JP2006309389A - Communication terminal, earthquake information acquiring method and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a device capable of detecting an earthquake and quickly reporting required information. <P>SOLUTION: When detecting the earthquake with an earthquake detection means 306 of a gas meter 1, this device transmits earthquake detection information to a communication terminal 2 by radio. When determining reception of the earthquake detection information with a report information determination means 302 of the communication terminal 2, the device acquires required earthquake information from a server 4 on the internet by an earthquake information acquisition means 304 and informs it by a report means 305. Thereby, information required at the earthquake can be quickly and widely supplied to many users. Furthermore, by using functions of the existing gas meter, introduction costs are made lower. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a communication terminal, an earthquake information acquisition method, and a program for communicating with a meter such as gas, electricity and water, and acquiring earthquake information with a communication terminal when receiving information on earthquake detection from the meter.

  Japanese Patent Application Laid-Open No. 2004-133867 discloses a collective housing management system with an earthquake notification function that gives an appropriate instruction to a resident when a conventional earthquake is detected.

  A system is configured by connecting the alarm monitoring panel installed in the management room of the apartment house and the housing information panel installed in each dwelling unit of the apartment house. In the alarm monitoring panel, fires and gas leaks occurred in each unit It is possible to monitor the state of crime prevention. And an earthquake detection means is provided in the house information board, and when an earthquake is detected by the earthquake detection means, a predetermined countermeasure guidance is notified by the notification means so that an appropriate instruction can be given to a resident when an earthquake occurs.

  Further, Patent Document 2 discloses an earthquake security system that uses a seismic device that detects an earthquake provided in a gas meter.

The level signal detected by the gas meter's seismic device is communicated to a monitoring center connected by a communication line, and a plurality of the signals are subjected to judgment processing by a seismic processing device. The gas supply stop device is operated remotely to determine only the gas supply area where the earthquake is severe and to automatically stop the gas supply.
Japanese Patent Laid-Open No. 2003-67866 JP 2003-141660 A

  However, the system disclosed in Patent Document 1 provides a housing information panel equipped with an earthquake sensor that detects an earthquake in an apartment house management system, so that the housing information panel can be used to notify the coping method in the event of an earthquake with sound and video. However, it does not obtain earthquake information such as information on seismic intensity and tsunami presence. In other words, the method of coping with the occurrence of an earthquake that has been stored in advance is only notified when an earthquake is detected. In addition, only apartment houses that have introduced the system can provide a method for dealing with earthquakes. In addition, providing the earthquake information sensor in the housing information panel increases the cost of the device.

  Moreover, the system of the above-mentioned patent document 2 can stop the gas supply for each region by determining the earthquake level detected by the gas meter's seismic sensor at the center, but there is no provision of earthquake information to the user and the serviceability is sufficient. It couldn't be said.

  In order to solve the above-mentioned problem, the present invention communicates to a communication terminal when an earthquake is detected by a seismometer that is an earthquake detection sensor provided in a meter, and a communication terminal that has received this communicates via a wide-area communication network. The purpose is to allow users to obtain necessary earthquake information, so that more users can be provided with necessary information quickly when an earthquake occurs, and a system can be provided at low cost.

  In order to solve the above-described conventional problems, when an earthquake is detected, communication is performed with a meter having a shut-off means for shutting off gas, electricity, and water, and communication means for receiving earthquake detection or shut-off information from the meter; and the communication By providing a communication terminal with information acquisition means for acquiring earthquake information from a wide area communication network when earthquake detection or interception information is received by means, it is possible to quickly provide necessary information in the event of an earthquake and is generally installed The system and service that uses the seismic detection function of the meter, the installation cost can be reduced.

  The communication terminal, earthquake information acquisition method, and program according to the present invention can provide information necessary at the time of an earthquake quickly and widely to many users, and use the earthquake detection function of an existing meter to reduce the introduction cost. It has the effect of making it cheaper.

  In addition, since the earthquake information is acquired only from the information terminal of the house having the meter that has detected the earthquake, the earthquake information can be provided only to the house that requires the earthquake information. In addition, since earthquake information is acquired only from the information terminal of a house equipped with a meter that detects an earthquake and detects an earthquake that is large enough to activate the shut-off means, it is possible to provide earthquake information only for houses that require earthquake information immediately. it can.

  If all information terminals acquire earthquake information regardless of earthquake detection and its size, it is expected that communication for acquisition will start all at once after the earthquake and the telephone and Internet lines will be tight. .

  1st invention communicates with the meter which has the interruption | blocking means which interrupts | blocks gas, electricity, and water when an earthquake is detected, The communication means which receives the information of an earthquake detection or interruption | blocking from the said meter, Earthquake detection by the said communication means Or a communication terminal provided with information acquisition means for acquiring earthquake information from a wide area communication network when receiving information on interruption, and upon receiving earthquake detection or interruption due to earthquake detection from a meter, earthquake information is obtained by the information acquisition means The communication terminal which acquires and alert | reports is comprised.

  And by detecting earthquakes with a meter and acquiring earthquake information with a communication terminal that has received the detection information, it is possible to provide information required at the time of an earthquake quickly and widely to many users. The introduction cost can be reduced by using the function of the meter.

  According to a second aspect of the present invention, the information acquisition means configures a communication terminal according to claim 1 that acquires earthquake information from a server on the Internet.

  And by acquiring earthquake information from a server on the Internet, it becomes easier for earthquake information providers to provide earthquake information that is frequently updated to an unspecified number of communication terminals. improves.

  According to a third aspect of the present invention, the information acquisition means is constituted by radio reception means for receiving AM or FM radio or TV broadcast, and the communication terminal according to claim 1 is configured to acquire earthquake information.

  And by acquiring earthquake information with a radio receiver that receives public radio waves, radio and television are resistant to disasters and do not require a communication line, so even if the communication line is down due to an earthquake, the earthquake information is stable. Serviceability will be improved. In addition, it will be possible to provide disaster information provision services that are more resistant to earthquake disasters.

  4th invention detects an earthquake with a meter, or shuts off gas, electricity, and water when an earthquake is detected, and communicates earthquake detection information from the meter or information on cutoff by earthquake detection to a communication terminal; An earthquake information acquisition method comprising a step of acquiring and notifying earthquake information from a wide area communication network by receiving the earthquake detection information or gas cutoff information by earthquake detection in the communication terminal.

  And by detecting earthquakes with a meter and acquiring earthquake information with a communication terminal that has received the detection information, it is possible to provide information required at the time of an earthquake quickly and widely to many users. The introduction cost can be reduced by using the function of the meter.

  A fifth invention is a program for causing at least a part of the device according to any one of items 1, 2, or 3 to be executed.

  By using a program, it is possible to easily realize at least a part of the communication terminal of the present invention by cooperating hardware resources such as an electric / information device, a computer, and a server. In addition, the program can be distributed / updated and installed easily by recording on a recording medium or distributing the program using a communication line.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiments.

(Embodiment 1)
Embodiment 1 of the present invention will be described below with reference to FIGS.

  FIG. 1 is a system configuration diagram showing a gas centralized monitoring system using a communication terminal that communicates with a gas meter according to Embodiment 1 of the present invention.

  Although a gas meter will be described here, any meter related to living infrastructure such as an electric power meter, a water meter, or a fuel meter may be used.

  The gas centralized monitoring system connects the gas meter 1 and the server 4 of the gas company center with a communication terminal 2 via a communication line (telephone line or the Internet), and the information detected by the gas meter 1 is periodically or periodically. It is a service system that reports and monitors the safe use of gas at the center.

  Moreover, this system is also called an automatic meter-reading system, and periodically reports the gas usage measured by the gas meter 1 to the server 4 of the center once a month. Then, the gas fee is calculated from the gas and charged to the user. In addition, if an abnormality is detected in the sensor or usage inside the gas meter 1, the gas is shut off to prevent it from becoming unsafe, and the information that the gas is shut off when an abnormality occurs is sent to the center server. 4 is notified. Furthermore, LP gas (liquefied petroleum gas) and city gas generally exist as gas types, but LP gas also notifies the center server 4 of the remaining amount of cylinders used.

  In FIG. 1, the gas meter 1 is a network device having a network connection function (communication function), and is connected to a wireless device 1 d and has a function of communicating with the communication terminal 2 wirelessly. The wireless device 1d is configured using a specific low power wireless (429 MHz, wavelength 70 cm).

  Further, the communication terminal 2 has a display function, and acquires content information (weather, news, area information, shop information, advertisement information, etc.) from the server 4 and displays and uses it on the communication terminal 2. In the case of content information created in HTML, browsing is performed with a browser function provided in the communication terminal 2. Also, advertisement information and the like are provided with a function of displaying information embedded in the control screen of the communication terminal 2 to enhance convenience for the user.

  Here, the network device is a concept indicating home appliances and facility devices having a function of connecting to various networks including the Internet 3, and includes a refrigerator, a microwave oven, a washing machine, an air conditioner, a water heater, a dryer, and a dishwasher. , Vacuum cleaner, gas table, IH equipment, rice cooker, warm water washing toilet seat, electronic lock, various security sensors (human sensor, open / close sensor), net camera, lighting equipment, cogeneration system equipment, fuel cell system equipment, home server TV, video, DVD equipment, personal computer, PDA, mobile phone, FAX, telephone, audio equipment, and remote control equipment, gas meter, water meter, power meter, etc.

  In the present embodiment, a system connected to the gas meter 1 will be described. However, in addition to the gas meter 1, the communication terminal 2 can also function as a control controller for the device.

  The communication terminal 2 is connected to the ISP via the ADSL modem 7 and the ADSL line, and is connected to the server 4 through the Internet 3. In this embodiment, the communication line is described as ADSL. However, the communication line is connected to the ISP via a communication medium constituted by a telephone line, ISDN, xDSL, CATV network, optical cable, PHS, wireless communication network, etc. You may connect to the server 4 via Further, it may be connected directly by a telephone line without going through the Internet, or may be a dedicated line.

  In this embodiment, although not shown, the ISP is an Internet service provider and provides a service for connecting to the Internet. Communication is performed using TCP / IP, HTTP, or the like generally used on the Internet as a communication protocol.

  In addition, the mobile phone 5 that can be connected to the Internet 3 or a telephone line network has a function of controlling the gas meter 1 or the communication terminal 2.

  The communication terminal 2 includes a gateway function of a communication protocol that mutually converts a communication protocol of the gas meter 1 and an application protocol used in Internet communication.

  The communication terminal 2 holds a user authentication ID, a password, and the like necessary for connecting to the server 4. Furthermore, the ID of the wireless device 1d that communicates with the communication terminal 2 is also held.

  As shown in FIG. 2, the communication terminal 2 includes a CPU 2a, a memory 2b, an external storage device 2c such as a flash ROM (Flash Read Only Memory), a ROM, a wireless device 2d for communicating with the wireless device of the gas meter 1, an Ethernet ( 3), a communication interface 2e such as a registered trademark), and a display 2f hardware resource composed of an LCD or the like. The wireless resources 301, the notification information determination unit 302, and the like as shown in FIG. The communication means 303, the earthquake information acquisition means 304, and the notification means 305 are functioning.

  In FIG. 2, the gas meter 1 includes a CPU 1a, a memory 1b, a sensor 1c, a wireless device 1d, a shut-off valve 1e, and a seismic device 1f. The blocking means 307 and the meter control means 308 are functioned.

  Next, the configuration function of the communication terminal 2 will be described in detail. The operation / action will be described later.

  In FIG. 3, the wireless communication unit 301 has a function of performing wireless communication with the wireless device 1 d connected to the gas meter 1. Meter reading information (gas usage information) measured by the gas meter 1 and abnormal gas information (cutoff information, etc.) monitored by the gas meter 1 are communicated with the gas meter 1. Normally, the meter reading information is set to be reported to the center server 4 once a month.

  The gas meter 1 has a function of shutting off gas by the valve shut-off means 307 by the meter control means 308 when gas leak detection, earthquake detection, pressure drop detection, usage time / use amount abnormality detection, etc. occur.

  The notification information determination unit 302 receives meter reading information, gas abnormality information, and the like communicated from the gas meter 1 to the communication terminal 2, and determines the content of the information. Further, in the case of gas abnormality information, it is determined whether to notify by the notification means of the communication terminal 2 according to the content of the gas abnormality information.

  The outside communication unit 303 connects the communication terminal 2 to the Internet 3 or an external communication network such as a telephone line and realizes a state in which data can be transmitted to and received from the server 4. Specifically, in FIG. 3, the out-of-home communication means 303 is connected to the ISP via the router 6 and the ADSL modem 7 and then connected to the server 4 via the Internet 3 via TCP / IP.

  The earthquake information acquisition unit 304 is notified of the earthquake detection when the notification information determination unit 302 receives the earthquake detection information and the information on the gas cutoff due to the earthquake from the gas meter 1, and transmits the necessary earthquake information to the user via the Internet 3. Receive from server 4. The server 4 may be configured by a server different from the server for the centralized gas monitoring service, or the operator may be different. It is also possible to connect to a server of a business operator that provides a service that provides earthquake information.

  The notification unit 305 provides a function of transmitting information to the user by characters, images, sounds, and the like. Specifically, the contents of the gas abnormality information are displayed on the liquid crystal display, and the countermeasures are displayed. At the same time, guidance is given by voice through a speaker. When an earthquake is detected, information such as the acquired earthquake information, damage status, evacuation location, countermeasures, etc. is displayed, and the text is read aloud.

  The earthquake detection means 306 is composed of the seismic device 1 f of the gas meter 1, detects the intensity level of the earthquake shake, and notifies the meter control means 308.

  The valve shut-off means 307 has a function of shutting off the valve of the flow path of the gas pipe (not shown) in the gas meter 1 when the above-described gas abnormality is detected. Specifically, when an earthquake occurs, when the earthquake detection means 306 detects a large earthquake, the meter control means 308 is notified, and the meter control means 308 controls the electromagnetic valve to shut off the gas shut-off valve 1e. In addition, when the abnormal state is resolved, a function of opening and returning the gas shut-off valve 1e through the communication from the center server 4 and the operation of the communication terminal 4 and the gas meter 1 is also provided.

  As described above, the meter control unit 308 controls the valve blocking unit 307 to be blocked based on the detection information of the earthquake detection unit 306. In addition, it has a function of generating a telegram for transmitting gas abnormality information detected by the gas meter 1, meter reading information, etc., and transmitting it to the communication terminal 4 via the wireless device 1d.

  On the other hand, the server 4 determines the type of authentication request, information acquisition request, control request, etc. of the communication terminal 2 transmitted from the communication terminal 2, and transmits the response message of the message. Therefore, as shown in FIG. 4, hardware resources such as a CPU 4 a, a memory 4 b, an external storage device 4 c, and a communication interface 4 d are provided, and these are cooperated to transmit / receive means 501, user authentication / determination processing means shown in FIG. 5. 502, the user information database 503, the transmission information generation means 504, and the earthquake information database 505 are made to function.

  The transmission / reception means 501 establishes a transmission / reception state with the communication terminal 2 when there is a TCP / IP connection such as an authentication request, an information acquisition request, or a control request from the communication terminal 2 via the Internet 3, and authentication information , Setting information, earthquake information, control information, etc. are transmitted and received.

  The user authentication / judgment processing means 502 performs processing for comparing and authenticating the terminal ID and password, which are authentication information of the communication terminal 2 received from the communication terminal 2 at the time of an authentication request, with the user information managed in the user information database 503. The terminal ID is a serial number uniquely recorded for each communication terminal 2, and is transmitted to the server 4 at the time of user authentication at the time of initial setting of the communication terminal 2, and other user information (phone number, It is managed together with a password (password). Further, the type of data is determined by the data identifier attached to the data. Notification contents of meter reading information and gas abnormality information are also received and processed here, and managed together with user information.

  The user information database 503 holds a user name, address, area code, telephone number, mobile phone number, personal identification number (password), terminal ID, service subscription status, mobile phone mail address, and the like. It also manages meter reading information and report history of gas abnormality reports.

  Upon receiving the request message from the communication terminal 2, the transmission information generation unit 504 generates a response message for the request message and responds. Although not described in the present embodiment, when an information acquisition request is received, setting information and earthquake information necessary for the communication terminal 2 are extracted and generated. This setting information is generated from setting information set in the user information database 503. For earthquake information, information registered in the earthquake information database 505 described later is extracted for each user's area code, and earthquake information to be provided to the user's area (damage status, evacuation location, countermeasures, emergency hospital information, etc.) ) Is generated and sent.

  The earthquake information database 505 records various information such as daily countermeasures for earthquakes and disasters, evacuation areas for each area, and emergency measures for injuries. In addition, in the event of an earthquake or disaster, emergency information that should be urgently communicated to each user, evacuation instructions and recommendations issued by the government / local government, damage status, lifeline (gas, electricity, water) status, recovery prospects, roads, traffic Traffic information such as the status of the institution, recovery prospects, life support information on disaster-stricken books, and information on consultation desks provided by local governments are updated and recorded in a timely manner.

  These pieces of information are recorded in a format that can be viewed with a WEB browser such as HTML, and are displayed by the notification unit 305 of the communication terminal 2. Further, emergency information to be notified by voice is also recorded, and when updated, information is acquired by the communication terminal 2 in a timely manner and notified by notification means 305 constituted by a speaker or the like so that the emergency information can be conveyed to the user. .

  In FIG. 5, the server 4 is illustrated as a single device, but there may be a plurality of servers, and the user information database 503 and the earthquake information database 505 may be in another device or in another place. Absent.

  Next, the operation and action in this embodiment will be described with reference to FIG.

  FIG. 6 is a flowchart showing an operation of detecting an earthquake with the earthquake detection means 306 of the gas meter 1 and acquiring earthquake information with the communication terminal 2. The explanation will be made with reference to FIG. 3 as appropriate.

  When an earthquake occurs, the earthquake detection means 306 of the gas meter 1 detects a shake, and notifies the meter control means 308 of the shake level as shake level information (step 601).

  Further, the gas meter 1 has a function of shutting off the gas when the seismic intensity is higher than a predetermined seismic intensity. If the seismic detecting means 306 is at a level indicating a predetermined seismic intensity, the meter control means 308 controls the valve shutting means 307. Control and shut off gas. When the gas is shut off, the gas meter 1 informs the center of the gas company that a gas shut-off event (gas abnormality) has occurred (not shown).

  When an earthquake is detected in the gas meter 1 or a gas interruption occurs due to the earthquake, a telegram for notifying the occurrence of an abnormality is generated by the meter control means 308 and transmitted to the wireless device 1d and transmitted to the wireless communication means 301 of the communication terminal 2 via wireless communication. (Step 602).

  The message received by the wireless communication unit 301 is subjected to determination processing by the notification information determination unit 302 by analyzing the notified message content. Then, if the notification message is earthquake detection or abnormal gas cutoff information due to an earthquake, the earthquake information acquisition unit 304 is made to acquire earthquake information.

  The earthquake information acquisition unit 304 generates an earthquake information acquisition request message, controls the outside communication unit 303, and transmits the message to the server 4 through the Internet 3. The server 4 analyzes the contents of the electronic message, and when the content is an earthquake information acquisition request, the information recorded in the earthquake information database 505 is set in a response electronic message and is received by the communication terminal 2 (step 603).

  The communication terminal 2 that has acquired the earthquake information notifies the user of the earthquake information acquired by the notification unit 305 with characters, images, sounds, and the like (step 604). Further, when a gas shut-off occurs due to an earthquake, the notifying means 305 notifies the gas abnormality, the shut-off valve return method, and the like.

  In addition to providing information to the communication terminal 2, it is also possible to distribute earthquake information in a timely manner to the user's mobile phone 5 using this system by e-mail.

  Note that the shaking level that is detected and notified by the gas meter 1 is set in advance to a predetermined value.

  At this time, the priority of earthquake information acquisition to the server 4 of the out-of-home communication means 303 (for example, providing a plurality of waiting times depending on the shaking level) may be provided according to the shaking level of the earthquake. Earthquake information may be acquired with the gas cutoff abnormality information as the highest priority. By providing the priority of earthquake information acquisition in this way, centralized access to the server 4 when an earthquake occurs can be distributed and alleviated.

  Although the communication terminal 2 and the server 4 have been described as being connected via the Internet 3, the present invention is not limited to this, and the communication line is a telephone line, ISDN, ADSL, CATV, optical cable (FTTH), wireless LAN, Ethernet ( Registered trademark) or the like.

  Moreover, although the specific low power radio | wireless was demonstrated as a communication means of the communication terminal 2 and the gas meter 1, power line communication, Ethernet (trademark), wireless LAN, etc. may be sufficient.

  The specific configuration of each part is not limited to the above-described embodiment, and various modifications can be made without departing from the spirit of the present invention.

  As described above, the earthquake detection means 306 of the gas meter 1 detects an earthquake, the valve shut-off means 307 shuts off the gas, and when an earthquake is detected, the earthquake detection or the gas shut-off information by the earthquake detection is sent to the communication terminal 2. By transmitting and acquiring the earthquake information from the wide area communication network by the earthquake information acquisition means 304 of the communication terminal 2, the necessary information at the time of the earthquake can be quickly provided to the user, so serviceability and user safety Will improve. In addition, if the user is a gas user, a system service using the function of the installed gas meter can reduce the introduction cost, and can be provided to a large number of users.

  In addition, by acquiring earthquake information from a web server on the Internet, it becomes easier for earthquake information providers to provide earthquake information with a high frequency of update to a large number of unspecified communication terminals. Will improve.

(Embodiment 2)
A second embodiment of the present invention will be described below with reference to FIG.

  FIG. 7 is a block configuration diagram of the communication terminal 2 according to the second embodiment. The present embodiment is different in that the earthquake information acquisition means 304 is a radio reception means 701 and earthquake information is acquired by radio waves. The same components as those in the first embodiment (FIG. 3) are denoted by the same reference numerals, and description thereof is omitted.

  The gas meter 1 detects an earthquake and transmits the earthquake detection information to the communication terminal 2. If the notification information determination unit 302 determines that the information is earthquake detection information or gas cutoff abnormality information due to an earthquake, the radio reception unit 701 is operated, and is tuned to a predetermined radio frequency set in advance to be in a radio reception state. The radio is received by the antenna 702. The voice and text information received by the radio is output by the notification means 305, and the earthquake information and disaster information are transmitted to the user more quickly. It is also possible to read out character information as speech.

  Although it is possible to switch to radio reception when the new arrival information is updated in the server 4, the radio reception means 701 operates only when necessary by linking with the earthquake detection information from the gas meter as in this embodiment. Therefore, it can operate and notify only when an earthquake occurs in your area.

  The predetermined radio frequency can be changed from the center server 4. The radio frequency may be AM broadcast, FM broadcast, or TV broadcast.

  As described above, since the earthquake information acquisition means is the radio reception means 701, it becomes possible to cope with a major disaster when the wired communication line becomes unusable, and the earthquake information can be stably acquired. Serviceability is improved. In addition, it will be possible to provide an information provision service at the time of disaster that is more resistant to earthquake disasters.

  In addition, the present embodiment can provide the same function as the program for causing the communication terminal 2 and the server 4 to function as a computer.

  By using the program, it can be realized as a partial function of a microcomputer, a personal computer, or another device, and convenience and versatility are improved and a system can be easily constructed. In addition, the program can be distributed and installed easily by recording on a recording medium or distributing the program using a communication line.

  In addition, although demonstrated as a gas meter in this Embodiment, not only this but an electric power meter and a water meter may be sufficient.

  Further, the earthquake detection means 306 may be provided on the communication terminal side.

  As described above, the communication terminal, the earthquake information acquisition method, and the program according to the present invention are realized by connecting the device provided with the earthquake detection sensor and the communication terminal, and thus realized similarly if the device is provided with the earthquake detection sensor. Is possible. For example, it can be applied to energy systems such as fuel cell systems and cogeneration systems.

1 is a system configuration diagram of a gas concentration monitoring system according to Embodiment 1 of the present invention. 1 is a block diagram of a communication terminal and a gas meter according to Embodiment 1 of the present invention. The block block diagram which shows the function of the communication terminal of Embodiment 1 of this invention Block configuration diagram of the server according to Embodiment 1 of the present invention The block block diagram which shows the function of the server of Embodiment 1 of this invention The flowchart which shows the operation | movement of earthquake information acquisition of the communication terminal of Embodiment 1 of this invention. The block block diagram which shows the function of the communication terminal of Embodiment 2 of this invention

Explanation of symbols

1 Gas meter (meter)
2 Communication terminal 3 Internet (wide area communication network)
4 server 301 wireless communication means (communication means)
304 Earthquake information acquisition means (information acquisition means)
306 Earthquake detection means 307 Valve shut-off means (blocking means)
701 Radio receiving means

Claims (5)

When an earthquake is detected, it communicates with a meter having a shut-off means that shuts off gas, electricity, and water, and communication means that receives earthquake detection or shut-off information from the meter, and receives earthquake detection or shut-off information by the communication means Then, the communication terminal provided with the information acquisition means which acquires earthquake information from a wide area communication network. The communication terminal according to claim 1, wherein the information acquisition unit acquires earthquake information from a server on the Internet. The communication terminal according to claim 1, wherein the information acquisition unit includes a radio reception unit that receives AM, FM, or TV broadcasts, and acquires earthquake information. Detecting an earthquake with a meter, or shutting off gas or electricity / water when an earthquake is detected, communicating earthquake detection information from the meter, or blocking information by earthquake detection, to the communication terminal; and An earthquake information acquisition method comprising a step of acquiring and notifying earthquake information from a wide area communication network by receiving earthquake detection information or blocking information by earthquake detection. The program for performing at least one part of the communication terminal of any one of Claim 1, 2, or 3.

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