JP2004126880A - Remote monitoring system for automatic fire alarm facility - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To confirm that facilities for fire protection are functioning by accessing a fire receiver at each building through a network. <P>SOLUTION: A customer service server registers each of the fire receivers and transmits to the network a calling signal for sequentially and individually calling each of the fire receivers. The fire receiver sends back a normality monitoring signal to the customer service server if normality is found when receiving the calling signal. Meanwhile, when the fire receiver has information on abnormality, the fire receiver returns an abnormality information signal to the customer service server. The customer service server stores the received normality monitoring signal or abnormality information signal upon receiving the normality monitoring signal or abnormality information signal from the fire receiver to which the calling signal was sent, or stores a no-response signal unless receiving the normality information signal or the abnormality information signal within a specified period after sending the calling signal. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention provides a remote monitoring of an automatic fire alarm system that installs a customer service server that performs various services via a network such as the Internet, accesses a fire receiver of a remotely registered property, and collects information. About the system.
[0002]
[Prior art]
Conventionally, fire-fighting equipment such as automatic fire alarm equipment, sprinkler fire-extinguishing equipment, and indoor fire hydrant equipment has been provided in a building that is a predetermined fire protection target. It is necessary to maintain such equipment so that it can function properly in the event of an unforeseen event such as a fire.
[0003]
Various types of firefighting equipment such as those described above often use a fire receiver as a central control device to aggregate alarm signals such as fire occurrences and abnormal information indicating functional abnormalities. A fire receiver that monitors and controls various devices in the building is installed in the disaster prevention center or the manager's office, and is monitored by a manager.
[0004]
In addition, it is possible to use a so-called general operation panel in which a monitoring panel is installed in each of the above fire-fighting facilities, various status information is output from each monitoring panel, and the information is collected into one comprehensive monitoring panel. The general operation panel in this case is functionally the same as the above fire receiver.
[0005]
[Problems to be solved by the invention]
In the above-mentioned conventional equipment, when a manager is resident in each building, when information on the occurrence of a fire or a malfunction is displayed on the panel of a fire receiver that supervises each of the facilities, it responds according to the content. However, it is not possible to respond immediately when the manager is not always present or when the manager is out of the seat.
[0006]
In some cases, a system is in place to report such equipment status via telephone.However, even if a specific center receives a report from a fire receiver, the fire If it is down, it cannot be grasped at that center.
[0007]
In addition, the fire receiver has a so-called event log function for recording the history of the state change in the facilities within the general range. Here, the “event” is a factor that should be simply recorded for the state change, and the “log” is a function of recording the event with time along with the time at which the event occurred. In order to exhibit such an event log function, the fire receiver is provided with a writable nonvolatile storage means such as a flash memory for storing records.
[0008]
However, even if an attempt is made to save all the events that have occurred in the fire receiver, the storage means has a limited capacity and cannot be saved without limitation. In addition, when the manufacturer or an inspection company checks what is stored in the fire receiver, it is necessary to go to a building and take out the fire receiver.
[0009]
Also, recent fire receivers are often provided with an automatic test function. The function tests provided by the fire receiver differ depending on the model. However, as an automatic test, a function test is automatically executed, for example, once a week at a specified time, and the results are saved and when there is an abnormality. , An abnormal alarm operation is performed.
[0010]
However, even if an abnormality is detected by the above-described automatic test, the response is delayed depending on the response of the manager, and when the user is out of the seat, the abnormality alarm operation becomes meaningless. Further, it is preferable that the state of the equipment can be always checked, but the record of the execution of the automatic test may be deleted, and it may not be possible to check that the execution is being performed periodically.
[0011]
In addition, if there is any display factor from the equipment installed in the building, it is displayed on the display panel such as the LCD by characters or symbols on the panel of the fire receiver, but the manager is unfamiliar with it. If so, the user may operate it erroneously and cannot understand the meaning of the display that needs to be dealt with.
[0012]
As described above, it is preferable to explain the operation of the appearance including the status of the indicator light and the switch other than the LCD and the like on the panel of the fire receiver panel. It is preferable to be able to comprehend.
[0013]
In addition, if any of the facilities installed in the building has contents to be notified, such as a change in handling items, etc., we will make them known by letter or telephone call. However, when there is content to be notified in this way, it is complicated to individually notify the building where the related equipment is installed.
[0014]
In addition, there is a fire receiver that has a simulation function in which the order of occurrence of events at the time of a fire occurrence is set in advance and attempts an accurate operation by a manager or the like. Once experienced, one can predict the order of occurrence of that event, or the order of occurrence of events that is optimal in a building or urban environment may need to be changed. Then, when changing the order of occurrence of events, the work of resetting the data stored in each fire receiver is complicated.
[0015]
Therefore, a first object of the present invention is to make it possible to access a fire receiver of each building via a network and confirm that the fire-fighting equipment is functioning.
[0016]
A second object of the present invention is to make it possible to store and use events generated in each building collectively via a network.
[0017]
A third object of the present invention is to enable an automatic test function to be executed via a network.
[0018]
A fourth object of the present invention is to make it possible to grasp the state of the fire receiver panel via a network.
[0019]
A fifth object of the present invention is to allow a fire receiver to display the contents to be notified via a network.
[0020]
A sixth object of the present invention is to make it possible to easily change the procedure of the simulation function via a network.
[0021]
[Means for Solving the Problems]
A first invention is a system in which a fire receiver of a plurality of properties and a customer service server for managing the plurality of properties are connected to a network, wherein the customer service server registers each of the fire detectors. Registration means, and call signal sending means for sending a call signal for sequentially calling each of the fire receivers to the network, wherein the fire receiver normally operates when the call signal is received. If so, a return means is provided for returning a normal monitoring signal to the customer service server, while, if it has abnormality information, a return means for returning an abnormality information signal to the customer service server. When the normal monitoring signal or the abnormal information signal is received from the fire receiver which is the signal transmission partner, the received normal monitoring signal or abnormal information signal is received. If the normal monitoring signal or the abnormal information signal is not received within a predetermined time after the transmission of the call signal, the non-response signal is stored in the call result storage means. It is a remote monitoring system for fire alarm equipment.
[0022]
A second invention is a system in which a fire receiver of a plurality of properties and a customer service server for managing the plurality of properties are connected to a network. Via the network, an event information signal transmitting means for transmitting an event information signal indicating the information of the event to the customer service server, wherein the customer service server receives the event information, This is a remote monitoring system for an automatic fire alarm system that stores information indicating a fire receiver that has occurred and the event information signal in event log means.
[0023]
A third invention is a system in which a fire receiver for a plurality of properties and a customer service server for managing the plurality of properties are connected to a network, wherein the customer service server registers the fire receivers. Registration means and, at the time of inspection according to each of the fire receivers, having transmission means for transmitting an inspection start signal to the network, the fire receiver receiving the inspection start signal starts an automatic inspection function. The inspection result signal returning means for returning the inspection result to the customer service server. The customer service server sends the inspection result signal from the fire receiver which has transmitted the inspection start signal. Automatic fire alarm that receives the inspection result signal, stores the inspection result, and notifies the contact registered in each fire receiver when the inspection result is abnormal. It is the Bei of the remote monitoring system.
[0024]
A fourth invention is a system in which a fire receiver of a plurality of properties and a customer service server for managing the plurality of properties are connected to a network, wherein the customer service server transmits information on a board of each of the fire receivers. Registration means for registering, and transmission means for transmitting a state information request signal to each of the fire receivers via the network, the fire receiver having received the state information request signal has information on its own state. A return means for returning a status information return signal to the customer service server, wherein the customer service server is a remote monitoring system for an automatic fire alarm system for creating a status relating to a board of a corresponding fire receiver. .
[0025]
According to a fifth aspect of the present invention, in the system in which a fire receiver of a plurality of properties and a customer service server for managing the plurality of properties are connected to a network, the customer service server includes a message, an image, and a moving image. Registration means for registering display information by at least one, and transmission means for transmitting the display information to each of the fire receivers via the network, wherein the fire receiver receiving the display information comprises: This is a remote monitoring system for an automatic fire alarm system that displays the display information on a display unit during normal monitoring in which no fire or the like has occurred.
[0026]
Further, a sixth invention is a system in which a fire receiver for a plurality of properties and a customer service server for managing the plurality of properties are connected to a network, wherein the customer service server is connected to the network via the network. At least one of the fire receivers has transmission means for transmitting the simulated operation signal, and the fire receiver having received the simulated operation signal performs an operation based on the simulated operation information received thereafter, and Simulating operation storing means for storing the simulated operation information and the information on the operation of the panel in a timely manner; This is a remote monitoring system for an automatic fire alarm system, which is a server having a server.
[0027]
Embodiments and Examples of the Invention
FIG. 1 is a diagram showing a remote monitoring system 100 for an automatic fire alarm system according to a first embodiment of the present invention.
[0028]
The remote monitoring system 100 for the automatic fire alarm system includes a customer service server 10, a storage device M1 such as an HDD storing equipment list data, a similar storage device M2 storing event log data, a personal computer and the like. And a fire detector RE connected to the fire receiver RE via a line, a fire receiver RE with a terminal function installed in the building, and the Internet NW. This is a system that reduces the functional burden on the fire receiver RE and makes the use of information convenient.
[0029]
A plurality of fire detectors S are installed in a building to be monitored "OO building" together with various equipment for fire-fighting equipment, but FIG. 1 shows only one fire detector S as a representative thereof. Is described. The storage devices M1 and M2 are connected to the customer service server 10. A fire receiver RE with a terminal function, a customer service server 10, and a terminal device D1 for a management company are connected to the Internet NW as a plurality of terminal devices.
[0030]
Note that there are a plurality of fire receivers RE connected to the Internet NW for each building where the automatic fire alarm system is installed, but FIG. 1 typically shows only one fire receiver. Similarly, the management company terminal device D1 exists for each related company, but FIG. 1 typically shows only one. Although only one customer service server 10 is shown, a plurality of the customer service servers 10 may be provided in consideration of the storage capacity and the processing speed, sharing the target area and functions to be described later.
[0031]
According to the above system configuration, each fire receiver RE is compatible with the network (with a terminal function) and exchanges information with the customer service server 10. , The information stored in the customer service server 10 can be retrieved and used, and furthermore, the customer service server 10 can be contacted by e-mail or the like to a related company.
[0032]
FIG. 2 is a block circuit diagram schematically showing a configuration of the fire receiver RE with a terminal function.
[0033]
The fire receiver RE includes a control unit 11, a terminal monitoring unit 12, a storage unit 13, a display operation unit 14, and a communication unit 15, and a plurality of fire detectors S are connected via a signal line L. It is connected.
[0034]
The control unit 11 is configured by a microcomputer or the like, and controls the overall movement of the fire receiver RE. The terminal monitoring unit 12 transmits and receives signals to and from a plurality of fire detectors S via the signal line L, receives status information of various connected devices (not shown in detail), and transmits control signals. I do. In addition to the fire detector S, a transmitter, a local acoustic device, a smoke elimination device, and the like are connected to the signal line L as necessary as fire alarm equipment.
[0035]
The storage unit 13 is a storage area configured by a flash memory or the like and capable of temporarily storing data. The display operation unit 14 has an LCD, various display lamps, and various operation switches. For example, when a fire signal is received from the fire detector S, a buzzer (not shown) as a main sound device sounds and fire information is displayed. The communication unit 15 is an interface that connects the fire receiver RE to the Internet NW, which is an example of a network, and that transmits and receives various information according to the protocol of the network.
[0036]
Next, the operation of the above embodiment will be described.
[0037]
[Polling operation]
FIG. 3 is a flowchart showing the polling operation performed by the customer service server 10 in the above embodiment.
[0038]
In the above-mentioned "polling operation", the fire receiver RE connected to the Internet NW is registered in advance in the customer service server 10, and the registered fire receiver RE is periodically called by the customer service server 10 and called. This is an operation in which the customer service server 10 confirms that the fire receiver RE is normally monitored. When registering the fire receiver RE with a terminal function, for example, the necessity of polling the fire receiver RE is registered as a property list in the storage device M1.
[0039]
First, when the polling operation is started, the polling operation is started periodically, for example, once an hour (S1), and depending on the necessity of the polling registered in the property list, the fire receiver RE is activated. The call destinations are sequentially read and a call signal is transmitted (S2).
[0040]
The fire receiver RE, which has received the calling signal, transmits a normal monitoring signal to the customer service server 10 when the automatic fire alarm device monitored and controlled by itself is normal monitoring, and conversely, when there is abnormal information, The abnormality information is transmitted to the customer service server 10 (S3). Here, in this embodiment, when specifying the call destination, an IP address that can specify the fire receiver RE as the terminal device via the Internet NW may be used.
[0041]
Further, the fire receiver RE receiving the call signal needs to confirm the validity of the customer service server 10 that provides the information. For example, an ID and a password are set in advance for each fire receiver RE, and the fire receiver RE is called. It is necessary to provide an authentication process for confirming that the signal has its own ID and password. Also, when responding to the call signal, the customer service server 10 can be specified by the IP address. Further, the customer service server 10 to be called and the data server storing the information are configured differently from each other, and the information is always stored in the data server. May be registered in the fire receiver RE so as to be transmitted.
[0042]
When the customer service server 10 receives the normal monitoring signal or the abnormal information from the fire receiver RE, the customer service server 10 stores the polling result data as a database, for example, in the storage device M2 (S4). Then, steps S2 to S4 are repeated by changing the call destination so as to collect normal monitoring signals or abnormal information from all the fire receivers that require polling. That is, the server 10 repeats calling, receiving a response, and storing a plurality of fire receivers based on the necessity of polling the property list.
Here, the fire receiver RE is not always operating and may be powered down for some reason. As described above, when a response cannot be obtained from the fire receiver RE and no response can be obtained even after a predetermined time has elapsed, it is determined that there is no response, and the non-response is stored in the polling result data.
[0043]
Then, the contact information is registered in advance in the property list for each fire receiver RE, and when abnormal information is received or when it is determined that there is no response, the contact information is notified to the contact information that there is an abnormality ( S5). Including the owner of the building where the fire receiver RE is installed, its manager, inspection company, construction company, and other related companies are set as the above-mentioned contacts as necessary, and in this embodiment, As the communication method, electronic mail is preferable, but fax transmission, automatic mail dispatch, or the like may be adopted. That is, for example, if the manager terminal device D1 is constantly connected to the Internet NW, the notification may be a display alert to the manager terminal device D1.
[0044]
As described above, the customer service server 10 can access the fire receiver RE of each building via the network NW to confirm that the fire-fighting equipment is functioning. Even when the fire receiver RE is down, the customer service server 10 may determine that the fire receiver RE has stopped functioning.
[0045]
[Event log operation]
FIG. 4 is a flowchart showing an event log operation to be performed on the customer service server 10 and an event log reference operation performed in the above embodiment.
[0046]
In this event log operation, the “event” in the automatic fire alarm system is, more specifically, a general term for display items related to a change in the state of the automatic fire alarm system and its surroundings, and operation items on the panel of the fire receiver RE. The "event log" refers to a function of recording an event that has occurred.
[0047]
2. Description of the Related Art Conventionally, a method has been adopted in which an event that has occurred in a fire receiver is printed out from time to time or a predetermined storage area is secured and sequentially stored. In the event log operation in the above embodiment, the history of events that have occurred in each fire receiver RE connected via the Internet NW is stored in the customer service server 10.
[0048]
First, in one of the fire receivers RE, for example, the fire detector S fails, and when the fire receiver RE recognizes this failure and abnormal information occurs, it is determined that an event has occurred (S11). , And transmits the abnormal information and the ID indicating the self to the customer service server 10 via the Internet NW (S12). Here, the fire receiver RE executes a normal operation corresponding to the event.
[0049]
The customer service server 10 that has received the content of the event stores the content in, for example, the storage device M2, that is, in the event log data as a database (S13). Then, based on the ID received together with the content of the event, necessary contact information is read from, for example, the receiver list registered in the storage device M1, and notification of the event occurrence is made (S14).
[0050]
In this communication method, as described in the description of the polling operation, a predetermined contact is notified. The content of the event varies from important to minor ones, and it is also possible to select a contact according to the content of the event. Also, it is not necessary to notify the fire receiver RE of an event such as a district sound stop operation or a recovery operation.
[0051]
Further, in this event log operation, the fire receiver RE itself may make a communication indicating that the event has occurred (S15). That is, although not shown in detail, in order for the automatic fire alarm system to operate effectively, a database for each building, such as information on the fire detector S, is set in the storage unit 13 of the fire receiver RE. If the contact information at the time of the event occurrence is set in this database, the fire receiver RE can communicate the event from the communication unit 15 via the Internet NW by utilizing its own terminal function. In addition, when the property in which the fire receiver RE is installed has a general operation panel, the communication operation may be performed by the general operation panel.
[0052]
In the above embodiment, since the customer service server 10 notifies the necessary contact information of the event, it overlaps with the communication by the fire receiver RE. Since the contact is received almost at the same time, there is only one response to the contact, and there is no problem.
[0053]
Next, a log inquiry operation in the above embodiment will be described.
[0054]
For example, an inspection contractor who performs maintenance inspection can refer to the event log when grasping the status of the building of the maintenance contractor. In this case, the customer service server 10 is accessed using the terminal device D1 for the manager, and the event log of the contracted party is referred to.
[0055]
First, necessary operations are performed on the management company terminal device D1 (S21), and the customer service server 10 is accessed from the management company terminal device D1 via the Internet NW (S22). Although not shown, the customer service server 10 confirms the necessity of a response based on the ID and the password from the terminal device D1 for the management company, and refers to, for example, a company registration list registered in the storage device M1, and Determine the necessity. After accessing in this manner, a property to be referred to is specified for the management company terminal device D1, and a request for an event log is transmitted from the management company terminal device D1 to the customer service server 10 via the Internet NW (S23).
[0056]
The customer service server 10 that has received the request for the event log uses the ID of the trader to determine, for example, whether the trader is registered in the property list registered in the storage device M1, and refers to the event log. It is determined whether or not the user has the qualification (access right) to perform (S24). If the qualification can be confirmed, the event of the corresponding property is extracted from the event log data stored in the storage device M2, for example. Is transmitted to the management company terminal device D1 via the Internet NW (S25).
[0057]
Then, the management company terminal device D1 receives the event log and displays it on the screen of the personal computer (S26). For example, an inspector can refer to this event log to predict the failure of the equipment installed in the relevant property, or, on the contrary, check the occurrence of a failure or the like for an inspection result that is not very good.
[0058]
[Automatic test operation]
FIG. 5 is a flowchart showing the automatic test operation by the customer service server 10 in the above embodiment.
[0059]
In this automatic test operation, the fire receiver RE connected to the Internet NW, which is to be subjected to the automatic test at a predetermined cycle, is registered in the customer service server 10 in advance, and at a predetermined time, This is an operation in which the customer service server 10 transmits an automatic test command to each registered fire receiver RE, executes an automatic test, and collects the result. Note that it is necessary that the fire receiver RE with a terminal function be provided with an automatic test function. When registering the fire receiver RE to be subjected to the automatic test, the fire receiver RE is registered in the same manner as in the polling operation described above. The necessity of the automatic test for the RE is registered as a property list together with its start time in, for example, the storage device M1.
[0060]
First, when the start time of the automatic test registered in the property list is reached (S31), the call destination of the fire receiver RE is read from the property list and an automatic test start is transmitted (S32). Here, the start time of the automatic test is normally set to once a week, and registered as what day and what minute. The setting of the time is not limited to the above-described cycle, and may be performed at intervals of 3 days or 5 days. Each time the automatic test is started, the next start date and time may be calculated and updated. Then, the fire receiver RE that has received the start of the automatic test starts its own automatic test (S33).
[0061]
Here, the “automatic test” includes, for example, a remote test of each connected fire detector S, a display unit test that turns on all the LEDs and the like of the display operation unit 14 on the panel of the fire receiver RE not shown in detail. This is a test in which all individual tests are executed in combination, such as a backup power supply test for checking the capacity of a backup power supply (not shown), and the contents and test methods differ for each model. The automatic test function is conventionally executed as an autonomous function of the fire receiver RE, and the fire receiver RE can also execute an automatic test manually or automatically.
[0062]
When the automatic test is completed, the fire receiver RE transmits the result of the automatic test to the customer service server 10 (S34). The result of this automatic test is either normal termination or abnormal termination, and if it is abnormal termination, the result including the abnormal result is transmitted. Here, when performing the automatic test, the IP address may be used as a call destination when the fire receiver RE as the terminal device is specified via the Internet NW, similarly to the polling operation described above. An authentication process is provided based on the password.
[0063]
The customer service server 10 that has received the result of the automatic test from the fire receiver RE stores the automatic test result data as a database, for example, in the storage device M2 (S35). Here, similarly to the above-mentioned polling operation, the fire receiver RE may be powered down, and when this state elapses a predetermined time (timeout), a no response is stored. Then, if there is an abnormality in the result of the automatic test, as in the polling operation, the contact information of each fire receiver RE registered in advance in the above-mentioned property list is notified of the abnormality, including no response, including a no response. (S36). It is preferable that the abnormal termination of the automatic test be reported to a vendor as soon as possible.
[0064]
[Information provision operation]
FIGS. 6 and 7 are flowcharts showing the operation of providing information by the customer service server 10 in the above embodiment.
[0065]
The “information providing operation” is an operation in which the customer service server 10 provides the fire receiver RE connected to the Internet NW with various kinds of information, including communication items, technical information, and advertisement items.
[0066]
Normally, the fire receiver RE has a display unit by LCD and a display device by CRT, although it differs depending on the model. When the fire monitor RE is in a normal monitoring state and has no events including operations, the power is turned off or a dark display is performed. Often. This is to enable information from the customer service server 10 to be displayed on the display operation unit 14 of the fire receiver RE in which the display is unnecessary in many cases.
[0067]
To display the information on the fire receiver RE (S41), the data of the information to be provided is set in the customer service server 10 (S42), and the data to be provided is stored in, for example, a database in the storage device M2. Is stored and transmitted to the corresponding fire receiver RE (S43).
[0068]
Here, the data of the information to be provided includes only text data, HTML data including image data, moving image data, combinations of these with audio data, and other data that can be displayed on the LCD of the fire receiver RE or the like. It is. Then, the fire receiver RE needs to be able to handle these data, and when transmitting the data, the data is transmitted only to the fire receiver RE that can handle the data. For this purpose, the format of the data that can be displayed and whether or not information can be provided are registered in the property list as registration data of the fire receiver RE. For example, “text”, “HTML” (“moving picture”, “movie” If it is desired to provide the data to all the fire receivers RE, it is preferable to prepare data for text and data for HTML, respectively. In some cases, the area for providing information may be limited to an area. In this case, it is determined whether transmission is necessary based on the location of the property list.
[0069]
Then, the fire receiver RE that has received the data of the provided information displays the data on an LCD or the like (S44). In addition, in order to leave a title as a history of the received information data in the fire receiver RE, a storage area of a predetermined number of titles is set in the storage unit 13, for example. Then, only the title of the data displayed on the LCD or the like of the display operation unit 14 is stored in the storage unit 13 (S45). Here, the provided data may be stored in the storage unit 13 as it is, and in this case, re-display is facilitated by inputting an operation to the display operation unit 14.
[0070]
Next, the operation of searching for provided information in the above embodiment will be described.
[0071]
Saving the entire information provided to the storage unit 13 in order to redisplay the information requires a relatively large capacity of a flash memory or the like. However, when the manager of the fire receiver RE has information that he / she recognizes but wants to confirm, it is necessary to redisplay the information displayed in the past (S51). In this case, the customer service server 10 is accessed from the fire receiver RE via the Internet NW (S52), and after authentication using an ID and a password, the information stored in the LCD or the like of the display operation unit 14 is displayed. The titles are displayed in a list, one of them is designated, and a signal requesting the contents of the information to the customer service server 10 is transmitted (S53).
[0072]
Then, the customer service server 10 requested for the content of the information reads the designated information from the provided data stored in the storage device M2, for example (S54), and sends it to the fire receiver RE via the Internet NW. The information is transmitted (S55). The fire receiver RE that has received the information from the customer service server 10 displays the information on the LCD or the like of the display operation unit 14 (S56).
[0073]
When the title of the information that the administrator wants to refer to remains in the storage unit 13 in the fire receiver RE, the title of the information can be displayed. Limited by capacity. Therefore, it is conceivable that information that is temporally old is not left in the history. In this case, the display operation unit 14 of the fire receiver RE is operated, and the list of titles is transmitted to the customer service server via the Internet NW. 10 is requested (S57).
[0074]
Then, the customer service server 10 requested for the list of information reads the title of each information from the provided data in the storage device M2, and stores the list of information as a list via the Internet NW as a fire receiver. The message is transmitted to the RE (S58). The fire receiver RE that has received the list of information from the customer service server 10 displays the list of information on the LCD or the like of the display operation unit 14 (S59).
[0075]
Then, in the fire receiver RE, a list of titles is displayed on the LCD or the like of the display operation unit 14, one of them is designated, and a signal requesting the content of the information is transmitted to the customer service server 10 (S60). ), Past information can be referred to regardless of the history stored in the storage unit 13 (S54 to S66). Therefore, past information can be read from the customer service server 10 without leaving a history of the information provided in the storage unit 13 as a function of the fire receiver RE.
[0076]
Further, as described above, by returning to steps S53, S57, S59, etc. after the information is displayed, it is possible to call another information.
[0077]
[Panel creation operation]
FIG. 8 is a flowchart showing an operation of creating a board in the management company terminal device D1 in the above embodiment.
[0078]
In the board surface creation operation, for example, when an event occurs in a building and an alarm is issued with sound such as a failure, it is necessary to perform a corresponding operation such as stopping the sound or checking the device after viewing the displayed content. Usually, the manager appropriately responds, but an inexperienced person cannot take necessary measures, and the board of the fire receiver RE may become incomprehensible due to extra operations. In such a case, it is necessary to make an inquiry by telephone or the like to the designated inquiry destination, but it is difficult for the trader accepting the inquiry to accurately hear the state of the board of the fire receiver RE from an inexperienced manager. . In the above embodiment, in the above case, the trader who has received the inquiry specifies the property, and displays the board of the fire receiver RE on the management trader terminal device D1.
[0079]
For example, an inspection contractor performing a maintenance inspection can refer to the event log in order to grasp the status of the building of the maintenance contractor. In this case, the customer service server 10 is accessed using the terminal device D1 for the manager, and the event log of the contracted party is referred to.
[0080]
First, necessary operations are performed on the management company terminal device D1 (S61), and similarly to the above-described operations, the management company terminal device D1 accesses the customer service server 10 via the Internet NW (S62). Although not shown in detail, the necessity of a response is confirmed based on the ID and the password. Then, a property to be referred to is specified for the manager terminal device D1, and a request for board information is transmitted from the manager terminal device D1 to the customer service server 10 via the Internet NW (S63).
[0081]
Upon receiving the board information request, the customer service server 10 uses the ID of the trader as in the event log operation, for example, to determine whether the trader is registered in the property list registered in the storage device M1. Is checked and it is determined whether or not the user is qualified to refer to the board of the designated fire receiver RE (S64). If the above qualification can be confirmed, the fire receiver of the designated property is connected via the Internet NW. A request for information on the board state is transmitted to the RE (S65).
[0082]
Then, the customer service server 10 receiving the information on the board from the fire receiver RE that has received the request (S66, S67), for example, calculates the board information from the model of the fire receiver RE as the property data stored in the storage device M1. The basic image of the shape is read out, and according to the information on the state of the panel received from the fire receiver RE, specifically, the current state of the LCD display, the state of the switch, the state of turning on and off the indicator lamp, etc. A board image is created, and the data of the board image is transmitted to the management company terminal device D1 via the Internet NW (S68).
[0083]
The terminal device D1 for the management company that has received the board image displays the board image on a screen of a personal computer (S69). The trader who receives the inquiry replies an appropriate response to the manager such as telephone communication while referring to the board image in the manager terminal device D1.
[0084]
Note that such a board image changes from moment to moment due to occurrence of an event such as an operation by a manager or an increase in failure. For this reason, the fire receiver RE that has transmitted the information on the board state needs to transmit information to be updated to the customer service server 10 via the Internet NW in accordance with its own state change (S71). According to the information, the customer service server 10 transmits the board image, which has been updated anew, to the management company terminal device D1 via the Internet NW (S72). As a result, the terminal device D1 for the management company can display the board image of the fire receiver RE in near real time, and thereby can grasp whether or not the inexperienced manager has taken an accurate response. it can.
[0085]
The time until the update information is transmitted from the fire receiver RE in the above steps S71 and S72 is determined by the time when the recovery input is made on the panel of the fire receiver RE as a result of the elimination of the fire or the abnormality, or The display of the board surface in the device D1 becomes unnecessary, and the terminal device D1 may end the input.
[0086]
In addition, an update input is performed by the terminal device D1 for the manager, the input is transmitted to the fire receiver RE via the customer service server 10, and the fire receiver RE returns state information in the current state. Based on the returned status information, the customer service server 10 creates a new board state, transmits it to the management company terminal device D1, and displays it, thereby updating the board state with the latest information. .
[0087]
In the above-described embodiment, a basic image of the required board shape of the fire receiver RE is stored in the customer service server 10, and based on the board information from the fire receiver RE, the board state of the board is displayed in the customer service server 10. Although the information is created, the information of the board state may be created in the fire receiver RE by storing the basic image of the board shape in each fire receiver RE. The board state from the receiver RE may be transmitted to the management terminal apparatus D1 and displayed.
[0088]
In addition, the information on the board of the fire receiver RE required for creating such a board state is usually handled as an event, and is stored in the customer service server 10 by the event log function. The board state may be created using the information of the event log.
[0089]
[Database update operation]
FIG. 9 is a flowchart showing an operation of updating the database to the fire receiver RE and an operation of referring to the database in the above embodiment.
[0090]
Normally, when an automatic fire alarm system is installed in a building, various data necessary for the operation are stored as a database in the storage unit 13 so that the fire receiver RE can be monitored and controlled depending on the installation status. Is stored in
[0091]
Terminal data related to the type and location of installed terminal equipment including the fire detector S, interlocking data for interlock control of area sound and smoke prevention equipment not shown when the fire detector S detects a fire, and CRT, etc. Various data, such as map data for displaying a floor plan for each floor of the building, depending on the property and the model of the fire receiver RE are stored in the database.
[0092]
Such a database is often changed due to a change in the use of a building or an extension or renovation. In this database update operation, the customer service server 10 updates the database for each fire receiver RE connected via the Internet NW, and stores communication data in, for example, the storage unit 13 of the fire receiver RE. To do.
[0093]
When updating the database of the fire receiver RE from the customer service server 10 (S81), update data for updating the database is registered (S82), and the corresponding fire reception is received from the customer service server 10 via the Internet NW. The update data is transmitted to the device RE (S83).
[0094]
Then, the fire receiver RE that has received the update data indicates whether the received update data is correctly received, whether the received update data is its own database, or the like. Aside from the missing database, it is temporarily stored in the storage unit 13 for confirmation (S84). Then, the actually used database is rewritten by the checked update data (S85). This database is stored, for example, in a flash memory or the like serving as a storage unit 13. During monitoring of the fire receiver RE, the control unit 11 by a microcomputer (not shown) supplies power from the storage unit 13 to a RAM (not shown) or the like. Read and use at times.
[0095]
In this database update operation, the update data is temporarily stored in the flash memory, and after checking, the database in use is replaced. During this update work, there is no need to interrupt the monitoring operation of the fire receiver RE because data exists in the RAM (not shown). However, in order to perform the monitoring operation with the updated database, the data must be displayed. It is necessary to read data into a RAM that does not need to read the data, and the timing of the monitoring operation is checked, and the monitoring operation for reading is momentarily interrupted.
[0096]
Next, the operation of referring to the database when referring to the database from the dealer terminal device D1 will be described.
[0097]
It may be checked whether or not the database of the fire alarm device RE has been updated by the above-mentioned update operation. In some cases, a database currently used for creating update data may be referred to. Consider a case where the database is referred to from the terminal device D1.
[0098]
First, necessary operations are performed on the terminal device D1 for the management company (S91), and the customer service server 10 is accessed from the terminal device D1 for the management company via the Internet NW (S92). Here, although not shown in detail, the necessity of a response is confirmed by an ID or a password. Then, a property that refers to the database is specified to the terminal device D1 for the manager, and a request for the database is transmitted from the terminal device D1 for the manager to the customer service server 10 via the Internet NW (S93).
[0099]
The customer service server 10 that has received the request for the database uses the ID of the trader or the like as in the event log operation and determines whether the trader is registered in the property list registered in the storage device M1, for example. Investigation is performed to determine whether or not the user has a qualification (access right) for referring to the database of the designated fire receiver RE (S94). If the qualification can be confirmed, the Internet NW is sent to the fire receiver RE of the specified property. (S95).
[0100]
Then, the fire receiver RE that has received the request reads a database (not shown in detail) from the storage unit 13 and transmits the database to the customer service server 10 via the Internet NW (S96). The customer service server 10 that has received the database (S97) transmits the database to the manager terminal device D1 via the Internet NW (S98). Then, the management company terminal device D1 that has received the database stores the database in a storage device (not shown) and displays the database on a screen of a personal computer (S99).
[0101]
If the database received in this way is a minor modification such as a change in terminal name, the database can be modified on the spot and used as update data (S100), and the update data is transmitted to the customer service via the Internet NW. The data is transmitted to the server 10 (S101). With this transmission, the customer service server 10 receives the updated data (S102), and can use the updated data as the update data in step S83 in the database update operation. The database of the fire receiver RE is updated (S84, S85).
[0102]
The database in this operation is sent to the fire receiver RE of each building, and the customer service server 10 stores the database in the above operation in the storage device M2 or a separately prepared storage device as database data. Is also good. In this way, if it is a reference for updating the database, it is possible to save the trouble of receiving from the fire receiver RE, and at the same time, it becomes a so-called backup. Out of the information received from the fire receiver RE of No. 1 can be reduced.
[0103]
[Simulation operation in fire receiver RE]
FIG. 10 is a flowchart showing a simulation operation in the fire receiver RE in the above embodiment.
[0104]
This simulation operation is a function for simulating the operation of the fire receiver RE based on a preset scenario so that the manager can learn how to handle the fire receiver RE in the event of a fire or the like. During this simulation operation, the operation is performed only on the surface of the fire receiver RE, and various devices such as the fire detector S are in a normal monitoring state. Even if there is a display, the device remains in the normal state. Although not described in detail, when a real fire occurs during the simulation operation, the simulation operation is interrupted based on a fire signal from the fire detector S.
[0105]
When performing a simulation operation in the fire receiver RE, an operation input is performed using the display operation unit 14 of the fire receiver RE (S111), and the fire receiver RE transmits the information to the customer service server 10 via the Internet NW. After accessing (S112) and authenticating with an ID and a password as in the above operation, a request for a list of scenarios is requested to the customer service server 10 via the Internet NW (S113).
[0106]
Then, the customer service server 10 that has received the request for the list of scenarios (S114) reads, for example, items of each scenario from the scenario data stored in the storage device M1. Items of the scenario are items that can be assumed as examples, such as “when a fire occurs on the second floor”, “mischief of the transmitter on the first floor”, and “non-fire report on the third floor”. Various corresponding items are prepared, and a list of scenarios is transmitted to the fire receiver RE via the Internet NW (S115). Then, the fire receiver RE that has received the list of scenarios from the customer service server 10 displays the list of scenarios on the LCD or the like of the display operation unit 14 (S116).
[0107]
Then, in the fire receiver RE, one scenario is designated from a list displayed on the LCD or the like of the display operation unit 14, and the selected scenario is transmitted to the customer service server 10 (S117), thereby being selected. The received scenario is received from the customer service server 10, stored in the storage unit 13, and a simulation operation according to the scenario is performed (S118 to S120).
[0108]
By this simulation operation, various patterns of simulation operations can be executed as a simulation function of the fire receiver RE without setting a large number of scenarios in the storage unit 13. By registering, the number of scenarios can be enriched. Furthermore, since the removal of the familiarity and the update of the scenario in accordance with the latest trend can be executed in the customer service server 10, an optimal simulation operation can be realized.
[0109]
[Remote simulation operation]
FIG. 11 is a flowchart showing a remote simulation operation by the customer service server 10 in the above embodiment.
[0110]
This remote simulation operation is performed for the same purpose as the simulation operation by the fire receiver RE, and the simulation operation is started by manual operation of the display operation unit 14 on the panel of the fire receiver RE. In the case of the remote simulation operation by the customer service server 10, the remote simulation operation is started from the customer service server 10, so that it is performed without notice for the building management side.
[0111]
Based on the setting of the start time or the reception of the start information from a trader (not shown in detail), first, the customer service server 10 starts a remote simulation (S121), and for the object to be simulated, for example, a storage device. From the information of the M1 property list, one of a plurality of scenarios set so as to match the equipment status is selected (S122), and based on the selected scenario, it may occur sequentially. The assumed event is assumed to be a pseudo event, and the similar event is transmitted from the customer service server 10 to the target fire receiver RE via the Internet NW (S123).
[0112]
The fire receiver RE that has received the pseudo event from the customer service server 10 performs a so-called simulated event generation operation only on the board (S124). When the manager performs a predetermined operation in response to the occurrence of the pseudo event, the fire receiver RE stores the executed operation in the storage unit 13 and stores the contents in the customer service server 10 via the Internet NW. The content of the executed operation is transmitted to (S125). Actually, a pseudo event transmission operation from the customer service server 10 to the fire receiver RE is performed based on the timing set in the scenario, and the transmission is performed by an event, and a specific operation is performed on the fire receiver RE panel. There may be a timing after it.
[0113]
When all the events of the above-described scenario are completed and the end of the recovery or the like is reached, the fire receiver RE transmits the history of the entire simulation operation to the customer service server 10 via the Internet NW (S126). . The customer service server 10 receives the history and stores it in, for example, a predetermined area of the storage device M2 (S127).
[0114]
The history of the remote simulation is referred to to select a different scenario at the time of the remote simulation again.Although not explained in detail, a stakeholder such as a building owner checks the management status of the property. In this case, the history of the remote simulation can be used, and it can be grasped whether or not various events can be accurately handled.
[0115]
[Disaster prevention diagnosis operation]
FIG. 12 is a flowchart showing a disaster prevention diagnosis operation by the customer service server 10 in the above embodiment.
[0116]
In the disaster prevention diagnosis operation, when the automatic fire alarm system of the fire receiver RE connected to the Internet NW is of a so-called analog type, the analog level, which is the detection value of each installed fire detector S, is a fire level. From the analog information collected by the receivers RE and from the respective fire detectors S, it is possible to make a proposal for realizing a monitoring operation by a normal facility, such as predicting a failure. As in the case of the polling operation and the like, in the fire receiver RE to be subjected to this disaster prevention diagnosis operation, the necessity of the fire prevention diagnosis for the fire receiver RE together with its start time is stored in, for example, the storage device M1 as a property list. It is registered.
[0117]
First, at the start time of the disaster prevention diagnosis registered in the property list (S131), the call destination of the fire receiver RE is read from the property list, and a request for analog information is transmitted (S132). Here, the start time of the disaster prevention diagnosis can be usually once a day or once every several hours, and is registered as what day of the week what time. Each time the disaster prevention diagnosis is started, the next start date and time may be calculated and updated according to the set interval. If this interval is shortened, detailed data such as comparison for each time can be created. If the analog information does not fluctuate greatly and it is a stable property, it is not necessary to create so detailed data, the interval is lengthened, the load on the customer service server 10 is reduced, and rough data is sufficient.
[0118]
Then, the fire receiver RE that has received the start of the disaster prevention diagnosis reads out the latest analog information stored in the storage unit 13 and transmits it to the customer service server 10 via the Internet NW, although not described in detail ( S133).
[0119]
The customer service server 10 that has received the analog information from the fire receiver RE stores the analog information data as a database in, for example, the storage device M2 (S134). Then, the analog information for the past stored in the storage device M2 is read (S135), and based on the read analog information, a malfunction of the equipment status or a prediction thereof is determined (S136). Regarding this determination, for example, the analog value of the smoke detector is gradually increasing, which may cause a false alarm, or the analog value may increase at any time or at a specific time, and the fire level (or pre-alarm level) may increase. If the difference is small, it is determined that the installation position of the smoke detector needs to be reviewed or the sensitivity setting needs to be changed. This determination is performed in the customer service server 10 by performing arithmetic processing, setting conditions such as inconveniences, and determining whether or not the set conditions are met.
[0120]
Then, if there is any judgment item as a result of the disaster prevention diagnosis, the customer service server 10 registers the contact information of each fire receiver RE in the property list, as in the case of the automatic test operation, and The result of the disaster prevention diagnosis is notified to the contact (S137).
[0121]
In each of the above operations, the customer service server 10 stores various information such as event log information, a result of a polling operation, a result of an automatic test function, a result of a simulation operation, and the like as information on the fire receiver EE of each building. However, the related trader can refer to necessary information at any time by connecting the management trader's terminal device D1 and requesting information via the Internet NW. Then, by registering the terminal device D1 for the trader or the management trader related to the customer service server 10 and setting the relation with each building, various information including the trader is transmitted to the unrelated trader. There is no.
[0122]
As described above, the fire receivers RE of the plurality of properties, the terminal device D1 for the management company used by the plurality of companies, and the customer service server 10 are connected as one network by the Internet NW, and each of the fire receivers RE Transmits / receives signals only to / from the customer service server 10, and each management company terminal device D1 obtains information on each fire receiver RE from the customer service server 10 to determine which fire receiver RE Can be easily used even in the communication setting of each fire receiver RE. There is a number of advantages, such as a single destination can be set as the customer service server 10 and the management of information transmitted to the Internet NW can be comprehensively managed by the customer service server 10.
[0123]
In the above embodiment, the Internet NW is used as a network. However, the customer service server 10 is mainly used, and each fire receiver RE and the management company terminal device D1 are dial-up or the like as necessary. The connection may be in the form of so-called personal computer communication. Further, on the network, it is necessary to sufficiently distinguish each of the fire receiver RE, the customer service server 10, and the terminal device D1 for the management company as terminals, so that information transmission and reception are not performed with irrelevant terminals. It is necessary to perform various restrictions such as ID and password management.
[0124]
【The invention's effect】
According to the invention described in claims 1 to 3, the customer service server accesses the fire receiver of each building via the network, confirms that the fire fighting equipment is functioning, stores the information, and stores the information as necessary. There is an effect that it can be referred to in response.
[0125]
According to the fourth and fifth aspects of the present invention, the customer service server can collect events generated in the fire receiver of each building via the network and reduce the capacity of the storage unit of the fire receiver of each building. In addition, it is possible to refer to the event history from the customer service server when necessary without going to each building.
[0126]
According to the sixth and seventh aspects of the present invention, the customer service server can execute the automatic test function via the network, and can save the trouble of operating the fire receiver in each building.
[0127]
According to the invention as set forth in claims 8 to 11, the customer service server creates the board status of the fire receiver by collecting information from the fire receiver of each building via the network. By receiving the board state from the customer service server, it is possible to refer to the board of the fire receiver without going to the building.
[0128]
According to the invention of claims 12 to 14, there is an effect that the customer service server can display the content to be notified to the fire receiver of each building via the network.
[0129]
According to the invention of claims 15 and 16, it is not necessary to store the procedure of the simulation function in the fire receiver of each building, the capacity of the storage unit can be reduced, and the work history can be stored. This produces an effect that the procedure of the simulation function can be easily updated.
[0130]
According to the invention of claims 17 to 20, the fire receiver of each building may transmit and receive information via the network only to the customer service server, so that the communication destination can be limited. In addition, the related service provider can refer to the information of the fire receiver without going to each building, so that it is not necessary to make a communication connection to the fire receiver of each building each time it becomes necessary. The effect is sufficient if it can be connected to.
[Brief description of the drawings]
FIG. 1 is a diagram showing a remote monitoring system 100 for an automatic fire alarm system according to a first embodiment of the present invention.
FIG. 2 is a block circuit diagram schematically showing a configuration of a fire receiver RE with a terminal function.
FIG. 3 is a flowchart showing a polling operation executed by the customer service server 10 in the embodiment.
FIG. 4 is a flowchart showing an event log operation and an operation of referring to an event log performed to the customer service server 10 in the embodiment.
FIG. 5 is a flowchart showing an automatic test operation by the customer service server 10 in the embodiment.
FIG. 6 is a flowchart showing an operation in which the customer service server 10 provides information in the embodiment.
FIG. 7 is a flowchart showing an operation in which the customer service server 10 provides information in the embodiment.
FIG. 8 is a flowchart illustrating an operation of creating a board in the dealer terminal device D1 in the embodiment.
FIG. 9 is a flowchart showing an operation of updating the database to the fire receiver RE and an operation of referring to the database in the embodiment.
FIG. 10 is a flowchart showing a simulation operation in the fire receiver RE in the embodiment.
FIG. 11 is a flowchart showing a remote simulation operation by the customer service server 10 in the embodiment.
FIG. 12 is a flowchart showing a disaster prevention diagnosis operation by the customer service server 10 in the embodiment.
[Explanation of symbols]
100 Remote monitoring system for automatic fire alarm
10. Customer service server,
M1, M2 ... storage devices,
D1 ... Terminal device for management company,
RE… Fire receiver,
11 ... control unit,
12 Terminal monitoring unit
13 ... storage unit,
14 display operation unit,
15 Communication unit,
S: Fire detector,
L: signal line,
NW ... Internet.

Claims (20)

In a system in which a fire receiver of a plurality of properties and a customer service server for managing the plurality of properties are connected to a network,
The customer service server,
Registration means for registering each of the above fire receivers;
Calling signal transmitting means for transmitting a calling signal for sequentially calling each of the fire receivers to the network;
Call result storage means for storing a response result from the fire receiver that is the destination of the call signal;
A remote monitoring system for an automatic fire alarm system, comprising: In claim 1,
When receiving the call signal, the fire receiver returns a normal monitoring signal to the customer service server if normal, and if the fire receiver has abnormal information, transmits the abnormal information signal to the customer service server. A remote monitoring system for an automatic fire alarm system, characterized by having a reply means for replying to a server. In claim 1,
The customer service server, when receiving the normal monitoring signal or the abnormal information signal from the fire receiver that has transmitted the calling signal, transmits the received normal monitoring signal or abnormal information signal as the response result. If the normal monitoring signal or the abnormal information signal is not received within a predetermined time after sending the calling signal, no response is returned as the response result to the calling result storing means. A remote monitoring system for automatic fire alarm equipment, which is stored. In a system in which a fire receiver of a plurality of properties and a customer service server for managing the plurality of properties are connected to a network,
The fire receiver, when an event occurs in the fire receiver, via the network, an event information signal indicating information of the event, an event information signal transmission means for transmitting to the customer service server,
Upon receiving the event information, the customer service server stores, in an event log means, information indicating a fire receiver in which the event has occurred and the event information signal. Monitoring system. In claim 4,
A trader terminal used by a trader is connected to the network as a terminal device of the network constituting the system,
The customer service server
When a log request signal specifying one or more of a plurality of fire receivers is received from the trader terminal via the network, the specified fire received from the trader terminal is received from the trader registration means for registering the trader. Determining means for determining whether the receiver is in charge of the property of the receiver;
Extracting means for extracting the event information of the specified fire receiver from the event log means when the trader is in charge;
Event information returning means for returning event information to the trader terminal;
A remote monitoring system for an automatic fire alarm system, comprising: In a system in which a fire receiver of a plurality of properties and a customer service server for managing the plurality of properties are connected to a network,
The customer service server,
Registration means for registering each of the above fire receivers;
Transmitting means for transmitting an inspection start signal to the network at an inspection time corresponding to each of the fire receivers;
Inspection result storage means for storing the inspection result received from the fire receiver which has transmitted the inspection start signal;
Notifying means for notifying a contact registered for each of the fire receivers when the inspection result is abnormal;
A remote monitoring system for an automatic fire alarm system, comprising: In claim 6,
The fire receiver receiving the inspection start signal activates an automatic inspection function, obtains the result, and has an inspection result signal returning means for returning an inspection result signal for returning the inspection result to the customer service server. A remote monitoring system for automatic fire alarms. In a system in which a fire receiver of a plurality of properties and a customer service server for managing the plurality of properties are connected to a network,
The customer service server,
Registration means for registering information relating to the board of each of the above fire receivers;
Transmitting means for transmitting a status information request signal to any of the fire receivers via the network;
State creating means for creating a state of the fire receiver panel based on the state information returned from the fire receiver that has received the state information request signal and information on the relevant fire receiver panel;
A remote monitoring system for an automatic fire alarm system, comprising: In claim 8,
An automatic fire alarm system, wherein the fire receiver having received the status information request signal has a return means for returning a status information return signal for returning information on the current operation status of the fire receiver to the customer service server. Remote monitoring system. In claim 8 or claim 9,
A trader terminal used by a trader is connected to the network as a terminal device of the network constituting the system,
The remote monitoring system for an automatic fire alarm system, wherein the customer service server sends the state of the board by the state creating means to a trader terminal serving as a necessary contact for the relevant fire receiver. In any one of claims 8 to 10,
A remote monitoring system for an automatic fire alarm system, wherein the state of the panel is image information. In a system in which a fire receiver of a plurality of properties and a customer service server for managing the plurality of properties are connected to a network,
The customer service server,
Registration means for registering display information of at least one of a message, an image, and a moving image that can be displayed on the display unit of the fire receiver;
Transmitting means for transmitting the display information to each of the fire receivers via the network;
A remote monitoring system for an automatic fire alarm system, comprising: In claim 12,
A remote monitoring system for an automatic fire alarm system, wherein the fire receiver receiving the display information displays the display information on a display unit of the fire receiver during normal monitoring in which no fire or the like has occurred. . In claim 12,
The customer service server, when receiving a request signal for display information from the fire receiver, transmits the designated display information to the requested fire receiver. system. In a system in which a fire receiver of a plurality of properties and a customer service server for managing the plurality of properties are connected to a network,
The customer service server,
Transmitting means for transmitting the simulated operation signal to at least one of the fire receivers via the network;
Simulated operation storage means for receiving and storing information on the panel operation of the fire receiver from the fire receiver that has transmitted the simulated operation signal;
A remote monitoring system for an automatic fire alarm system, comprising: In claim 15,
The fire receiver that has received the simulated operation signal performs an operation based on the simulated operation information received thereafter, and returns information to the panel operation of the fire receiver to the customer service server. Monitoring system for automatic fire alarm system. In a system in which a fire receiver of a plurality of properties, a trader terminal used by a plurality of traders, and a customer service server managing the plurality of properties and the plurality of traders are connected to one network,
Each of the fire receivers transmits and receives signals only to the customer service server,
The customer service server collects and stores various information by transmitting and receiving signals to and from each of the fire receivers,
Further, each of the trader terminals acquires the above-mentioned various information of each of the fire receivers from the customer service server. In claim 17,
The remote monitoring system for an automatic fire alarm system, wherein the network is the Internet. In claim 17 or claim 18,
A remote monitoring system for an automatic fire alarm system, wherein the customer service server discriminates each of the vendor terminals that can use the various information for each of the fire receivers. In any one of claims 17 to 19,
The remote monitoring system for an automatic fire alarm system, wherein the various information is one or a combination of a polling call result, an event log, an automatic test result, a board state, and a simulation operation result by simulation.

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