JP6579769B2 - Relay device and alarm system - Google Patents

Description

  The present invention relates to a relay device that is interposed between a terminal device and a receiver and relays a signal from the terminal device to the receiver, and an alarm system including the relay device.

  2. Description of the Related Art Conventionally, a relay device that relays a signal from a terminal device to a receiver is interposed between the terminal device and the receiver. Patent Document 1 discloses a disaster prevention monitoring system including such a relay device (wireless reception repeater). In Patent Document 1, a relay device is interposed between a terminal device (wireless sensor) and a receiver, is connected to the terminal device via radio, and is connected to the receiver via a pair of reception wires. Yes. And the relay apparatus will transmit the said various signals to a receiver via a pair of receiving wiring, if the various signals transmitted from a terminal device are received via radio | wireless.

  For example, when the relay device receives a fire signal transmitted from the terminal device, the relay device transmits a fire signal to the receiver by substantially short-circuiting the pair of receiving wires. In addition, when the relay device receives an abnormal signal (for example, a battery exhaustion signal) transmitted from the terminal device, the relay device transmits a disconnection signal generated by disconnecting the pair of reception wirings to the receiver as the abnormal signal.

JP 2011-96169 A

  The relay device as described above may be configured to transmit a disconnection signal by disconnecting a pair of reception wirings to the receiver as an abnormal signal when no power is supplied to the power supply. . However, although the relay device is in a non-energized state, such as when a maintenance inspection is performed, there is an opinion that a disconnection signal based on the non-energization is unnecessary depending on the user. I want to be able to select the necessity of a disconnection signal based on energization.

  In addition, as a relay device as described above, in the case of various abnormalities other than a fire, it is configured to transmit a disconnection signal by disconnecting between a pair of reception wirings to the receiver, so that on the receiver side There is a desire to be able to confirm that various abnormalities have occurred. Therefore, it is necessary to be able to output a disconnection signal even when other abnormalities occur while allowing the user to select whether a disconnection signal based on non-energization is necessary.

  The present invention has been made to solve the above problems, and provides a relay device that can select whether or not to output a disconnection signal when no power is supplied, and an alarm system including the relay device. To do.

  In addition, the present invention provides a relay device capable of selecting whether or not to output a disconnection signal when no power is supplied, and can output a disconnection signal when another abnormality occurs and the relay device An alarm system including the above is provided.

  The relay device according to the present invention is interposed between a terminal device and a receiver and relays a signal from the terminal device to the receiver. The relay device is connected to the receiver via a pair of reception wirings, and A relay device that can select whether or not to output a disconnection signal that disconnects between a pair of receiving wires as a signal indicating a non-energized state when energized, and is connected to the relay connected to the other of the receiving wires and the relay And a third jumper terminal connected to one of the reception wirings, and the relay connects the other of the reception wirings and the fourth jumper terminal when no power is applied. Between the third jumper terminal and the fourth jumper terminal, either the non-short-circuit state or the short-circuit state is selected. In the non-short-circuit state, a disconnection signal is output when no power is supplied, and the short-circuit state The disconnection signal is output when no power is supplied. Characterized in that it is configured so as not.

  According to the present invention, a relay, a third jumper terminal, and a fourth jumper terminal are provided, and the relay connects the other of the reception wiring and the fourth jumper terminal when no power is supplied. Between the jumper terminal 3 and the fourth jumper terminal, either a non-short-circuit state or a short-circuit state is selected. In the non-short-circuit state, a disconnection signal is output when no power is supplied. The disconnection signal is not output when no power is supplied. Thereby, it is possible to select whether or not to output a disconnection signal when no power is supplied.

It is a block diagram which shows the alarm system 2 which concerns on Embodiment 1 of this invention. 1 is a block diagram showing a wireless repeater power supply device 1 according to a first embodiment of the present invention. It is a circuit diagram which shows the connection of the power supply apparatus 1 for wireless repeaters and the receiver 5 which concern on Embodiment 1 of this invention. It is a figure which shows the jumper setting in Embodiment 1 of this invention. It is a circuit diagram which shows the power supply apparatus 1 for wireless repeaters which concerns on Embodiment 2 of this invention.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments of a power supply device 1 for a wireless repeater and an alarm system 2 according to the present invention will be described with reference to the drawings. The present invention is not limited to the embodiments described below. Moreover, in the following drawings including FIG. 1, the relationship of the size of each component may be different from the actual one.

Embodiment 1 FIG.
FIG. 1 is a block diagram showing an alarm system 2 according to Embodiment 1 of the present invention. The alarm system 2 will be described based on FIG. As shown in FIG. 1, the alarm system 2 includes a wireless sensor 3, a wireless relay 4 (an example of a terminal device), a receiver 5, and a wireless relay power supply device 1 (an example of a relay device). And. The wireless sensor 3 is a fire sensor that detects smoke or the like, for example. The wireless sensor 3 is not directly connected to the receiver 5 by wire, and a fire signal or the like is transmitted and received wirelessly via the wireless relay 4.

  The wireless repeater 4 wirelessly transmits and receives signals to and from the wireless sensor 3 and transmits a signal received from the wireless sensor 3 to the receiver 5 through wiring. In the first embodiment, the wireless repeater 4 transmits a signal to the receiver 5 via the wireless repeater power supply device 1.

  The receiver 5 performs notification such as a fire alarm based on the signal received from the wireless repeater 4. In the first embodiment, the receiver 5 receives a signal from the wireless repeater 4 via the wireless repeater power supply device 1. The receiver 5 is input with, for example, an AC power supply of 100V. Note that the receiver 5 may be a notification repeater for a fire or the like.

  The power supply device 1 for the wireless repeater supplies power to the wireless repeater 4 and is interposed between the wireless repeater 4 and the receiver 5 so that the signal from the wireless repeater 4 is sent to the receiver 5. Relay. For example, a 100 V AC power supply (commercial power supply) is input to the power supply device 1 for the wireless repeater, and a spare power supply 14 is also connected thereto. The wireless relay power supply device 1 may not have a power supply function but may have only a relay function.

  Here, the wireless relay power supply device 1 further includes a power supply voltage monitoring circuit (not shown). The power supply voltage monitoring circuit is connected to the power supply circuit 26, for example, and measures the voltage output from the power supply circuit 26. Normally, the wireless relay power supply device 1 is driven by a commercial power supply. When the voltage measured by the power supply voltage monitoring circuit falls below a predetermined voltage, the wireless repeater power supply device 1 is switched from driving by the commercial power supply to driving by the standby power supply 14. As a result, the wireless relay power supply device 1 is driven by the standby power supply 14.

  The wireless repeater power supply 1 and the wireless repeater 4 are connected by a pair of power supply lines 13, and the wireless repeater power supply 1 uses the power supply line 13 to supply power to the wireless repeater 4. Supply. The wireless repeater power supply device 1 and the wireless repeater 4 are connected by a pair of relay wires 11, and the wireless repeater power supply device 1 uses the relay wires 11 to connect the wireless repeater 4. Sends and receives signals to and from. This signal is, for example, a fire signal received by the wireless repeater 4 from the wireless sensor 3.

  Further, the wireless relay power supply device 1 and the receiver 5 are connected by a pair of reception wirings 12, and the wireless relay power supply device 1 is connected to the receiver 5 using the reception wiring 12. Send and receive signals. This signal is, for example, a fire signal received from the wireless repeater 4 by the wireless repeater power supply device 1. The wireless repeater power supply device 1 has a function of transferring various types of abnormality information to an external device.

  The wireless sensor 3 transmits a fire signal when it detects a fire due to smoke or the like.

  In addition, although not shown, the wireless repeater 4 is normally connected in series with a first switching element that is open and a resistance for adjusting a reporting current (for example, 100Ω) (see FIG. 2). A switching circuit connected in parallel to a relay termination resistor 15) to be described later is provided. This switching circuit has the same configuration as the switching circuit (described later) of the wireless relay power supply device 1. When the wireless repeater 4 receives the fire signal from the wireless sensor 3, the wireless repeater 4 operates the switching circuit by closing the first switching element to adjust the alarm current as fire information (fire signal). It operates so that a substantially short-circuit current based on the resistance of the current flows through the relay wiring 11.

  FIG. 2 is a block diagram showing the wireless relay power supply device 1 according to Embodiment 1 of the present invention. As shown in FIG. 2, the power supply device 1 for a wireless repeater includes a first reception terminal 22a, a second reception terminal 22b, a first termination terminal 29a, and a second termination terminal 29b. Yes. Further, the wireless relay power supply device 1 includes a relay disconnection monitoring circuit 25, a pair of relay terminals 21, a control circuit 27, a power supply terminal 28, a message relay 30, an LED 31, a wiring terminal block 32, A transfer terminal block 33 is provided. The first reception terminal 22a and the second reception terminal 22b are a pair of reception terminals, and the first termination terminal 29a and the second termination terminal 29b are a pair of termination terminals.

  The first reception terminal 22 a is connected to one end of the receiver 5 via one of the pair of reception wirings 12. The second reception terminal 22 b is connected to the other end of the receiver 5 via the other of the pair of reception wirings 12. The first termination terminal 29a is connected to one end of the terminator 16 for detecting disconnection of the reception wiring 12 by the receiver 5, and is connected to the first reception terminal 22a. The second termination terminal 29 b is connected to the other end of the terminator 16. The terminator 16 may be a termination resistor, and the resistance value may be the same as that of the relay termination resistor 15 (described later), for example, 10 kΩ.

  The pair of relay terminals 21 are connected to the wireless repeater 4 via the relay wiring 11.

  The relay disconnection monitoring circuit 25 is connected between the relay terminals 21 and monitors disconnection of the relay wiring 11. The wireless repeater 4 is connected to a relay termination resistor 15 for detecting disconnection connected to the end of the relay wiring 11 and is, for example, 10 kΩ. The relay disconnection monitoring circuit 25 detects a weak current based on the relay termination resistor 15 flowing in the relay wiring 11 and determines that the relay wiring 11 is disconnected when detecting that the weak current stops flowing. In this way, the relay disconnection monitoring circuit 25 monitors the disconnection of the relay wiring 11. When the disconnection of the relay wiring 11 is confirmed, a relay disconnection alarm (described later) indicating that the relay wiring 11 is disconnected is output.

  The relay disconnection monitoring circuit 25 also has a function of detecting a fire signal received from the wireless repeater 4 and transmitting it to the control circuit 27. Here, the relay disconnection monitoring circuit 25 detects a substantially short-circuit current flowing through the relay wiring 11 based on the switching operation of the wireless repeater 4, and determines that the substantially short-circuit current is flowing, it detects a fire signal. to decide.

  Note that a circuit for detecting a fire signal may be provided as a relay fire monitoring circuit separately from the relay disconnection monitoring circuit 25.

  The power supply circuit 26 is input with power after being transformed by the transformer from the power supplied from the AC power supply. The power supply circuit 26 converts this power into a predetermined power and supplies it to the relay disconnection monitoring circuit 25 and the control circuit 27. Output. The relay disconnection monitoring circuit 25 and the control circuit 27 are configured to be supplied with power also from the standby power supply 14. The control circuit 27 transmits abnormality information or fire information to the receiver 5 based on the signal received from the relay disconnection monitoring circuit 25. In addition, the control circuit 27 transmits the abnormality information or the fire information to the relay relay 30 and the LED 31. The pair of power supply terminals 28 are connected to the wireless repeater 4 via the power supply line 13. Note that a fuse is attached to the power supply terminal 28. Further, the wireless repeater power supply device 1 is provided with a panel switch 14a. When the panel switch 14a is pressed, the battery test circuit 14b is driven and a voltage test of the standby power supply 14 is performed.

  Here, a disconnection output circuit 42 is provided between the terminator 16 (the first termination terminal 29a and the second termination terminal 29b) and the reception wiring 12 (the first reception terminal 22a and the second reception terminal 22b). And a third switching element 43 as a switching circuit, and a resistor 44.

  In addition, the part in which the disconnection output circuit 42 and the third switching element 43 are mounted is insulated from other parts.

  When the relay disconnection monitoring circuit 25 confirms the disconnection of the relay wiring 11, the relay disconnection monitoring circuit 25 transmits the abnormality information (disconnection information) to the control circuit 27. And in the case of abnormality information, the control circuit 27 is normally from the state which has short-circuited the 2nd receiving terminal 22b and the 2nd terminal 29b by the disconnection output circuit 42 connected in series with the terminator 16. The second receiving terminal 22b and the second termination terminal 29b are changed to a state of opening. Thereby, the abnormality information is transmitted to the receiver 5. That is, a disconnection signal for disconnecting between the reception wirings 12 is output as abnormality information (a signal indicating an abnormal state), and a weak current based on the terminator 16 is not supplied to the reception wiring 12. At this time, a relay disconnection alarm (described later) indicating that the relay wiring 11 is disconnected is output.

  When the relay disconnection monitoring circuit 25 receives a fire signal or the like from the wireless repeater 4, the relay disconnection monitoring circuit 25 transmits the fire information to the control circuit 27. Then, in the case of fire information, the control circuit 27 closes the normally open third switching element 43 connected in parallel to the terminator 16 and causes the switching circuit to perform a switching operation. Thereby, fire information is transmitted to the receiver 5. The third switching element 43 is connected in series with an alarm current adjusting resistor 44 having a resistance value smaller than that of the terminator 16. A substantially short-circuit current larger than the weak current based on the terminator 16 flows.

  The transfer relay 30 is a switch used when transferring each abnormality information to an external device. The LED 31 displays information, and includes an AC power supply lamp, a standby power supply abnormality lamp, a secondary power supply abnormality lamp, a fire lamp, and a disconnection lamp. The AC power lamp is displayed when the supply of AC power is cut off. The standby power supply abnormality lamp is displayed when an abnormality occurs in the backup power supply 14. The secondary power abnormality lamp is displayed when an abnormality occurs in the fuse attached to the power terminal 28. The fire light is displayed in the event of a fire. The disconnection lamp is displayed when disconnection is an example of a relay disconnection alarm.

  The wiring terminal block 32 is a terminal block provided with the relay terminal 21, the first reception terminal 22a, the second reception terminal 22b, the power supply terminal 28, the first termination terminal 29a, and the second termination terminal 29b. The transfer terminal block 33 is a terminal block provided with terminals for transferring information to an external device. For example, an abnormal representative terminal, an AC power disconnection terminal, a standby power supply abnormal terminal, and a secondary power supply abnormal terminal are provided. The abnormality representative terminal is a terminal for transferring information when any abnormality occurs, and corresponds to the transfer terminal 98 of the present invention. This abnormality includes disconnection of the relay wiring 11, and this is also an example of the relay disconnection alarm. The AC power cut-off terminal is a terminal for transferring information when the supply of AC power is cut off. The standby power supply abnormality terminal is a terminal for transferring information when an abnormality occurs in the standby power supply 14. The secondary power supply abnormality terminal is a terminal for transferring information when an abnormality occurs in the fuse attached to the power supply terminal 28.

  Next, in FIG. 1, the receiver 5 is connected to the reception wiring unit 12 and a reception alarm unit (not shown) that outputs a reception disconnection alarm when a disconnection between the reception wirings 12 is confirmed. And a monitoring circuit (not shown) for monitoring disconnection between them. When the monitoring circuit detects a weak current based on the terminator 16 flowing in the reception wiring 12 and detects that the weak current stops flowing, the reception circuit 12 is disconnected, that is, as a signal indicating an abnormal state. It is determined that a disconnection signal has been received. In this way, the monitoring circuit monitors whether or not a disconnection signal is received. When reception of the disconnection signal is confirmed, the reception alarm unit outputs a reception disconnection alarm indicating that the disconnection signal has been received.

  The receiver 5 determines that the fire information has been received when the monitoring circuit (not shown) detects a substantially short-circuit current based on the switching operation of the wireless relay power supply device 1. And the above-mentioned reception warning part (not shown) outputs a reception fire warning.

  Note that the receiver 5 may separately provide a fire monitoring circuit that is a circuit that detects fire information and a disconnection monitoring circuit that is a circuit that monitors disconnection between the reception wirings 12 as monitoring circuits.

  FIG. 3 is a circuit diagram showing the connection between radio relay power supply apparatus 1 and receiver 5 according to the first embodiment of the present invention. Next, the wireless relay power supply device 1 will be described in detail. As shown in FIG. 3, the disconnection output circuit 42 of the wireless relay power supply device 1 includes a relay 65, a first jumper terminal 51, a second jumper terminal 52, a third jumper terminal 56, 4 jumper terminals 57, switching unit 60, fifth jumper terminal 53, sixth jumper terminal 54, seventh jumper terminal 58, eighth jumper terminal 59, first resistor 45, , A second resistor 46, a third resistor 47, and a fourth resistor 48. In FIG. 3, the third switching element 43 and the resistor 44 are connected to the receiver 5 side with respect to the disconnection output circuit 42. Thereby, the power supply device 1 for wireless repeaters gives priority to fire notification over abnormality notification.

  The relay 65 has a relay base terminal 68, a first relay terminal 66, and a second relay terminal 67 connected to the second reception terminal 22b, and connects the relay base terminal 68 and the first relay terminal 66. Or whether the relay base terminal 68 and the second relay terminal 67 are connected can be switched. In addition, the relay base terminal 68 and the 2nd relay terminal 67 are connected to the relay 65 at the time of no electricity supply. The first jumper terminal 51 is connected to the first relay terminal 66. The second jumper terminal 52 is connected to the second termination terminal 29b. The third jumper terminal 56 is connected to the second termination terminal 29b. The fourth jumper terminal 57 is connected to the second relay terminal 67.

  The fifth jumper terminal 53 is connected to the switching unit 60. The sixth jumper terminal 54 has a high impedance when energization is normal and is grounded when energization is abnormal. This is controlled by an energization control unit 70 composed of each element. The seventh jumper terminal 58 also has a high impedance when energization is normal, and is grounded when energization is abnormal. A first voltage source 71 is connected to the sixth jumper terminal 54 and the seventh jumper terminal 58. The eighth jumper terminal 59 is connected to the switching unit 60.

  The switching unit 60 controls the operation of the relay 65. The switching unit 60 includes a first relay switching element 61, a second relay switching element 62, and a relay control unit 63. The first relay switching element 61 is, for example, a bipolar transistor, and the eighth jumper terminal 59 is connected to the base, the second voltage source 72 and the fifth jumper terminal 53 are connected to the collector, and the emitter is grounded. ing.

  The second relay switching element 62 is, for example, a bipolar transistor. The second voltage source 72, the fifth jumper element, and the collector of the first relay switching element 61 are connected to the base, and the relay control unit 63 is connected to the collector. Connected and the emitter is grounded. The relay control unit 63 is composed of each element and controls the operation of the relay 65. The relay control unit 63 connects the relay base terminal 68 and the first relay terminal 66 when current flows, and connects the relay base terminal 68 and the second relay terminal 67 when current does not flow.

  The first resistor 45 is provided downstream of the first voltage source 71. The second resistor 46 is provided downstream of the second voltage source 72. The third resistor 47 is connected to the base of the first relay switching element 61. The fourth resistor 48 is connected to the base of the second relay switching element 62.

  Here, the first jumper terminal 51 and the second jumper terminal 52 are short-circuited by, for example, the first jumper 50. The fifth jumper terminal 53 and the sixth jumper terminal 54 are also short-circuited by the first jumper 50, for example. On the other hand, the third jumper terminal 56 and the fourth jumper terminal 57 are short-circuited by, for example, the second jumper 55. The seventh jumper terminal 58 and the eighth jumper terminal 59 are also short-circuited by the second jumper 55, for example.

  As described above, in the wireless relay power supply device 1, the first jumper 50 short-circuits the first jumper terminal 51 and the second jumper terminal 52, and the first jumper 50 connects the fifth jumper terminal 53. A first state in which the sixth jumper terminal 54 is short-circuited, a third jumper terminal 56 and a fourth jumper terminal 57 are short-circuited by the second jumper 55, and a seventh jumper terminal 55 is short-circuited by the second jumper 55. One of the second states in which the jumper terminal 58 and the eighth jumper terminal 59 are short-circuited is selected.

  Next, the operation of the wireless relay power supply device 1 will be described. First, the operation when a fire or the like occurs will be described. When the relay disconnection monitoring circuit 25 receives a fire signal or the like from the wireless repeater 4 by detecting a substantially short-circuit current based on the switching operation of the wireless repeater 4, the relay disconnection monitoring circuit 25 displays the fire information. Transmit to the control circuit 27. And the control circuit 27 closes the 3rd switching element 43 in the case of fire information. Thereby, fire information is transmitted to the receiver 5. Further, the control circuit 27 performs a fire display with a fire light of the LED 31.

  On the other hand, when the monitoring circuit (not shown) detects a substantially short-circuit current based on the switching operation of the wireless relay power supply device 1, the receiver 5 determines that the fire information has been received. Then, a reception alarm unit (not shown) outputs a reception fire alarm.

  Next, an operation when the relay wiring 11 is disconnected will be described. The relay disconnection monitoring circuit 25 determines that the relay line 11 is disconnected when it detects that the weak current based on the relay termination resistor 15 flowing in the relay line 11 does not flow as described above. When the relay disconnection monitoring circuit 25 confirms the disconnection of the relay wiring 11, the relay disconnection monitoring circuit 25 transmits the abnormality information (disconnection information) to the control circuit 27. Then, in the case of abnormality information, the control circuit 27 outputs a disconnection signal for disconnecting the reception wires 12 by the disconnection output circuit 42. Thereby, the abnormality information is transmitted to the receiver 5. In addition, the control circuit 27 performs a disconnection display by the disconnection lamp of the LED 31, and outputs a relay disconnection alarm indicating that the relay wiring 11 is disconnected.

  On the other hand, when the monitoring circuit (not shown) detects the weak current based on the terminator 16 that always flows in the reception wiring 12, the receiver 5 detects that the weak current stops flowing. It is determined that a disconnection signal is received as a signal indicating an abnormal state. When reception of the disconnection signal is confirmed, a reception alarm unit (not shown) outputs a reception disconnection alarm indicating that the disconnection signal has been received.

  FIG. 4 is a diagram showing jumper settings in the first embodiment of the present invention. Next, the operation | movement in each energization state of the power supply device 1 for wireless repeaters is demonstrated. Examples of the energized state include normal energization, abnormal energization, and no energization. The normal energization refers to a state (normal state) in which power is supplied by either the AC power supply or the standby power supply 14 and the relay disconnection monitoring circuit 25 does not detect disconnection. The energization abnormality refers to a state (abnormal state) in which the AC power supply or the standby power supply 14 is energized and the relay disconnection monitoring circuit 25 detects the disconnection. “Non-energized” refers to a state where no power is supplied by either the AC power supply or the standby power supply 14.

  First, the case of the first state in which the first jumper 50 is attached will be described. As shown in FIG. 4, when the energization state is normal energization, the energization control unit 70 becomes high impedance under the control of the control circuit 27. Therefore, the sixth jumper terminal 54 has a high impedance, and the fifth jumper terminal 53 also has a high impedance. Further, since no current flows through the base of the first relay switching element 61, the first relay switching element 61 is turned off. Therefore, no current flows from the collector to the emitter of the first relay switching element 61. Therefore, current flows in the order of the first voltage source 71, the first resistor 45, the sixth jumper terminal 54, the fifth jumper terminal 53, the fourth resistor 48, and the base of the second relay switching element 62.

  As a result, the second relay switching element 62 is turned on, and a current flows from the collector of the second relay switching element 62 to the emitter. That is, a current flows through the relay control unit 63, and the relay base terminal 68 and the first relay terminal 66 are connected in the relay 65. At this time, the second reception terminal 22b and the second termination terminal 29b are the second reception terminal 22b, the relay base terminal 68, the first relay terminal 66, the first jumper terminal 51, and the second jumper terminal. 52 and the second terminal 29b. Therefore, since the terminator 16 is connected to the wireless repeater power supply device 1, a disconnection signal due to disconnection between the pair of reception wirings 12, which is a signal indicating an abnormal state, is not output. Therefore, the reception disconnection alarm in the reception alarm unit of the receiver 5 is blocked.

  As shown in FIG. 4, when the energization state is an energization abnormality, the energization control unit 70 is grounded under the control of the control circuit 27. Therefore, the sixth jumper terminal 54 is grounded, and the fifth jumper terminal 53 is also grounded. Further, since no current flows through the base of the first relay switching element 61, the first relay switching element 61 is turned off. Therefore, no current flows from the collector to the emitter of the first relay switching element 61. Therefore, since the base of the second relay switching element 62 connected to the fifth jumper terminal 53 is also grounded, the second relay switching element 62 is turned off.

  Accordingly, no current flows from the collector to the emitter of the second relay switching element 62. That is, no current flows through the relay control unit 63, and the relay base terminal 68 and the second relay terminal 67 are connected in the relay 65. At this time, the second reception terminal 22b and the second termination terminal 29b are not connected because the third jumper terminal 56 and the fourth jumper terminal 57 are open. Therefore, since the terminator 16 is disconnected from the power supply device 1 for the wireless repeater, a disconnection signal is output as a signal indicating an abnormal state by disconnecting the pair of reception wires 12. Therefore, a reception disconnection alarm in the reception alarm unit of the receiver 5 is output.

  Thus, in the first state, in the first state, the relay base terminal 68 and the first relay terminal 66 are connected when the energization is normal, and the relay base terminal 68 and the second relay terminal 67 are connected when the energization is abnormal. Is done.

  As shown in FIG. 4, when the energized state is non-energized, no current flows through the relay control unit 63, so that the relay base terminal 68 and the second relay terminal 67 are connected in the relay 65. At this time, the second reception terminal 22b and the second termination terminal 29b are not connected because the third jumper terminal 56 and the fourth jumper terminal 57 are open. Therefore, since the terminator 16 is disconnected from the power supply device 1 for the wireless repeater, a disconnection signal is output as a signal indicating an abnormal state by disconnecting the pair of reception wires 12. Therefore, a reception disconnection alarm in the reception alarm unit of the receiver 5 is output. Thus, in the first state where the first jumper 50 is attached, when the wireless relay power supply device 1 is not energized, a reception disconnection alarm in the reception alarm unit of the receiver 5 is output.

  Next, the case of the second state in which the second jumper 55 is attached will be described. As shown in FIG. 4, when the energization state is normal energization, the energization control unit 70 becomes high impedance under the control of the control circuit 27. For this reason, the seventh jumper terminal 58 has high impedance, and the eighth jumper terminal 59 also has high impedance. Therefore, current flows in the order of the first voltage source 71, the first resistor 45, the seventh jumper terminal 58, the eighth jumper terminal 59, the third resistor 47, and the base of the first relay switching element 61. As a result, the first relay switching element 61 is turned on, and a current flows from the collector of the first relay switching element 61 to the emitter.

  Therefore, since the current flows in the order of the second voltage source 72, the second resistor 46, the collector of the first relay switching element 61, and the emitter of the first relay switching element 61, the base of the second relay switching element 62 There is no current flowing through. Accordingly, the second relay switching element 62 is turned off, and no current flows from the collector to the emitter of the second relay switching element 62. That is, no current flows through the relay control unit 63, and the relay base terminal 68 and the second relay terminal 67 are connected in the relay 65. At this time, the second reception terminal 22b and the second termination terminal 29b are the second reception terminal 22b, the relay base terminal 68, the second relay terminal 67, the fourth jumper terminal 57, and the third jumper terminal. 56 and the second terminal 29b are connected by a path. Therefore, since the terminator 16 is connected to the wireless repeater power supply device 1, a disconnection signal due to disconnection between the pair of reception wirings 12, which is a signal indicating an abnormal state, is not output. Therefore, the reception disconnection alarm in the reception alarm unit of the receiver 5 is blocked.

  As shown in FIG. 4, when the energization state is an energization abnormality, the energization control unit 70 is grounded under the control of the control circuit 27. Therefore, the seventh jumper terminal 58 is grounded, and the eighth jumper terminal 59 is also grounded. Therefore, since no current flows through the base of the first relay switching element 61, the first relay switching element 61 is turned off. Therefore, no current flows from the collector to the emitter of the first relay switching element 61. Therefore, current flows in the order of the second voltage source 72, the second resistor 46, the fourth resistor 48, and the base of the second relay switching element 62.

  As a result, the second relay switching element 62 is turned on, and a current flows from the collector to the emitter of the second relay switching element 62. That is, a current flows through the relay control unit 63, and the relay base terminal 68 and the first relay terminal 66 are connected in the relay 65. At this time, the second reception terminal 22b and the second termination terminal 29b are not connected because the first jumper terminal 51 and the second jumper terminal 52 are open. Therefore, since the terminator 16 is disconnected from the power supply device 1 for the wireless repeater, a disconnection signal is output as a signal indicating an abnormal state by disconnecting the pair of reception wires 12. Therefore, a reception disconnection alarm in the reception alarm unit of the receiver 5 is output.

  Thus, in the second state, in the second state, the relay base terminal 68 and the second relay terminal 67 are connected when the energization is normal, and the relay base terminal 68 and the first relay terminal 66 are connected when the energization is abnormal. Is done.

  As shown in FIG. 4, when the energized state is non-energized, no current flows through the relay control unit 63, so that the relay base terminal 68 and the second relay terminal 67 are connected in the relay 65. At this time, the second reception terminal 22b and the second termination terminal 29b are the second reception terminal 22b, the relay base terminal 68, the second relay terminal 67, the fourth jumper terminal 57, and the third jumper terminal. 56 and the second terminal 29b are connected by a path. Therefore, since the terminator 16 is connected to the wireless repeater power supply device 1, a disconnection signal due to disconnection between the pair of reception wirings 12, which is a signal indicating an abnormal state, is not output. Therefore, the reception disconnection alarm in the reception alarm unit of the receiver 5 is blocked. Thus, in the second state in which the second jumper 55 is attached, the reception disconnection alarm in the reception alarm unit of the receiver 5 is blocked when the wireless relay power supply device 1 is not energized.

  Next, the operation of the wireless relay power supply device 1 will be described. The wireless repeater power supply device 1 includes a relay 65, a third jumper terminal 56, and a fourth jumper terminal 57. The relay 65 and the fourth jumper terminal 57 are connected to the other of the reception wiring 12 when no power is supplied. Between the third jumper terminal 56 and the fourth jumper terminal 57, either a non-short-circuit state or a short-circuit state is selected. A disconnection signal is sometimes output, and in a short-circuit state, the disconnection signal is not output when no power is supplied. Thereby, it is possible to select whether or not to output a disconnection signal when no power is supplied.

  Thereby, when the power supply device 1 for a wireless repeater is subjected to maintenance inspection or the like, it is possible to prevent a disconnection signal from being output even if the wireless relay device 1 is turned off.

  The wireless relay power supply device 1 includes a first reception terminal 22a connected to one of the pair of reception wirings 12, a second reception terminal 22b connected to the other of the pair of reception wirings 12, and a termination. One end of the device 16, a first terminal 29 a connected to the first receiving terminal 22 a, and a second terminal 29 b connected to the other end of the terminal 16, and the relay 65 includes: A relay base terminal 68 and a second relay terminal 67; the relay base terminal 68 is connected to the second receiving terminal 22b; the second relay terminal 67 is connected to the fourth jumper terminal 57; It is configured to switch whether to connect the relay base terminal 68 and the second relay terminal 67, and further, the relay base terminal 68 and the second relay terminal 67 are connected when no power is supplied. The other of the reception wiring 12 and the fourth The third jumper terminal 56 is connected to the second termination terminal 29b. In the non-short-circuit state, the receiving wiring 12 and the terminator 16 are connected to each other when no current is applied. By disconnecting, a disconnection signal is output, and in a short circuit state, the disconnection signal is not output by connecting the receiving wiring 12 and the terminator 16 when no power is supplied. For this reason, as described above, it is possible to select whether or not to output a disconnection signal when no power is supplied.

  Further, the relay 65 has a first relay terminal 66 and connects the relay base terminal 68 and the first relay terminal 66 or connects the relay base terminal 68 and the second relay terminal 67. The wireless repeater power supply device 1 is configured to switch between the first jumper terminal 51 connected to the first relay terminal 66 and the second jumper terminal 29b. A first state in which the first jumper terminal 51 and the second jumper terminal 52 are short-circuited, and a short-circuit state (the third jumper terminal 56 and the fourth jumper terminal 57 are One of the second state, which is a short circuit state), is selected. In the first state, the disconnection signal is output by disconnecting the receiving wiring 12 and the terminator 16 when no power is supplied. In the second state, no power is supplied To, by the receive line 12 and the terminal 16 is connected, disconnected signal is configured not output. For this reason, as described above, it is possible to select whether or not to output a disconnection signal when no power is supplied.

  Furthermore, in the first state, the relay 65 is connected to the relay base terminal 68 and the first relay terminal 66 when the energization and abnormality are not generated (the relay wiring 11 is not disconnected) and the energization is normal. In addition, the relay base terminal 68 and the second relay terminal 67 are connected when the energization and abnormality occurs (the relay wiring 11 is disconnected) and the energization abnormality occurs, and in the second state, when the energization is normal The relay base terminal 68 and the second relay terminal 67 are connected, and the relay base terminal 68 and the first relay terminal 66 are connected in the first state when the energization is abnormal. Then, when the energization is normal, the reception wiring 12 and the terminator 16 are connected, so that the disconnection signal is not output, and when the energization is abnormal, the reception wiring 12 and the terminator 16 are disconnected, thereby causing the disconnection signal. Is output In the second state, when the energization is normal, the receiving wiring 12 and the terminator 16 are connected, so that a disconnection signal is not output, and when the energization is abnormal, the receiving wiring 12 and the terminator 16 are disconnected. As a result, a disconnection signal is output. For this reason, it is possible to select whether or not to output a disconnection signal indicating a non-energized state at the time of non-energization, but also when other abnormality occurs (such as when the relay wiring 11 is disconnected). Can be output.

  The alarm system 2 includes a wireless repeater 4 (terminal device), a receiver 5, and a wireless repeater power supply device 1 (relay device). The receiver 5 is transmitted from the relay device. A reception alarm is provided for outputting a reception disconnection alarm when a disconnection signal is received. For this reason, the disconnection signal can be received on the receiver side and a reception disconnection alarm can be output.

  It is interposed between the terminal device and the receiver 5 and relays the signal from the terminal device to the receiver 5, and is connected to the receiver 5 through a pair of receiving wirings 12, and when no power is supplied, A relay device capable of selecting whether or not to output a disconnection signal for disconnecting a pair of receiving wirings 12 as a signal indicating an energized state, the disconnection being provided between the pair of receiving wirings 12 and the terminator 16 The disconnection output circuit 42 includes a first state in which the first jumper 50 is attached and a second jumper 55 in a path in which the pair of reception wirings 12 and the terminator 16 can be connected. Either the second state or the attached second state can be selected. In the first state, a disconnection signal is output when no power is supplied, and in the second state, a disconnection signal is not output when no power is supplied. It is configured. Thereby, it is possible to select whether or not to output a disconnection signal when no power is supplied.

  Furthermore, the disconnection output circuit 42 outputs no disconnection signal, and energization and abnormality occur when the energization is normal and no energization occurs in both the first state and the second state. A disconnection signal is output when there is an abnormal energization. Therefore, it is possible to select whether or not to output a disconnection signal indicating a non-energized state at the time of non-energization, and it is possible to output a disconnection signal even when an abnormality occurs.

  In the above-described embodiment, the disconnection of the relay wiring 11 has been described as an example of the abnormality in the energization abnormality. However, other abnormality may be used, and the wireless relay power supply device 1 has the abnormality. The configuration may be such that when it occurs, a disconnection signal that disconnects between the pair of reception wirings 12 is output as a signal indicating an abnormal state.

  That is, based on the presence / absence of other abnormalities, or including the presence / absence of other abnormalities, it may be set as normal energization or abnormal energization. It may be an abnormality caused by the device 1 itself (for example, a power failure of an AC power supply), an abnormality signal received from the wireless repeater 4 (for example, abnormal battery exhaustion of the wireless sensor 3), or the like.

Embodiment 2. FIG.
Next, the wireless relay power supply device 1 according to Embodiment 2 of the present invention will be described. FIG. 5 is a circuit diagram showing a wireless repeater power supply apparatus 1 according to Embodiment 2 of the present invention. The second embodiment is an invention different from the first embodiment in that the information can be blocked from being transferred when the AC power source is cut off (power failure). You may combine with the form 1. In the second embodiment, portions common to the first embodiment are denoted by the same reference numerals, description thereof is omitted, and differences from the first embodiment will be mainly described.

  The wireless repeater power supply device 1 includes a transition relay 30, a transition switching unit 90, a ninth jumper terminal 81, a tenth jumper terminal 82, and a transition control unit 99. The transfer relay 30 is connected to a transfer terminal 98 for transferring an abnormality (power failure) of the AC power supply. The ninth jumper terminal 81 is connected to the message switching unit 90. The tenth jumper terminal 82 is grounded when the AC power supply is abnormal, and is controlled by a transfer control unit 99 constituted by each element.

  The message switching unit 90 controls the operation of the message relay 30. The message switching unit 90 includes a message switching element 91, a message relay control unit 92, a fifth resistor 93, and a sixth resistor 94. The message switching element 91 is, for example, a bipolar transistor, and the third voltage source 96 and the ninth jumper terminal 81 are connected to the base, and the message relay control unit 92 and the fourth voltage source 97 are connected to the collector. The emitter is grounded. The transfer relay control unit 92 is configured by each element and controls the operation of the transfer relay 30. The relay relay controller 92 opens the relay relay 30 from between the transition terminals 98 when current flows, and connects between the transition terminals 98 when current does not flow.

  The fifth resistor 93 is provided downstream of the third voltage source 96. The sixth resistor 94 is connected to the base of the transfer switching element 91.

  Here, the ninth jumper terminal 81 and the tenth jumper terminal 82 are short-circuited by, for example, the third jumper 80. As described above, the wireless repeater power supply device 1 includes the third state in which the ninth jumper terminal 81 and the tenth jumper terminal 82 are short-circuited by the attachment of the third jumper 80, and the third jumper 80. One of the fourth states in which the ninth jumper terminal 81 and the tenth jumper terminal 82 are opened by the removal is selected.

  Next, the operation of setting the third jumper 80 of the wireless repeater power supply device 1 will be described. First, the case of the third state in which the third jumper 80 is attached will be described. When the supply of AC power is cut off, the transfer control unit 99 is grounded, and the tenth jumper terminal 82 and the ninth jumper terminal 81 are also grounded. Therefore, current flows in the order of the third voltage source 96, the fifth resistor 93, the ninth jumper terminal 81, and the tenth jumper terminal 82.

  As a result, no current flows through the base of the transfer switching element 91. Therefore, the transition switching element 91 is turned off, and no current flows from the collector to the emitter of the transition switching element 91. Therefore, since no current flows through the relay relay control unit 92, the relay relay 30 is connected between the relay terminals 98. Therefore, when the AC power supply is cut off, the information is transferred to the external device.

  Next, the case of the fourth state in which the third jumper 80 is removed will be described. When the supply of AC power is cut off, the transfer control unit 99 is grounded and the tenth jumper terminal 82 is grounded, but the tenth jumper terminal 82 and the ninth jumper terminal 81 are open. Therefore, the ninth jumper terminal 81 is not grounded. Therefore, a current flows in the order of the third voltage source 96, the fifth resistor 93, the sixth resistor 94, and the base of the transition switching element 91.

  Therefore, the transition switching element 91 is turned on, and a current flows from the collector of the transition switching element 91 to the emitter. For this reason, since the current flows in the order of the fourth voltage source 97, the transition relay control unit 92, the collector of the transition switching element 91, and the emitter of the transition switching element 91, the current flows through the transition relay control unit 92. . Therefore, the relay relay 30 is opened from between the transition terminals 98. Therefore, when the AC power supply is cut off, the information is blocked from being transferred to an external device.

  Next, the operation of the wireless relay power supply device 1 will be described. In the wireless repeater power supply device 1, the third state in which the ninth jumper terminal 81 and the tenth jumper terminal 82 are short-circuited, and the ninth jumper terminal 81 and the tenth jumper terminal 82 are open. One of the fourth states to be performed is selected. As described above, in the third state, when the AC power supply is shut off, the information is transferred to an external device. In the fourth state, when the AC power supply is shut off, the information is not transferred to an external device. Accordingly, the wireless relay power supply device 1 can select whether or not to transfer to an external device when the AC power supply is cut off.

  Thereby, when the power supply device 1 for a wireless repeater is subjected to maintenance and inspection, even if the AC power supply is cut off, transfer to an external device can be cut off.

  In addition, the third state is realized by attaching the third jumper 80, and the fourth state is realized by removing the third jumper 80. Therefore, the presence or absence of the transfer when the AC power supply is shut off can be selected by attaching and detaching the third jumper 80.

  In all the embodiments, the wireless relay power supply device 1 has been described as an example of the relay device. However, other relay devices may be used and interposed between the terminal device and the receiver. Any device that relays the signal from the terminal device to the receiver may be used. The terminal device is not limited to wiring, and may be configured to be connected wirelessly. For example, the wireless repeater 4 in the embodiment may be a relay device, and the wireless sensor 3 may be a terminal device.

  DESCRIPTION OF SYMBOLS 1 Power supply device for wireless repeaters, 2 Alarm systems, 3 Wireless sensors, 4 Wireless repeaters, 5 Receivers, 11 Relay wires, 12 Receive wires, 13 Power wires, 14 Backup power, 14a Panel switch, 14b Battery Test circuit, 15 relay termination resistor, 16 terminator, 21 relay terminal, 22a first reception terminal, 22b second reception terminal, 25 relay disconnection monitoring circuit, 26 power supply circuit, 27 control circuit, 28 power supply terminal, 29a first 1 terminal terminal, 29b second terminal terminal, 30 transmission relay, 31 LED, 32 wiring terminal block, 33 transmission terminal block, 42 disconnection output circuit, 43 third switching element, 44 resistance, 45 first Resistor, 46 second resistor, 47 third resistor, 48 fourth resistor, 50 first jumper, 51 first jumper terminal, 52 second jumper end 53 fifth jumper terminal, 54 sixth jumper terminal, 55 second jumper, 56 third jumper terminal, 57 fourth jumper terminal, 58 seventh jumper terminal, 59 eighth jumper terminal, 60 Switching unit, 61 first relay switching element, 62 second relay switching element, 63 relay control unit, 65 relay, 66 first relay terminal, 67 second relay terminal, 68 relay base terminal, 70 energization control unit , 71 1st voltage source, 72 2nd voltage source, 80 3rd jumper, 81 9th jumper terminal, 82 10th jumper terminal, 90 message switching unit, 91 message switching element, 92 message Relay control unit, 93 fifth resistor, 94 sixth resistor, 96 third voltage source, 97 fourth voltage source, 98 transmission terminal, 99 Transfer control unit.

Claims (3)

It is interposed between the terminal device and the receiver, and relays the signal from the terminal device to the receiver, and is connected to the receiver via a pair of receiving wirings. A relay device capable of selecting whether or not to output a disconnection signal for disconnecting between the pair of reception wires as a signal indicating a state,
A relay connected to the other of the receiving wiring;
A fourth jumper terminal connected to the relay;
A third jumper terminal connected to one of the receiving wirings,
The relay is
Connecting the other of the reception wiring and the fourth jumper terminal when no power is supplied;
Between the third jumper terminal and the fourth jumper terminal,
Either a non-short-circuit state or a short-circuit state is selected,
In the non-short-circuit state, the disconnection signal is output when no power is supplied,
In the short-circuit state, the relay device is configured so that the disconnection signal is not output when no power is supplied. A first receiving terminal connected to one of the pair of receiving wires;
A second receiving terminal connected to the other of the pair of receiving wires;
One end of a terminator and a first termination terminal connected to the first reception terminal;
A second termination terminal connected to the other end of the terminator,
The relay is
A relay base terminal and a second relay terminal, the relay base terminal connected to the second receiving terminal, the second relay terminal connected to the fourth jumper terminal, and the relay It is configured to switch whether or not to connect the base terminal and the second relay terminal, and further, when no power is supplied, the relay base terminal and the second relay terminal are connected, Connecting the other of the reception wiring and the fourth jumper terminal,
The third jumper terminal is
Connected to the second terminal terminal;
In the non-short-circuit state, the disconnection signal is output by disconnecting the reception wiring and the terminator when there is no energization,
2. The relay device according to claim 1, wherein in the short-circuit state, the disconnection signal is not output by connecting the reception wiring and the terminator when no power is supplied. The terminal device;
The receiver;
A relay device according to claim 1 or 2 ,
The receiver includes
An alarm system comprising a reception alarm unit that outputs a reception disconnection alarm when a disconnection signal transmitted from the relay device is received.

Images