JP5947927B2 - Receiver - Google Patents

Description

  The present invention relates to a receiving apparatus.

  Conventionally, disaster prevention systems that notify the occurrence of a fire using various types of terminal devices have been used. FIG. 12 is a schematic diagram of a conventional disaster prevention system 101. As shown in FIG. 12, the disaster prevention system 101 includes a wired sensor 110 and a wireless sensor 120 that transmit a fire signal to notify a fire when a fire is detected in each level of a building, and a push button. A transmitter 130 that transmits a fire signal when operated, a receiver 140 that relays the fire signal received from the wireless sensor 120 to the receiver 150, and a fire signal from the receiver 140 via the signal line 102 And a receiver 150 for receiving the signal. The signal line 102 includes an A line 102a, a C line 102b, and an L line 102c. The A line 102a connects the transmitter 130 and the receiving device 140 to each other, and connects the receiving device 140 and the receiver 150 to each other. Moreover, the A line 102a is connected across the transmitter 130 provided for each level of the building. On the other hand, the C line 102b and the L line 102c connect the transmitter 130 and the wired sensor 110 to each other, connect the wired sensor 110 and the receiving device 140 to each other, and the receiving device 140 and the receiver. 150 are connected to each other. A predetermined voltage is applied from the receiver 150 between the A line 102a and the C line 102b and between the L line 102c and the C line 102b. Further, a terminator (not shown) (for example, a resistor) is connected to the termination of the L line 102c and the C line 102b, and the receiver electrically determines whether or not the terminator is connected (for example, as described above). By checking whether the current flowing from the L line 102c to the C line 102b via the terminator is within a predetermined range), it is confirmed whether the L line 102c and the C line 102b are disconnected. Yes.

  In such a configuration of the disaster prevention system 101, as a method of transmitting the fire signal of the terminal device to the receiver 150, for example, the terminal device short-circuits the signal line 102 connected to the terminal device. A fire signal of the terminal device is transmitted to the receiver 150. Specifically, in the case of a fire signal from the transmitter 130, the transmitter 130 short-circuits the A line 102a, the C line 102b, and the L line 102c connected to the transmitter 130, thereby the A line 102a. In addition, a current flows from the L line 102c toward the C line 102b, and the current is caused to be detected by the receiver 150, thereby transmitting a fire signal of the transmitter 130 to the receiver 150. In the case of a fire signal from the wired sensor 110, the wired sensor 110 short-circuits the C line 102b and the L line 102c connected to the wired sensor, so that the wired sensor 110 is connected. The fire signal is transmitted to the receiver 150. In the case of a fire signal from the wireless sensor 120, after the receiving device 140 receives the fire signal from the wireless sensor 120, the C line 102b and the L line 102c connected to the receiving device 140 are short-circuited. By causing the current to flow from the L line 102c toward the C line 102b and causing the receiver 150 to detect the current, a fire signal of the wired sensor 110 is transmitted to the receiver 150 (for example, , See Patent Document 1).

Japanese Patent Laid-Open No. 08-185590

  However, such a conventional disaster prevention system 101 has a problem with respect to the installation of the transmitter 130. For example, since the transmitter 130 shown in FIG. 12 must be connected to the receiver 150 by the signal line 102, when the number of transmitters 130 to be installed is large, installation cost and installation time are required. The transmitter 130 is provided for each level of the building, and the transmitters 130 are connected to each other by an A line 102a. Specifically, the transmitters 130 are connected to the A line 102a through through holes provided in the ceiling or floor of each level of the building. In the installation of such a transmitter 130, it is necessary to make a through-hole, and this further increases the installation cost and installation effort.

  The present invention has been made in view of the above, and an object thereof is to provide a receiving apparatus.

In order to solve the above-described problems and achieve the object, the receiving device according to claim 1 is a receiving device connected to the receiver via a plurality of signal lines, and notifies a fire. The first fire signal transmitted by the first fire notification terminal for the first fire signal including the first identification information for uniquely identifying the first fire notification terminal , or the above-mentioned in order to notify the fire A second fire signal transmitted from a second fire information terminal different from the first fire information terminal and including second identification information for uniquely identifying the second fire information terminal is wirelessly transmitted. A wireless receiving means for receiving, and when the wireless receiving means receives the first fire signal wirelessly, obtains the first identification information included in the received first fire signal, and receives the wireless reception When the means receives the second fire signal wirelessly An identification information acquiring means for acquiring the second identification information included in the received second fire signal, if the first identification information acquired by the identification information acquiring means, transfer of the first fire signal The second fire signal is transferred when the connection state of the plurality of signal lines is set to the first connection state and the second identification information is acquired by the identification information acquisition means so as to perform notification to the receiver. Control means for setting the connection state of the plurality of signal lines to a second connection state different from the first connection state.

The receiving device according to claim 2 is the receiving device according to claim 1, wherein the control means receives only the first identification information when the wireless receiving means receives only the first fire signal. When the identification information acquisition unit acquires , the connection state of the plurality of signal lines is set to the first connection state, and then the second fire signal is further received while the wireless reception unit continues to receive the first fire signal. When the wireless reception means receives the fire signal and the identification information acquisition means acquires the second identification information, the connection state of the plurality of signal lines is changed to the first connection state and the second connection is established. State.

Receiver according to claim 3, in the receiving apparatus according to claim 2, wherein the wireless receiver means is a fire reset signal the second fire alarm terminal transmits in order to inform the recovery from the fire The fire recovery signal including the second identification information is further received, and the identification information acquisition unit is included in the received fire recovery signal when the wireless reception unit wirelessly receives the fire recovery signal. The control means acquires the second fire signal after the wireless receiving means further receives the first fire signal while the wireless receiving means continues to receive the first fire signal. When the wireless reception means receives the fire recovery signal instead of the second fire signal while the wireless reception means continues to receive the first fire signal, the second identification information The identification If broadcast acquisition means has acquired, to the first connection state by changing the connection state of the plurality of signal lines to the second connection state.

  The receiving device according to claim 4 is the receiving device according to claim 2 or 3, wherein the plurality of signal lines include first to third signal lines, and the first connection state is the first connection state. The signal line and the second signal line are short-circuited, and the third signal line and the first and second signal lines are open, and the second connection state is In this connection state, the first signal line and the second signal line are short-circuited, and the second signal line and the third signal line are short-circuited.

It is the schematic which shows the structure of a fire alerting | reporting system. It is a schematic diagram which shows the connection condition of the signal wire | line of a receiver and a receiver. It is the block diagram which showed the electrical structure of the transmitter. It is the block diagram which showed the electrical structure of the relay apparatus. It is a block diagram which shows notionally the electrical structure of a receiver. It is the schematic which shows the connection condition of each terminal of a signal output part. It is the table | surface which illustrated the content of the information stored in a transfer method table. It is a flowchart of the relay process performed by a sensor, a transmitter, a relay device, and a receiver. It is a flowchart of the relay process performed by a transmitter and a receiver. It is a flowchart of the test process performed by a transmitter and a receiver. It is a flowchart of the output voltage determination process performed by a transmitter and a receiver. It is the schematic of the conventional disaster prevention system.

  Hereinafter, embodiments of a transmitter and a fire alarm system according to the present invention will be described in detail with reference to the accompanying drawings. First, the overall configuration of the fire alarm system configured with the transmitter will be described, then the configuration of the transmitter will be described, and the flow of relay processing executed by each device constituting the fire alarm system In addition, the relay processing, test processing, and output voltage determination processing of the transmitter will be described, and finally, a modified example of the present embodiment will be described. However, the present invention is not limited by this embodiment. In addition, although the installation object and application object of the transmitter which concerns on embodiment are arbitrary, below, the case where it applies to the transmitter installed indoors in an office building is demonstrated as an example.

Embodiment
(Configuration-Fire alarm system)
FIG. 1 is a schematic diagram illustrating a configuration of a fire alarm system. As shown in FIG. 1, the fire alarm system 1 includes a sensor 10, a transmitter 20, a relay device 30, a receiving device 40, and a receiver 50. The sensor 10, the transmitter 20, the relay device 30, and the receiving device 40 are arranged on the ceiling or wall on each floor of the building. Among these, one or a plurality of detectors 10 and transmitters 20 are arranged on each floor so as to satisfy legal installation intervals. The relay device 30 is disposed between the sensor 10 and the transmitter 20 to be relayed on each floor and the receiving device 40. One receiving device 40 is arranged on each floor. One receiver 50 is arranged in a building, for example, in a manager room of the building. The receiving device 40 and the receiver 50 are connected by a signal line 2 and a power line 3.

  Here, the sensor 10 is a wireless fire alarm terminal that transmits a fire signal for notifying a fire or a fire recovery signal for notifying a recovery from a fire. The transmitter 20 notifies a fire signal, a fire recovery signal, a test signal for confirming the transmission status of the signal transmitted from the transmitter 20, or a decrease in the output voltage of the power supply unit 25 of the transmitter 20 described later. This is a wireless fire alarm terminal that transmits an output voltage drop signal for the purpose. The relay device 30 receives a fire signal, a fire restoration signal, a test signal, or an output voltage drop signal from the sensor 10 or the transmitter 20, and receives the received fire signal, fire restoration signal, test signal, or output voltage drop signal. Are relayed to the receiving device 40. The receiving device 40 receives a fire signal, a fire recovery signal, a test signal, or an output voltage drop signal transmitted from the sensor 10, the transmitter 20, and / or the relay device 30, and the received fire signal or output voltage. The lowered signal is output to the receiver 50 via the signal line 2. The receiver 50 executes various processes such as alarm display and alarm sound output based on information input from the receiver 40 via the signal line 2, and power to the receiver 40 via the power line 3. Supply.

  Next, a connection form of each terminal device via the signal line 2 will be described. In the present embodiment, the fire alarm system 1 is configured as a so-called P-type second-class fire alarm system. FIG. 2 is a schematic diagram illustrating a connection state of the signal line 2 between the receiving device 40 and the receiver 50. As shown in FIG. 2, the signal line 2 includes an A line 2a, a C line 2b, and an L line 2c. The A line 2a, the C line 2b, and the L line 2c are connected to the receiving device 40. And the receiver 50 are connected to each other. Moreover, the A line 2a is connected across the receiving device 40 provided for each floor of the building (not shown). The A line 2a and the C line 2b (hereinafter referred to as “AC line” 2d) are lines for transmitting the fire signal of the transmitter 20 received by the receiving device 40 toward the receiver 50. The L line 2c and the C line 2b (hereinafter referred to as “LC line” 2e) are lines for transmitting a fire signal of the sensor 10 received by the receiving device 40. It is also a line for transmitting an output voltage drop signal. A terminal resistor (not shown) is provided at the terminal of the L-C line 2e of each system (here, each floor of the building).

(Configuration-Fire alarm system-Detector)
Next, the configuration of the sensor 10 will be described. The sensor 10 includes a sensor unit, a wireless transmission unit, and a power supply unit (not shown). The sensor unit is detection means for detecting temperature, smoke density, and the like. The wireless transmission unit is a wireless transmission unit that transmits a fire signal or a fire recovery signal. For example, when the fire determination unit (not shown) determines that the detection result is higher than the threshold based on the detection result of the temperature or smoke density in the sensor unit, the wireless transmission unit Send a signal. In addition, after the fire signal is transmitted, if the fire determination unit (not shown) determines that the detection result is lower than the threshold value, the wireless transmission unit transmits a fire recovery signal. In addition, the wireless transmission unit is, for example, information stored in advance in a known storage unit (not shown) included in the sensor 10, and the sensor identification information for uniquely identifying the sensor 10 is used as a fire signal or Include in fire recovery signal and send. Here, as the sensor identification information stored in the known storage means, for example, the address number or serial number of the sensor 10 can be used (the same applies to the transmitter identification information of the transmitter 20 described later). The power supply unit is a battery that supplies power to each unit of the sensor 10, and includes, for example, a known dry battery or a rechargeable battery (a power supply unit 25 of the transmitter 20 and a power supply unit 34 of the relay device 30 described later). The same applies to.

(Configuration-Fire alarm system-Transmitter)
Next, the configuration of the transmitter 20 will be described. FIG. 3 is a block diagram showing an electrical configuration of the transmitter 20. As shown in FIG. 3, the transmitter 20 includes a push button unit 21, a test switch unit 22, a wireless transmission unit 23, a display unit 24, a power supply unit 25, an output voltage detection unit 26, a control unit 27, and a storage unit 28. It is prepared for. Since the configuration of the power supply unit 25 is the same as that of the power supply unit in the sensor 10 described above, the description thereof will be omitted except for specially described parts.

  The push button unit 21 is an operation unit that receives a transmission instruction of a fire signal or a fire recovery signal by a user. The test switch unit 22 is a test operation unit that receives a test signal transmission instruction from a user, and includes, for example, a reed switch.

  The wireless transmission unit 23 is a wireless transmission unit that transmits a fire signal, a fire recovery signal, a test signal, or an output voltage drop signal. The wireless transmission unit 23 transmits a fire signal when, for example, the push button unit 21 is pushed down by the user, and stops the fire signal when the state is restored before the push button unit 21 is pushed down by the user. Send fire recovery signal. In addition, a test signal is transmitted when the test switch unit 22 is operated by the user. Further, when the output voltage determination unit 27b described later determines that the output voltage of the power supply unit 25 is lower than the predetermined voltage, the output voltage decrease signal is transmitted.

  The display unit 24 is a display unit for displaying information related to the transmitter 20, and includes, for example, a known LED lamp, fluorescent lamp, and the like. The output voltage detection unit 26 is an output voltage detection unit that detects the output voltage of the power supply unit 25.

  The control unit 27 is a control unit that controls each unit of the transmitter 20. Specifically, the control unit 27 is a CPU, various programs that are interpreted and executed on the CPU (a basic control program such as an OS, and the OS is started on the OS. And an internal memory such as a RAM for storing the program and various data (including a control unit 35 of the relay device 30 and a control of the receiving device 40 to be described later) The same applies to the part 46).

  The control unit 27 includes a fire signal generation unit 27a and an output voltage determination unit 27b in terms of functional concept. When the push button unit 21 receives a fire signal transmission instruction from the user, the fire signal generation unit 27a acquires transmitter identification information described later from the storage unit 28 described later, and fires the acquired transmitter identification information. Fire signal generating means for adding transmitter identification information, which will be described later, acquired from the storage unit 28, which will be described later, to the fire recovery signal when it is added to the signal or restored to the state before the push button unit 21 is pushed down by the user It is. The output voltage determination unit 27b is an output voltage determination unit that determines whether or not the output voltage detected by the output voltage detection unit 26 is lower than a predetermined voltage. Details of processing executed by the control unit 27 will be described later.

  The storage unit 28 is identification information storage means for storing transmitter identification information for uniquely identifying the transmitter 20. The storage unit 28 is configured by using a rewritable recording medium, and a non-volatile recording medium such as a flash memory can be used (a storage unit 36 of the relay device 30 and a storage unit 47 of the receiving device 40 described later). The same applies to.

(Configuration-Fire alarm system-Relay device)
Next, the configuration of the relay device 30 will be described. FIG. 4 is a block diagram illustrating an electrical configuration of the relay device 30. As illustrated in FIG. 4, the relay device 30 includes an operation unit 31, a display unit 32, a wireless communication unit 33, a power supply unit 34, a control unit 35, and a storage unit 36. Since the configuration of the power supply unit 34 is the same as that of the power supply unit in the sensor 10 described above, the description thereof will be omitted except for specially described parts.

  The operation unit 31 is an operation unit that receives an operation input to the relay device 30 and is configured using a known operation unit such as a switch or a touch panel (the same applies to the operation unit 41 of the reception device 40 described later).

  The display unit 32 is a display unit for displaying information related to the relay device 30 and is configured to include, for example, a known 7-segment display or a liquid crystal display (the same applies to the display unit 42 of the receiving device 40 described later). .

  The wireless communication unit 33 is a wireless communication unit that receives and transmits a fire signal, a fire recovery signal, a test signal, or an output voltage drop signal. The wireless communication unit 33 includes, for example, a wireless signal receiving circuit and a transmitting circuit (both not shown), and a fire signal or a fire recovery signal transmitted from the sensor 10 or the transmitter 20 via the receiving circuit. Receive a test signal or an output voltage drop signal transmitted from the transmitter 20 via the receiving circuit, and receive a fire signal, a fire recovery signal, a test signal, or a signal to the receiving device 40 via the transmitting circuit, or Transmits an output voltage drop signal.

  The control unit 35 is a control unit that controls each unit of the relay device 30. The storage unit 36 is a storage unit that stores programs and various data necessary for control by the control unit 35.

(Configuration-Fire alarm system-Receiver)
Next, the configuration of the receiving device 40 will be described. FIG. 5 is a block diagram conceptually showing the electrical configuration of the receiving device 40. As illustrated in FIG. 5, the reception device 40 includes an operation unit 41, a display unit 42, a wireless reception unit 43, a signal output unit 44, a power supply circuit unit 45, a control unit 46, and a storage unit 47. In addition, since the structure of the operation part 41 and the display part 42 is the same as that of the operation part 31 and the display part 32 in the above-mentioned relay apparatus 30, description is abbreviate | omitted except the part mentioned specially.

  The wireless receiver 43 is a wireless receiver that receives a fire signal, a fire recovery signal, a test signal, or an output voltage drop signal. The wireless reception unit 43 includes a reception circuit (not shown) for receiving a fire signal, a fire recovery signal, a test signal, or an output voltage drop signal, and the sensor 10, the transmitter 20, and / or the relay via the reception circuit. A fire signal or a fire recovery signal transmitted from the device 30 is received, or a test signal or an output voltage drop signal transmitted from the transmitter 20 and / or the relay device 30 is received via the receiving circuit.

  The signal output unit 44 outputs the fire signal received from the sensor 10, the transmitter 20, and / or the relay device 30 to the receiver 50, or the output voltage drop received from the transmitter 20 and / or the relay device 30. It is a transfer means for outputting a signal to the receiver 50. The signal output unit 44 includes an AC output unit 44a and an LC output unit 44b. The AC output unit 44a is an AC output unit that outputs a fire signal received from the transmitter 20 and / or the relay device 30 to the receiver 50 via the AC line 2d. The L-C output unit 44b outputs a fire signal received from the sensor 10 and / or the relay device 30 to the receiver 50 via the LC line 2e, or the transmitter 20 and / or the relay device. L-C output means for outputting a fire signal or output voltage drop signal received from 30 to the receiver 50.

  FIG. 6 is a schematic diagram illustrating a connection state of each terminal of the signal output unit 44. As shown in FIG. 6, the signal output unit 44 includes an A line output terminal 2a1, an A line input terminal 2a2, a C line output terminal 2b1, a C line input terminal 2b2, an L line output terminal 2c1, and an L line input terminal 2c2. It is prepared for. These A-line output terminal 2a1, C-line output terminal 2b1, and L-line output terminal 2c1 are for outputting a fire signal or an output voltage drop signal to the receiver 50, and are on the side opposite to the receiver 50 side ( The A line 2a, the C line 2b, and the L line 2c on the side opposite to the receiver 50 side with the receiving device 40 interposed therebetween are respectively connected. The A line input terminal 2a2, the C line input terminal 2b2, and the L line input terminal 2c2 are for inputting a fire signal or an output voltage drop signal to the receiver 50. The A line on the receiver 50 side. 2a, C line 2b, and L line 2c are connected to each other.

  The L line 2c that connects the L line output terminal 2c1 and the L line input terminal 2c2 is provided with a relay 2f for switching the connection of the L line 2c. Between the L line 2c connecting the L line output terminal 2c1 and the L line input terminal 2c2, and the C line 2b connecting the C line output terminal 2b1 and the C line input terminal 2b2, the L line 2c and A relay 2g for switching the connection of the C line 2b is provided. The relay 2g is disposed closer to the receiver 50 than the relay 2f. Between the A line 2a connecting the A line output terminal 2a1 and the A line input terminal 2a2, and the L line 2c connecting the L line output terminal 2c1 and the L line input terminal 2c2, the A line 2a and A relay 2h for switching the connection of the C line 2b is provided.

  Here, as a method for the signal output unit 44 to output a fire signal or an output voltage drop signal to the receiver 50, for example, the signal output unit 44 can conduct the signal line 2 connected to the receiving device 40. The fire signal of the sensor 10 or the transmitter 20 is transmitted to the receiver 50, or the output voltage drop signal of the transmitter 20 is transmitted to the receiver 50 by making it short-circuited, short-circuited, or disconnected. Specifically, when the signal output unit 44 performs a normal operation, the L-C output unit 44b connects the L line 2c with the relay 2f so that the L-C line 2e can be conducted. When the signal output unit 44 outputs a fire signal from the sensor 10 to the receiver 50, the L-C output unit 44b causes the L-C line 2e to be short-circuited. 2e is connected by the relay 2g. Further, when the signal output unit 44 outputs a fire signal of the transmitter 20 to the receiver 50, the AC output unit 44a is connected to the AC line so that the AC line 2d is short-circuited. 2d is connected by the relay 2h, and the LC output unit 44b connects the LC line 2e by a known relay 2g so that the LC line 2e is short-circuited. Further, when the signal output unit 44 outputs the output voltage drop signal of the transmitter 20 to the receiver 50, the L-C output unit 44b causes the L line 2c to break the L-C line 2e. Is disconnected by the relay 2f. In the following, “disconnection” means that either the A line 2a, the C line 2b, or the L line 2c is separated into the side closer to the receiver 50 and the side farther from the signal output unit 44 of the receiving device 40. Means that. As a result, the terminator is electrically disconnected from the receiver 50 and an output voltage drop signal is transmitted to the receiver 50.

  Returning to FIG. 5, the power supply circuit unit 45 supplies the power supplied from the receiver 50 via the power supply line 3 to each unit of the receiving device 40 (note that the power supply unit 45 supplies power to each unit of the receiving device 40. (The illustration of the lines is omitted).

  The control unit 46 is a control unit that controls each unit of the receiving device 40. The control unit 46 includes an identification information acquisition unit 46a and a reception intensity measurement unit 46b in terms of functional concept. The identification information acquisition unit 46a is identification information acquisition means for acquiring sensor identification information or transmitter identification information from the fire signal or fire recovery signal when the receiving device 40 receives the fire signal or fire recovery signal. The reception strength measurement unit 46 b is a reception strength measurement unit that measures the reception strength of the test signal received from the transmitter 20. Details of processing executed by the control unit 46 will be described later.

  The storage unit 47 includes a transfer method table 47 a that the control unit 46 refers to when the signal output unit 44 transmits a fire signal to the receiver 50. FIG. 7 is a table illustrating the contents of information stored in the transfer method table 47a. As shown in FIG. 7, in the transfer method table 47a, information corresponding to the table items “terminal ID”, “type”, and “transfer method” is stored in association with each other. The information stored in correspondence with the item “terminal ID” is identification information for uniquely identifying the sensor 10 or the transmitter 20. For example, the address number of the sensor 10 or the like (“0101”, “0102” in FIG. 9). "," 0103 ", etc.) are stored. The information stored corresponding to the item “type” is type information for specifying the type of device, and stores, for example, “sensor” and “transmitter”. The information stored corresponding to the item “transfer method” is the transfer method information for specifying the transfer method of the fire signal of the sensor 10 or the transmitter 20, for example, “LC line short circuit”. , “LC line and AC line short circuit” and the like are stored.

(Configuration-Fire alarm system-Receiver)
Next, the configuration of the receiver 50 will be described. As this receiver 50, for example, a known disaster prevention receiver can be used.

(processing)
Next, the process performed by the fire alarm system 1 configured as described above will be described. The process executed by the fire alarm system 1 is a relay process in which the fire signal or the fire recovery signal transmitted from the sensor 10 or the transmitter 20 is relayed to the receiver 50 via the receiver 40, and transmitted from the transmitter 20. Are roughly classified into a test process for confirming the transmission status of the transmitted signal and an output voltage determination process for determining whether or not the output voltage of the power supply unit 25 of the transmitter 20 is lower than a predetermined voltage. Hereinafter, these processes will be described.

(Processing-Relay processing executed by each device constituting the fire alarm system)
First, relay processing executed by each device constituting the fire alarm system 1 will be described. As shown in FIG. 1, the case where the sensor 10, the transmitter 20, the relay device 30, and the reception device 40 are installed on the third floor of the building will be described as an example. FIG. 8 is a flowchart of relay processing executed by the sensor 10, the transmitter 20, the relay device 30, and the reception device 40 (note that the operation of the relay device 30 is not shown). In the following description, “step” is abbreviated as “S”. Further, the step of the sensor 10 is abbreviated as “SA”, the step of the transmitter 20 as “SB”, and the step of the receiving device 40 as “SC”. In addition, an event that occurs during the operation of the receiving device 40 is recorded in the storage unit 47 by the control unit 46 of the receiving device 40.

  As shown in FIG. 8, when a fire is detected by the detection unit of the sensor 10 and the wireless transmission unit of the sensor 10 transmits a fire signal (SA 1), the wireless reception unit 43 of the reception device 40. Receives the fire signal from the sensor 10 wirelessly (SC1), and the signal output unit 44 transfers the fire signal of the sensor 10 received by the wireless receiver 43 to the receiver 50 ( SC2). In addition, the wireless transmission part of the sensor 10 transmits a fire signal continuously or intermittently until a detection part stops detecting a fire.

  Next, when the wireless transmission unit 23 of the transmitter 20 transmits a fire signal due to the push button unit 21 of the transmitter 20 being pressed down (SB1), the wireless reception unit 43 of the reception device 40 20 and / or a fire signal is received from the relay device 30 (SC3). Here, the signal output unit 44 of the receiver 40 is in a state where the fire signal of the detector 10 of SC2 is being transferred, but it is informed to the receiver 50 that the transmitter 20 is outputting the fire signal. In order to notify, the fire signal of the transmitter 20 received by the wireless receiver 43 is transferred to the receiver 50 instead of the fire signal of the sensor 10 (SC4). In addition, the push button part 21 of the transmitter 20 continuously or intermittently transmits a fire signal until the state before being pushed down is restored while maintaining the pushed state.

  Next, when the wireless transmission unit 23 of the transmitter 20 transmits a fire recovery signal because the push button unit 21 of the transmitter 20 is restored from the state of being pushed down by the user to the state before being pushed down (SB2). The wireless receiver 43 of the receiving device 40 receives the fire recovery signal from the transmitter 20 and / or the relay device 30 (SC5). As a result, the signal output unit 44 of the receiving device 40 recovers from the state where the fire signal of the transmitter 20 of SC4 is transferred to the state before the fire signal of the transmitter 20 is transferred, that is, The transmission of the fire signal of the transmitter 20 is stopped (SC6). Here, after the processing of SC1, the wireless reception unit 43 of the reception device 40 continuously receives the fire signal of the sensor 10 from the sensor 10 and / or the relay device 30. Therefore, after the processing of SC6, the signal output unit 44 of the receiving device 40 transfers the fire signal of the sensor 10 received by the wireless receiving unit 43 to the receiver 50 (SC7).

  Next, when a fire is no longer detected by the detection unit of the sensor 10, and the wireless transmission unit of the sensor 10 transmits a fire recovery signal (SA2), the wireless reception unit 43 of the reception device 40 10 and / or the fire recovery signal is received from the relay device 30 (SC8), and the signal output unit 44 of the receiving device 40 stops the transfer of the fire signal of the sensor 10 of SC7 (SC9).

(Processing-Relay processing)
Next, the relay processing executed by the transmitter 20 and the receiving device 40 will be described in association with the relay processing of SB1 to SB2 and SC1 to SC9 shown in FIG. FIG. 9 is a flowchart of relay processing executed by the transmitter 20 and the receiving device 40. The execution timing of this relay process is arbitrary, and is executed, for example, when the transmitter 20 is turned on and an operation input for executing the relay process is performed via the operation unit 41 of the receiving device 40. Further, it is assumed that the signal line 2 that connects the receiving device 40 and the receiver 50 is in a conductive state. In the following description, the step of the transmitter 20 is abbreviated as “SD”, and the step of the receiving device 40 is abbreviated as “SE”.

  First, the relay process of the transmitter 20 will be described. As shown in FIG. 9, first, the control unit 27 of the transmitter 20 monitors whether or not the push button unit 21 has received a fire signal transmission instruction from the user (SD1).

  Here, when the push button unit 21 is pushed down by the user and the push button unit 21 receives a fire signal transmission instruction (Yes, SD1), the fire signal generation unit 27a of the transmitter 20 identifies the transmitter. Information is acquired from the storage unit 28, and the acquired transmitter identification information is added to the fire signal (SD2). Then, the control unit 27 of the transmitter 20 causes the wireless transmission unit 23 to wirelessly transmit the fire signal to which the transmitter identification information is added (SB1) (SD3). As a result, it is possible to save signal line laying and the like compared to a wired transmitter that transmits a fire signal to the receiving device 40 via the signal line, and to reduce the installation cost and installation effort of the transmitter 20. be able to. Further, since the wireless transmission unit 23 of the transmitter 20 wirelessly transmits the fire signal to which the transmitter identification information is added by the fire signal generation unit 27a, the reception device 40 includes, for example, the transmitter. Twenty fire signals can be easily identified. In addition, the transmission method of the fire signal by the wireless transmission unit 23 is arbitrary, and in order to improve the certainty of reception of the fire signal of the relay device 30 or the reception device 40, for example, the push button unit 21 instructs the transmission of the fire signal. May be received, the wireless transmission unit 23 of the transmitter 20 may repeatedly transmit the fire signal wirelessly every predetermined time.

  Next, the control unit 27 of the transmitter 20 monitors whether or not the push button unit 21 has been restored to the state before receiving the fire signal transmission instruction by the user (SD4). Here, when the operation of the push button unit 21 by the user is not performed and the push button unit 21 maintains the state in which the instruction to transmit the fire signal is received (SD4, No), the control unit 27 of the transmitter 20 The process proceeds to SD3 and the fire signal is continuously transmitted.

  On the other hand, when the push button unit 21 is pushed up to the original position by the user, the push button unit 21 is restored to the state before accepting the fire signal transmission instruction (SD4, Yes), the fire signal of the transmitter 20 The generation unit 27a acquires transmitter identification information from the storage unit 28, and adds the acquired transmitter identification information to the fire recovery signal (SD5). Then, the control unit 27 of the transmitter 20 causes the wireless transmission unit 23 to wirelessly transmit the fire restoration signal to which the transmitter identification information is added (SB2) (SD6). As a result, it is possible to save signal line laying and the like compared to a wired transmitter that transmits a fire recovery signal to the receiving device 40 via the signal line, and further reduce the installation cost and installation effort of the transmitter 20. Can be reduced. Thereafter, the control unit 27 of the transmitter 20 proceeds to the processing of SD1.

  Next, the relay process of the receiving device 40 will be described. As shown in FIG. 9, first, the control unit 46 of the receiving device 40 monitors whether or not the wireless receiving unit 43 has received a fire signal (SE1).

  Here, when the wireless receiver 43 receives the fire signal of the sensor 10 (SC1) (SE1, Yes), the identification information acquisition unit 46a of the receiver 40 receives the sensor 10 received by the wireless receiver 43. The sensor identification information of the fire signal is acquired (SE2). Then, the control unit 46 of the receiving device 40 refers to the transfer method table 47a and causes the signal output unit 44 to short-circuit the signal line 2 in accordance with the sensor identification information acquired by the identification information acquisition unit 46a ( SC2) (SE3). Specifically, the control unit 46 of the receiving device 40 short-circuits the LC line 2e by the LC output unit 44b. Note that the control unit 46 of the reception device 40 may cause the display unit 42 to display that the L-C line 2e is in a short-circuited state. Thereby, it can alert | report that the signal wire | line 2 is a short circuit state with respect to a user. Or the control part 46 of the receiver 40 may display the individual sensor 10 by the display part 42 so that it can identify that the sensor 10 is in a fire alarm state. This facilitates the identification of the fire location.

  Subsequently, the control unit 46 of the reception device 40 monitors whether or not the wireless reception unit 43 has received a fire recovery signal (SE4). Here, when the wireless reception unit 43 has not received the fire recovery signal (SE4, No), the control unit 46 of the reception device 40 proceeds to the process of SE1.

  Next, when the wireless receiver 43 of the receiver 40 receives the fire signal of the transmitter 20 (SC3) (SE1, Yes), the identification information acquisition unit 46a of the receiver 40 receives the fire signal of the transmitter 20 received. Transmitter identification information is acquired from (SE2). Then, the control unit 46 of the receiving device 40 refers to the transfer method table 47a and shorts the signal line 2 by the signal output unit 44 according to the transmitter identification information acquired by the identification information acquisition unit 46a (SC4). ) (SE3). Specifically, the control unit 46 of the receiving device 40 short-circuits the A-C line 2d by the A-C output unit 44a while maintaining the state in which the L-C line 2e is short-circuited by the L-C output unit 44b. .

  Subsequently, the control unit 46 of the reception device 40 monitors whether or not the wireless reception unit 43 has received a fire recovery signal (SE4). Here, when the wireless reception unit 43 has not received the fire recovery signal (SE4, No), the control unit 46 of the reception device 40 proceeds to the process of SE1.

  Next, after processing of SE1 to SE3, or without the wireless reception unit 43 of the reception device 40 receiving a fire signal (SE1, No), the wireless reception unit 43 of the reception device 40 transmits a fire recovery signal of the transmitter 20. When received (SC5) (SE4, Yes), the identification information acquisition unit 46a of the receiver 40 acquires transmitter identification information from the received fire recovery signal of the transmitter 20 (SE5).

  Next, the control unit 46 of the receiving device 40 recovers from the state in which the signal line 2 is short-circuited by the signal output unit 44 to the state before short-circuiting according to the transmitter identification information acquired by the identification information acquisition unit 46a. (SC6) (SE6). Here, since the wireless reception unit 43 of the reception device 40 continuously receives the fire signal of the sensor 10 after the processing of SC1, the control unit 46 of the reception device 40 is detected by the signal output unit 44. Of the signal line 2 overlapping when the signal line 2 is short-circuited according to the sensor identification information of the transmitter 10 and when the signal line 2 is short-circuited according to the transmitter identification information of the transmitter 20 While maintaining the short circuit state, the other part of the non-overlapping signal line 2 is restored (SC7) (SE6). Specifically, the control unit 46 of the receiving device 40 opens the AC line 2d from the short-circuited state by the A-C output unit 44a while maintaining the short-circuited state of the L-C line 2e by the L-C output unit 44b. Restore to the state. Thereafter, the control unit 46 of the receiving device 40 proceeds to the processing of SE1.

  Next, after processing of SE <b> 1 to SE <b> 3 or without the wireless reception unit 43 of the reception device 40 receiving a fire signal (No in SE <b> 1), the wireless reception unit 43 of the reception device 40 transmits a fire recovery signal of the sensor 10. When received (SC8) (SE4, Yes), the identification information acquisition unit 46a of the receiving device 40 acquires sensor identification information from the received fire recovery signal of the sensor 10 (SE5).

  Subsequently, the control unit 46 of the receiving device 40 changes from the state in which the signal line 2 is short-circuited by the signal output unit 44 to the state before short-circuiting according to the sensor identification information acquired by the identification information acquisition unit 46a. Restore (SC9) (SE6). Specifically, the control unit 46 of the receiving device 40 restores the L-C line 2e from the short-circuited state to the conductive state by the L-C output unit 44b. Thereafter, the control unit 46 of the receiving device 40 proceeds to the processing of SE1.

(Processing-Test processing)
Next, a test process executed by the transmitter 20 and the receiving device 40 will be described. FIG. 10 is a flowchart of a test process executed by the transmitter 20 and the receiving device 40. The execution timing of the test process is arbitrary. For example, the test process is executed when the transmitter 20 is turned on and an operation input for executing the test process is performed via the operation unit 41 of the receiving device 40. In the following description, the step of the transmitter 20 is abbreviated as “SF”, and the step of the receiving device 40 is abbreviated as “SG”.

  As shown in FIG. 10, first, the control unit 27 of the transmitter 20 monitors whether or not the test switch unit 22 has received a test signal transmission instruction from the user (SF1). Here, when the test switch unit 22 is turned on by the user and the test switch unit 22 receives an instruction to transmit a fire signal (SF1, Yes), the control unit 27 of the transmitter 20 A test signal is transmitted wirelessly by the transmitter 23 (SF2). Note that at the same timing as the processing of SF2, the control unit 27 of the transmitter 20 may display on the display unit 24 that the test switch unit 22 has received a test signal transmission instruction from the user. Specifically, the control unit 27 of the transmitter 20 is turned on or blinked for about 5 seconds by the display unit 24 at the timing when the test switch unit 22 is turned on by the user. Thereby, it can be shown that the test signal is transmitted to the user.

  Next, the control unit 46 of the receiving device 40 monitors whether or not the wireless receiving unit 43 has received a test signal (SG1). Here, when the wireless reception unit 43 receives the test signal (SG1, Yes), the reception intensity measurement unit 46b of the reception device 40 measures the reception intensity of the received test signal (SG2). Next, the control unit 46 of the receiving device 40 causes the display unit 42 to display the test signal reception intensity measured by the reception intensity measurement unit 46b (SG3). Thereby, based on the received strength of the test signal, the transmission status of the signal transmitted from the transmitter 20 can be presented to the user. Further, the receiver 40 does not relay signals other than the fire signal and the output voltage drop signal to the receiver 50. Therefore, since the control unit 46 of the receiving device 40 does not cause the receiver 50 to transfer the test signal by the signal output unit 44, the receiver 50 can be prevented from receiving the test signal, It is possible to prevent a fire alarm or the like from being erroneously issued in the receiver 50 during processing.

(Processing-Output voltage judgment processing)
Next, output voltage determination processing executed by the transmitter 20 and the receiving device 40 will be described. FIG. 11 is a flowchart of output voltage determination processing executed by the transmitter 20 and the receiving device 40. The execution timing of the output voltage determination process is arbitrary, and for example, when the transmitter 20 and the receiver 40 are turned on, the output voltage determination process is automatically and repeatedly executed at a predetermined cycle. Further, it is assumed that the signal line 2 that connects the receiving device 40 and the receiver 50 is in a conductive state. In the following description, the step of the transmitter 20 is abbreviated as “SH”, and the step of the receiving device 40 is abbreviated as “SJ”.

  As shown in FIG. 11, first, the control unit 27 of the transmitter 20 monitors whether or not a predetermined monitoring time has come (SH1). Here, when the predetermined monitoring time has arrived (SH1, Yes), the control unit 27 of the transmitter 20 causes the output voltage detection unit 26 to measure the output voltage of the power supply unit 25 (SH2).

  Next, the output voltage determination unit 27b of the transmitter 20 determines whether or not the output voltage measured by the output voltage detection unit 26 is lower than a predetermined voltage (SH3). Here, when the output voltage measured by the output voltage detection unit 26 is higher than the predetermined voltage (SH3, No), the control unit 27 of the transmitter 20 ends the process.

  On the other hand, when the output voltage measured by the output voltage detection unit 26 is lower than the predetermined voltage (SH3, Yes), the control unit 27 of the transmitter 20 transmits the output voltage drop signal wirelessly by the wireless transmission unit 23. Transmit (SH4).

  Subsequently, the control unit 46 of the reception device 40 monitors whether or not the wireless reception unit 43 has received the output voltage drop signal (SJ1). Here, when the wireless reception unit 43 receives the output voltage drop signal (SJ1, Yes), the control unit 46 of the reception device 40 causes the signal output unit 44 to disconnect the signal line 2 (SJ2). Specifically, the control unit 46 of the receiving device 40 disconnects the LC line 2e by the LC output unit 44b. Thus, since the output voltage drop signal can be transferred to the receiver 50, the user can be notified that the output voltage of the battery has dropped.

(effect)
Thus, according to the embodiment, the transmitter 20 has a push button unit 21 that receives a fire signal transmission instruction by a user, and when the push button unit 21 receives a fire signal transmission instruction from a user, Since it has a wireless transmission unit 23 that wirelessly transmits a fire signal, it is possible to transmit a fire signal to other devices without a signal line, and compared to a wired transmitter, the installation cost and labor of installation Can be reduced.

  Moreover, since the wireless transmission unit 23 of the transmitter 20 wirelessly transmits the fire signal to which the transmitter identification information is added by the fire signal generation unit 27a of the transmitter 20, the receiver 40 side or the receiver 50 side If there is a function for displaying the fire state in such a way that the individual sensor 10 that transmitted the fire signal can be identified, the fire signal of the transmitter 20 can be easily identified and the position of the fire can be easily identified.

  In addition, when the push button unit 21 of the transmitter 20 receives a fire signal transmission instruction from the user, the wireless transmission unit 23 of the transmitter 20 repeats the fire signal wirelessly every predetermined time (for example, every 5 seconds). Since transmission is performed, it is possible to improve the certainty of receiving fire signals to other devices, and it is possible to ensure the stability of communication equivalent to that of a wired transmitter.

  Further, when the push button unit 21 of the transmitter 20 maintains the state in which the instruction to transmit the fire signal is received from the user, the wireless transmission unit 23 of the transmitter 20 transmits the fire signal wirelessly. When the push button unit 21 of the machine 20 is restored to the state before the user receives the fire signal transmission instruction, the wireless transmission unit 23 of the transmitter 20 stops the transmission of the fire signal and the fire restoration signal Is transmitted wirelessly, a fire recovery signal can be transmitted to other devices without a signal line, and the installation cost and installation effort can be further reduced compared to a wired transmitter.

  In addition, the wireless transmission unit 23 of the transmitter 20 transmits the test signal wirelessly when the test switch unit 22 of the transmitter 20 receives a test signal transmission instruction from the user. The transmission status of the signal transmitted from the machine 20 can be confirmed, and the communication stability equivalent to that of the wired transmitter can be further ensured.

  Further, when the test switch unit 22 of the transmitter 20 receives a test signal transmission instruction from the user, the display unit 24 of the transmitter 20 displays that fact, so the test signal is transmitted to the user. It is possible to easily indicate that the transmitter 20 is performing a test process.

  In addition, the wireless transmission unit 23 of the transmitter 20 outputs an output voltage drop signal when the output voltage determination unit 27b of the transmitter 20 determines that the output voltage of the power supply unit 25 of the transmitter 20 is lower than a predetermined voltage. Can be notified to the user that the output voltage of the power supply unit 25 of the transmitter 20 has decreased, and the user can perform maintenance of the power supply unit 25 after the notification. The stability of communication equivalent to that of a wired transmitter can be further ensured.

  The fire alarm system 1 includes a transmitter 20 and a receiving device 40. The transmitter 20 includes a push button unit 21 for receiving a fire signal transmission instruction from a user, and the push button unit 21 includes a user. And a wireless transmission unit 23 that wirelessly transmits a fire signal when a fire signal transmission instruction is received from the receiver, and the receiving device 40 transfers the signal received from the transmitter 20 to the receiver 50. Signal output unit 44 and a control unit 46 that, when receiving a fire signal from the transmitter 20, causes the signal output unit 44 to transfer the received fire signal to the receiver 50. 40 can receive a fire signal from the transmitter 20 wirelessly, and can transfer the received fire signal to the receiver 50, and is configured to include a wired transmitter. It is possible to reduce the installation cost and installation effort compared with beam 1.

  In addition, when a test signal is received from the transmitter 20, the reception intensity measuring unit 46 b of the receiving device 40 measures the reception intensity of the received test signal, and the control unit 46 displays the measured reception intensity using the display unit 42. Since it is displayed, the transmission status of the signal transmitted from the transmitter 20 can be presented to the user based on the reception strength of the test signal, and an installation environment where radio waves reach with sufficient strength based on this transmission status is obtained. Since the installation position can be selected by the user, communication stability equivalent to that of a wired transmitter can be ensured. Further, since the control unit 46 of the receiving device 40 does not cause the receiver 50 to transfer the test signal by the signal output unit 44, the receiver 50 can be prevented from receiving the test signal, and the test can be performed. It is possible to prevent a fire alarm or the like from being erroneously issued in the receiver 50 during processing.

[Modifications to Embodiment]
Although the embodiments of the present invention have been described above, the specific configuration and means of the present invention can be arbitrarily modified and improved within the scope of the technical idea of each invention described in the claims. Can do. Hereinafter, such a modification will be described.

(About problems to be solved and effects of the invention)
First, the problems to be solved by the invention and the effects of the invention are not limited to the above-described contents, and the present invention solves the problems not described above or has the effects not described above. There are also cases where only some of the described problems are solved or only some of the described effects are achieved.

(About distribution and integration)
Each electrical component of the fire alarm system 1 described above is functionally conceptual and does not necessarily need to be physically configured as illustrated. That is, the specific form of distribution or integration of each part is not limited to the one shown in the figure, and all or a part thereof is functionally or physically distributed or integrated in arbitrary units according to various loads or usage conditions. Can be configured.

(About sensor)
In the above-described embodiment, the wireless transmission unit of the sensor 10 has been described as transmitting a fire signal or a fire recovery signal, but the present invention is not limited to this. For example, the wireless transmission unit may periodically transmit the sensor identification information of the sensor 10 in order to monitor the operation status of the sensor 10. In this case, when it is determined that the wireless reception unit 43 of the reception device 40 has not received the sensor identification information periodically, the control unit 46 of the reception device 40 disconnects the signal line 2 by the signal output unit 44. You may let them. Specifically, the control unit 46 of the receiving device 40 disconnects the LC line 2e by the LC output unit 44b (the same applies to the wireless transmission unit 23 of the transmitter 20).

(About transmitter identification information)
In the above-described embodiment, the transmitter identification information has been described as information for uniquely identifying the transmitter 20, but is not limited to identifying each of the transmitters 20. For example, the transmitter identification information simply identifies the transmitter 20. It may be information.

(About processing of receiving device 40)
When the receiving device 40 receives a fire signal or a fire recovery signal, the processing performed by the receiving device 40 is not limited to the processing of the above-described embodiment. That is, when a fire signal is transmitted from each of a plurality of terminal devices (here, the sensor 10, the transmitter 20, and the relay device 30), the receiving device 40 connects the signal lines 2 in the order in which the fire signals are transmitted. Short-circuit in the form corresponding to each fire signal. In this short-circuit processing, if there is a part that has already been short-circuited in the signal line 2 to be short-circuited, only the remaining part may be short-circuited. Alternatively, in the signal line 2 to be short-circuited, the next part to be short-circuited includes a part that overlaps the part that has already been short-circuited, and the number of parts to be short-circuited is smaller than the part that has already been short-circuited In this case, the remaining part may be restored by maintaining the already short-circuited part or maintaining the short-circuit state of the part that is already short-circuited and the part that is next short-circuited. Moreover, when a fire recovery signal is transmitted from each of the plurality of terminal devices, the receiving device 40 is in a state in which the signal line 2 can be conducted in a form corresponding to each fire recovery signal in the order in which the fire recovery signal is transmitted. Restore. In this restoration process, if there is a part that has already been restored in the signal line 2 to be restored, it is sufficient to restore only the remaining part. When there is a terminal device that does not transmit, only the other portion is restored while the shorted portion in a form corresponding to the fire signal from the terminal device is maintained in the short-circuited state.

  For example, when the push button unit 21 of the transmitter 20 is pressed down, the wireless transmission unit 23 of the transmitter 20 transmits a fire signal, and then the detection unit of the sensor 10 detects the fire. Even when the wire transmission unit of the transmitter 10 transmits a fire signal, the wireless reception unit 43 of the receiver 40 receives the fire recovery signal from the sensor 10 or the transmitter 20, thereby receiving the receiver 40. The signal output unit 44 stops the fire signal transmission to the receiver 50. Specifically, first, when the wireless receiver 43 of the receiver 40 receives a fire signal from the transmitter 20, the controller 46 of the receiver 40 uses the signal output unit 44 to identify the transmitter of the transmitter 20. The signal line 2 is short-circuited according to information. Next, when the wireless reception unit 43 of the reception device 40 receives the fire signal of the sensor 10, the control unit 46 of the reception device 40 performs a signal according to the sensor identification information of the sensor 10 by the signal output unit 44. Wire 2 is short-circuited. In this case, since the portion for short-circuiting the signal line 2 according to the sensor identification information is smaller than the portion for short-circuiting the signal line 2 according to the transmitter identification information, the control unit 46 of the receiving device 40 is configured to be a signal output unit. 44, the state in which the signal line 2 is short-circuited according to the transmitter identification information is maintained (for this, in the transmission of the fire signal of the transmitter 20, the AC line 2d and the LC line 2e are short-circuited). The fire signal from the sensor 10 is transferred on the premise that the L-C line 2e is short-circuited. Next, when the wireless receiver 43 of the receiver 40 first receives the fire recovery signal of the transmitter 20, the controller 46 of the receiver 40 uses the signal output unit 44 to detect the sensor identification information of the sensor 10. While maintaining the short-circuit state of a part of the overlapping signal line 2 in the case where the signal line 2 is short-circuited according to and the case where the signal line 2 is short-circuited according to the transmitter identification information of the transmitter 20, The other part of the non-overlapping signal line 2 is restored. Thereafter, when the wireless receiver 43 of the receiver 40 receives the fire recovery signal of the sensor 10, the controller 46 of the receiver 40 responds to the sensor identification information of the sensor 10 by the signal output unit 44. Thus, the signal line 2 is restored to a conductive state. On the other hand, when the wireless receiver 43 of the receiver 40 first receives the fire recovery signal of the sensor 10, the controller 46 of the receiver 40 uses the signal output unit 44 to change the sensor identification information of the sensor 10. In response, the signal line 2 is short-circuited and the signal line 2 is short-circuited according to the transmitter identification information of the transmitter 20 while maintaining the short-circuit state of a part of the overlapping signal lines 2 while transmitting. The short-circuit state of a part of the signal line 2 used only for transferring the fire signal of the machine is also maintained. Thereafter, when the wireless reception unit 43 of the receiving device 40 receives the fire recovery signal of the transmitter 20, the control unit 46 of the receiving device 40 responds to the transmitter identification information of the transmitter 20 by the signal output unit 44. Thus, the signal line 2 is restored to a conductive state.

  Further, when a plurality of transmitters 20 are provided in the fire alarm system 1 (here, two transmitters 20 are provided), the push button portion 21 of one transmitter 20 is pushed down. Thus, after the wireless transmission unit 23 of the transmitter 20 transmits a fire signal, the push button unit 21 of the other transmitter 20 is pushed down, so that the wireless transmission unit 23 of the transmitter 20 Even in the relay process when a fire signal is transmitted, the signal output unit 44 of the receiver 40 receives the fire recovery signal from the transmitter 20 so that the signal output unit 44 of the receiver 40 receives the signal from the receiver 50. Stop the transmission of fire signals. Specifically, first, when the wireless reception unit 43 of the reception device 40 receives a fire signal from one transmitter 20, the control unit 46 of the reception device 40 transmits the transmission of the transmitter 20 by the signal output unit 44. The signal line 2 is short-circuited according to the machine identification information. Next, when the wireless receiver 43 of the receiver 40 receives the fire signal of the other transmitter 20, the controller 46 of the receiver 40 uses the signal output unit 44 to change the transmitter identification information of the transmitter 20. In response, the signal line 2 is short-circuited. In this case, since the part which short-circuits the signal line 2 according to these transmitter identification information is the same, the control part 46 of the receiver 40 uses the signal output part 44 according to the transmitter identification information. Is kept short-circuited. Next, when the wireless receiver 43 of the receiving device 40 receives the fire recovery signal of one of the two transmitters 20, the short-circuit state of the signal line 2 corresponding to the transmitter identification information of these transmitters 20 Therefore, the control unit 46 of the receiving device 40 causes the signal output unit 44 to maintain the short-circuit state of the signal line 2 as it is. Thereafter, when the wireless receiver 43 of the receiver 40 receives the other fire recovery signal of the transmitter 20, the controller 46 of the receiver 40 uses the signal output unit 44 to transmit the transmitter of the transmitter 20. The signal line 2 is restored to a conductive state according to the identification information.

(About test processing)
In the above-described embodiment, the control unit 27 of the transmitter 20 has been described as transmitting the test signal wirelessly by the wireless transmission unit 23 in SF2, but the present invention is not limited to this. For example, when a test process for a plurality of transmitters 20 is performed, the fire signal generation unit 27a of the transmitter 20 acquires transmitter identification information from the storage unit 28, and uses the acquired transmitter identification information as a test signal. In addition, the control unit 27 of the transmitter 20 causes the wireless transmission unit 23 to wirelessly transmit the test signal to which the transmitter identification information is added. Then, the identification information acquisition unit 46a of the reception device 40 acquires transmitter identification information included in the test signal received from the wireless reception unit 43, and the control unit 46 of the reception device 40 is measured by the reception intensity measurement unit 46b. The display unit 42 displays a list of the received signal strengths of the test signals of the transmitters 20 in association with the acquired transmitter identification information. Thereby, even if it is a test process of the some transmitter 20, it can carry out rapidly and correctly.

(About output voltage drop judgment processing)
In the above-described embodiment, the output voltage decrease determination process when the wireless transmission unit 23 of the transmitter 20 transmits the output voltage decrease determination signal has been described. However, the present invention is not limited to this, and for example, the wireless transmission unit of the sensor 10 May be an output voltage decrease determination process when an output voltage decrease determination signal is transmitted. In this case, the sensor 10 includes an output voltage detection unit and an output voltage determination unit in addition to each component.

  In addition, when the output voltage decrease determination process of the plurality of transmitters 20 or the output voltage decrease determination process including the sensor 10 and the transmitter 20 is performed, the fire signal generation unit 27a of the transmitter 20 identifies the transmitter. The information is acquired from the storage unit 28, the acquired transmitter identification information is added to the output voltage drop signal, and the control unit 27 of the transmitter 20 transmits the output voltage drop signal with the transmitter identification information added thereto to the wireless transmission unit. 23 is transmitted wirelessly. The wireless transmission unit of the sensor 10 also transmits the output voltage drop signal including the sensor identification information. Then, the identification information acquisition unit 46a of the reception device 40 acquires transmitter identification information or sensor identification information included in the output voltage drop signal received from the wireless reception unit 43, and the control unit 46 of the reception device 40 receives the signal output unit. The signal line 2 is disconnected by 44 and the acquired transmitter identification information or sensor identification information is displayed on the display unit 42. Thereby, even if it is the output voltage fall determination process of the some transmitter 20, or the output voltage fall determination process including the sensor 10 and the transmitter 20, it can be performed rapidly and correctly.

( First note)
The transmitter according to the first supplementary note 1 is a transmitter that transmits a fire signal for notifying a fire, and an operation unit that receives an instruction to transmit the fire signal from a user, and the operation unit transmits the fire signal from the user. And a wireless transmission means for wirelessly transmitting the fire signal when an instruction is accepted.

Further, the transmitter of the first supplementary note 2 is the transmitter of the first supplementary note 1, in which the identification information storing means for storing the identification information for identifying the transmitter and the operation means are received from the user. A fire signal generating means for acquiring the identification information from the identification information storage means and adding the acquired identification information to the fire signal when receiving a fire signal transmission instruction; Transmits wirelessly the fire signal to which the identification information is added by the fire signal generating means.

Further, the transmitter of the first supplementary note 3 is the transmitter of the first supplementary note 1 or 2, wherein the wireless transmission means is configured such that when the operation means accepts a fire signal transmission instruction from a user, The fire signal is repeatedly transmitted by radio every predetermined time.

Further, transmitter of the first appendix 4, in the transmitter according to any one of the first Appendix 1 to 3, wherein the transmitter has been made to send a fire reset signal for notifying the fire reset In the case where the wireless transmission means transmits the fire signal wirelessly while the operation means maintains the state in which the instruction to transmit the fire signal is received from the user, the operation means is configured to transmit the fire signal by the user. When the state before the transmission instruction is received is restored, the wireless transmission means stops transmitting the fire signal and transmits the fire recovery signal wirelessly.

Further, transmitter of the first appendix 5, test for the transmitter according to any one of the first appendix 1 to 4, wherein the transmitter is to check the transmission status of the signal transmitted from the self A test operation means for transmitting a signal and receiving a test signal transmission instruction by a user, and the wireless transmission means, when the test operation means receives a test signal transmission instruction from a user, The test signal is transmitted wirelessly.

Further, the transmitter of the first supplementary note 6 is a transmitter that displays the fact that when the test operation means accepts an instruction to transmit the test signal from the user in the transmitter of the first supplementary note 5. Is provided.

Further, transmitter of the first appendix 7, the transmitter according to any one of the first appendix 1 to 6, wherein the transmitter is intended with a battery for supplying power, and An output voltage drop signal for notifying the battery output voltage drop is transmitted, the output voltage detection means for detecting the output voltage of the battery, and the output voltage detected by the output voltage detection means Output voltage determining means for determining whether or not the output voltage is lower than a predetermined voltage, and when the output voltage determining means determines that the output voltage of the battery is lower than the predetermined voltage, The output voltage drop signal is transmitted.

The fire notification system according to the first supplementary note 8 is a fire notification system that detects a fire in a monitoring area and issues an alarm, and a transmitter that transmits a fire signal that notifies the fire and a transmitter that receives the fire signal. A receiving device that relays a fire signal to a receiver, wherein the transmitter has an operation means for receiving a fire signal transmission instruction by a user, and the operation means has received a fire signal transmission instruction from a user. Wireless transmission means for wirelessly transmitting the fire signal, and the reception device includes a transmission means for transferring the signal received from the transmitter to the receiver, and the transmitter. Control means for causing the transfer means to transfer the received fire signal to the receiver when the fire signal is received.

The fire alarm system according to the first supplementary note 9 is the fire alarm system according to the first supplementary note 8, wherein the transmitter transmits a test signal for confirming a transmission status of a signal transmitted from itself. Test operation means for receiving an instruction to transmit the test signal by a user, and when the test operation means receives an instruction to transmit the test signal from a user, the wireless transmission means wirelessly transmits the test signal. The reception device comprises a reception strength measurement means for measuring the reception strength of the test signal received from the transmitter, and a display means for displaying the reception strength measured by the reception strength measurement means, When the test signal is received from the transmitter, the reception strength measuring unit measures the reception strength of the received test signal, and the control unit displays the measured reception strength. To be displayed by the stage.

(Effect of the first supplementary note)
According to the transmitter described in the first supplementary note 1, the transmitter is configured to receive a fire signal transmission instruction from the user, and when the operation means receives a fire signal transmission instruction from the user, Because it is equipped with wireless transmission means that transmits signals wirelessly, it can transmit a fire signal to other devices even without a signal line, reducing installation costs and labor compared to wired transmitters can do.

Further, according to the transmitter described in the first supplementary note 2, since the wireless transmission means wirelessly transmits the fire signal to which the transmitter identification information is added by the fire signal generation means, the receiving device or the receiver If there is a function to display the fire status in a way that can identify the individual sensor that sent the fire signal to the side, it can easily identify the fire signal of the transmitter and easily identify the location of the fire it can.

In addition, according to the transmitter described in the first supplementary note 3, the wireless transmission unit repeatedly transmits the fire signal wirelessly every predetermined time when the operation unit receives a fire signal transmission instruction from the user. Therefore, it is possible to improve the certainty of receiving fire signals to other devices, and to ensure the stability of communication equivalent to that of a wired transmitter.

Further, according to the transmitter described in the first supplementary note 4, the wireless transmission unit transmits the fire signal wirelessly while maintaining the state in which the operation unit receives the fire signal transmission instruction from the user. In the case where the operation means is restored to the state before receiving the fire signal transmission instruction by the user, the wireless transmission means stops the transmission of the fire signal and transmits the fire recovery signal wirelessly. Even if there is no signal line, a fire recovery signal can be transmitted to other devices, and the installation cost and installation effort can be further reduced as compared with a wired transmitter.

Further, according to the transmitter described in the first supplementary note 5, the wireless transmission means transmits the test signal wirelessly when the test operation means accepts a test signal transmission instruction from the user. Can be used to confirm the transmission status of a signal transmitted from the transmitter, and the stability of communication equivalent to that of a wired transmitter can be further ensured.

Further, according to the transmitter described in the first supplementary note 6, when the test operation means receives a test signal transmission instruction from the user, the display means displays the fact, so that the test signal is sent to the user. It can be shown that it is being transmitted, and it can be easily identified that the transmitter is performing a test process.

Further, according to the transmitter described in the first supplementary note 7, the wireless transmission unit transmits the output voltage decrease signal when the output voltage determination unit determines that the output voltage of the battery is lower than the predetermined voltage. Therefore, it is possible to notify the user that the output voltage of the battery has decreased, for example, by allowing the user to maintain the battery after the notification is made, it is equivalent to a wired transmitter. The stability of communication can be further ensured.

Further, according to the fire alarm system described in the first supplementary note 8, the fire alarm system is configured to include a transmitter and a receiver, and among these, the transmitter receives an operation for receiving a fire signal transmission instruction from the user. And a wireless transmission means for wirelessly transmitting the fire signal when the operation means receives a fire signal transmission instruction from the user, and the receiving device transfers the signal received from the transmitter to the receiver. A transmission means for reporting, and a control means for causing the transmission means to transfer the received fire signal to the receiver when a fire signal is received from the transmitter. It is possible to receive a fire signal wirelessly from the machine and transfer the received fire signal to the receiver, and compared to a fire alarm system configured with a wired transmitter, the installation cost and installation It is possible to reduce the between.

Further, according to the fire alarm system described in the first supplementary note 9, when the test signal is received from the transmitter, the reception intensity measuring means of the receiving device measures the reception intensity of the received test signal, and the control means Displays the measured reception strength by the display means, so that the transmission status of the signal transmitted from the transmitter can be presented to the user based on the reception strength of the test signal. Since the user can select an installation position as an installation environment where radio waves reach with strength, the stability of communication equivalent to that of a wired transmitter can be ensured. In addition, since the control means of the receiving device does not cause the receiver to transfer the test signal by the transferring means, the receiver can be prevented from receiving the test signal. It is possible to prevent a fire alarm or the like from being erroneously issued.
(Second supplementary note)
The receiving device according to the second supplementary note 1 is a receiving device connected to the receiver via a plurality of signal lines, and the first fire signal transmitted from the first fire notification terminal to notify the fire. Or wireless receiving means for wirelessly receiving a second fire signal transmitted from a second fire notification terminal different from the first fire notification terminal for notifying the fire, and receiving the first fire signal wirelessly When the means receives the first fire signal, the wireless reception means sends the second fire signal to the receiver in order to transfer the first fire signal to the receiver. Control means for setting the connection state of the plurality of signal lines to a second connection state different from the first connection state in order to transfer the second fire signal to the receiver when received. Prepare.
The receiving device according to the second supplementary note 2 is the receiving device according to the second supplementary note 1, wherein the control means receives the first fire signal only when the wireless receiving means receives the plurality of signal lines. When the wireless reception means further receives the second fire signal while the wireless reception means continues to receive the first fire signal, the plurality of connection states are set to the first connection state. The signal line connection state is changed to the first connection state to be the second connection state.
Further, the receiving device according to the second supplementary note 3 is the receiving device according to the second supplementary note 2, wherein the wireless receiving means transmits the fire recovery transmitted by the second fire notification terminal to notify the recovery from the fire. A signal is further received, and the control means further receives the second fire signal while the wireless receiving means continues to receive the first fire signal, and the wireless receiving means receives the second fire signal. When the wireless reception means receives the fire recovery signal instead of the second fire signal while the wireless reception means is still receiving the one fire signal, the connection state of the plurality of signal lines is The first connection state is used instead of the second connection state.
The receiving device according to the second supplementary note 4 is the receiving device according to the second supplementary note 2 or 3, wherein the plurality of signal lines include first to third signal lines, and the first connection state is The second connection is a connection state in which the first signal line and the second signal line are short-circuited, and the third signal line and the first and second signal lines are open. The state is a connection state in which the first signal line and the second signal line are short-circuited, and the second signal line and the third signal line are short-circuited.

1 Fire alarm system 2, 102 Signal line 2a, 102a A line 2a1 A line output terminal 2a2 A line input terminal 2b, 102b C line 2b1 C line output terminal 2b2 C line input terminal 2c, 102c L line 2c1 L line output terminal 2c2 L-line input terminal 2d A-C line 2e L-C line 2f, 2g, 2h Relay 3 Power line 10 Sensor 20, 130 Transmitter 21 Push button part 22 Test switch part 23 Wireless transmission part 24, 32, 42 Display part 25, 34 Power supply unit 26 Output voltage detection unit 27, 35, 46 Control unit 27a Fire signal generation unit 27b Output voltage determination unit 28, 36, 47 Storage unit 30 Relay device 31, 41 Operation unit 33 Wireless communication unit 40, 140 Reception Device 43 Wireless receiver 44 Signal output unit 44a A-C output unit 44b L-C output unit 45 Power supply circuit unit 46a Identification Information acquisition unit 46b Reception strength measurement unit 47a Transfer method table 50, 150 Receiver 101 Disaster prevention system 110 Wired sensor 120 Wireless sensor

Claims (4)

A receiving device connected to a receiver via a plurality of signal lines,
A first fire signal transmitted by the first fire information terminal to notify the fire, and includes a first fire signal including first identification information for uniquely identifying the first fire information terminal , or notifies the fire A second fire signal transmitted by a second fire information terminal different from the first fire information terminal and including second identification information for uniquely identifying the second fire information terminal Wireless receiving means for receiving wirelessly;
When the wireless receiving means receives the first fire signal wirelessly, the wireless receiving means acquires the first identification information included in the received first fire signal, and the wireless receiving means receives the second fire signal. Identification information acquisition means for acquiring the second identification information included in the received second fire signal,
If the first identification information acquired by the identification information acquiring means, to perform the transfer paper of the first fire signal to the receiver, the connection status of the plurality of signal lines as the first connection state, the When the identification information acquisition means acquires the second identification information, the connection state of the plurality of signal lines is different from the first connection state so that the second fire signal is transferred to the receiver. Control means for setting the second connection state,
Receiver device. When the wireless reception means receives only the first fire signal and the identification information acquisition means acquires only the first identification information, the control means determines the connection state of the plurality of signal lines. When the wireless reception means further receives the second fire signal while the wireless reception means continues to receive the first fire signal , the second identification information is When the identification information acquisition means acquires , the connection state of the plurality of signal lines is changed to the first connection state to the second connection state,
The receiving device according to claim 1. The wireless receiving means further receives a fire recovery signal including the second identification information, which is a fire recovery signal transmitted by the second fire notification terminal to notify the recovery from the fire,
The identification information acquisition means acquires the second identification information included in the received fire recovery signal when the wireless reception means wirelessly receives the fire recovery signal,
The control means further receives the second fire signal after the wireless receiving means receives the first fire signal while the wireless receiving means continues to receive the first fire signal. In the case where the wireless reception means receives the fire recovery signal instead of the second fire signal while the reception means continues to receive, and the identification information acquisition means acquires the second identification information The connection state of the plurality of signal lines is changed to the second connection state to be the first connection state.
The receiving device according to claim 2. The plurality of signal lines include first to third signal lines,
The first connection state is a connection state in which the first signal line and the second signal line are short-circuited, and the third signal line and the first and second signal lines are open. Yes,
The second connection state is a connection state in which the first signal line and the second signal line are short-circuited, and the second signal line and the third signal line are short-circuited.
The receiving device according to claim 2 or 3.

Images