unit 12 as the seismic intensity of the elevator; Is included.

  The elevator installation location information recorded in the elevator installation information recording unit 16 is, for example, as shown in FIG. 4, as shown in FIG. 4, the elevator management number field in which the elevator maintenance company has a management contract is entered. This is elevator installation information composed of a latitude / longitude column in which the latitude / longitude of the installation location is entered and a nearest observation location column in which the name of the observation location closest to the elevator installation location is entered. In the elevator installation information shown in FIG. 4, the field of the nearest observation site of the newly contracted elevator (for example, management number 111111) is blank.

  The observation site specifying unit 12 is the latitude of the observation site closest to the latitude / longitude of the newly contracted elevator (management number 111111) among the elevator latitude / longitude of the elevator installation information recorded in the elevator installation information recording unit 16. / Longitude is specified from the latitude / longitude of observation site information. Then, the observation location specifying unit 12 sets an observation location (AAA) having the specified latitude / longitude (for example, eeee, eeee) in the column of the nearest observation location that is blank in the elevator installation information, and the configuration shown in FIG. As shown, the elevator installation information for which all the observation sites have been completed is recorded in the elevator installation information recording unit 16. Thereby, the elevator installation information in the elevator installation information recording unit 16 is updated to the latest one.

  The seismic intensity identification unit 13 identifies the seismic intensity of the nearest observation site of the elevator of the latest elevator installation information recorded in the elevator installation information recording unit 16 from the seismic intensity of the observation site of the seismic intensity information, and sets the identified seismic intensity as the seismic intensity of the elevator As shown in FIG. 6, the control number field where the elevator management number is entered, the field of the nearest observation site where the name of the observation site closest to the elevator installation location is entered, and the seismic intensity of the elevator Elevator seismic intensity information composed of the entered seismic intensity columns is created.

  Further, the wide area disaster recovery support system 10 includes an elevator earthquake stop information recording unit 17 as a recording unit in which stop information indicating whether or not the elevator has stopped is recorded with respect to the intensity of the elevator caused by a past earthquake, and the elevator earthquake stop Based on the stop information recorded by the information recording unit 17 and the seismic intensity of the elevator specified by the seismic intensity specifying unit 13, a stop elevator specifying unit 14 for specifying whether the elevator stops due to an earthquake, and the stop elevator specifying unit 14 includes a stop elevator information output unit 15 that outputs information related to the elevator specified by 14 to the outside, and a monitoring information communication unit 18 that receives monitoring information described later from the outside and communicates with the elevator earthquake stop information recording unit 17. Yes.

  The stop information recorded in the elevator earthquake stop information recording unit 17 includes, for example, as shown in FIG. 7, a management number field where the elevator management number is written, a seismic intensity field where the elevator seismic intensity is written, This is elevator earthquake stop information composed of a column indicating whether or not the vehicle has stopped, and a column of minimum stop seismic intensity in which the minimum seismic intensity of the elevator when the elevator stops due to an earthquake is entered. In the elevator earthquake stop information shown in FIG. 7, the stop / non-stop column of the newly contracted elevator (management number 111111) and the minimum stop seismic intensity column are blank.

  The stop elevator specifying unit 14 writes the seismic intensity of the elevator of the elevator seismic intensity information in the seismic intensity column of the elevator earthquake stop information recorded in the elevator earthquake stop information recording unit 17 in correspondence with the management number. Moreover, the stop elevator specific | specification part 14 determines that the elevator has stopped when the seismic intensity of the elevator of elevator earthquake stop information and the minimum stop seismic intensity are equal to or more than the minimum stop seismic intensity. If the seismic intensity is less than the minimum stop seismic intensity, it is determined that the elevator has not stopped. In addition, in the elevator earthquake stop information shown in FIG. 7, it is determined that the elevator is stopped for an elevator (management number 111111) in which the column for whether or not to stop and the column for minimum stop seismic intensity are blank.

  And the stop elevator specific | specification part 14 is shown in the elevator management number column, the seismic intensity column, and the elevator seismic intensity column determined as being out of the elevator earthquake stop information from the determination result of the elevator stop due to the earthquake as shown in FIG. Elevator earthquake stop prediction information consisting only of the column indicating whether or not there is a stop is created, and this elevator earthquake stop prediction information is transmitted to the stop elevator information output unit 15. The stop elevator information output unit 15 transmits the elevator earthquake stop prediction information received from the stop elevator specifying unit 14 to a portable terminal (not shown) carried by a maintenance worker who performs maintenance management of the elevator.

  Here, the maintenance staff dispatches to the site where the elevator having the management number indicated in the elevator earthquake stop prediction information received by the mobile terminal is installed, and checks whether the elevator is stopped due to the earthquake. Then, the maintenance staff creates the monitoring information described above, which is composed of a management number column in which the elevator management number is entered, and a stop presence / absence column in which whether or not the elevator has stopped due to an earthquake is written. To transmit the monitoring information to the monitoring information communication unit 18.

  In addition, when the elevator with the control number indicated in the elevator earthquake stop prediction information from the stop elevator information output unit 15 to the maintenance staff is notified, for example, the elevator at the office of the sales office that is responsible for the maintenance management of the elevator It may be performed from the sales office by outputting the prediction information or printing the elevator earthquake stop prediction information. Further, the monitoring information may be transmitted from the maintenance staff to the monitoring information communication unit 18 by, for example, oral communication by telephone. In this case, the operator of the sales office that has received oral communication by telephone operates a console (not shown) of the monitoring information communication unit 18 to input monitoring information to the monitoring information communication unit 18.

  The monitoring information communication unit 18 refers to the monitoring information received from the maintenance worker's mobile terminal, and as shown in FIG. 9, in the column of whether or not the elevator earthquake stop information is recorded in the elevator earthquake stop information recording unit 17. Among them, the column indicating whether or not the elevator has stopped is overwritten with “stop” and the seismic intensity of the elevator is overwritten in the minimum stop seismic intensity column. On the other hand, the monitoring information communication unit 18 overwrites the column indicating whether or not the elevator that has not stopped in the column indicating whether or not the elevator is stopped in the column indicating whether or not the elevator has stopped with “not stopped” and also displays the minimum stop seismic intensity column. In addition, the value obtained by adding 1 to the seismic intensity of the elevator is overwritten.

  Next, the operation of the seismic intensity information distribution service 1, the seismic intensity information receiving unit 11, the observation site specifying unit 12, the seismic intensity specifying unit 13, the stop elevator specifying unit 14, and the stop elevator information output unit 15 of the wide area disaster recovery support system 10 Will be described in detail based on the flowchart of FIG. In FIG. 10, the operation procedure of the seismic intensity information distribution service 1 is described by adding S to the procedure number, and the seismic intensity information receiving unit 11, observation site specifying unit 12, seismic intensity of the wide area disaster recovery support system 10. The processing procedure of the operations of the specifying unit 13, the stopped elevator specifying unit 14, and the stopped elevator information output unit 15 is described with T added to the procedure number.

  First, the seismic intensity information distribution service 1 confirms whether or not the observation site information is open to the public (S1). At this time, if the seismic intensity information distribution service 1 confirms that it is not the time to disclose the observation site information (S1 / NO), the processing procedure of S3 described later is performed. On the other hand, if it is confirmed in the processing procedure of S1 that the seismic intensity information distribution service 1 is the release time of the observation site information (S1 / YES), the seismic intensity information distribution service 1 sends the observation site information to the wide area disaster recovery support system. 10 (S2) and confirms whether an earthquake has occurred (S3).

  At this time, when the earthquake information distribution service 1 confirms that no earthquake has occurred (S3 / NO), the processing procedure from S1 described above is repeated. On the other hand, when the seismic intensity information distribution service 1 confirms that an earthquake has occurred in the processing procedure of S3 (S3 / YES), the seismic intensity information of the earthquake is transmitted to the wide area disaster recovery support system 10 (S4). The processing procedure from is repeated.

  On the other hand, the seismic intensity information receiving unit 11 of the wide area disaster recovery support system 10 confirms whether the information received from the seismic intensity information distribution service 1 is seismic intensity information (T1). At this time, when the seismic intensity information receiving unit 11 confirms that the information received from the seismic intensity information distribution service 1 is not seismic intensity information (T1 / NO), the processing procedure of T1 is repeated. On the other hand, in the processing procedure of T1, when the seismic intensity information receiving unit 11 confirms that the information received from the seismic intensity information distribution service 1 is seismic intensity information (T1 / YES), the seismic intensity information receiving unit 11 receives it from the seismic intensity information distribution service 1 It is confirmed whether the observation location information is included in the information (T2).

  At this time, if the seismic intensity information receiving unit 11 confirms that the observation site information is not included in the information received from the seismic intensity information distribution service 1 (T2 / NO), the processing procedure of T6 described later is performed. On the other hand, in the processing procedure of T2, when the seismic intensity information receiving unit 11 confirms that the information received from the seismic intensity information distribution service 1 includes observation site information (T2 / YES), the wide area disaster recovery support system Ten observation site specifying units 12 read the elevator installation information of the elevator installation information recording unit 16 (T3). And the observation site specific | specification part 12 confirms whether there is a newly contracted elevator in the read elevator installation information (T4).

  At this time, if the observation site specifying unit 12 confirms that there is no newly contracted elevator (T4 / NO), the processing procedure from T1 is repeated. On the other hand, in the processing procedure of T4, when the observation site specifying unit 12 confirms that there is a newly contracted elevator (T4 / YES), out of the latitude / longitude of the elevator in the elevator installation information read out in the processing procedure of T3 The latitude / longitude of the observation location closest to the latitude / longitude of the newly contracted elevator is specified from the latitude / longitude of the observation location in the observation location information. Then, the observation site specifying unit 12 sets the observation site having the specified latitude / longitude in the nearest observation site column that is blank in the elevator installation information, and fills in the elevator by the elevator installation information recording unit 16 The installation information is updated (T5), and the processing procedure from T1 is repeated.

  Next, in the processing procedure of T6, the seismic intensity specifying unit 13 of the wide area disaster recovery support system 10 reads the elevator installation information of the elevator installation information recording unit 16 (T6). Then, the seismic intensity identification unit 13 identifies the seismic intensity of the nearest observation site of the elevator in the read elevator installation information from the seismic intensity of the observation area of the seismic intensity information, and sets the identified seismic intensity as the seismic intensity of the elevator, thereby obtaining the elevator seismic intensity information. Create (T7).

  Next, the stop elevator specifying unit 14 of the wide area disaster recovery support system 10 reads the elevator earthquake stop information of the elevator earthquake stop information recording unit 17 (T8). Then, the stop elevator specific | specification part 14 fills in the seismic intensity of the elevator of elevator seismic intensity information corresponding to a management number in the column of the seismic intensity of the read elevator earthquake stop information.

  Next, the stop elevator identification unit 14 compares the entered seismic intensity of the elevator with the minimum stop seismic intensity of the elevator earthquake stop information, determines the elevator stop due to the earthquake, and creates elevator earthquake stop prediction information from the determination result (T9). Thereafter, the stop elevator identification unit 14 transmits the created elevator earthquake stop prediction information to the stop elevator information output unit 15. Then, the stop elevator information output unit 15 of the wide area disaster recovery support system 10 transmits the elevator earthquake stop prediction information received from the stop elevator specifying unit 14 to the maintenance worker's mobile terminal (T10), and the processing procedure from T1 is repeated. It is.

  Next, the operation of the monitoring information communication unit 18 of the wide area disaster recovery support system 10 will be described in detail based on the flowchart of FIG. In FIG. 11, the processing procedure of the operation of the monitoring information communication unit 18 is described with U added to the procedure number.

  First, the monitoring information communication unit 18 confirms whether or not monitoring information has been received from the portable terminal of the maintenance staff (U1). At this time, when the monitoring information communication unit 18 confirms that the monitoring information is not received from the maintenance person's portable terminal (U1 / NO), the processing procedure of U1 is repeated. In the processing procedure of U1, when the monitoring information communication unit 18 confirms that the monitoring information has been received from the portable terminal of the maintenance staff (U1 / YES), it reads the elevator earthquake stop information of the elevator earthquake stop information recording unit 17 (U2 ). And the monitoring information communication part 18 confirms whether the elevator of the management number shown by monitoring information stopped by the earthquake by referring the presence or absence of the stop of the elevator of monitoring information (U3).

  At this time, when the monitoring information communication unit 18 confirms that the elevator has stopped due to the earthquake (U3 / YES), the elevator that has stopped in the column of whether or not to stop the elevator earthquake stop information read in the processing procedure of U2 "Stop" is entered and overwritten in the column of whether or not there is a stop, and the seismic intensity of the elevator is overwritten in the minimum stop seismic intensity column (U4). On the other hand, when the monitoring information communication unit 18 confirms that the elevator has not stopped due to the earthquake in the processing procedure of U3 (U3 / NO), the column of whether or not the elevator earthquake stop information is read out in the processing procedure of U2 Of the elevators that have not stopped, enter “not stopped” in the column indicating whether or not the elevator has stopped, and overwrite it, and in the minimum stop seismic intensity column, enter the value obtained by adding 1 to the elevator seismic intensity and overwrite it. (U5).

  And the monitoring information communication part 18 confirms whether overwrite of elevator earthquake stop information was completed with respect to the elevator of all the management numbers shown by the monitoring information received in U1 (U6). At this time, when the monitoring information communication unit 18 confirms that the overwrite of the elevator earthquake stop information is not completed (U6 / NO), the elevator earthquake stop information is still overwritten among the elevators indicated in the monitoring information. The process procedure from U3 is performed with respect to the elevator which is not.

  On the other hand, when the monitoring information communication unit 18 confirms that the overwrite of the elevator earthquake stop information has been completed in the processing procedure of U6 (U6 / YES), the overwritten elevator earthquake stop information is recorded in the elevator earthquake stop information recording unit 17. By doing so, the elevator earthquake stop information of the elevator earthquake stop information recording unit 17 is updated, and the processing procedure from U1 is repeated.

  According to the present embodiment configured as described above, the wide area disaster recovery support system 10 makes the observation site information and seismic intensity information distributed from the seismic intensity information distribution service 1 effective by the observation site specifying unit 12 and the seismic intensity specifying unit 13. By utilizing this, the elevator earthquake stop prediction information specifying the elevator to be stopped by the earthquake can be created by the stop elevator specifying unit 14 without using information on the magnitude and location of the earthquake, so this elevator earthquake stop prediction information Therefore, it is possible to accurately predict the elevator stop due to the earthquake. As a result, maintenance personnel who perform elevator maintenance management in the event of an earthquake acquire elevator earthquake stop prediction information from the mobile terminal, and by preferentially patrol from the elevator with the management number indicated in the elevator earthquake stop prediction information, Can be efficiently managed.

  In particular, when a remote monitoring system is used in elevator maintenance management in the event of an earthquake to grasp elevators that have stopped due to an earthquake, the public line network may become congested due to a large-scale earthquake. Even if the stop notification from the elevator side in the monitoring system is interrupted, the stop elevator specifying unit 14 refers to the elevator earthquake stop information in the elevator earthquake stop information recording unit 17 in which the stop results with respect to the seismic intensity of the elevator due to past earthquakes are shown. can do. Therefore, since the stop elevator specifying unit 14 can quickly create elevator earthquake stop prediction information from the elevator earthquake stop information regardless of congestion of the public network due to the earthquake, it is excellent for maintenance management of the elevator when an earthquake occurs. Reliable.

  In addition, this embodiment mentioned above was described in detail in order to demonstrate this invention easily, and is not necessarily limited to what is provided with all the demonstrated structures. Further, a part of the configuration of an embodiment can be replaced with the configuration of another embodiment, and the configuration of another embodiment can be added to the configuration of an embodiment.

DESCRIPTION OF SYMBOLS 1 Earthquake seismic intensity information delivery service 2 Communication network 10 Wide area disaster recovery support system 11 Earthquake seismic intensity information receiving part 12 Observation site specific part 13 Seismic intensity specific part 14 Stop elevator specific part 15 Stop elevator information output part 16 Elevator installation information recording part 17 Elevator earthquake Stop information recording part (recording part)
18 Monitoring Information Communication Department

Claims (1)

Based on the location information and seismic intensity information acquired from this seismic intensity information distribution service, connected to the seismic intensity information distribution service that distributes the location information and seismic intensity information of multiple observation sites where the seismic intensity is measured In the elevator wide area disaster recovery support system that supports the recovery of the elevator stopped by
Comparing the location information acquired from the seismic intensity information distribution service with the location of the elevator, an observation location specifying unit for specifying the nearest observation location of the elevator from the plurality of observation locations;
A seismic intensity identifying unit that identifies the seismic intensity of the observation site nearest to the elevator identified by the observation site identifying unit as the seismic intensity of the elevator with reference to the seismic intensity information;
A recording unit in which stop information indicating whether or not the elevator is stopped is recorded with respect to a seismic intensity of the elevator due to a past earthquake,
A stop elevator specifying unit that specifies whether the elevator stops due to an earthquake based on the stop information recorded by the recording unit and the seismic intensity of the elevator specified by the seismic intensity specifying unit. Elevator wide area disaster recovery support system.