JP7360796B2 - How to correct status confirmation identifier of fire alarm system and fire alarm terminal - Google Patents

Description

The present invention relates to a fire alarm system and a method for correcting a status confirmation identifier of a fire alarm terminal.

BACKGROUND ART Fire alarm systems are conventionally known in which a plurality of smoke detectors, heat detectors, transmitters, etc. are installed as fire alarm terminals, and fire is detected and notified based on sensed information from these fire alarm terminals.

The following configurations are known as conventional fire alarm systems.

A fire alarm terminal such as a smoke detector, a heat detector, or a transmitter is connected to a receiver having a display section, and the sensing information of the fire alarm terminal is sent to the receiver, and the sensing information is aggregated and received. It was configured to be displayed on the machine's display.

The supervisor monitors fires and the like based on the sensing information displayed on the display section of the receiver.

Conventional fire alarm systems have the following problems.

JP 2017-116973 Publication Japanese Patent Application Publication No. 5-298588

In conventional fire alarm systems, during the system installation process, individual identifiers (addresses) are set for each fire alarm terminal, such as smoke detectors, heat detectors, and transmitters, in order to identify each fire alarm terminal. was.

Normally, the address of each fire alarm terminal is set using a dedicated address setting device for each fire alarm terminal during the installation process of the system, before each fire alarm terminal is wired. In other words, the installer sets the address of each fire alarm terminal using a dedicated address setting device based on the setting diagram of each fire alarm terminal, and then installs and wires the sensor with the address set. I was about to go.

However, in this case, the installation position of the fire alarm terminal may be mistaken, resulting in an incorrect address of the wired fire alarm terminal. Here, an address error means that a fire alarm terminal with a different address is installed at the address position where it should originally be installed based on the setting diagram of each fire alarm terminal.

The connection of each fire alarm terminal to the transmission line can be confirmed by using the address confirmation function built into the receiver, or by installing a simulated device ( simulator) to check the connection of each fire alarm terminal to the transmission line.

However, when checking the connection of each fire alarm terminal to the transmission line using a receiver or simulation device, the connection confirmation of each individual system (for example, the fire alarm terminal system on each floor) is displayed, and then the display switches to the next display. It was in the form of confirmation. Therefore, it is not possible to instantly check the connections of all fire alarm terminals, and there is a problem in that checking takes time and may be overlooked.

In addition, after setting the addresses of multiple fire alarm terminals, if the address of a specific fire alarm terminal needs to be corrected due to a mistake in the address of a sensor, etc., the receiver or simulation device It was not possible to correct only the address of the fire alarm terminal. Therefore, if the address of a specific fire alarm terminal must be corrected, that specific fire alarm terminal must be removed from the transmission line, and the address correction must be made for the removed specific fire alarm terminal. Ta.

The present invention has been made in view of the above problems, and its purpose is to provide a fire alarm system that can easily check the connection status of all fire alarm terminals and address duplication, and to check the status of fire alarm terminals. An object of the present invention is to provide an identifier correction method.

Another object of the present invention is to provide a fire alarm system and a fire alarm terminal status confirmation identifier correction method that can easily detect a wrong address of a fire alarm terminal and correct the address of a specific fire alarm terminal. That's true.

A first invention includes a plurality of fire alarm terminals each having an identifier and detecting sensing information related to a fire, and a receiver connected to the fire alarm terminal for receiving and displaying sensing information from the fire alarm terminal. a simulating device connected to the fire alarm terminal to detect a state of the fire alarm terminal corresponding to the identifier; and a simulating device wirelessly communicating with the simulating device; and a mobile terminal that displays the status of the fire alarm terminal corresponding to the identifier.

A second invention is that in the fire alarm system according to the first invention, the mobile terminal displays a list of states of the fire alarm terminals detected by the simulator in order of identifiers.

A third invention is that in the fire alarm system according to the second invention, the state of the fire alarm terminal is a connected state of the fire alarm terminal.

A fourth invention is that in the fire alarm system according to the second invention, the state of the fire alarm terminal is a duplicate of the identifier of the fire alarm terminal.

In a fifth invention, in the fire alarm system according to the first invention, the fire alarm terminal has display means for displaying respective operating states, and the mobile terminal wirelessly communicates with the simulating device. and transmits a display instruction to display the display means of the fire alarm terminal according to the identifier of the fire alarm terminal to the simulation device, and the simulation device displays the identifier of the fire alarm terminal according to the display instruction from the mobile terminal. Accordingly, the display means of the fire alarm terminal is displayed.

A sixth invention is the fire alarm system according to the fifth invention, in which the identifier of the fire alarm terminal is set to a predetermined setting based on the display by the display means of the fire alarm terminal according to the identifier of the fire alarm terminal. What is different is to be detected.

A seventh invention is the fire alarm system according to the sixth invention, wherein the simulator corrects an identifier that is different from a predetermined setting of the fire alarm terminal based on a correction instruction from the mobile terminal. It is.

An eighth invention is the fire alarm system according to the fourth invention, in which the simulator corrects a duplicate identifier of the fire alarm terminal based on an instruction from the mobile terminal.

A ninth invention is the fire alarm system according to any one of the first to eighth inventions, wherein the receiver is not connected to the fire alarm terminal.

A tenth invention is the fire alarm system according to any one of the first to ninth inventions, in which the display means of the fire alarm terminal comprises lights for displaying respective operating states.

An eleventh invention provides a plurality of fire alarm terminals each having an identifier and detecting sensed information related to a fire, and a receiver connected to the fire alarm terminal for receiving and displaying sensed information from the fire alarm terminal. a simulator connected to the fire alarm terminal for confirming and correcting an identifier of the fire alarm terminal; and a mobile terminal that displays the status of the identifier of the fire alarm terminal, and the fire alarm terminal has a display means that displays the operating status of each, and the mobile terminal displays the display according to the identifier of the fire alarm terminal. A display instruction for displaying the means is transmitted to the simulating device, and the simulating device displays the display means according to the identifier of the fire alarm terminal according to the display instruction from the mobile terminal, and the simulating device displays the display means according to the identifier of the fire alarm terminal. It is detected that the identifier of the fire alarm terminal is different from the predetermined setting based on the display by the display means of the fire alarm terminal, and if the identifier of the fire alarm terminal is different from the predetermined setting, the The mobile terminal instructs the simulation device to correct the identifier that is different from the predetermined setting, and the simulation device corrects the identifier that is different from the predetermined setting based on the correction instruction from the mobile terminal. The purpose is to correct the existing identifier.

A twelfth invention is that in the fire alarm system according to the eleventh invention, the receiver is not connected to the fire alarm terminal.

A thirteenth invention is that in the fire alarm system according to either the eleventh or twelfth invention, the display means of the fire alarm terminal comprises lights for displaying respective operating states.

A fourteenth invention provides a plurality of fire alarm terminals each having an identifier and detecting sensed information related to a fire, and a receiver connected to the fire alarm terminal for receiving and displaying sensed information from the fire alarm terminal. A method for correcting a status confirmation identifier of a fire alarm terminal in a fire alarm system having a fire alarm terminal, a simulation device connected to the fire alarm terminal, and a mobile terminal wirelessly communicating with the simulation device, the method comprising: a step of detecting the state of the fire alarm terminal corresponding to the identifier; a step of transmitting information on the state of the fire alarm terminal to the mobile terminal by the simulation device; and a step of detecting the state of the fire alarm terminal corresponding to the identifier; and displaying a list of states of the fire alarm terminals in order of their identifiers.

A fifteenth invention provides a plurality of fire alarm terminals each having an identifier and detecting sensed information related to a fire, and a receiver connected to the fire alarm terminal for receiving and displaying sensed information from the fire alarm terminal. a simulator connected to the fire alarm terminal, and a mobile terminal wirelessly communicating with the simulator, and the fire alarm terminal has a display means for displaying the operating status of each of the fire alarm systems. A method for correcting a status confirmation identifier of a fire alarm terminal, the method comprising: transmitting a display instruction from the mobile terminal to the simulation device to display a display means of the fire alarm terminal according to an identifier of the fire alarm terminal; a step of displaying the display means of the fire alarm terminal according to the identifier of the fire alarm terminal by the device based on a display instruction from the mobile terminal; and displaying the fire alarm terminal according to the identifier of the fire alarm terminal. detecting that the identifier of the fire alarm terminal is different from a predetermined setting based on an indication by the means; , a step in which a correction instruction is given to the simulation device to correct the identifier that is different from the predetermined setting; and correcting the identifier.

According to the present invention, the connection status of all fire alarm terminals and address duplication can be easily confirmed, and the address of a specific fire alarm terminal can be corrected.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an explanatory diagram of an embodiment of a fire alarm system according to the present invention. FIG. 2 is an explanatory diagram after the installation of the fire alarm system 1 shown in FIG. 1 is completed. 2 is a schematic internal circuit block diagram of a fire alarm terminal connected to the sensor transmission line shown in FIG. 1. FIG. FIG. 2 is an explanatory diagram of the simulator 35 shown in FIG. 1, in which (a) is an internal configuration diagram of the simulator 35, and (b) is a configuration diagram of its control section 35b. 2 is an explanatory diagram of the mobile terminal 9 shown in FIG. 1, in which (a) is an internal configuration diagram of the mobile terminal 9, and (b) is a configuration diagram of its control unit 9a. FIG. 2 is a flowchart of a first operation of detecting and displaying connection states of fire alarm terminals corresponding to identifiers and identifier duplication in the fire alarm system 1 shown in FIG. 1. FIG. 2 is an explanatory diagram showing a signal communication sequence between the mobile terminal 9, the simulator 35, and the fire alarm terminal in the first operation of the fire alarm system 1 shown in FIG. 1. FIG. FIG. 7 is an explanatory diagram of the display screen of the display unit 9b of the mobile terminal 9 in the first operation. FIG. 7 is an explanatory diagram of the display screen of the display unit 9b of the mobile terminal 9 in the first operation. FIG. 7 is an explanatory diagram of the display screen of the display unit 9b of the mobile terminal 9 in the first operation. It is a flowchart of the 2nd operation|movement of confirming the identifier of the fire alarm terminal in the fire alarm system 1 shown in FIG. 1, and correcting a wrong identifier. 2 is an explanatory diagram showing a signal communication sequence between the mobile terminal 9, the simulator 35, and the fire alarm terminal in a second operation of the fire alarm system 1 shown in FIG. 1. FIG. FIG. 7 is an explanatory diagram of the display screen of the display unit 9b of the mobile terminal 9 in the second operation. FIG. 7 is an explanatory diagram of the display screen of the display unit 9b of the mobile terminal 9 in the second operation. FIG. 7 is an explanatory diagram of the display screen of the display unit 9b of the mobile terminal 9 in the second operation. FIG. 7 is an explanatory diagram of the display screen of the display unit 9b of the mobile terminal 9 in the second operation. FIG. 7 is an explanatory diagram of the display screen of the display unit 9b of the mobile terminal 9 in the second operation. FIG. 7 is an explanatory diagram of the display screen of the display unit 9b of the mobile terminal 9 in the second operation. FIG. 7 is an explanatory diagram of the display screen of the display unit 9b of the mobile terminal 9 in the second operation. FIG. 7 is an explanatory diagram of the display screen of the display unit 9b of the mobile terminal 9 in the second operation. 2 is an explanatory diagram showing a signal communication sequence between the mobile terminal 9, the simulator 35, and the fire alarm terminal in a second operation of the fire alarm system 1 shown in FIG. 1. FIG. FIG. 7 is an explanatory diagram of the display screen of the display unit 9b of the mobile terminal 9 in the second operation. FIG. 7 is an explanatory diagram of the display screen of the display unit 9b of the mobile terminal 9 in the second operation.

Hereinafter, one embodiment of the present invention will be described with reference to the drawings.

A feature of the present invention is that the status confirmation identifier correction operation of each fire alarm terminal such as a smoke detector, a heat sensor, and a transmitter in a fire alarm system is performed by a simulator using a mobile terminal.

In particular, the builder uses a mobile terminal to perform the operation of correcting the status confirmation identifier of each fire alarm terminal in a state before the receiver is connected during the installation of the fire alarm system.

To explain in more detail, the fire alarm terminal status confirmation identifier correction operation is performed by a simulator, through a mobile terminal that wirelessly communicates with the simulator, to detect a fire alarm corresponding to the identifier of each fire alarm terminal. An operation in which the condition of the terminal is detected, the builder displays a list of the statuses of the fire alarm terminals corresponding to the identifiers on the mobile terminal in the order of the identifiers, and then the builder corrects the predetermined identifier using the mobile terminal. becomes.

Here, the status check identifier correction operation can be roughly divided into the first operation (Figs. 6 to 10) that detects and displays the connection status of the fire alarm terminal corresponding to the identifier and the duplication of the identifier, and the first operation that detects and displays the connection state of the fire alarm terminal corresponding to the identifier and and a second operation (FIGS. 11 to 23) of confirming the identifier and correcting the incorrect identifier.
The identifier of each fire alarm terminal consists of an address assigned to each fire alarm terminal.

First, a fire alarm system after installation will be described, and then an embodiment of the fire alarm system according to the present invention will be described in detail, in which a simulator performs a state check identifier correction operation for each fire alarm terminal.

FIG. 2 is an explanatory diagram after installation of the embodiment of the fire alarm system according to the present invention shown in FIG. 1 is completed.

As shown in FIG. 2, a sensor transmission line 13 is connected to the receiver 3, and a smoke detector 19, a thermocouple detection 21, an address adapter 23, a smoke detector 25, a heat detector 29, a transmitter with an address 31-1, a transmitter for connecting an address adapter 31-2, and other fire alarm terminals are connected.

Smoke detector 19, heat detector 29, smoke detector 25, and address transmitter 31-1 are each provided with LED lights 19a, 25a, 29a, and 31a for indicating their operating states.

In addition, in FIG. 2, only some fire alarm terminals are shown, and a large number of general type (without addresses) fire alarm terminals are connected to the address adapter connection transmitter 31-2. There is. Furthermore, a fire alarm terminal with an address is connected to the address transmitter 31-1 and the address adapter 23.

Note that the address transmitter 31-1 and the address adapter connection transmitter 31-2 are connected by a telephone line 31-3, and the telephone line 31-3 is connected to the receiver 3.

FIG. 1 is an explanatory diagram of an embodiment of a fire alarm system according to the present invention.

As shown in FIG. 1, the fire alarm system 1 according to this embodiment is in the middle of installation, the receiver 3 is not yet connected to the sensor transmission line 13, and the simulator 35 is installed in the isolator 15a. It is installed as a simulator and is connected to the sensor transmission line 13a as described later.

As shown in FIG. 1, the isolator 15a is connected to a smoke detector 19, a heat sensor 29, a smoke detector 25, a transmitter with an address 31-1, and a transmitter for connecting an address adapter via a sensor transmission line 13a. A fire alarm terminal such as 31-2 is connected. Further, fire alarm terminals such as a smoke detector 19, a thermocouple detector 21, an address adapter 23, and a general detector 25 are connected via the sensor transmission line 13b of the isolator 15b.

The smoke detector 19, the smoke detector 25, the heat detector 29, and the address transmitter 31-1 are each provided with LED lights (display means) 19a, 25a, 29a, and 31a to notify the operating status thereof. It is being

The LED lights 19a, 25a, 29a, and 31a are also used to confirm the addresses of the smoke detector 19, the smoke detector 25, the heat sensor 29, and the address transmitter 31-1, as will be described later.

Note that FIG. 1 also shows only some of the fire alarm terminals, and a large number of fire alarm terminals are connected to the end of the address adapter connection transmitter 31-2.

FIG. 3 is a schematic internal circuit block diagram of a fire alarm terminal connected to a sensor transmission line. FIG. 3 shows the internal circuitry of the smoke detector 25 connected to the simulator 35 via the sensor transmission line 13a.

As shown in FIG. 3, the smoke detector 25 includes a communication section 25b that receives a communication signal from the sensor transmission line 13a and performs modulation/demodulation, and a communication section 25b that receives a communication signal from the sensor transmission line 13a and supplies power for internal use by receiving power from the sensor transmission line 13a. a control section 25d that performs overall control according to the communication content, a detection section 25e that detects fire elements such as heat and smoke, and an address storage section that stores its own address (identifier) used in communication. 25f, and the above-mentioned LED light 25a is connected to the control section 25d.

Then, the control unit 25d controls the LED light 25a to turn on based on the address confirmation signal from the simulator 35, and also controls the address stored in the address storage unit 25f based on the address correction signal from the simulator 35. control to rewrite and correct.

Note that the internal circuit configurations of the smoke detector 19 other than the smoke detector 25, the heat sensor 29, the address transmitter 31-1, the address adapter 23, the thermocouple detector 21, etc. are also the same as the internal configuration shown in FIG. It is almost the same as

In this embodiment, the address of each fire alarm terminal is set using a dedicated address setting device for each fire alarm terminal before wiring of each fire alarm terminal. In other words, the installer sets the address of each fire alarm terminal using a dedicated address setting device based on the setting diagram of each fire alarm terminal, and the installer transmits the sensor to which the address has been set. It is installed and wired to line 13a.

This simulator 35 detects and displays the connection status and identifier duplication of fire alarm terminals such as the smoke detector 19, heat sensor 29, and address transmitter 31-1 connected to the sensor transmission line 13a. This operation and the second operation of checking the identifier of the fire alarm terminal and correcting an incorrect identifier are controlled by the mobile terminal 9 held by the installer 11, as will be described later.

In this embodiment, the simulator 35 is installed within the isolator 15a, but the simulator 35 is not limited to installation within the isolator 15a, and may be installed anywhere as long as the simulator 35 is connected to the sensor transmission line 13a.

FIG. 4 is an explanatory diagram of the simulator 35, in which (a) is an internal configuration diagram of the simulator 35, and (b) is a configuration diagram of its control section 35b.

As shown in FIG. 4(a), in this embodiment, the simulator 35 is installed in the isolator 15a, and has a sensor communication section 35a connected to the sensor transmission line 13a, and a sensor communication section 35a connected to the sensor communication section 35a. a wireless transmitting/receiving section 35c connected to the controlling section 35b, and a power source section 35d for supplying power to the sensor communicating section 35a, the controlling section 35b, and the wireless transmitting/receiving section 35c. 35d is designed to be powered by USB.

Note that power may be supplied to the power supply section 35d by other methods such as an AC power source or a battery.

Further, as shown in FIG. 4(b), the control unit 35b includes a CPU 35b1, a RAM 35b3, and a ROM (non-volatile memory) 35b5. The first program for detecting and displaying the fire alarm terminal and the second operation for checking the identifier of the fire alarm terminal and correcting the wrong identifier are downloaded and stored, and can be downloaded and stored on a mobile terminal by the installer, etc. a first operation of detecting and displaying the connection status of the fire alarm terminal and the duplication of identifiers based on the instruction input through the computer 9 and the first program thereof; and checking the identifier of the fire alarm terminal and correcting the wrong identifier; The second operation is performed by the CPU 35b1.

Note that the application software consisting of the first program described above may be stored in the ROM 35b5 in advance, or may be imported into the RAM 35b3 from the Internet through a specific authentication.

The detailed operation of the simulator 35 will be explained in detail later along with the status confirmation identifier correction method.

Next, the mobile terminal 9 carried and used by the constructor 11 will be described.

In this embodiment, the mobile terminal 9 is a general smartphone or tablet terminal that has a wireless communication function with the wireless transmitter/receiver 35c of the simulator 35, and also has a telephone call function, a communication function via the Internet, and the like.

Note that the mobile terminal 9 may be connected by a wired communication function such as a USB using the wireless transmitter/receiver 35c of the simulator 35 as a wired transmitter/receiver.

FIG. 5 is an explanatory diagram of the mobile terminal 9, in which (a) is an internal configuration diagram of the mobile terminal 9, and (b) is a configuration diagram of its control section 9a.

As shown in FIG. 5A, the mobile terminal 9 includes a control section 9a for controlling the entire terminal including display operations of sensing information, etc., which will be described later, and a control section 9a for displaying display information from the control section 9a. A display section 9b consisting of a liquid crystal screen connected to the simulator 35, a transmitting/receiving section 9c for transmitting and receiving display information etc. to the wireless transmitting/receiving section 35c of the simulator 35, and a transmitting/receiving section 9c connected to the control section 9a for supplying power to the control section 9a. It has a power supply section 9d and a power storage section 9e. Here, the configuration of the display section 9b is not limited to a liquid crystal screen, but may be any other device capable of displaying display information, such as an organic EL screen.

Note that when the wireless transmitter/receiver 35c of the simulator 35 is a wired transmitter/receiver, the transmitter/receiver 9c for transmitting and receiving may be connected with a wired communication function.

Further, as shown in FIG. 5(b), the control unit 9a has a CPU 9a1, a RAM 9a3, and a ROM (non-volatile memory) 9a5. A second program for performing the first operation of detecting and displaying the fire alarm terminal and the second operation of checking the fire alarm terminal's identifier and correcting the incorrect identifier is downloaded and stored, and the second program Based on this, the first operation and the second operation are performed by the CPU 9a1 in cooperation with the simulator 35.

Note that the application software consisting of the second program described above may be stored in the ROM 9a5 in advance, or may be imported into the RAM 9a3 from the Internet through a specific authentication.

Next, with reference to FIGS. 6 to 10, a method for checking the status of a fire alarm terminal in the fire alarm system 1 shown in FIG. ) will be explained.

FIG. 6 is a flowchart of the first operation of detecting and displaying the connection state of the fire alarm terminal corresponding to the identifier and the duplication of the identifier in the fire alarm system 1 shown in FIG. 8 to 10 are explanatory diagrams showing a signal communication sequence between the mobile terminal 9, the simulator 35, and the fire alarm terminal in the first operation of the fire alarm system 1, and FIGS. 8 to 10 show the display of the mobile terminal 9 in the first operation. It is an explanatory view of a display screen of section 9b.

In addition, in the fire alarm system 1 shown in FIG. 1, the state confirmation of the fire alarm terminal is performed by a fire alarm terminal scanning operation performed by the installer 11 following instructions input to the mobile terminal 9 wirelessly connected to the simulator 35. .

In step 101 of FIG. 6, a scanning operation consisting of checking the status of the fire alarm terminals connected to the sensor transmission line 13a is performed in address order.

That is, first, while the transmitting/receiving unit 9c of the mobile terminal 9 held by the constructor 11 is performing wireless communication with the wireless transmitting/receiving unit 35c of the simulator 35, the second program is run on the mobile terminal 9, and as shown in FIG. As shown in FIG. 8(a), an operation mode selection screen is displayed on the display section 9b of the mobile terminal 9.

That is, the CPU 9a1 of the mobile terminal 9 causes the display unit 9b to display an operation mode selection screen as shown in FIG. 8A on the display unit 9b based on the second program stored in the RAM 9a3.

Then, as shown in FIG. 8(a), when the installer 11 presses the confirmation button 9b1 on the operation mode selection screen, an address confirmation screen in order of addresses as shown in FIG. 8(b) is displayed on the mobile terminal 9. is displayed on the display section 9b.

That is, the CPU 9a1 of the mobile terminal 9 causes the display unit 9b to display an address confirmation screen in the order of addresses as shown in FIG. 8(b) on the display unit 9b based on the second program stored in the RAM 9a3.

Here, the status of each fire alarm terminal is indicated by a circle icon displayed in a matrix corresponding to the address. In this embodiment, as shown in FIG. 8(b), the addresses are displayed in order of address in a matrix of columns 0 to 9 (in increments of 1) and rows 0 to 120 (in increments of 10).

As shown in FIG. 9(c), when the builder 11 presses the scan button 9b3 on the address confirmation screen, a scanning operation starts in the order of the addresses. That is, the addresses are scanned from 00 to 01, 02---- in increments of 1 in ascending order of address.

That is, the CPU 9a1 of the mobile terminal 9 transmits scan operation start instruction information to the wireless transmitter/receiver 35c of the simulator 35 via the transmitter/receiver 9c based on the second program stored in the RAM 9a3. .

As shown in FIG. 7, when the simulator 35 receives the scan operation start instruction information S1 by its wireless transmitter/receiver 35c, the simulator 35 determines the address of each fire alarm terminal based on the first program stored in the RAM 35b3. Start sequential scanning operation.

That is, as shown in FIG. 7, the simulator 35 sends the address confirmation signal S3 to the smoke detector 19, the smoke sensor 25, the heat sensor 29, the address transmitter 31-1, etc. in address order, and sends the response signal S5. Confirm the address by. As a result, the simulator 35 detects unscanned fire alarm terminals, unconnected fire alarm terminals, normally connected fire alarm terminals, and fire alarm terminals with duplicate addresses.

Then, as shown in FIG. 7, the simulator 35 generates information on detected unscanned fire alarm terminals, unconnected fire alarm terminals, normally connected fire alarm terminals, and fire alarm terminals with duplicate addresses. S7 is sequentially wirelessly communicated from the wireless transmitter/receiver 35c to the transmitter/receiver 9c of the mobile terminal 9, and the mobile terminal 9 receives the detected information S7.

Then, the mobile terminal 9 sequentially displays the scan operation result information as follows based on the received fire alarm terminal information S7.

That is, in the mobile terminal 9, a scan operation screen as shown in FIG. 9(d) is displayed on the display section 9b of the mobile terminal 9.

Here, on the scan operation screen, as shown in FIG. 9(d), the scan button 9b3 on the address confirmation screen changes to a stop button 9b5 indicating that the scan is in progress, and a message 9b7 indicating that the scan is in progress is displayed in the center. be done. The color of the circle icons displayed in a matrix will change sequentially from the fire alarm terminal that has been scanned, and if an unconnected state or address duplication is detected, the number representing the number of cases will be updated. Ru.

As for the icon color, as shown in Figure 10(d), if the fire alarm terminal's circle icon is blue, it means that the fire alarm terminal is in an unscanned state, and the fire alarm terminal's circle icon is gray. If , it indicates that the fire alarm terminal is not connected, and if the circle icon of the fire alarm terminal is green, it indicates that the fire alarm terminal is normally connected, and the circle icon of the fire alarm terminal is green. If it is yellow, it indicates that the fire alarm terminal is in an address duplication state.

In addition, on the scan operation screen of the mobile terminal 9 shown in FIGS. 8 to 10, blue circle icons are indicated by white circles, gray circle icons are indicated by diagonal circles, and green circle icons are indicated by black circles. It shows.

Next, in step 103 of FIG. 6, it is determined whether the scanning operation of all the fire alarm terminals having the address has been completed, and if the scanning operation of all the fire alarm terminals having the address has been completed, in step 105 , a list of scan results in address order is displayed in a matrix format.

That is, as shown in FIG. 7, information S7 of unconnected fire alarm terminals, normally connected fire alarm terminals, and fire alarm terminals with duplicate addresses detected by the simulator 35 is sequentially sent to the mobile terminal 9. When the scan operation of all the fire alarm terminals having the transmitted address is completed, the mobile terminal 9 changes the scan operation screen as shown in FIG. 10(a) to the scan result confirmation screen as shown in FIG. 10(b). is displayed on the display section 9b of the mobile terminal 9 instead.

Here, on the scan result confirmation screen, as shown in FIG. 10(b), the stop button 9b5 indicating that the scan operation is in progress on the address confirmation screen returns to the scan button 9b3, and the scan operation that was displayed in the center Message 9b7 is deleted and the scan result is displayed at the bottom of the screen. Thereby, the constructor 11 can confirm the scan results. Then, as shown in FIG. 10C, the installer 11 scrolls the address confirmation screen with his or her finger to confirm all scan results.

In this embodiment, it is assumed that 200 fire alarm terminals are connected, and 200 of their addresses are displayed by scrolling.

In addition, as shown in FIG. 10(b), in this embodiment, in a matrix of columns 0 to 9 (in increments of 1) and rows 0 to 120 (in increments of 10), the addresses of rows 0 to 20 are The fire alarm terminals in blue (white circles) are in an unscanned state, the address fire alarm terminals in the first column of the 40th row are in an unconnected state in gray (hatched circles), and the address fire alarm terminals in the other 30 to 120 rows are in an unscanned state. The notification terminal is displayed in green (black circle) to indicate that it is in a normal connection state.

Further, in this embodiment, as shown in FIG. 7, in parallel with the scanning operation of the fire alarm terminal by the simulator 35, the information S7 of the fire alarm terminal is sequentially transmitted to the mobile terminal 9, and the scan result on the mobile terminal 9 is However, the simulator 35 completed the scanning operation of all fire alarm terminals with addresses, and all detected unscanned fire alarm terminals, unconnected fire alarm terminals, and normally connected fire alarm terminals were confirmed. The scan result may be confirmed on the mobile terminal 9 after the information S7 of the fire alarm terminal in the state and the fire alarm terminal with the same address is transmitted to the mobile terminal 9.

As described above, according to the method for checking the status of fire alarm terminals according to this embodiment, the scan results of each fire alarm terminal are displayed in a list matrix in order of address, so it is easy to check the connection of each fire alarm terminal to the transmission line. In addition to detecting and displaying address duplication of each fire alarm terminal, it is also possible to easily confirm address duplication of each fire alarm terminal.

Note that address duplication of each fire alarm terminal detected and displayed by the fire alarm terminal status confirmation method can be corrected by an address correction method described later.

Next, with reference to FIGS. 11 to 23, a method for confirming and correcting the address of a fire alarm terminal in the fire alarm system 1 shown in FIG. (operation) will be explained.

FIG. 11 is a flowchart of a second operation of checking the identifier of a fire alarm terminal in the fire alarm system 1 shown in FIG. 1 and correcting an incorrect identifier, and FIG. FIG. 13 to FIG. 20, FIG. 22, and FIG. FIG. 21 is an explanatory diagram of the display screen of the display unit 9b of FIG. It is a diagram.

Note that this address confirmation/correction of the fire alarm terminal is performed in the fire alarm system 1 shown in FIG. 1 by the installer 11 inputting an instruction to the mobile terminal 9 wirelessly connected to the simulator 35.

In step 201 of FIG. 11, an operation of confirming the address of the fire alarm terminal connected to the sensor transmission line 13 is performed.

That is, first, while the transmitting/receiving unit 9c of the mobile terminal 9 held by the constructor 11 is performing wireless communication such as Wi-Fi with the wireless transmitting/receiving unit 35c of the simulator 35, the second program is activated in the mobile terminal 9. Then, as shown in FIG. 8A, an operation mode selection screen is displayed on the display section 9b of the mobile terminal 9.

That is, the CPU 9a1 of the mobile terminal 9 causes the display unit 9b to display an operation mode selection screen as shown in FIG. 8A on the display unit 9b based on the second program stored in the RAM 9a3.

Then, as shown in FIG. 8(a), when the installer 11 presses the confirmation button 9b1 on the operation mode selection screen, an address confirmation screen as shown in FIG. 8(b) appears on the display of the mobile terminal 9. 9b.

That is, the CPU 9a1 of the mobile terminal 9 causes the display unit 9b to display an address confirmation screen as shown in FIG. 8(b) based on the second program stored in the RAM 9a3.

Here, the status of each fire alarm terminal is indicated by circle icons displayed in a matrix. In this embodiment, as shown in FIG. 8(b), it is displayed as a matrix with columns 0 to 9 (in increments of 1) and rows 0 to 120 (in increments of 10).
The process up to this point is the same as the address confirmation operation of the fire alarm terminal explained in step 101 of FIG.

Next, when the constructor 11 selects the circle icon of an arbitrary address on the address confirmation screen as shown in FIG. 8(b) and presses it with his/her finger, the individual detailed confirmation as shown in FIG. 13(a) is performed. A screen is displayed on the display section 9b of the mobile terminal 9.

As shown in FIG. 13(a), it can be seen from this individual details confirmation screen that the fire alarm terminal with address number 11 has been selected.

When the builder 11 presses the operation button 9b8 on the individual details confirmation screen shown in FIG. 13(a), an operation screen as shown in FIG. 13(b) is displayed on the display section 9b of the mobile terminal 9.

When the builder 11 presses the lighting button 9b9 on the operation screen as shown in FIG. 13(b), the LED light of the fire alarm terminal with address number 11 lights up, as described below.

That is, as shown in FIG. 12, the CPU 9a1 of the mobile terminal 9 transmits address confirmation operation start instruction information S11 to the wireless transmitter/receiver 35c of the simulator 35 by wireless communication based on the second program stored in the RAM 9a3. (display instruction) is transmitted via the transmitting/receiving section 9c.

When the simulator 35 receives the address confirmation operation start instruction information S11 by its wireless transmitting/receiving unit 35c, it starts the address confirmation operation of each fire alarm terminal based on the first program stored in the RAM 35b3.

That is, as shown in FIG. 12, the simulator 35 transmits the address confirmation signal S13 to the fire alarm terminals such as the smoke detector 19, the smoke detector 25, the heat sensor 29, and the address transmitter 31-1. Send to the fire alarm terminal with address number 11. As a result, as shown in FIG. 14(c), the LED light 25a of the fire alarm terminal with address number 11 (in this embodiment, the smoke detector 25) lights up.

That is, when the smoke detector 25 receives the address confirmation signal S13 from the simulator 35, the control unit 25d of the smoke detector 25 controls the LED light 25a to turn on based on the address confirmation signal from the simulator 35. do.

Note that, in FIG. 14(c), the smoke detector 25 with the LED light 25a turned on is schematically shown below the display section 9b of the mobile terminal 9.

As described above, in this embodiment, when the LED light 25a of the smoke detector 25, which is the fire alarm terminal with the selected address number 11, lights up, the installer 11 selects it by holding the mobile terminal 9. If the user goes to the address number 11 and confirms that the LED light 25a of the smoke detector 25 is lit, it can be determined whether the smoke detector 25 is installed correctly.

That is, since the installer uses a dedicated address setting device for each fire alarm terminal according to the setting diagram of each fire alarm terminal, the setting diagram of each fire alarm terminal is stored in the mobile terminal 9 in advance. Once installed, the installer 11 displays the setting diagram of each fire alarm terminal on the display section 9b of the mobile terminal 9, goes to the location where the fire alarm terminal with the selected address number 11 is to be installed, and By checking whether the LED light 19a of the notification terminal is lit, it can be determined whether the correct fire notification terminal is installed. This allows for easy confirmation and detection of incorrect addresses on fire alarm terminals.

In this embodiment, the setting diagram of each fire alarm terminal is stored in advance in the mobile terminal 9, and the setting diagram of each fire alarm terminal is displayed on the display section 9b of the mobile terminal 9, so that the installer 11 can Although the construction drawing is not limited to this, the constructor 11 may directly view the setting drawing.

Further, as shown in FIG. 14(d), when the light-off button 9b11 on the operation screen is pressed, an operation operation is performed in which the LED light of the fire alarm terminal with address number 11 is turned off. Note that, in FIG. 14(d), the smoke detector 25 with the LED light 25a turned off is schematically shown below the display section 9b of the mobile terminal 9.

Note that this operation of turning off the light is performed in substantially the same way as the operation of turning on the light described above (only the turning on is changed to turning off the light), so a detailed explanation will be omitted.

In the address confirmation operation shown in FIGS. 13 and 14 above, address confirmation was performed by specifying address numbers one by one, but as explained below, address confirmation is performed by specifying address numbers in succession. You can also do

FIGS. 15 and 16 are explanatory diagrams of the display screen of the display section 9b of the mobile terminal 9 in the address confirmation and correction method for a fire alarm terminal. In particular, when the address is confirmed by sequentially specifying address numbers, It is an explanatory diagram.

Note that even when address confirmation is performed by sequentially specifying address numbers, the intermediate operations are the same as in the above-described case where address numbers are specified one by one and address confirmation is performed. That is, first, while the transmitting/receiving unit 9c of the mobile terminal 9 held by the constructor 11 is performing wireless communication with the wireless transmitting/receiving unit 35c of the simulator 35, the second program is run on the mobile terminal 9, and as shown in FIG. As shown in FIG. 8(a), an operation mode selection screen is displayed on the display section 9b of the mobile terminal 9.

That is, the CPU 9a1 of the mobile terminal 9 causes the display unit 9b to display an operation mode selection screen as shown in FIG. 8A on the display unit 9b based on the second program stored in the RAM 9a3.

Then, as shown in FIG. 8(a), when the installer 11 presses the confirmation button 9b1 on the operation mode selection screen, an address confirmation screen as shown in FIG. 8(b) appears on the display of the mobile terminal 9. 9b.

That is, the CPU 9a1 of the mobile terminal 9 causes the display unit 9b to display an address confirmation screen as shown in FIG. 8(b) based on the second program stored in the RAM 9a3.

Next, when the constructor 11 selects the circle icon of an arbitrary address on the address confirmation screen as shown in FIG. 8(b) and presses it with his/her finger, the individual detailed confirmation as shown in FIG. 13(a) is performed. A screen is displayed on the display section 9b of the mobile terminal 9.

As shown in FIG. 13(a), it can be seen from this individual details confirmation screen that the fire alarm terminal with address number 11 has been selected.

Here, if address confirmation is to be performed by sequentially specifying address numbers, the builder 11 presses the sequentially continuous button 9b13 on the individual details confirmation screen, as shown in FIG. 15(e).

Then, an individual details confirmation screen as shown in FIG. 15(f) will be displayed on the display section 9b of the mobile terminal 9, so when you press the operation button 9b8 on the individual details confirmation screen, the screen as shown in FIG. 16(g) will be displayed. A confirmation screen is displayed on the display section 9b of the mobile terminal 9.

That is, as shown in FIG. 16(g), in this embodiment, along with the display of address number 11, the LED light 25a of the smoke detector 25 of address number 11 is lit below the display of the address number. The LED light 25a of the smoke detector 25 with address number 11 actually lights up.

That is, the CPU 9a1 of the mobile terminal 9 transmits address confirmation operation start instruction information to the wireless transmitter/receiver 35c of the simulator 35 via the transmitter/receiver 9c based on the second program stored in the RAM 9a3. do.

As shown in FIG. 12, when the simulator 35 receives the start instruction information S11 (display instruction) for the address confirmation operation by its wireless transmitter/receiver 35c, the simulator 35 performs each operation based on the first program stored in the RAM 35b3. Start checking the address of the fire alarm terminal.

That is, as shown in FIG. 12, the simulator 35 sends an address confirmation signal S13 to the smoke detector 19, the smoke detector 25, the heat sensor 29, the address transmitter 31-1, etc., when the selected address number is 11. sent to the fire alarm terminal. As a result, an operation is performed to turn on the LED light 25a of the fire alarm terminal with address number 11 (in this embodiment, the smoke detector 25).

As shown in FIG. 16(g), below the picture of the smoke detector 25 on the display section 9b of the mobile terminal 9, there is a next button 9b15 and a previous button 9b17 for moving to or closing the next or previous address confirmation. A close button 9b19 is displayed.

Then, when the next button 9b15 is pressed, as shown in FIG. 16(h), the operation proceeds to the address confirmation operation of the fire alarm terminal (in this embodiment, the heat sensor 29) at address number 12, which is the next address after address number 11. and move on.

That is, as shown in FIG. 16(h), in this embodiment, along with the display of address number 12, the LED light 29a of the heat sensor 29 of address number 12 is lit below the display of the address number. The LED light 29a of the heat sensor 29 with address number 12 actually lights up.

Here again, the CPU 9a1 of the mobile terminal 9 transmits address confirmation operation start instruction information to the wireless transmitter/receiver 35c of the simulator 35 via the transmitter/receiver 9c, based on the second program stored in the RAM 9a3. Send.

As shown in FIG. 12, when the simulator 35 receives the address confirmation operation start instruction information S11 by its wireless transmitting/receiving unit 35c, the simulator 35 determines whether each fire alarm terminal The simulator 35 starts the address confirmation operation, and as shown in FIG. The fire alarm terminal with address number 12 is sent. As a result, an operation is performed to turn on the LED light 29a of the heat sensor 29 with address number 12.

In this sequential address confirmation, when the LED light 29a of the heat sensor 29, which is the fire alarm terminal with the selected address number 12, lights up, the installer 11 can check the mobile terminal 9. If you go to the selected address number 12 and check that the LED light 29a of the heat sensor 29 is lit, you will be able to tell whether the heat sensor 29 is installed correctly.

This sequential address confirmation can be made easier by pressing the next button 9b15, the previous button 9b17, and the close button 9b19 displayed below the picture of the smoke detector 19 on the display section 9b of the mobile terminal 9. Continuous address confirmation can be performed one after another.

That is, since the installer 11 uses a dedicated address setting device for each fire alarm terminal according to the setting diagram of each fire alarm terminal, the setting diagram of each fire alarm terminal is stored in the mobile terminal 9 in advance. If so, the installer 11 displays the configuration diagram of each fire alarm terminal, goes to the location where the fire alarm terminal with the selected address number is to be installed, and turns on the LED light of that fire alarm terminal. By checking them one after another, you can determine whether the correct fire alarm terminal is installed. This allows for easy confirmation and detection of incorrect addresses on fire alarm terminals.
In this embodiment, the setting diagram of each fire alarm terminal is stored in advance in the mobile terminal 9, and the setting diagram of each fire alarm terminal is displayed on the display section 9b of the mobile terminal 9, so that the installer 11 can Although the construction drawing is not limited to this, the constructor 11 may directly view the setting drawing.

Address errors found by the address confirmation described above include cases where an address that is not in the configuration diagram is displayed in the matrix display, or an address that is supposed to be in the configuration diagram is displayed in the matrix display. This also includes cases where there is none.

Next, a description will be given of an operation for correcting the address of a fire alarm terminal whose address is found to be incorrect by the address confirmation described above.

Returning to FIG. 11, in step 203, an address error is found through the address confirmation described above, and it is determined whether or not to rewrite the address number of the specific fire alarm terminal where the address error was found. When rewriting the address number of the notification terminal, an address rewriting operation of the specific fire notification terminal is performed in step 205.

That is, first, when the installer 11 attempts to correct the address error after an address error is found, the display section 9b of the mobile terminal 9 is set to the operation mode shown in FIG. 8(a) described above. When the installer 11 presses the confirmation button 9b1 on the operation mode selection screen as shown in FIG. 8(a), the fire alarm as shown in FIG. 17(a) is displayed. An address confirmation screen displaying a list of terminals in address order is displayed on the display section 9b of the mobile terminal 9.

That is, the CPU 9a1 of the mobile terminal 9 causes the display unit 9b to display an address confirmation screen as shown in FIG. 17(a) based on the second program stored in the RAM 9a3.

Next, on the address confirmation screen as shown in FIG. When pressed, an individual details confirmation screen as shown in FIG. 17(b) is displayed on the display section 9b of the mobile terminal 9.

As shown in FIG. 17(b), it can be seen from this individual details confirmation screen that the fire alarm terminal with address number 11 has been selected.

When the constructor 11 presses the setting button 9b21 on the individual details confirmation screen as shown in FIG. 18(c), an address setting screen as shown in FIG. 18(d) is displayed on the display section 9b of the mobile terminal 9. be done. This address setting screen displays that the fire alarm terminal with address number 11 has been selected.

When the installer 11 presses the address display button 9b23 on the address setting screen as shown in FIG. 18(d), the address input screen for setting the address appears on the mobile terminal 9 as shown in FIG. is displayed on the display section 9b. In this address input screen, an address input screen section 9b25 is displayed.

Then, as shown in FIG. 19(e), the builder 11 inputs a new address number to be set for the fire alarm terminal with the address number 11 on the address input screen section 9b25. In this embodiment, when 12 is input as a new address number, an address setting screen as shown in FIG. 19(f) is displayed on the display section 9b of the mobile terminal 9.

This address setting screen displays that the fire alarm terminal with address number 11 will be corrected to address number 12.

Next, as shown in FIG. 20(g), when the installer 11 presses the OK button 9b27 on the address setting screen, the fire alarm terminal with the address number 11 is corrected to the address number 12.

That is, as shown in FIG. 21, the CPU 9a1 of the mobile terminal 9 transmits corrected address information S15 of the address correction operation to the wireless transmitter/receiver 35c of the simulator 35 by wireless communication based on the second program stored in the RAM 9a3. (correction instruction) is transmitted via the transmitting/receiving section 9c.

When the simulator 35 receives the corrected address information S15 of the address correction operation by its wireless transmitter/receiver 35c, the simulator 35 corrects the fire alarm terminal (with address number 11) based on the first program stored in the RAM 35b3. In this embodiment, an address rewriting command signal S17 is sent to the smoke detector 25).

Then, in the smoke detector 25, based on the address rewriting command signal S17, the address number rewriting function starts an address correction operation of the fire alarm terminal with address number 11 to address number 12. A correction operation is performed in which the address number of the notification terminal is changed to address number 12.

That is, when the smoke detector 25 receives the address rewriting command signal S17 from the simulator 35, the control unit 25d of the smoke detector 25 stores the address in the address storage unit 25f based on the address rewriting command signal S17 from the simulator 35. control to rewrite and correct the address. Note that since the operation of the address number rewriting function provided in the smoke detector 25 is well known, a detailed explanation will be omitted.

In this way, in this address correction operation, when an error in the address number of a predetermined fire alarm terminal is detected, the installer 11 corrects the address error of the predetermined fire alarm terminal via the mobile terminal 9. Since the address number can be corrected, there is no need for the installer 11 to go to the designated fire alarm terminal and remove the fire alarm terminal such as a detector to correct the address number, dramatically improving the work efficiency of address number correction. improve.

Thereafter, as shown in FIG. 21, an address number correction completion signal S21 from the smoke detector 25 whose address number has been changed to 12 is sent to the simulator 35, and an address number correction completion signal S23 is sent from the simulator 35 to the mobile terminal 9. Then, the address confirmation screen is displayed again on the display section 9b of the mobile terminal 9, as shown in FIG. 20(h), and the matrix shows that the fire alarm terminal with address number 11 has been corrected to address number 12. The addresses are listed in order of address. That is, the fact that the corrected fire alarm terminal has address number 12 is displayed on the list to reflect the correction. In FIG. 20(h), the fact that the fire alarm terminal has the corrected address number 12 is indicated by a diagonal circle.

On the address confirmation screen shown in FIG. 20(h), the status of each fire alarm terminal is indicated by circle icons displayed in a matrix corresponding to the address. In this embodiment, the addresses are displayed in a matrix of columns 0 to 9 (in increments of 1) and rows 0 to 120 (in increments of 10) in address order.

That is, on the address confirmation screen shown in FIG. 20(h), addresses are displayed in 1 increments from 00 to 01, 02, etc. in descending order from the top left of the screen.

Furthermore, when the builder 11 presses the cancel button 9b29 on the address setting screen shown in FIG. 20(g), the screen returns to the individual details confirmation screen as shown in FIG. 17(b).

In this embodiment, when the address of the terminal is confirmed in step 201 of FIG. 11 and the address of the specific terminal is rewritten in step 203, the address of the specific terminal is rewritten. Even if address duplication of each fire alarm terminal is detected by the first operation of detecting and displaying the connection status and identifier duplication of the fire alarm terminal corresponding to the address shown, the address correction method of step 205 in FIG. You may correct it.

In this case, the installer 11 clicks the circle icon of the address of the fire alarm terminal with the duplicate address shown on the scan result confirmation screen displayed on the display section 9b of the mobile terminal 9 as shown in FIG. 10(b). Select to display the individual details confirmation screen as shown in FIG. 17(b), press the setting button 9b21 on the individual details confirmation screen as shown in FIG. 18(c), and click the setting button 9b21 as shown in FIG. 18(d). Display the address setting screen and press the address display button 9b23 on the address setting screen to display the address input screen for setting the address as shown in FIG. 19(e). , a new address number is input into the address input screen section 9b25, and an address correction operation is performed.

Next, a case will be described in which the address number that the builder 11 inputs into the address input screen section 9b25 shown in FIG. 19(e) is an address number that is already in use.

If the address number that the constructor 11 inputs into the address input screen section 9b25 shown in FIG. As shown in a), an error message 9b31 saying "The specified address is already in use. Please specify another address." is displayed, and the OK button 9b33 displayed below the error message 9b31 is displayed. When the builder 11 presses , the screen returns to the address setting screen as shown in FIG. 22(b). Then, when the installer 11 presses the address: 11 button 9b35 on the address setting screen as shown in FIG. 22(b), the screen returns to the address setting screen as shown in FIG. 19(e), and the address number is re-corrected. I can do it.

In addition, when the address correction operation of the fire alarm terminal with address number 11 is completed and there is another fire alarm terminal that requires address correction, the display of the mobile terminal 9 will be displayed on the display of the fire alarm terminal whose address needs to be corrected. It is necessary to switch the screen of 9b.

In such a case, the constructor 11 may press the previous button 9b37 and next button 9b39 displayed at the lower end of the display section 9b of the mobile terminal 9, as shown in FIGS. 23(a) and 23(b). As a result, the screen on the display section 9b of the mobile terminal 9 is switched to display an individual details confirmation screen for the fire alarm terminal whose address needs to be corrected.

In this way, when the address correction operation of a predetermined fire alarm terminal is completed and there is another fire alarm terminal that needs to perform the address correction operation, another address correction operation can be easily performed.

The present invention is not limited to the embodiments described above, but can be implemented in other forms by making appropriate corrections.

In the above embodiment, during the installation process of the fire alarm system, the simulator is installed to check and correct the address of the fire alarm terminal without the receiver being connected, but this is not limited to this. After connecting the receiver, a simulator may be installed to confirm and correct the address of the fire alarm terminal.

In the above embodiment, the mobile terminal 9 uses a general smartphone compatible with Wi-Fi, but is not limited to this, and a dedicated reception display terminal may also be used.

In the above embodiment, the isolator 15a is connected to a smoke detector 19, a thermocouple detector 21, an address adapter 23, a smoke detector 25, a heat sensor 29, and a transmitter with address 31 via the sensor transmission line 13a. -1, a fire alarm terminal such as the address adapter connection transmitter 31-2 is connected, but each terminal may be a plurality of terminals.

1...Fire alarm system 3...Receiver 9...Mobile terminal 11...Constructor 13a, 13b...Sensor transmission lines 15a, 15b...Isolator 19...Smoke detector 21...Thermocouple type detector 23...Address adapter 25...General sensing Device 29... Heat sensor 31-1, 31-2... Transmitter 35... Simulator (simulation device)

Claims (16)

A fire alarm system comprising: a plurality of fire alarm terminals each having an identifier and detecting fire-related sensing information; and a receiver connected to the fire alarm terminal for receiving and displaying sensing information from the fire alarm terminal. A notification system,
a simulation device connected to the fire alarm terminal to detect the state of the fire alarm terminal corresponding to the identifier; and a simulation device wirelessly communicating with the simulation device to detect the state of the fire alarm terminal corresponding to the identifier. a mobile device for displaying;
The mobile terminal displays a list of icons corresponding to each of the fire alarm terminals and indicating the status of each of the fire alarm terminals in a two-dimensional matrix,
The mobile terminal is characterized in that the icons are displayed in the order of the identifiers of the fire alarm terminals as a two-dimensional matrix with columns of 0 to 9 in increments of 1 and rows in increments of 10. A fire alarm system characterized by: The fire alarm system according to claim 1, wherein the mobile terminal displays a list of states of the fire alarm terminals detected by the simulator in order of identifiers. 3. The fire alarm system according to claim 2, wherein the state of the fire alarm terminal is a connected state of the fire alarm terminal. 3. The fire alarm system according to claim 2, wherein the state of the fire alarm terminal is that the identifiers of the fire alarm terminals are duplicated. The fire alarm terminal has a display means for displaying the operating status of each, and the mobile terminal wirelessly communicates with the simulator to display the display means for the fire alarm terminal according to the identifier of the fire alarm terminal. A display instruction for displaying is transmitted to the simulation device, and the simulation device displays the display means of the fire alarm terminal according to the identifier of the fire alarm terminal according to the display instruction from the mobile terminal. The fire alarm system described in item 1. According to claim 5, it is detected that the identifier of the fire alarm terminal is different from a predetermined setting based on the display by the display means of the fire alarm terminal according to the identifier of the fire alarm terminal. Fire alarm system as described. 7. The fire alarm system according to claim 6, wherein the simulator corrects an identifier that is different from a predetermined setting of the fire alarm terminal based on a correction instruction from the mobile terminal. 5. The fire alarm system according to claim 4, wherein the simulator corrects a duplicate identifier of the fire alarm terminal based on an instruction from the mobile terminal. 9. The fire alarm system according to claim 1, wherein the receiver is not connected to the fire alarm terminal. 10. The fire alarm system according to claim 1, wherein the display means of the fire alarm terminal comprises lights for displaying respective operating states. A fire alarm system comprising: a plurality of fire alarm terminals each having an identifier and detecting fire-related sensing information; and a receiver connected to the fire alarm terminal for receiving and displaying sensing information from the fire alarm terminal. A notification system,
a simulator connected to the fire alarm terminal to confirm and correct the identifier of the fire alarm terminal; and a simulator that communicates wirelessly with the simulator to correspond to each of the fire alarm terminals. The icons indicating the status of each identifier are listed in a two -dimensional matrix, and the identifiers of each of the fire alarm terminals are displayed in columns of 0 to 9 in units of 1 and rows in units of 10 in the two-dimensional matrix. a mobile terminal that displays each of the icons in the order of the identifier as a matrix ;
The fire alarm terminal has display means for displaying respective operating states, and the mobile terminal transmits a display instruction to the simulation device to display the display means according to the identifier of the fire alarm terminal, and The simulator causes the display means to display according to the identifier of the fire alarm terminal in response to a display instruction from the mobile terminal, and based on the display by the display means of the fire alarm terminal according to the identifier of the fire alarm terminal, If it is detected that the identifier of the fire alarm terminal is different from the predetermined setting, and the identifier of the fire alarm terminal is different from the predetermined setting, the mobile terminal corrects the identifier that is different from the predetermined setting. The fire alarm system is characterized in that a correction instruction is given to the simulation device, and the simulation device corrects an identifier that is different from its predetermined setting based on the correction instruction from the mobile terminal. The fire alarm system according to claim 11, wherein the receiver is not connected to the fire alarm terminal. 13. The fire alarm system according to claim 11, wherein the display means of the fire alarm terminal comprises lights for displaying respective operating states. a plurality of fire alarm terminals each having an identifier and detecting sensed information related to a fire; a receiver connected to the fire alarm terminal for receiving and displaying sensed information from the fire alarm terminal; and a receiver connected to the fire alarm terminal for receiving and displaying sensed information from the fire alarm terminal; A method for correcting a state confirmation identifier of a fire alarm terminal in a fire alarm system having a simulation device connected to a terminal and a mobile terminal wirelessly communicating with the simulation device, the method comprising: a step in which the state of the notification terminal is detected;
transmitting information on the state of the fire alarm terminal to the mobile terminal by the simulation device;
The mobile terminal displays a list of icons indicating the status of each of the fire alarm terminals corresponding to the identifier in a two-dimensional matrix in the order of the identifier , and displays the identifier of each of the fire alarm terminals in increments of one. A status check identifier correction method comprising the step of displaying each of the icons in the order of the identifier as the two-dimensional matrix with columns of 0 to 9 and rows of 10. a plurality of fire alarm terminals each having an identifier and detecting sensed information related to a fire; a receiver connected to the fire alarm terminal for receiving and displaying sensed information from the fire alarm terminal; and a receiver connected to the fire alarm terminal for receiving and displaying sensed information from the fire alarm terminal; Checking the status of a fire alarm terminal in a fire alarm system that has a simulation device connected to a terminal, and a mobile terminal that communicates wirelessly with the simulation device, and the fire alarm terminal has display means for displaying the operating status of each. An identifier correction method, comprising:
The mobile terminal displays the display means of the fire alarm terminal according to each icon indicating the status of each of the fire alarm terminals listed in a two-dimensional matrix corresponding to the identifier of each of the fire alarm terminals. and a display instruction for displaying the icons in the order of the identifiers as the two-dimensional matrix with columns of 0 to 9 in units of 1 and rows in units of 10 of the identifiers of each of the fire alarm terminals is given to the simulation device. The process of being sent,
a step of displaying a display means of the fire alarm terminal according to an identifier of the fire alarm terminal by the simulation device based on a display instruction from the mobile terminal;
a step of detecting that the identifier of the fire alarm terminal is different from a predetermined setting based on a display by a display means of the fire alarm terminal according to the identifier of the fire alarm terminal;
If the identifier of the fire alarm terminal is different from a predetermined setting, the mobile terminal issues a correction instruction to the simulation device to correct the identifier that is different from the predetermined setting;
A status confirmation identifier correction method comprising the step of correcting, by the simulation device, an identifier that is different from a predetermined setting based on a correction instruction from the mobile terminal. 2. The mobile terminal is characterized in that the icons are displayed in different colors depending on at least one of a scan state, a connection state, and a duplication state of the identifiers of the fire alarm terminal. Fire alarm system as described.

Images