JP6566353B2 - Automatic fire alarm system slave unit, automatic fire alarm system, and automatic fire alarm system master unit - Google Patents

Description

  The present invention relates to a slave unit of an automatic fire notification system, an automatic fire notification system, and a master unit of an automatic fire notification system.

  Conventionally, an automatic fire alarm system configured by connecting a fire sensor (slave unit) to a sensor line (a pair of wires) derived from a fire receiver (master unit) is known. Is disclosed. The fire receiver of this automatic fire alarm system is configured to output a control signal to a fire detector via a sensor line. The fire detector is configured to execute an abnormality detection mode when receiving a control signal from the fire receiver.

JP 2002-8154 A

  By the way, in the automatic fire alarm system like the above-mentioned conventional example, reduction of power consumption is desired.

  An object of this invention is to provide the subunit | mobile_unit of an automatic fire alarm system which can reduce power consumption, an automatic fire alarm system, and the main | base station of an automatic fire alarm system.

The slave unit of the automatic fire alarm system of the present invention includes a receiving unit that is electrically connected to a pair of wires and receives a signal transmitted from the master unit by changing a voltage applied between the pair of wires. A control unit that switches a state of the receiving unit to either a receiving operation state in which the receiving unit operates or a reception stop state in which the operation of the receiving unit stops, and the control unit includes the receiving unit Depending on whether or not to supply a power supply signal to the receiving unit as the operating power, the state of the receiving unit is switched to either the receiving operation state or the reception stop state, the control unit from the base unit For each minimum bit width of the transmitted synchronization signal, the state of the reception unit is alternately switched a plurality of times between the reception operation state and the reception stop state .

  An automatic fire alarm system of the present invention includes a slave unit of the above automatic fire alarm system and a master unit that applies a voltage between the pair of electric wires, and the master unit changes a voltage between the pair of electric wires. And a transmitter that transmits a signal to the slave unit.

  The base unit of the automatic fire notification system according to the present invention is used in the above automatic fire notification system.

  The slave unit, the automatic fire notification system, and the master unit of the automatic fire notification system of the present invention can reduce power consumption.

It is a block diagram which shows schematic structure of the subunit | mobile_unit of the automatic fire alarm system which concerns on embodiment. It is a block diagram showing a schematic structure of an automatic fire information system concerning an embodiment. It is a schematic circuit diagram of the receiving part in the subunit | mobile_unit of the automatic fire alarm system which concerns on embodiment. It is a block diagram which shows schematic structure of the modification 1 of the control part in the subunit | mobile_unit of the automatic fire alarm system which concerns on embodiment. It is a block diagram which shows schematic structure of the modification 1 of the control part which incorporated the oscillation part in the microcomputer in the subunit | mobile_unit of the automatic fire alarm system which concerns on embodiment. FIG. 6A is a block diagram illustrating a schematic configuration of Modification Example 2 of the control unit in the slave unit of the automatic fire notification system according to the embodiment. FIG. 6B is a diagram illustrating a state of the processing circuit in the slave unit of the automatic fire notification system according to the embodiment. It is explanatory drawing of the operation example 1 of the subunit | mobile_unit of the automatic fire alarm system which concerns on embodiment. It is explanatory drawing of the operation example 2 of the subunit | mobile_unit of the automatic fire alarm system which concerns on embodiment. It is explanatory drawing of the operation example 3 of the subunit | mobile_unit of the automatic fire alerting | reporting system which concerns on embodiment.

  The subunit | mobile_unit 1 of the automatic fire alarm system 100 of this embodiment is provided with the receiving part 15 and the control part 17, as shown in FIG. 1 and FIG. The receiving unit 15 is electrically connected to the pair of electric wires 31 and 32 and receives a signal transmitted from the parent device 2 by changing a voltage (standby voltage) V1 applied between the pair of electric wires 31 and 32. To do. The control unit 17 switches the state of the reception unit 15 between a reception operation state in which the reception unit 15 operates and a reception stop state in which the operation of the reception unit 15 stops. Then, the control unit 17 switches the state of the reception unit 15 between the reception operation state and the reception stop state depending on whether or not the power supply signal PS1 serving as the operation power of the reception unit 15 is supplied to the reception unit 15.

  Moreover, the automatic fire alarm system 100 of this embodiment is provided with the subunit | mobile_unit 1 and the main | base station 2 which applies a voltage between a pair of electric wires 31 and 32, as shown in FIG. The parent device 2 includes a transmission unit 24 that transmits a signal to the child device 1 by changing a voltage between the pair of electric wires 31 and 32.

  Moreover, the main | base station 2 of the automatic fire notification system 100 of this embodiment is used for the automatic fire notification system 100 of this embodiment, as shown in FIG.

  Hereinafter, the subunit | mobile_unit 1 of the automatic fire notification system 100 which concerns on this embodiment, the main | base station 2 of the automatic fire notification system 100, and the automatic fire notification system 100 are demonstrated in detail. However, the configuration described below is merely an example of the present invention, and the present invention is not limited to the following embodiment, and the technical idea according to the present invention is not limited to this embodiment. Various changes can be made according to the design or the like as long as they do not deviate. Note that broken-line arrows in the drawings represent signal flows.

  Below, the case where the automatic fire alarm system 100 of this embodiment is used for an apartment house (apartment) is illustrated. Of course, the automatic fire notification system 100 according to the present embodiment is not limited to a housing complex, and may be used in various buildings such as commercial facilities, hospitals, hotels, and residential buildings.

  The basic configuration of the automatic fire notification system 100 of the present embodiment is the same as a general automatic fire notification system. For example, the automatic fire notification system 100 is configured to detect the occurrence of a fire by the slave unit 1 and to notify the fire occurrence from the slave unit 1 to the master unit 2 (fire report). In addition, the subunit | mobile_unit 1 may be the structure containing not only the structure which detects generation | occurrence | production of a fire but a transmitter etc., for example. The transmitter means, for example, a device that has a push button switch and notifies the parent device 2 of the occurrence of a fire by manually operating the push button switch when a person detects a fire.

  In addition, the automatic fire notification system 100 of the present embodiment, when the master unit 2 receives a notification (interlock report) for interlocking other devices, other than smoke prevention equipment, emergency broadcasting equipment, etc. It has an interlocking function for interlocking devices. Therefore, the automatic fire notification system 100 according to the present embodiment may control the fire door of the smoke evacuation facility or notify the occurrence of the fire by sound or voice in the emergency broadcasting facility when a fire occurs. Is possible.

  The automatic fire notification system 100 of this embodiment is based on a P-type (Proprietary-type) automatic fire notification system. And in the automatic fire alarm system 100 of this embodiment, in the housing complex in which the P-type automatic fire alarm system was introduced, the existing wiring was used as it was, and the master unit 2 and the plurality of slave units 1 were replaced. Assume a case. Note that the automatic fire notification system 100 of the present embodiment can also be adopted as a newly introduced automatic fire notification system.

  Hereinafter, the configuration of the master unit 2 and the plurality of slave units 1 will be described in detail. In the following description, only one slave unit 1 among the plurality of slave units 1 will be described, and the remaining slave units 1 have the same configuration as the single slave unit 1, and thus description thereof will be omitted. .

<Configuration of base unit>
Base unit 2 is a P-type receiver that receives fire reports and interlocking reports from slave unit 1. Base unit 2 is installed in a management room of a building (a collective housing).

  As shown in FIG. 2, the master device 2 includes a resistor 22, a receiver 23, a transmitter 24, a display unit 25 for performing various displays, and an operation for receiving an operation input from a user, in addition to the application unit 21. The unit 26 and a control unit 27 that controls each unit are provided. The master unit 2 is electrically connected to the pair of electric wires 31 and 32.

  The application unit 21 applies a predetermined voltage to the pair of electric wires 31 and 32. Here, as an example, the voltage applied between the pair of electric wires 31 and 32 by the applying unit 21 is 24V DC, but the present invention is not limited to this value.

  The resistor 22 is connected between the applying unit 21 and at least one of the pair of electric wires 31 and 32. In the example of FIG. 1, the resistor 22 is inserted between one (high potential side) of the pair of electric wires 31 and 32 and the application unit 21. However, not limited to this example, the resistor 22 may be inserted between the other (low potential side) electric wire 32 and the application unit 21, or both the pair of electric wires 31 and 32 and the application unit 21. Between them.

  The resistor 22 has a first function of converting a current flowing through the resistor 22 into a potential difference (voltage) between both ends of the resistor 22 due to a voltage drop, and a pair of wires 31 when the pair of wires 31 and 32 are short-circuited. , 32 has a second function of limiting the current flowing through the first and second currents. In short, the resistor 22 has a first function as a current-voltage conversion element and a second function as a current limiting element. Here, as an example, the resistance value of the resistor 22 is 470Ω, but the value is not limited to this value.

  The receiving unit 23 is electrically connected between the resistor 22 and the pair of electric wires 31 and 32. The receiving unit 23 receives the signal S2 transmitted from the child device 1 based on the voltage (standby voltage) V1 between the pair of electric wires 31 and 32. Specifically, when the handset 1 draws in the current flowing through the pair of electric wires 31 and 32 as will be described later, the current value of the current flowing through the resistor 22 changes and the standby voltage V1 changes. The receiving unit 23 receives the signal S2 transmitted from the child device 1 by detecting the voltage value of the standby voltage V1. In addition, the receiving part 23 receives the fire report and the interlocking report notified from the subunit | mobile_unit 1 by detecting the voltage value of the standby voltage V1.

  The transmission unit 24 is electrically connected between the resistor 22 and the pair of electric wires 31 and 32. The transmission unit 24 transmits the signal S1 to the child device 1 by changing the current flowing through the pair of electric wires 31 and 32. Specifically, when the transmission unit 24 draws a current flowing from the application unit 21 to the resistor 22, the standby voltage V1 changes. That is, the transmission unit 24 transmits the signal S1 to the child device 1 by changing the standby voltage V1 by drawing the current flowing from the application unit 21 to the resistor 22.

  In the base unit 2 of the present embodiment, the control unit 27 controls the transmission unit 24 to switch the voltage value of the standby voltage V1 alternately between the first level and the second level (<first level), for example, Signal S1 is transmitted to handset 1.

  The display unit 25 includes, for example, an LED (Light Emitting Diode), a liquid crystal display, an organic electroluminescence display, and the like. The display part 25 displays the content according to the data contained in signal S2 received from the subunit | mobile_unit 1 by being controlled by the control part 27. FIG. The display unit 25 displays, for example, the occurrence of a fire and the floor (floor) where the fire occurred. Moreover, the display part 25 can also display the installation place of the said subunit | mobile_unit 1 when the specific identification information (for example, address) of the subunit | mobile_unit 1 which detected the fire can be acquired.

  The control unit 27 has a microcomputer (microcomputer) as a main component, and implements a desired function by executing a program stored in a memory. The program may be written in the memory in advance, but may be provided by being stored in a recording medium such as a memory card, or may be provided through an electric communication line.

  The base unit 2 applies the voltage between the pair of electric wires 31 and 32 from the applying unit 21 as described above, and thus the automatic fire alarm system 100 as a whole including the sub unit 1 connected to the pair of electric wires 31 and 32. It functions as a power source for the operation.

  Moreover, the main | base station 2 is further provided with the standby power supply 28 using a storage battery so that the power supply for operation | movement of the automatic fire alarm system 100 can be ensured also at the time of a power failure. The main unit 2 uses a commercial power source, a private power generation facility, etc. as a main power source. The application unit 21 automatically switches the power supply source from the main power source to the standby power source 28 when the main power source is interrupted, and automatically switches from the standby power source 28 to the main power source when the main power source is restored.

<Configuration of slave unit>
As shown in FIGS. 1 and 2, the slave unit 1 includes a diode bridge 11, a power supply unit 12, a detection unit 13, a notification unit 14, a reception unit 15, a transmission unit 16, a control unit 17, And a storage unit 18.

  In the diode bridge 11, a pair of electric wires 31 and 32 are electrically connected to an input end, and a power supply unit 12, a notification unit 14, a reception unit 15, and a transmission unit 16 are electrically connected to an output end.

  The power supply unit 12 generates power for operation of the child device 1 by being supplied with power from the pair of electric wires 31 and 32. The power supply unit 12 includes a current adjustment unit 121, a low drop-out regulator (LDO) 122, and a reset IC (Integrated Circuit) 123. The current adjustment unit 121 is electrically connected to the pair of electric wires 31 and 32 and adjusts the upper limit value of the current flowing through the pair of electric wires 31 and 32.

  The low loss regulator 122 has an input terminal electrically connected to an output terminal of the current adjusting unit 121, and an output terminal electrically connected to a reset IC 123, a control unit 17, and an oscillation unit 172 (described later). The low-loss regulator 122 operates so that the difference between the voltage input to the input terminal and the voltage output from the output terminal becomes small. The output voltage of the low-loss regulator 122 is input to the power supply terminal (“Vcc” shown in FIG. 1) of the control unit 17 as the operation voltage of the control unit 17.

  The reset IC 123 monitors the input voltage to the control unit 17 by monitoring the output voltage of the low-loss regulator 122. Then, when the voltage value of the input voltage deviates from the range necessary for the operation of the control unit 17, the reset IC 123 inputs a reset signal to the reset terminal (“RESET” shown in FIG. 1) of the control unit 17, thereby The unit 17 is reset (initialized).

  The detection unit 13 detects the occurrence of fire and smoke by detecting changes in smoke concentration, temperature, and gas concentrations such as carbon monoxide, for example. In the subunit | mobile_unit 1 of this embodiment, the detection part 13 is provided with the smoke detection part 131 which detects the generation | occurrence | production of smoke and the density | concentration of smoke, and the heat detection part 132 which detects the change of temperature. When the detection unit 13 detects the occurrence of a fire based on the detection results of the smoke detection unit 131 and the heat detection unit 132, the detection unit 13 transmits a detection signal to the control unit 17. The detection unit 13 is controlled by the control unit 17.

  The notification unit 14 includes, for example, a buzzer, a light emitting diode (LED), and the like, and is configured to notify the occurrence of a fire around. The notification unit 14 is controlled by the control unit 17.

  The receiving unit 15 receives the signal S1 transmitted from the parent device 2 based on the change in the standby voltage V1. Specifically, when the base unit 2 draws the current flowing through the pair of electric wires 31 and 32, the current value of the current flowing through the resistor 22 changes, and the standby voltage V1 changes. The receiving unit 15 receives the signal S1 transmitted from the parent device 2 as a received signal by detecting the voltage value of the output voltage of the diode bridge 11 corresponding to the standby voltage V1.

  Here, an example of a specific circuit of the receiving unit 15 will be described. As shown in FIG. 3, the receiving unit 15 includes a filter capacitor 151, resistors 152 and 153, a semiconductor element 154, and a pull-up resistor 155. The receiving unit 15 operates using the power signal PS1 supplied from the control unit 17 as a power source.

  The semiconductor element 154 is an npn-type bipolar transistor. Of course, the semiconductor element 154 may be composed of another semiconductor element such as a MOSFET (Metal-Oxide-Semiconductor Field-Effect Transistor). The emitter of the semiconductor element 154 is electrically connected to circuit ground (the output terminal on the low potential side of the diode bridge 11). The base of the semiconductor element 154 is electrically connected to one of the pair of electric wires 31 and 32 (here, the electric wire 31) via the capacitor 151 and the resistor 153. The power supply signal PS1 flows into the collector of the semiconductor element 154 via the pull-up resistor 155. Further, the power supply signal PS1 flows into the connection point 15A between the capacitor 151 and the resistor 153 via the resistor 152.

  The connection point 15A is electrically connected to one of the pair of electric wires 31 and 32 (here, the electric wire 31) via the capacitor 151. The potential at the connection point 15A changes as the standby voltage V1 changes. The semiconductor element 154 is used in a so-called open collector method. The collector-emitter voltage of the semiconductor element 154 becomes the received signal voltage V2.

Hereinafter, the operation of the receiving unit 15 will be described. In the following description, it is assumed that the power signal PS1 is given to the receiving unit 15 from the control unit 17. When the voltage value of the standby voltage V1 is the first level, the potential of the connection point 15A exceeds the threshold value (V _BE ) of the semiconductor element 154. At this time, since the semiconductor element 154 is turned on, the voltage V2 of the reception signal becomes a low level. On the other hand, when the voltage value of the standby voltage V1 is the second level, the potential at the connection point 15A is lower than the threshold value (V _BE ) of the semiconductor element 154. At this time, since the semiconductor element 154 is turned off, the voltage V2 of the reception signal becomes a high level.

  As described above, the receiving unit 15 receives the signal S1 transmitted from the parent device 2 as a reception signal by switching on / off of the semiconductor element 154 in accordance with the change in the standby voltage V1.

  The transmission unit 16 is electrically connected to the pair of electric wires 31 and 32. The transmission unit 16 transmits the signal S2 to the parent device 2 by changing the current flowing through the pair of electric wires 31 and 32. Specifically, when the transmitter 16 draws a current flowing through the pair of electric wires 31 and 32, the standby voltage V1 changes. That is, the transmission unit 16 transmits the signal S2 to the parent device 2 by changing the voltage (standby voltage) V1 between the pair of wires 31 and 32 by drawing the current flowing through the pair of wires 31 and 32.

  The control unit 17 has a microcomputer 170 as a main configuration, and realizes a desired function by executing a program stored in a memory. The program may be written in the memory in advance, but may be provided by being stored in a recording medium such as a memory card, or may be provided through an electric communication line. In addition, the main configuration of the control unit 17 is not limited to the microcomputer 170, and the control unit 17 may have, for example, an FPGA (Field-Programmable Gate Array) as the main configuration.

  The control unit 17 includes a GPI (General Purpose Input) terminal 41, GPO (General Purpose Output) terminals 42 to 44, A / D (Analog to Digital) terminals 45 and 46, and an SCI (Serial Communication Interface) terminal 47. It has. The control unit 17 acquires data included in the received signal from the received signal input to the GPI terminal 41. Further, the control unit 17 outputs a power signal PS1 from the GPO terminal 42 to the receiving unit 15. The control unit 17 controls the operation of the transmission unit 16 by outputting a control signal from the GPO terminal 43 to the transmission unit 16. The control unit 17 controls the operation of the notification unit 14 by outputting a control signal from the GPO terminal 44 to the notification unit 14.

  The control unit 17 acquires the detection value of the smoke detection unit 131 input to the A / D terminal 45. For example, the A / D terminal 45 receives a voltage signal that changes according to the smoke concentration. In addition, the control unit 17 acquires the detection value of the heat detection unit 132 that is input to the A / D terminal 46. For example, a voltage signal that changes according to the ambient temperature of the heat detection unit 132 is input to the A / D terminal 46. The control unit 17 acquires data stored in the storage unit 18 or rewrites data stored in the storage unit 18 via the SCI terminal 47.

  The control unit 17 further includes a processing circuit 171 that executes processing (program) according to the clock signal. Here, the processing circuit 171 is a CPU (Central Processing Unit). A clock signal supplied to the processing circuit 171 is generated by the oscillation unit 172. The oscillation unit 172 includes, for example, a crystal resonator. Needless to say, the oscillation unit 172 may be configured to generate a clock signal supplied to the processing circuit 171 and is not limited to a configuration including a crystal resonator. In the subunit | mobile_unit 1 of this embodiment, although the oscillation part 172 is provided separately from the microcomputer 170, you may incorporate in the microcomputer 170. FIG.

  The control unit 17 controls the reception unit 15 and the transmission unit 16. Specifically, the control unit 17 controls the reception unit 15 to cause the reception unit 15 to receive a signal S1 such as a synchronization signal transmitted from the parent device 2. Moreover, the control part 17 reads the output of the detection part 13 regularly, and will judge that it is a fire if the output of the detection part 13 exceeds a 1st reference value. And the control part 17 changes the standby voltage V1 to a fire alert level by controlling the transmission part 16 and adjusting the drawing-in amount of the electric current which flows through a pair of electric wires 31 and 32. FIG. Thereby, the control unit 17 notifies the master unit 2 of the fire report. At this time, the control unit 17 controls the notification unit 14 to notify the surroundings of the occurrence of a fire.

  In addition, when the output of the detection unit 13 exceeds the second reference value (> first reference value), the control unit 17 determines that the other device is linked. Then, the control unit 17 controls the transmission unit 16 to adjust the amount of current drawn through the pair of electric wires 31 and 32, thereby changing the standby voltage V1 to the interlocking report level (<fire report level). As a result, the control unit 17 notifies the master unit 2 of the linked information.

  In addition, the control unit 17 controls the transmission unit 16 to transmit the signal S2 to the parent device 2 by alternately switching the voltage value of the standby voltage V1 between the first level and the second level. The signal S2 includes, for example, information (identification information) for specifying the issue source for each slave unit, information for automatic testing, and the like. The items of the automatic test include, for example, survival confirmation (keep alive), self-diagnosis of the slave unit 1 and the like.

  The storage unit 18 stores at least identification information (for example, an address) assigned in advance to the child device 1. That is, unique identification information is assigned to each of the plurality of slave units 1 included in the automatic fire notification system 100 of the present embodiment. The identification information is registered in the parent device 2 in association with each installation location (for example, a room number) of the plurality of child devices 1.

<About the receiver>
In the automatic fire alarm system 100 of the present embodiment, the parent device 2 periodically transmits a synchronization signal to the plurality of child devices 1 connected to the same line (a pair of electric wires 31 and 32). The synchronization signal is a signal that is used, for example, to define the timing at which the child device 1 performs an automatic test and the timing at which communication with the parent device 2 is performed.

  Here, in the receiving unit 15, when the semiconductor element 154 is on, a current flows mainly through the resistor 153 and the pull-up resistor 155. In the receiving unit 15, when the semiconductor element 154 is off, a current flows through the capacitor 151 mainly through the resistor 152. That is, the receiving unit 15 consumes power by flowing a current not only during reception of the signal S1 from the parent device 2 but also during reception of the signal S1. Therefore, if the receiving unit 15 is always operating in order to wait for the signal S1 (here, the synchronization signal) transmitted from the base unit 2, extra power is consumed while the signal S1 is not received. There is a problem that power consumption increases.

  In addition, when the receiving units 15 of all the slave units 1 belonging to the automatic fire alarm system 100 of the present embodiment are always operating, a current is drawn from the pair of electric wires 31 and 32 to the receiving unit 15, so that the standby voltage V1 decreases. Then, although the fire has not occurred, the standby voltage V1 reaches the fire report level, and there is a possibility that the slave unit 1 erroneously notifies the master unit 2 of the fire report.

  Therefore, in the handset 1 of the present embodiment, the control unit 17 determines the state of the reception unit 15 according to whether the power supply signal PS1 serving as the operating power of the reception unit 15 is given to the reception unit 15 or not. It is configured to switch to one of the stopped states. The receiving operation state is a state in which the receiving unit 15 operates by receiving the power signal PS1. The reception stop state is a state in which the operation of the receiving unit 15 is stopped when the power supply signal PS1 is not given.

  That is, the receiving unit 15 can operate while receiving the power signal PS1 from the control unit 17 and receive the signal S1. Further, the receiving unit 15 cannot receive the signal S1 because it does not operate while the power supply signal PS1 is not supplied from the control unit 17, but hardly consumes power because no current flows. .

  Therefore, the control unit 17 can operate the receiving unit 15 when necessary, for example, when receiving a synchronization signal, and can stop the operation of the receiving unit 15 when not necessary. For this reason, in the subunit | mobile_unit 1 of this embodiment, since the receiving part 15 does not always wait for signal S1 (here synchronous signal) from the main | base station 2, power consumption can be reduced.

<Modification Example 1 of Control Unit>
Hereinafter, the modification 1 of the control part 17 in the subunit | mobile_unit 1 of this embodiment is demonstrated. In the first modification, the control unit 17 is configured to switch the state of the processing circuit 171 between the processing operation state and the processing stop state depending on whether or not a clock signal is supplied to the processing circuit 171. The processing operation state is a state in which the processing circuit 171 operates by receiving a clock signal. The process stop state is a state in which the operation of the processing circuit 171 stops when no clock signal is given.

  That is, the control unit 17 can operate the processing circuit 171 when processing by the processing circuit 171 is necessary, and can stop the operation of the processing circuit 171 when it is not necessary. In this configuration, not only the power consumption in the receiving unit 15 but also the power consumption in the processing circuit 171 can be reduced.

  For example, as illustrated in FIG. 4, the modification 1 can be realized by the control unit 17 including a timer 173. A clock signal generated by the oscillation unit 172 is input to the timer 173. The timer 173 periodically gives a clock signal to the processing circuit 171 by counting time. Therefore, the control unit 17 can switch the state of the processing circuit 171 between the processing operation state and the processing stop state.

  In addition, in the subunit | mobile_unit 1 of this embodiment, although the timer 173 is incorporated in the microcomputer 170, similarly to the oscillation part 172, you may provide separately from the microcomputer 170. FIG. Further, as shown in FIG. 5, the control unit 17 may have a configuration in which an oscillation unit 172 having a function of a timer 173 is built in the microcomputer 170. In this configuration, the oscillation unit 172 periodically provides a clock signal to the processing circuit 171 by the function of the built-in timer 173.

<Modification Example 2 of Control Unit>
Hereinafter, Modification 2 of the control unit 17 in the slave unit 1 of the present embodiment will be described. In the second modification, the control unit 17 is configured to switch the state of the processing circuit 171 between the first state and the second state. The first state is a state where a first clock signal is given. The second state is a state in which the second clock signal is given. The second clock signal has a longer period than the first clock signal.

  That is, for example, the control unit 17 operates the processing circuit 171 at the first clock signal (normal speed) at the normal time, and executes the processing circuit 171 at the second clock signal when executing processing with a small load such as waiting for the synchronization signal. It can be operated at (low speed). In this configuration, the processing circuit 171 is operated with the second clock signal (low speed) as necessary, so that the processing circuit 171 is always operated with the first clock signal (normal speed) as compared with the processing circuit 171. The power consumption at 171 can be reduced.

  For example, as illustrated in FIG. 6A, the modification 2 can be realized by including a frequency divider 174 in the control unit 17. The frequency divider 174 receives a clock signal (here, the first clock signal) generated by the oscillation unit 172. In response to a request from the processing circuit 171, the frequency divider 174 supplies the clock signal (first clock signal) supplied from the oscillation unit 172 to the processing circuit 171 without frequency division (multiplication), or performs frequency division. Then, one of the processes of giving the second clock signal to the processing circuit 171 is executed. Therefore, the control unit 17 can switch the state of the processing circuit 171 between the first state and the second state.

  Here, the control unit 17 may be configured in combination with the first modification and the second modification. That is, as shown in FIG. 6B, the control unit 17 may be configured to switch the state of the processing circuit 171 to any one of the first state, the second state, and the processing stop state. Hereinafter, in the drawings (FIG. 6B, FIGS. 7 to 9), “enable” of the “processing circuit” represents a processing operation state, and “disable” represents a processing stop state. Further, “enable (first state)” of the “processing circuit” indicates that the processing operation state and the first state. Further, “enable (second state)” of the “processing circuit” represents the processing operation state and the second state.

  This configuration can be realized, for example, when the control unit 17 includes a timer 173 and a frequency divider 174. Note that the timer 173 and the frequency divider 174 may be provided separately from the microcomputer 170 or may be built in the microcomputer 170.

<Operation example 1>
Hereinafter, an operation example 1 of the handset 1 of this embodiment when receiving a synchronization signal will be described with reference to FIG. Hereinafter, in the drawings (FIGS. 7 to 9), “enable” of the “reception unit” represents a reception operation state, and “disable” represents a reception stop state. In addition, “H” of the “synchronization signal” represents a high level and “L” represents a low level. Here, for example, the high level is a voltage value of the first level of the standby voltage V1, and the low level is a voltage value of the second level of the standby voltage V1.

  In the operation example 1, the control unit 17 switches the state of the reception unit 15 to the reception operation state during the period when the synchronization signal is transmitted from the base unit 2, and sets the state of the reception unit 15 to the reception stop state during other periods. Switching. That is, the reception unit 15 operates during a period in which the synchronization signal is transmitted from the parent device 2 to receive the synchronization signal, and stops operating in other periods. Therefore, in the operation example 1, the power consumption in the receiving unit 15 can be reduced compared to the case where the receiving unit 15 is always operated.

  Further, the control unit 17 switches the state of the processing circuit 171 to the second state during the period when the synchronization signal is transmitted from the parent device 2, and switches the state of the processing circuit 171 to the first state during the other periods. . That is, the processing circuit 171 operates with the second clock signal (low speed) during a period when the synchronization signal is transmitted from the parent device 2, and operates with the first clock signal (normal speed) during other periods. Therefore, in the operation example 1, the power consumption in the processing circuit 171 can be reduced as compared with the case where the processing circuit 171 is always operated at the first clock signal (normal speed).

  Here, the “period during which the synchronization signal is transmitted” is not limited to the same period as the period during which the synchronization signal is transmitted. That is, the “period during which the synchronization signal is transmitted” may include a period that is slightly longer than the period.

  In addition, when the subunit | mobile_unit 1 of this embodiment notifies the fire report and the interlocking | reporting report to the master | base_unit 2, the control part 17 receives the state of the receiving part 15 until it stops the notification of a fire report or a interlocking | reporting operation state. May be maintained. In this configuration, the slave unit 1 can communicate with the master unit 2 in real time in an emergency such as a fire.

<Operation example 2>
Hereinafter, an operation example 2 of the slave unit 1 of the present embodiment when receiving a synchronization signal will be described with reference to FIG. In the operation example 2, unlike the operation example 1, the control unit 17 changes the state of the reception unit 15 between the reception operation state and the reception stop state for each minimum bit width W1 of the synchronization signal transmitted from the parent device 2. It is switched alternately several times (here twice). That is, the receiving unit 15 does not always operate but operates intermittently during a period in which the synchronization signal is transmitted from the parent device 2.

  In this configuration, the control unit 17 acquires the synchronization signal by sampling a plurality of times for each minimum bit width W1 of the synchronization signal. Therefore, in this configuration, it is possible to reduce power consumption in the receiving unit 15 as compared with a case where the receiving unit 15 is always operated during a period in which the synchronization signal is transmitted from the parent device 2.

  Note that the control unit 17 may acquire the synchronization signal by sampling once for each minimum bit width W1 of the synchronization signal. That is, the control unit 17 may be configured to switch the state of the reception unit 15 alternately once between the reception operation state and the reception stop state for each minimum bit width W1 of the synchronization signal.

<Operation example 3>
Hereinafter, an operation example 3 of the slave unit 1 of the present embodiment when receiving a synchronization signal will be described with reference to FIG. In the operation example 3, the control unit 17 determines that the state of the processing circuit 171 is the processing operation state (here, the second state) and the state of the reception unit 15 is the reception stop state when the state of the reception unit 15 is the reception operation state. At this time, the state of the processing circuit 171 is switched to the processing stop state. That is, the processing circuit 171 operates with the second clock signal (low speed) when the receiving unit 15 is operating, and stops operating during other periods. In other words, the processing circuit 171 does not always operate but operates intermittently.

  In this configuration, power consumption in the processing circuit 171 can be reduced as compared with a case where the processing circuit 171 is always operated during a period in which the synchronization signal is transmitted from the parent device 2. Note that the processing circuit 171 only needs to be operating when the receiving unit 15 is operating, and thus may be operating at the first clock signal (normal speed).

  Since the processing circuit 171 only needs to operate at least when the receiving unit 15 is operating, the operation period W2 of the receiving unit 15 and the operation period W3 of the processing circuit 171 may not match. Good. Here, the operation period W3 of the processing circuit 171 is longer than the operation period W2 of the receiving unit 15.

DESCRIPTION OF SYMBOLS 100 Automatic fire alarm system 1 Slave unit 15 Receiving unit 17 Control unit 171 Processing circuit 2 Master unit 24 Transmitting unit 31, 32 Pair of electric wires PS1 Power supply signal W1 Minimum bit width

Claims (6)

A receiving unit that is electrically connected to the pair of wires and receives a signal transmitted from the master unit by changing a voltage applied between the pair of wires;
A control unit that switches the state of the reception unit to either a reception operation state in which the reception unit operates or a reception stop state in which the operation of the reception unit stops;
The control unit switches the state of the reception unit to either the reception operation state or the reception stop state depending on whether or not to supply a power supply signal serving as operating power of the reception unit to the reception unit ,
The control unit automatically switches the reception unit state between the reception operation state and the reception stop state a plurality of times for each minimum bit width of the synchronization signal transmitted from the master unit. A child of the fire alarm system. The control unit further includes a processing circuit that executes processing according to a clock signal,
The control unit determines whether the processing circuit is in a processing operation state in which the processing circuit operates and a processing stop state in which the operation of the processing circuit is stopped, depending on whether the clock signal is supplied to the processing circuit. The slave unit of the automatic fire alarm system according to claim 1, wherein the slave unit is switched to either one.   The control unit switches the state of the processing circuit between a first state in which a first clock signal is applied and a second state in which a second clock signal having a longer cycle than the first clock signal is applied. The slave unit of the automatic fire alarm system according to claim 2.   The control unit is configured such that the state of the processing circuit is in the processing operation state when the state of the receiving unit is the reception operation state, and the state of the processing circuit is in the reception stop state when the state of the reception unit is the reception stop state. The slave unit of the automatic fire alarm system according to claim 2, wherein the slave unit is switched so as to be in a process stop state.   A slave of the automatic fire alarm system according to any one of claims 1 to 4,
  A master unit for applying a voltage between the pair of wires;
  The said main | base station is provided with the transmission part which transmits a signal to the said subunit | mobile_unit by changing the voltage between a pair of said electric wires, The automatic fire alarm system characterized by the above-mentioned.   A base unit for an automatic fire notification system, which is used in the automatic fire notification system according to claim 5.

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