JP2009219033A - Remote supervisory controller and controlling method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a remote supervisory controller and a remote supervisory control method automatically opening an automatic door in a building in an area where an earthquake has occurred when detecting the earthquake by an already installed earthquake sensor. <P>SOLUTION: An earthquake sensor management information storage section 12 stores an area ID identifying an area where the building with the earthquake sensor 20 is present in correspondence with an earthquake sensor ID identifying the earthquake sensor 20. An automatic door management information storage section 14 stores an automatic door ID identifying the automatic door 30 installed in the building in the area identified by the area ID, assigned corresponding to the area ID. An area specifying section 13 specifies the area specified by the area ID assigned corresponding to the earthquake sensor ID identifying the earthquake sensor 20 sensing the occurrence of the earthquake. A control signal outputting section 15 outputs a control signal to open the automatic door 30 identified by the automatic door ID assigned corresponding to the area ID identifying the specified area. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention provides a remote monitoring control for automatically opening an automatic door to prevent a disaster such as being trapped in a building when the automatic door provided in the building is not opened when an earthquake occurs. The present invention relates to an apparatus and a remote monitoring control method.

  2. Description of the Related Art In recent years, in buildings such as buildings, doors (hereinafter referred to as automatic doors) that automatically open and close when people are detected are provided at places where people enter and exit.

  When an earthquake occurs in an area where such a building is located, there is a possibility that an automatic door will not open due to distortion of the building and a disaster may occur such that people who were in the building are trapped in the building There is.

  In order to prevent such a disaster, for example, it is necessary to automatically open the automatic door when an earthquake occurs.

Thus, for example, there is a technique (hereinafter referred to as prior art) that automatically opens an automatic door when an earthquake occurs (see, for example, Patent Document 1). According to this prior art, for example, the automatic door is provided with an earthquake detector that operates when a predetermined seismic intensity is reached, so that the automatic door is automatically opened when the operation of the earthquake detector is detected. Can do.
JP-A-4-161582

  However, in the above-described prior art, it is necessary to install and connect an earthquake detector (earthquake detector) near the automatic door.

  Moreover, although the range (region) where an earthquake occurs is wide, only the automatic door on which the earthquake detector is installed can be automatically opened.

  In addition, since the earthquake is detected based on the operation of only the earthquake detector installed in the vicinity of the automatic door, the earthquake detector detects a shake other than an earthquake, such as a shake caused by a large vehicle. Will also automatically open the automatic door. As described above, it is difficult to determine whether or not the vibration is caused by an earthquake with only one earthquake sensor, and the reliability is low.

  An object of the present invention is to automatically open an automatic door provided in a building located in an area where the earthquake occurs when an earthquake is detected by an earthquake detector already installed in the building. It is an object of the present invention to provide a remote monitoring control device and a remote monitoring control method that are possible.

  According to one aspect of the present invention, a remote monitoring and control device is provided that automatically opens automatic doors provided in a plurality of buildings. This remote monitoring control device is installed in a plurality of buildings, and the building in which the earthquake detector is installed is associated with the earthquake detector identification information for identifying the earthquake detector that detects the occurrence of the earthquake. First storage means for storing earthquake detector management information including area identification information for identifying the area where the site is located, and area identification information included in the earthquake detector management information stored in the first storage means Second storage means for storing in advance automatic door management information including automatic door identification information for identifying an automatic door provided in a building located in a region identified by the region identification information in association with Based on earthquake signal input means for inputting an earthquake signal indicating the occurrence of an earthquake detected by the earthquake sensor from the earthquake sensor, and earthquake sensor management information stored in the first storage means. The region identified by the region identification information associated with the earthquake detector identification information for identifying the earthquake detector that sensed the occurrence of the earthquake indicated by the input earthquake signal is specified as the region where the earthquake occurred A control signal for opening the automatic door identified by the automatic door identification information associated with the area identification information for identifying the specified area, and the second storage means Control signal output means for outputting based on the automatic door management information stored in.

  According to the present invention, when an earthquake is detected by an earthquake detector already installed in a building, the automatic door provided in the building located in the area where the earthquake occurred is automatically opened. Make it possible.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is a block diagram mainly showing a functional configuration of a remote monitoring control apparatus according to an embodiment of the present invention. The remote monitoring control device 10 is provided in a monitoring center or the like that monitors buildings such as a plurality of buildings (hereinafter simply referred to as buildings) located in a specific range (periphery), for example. The remote monitoring control device 10 performs remote control on a door (hereinafter referred to as an automatic door) that is provided in a building to be monitored and automatically opens and closes when a person is detected.

  1 includes an earthquake signal input unit 11, an earthquake detector management information storage unit (first storage unit) 12, an area specifying unit 13, an automatic door management information storage unit (second storage unit). ) 14 and the control signal output unit 15.

  The earthquake signal input unit 11 inputs an earthquake signal indicating the occurrence of an earthquake detected (detected) by, for example, a plurality of earthquake detectors (seismic meters) 20 installed in a plurality of buildings from the earthquake detector 20. . The earthquake sensor 20 senses the occurrence of an earthquake by detecting the acceleration generated by the earthquake, for example. For example, a seismic detector 20 is generally provided in a building provided with an elevator or a boiler. In this embodiment, the seismic detector 20 already installed in the building is used. it can.

  The earthquake detector management information storage unit 12 is associated with earthquake detector identification information (hereinafter referred to as earthquake detector ID) for identifying the earthquake detector 20 installed in the plurality of buildings described above. Earthquake detector management information including area identification information (hereinafter referred to as area ID notation) for identifying the area where the building where the earthquake detector 20 is located is stored.

  Based on the earthquake signal input by the earthquake signal input unit 11 and the earthquake detector management information stored in the earthquake detector management information storage unit 12, the region specifying unit 13 performs an area where an earthquake has occurred (hereinafter referred to as an earthquake occurrence). Identify the region. The area specifying unit 13 is identified by the area ID associated with the earthquake detector ID for identifying the earthquake sensor 20 that has detected the occurrence of the earthquake indicated by the earthquake signal input by the earthquake signal input unit 11. Are identified as earthquake occurrence areas. Further, the area specifying unit 13 receives a predetermined number or more of earthquake detectors 20 among the earthquake detectors 20 identified by the earthquake detector ID associated with the area ID that identifies the same area. When the earthquake signal is input by the earthquake signal input unit 11, the area identified by the area ID is specified as the earthquake occurrence area.

  The automatic door management information storage unit 14 is located in the region indicated by the region ID in association with the region ID included in the earthquake detector management information stored in the earthquake detector management information storage unit 12. Stored is automatic door management information including automatic door identification information (hereinafter referred to as automatic door ID) for identifying the automatic door 30 provided in the building. The automatic door 30 identified by the automatic door ID included in the automatic door management information may be provided in a building other than the building where the earthquake detector 20 is installed.

  The control signal output unit 15 outputs a control signal for opening the automatic door 30 identified by the automatic door ID associated with the region ID for identifying the earthquake occurrence region identified by the region identifying unit 13. Output based on the automatic door management information storage unit 14. That is, the control signal output unit 15 outputs a control signal for opening the automatic door 30 provided in the building located in the earthquake occurrence area to the automatic door 30.

  FIG. 2 shows an example of the data structure of the earthquake detector management information storage unit 12 shown in FIG. The earthquake detector management information storage unit 12 stores earthquake detector management information in advance. As shown in FIG. 2, the earthquake detector management information includes an earthquake detector ID and an area ID. The earthquake sensor ID is identification information for uniquely identifying the earthquake sensor 20 installed in a plurality of buildings, and the area ID is for uniquely identifying the area where the earthquake sensor 20 is installed. Identification information.

  In the example shown in FIG. 2, earthquake detector management information 121 to 123 is stored in the earthquake detector management information storage unit 12. The earthquake detector management information 121 includes an earthquake detector ID “1” and an area ID “1”. The earthquake detector management information 122 includes an earthquake detector ID “2” and an area ID “1”. The earthquake detector management information 123 includes an earthquake detector ID “3” and an area ID “2”. According to the example shown in FIG. 2, the earthquake sensor 20 identified by the earthquake sensor ID “1” and the earthquake sensor ID “2” is the area identified by the area ID “1” (that is, the same area). It is shown that it is installed. Further, it is shown that the earthquake sensor 20 identified by the earthquake sensor ID “3” is installed in the area identified by the area ID “2”.

  FIG. 3 shows an example of the data structure of the automatic door management information storage unit 14 shown in FIG. The automatic door management information storage unit 14 stores automatic door management information in advance. As shown in FIG. 3, the automatic door management information includes a region ID and an automatic door ID. The area ID is an area ID included in the above-described earthquake detector management information, and the automatic door ID is an identification for uniquely identifying the automatic door 30 provided in the building located in the area identified by the area ID. Information.

  In the example shown in FIG. 3, automatic door management information 141 to 143 is stored in the automatic door management information storage unit 14. The automatic door management information 141 includes a region ID “1” and an automatic door ID “1”. The automatic door management information 142 includes a region ID “1” and an automatic door ID “2”. Further, the automatic door management information 143 includes a region ID “2” and an automatic door ID “3”. According to the example shown in FIG. 3, it is shown that the automatic door 30 identified by the automatic door ID “1” and the automatic door “2” is provided in the building located in the area identified by the area ID “1”. It is. Further, it is shown that the automatic door 30 identified by the automatic door ID “3” is provided in the building located in the area identified by the area ID “2”.

  Next, a processing procedure of the remote monitoring control device 10 shown in FIG. 1 will be described with reference to the flowchart of FIG.

  First, the earthquake signal input unit 11 inputs an earthquake signal indicating the occurrence of an earthquake detected by a plurality of earthquake detectors 20 installed in a plurality of buildings from the earthquake detector 20 (step S1). The earthquake sensor 20 is activated when, for example, a vibration caused by an earthquake occurs. The earthquake signal input unit 11 inputs an earthquake signal when the earthquake detector 20 is activated. In addition, if the earthquake signal input by the earthquake signal input unit 11 senses a shake due to an earthquake, a plurality of earthquake detections installed in a building located in the area where the earthquake occurred (the area where the earthquake occurred) An earthquake signal is input from each of the containers 20.

  Next, the area specifying unit 13 specifies the earthquake occurrence area based on the earthquake signal input by the earthquake signal input unit 11 and the earthquake detector management information stored in the earthquake detector management information storage unit 12 ( Step S2). The area specifying unit 13 specifies, for each of the earthquake signals input by the earthquake signal input unit 11, an area where the earthquake detector 20 that detects the occurrence of the earthquake indicated by the earthquake signal is installed. At this time, if the number of earthquake detectors 20 that have detected the occurrence of an earthquake in the same area is greater than a predetermined number, the area is identified as an earthquake occurrence area.

  Specifically, first, the area specifying unit 13 is associated with an earthquake detector ID that identifies the earthquake detector 20 that has detected the occurrence of the earthquake indicated by the earthquake signal input by the earthquake signal input unit 11. The area ID is specified based on the earthquake detector management information stored in the earthquake detector management information storage unit 12. This process is performed for all the seismic signals input by the seismic signal input unit 11, and when the same area ID of a predetermined number or more is specified, it is predetermined in the area identified by the area ID. It is determined that the occurrence of an earthquake has been detected by the number of earthquake detectors 20 or more, and the area is identified as an earthquake occurrence area.

  The control signal output unit 15 includes the automatic door ID stored in the automatic door management information storage unit 14 and the automatic door ID associated with the region ID for identifying the earthquake occurrence region specified by the region specifying unit 13. Specify based on management information. The specified automatic door ID is identification information for uniquely identifying the automatic door 30 provided in the building located in the earthquake occurrence area. The control signal output unit 15 outputs a control signal for opening the automatic door 30 identified by the specified automatic door ID to the automatic door 30. Thereby, the automatic door 30 is opened according to the control signal output by the control signal output unit 15.

  When the number of earthquake detectors 20 that have detected an occurrence of an earthquake in the same area in step S2 described above is smaller than a predetermined number, for example, by passing a large vehicle in the vicinity of the earthquake detector 20 The control signal is not output as if the earthquake detector 20 senses a shake that is not caused by an earthquake such as a shake that has occurred (that is, no earthquake has occurred in the area).

  As described above, in this embodiment, when the occurrence of an earthquake is detected by the earthquake detector 20, an earthquake signal indicating the occurrence of the earthquake is input and stored in the earthquake signal and earthquake detector management information storage unit 12. The earthquake occurrence area is identified based on the seismic detector management information. In the present embodiment, the automatic door stored in the automatic door management information storage unit 14 includes a control signal for opening the automatic door 30 provided in a building such as a building located in the specified earthquake occurrence area. By outputting to the automatic door 30 based on the management information, the automatic door 30 can be automatically opened. Thus, for example, in a building or the like, it is possible to avoid a situation (disaster) in which a person in the building is trapped due to the automatic door not being opened due to distortion of the building or the like when an earthquake occurs.

  Further, in this embodiment, since the seismic detector 20 already installed in an elevator or the like in the building can be used, for example, the seismic detector 20 is newly added in the vicinity of the automatic door 30 to be monitored. The automatic door can be opened automatically without being installed. For this reason, in this embodiment, an effect is realizable economically.

  In the present embodiment, the automatic door 30 is automatically opened when the occurrence of an earthquake is detected by a plurality of earthquake detectors 20 in a specific area, so only one earthquake detector 20 is provided. The reliability can be improved as compared with the configuration for determining the occurrence of an earthquake based on the above.

  In the present embodiment, for example, the earthquake detector 20 is installed by monitoring and controlling the automatic door 30 provided in a building located in an area where the occurrence of an earthquake is detected by the plurality of earthquake detectors 20. Even automatic doors in buildings that are not open can be opened automatically in the event of an earthquake.

  It is to be noted that an earthquake is detected at an earlier stage by using an earthquake detector capable of detecting an initial tremor called a P wave of an earthquake generally installed in an elevator or the like as the earthquake detector 20, and the automatic door 30 Can be opened.

  Further, the present invention is not limited to the above-described embodiments as they are, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. Moreover, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment.

The block diagram which mainly shows the function structure of the remote monitoring control apparatus which concerns on embodiment of this invention. The figure which shows an example of the data structure of the earthquake detector management information storage part 12 shown in FIG. The figure which shows an example of the data structure of the automatic door management information storage part 14 shown in FIG. The flowchart which shows the process sequence of the remote monitoring control apparatus 10 shown in FIG.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 ... Remote monitoring control apparatus, 11 ... Earthquake signal input part, 12 ... Earthquake detector management information storage part (1st storage means), 13 ... Area identification part, 14 ... Automatic door management information storage part (2nd storage) Means), 15 ... control signal output unit, 20 ... earthquake detector, 30 ... automatic door.

Claims (4)

In the remote monitoring and control device that automatically opens the automatic doors provided in multiple buildings,
To identify the area where the building where the seismic detector is installed is associated with the seismic detector identification information that is installed in multiple buildings and identifies the seismic detector that detects the occurrence of an earthquake First storage means for storing earthquake detector management information including area identification information of
For identifying an automatic door provided in a building located in a region identified by the region identification information in association with the region identification information included in the earthquake detector management information stored in the first storage unit Second storage means for storing automatic door management information including automatic door identification information in advance;
An earthquake signal input means for inputting an earthquake signal indicating the occurrence of an earthquake detected by the earthquake detector from the earthquake detector;
Corresponding to earthquake detector identification information for identifying the earthquake detector that has detected the occurrence of the earthquake indicated by the input earthquake signal based on the earthquake detector management information stored in the first storage means Area identification means for identifying the area identified by the attached area identification information as the area where the earthquake occurred,
The control signal for opening the automatic door identified by the automatic door identification information associated with the area identification information for identifying the specified area is automatically stored in the second storage means. And a control signal output means for outputting based on the door management information.   The area specifying means is identified by earthquake detector identification information associated with area identification information for identifying the same area included in the earthquake detector management information stored in the first storage means. The area where the earthquake occurred is identified by the area identification information when earthquake signals from a predetermined number of earthquake sensors are input by the earthquake signal input means. The remote monitoring control apparatus according to claim 1, characterized by:   2. The remote according to claim 1, wherein the earthquake signal input means inputs an earthquake signal indicating an occurrence of an earthquake detected by an earthquake detector installed in an elevator provided in the plurality of buildings. Supervisory control device. To identify the area where the building where the seismic detector is located is located in association with the seismic detector identification information that is installed in multiple buildings and identifies the seismic detector that detects the occurrence of an earthquake A first storage means for storing earthquake detector management information including the area identification information in advance, and the area associated with the area identification information included in the earthquake detector management information stored in the first storage means Executed by a remote monitoring and control device comprising second storage means for storing in advance automatic door management information including automatic door identification information for identifying automatic doors provided in a building located in the area indicated by the identification information A remote monitoring control method, comprising:
Inputting an earthquake signal indicating the occurrence of an earthquake detected by the earthquake sensor from the earthquake sensor;
Corresponding to earthquake detector identification information for identifying the earthquake detector that has detected the occurrence of the earthquake indicated by the input earthquake signal based on the earthquake detector management information stored in the first storage means Identifying the area identified by the attached area identification information as the area where the earthquake occurred,
The control signal for opening the automatic door identified by the automatic door identification information associated with the area identification information for identifying the specified area is automatically stored in the second storage means. A remote monitoring control method comprising: outputting based on door management information.

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