JP6646839B2 - Automatic fire alarm system - Google Patents

Description

  The present invention relates to an automatic fire alarm system, and more particularly, to an automatic fire alarm system that transmits a fire signal to a receiver by short-circuiting a pair of electric wires electrically connected to the receiver. .

  Conventionally, an automatic fire alarm system has been used in which a fire signal from a sensor is received by a receiver to sound a local acoustic device, and a linked signal from the sensor is received by a receiver to operate a smoke prevention device. I have.

  As this type of automatic fire alarm system, a disaster prevention sensor that sends out a level signal that changes in level according to a change in the sensing state, and a receiver that generates an alarm corresponding to the level signal, are connected via a signal transmission line. A connected structure is known (for example, see Patent Document 1).

  Patent Literature 1 states that a smoke detection density can be transmitted by a level signal transmitted from a disaster prevention sensor to a receiver, and a preliminary alarm and a main alarm can be distinguished.

  However, Patent Document 1 is an invention of an information transmission system used for a self-fire alarm system, a smoke prevention system, and the like, and does not disclose a detailed structure of a disaster prevention sensor or a receiver as a sensor in detail. .

JP-A-59-99595

  By the way, in the automatic fire alarm system, when a sensor sends a fire signal to a receiver by short-circuiting a pair of electric wires, separate wiring is required to send another signal to the receiver in addition to the fire signal And the number of wirings increases.

  An object of the present invention is to provide an automatic fire alarm system capable of further reducing wiring.

The automatic fire alarm system of the present invention includes a receiver, a first sensor, and a second sensor. The first sensor is configured to transmit a fire signal to the receiver. The second sensor is configured to transmit at least one of an interlock signal and a fire signal to the receiver. The interlock signal is a signal for operating the smoke control device in interlock. The first sensor and the second sensor are electrically connected to the receiver with a pair of wires. The receiver has a voltage applying unit and a receiving unit. The voltage applying unit applies a voltage between the pair of electric wires. The receiving unit is configured to be able to receive a fire signal and an interlocking signal. The second sensor includes a transmission unit and a control unit. The transmitting unit transmits a fire signal and an interlocking signal between the pair of wires by short-circuiting the pair of wires. The fire signal and the interlocking signal are current signals having different current values. The control unit controls the transmitting unit to transmit a current signal. The second sensor is configured to be able to discriminate a fire signal and an interlocking signal by a current signal flowing through the pair of wires, and the second sensor is configured to respond to a current signal flowing through the pair of wires, It is characterized in that it is determined whether a fire signal is transmitted to the receiver or an interlocking signal is transmitted to the receiver .

The automatic fire alarm system of the present invention includes a receiver, a first sensor, and a second sensor. The first sensor is configured to transmit a fire signal to the receiver. The second sensor is configured to transmit at least one of an interlock signal and a fire signal to the receiver. The interlock signal is a signal for operating the smoke control device in interlock. The first sensor and the second sensor are electrically connected to the receiver with a pair of wires. The receiver has a voltage applying unit and a receiving unit. The voltage application unit applies a voltage between the pair of electric wires. The receiving unit is configured to be able to receive a fire signal and an interlocking signal. The second sensor includes a transmission unit and a control unit. The transmitting unit short-circuits the pair of electric wires and transmits a fire signal and an interlocking signal between the pair of electric wires. The fire signal and the interlocking signal are voltage signals having different voltage values. The control unit controls the transmitting unit to transmit a voltage signal. The second sensor is configured to be able to discriminate a fire signal and an interlocking signal by a voltage signal applied to the pair of wires, and the second sensor is configured to detect a voltage signal applied to the pair of wires. And transmitting a fire signal to the receiver or an interlocking signal to the receiver .

  The automatic fire alarm system of the present invention can further reduce wiring.

1 is a block diagram illustrating an automatic fire alarm system according to a first embodiment. 1 is a system configuration diagram illustrating an automatic fire alarm system according to a first embodiment. It is a circuit diagram which shows the principal part of the automatic fire alarm system of Embodiment 1. FIG. 4 is a current waveform diagram illustrating an operation of the automatic fire alarm system according to the first embodiment. It is a current waveform diagram explaining another operation | movement of the automatic fire alarm system of Embodiment 1. It is a circuit diagram which shows the principal part of the automatic fire alarm system of Embodiment 2. It is a voltage waveform diagram explaining operation | movement of the automatic fire alarm system of Embodiment 2. It is a voltage waveform diagram explaining another operation | movement of the automatic fire alarm system of Embodiment 2.

(Embodiment 1)
Hereinafter, the automatic fire alarm system 10 of the present embodiment will be described with reference to FIGS. 1 to 5. Hereinafter, the automatic fire alarm system 10 is also referred to as an automatic fire alarm system 10. In the drawings, the same components are denoted by the same reference numerals, and redundant description will be omitted.

  The automatic fire alarm system 10 according to the present embodiment includes a receiver 2, a first sensor 11, and a second sensor 12, as shown in FIGS. The first sensor 11 is configured to transmit a fire signal to the receiver 2. The second sensor 12 is configured to transmit at least one of the interlocking signal and the fire signal to the receiver 2. The interlocking signal is a signal for operating the smoke control device 3a in an interlocked manner. The first sensor 11 and the second sensor 12 are electrically connected to the receiver 2 by a pair of electric wires 10a. The receiver 2 has a voltage applying unit 2a and a receiving unit 2c. The voltage application unit 2a applies a voltage between the pair of electric wires 10a. The receiving unit 2c is configured to be able to receive a fire signal and an interlocking signal. As shown in FIG. 3, the second sensor 12 includes a transmission unit 1a and a control unit 1b. The transmitting unit 1a transmits a fire signal and an interlock signal between the pair of wires 10a by short-circuiting the pair of wires 10a. The fire signal and the interlocking signal are current signals having different current values as shown in FIG. The control unit 1b controls the transmission unit 1a to transmit a current signal. The second sensor 12 and the receiver 2 are configured so that a fire signal and an interlocking signal can be distinguished by a current signal flowing through the pair of electric wires 10a.

  The self-fire alarm system 10 of the present embodiment is a current signal in which the transmission unit 1a short-circuits the pair of electric wires 10a and changes the current value of the current flowing between the pair of electric wires 10a. Is transmitted, it is possible to further reduce wiring.

  Hereinafter, first, the configuration of the entire self-fire alarm system 10 will be briefly described with reference to FIG.

  The self-fire alarm system 10 of the present embodiment includes a plurality of sensors 1, a single receiver 2, a smoke elimination device 3a, a district acoustic device 3b, and a terminating resistor 4. . Different types of sensors 1 are used for the plurality of sensors 1. As different types of sensors 1, a plurality of types of first sensors 11 and second sensors 12 are used. As the plurality of types of first sensors 11, a differential spot type sensor 11a and a smoke spot type sensor 11b are used. The differential spot type sensor has a configuration in which a thermistor is provided in the heat-sensitive section. The differential spot type sensor is configured to transmit a fire signal by detecting a fire using a change in electric resistance of the thermistor due to heat. The second sensor 12 is configured to be able to transmit two signals, a fire signal and an interlocking signal. The fire signal is a signal for notifying the occurrence of a fire.

  In the self-fire alarm system 10, the first sensor 11 and the second sensor 12 are electrically connected to the receiver 2 via a pair of electric wires 10a. In the self-fire alarm system 10, a terminating resistor 4 is electrically connected to ends of the pair of electric wires 10a on the opposite side to the receiver 2. The receiver 2 is electrically connected to the smoke elimination device 3a and the district sound device 3b. The self-fire alarm system 10 is configured such that one or more lines can be connected to the receiver 2 using a pair of electric wires 10a as one line. FIG. 2 shows an example of two lines. The self-fire alarm system 10 is provided with each line in each of the guard areas where the occurrence of a fire is monitored. The receiver 2 can connect, for example, up to 20 sensors 1 to one line. The self-fire alarm system 10 can provide one line for each floor, for example, when a guard area is set for each floor such as an apartment house or a mixed-use building.

  In the self-fire alarm system 10, when the detector 1 detects a fire, the receiver 2 receives a fire signal transmitted by the detector 1 that has detected the fire via a pair of electric wires 10a. For example, when any one of the first sensor 11 and the second sensor 12 in the guard area transmits a fire signal, the self-fire alarm system 10 causes the receiver 2 to detect a fire in any of the plurality of guard areas. It can be notified of occurrence. The self-fire alarm system 10 is configured so that, for example, the area sound device 3b connected to the receiver 2 can notify a warning zone or the like of the occurrence of a fire to a warning area where the detector 1 has detected the fire. ing. In the self-fire alarm system 10, for example, when any one of the second sensors 12 in the guard area transmits an interlocking signal, the receiver 2 receiving the interlocking signal activates the smoke prevention device 3a. The smoke prevention device 3a is configured to operate a fire door or the like in order to prevent the diffusion of smoke in a warning area where the detector 1 has detected a fire. The self-fire alarm system 10 may include a transmitter that can short-circuit the pair of electric wires 10a in addition to the sensor 1. The transmitter may have a configuration in which, for example, when a push button switch is pressed, a short circuit occurs between the pair of wires 10a.

  Hereinafter, each configuration in the self-fire alarm system 10 of the present embodiment will be described.

  For example, a smoke detector, a heat detector, a flame detector, or the like can be used as the detector 1 so as to detect a fire. As the sensor 1, a first sensor 11 for transmitting a fire signal and a second sensor 12 for transmitting an interlocking signal in addition to the fire signal according to a fire situation are used. The second sensor 12 is mainly different from the first sensor 11 in that a configuration capable of transmitting an interlocking signal to the first sensor 11 is added. Hereinafter, the configuration of the second sensor 12 will be mainly described, and the configuration of the first sensor 11 that is common to the configuration of the second sensor 12 will also be described.

  The second sensor 12 is configured to detect a fire and transmit a fire signal to the receiver 2 and, in addition, to transmit an interlocking signal for operating the smoke prevention device 3 a to the receiver 2. I have. In other words, the first sensor 11 has a single function type configuration for transmitting a fire signal, and the second sensor 12 has a configuration for transmitting two signals, a fire signal and an interlocking signal. The self-fire alarm system 10 uses a single-function type sensor 1 and a sensor 1 that transmits two signals by connecting them to the same line.

  As shown in FIG. 1, the second sensor 12 has a sensor unit 1c in addition to the transmission unit 1a and the control unit 1b. The second sensor 12 further includes a diode bridge 1d, a detecting unit 1e, a light emitting unit 1f, a power supply unit 1g, and a storage unit 1m. A pair of electric wires 10a is connected to a pair of terminals 1t of the second sensor 12. The voltage from the voltage application unit 2a of the receiver 2 is applied to the pair of terminals 1t of the second sensor 12 via the pair of electric wires 10a. In the diode bridge 1d, a pair of electric wires 10a is electrically connected to the input end side, and the transmission unit 1a, the detection unit 1e, and the power supply unit 1g are electrically connected to the output end side. The diode bridge 1d depolarizes the voltage applied to the pair of terminals 1t of the second sensor 12. The power supply unit 1g is configured to generate a voltage for operating the second sensor 12. As the second sensor 12, various sensors can be used for the sensor unit 1c so as to detect a fire.

  The sensor unit 1c may be of a heat-sensing type that closes the electrical contact due to deformation of the bimetal due to heat and senses a fire, for example. The sensor unit 1c can be configured to include a flame sensor. The flame sensor has a sensitivity in a predetermined ultraviolet region so that ultraviolet rays generated from the flame can be detected. The sensor unit 1c can detect a fire based on the output from the flame sensor. The sensor unit 1c can be configured to include a pyroelectric element. The pyroelectric element has a sensitivity in a predetermined infrared region so that infrared rays generated from a flame can be detected. The sensor unit 1c can be configured to detect a fire when the change in the amount of infrared light received by the pyroelectric element is equal to or greater than a certain value. For example, in the case of a smoke detector, the sensor unit 1c may be configured to include a smoke sensing chamber, a light emitting element that emits infrared light to the smoke sensing chamber, and a light receiving element that can receive infrared light from the light emitting element. it can. The sensor unit 1c can be configured so that infrared light from the light emitting element is irregularly reflected on the smoke particles that have entered the smoke detection chamber, and the light receiving element receives the irregularly reflected infrared light so that smoke can be sensed. The smoke detector can detect a fire by detecting smoke. The smoke detector can also detect the fire level by detecting the magnitude of the output value from the light receiving element according to the smoke concentration. The sensor unit 1c is configured to output a sensor signal to the control unit 1b.

  The control unit 1b is configured to determine whether or not a fire has occurred based on the sensor signal. The control unit 1b is electrically connected to the transmitting unit 1a, the detecting unit 1e, the light emitting unit 1f, and the storage unit 1m in addition to the sensor unit 1c. The storage unit 1m stores a predetermined value for the control unit 1b to determine whether the sensor signal has reached a level at which a fire signal or an interlocking signal is transmitted. The control unit 1b compares the value of the sensor signal corresponding to, for example, the concentration of smoke detected by the sensor unit 1c with a predetermined value stored in the storage unit 1m, and determines that the value of the sensor signal is smaller than the predetermined value. If it is larger, it is determined that a fire of a size that reaches a predetermined fire level has occurred. The control unit 1b reads the sensor signal as appropriate and compares it with a predetermined value in the storage unit 1m to determine whether to transmit a fire signal or an interlocking signal. When determining that a fire has occurred, the control unit 1b controls the transmission unit 1a to transmit a fire signal. When transmitting the fire signal, the control unit 1b causes the light emitting unit 1f to emit light. The control unit 1b can be configured using a microcomputer. The control unit 1b can execute a predetermined control function by causing the microcomputer to execute a program stored in the memory. When the second sensor 12 is configured as a smoke sensor, the control unit 1b controls the transmitting unit 1a such that the fire signal is transmitted when the smoke concentration detected by the sensor unit 1c is 7% or more, for example. The control unit 1b can be configured to control the transmission unit 1a such that the interlocking signal is transmitted when the smoke density detected by the sensor unit 1c is 13% or more, for example.

  The transmission section 1a includes a fire alarm circuit 1a1 for transmitting a fire signal and an interlock alarm circuit 1a2 for transmitting an interlock signal. The fire alarm circuit 1a1 is configured to transmit a fire signal with a predetermined current signal obtained by changing a current value of a current flowing between the pair of electric wires 10a. The interlocking notification circuit 1a2 is configured to be able to transmit an interlocking signal with a predetermined current signal different from a fire signal obtained by changing a current value of a current flowing between the pair of electric wires 10a. As shown in FIG. 3, the transmission unit 1a includes, for example, two series circuits in which a resistor 1r and a switching element 1q are connected. The transmission unit 1a can be configured to electrically connect two series circuits each including the resistor 1r and the switching element 1q in parallel. The transmission section 1a is electrically connected to the pair of electric wires 10a via the diode bridge 1d. A series circuit of the resistor 1r and the switching element 1q is electrically connected in parallel with a pair of output terminals of the diode bridge 1d. In the transmitting unit 1a, one of the series circuits in which the resistor 1r and the switching element 1q are connected forms a fire alarm circuit 1a1, and the other of the series circuit in which the resistor 1r and the switching element 1q are connected is an interlocking alarm circuit. 1a2. Hereinafter, the resistor 1r of the fire alarm circuit 1a1 is referred to as a first resistor 1r1, and the resistor 1r of the interlocking alarm circuit 1a2 is also referred to as a second resistor 1r2. In the transmitting unit 1a, the resistance value of the first resistor 1r1 forming the fire alarm circuit 1a1 is different from the resistance value of the second resistor 1r2 forming the interlocking alarm circuit 1a2. The resistance value of the first resistor 1r1 and the resistance value of the second resistor 1r2 are larger than the resistance value of the termination resistor 4.

The transmitting unit 1a, for example, makes the resistance value of the second resistor 1r2 forming the interlocking alarm circuit 1a2 smaller than that of the first resistor 1r1 forming the fire alarm circuit 1a1. The fire report circuit 1a1, and the first current value I ₁ or more predetermined corresponding to the fire signal shown in FIG. 4, during a predetermined second current value I ₂ of less than the current corresponding to the interlocking signals of a pair of wires 10a The resistance value of the first resistor 1r1 is selected so that the current can flow through the first resistor 1r1. In conjunction report circuit 1a2, so as to be able to flow a predetermined second current value I ₂ or more current corresponding to the interlocking signal between a pair of electric wires 10a, the resistance value of the second resistor 1r2 is selected .

  In the transmitting unit 1a, ON and OFF of the switching element 1q are controlled based on a control signal from the control unit 1b. The transmission unit 1a is in an electrically open state, for example, when the control unit 1b controls the switching element 1q of the fire alarm circuit 1a1 to be off and the switching element 1q of the interlocking alarm circuit 1a2 is off. Becomes For example, when the switching element 1q of the fire alarm circuit 1a1 is controlled to be turned on and the switching element 1q of the interlocking alarm circuit 1a2 is controlled to be turned off by the control section 1b, the transmission section 1a is connected via the first resistor 1r1. The pair of electric wires 10a is short-circuited. Here, the short circuit between the pair of electric wires 10a means that the line of the pair of electric wires 10a is closed by the switching element 1q or the like and current flows. Therefore, a short circuit between the pair of electric wires 10a means that even if various electronic components such as a resistor and a zener diode are connected between the pair of electric wires 10a, a current flows through the pair of electric wires 10a due to the ON control of the switching element 1q. It is included.

Since the voltage applying unit 2a of the receiver 2 applies a voltage between the pair of wires 10a, the transmitting unit 1a can flow between the pair of wires 10a when the pair of wires 10a is short-circuited. . Transmitting section 1a includes a resistor by selecting the resistance value appropriate for 1r, first current value I ₁ or more corresponding to the first resistor IRl, and a pair of composed such current to the second than the current value I ₂ Between the electric wires 10a. For example, when the control unit 1b controls the switching element 1q of the fire alarm circuit 1a1 to be turned off and the switching element 1q of the interlocking alarm circuit 1a2 to be turned on by the control unit 1b, the transmission unit 1a transmits the signal via the second resistor 1r2. The pair of electric wires 10a is short-circuited. Transmission unit 1a, since the voltage application unit 2a of the receiver 2 applies a voltage between the pair of wires 10a, current pair to be the second current value I ₂ or more corresponding to the second resistor 1r2 It can flow between the electric wires 10a. Switching element 1q can be configured using, for example, an npn-type transistor. The switching element 1q is not limited to an npn-type transistor, but may be a pnp-type transistor, a MOSFET (Metal-Oxide-Semiconductor Field-Effect Transistor), a relay, or the like.

  The detection unit 1e is configured to detect a current flowing through the pair of electric wires 10a and receive a current signal. The detecting unit 1e is configured to receive a current signal of a current flowing through the pair of electric wires 10a, thereby receiving a fire signal transmitted by another sensor 1. When the detection unit 1e receives a fire signal, the second sensor 12 transmits a fire signal from a function for transmitting a fire signal to a function for smoke prevention that transmits an interlocking signal for operating the smoke prevention device 3a. It is configured to switch to. The second sensor 12 determines whether another detector 1 such as the first sensor 11 has transmitted a fire signal based on whether the detection unit 1e receives a current signal of a current flowing between the pair of electric wires 10a. Can be determined. In the self-fire alarm system 10, for example, when the first sensor 11 short-circuits the pair of electric wires 10a, the detection unit 1e of the second sensor 12 located in the same alert area receives a fire signal. When the detecting unit 1e receives the fire signal, the control unit 1b can control the transmitting unit 1a based on the sensor signal from the sensor unit 1c so as to transmit only the interlocking signal. When the detection unit 1e receives a fire signal from the outside, the second sensor 12 stands by for smoke prevention. The self-fire alarm system 10 includes, for example, when a plurality of second sensors 12 are provided in one line of one guard area, if any one of the second sensors 12 transmits a fire signal, all the remaining second sensors 12 transmit. The sensor 12 can be configured to stand by for smoke control.

  The light emitting unit 1f is configured to emit light under the control of the control unit 1b. When a fire signal is transmitted, the light emitting unit 1f emits light so that the sensor 1 that has transmitted the fire signal can be specified. The light emitting unit 1f can be configured to include, for example, a light emitting diode. The light emitting unit 1f is not limited to the configuration that emits light under the control of the control unit 1b. The light emitting section 1f may have a structure in which a series circuit of a light emitting diode and a resistor is connected between the pair of electric wires 10a and the diode bridge 1d. In the light emitting unit 1f, when the second sensor 12 detects a fire and a current of a predetermined value or more flows from the pair of electric wires 10a into the second sensor 12, the light emitting diode emits light. When transmitting the fire signal and the interlocking signal, the second sensor 12 can notify the surroundings that the second sensor 12 is in the transmission state by emitting light from the light emitting diode.

  The first sensor 11 has the same configuration as that of the transmitter 1a of the second sensor 12, except that the interlocking notification circuit 1a2 and the detector 1e are omitted. When transmitting the fire signal, the first sensor 11 is configured to output a current signal having the same value as the current value of the current signal indicating the fire signal of the second sensor 12. The second sensor 12 may output a current signal having a smaller current value than the fire signal of the first sensor 11. The self-fire alarm system 10 can also determine which sensor 1 has transmitted by changing the fire signal or the interlocking signal for each different sensor 1.

  Next, the receiver 2 includes a resistor 2b, a display unit 2d, an operation unit 2e, a processing unit 2f, a transmission unit 2h, and a standby power supply 2j, in addition to the voltage application unit 2a and the reception unit 2c. ing. The operation unit 2e is configured to receive an operation input from a user. The backup power supply 2j is configured so that the receiver 2 can operate even when a commercial AC power supply fails. The transmitter 2 of the receiver 2 is connected to the smoke control device 3a and the district sound device 3b. The receiver 2 is installed in, for example, a management room of a building.

  When receiving the fire signal from any one of the sensors 1, the receiver 2 sounds the district sound device 3b such as an alarm bell. When receiving the interlocking signal from the second sensor 12, the receiver 2 operates the smoke prevention device 3a. When the receiver 2 receives the interlocking signal from the sensor 1 with the receiver 2c, the receiver 2 interlocks the emergency broadcast equipment, the fire hydrant equipment, the external notification device, and the like, in addition to the smoke elimination device 3a and the district sound device 3b. It may have an interlocking function. The receiver 2 is configured to be able to control a fire door and a smoke exhaust facility of the smoke exhaust device 3a when a fire occurs. The receiver 2 is configured to be able to issue an alarm with the district sound device 3b. The receiver 2 can be configured to be able to notify the occurrence of a fire by sound or voice in emergency broadcast equipment. The receiver 2 can be configured to be able to extinguish a fire by driving a sprinkler or the like of a fire hydrant facility. The receiver 2 can be configured to notify a fire engine or a security company outside the facility where the self-fire alarm system 10 is installed by an external notification device.

  The voltage application unit 2a applies a predetermined voltage between the pair of electric wires 10a. The voltage applying unit 2a is configured to be able to constantly apply, for example, a DC voltage between the pair of electric wires 10a. In the self-fire alarm system 10, when the detector 1 is not detecting a fire, the receiver 2 causes the minute current for disconnection detection to flow due to the voltage applied between the pair of electric wires 10a by the voltage application unit 2a. It is configured as follows. Hereinafter, a state in which the sensor 1 does not detect a fire is referred to as normal. The resistor 2b is connected between the voltage applying unit 2a and at least one of the pair of electric wires 10a. The resistor 2b is provided, for example, between the high potential side of the pair of electric wires 10a and the voltage applying unit 2a. The resistor 2b may be provided between the low potential side of the pair of electric wires 10a and the voltage applying unit 2a. The resistor 2b may be provided between each of the pair of electric wires 10a and the voltage applying unit 2a.

  The resistor 2b has a current limiting function of limiting a current flowing through the pair of wires 10a when the pair of wires 10a is short-circuited. The receiving unit 2c is electrically connected between the resistor 2b and the pair of electric wires 10a. The receiving unit 2c is configured to receive a current signal from the sensor 1 by detecting a current value of a current flowing between the pair of electric wires 10a. The receiving unit 2c constantly detects the current value of the current flowing through the pair of electric wires 10a at predetermined intervals. The receiving unit 2c is configured to detect a minute current flowing through the pair of electric wires 10a. When the receiving unit 2c detects the minute current, the processing unit 2f can determine that the disconnection has not occurred in the pair of electric wires 10a. The receiving unit 2c detects whether or not the current from the minute current has been changed to a current having a predetermined current value by the transmitting unit 1a of the sensor 1. The receiving unit 2c can receive a fire signal or an interlocking signal from the sensor 1 by detecting a current value of a current flowing through the pair of electric wires 10a.

  When the receiver 2 receives the fire signal from the sensor 1, the processing unit 2f displays a fire occurrence location and the like for each caution area on the display unit 2d. The receiver 2 can display each of the lines for each line so that the guard area can be identified. The display unit 2d discriminates each of the lines constituted by the pair of electric wires 10a in the guard zone, and displays the guard zone in which the received fire signal or the interlock signal is transmitted. The processing unit 2f can be configured using a microcomputer. The processing unit 2f can execute a predetermined control function by the microcomputer executing the program stored in the memory. When receiving the interlocking signal from the sensor 1, the receiver 2 issues an instruction to the firefighting equipment 3 from the transmitting unit 2h, and can interlock the firefighting equipment 3.

  The receiver 2 is configured to be supplied with power from an external power supply such as a commercial AC power supply or a private power generation facility. The standby power supply 2j is configured so that the self-fire alarm system 10 can be operated at the time of a power failure of the external power supply. The backup power supply 2j can be configured to include an appropriate storage battery. The voltage application unit 2a is configured to be able to automatically switch from the external power supply to the backup power supply 2j and drive when the external power supply fails. The voltage applying section 2a is configured to be able to automatically switch from the standby power supply 2j to the external power supply when the external power supply is restored.

  The receiver 2 applies, for example, a DC voltage of 24 V between the pair of electric wires 10a. In the self-fire alarm system 10, for example, the terminating resistor 4 having a resistance value of 10 kΩ can be provided at the terminating end of the pair of electric wires 10a. The receiver 2 is configured such that a weak current of, for example, about 2.4 mA can flow between the pair of electric wires 10a by providing the terminating resistor 4 having a resistance value of 10 kΩ. The receiver 2 is configured to monitor a weak current. In the self-fire alarm system 10, when the receiver 2 cannot detect a weak current, it can be determined that the pair of electric wires 10a is disconnected. The self-fire alarm system 10 is set so that the receiver 2 does not operate with a weak current. When the sensor unit 1c of the first sensor 11 or the second sensor 12 detects a fire and the switching element 1q of the transmitting unit 1a is controlled to be off, the self-fire alarm system 10 is connected between the pair of electric wires 10a. The flowing current increases. In the receiver 2, the increase in the value of the current flowing between the pair of electric wires 10a is received by the receiver 2c, and the receiver 2 can notify the fire.

  By the way, in the self-fire alarm system, a system called P-type (Proprietary-type) and a system called R-type (Record-type) are known. The P-type self-fire alarm system is configured by connecting a sensor to one or a plurality of lines derived from a receiver, and issues an alarm when the receiver receives a fire signal from the sensor. In the P-type self-fire alarm system, when the electrical contact of the sensor closes, current flows between a pair of wires between the sensor and the receiver, and the fire signal is directly received by the receiver. I do.

  The R-type self-fire alarm system connects a sensor to a common multiplex transmission line derived from a receiver, and polls the multiplex transmission line between the receiver and the sensor to check the state of the sensor. Monitors and issues an alarm when the fire signal emitted by the sensor is interrupted and received by the receiver. The R-type self-fire alarm system converts a fire signal from a sensor into a digital signal by a repeater and transmits the digital signal to a receiver. The P-type self-fire alarm system can have a relatively simple configuration as compared with the R-type self-fire alarm system.

  The P-type self-fire alarm system may use two types of sensors, a sensor that transmits a fire signal for sounding a local sound device and a sensor that transmits an interlocking signal for controlling smoke emission control. When the P-type self-fire alarm system uses two types of sensors, the number of installed sensors increases. The P-type self-fire alarm system can reduce the number of installed sensors by using a sensor that can transmit a fire signal and a disaster prevention signal from one sensor, compared to using two types of sensors. Can be reduced.

  However, in the case of the P-type self-fire alarm system, if the sensor that transmits only a fire signal and the sensor that transmits a fire signal and a disaster prevention signal are mixed, the R-type self-fire alarm system should be applied as it is. Can not. In the P-type self-fire alarm system, when a sensor that transmits only a fire signal and a sensor that transmits a fire signal and a disaster prevention signal from one sensor coexist, wiring for transmitting a fire signal, It is necessary to separately provide a wiring for transmitting an interlocking signal, and the number of wirings increases.

  The self-fire alarm system 10 of the present embodiment uses the current value of the current flowing between the pair of electric wires 10a as a current signal corresponding to a fire signal or an interlock signal, so that the fire signal and the interlock signal are Can be distinguished. The self-fire alarm system 10 can receive a fire signal and an interlocking signal separately on the same line, and can reduce wiring compared to a case where a separate line is provided with a fire signal wire and an interlocking signal wire. it can.

  Hereinafter, the operation of the self-fire alarm system 10 will be described with reference to FIG.

  FIG. 4 shows the current value of the current flowing through the pair of electric wires 10a, with the horizontal axis representing the time axis and the vertical axis representing the current value. In FIG. 4, the control unit 1b appropriately controls on and off of each of the switching elements 1q in the transmission unit 1a, so that the current value of the current flowing through the pair of electric wires 10a is gradually changed from the current value of the minute current. It illustrates that it can be raised.

  In the sensor 1, the control unit 1b reads the sensor value from the sensor unit 1c periodically at a predetermined sampling cycle. The sensor 1 determines whether a fire has occurred based on a sensor signal from the sensor unit 1c. When the sensor 1 does not detect a fire, the self-fire alarm system 10 repeatedly reads the sensor value. In the self-fire alarm system 10, when all the sensors 1 are normal, a minute current for detecting a predetermined disconnection remains flowing between the pair of electric wires 10a.

Next, when a fire is detected by the second sensor 12 at time t1, the self-fire alarm system 10 switches the fire alarm circuit 1a1 so that the control unit 1b of the second sensor 12 can transmit a fire signal. The element 1q is turned on. The second sensor 12, by the switching device 1q fire report circuit 1a1 is turned on, the first current value I ₁ or the pair of wires 10a, and the second current value I ₂ of less than current flows. In the receiver 2, first current value I ₁ or the pair of wires 10a, when received by the receiving portion 2c that and has a second current value I ₂ of less than current flows, to display the display portion 2d. The receiver 2 transmits a transmission signal from the transmission unit 2h to make the district sound device 3b sound. The sensor 1 reads a sensor value periodically at a predetermined sampling cycle, and determines whether or not it is in a state of transmitting a link signal. When the sensor 1 is not in the state of transmitting the interlocking signal, the sensor 1 keeps the off state of the switching element 1q in the interlocking notification circuit 1a2 and repeatedly reads the sensor value. Next, when the self-fire alarm system 10 transmits the interlocking signal in the second sensor 12, the control unit 1b of the sensor 1 that has determined the transmission of the interlocking signal transmits the interlocking signal so that the interlocking signal is transmitted. The switching element 1q of 1a2 is turned on. In the receiver 2, when it is received by the receiving portion 2c of that second current value I ₂ or more current flows through the pair of wires 10a, thereby operating the Bohai smoke device 3a by transmitting signals from the transmitting unit 2h.

  The self-fire alarm system 10 of the present embodiment is not limited to the configuration in which the amount of current flowing through the pair of electric wires 10a is increased stepwise according to a fire signal or an interlocking signal. In the self-fire alarm system 10, as shown in FIG. 5, in the second sensor 12, one of the fire signal and the interlocking signal is a pulse signal, and the other is a signal of a constant level.

  The self-fire alarm system 10 can control one of the switching elements 1q to be repeatedly turned on and off at a predetermined timing, so that one of the fire signal and the interlocking signal can be a pulse signal. The self-fire alarm system 10 can set the other one of the fire signal and the interlocking signal to a constant level signal by turning on one switching element 1q at a predetermined timing.

  In the self-fire alarm system 10 of the present embodiment, for example, the control unit 1b controls the transmission unit 1a to turn on and off one switching element 1q to adjust the time interval of the current flowing in a pulsed manner on the pair of electric wires 10a. Then, the fire signal and the interlocking signal can be transmitted. The self-fire alarm system 10 can transmit a fire signal and an interlocking signal to the transmission unit 1a by controlling ON / OFF of one switching element 1q, and thus can have a simpler configuration.

(Embodiment 2)
The self-fire alarm system 10 of the present embodiment discriminates a fire signal and an interlocking signal by changing the current value of the current flowing through the pair of electric wires 10a in the first embodiment, The main difference is that the fire signal is distinguished from the interlocking signal by changing the voltage value. The same components as those in the first embodiment are denoted by the same reference numerals, and the description will be appropriately omitted.

  The self-fire alarm system 10 of the present embodiment includes a receiver 2, a first sensor 11, and a second sensor 12, as in the first embodiment. The first sensor 11 is configured to transmit a fire signal to the receiver 2. The second sensor 12 is configured to transmit at least one of the interlocking signal and the fire signal to the receiver 2. The interlocking signal is a signal for operating the smoke control device 3a in an interlocked manner. The first sensor 11 and the second sensor 12 are electrically connected to the receiver 2 by a pair of electric wires 10a. The receiver 2 has a voltage applying unit 2a and a receiving unit 2c. The voltage application unit 2a applies a voltage between the pair of electric wires 10a. The receiving unit 2c is configured to be able to receive a fire signal and an interlocking signal. As shown in FIG. 6, the second sensor 12 includes a transmission unit 1a and a control unit 1b. The transmitting unit 1a transmits a fire signal and an interlock signal between the pair of wires 10a by short-circuiting the pair of wires 10a. The fire signal and the interlocking signal are voltage signals having different voltage values as shown in FIG. The control unit 1b controls the transmitting unit 1a to transmit a voltage signal. The second sensor 12 and the receiver 2 are configured so that a fire signal and an interlocking signal can be distinguished by a voltage signal applied to the pair of electric wires 10a.

  The self-fire alarm system 10 of the present embodiment transmits a fire signal and an interlocking signal with a voltage signal in which the transmission unit 1a short-circuits the pair of electric wires 10a and changes the voltage value between the pair of electric wires 10a. This can further reduce wiring.

  In the self-fire alarm system 10 of the present embodiment, as shown in FIG. 6, the transmission unit 1a can be configured to include a Zener diode 1s and a switching element 1q. The transmission section 1a includes two series circuits in which a zener diode 1s and a switching element 1q are connected. The transmission unit 1a has a configuration in which two series circuits each including a zener diode 1s and a switching element 1q are electrically connected in parallel. The transmitter 1a is set so that the voltage values of the breakdown voltages of the Zener diodes 1s connected in parallel are different. Each of the switching elements 1q is configured to be individually turned on and off by the control unit 1b.

  The switching element 1q is electrically connected to the anode of the Zener diode 1s. The cathode of the Zener diode 1s is electrically connected to the output terminal on the high potential side of the diode bridge 1d. In the transmitting section 1a, when the control section 1b turns on the switching element 1q, the Zener diode 1s is electrically connected between the pair of electric wires 10a. When the voltage applied between the pair of electric wires 10a exceeds the breakdown voltage of the Zener diode 1s, the voltage is maintained at the breakdown voltage of the Zener diode 1s. The transmitting unit 1a can generate a constant voltage corresponding to the breakdown voltage of the Zener diode 1s between the pair of electric wires 10a. When turning off the switching element 1q, the control unit 1b is electrically disconnected from the pair of electric wires 10a, and the voltage applied between the pair of electric wires 10a does not change. When the control unit 1b controls the switching element 1q to be turned on, the second sensor 12 reduces the voltage between the pair of electric wires 10a to a predetermined voltage value by stepping down the voltage applied to the pair of electric wires 10a. Can be changed. In the transmitting section 1a, the breakdown voltage of the Zener diode 1s is individually set in order to transmit a fire signal and an interlocking signal. In FIG. 6, the Zener diode 1s of the fire alarm circuit 1a1 for transmitting a fire signal is a first Zener diode 1s1, and the Zener diode 1s of the interlock alarm circuit 1a2 for transmitting an interlock signal is a second Zener diode 1s2. The transmission unit 1a can switch the voltage value applied between the pair of electric wires 10a when the switching element 1q of the fire alarm circuit 1a1 is on and when the switching element 1q of the interlocking alarm circuit 1a2 is on. it can.

  When the transmitter 1a reduces the voltage between the pair of electric wires 10a to a predetermined voltage value by the transmission unit 1a, the sensor 1 corresponds to a difference between the voltage applied by the voltage application unit 2a and the predetermined voltage by the Zener diode 1s. Voltage occurs across the resistor 2b of the receiver 2. The resistor 2b has a voltage detecting function of detecting a potential difference between both ends of the resistor 2b based on a voltage drop of a current flowing through the resistor 2b. The receiver 2 can change the voltage between the pair of electric wires 10a to a predetermined voltage value even when the voltage applied by the voltage application unit 2a maintains the same voltage value. The transmission section 1a is not limited to the configuration in which the Zener diode 1s and the switching element 1q are electrically connected in series, and may have a configuration including a constant voltage generation circuit capable of only stepping down.

  Hereinafter, the operation of the self-fire alarm system 10 will be described with reference to FIG.

  FIG. 7 shows the voltage value of the voltage between the pair of electric wires 10a, with the horizontal axis representing the time axis and the vertical axis representing the voltage value. FIG. 7 illustrates that the voltage applied to the pair of electric wires 10a is stepped down by the control unit 1b appropriately controlling the ON and OFF of each switching element 1q in the transmission unit 1a. I have.

Dicaprate warning systems 10, when detector 1 is normal, the voltage application section 2a of the receiver 2, the voltage V ₀ is applied between the pair of wires 10a.

In the sensor 1, the control unit 1b reads the sensor value from the sensor unit 1c periodically at a predetermined sampling cycle. The sensor 1 determines whether a fire has occurred based on a sensor signal from the sensor unit 1c. If the detector 1 does not detect a fire, it repeatedly reads the sensor value. Dicaprate warning systems 10, if all of the sensor 1 is normal, the voltage between the pair of wires 10a will remain the voltage V _0.

Next, the self-fire alarm system 10 turns on the switching element 1q of the fire alarm circuit 1a1 so that the control unit 1b can transmit a fire signal when the second sensor 12 detects a fire at time t5. I do. The second sensor 12, by the switching device 1q fire report circuit 1a1 is turned on, the first voltage V smaller than ₁ showing a fire signal from the voltage V _0, stepping down and such that the second voltage V ₂ or more . In the receiver 2, when the receiving unit 2c receives the fire signal, the display unit 2d is displayed, and the local acoustic device 3b is operated by the signal from the transmitting unit 2h. The second sensor 12 reads the sensor value periodically at a predetermined sampling cycle, and determines whether or not it is in a state of transmitting an interlocking signal. When the second sensor 12 is not in the state of transmitting the interlocking signal, the second sensor 12 maintains the off state of the switching element 1q of the interlocking notification circuit 1a2, and repeatedly reads the sensor value.

  Next, when the second sensor 12 transmits an interlocking signal at time t6, the self-fire alarm system 10 turns on the switching element 1q of the interlocking alarm circuit 1a2 so that the control unit 1b transmits the interlocking signal. . The second sensor 12 lowers the voltage so as to be lower than the second voltage V1 indicating the interlocking signal by turning on the switching element 1q of the interlocking notification circuit 1a2.

  The self-fire alarm system 10 according to the present embodiment is not limited to the configuration in which the voltage applied to the pair of electric wires 10a is stepwise reduced in accordance with a fire signal or an interlocking signal. In the self-fire alarm system 10 of the present embodiment, as shown in FIG. 8, the second sensor 12 may be configured such that one of the fire signal and the interlocking signal is a pulse signal and the other is a signal of a constant level. it can.

  The self-fire alarm system 10 can control one of the switching elements 1q to be repeatedly turned on and off at a predetermined timing, so that one of the fire signal and the interlocking signal can be a pulse signal. The self-fire alarm system 10 can set the other one of the fire signal and the interlocking signal to a constant level signal by turning on one switching element 1q at a predetermined timing.

  In the self-fire alarm system 10 of the present embodiment, for example, the control unit 1b controls the transmission unit 1a to turn on and off one switching element 1q, thereby setting the time interval of the voltage applied to the pair of electric wires 10a. By adjusting, a fire signal and an interlocking signal can be transmitted. The self-fire alarm system 10 can transmit a fire signal and an interlocking signal to the transmission unit 1a by controlling ON / OFF of one switching element 1q, and thus can have a simpler configuration.

1a Transmission unit 1b Control unit 2 Receiver 2a Voltage application unit 2c Receiving unit 3a Smoke elimination device 3b District sound device 10 Automatic fire alarm system 10a A pair of electric wires 11 First sensor 12 Second sensor

Claims (5)

A receiver, a first sensor for transmitting a fire signal, and a second sensor for transmitting at least one of an interlocking signal or a fire signal for operating the smoke prevention device in conjunction with the first sensor,
The first sensor and the second sensor are electrically connected to the receiver with a pair of wires,
The receiver has a voltage application unit that applies a voltage between the pair of electric wires, and a reception unit that receives a fire signal and an interlocking signal,
A transmitting unit that short-circuits the pair of electric wires and transmits a fire signal and an interlocking signal with current signals having different current values between the pair of electric wires, and controls the transmitting unit; And a control unit for transmitting the current signal by
The second sensor is a current signal flowing through said pair of wires, is configured to be able to discriminate between the interlocking signal and a fire signal,
The second sensor is configured to determine whether to transmit a fire signal to the receiver or an interlocking signal to the receiver in accordance with a current signal flowing through the pair of electric wires. Notification system. 2. The automatic fire alarm system according to claim 1 , wherein the receiver is configured to be able to discriminate a fire signal and an interlocking signal based on a current signal flowing through the pair of electric wires. 3. A receiver, a first sensor for transmitting a fire signal to the receiver, and a second signal for transmitting at least one of an interlocking signal or a fire signal for operating the smoke control device in cooperation with the receiver. And a sensor,
The first sensor and the second sensor are electrically connected to the receiver with a pair of wires,
The receiver has a voltage application unit that applies a voltage between the pair of electric wires, and a reception unit that receives a fire signal and an interlocking signal,
A transmitting unit that short-circuits the pair of wires and transmits a fire signal and an interlocking signal with voltage signals having different voltage values between the pair of wires, and controls the transmitting unit; And a control unit for transmitting a voltage signal by
The second sensor is configured to be able to discriminate a fire signal and an interlocking signal by a voltage signal applied to the pair of electric wires ,
The second sensor determines whether to transmit a fire signal to the receiver or an interlocking signal to the receiver according to a voltage signal applied to the pair of wires . automatic fire alarm system that. 4. The automatic fire alarm system according to claim 3 , wherein the receiver is configured to be able to discriminate a fire signal and an interlocking signal based on a voltage signal applied to the pair of electric wires. 5. Said second sensor, said one of the fire signal or the interlock signal transmitted as a pulse signal, any one of claims 1 to 4, characterized in that sending the other a constant level signal Automatic fire alarm system described in section.

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