JPH0670090U - Additional DC power supply for reception control panel - Google Patents

Abstract

(57) [Summary] [Purpose] A single DC power supply unit for a reception control panel that is added as a separate power source to the main DC power supply unit installed in the reception control panel for reporting abnormalities such as fire and gas leakage. With this device, it is possible to adopt a power output format that suits the type of load, and the wiring between the main unit and the operation panel can be simplified. [Composition] A relay contact 38a which is opened / closed by a control signal from the outside and an output changeover switch 31 which is turned on / off are arranged in parallel on a line for applying a DC power supply voltage to a power supply output terminal for connecting a detector or a load. Depending on the load connected to the power supply output terminal, it is possible to switch the output format between constant voltage output and voltage output only during relay control. In addition to a terminal device equipped with input / output terminals for signal lines from the outside, a connector device in which each input / output terminal of the terminal device is connected in parallel to the connector terminal is provided, enabling external connection by terminal connection or connector connection. And

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to an additional DC power supply unit for a reception control panel, which is added as a separate power supply to the main DC power supply unit installed in the reception control panel for reporting an abnormality such as a fire or a gas leak.

[0002]

[Prior art]

 Conventionally, the reception control panel of the fire alarm system has been equipped with a DC power supply device with a power capacity that matches the load such as the sensor, bell, and indicator light connected to the reception control panel. The DC power supply unit installed on the reception control panel is used for fire detector power supplies, gas leak detector power supplies, bell control power supplies, fire door release control power supplies, damper and smoke exhaust control power supplies, indicator light power supplies, etc. There are various.

[0003]

[Problems to be Solved by the Invention]

 However, when a large number of bells, indicator lights, etc. are connected, the standard DC power supply device prepared in advance for the reception control panel lacks the power supply capacity. In order to deal with such a shortage of power supply capacity, it is possible to prepare multiple types of DC power supply devices with different power supply capacities and select and use the device that matches the power supply capacity of the load. If a large number of devices having different power supply capacities are prepared in this way, the production efficiency becomes poor and the cost increases.

Therefore, an additional DC power supply unit is separately prepared from the standard DC power supply unit, and a required number of additional DC power supply units are added according to the power capacity of the load to be used as a separate power source. It is desirable to do. However, the load of the DC power supply of the reception control panel, such as fire detector power supply, gas leak detector power supply, indicator light power supply, etc., which constantly supplies power, bell control power supply, fire door release There is a load that supplies power only during control, such as a control power supply, damper or smoke exhaust control power supply, and an additional DC power supply that can output power according to the type of these loads must be prepared separately. There are at least two types of additional DC power supply equipment, and in this respect, production efficiency is poor and costs are increasing.

Furthermore, the DC power supply device used for the reception control panel is equipped with a backup power supply using a battery for power backup in the event of a power failure of the commercial AC power supply, and automatically switches to the power supply in the event of a power failure. It has a function. This backup power supply has a backup power supply test function to ensure backup performance in the event of a power failure, and a backup power supply test can be performed using a test signal from the outside or a test switch provided on the operation panel.

This point is the same for the extension DC power supply device. The main unit of the extension DC power supply device is installed in the panel, and at the same time, the operation panel is installed in front of the reception control panel and the signal line from the outside is installed. And the signal line with the operation panel is connected using the terminal block. However, the wiring between the main unit of the additional DC power supply unit using the terminal block and the operation panel becomes complicated because it requires wiring work inside the receiving panel, and it takes time to add the DC power supply unit. There was a problem.

The present invention has been made in view of the above-mentioned conventional problems, and a single device can take a power supply output format suitable for the type of load, and a main body unit and an operation panel. The aim is to provide an additional DC power supply unit for the reception control panel that can be easily wired.

[0008]

[Means for Solving the Problems]

 First of all, the present invention proposes a receiving control panel that is added as a separate power source to the main DC power supply unit installed in the receiving control panel that controls the load while notifying the abnormality by the signal from the detector such as fire and gas leakage. Applies to additional DC power supply. With respect to such an additional DC power supply device, the present invention provides a relay contact that is opened / closed by a control signal from the outside and is turned on / off in a line that applies a DC power supply voltage to a power output terminal that connects a load and a detector. It is characterized in that it can be connected in parallel with a power output switch and the output format can be switched between steady power output and voltage output only during relay control according to the load connected to the power output terminal.

The additional DC power supply device of the present invention is a connector device in which each input / output terminal of the terminal device is connected in parallel to a connector terminal, in addition to a terminal device having a connection terminal for input / output connection of an external signal line. Is provided, and connection to the outside is possible by terminal connection or connector connection.

[0010]

[Action]

 According to the additional DC power supply device of the present invention having such a configuration, if the output switching switch is opened, the power supply device of the output type suitable for the load requiring power supply during relay control can be provided. If the output selector switch is closed, an output type power supply device suitable for a load that requires constant power supply can be provided.

Further, since the connectors are connected in parallel to the terminal device in parallel, the connection with the operation panel installed on the receiving board can be easily made by connecting the connectors.

[0012]

【Example】

 FIG. 1 is an explanatory view showing an example of a reception control panel in which the expanded DC power supply device of the present invention is used. In FIG. 1, a main direct-current power supply device 2 that is installed as a standard is incorporated in the lower middle part of the reception control panel 1. If the main DC power supply 2 is insufficient in the power supply capacity of the load, the additional DC power supply 3 of the present invention is additionally provided.

On the upper part of the front panel of the reception control panel 1, there is provided a display section 5 provided with an alarm indicator light for each warning area. Below the display unit 5, an operation panel unit 4 of the expanded DC power supply device 3 is provided. An operation display unit 4a is provided at the center of the operation panel unit 4. FIG. 2 shows the operation panel unit 4 of FIG. 1 taken out and provided with a standby power source test switch 7, an AC power source lamp 8, a power source output lamp 9 and a standby power source unconnected lamp 10 on the operation display section 4a. . FIG. 3 is an enlarged view of the operation display unit 4a of FIG. 2, and the operation display unit 4a is provided with a handling explanation as a name plate. The backup power supply test switch 7 tests the battery provided in the main unit as a backup power supply.

The AC power supply lamp 8 uses a two-color LED, and lights up, for example, in green when the AC power supply is normally supplied. The AC power supply lamp 8 is also used as a standby power supply test lamp. After the standby power supply test switch 7 is pressed, it switches to red, and if the standby power supply is normal, it continues to turn on red. When the voltage drops, it goes off and informs of an abnormality in the standby power supply. The power output lamp lights up in green when power is being supplied to the load normally. Furthermore, the standby power non-connection lamp 10 lights up in red if the main unit does not have a battery.

FIG. 4 is a plan view showing the internal structure of the main unit of the additional DC power supply device 3 of the present invention. In FIG. 4, 11 is a power supply terminal to which a commercial AC100V power supply line is connected. A switching regulator 13 which operates as an AC-DC converter is provided on the right side of the power supply terminal 11. Further, five fuses 17 are provided near the power supply terminal 11, and an AC power switch 20 is further provided.

Reference numeral 14 is a battery used as a standby power source, and the battery 14 can be electrically connected to the unit body by a battery connector 15. An output selector switch 16 is provided on the left side of the battery connector 15, so that the power output format can be selected according to the type of load, which will be clarified later. A circuit unit 18 is provided on the left side of the output switching switch 16, and an external line terminal block 12 is provided on the upper side of the circuit unit 18 for terminal connection of signal lines from units other than the power supply device. The signal line connection with the operation panel unit 4 shown in FIG. 2 is made using a connector, and the connector is provided on the side surface of the main unit.

FIG. 5 is a circuit diagram of the main body unit shown in FIG. In FIG. 5, an AC power switch 20 is provided following the power terminals P1 and P2 to which commercial AC100V is supplied. The commercial AC 100V when the AC power switch 20 is turned on is input to the switching regulator 13, rectified and converted into a DC voltage, and then AC-DC converted into a predetermined DC voltage, for example, DC 24V.

Following the switching regulator 13, an AC power transfer relay 22 driven by a transistor 21 and a power switching relay 24 driven by a transistor 23 are provided. When the Zener diode ZD3 conducts at the normal DC output voltage 24V of the switching regulator 13, the transistors 21 and 23 receive the voltage generated across the resistor R4 through the resistors R5 and R6, and turn on.

Therefore, if the commercial AC 100V is normally obtained, both the transistors 21 and 23 are turned on, and the AC power supply transfer relay 22 and the power supply switching relay 24 are operating. The relay contact 22a of the AC power transfer relay 22 is connected to the lower terminals 1 and m, and serves as an AC power transfer output. The power source switching relay 24 has switching relay contacts 24a and 24b for switching to the standby power source.

The backup power source side will be described below. The output stage of the AC power switch 20 is branched, the voltage is reduced to AC56V by the power transformer 32, and rectified by the diode bridge 33. The rectified voltage of the diode bridge 33 charges the battery 14 connected as a standby power source via the relay contact 24a of the power source switching relay 24. For the battery 14, a standby power supply non-connection relay 36 driven by a transistor 35 is provided.

When the battery 14 is not connected, the diode bridge 33 obtains DC 56 V which is almost equal to the output voltage of the power supply transformer 32. On the other hand, when the battery 14 is connected, the voltage of the output stage of the diode bridge 33 is 24 V. Go down to. The Zener diode ZD1 connected to the base side of the transistor 35 becomes conductive at DC56V when the battery 14 is not connected, and becomes non-conductive at DC24V when the battery 14 is connected. Therefore, when the battery 14 is not connected, the Zener diode ZD1 is turned on to receive the bias due to the divided voltage of the resistors R1 and R2, the transistor 35 is turned on, and the standby power supply unconnected relay 36 is turned on. At the same time, the standby power non-connection lamp 10a connected in parallel is turned on.

The power supply line from the battery 14 is selectively connected to the power supply output line side via the relay contact 24 b of the power supply switching relay 24. Further, a relay contact 24 a of the power source switching relay 24 is also provided between the diode bridge 33 and the battery 14. The relay contact 24a is switched to the a side in the operating state of the power source switching relay 24 when the commercial AC 100V is normally obtained to charge the battery 14. At this time, the relay contact 24b is similarly switched to the side a to supply the output voltage of the switching regulator 13 to the load.

On the other hand, when the commercial AC 100V is cut off, the power source switching relay 24 is deactivated and the relay contacts 24a and 24b are switched to the b side. The relay contact 24a switched to the b side supplies the output voltage of the battery 14 to the LED 2 of the AC power supply lamp 8a and lights up in red indicating the switching to the standby power supply. At the same time, the relay contact 24b is switched to the b side, the output line of the switching regulator 13 is switched to the output line of the battery 14, and the standby power is supplied by the battery 14.

The LED 1 provided in the AC power supply lamp 8 a and lighting in green is driven by the transistor 25. The transistor 25 is driven by the transistor 23 that drives the power supply switching relay 24. That is, when the commercial AC 100V is normally obtained and the transistor 23 is turned on, the transistor 25 is turned on simultaneously with the operation of the power supply switching relay 24, and the green LED 1 provided in the AC power supply lamp 8a is driven to be lit.

Of course, when the commercial AC power supply AC100V is cut off, the transistor 25 is turned off, the green display by the LED disappears, and the red LED 2 is turned on by the voltage supply from the battery 14 via the switching relay contact 24a. Switch. A standby power supply test relay 26 is provided following the AC power supply lamp 8a. To the standby power supply test relay 26, the standby power supply test switch 27 and the relay contacts 37a of the standby power supply test external relay 37 connected to the lower terminals a− and a + are connected in parallel.

Further, wires from terminals m and o for external input of the preliminary power supply test are connected to the preliminary power supply test switch and the relay contact 37a. Therefore, the standby power supply test can be performed by any one of the following: test by turning on the backup power supply test switch 27, test by operation of the backup power supply test external relay 37, test by backup power supply test external input signal.

Here, taking the test by the standby power supply test switch 27 as an example, when the standby power supply test switch 27 is turned on, the backup power supply test relay 26 operates. The relay contact 26a of the standby power supply test relay 26 is provided on the emitter side of the transistor 23 that operates the power supply switching relay 24, and switches from the a side during non-testing to the b side during testing.

The b side of the relay contact 26a, which is closed during the test, is connected to the + side of the battery 14 via the test load resistor RD and the relay contact 26a. That is, when the standby power supply test switch 27 side is turned on, the relay contact 26a is switched from the a side to the b side by the operation of the standby power supply test relay 26, the transistor 23 is forcibly turned off, and the power supply switching relay 24 is deactivated. .

Therefore, the relay contact 24a is closed to the side b, and the discharge current is supplied from the battery 14 to the test dummy resistor RD. At the same time, the relay contact 24b is switched to the b side, and the battery 14 is tested as a supply state of the standby power supply from the battery 14 to the load. Following the standby power supply test relay 26 is a power supply output relay 30 which is operated by a transistor 29.

The transistor 29 is turned on by the Zener diode ZD 4 which is turned on when a specified DC output voltage is obtained from the switching regulator 13 or the battery 14, and operates the power output relay 30. The power output transfer relay 30 includes relay contacts 30a and 30b for the lower terminals f to k. Here, the relay contacts 26b of the standby power supply test relay 26 are further provided in the terminals f to h provided with the relay contacts 30a.

The relay contact 30a is closed to the side a when the power supply voltage is normal, and is switched to the side b when the power supply voltage drops and becomes abnormal. The relay contact 26b is normally open and is closed during the preliminary power supply test. Therefore, if the output voltage is normal in the standby power supply test, the terminals f and g are short-circuited, while if the output voltage is low and abnormal in the standby power supply test, the terminals g and h are short-circuited.

Therefore, for example, by driving the red LED of the AC power supply lamp 8 of the operation panel unit between the terminals f and g, the LED turns on red in the preliminary power supply test, and turns on green if the output voltage is normal. The state is maintained, and if the output voltage drops and it becomes abnormal, it goes out. Regarding the circuit of terminals i to k using the relay contact 30b of the power output transfer relay 30 for performing the normal power output transfer, the relay contact of the standby power supply test relay 26 is not provided and the output voltage is Is normal, the relay contact 30b is switched to the a side to short-circuit the terminals i and j, and when the output voltage drops and becomes abnormal, the relay contact 30b is switched to the b side to short-circuit the terminals j and k.

Following the power supply output relay 30, the power supply output terminals + V ₁₁ to + V ₂₂ on the positive side are connected between the power supply output control terminals b− and b + in order to switch the output form according to the load. A relay contact 38a of the power output control relay 38 and a power output switching switch 31 are provided. That is, for positive power supply terminal + V _11, + V _12, the relay contact 38a and the power output switch 31 of the power supply output control relay 38 are connected in parallel.

Therefore, when the power supply output changeover switch 31 is turned on, the output form is such that the power is always supplied. Further, when the power supply output changeover switch 31 is turned off, the relay contact 38a is closed only when the power supply output control relay 38 is operated, so that the power supply output can be supplied to the load. Furthermore, the power input side of the relay contact 38a and the power output switch 31 connected in parallel is connected directly the positive power supply terminal + V _21, the + V _22. For this reason, the power supply terminals + V ₂₁ and + V ₂₂ can be of an output type in which the voltage is constantly supplied regardless of the power supply output switching switch 31 and the relay contact 38a.

Further, in the present invention, as shown in the lower right corner, a connector 42 is provided which is connected in parallel to the terminals a to o which connect the external wires. In this embodiment, the connector 42 has connector terminals CN1-12. Of these, with respect to the connector terminals CN1 to CN9, the terminals m, e, f, a-, b-, a +, b +, and i are directly connected. On the other hand, with respect to the terminals CN11, 12, each of the terminals d, g, j, l and the connector terminals CN4, 10 can be selectively connected to the DIP switches 40a-40f.

The connector 42 makes a signal line connection with the operation panel unit shown in FIG. The dip switches 40a to 40f are appropriately selected according to an indicator light and a switch provided on the operation panel unit. Therefore, the signal line connection to the operation panel unit and the main unit can be easily made by connector connection instead of terminal connection.

FIG. 6 is an explanatory view showing an example of a power supply output format for a load in the main body unit of the present invention shown in FIG. For the sake of simplicity, the main part of the power supply circuit is collectively shown as a power supply circuit part 45 in one block. The output form of FIG. 6 is one in which the power supply output selector switch 31 is turned on without using the power supply output control relay 38, and a DC voltage is constantly supplied to the power supply terminals + V ₁₁ and + V ₁₂ , and, for example, the indicator light P or the like is fixed. The output format is for the load that supplies power constantly. Further, the power supply output terminal + V _21, for also + V _22, since a fixed steady power output, connect the load such Likewise indicator P.

FIG. 7 shows another example of the power output format according to the present invention, in which the power output switching switch 31 is turned off and the power output is controlled by turning on / off the power output control relay 38 from the outside. Terminal + V₁₁, + V₁₂It is characterized in that the load such as a bell connected to is controlled. In addition, the power supply output terminal + V which becomes the steady power supply output_{twenty one}, + V _{twenty two} In this case, it is an empty terminal.

Further, FIG. 8 shows another output format, in which the power output selector switch 31 is turned off to control the load such as the bell B by the relay contact 38a of the power output control relay 38 and the power output terminal. A load such as an indicator light P is connected to + V ₂₁ and + V ₂₂ to constantly supply power.

[0040]

[Effect of device]

 As described above, according to the present invention, even a load that requires a constant power supply by one additional DC power supply device is a load that requires a temporary power supply by relay control. However, it is possible to create an output format suitable for the type of load as needed, and it is sufficient to prepare one device even if the power supply format for the load is different.

Wiring work can be simplified by providing a connector in parallel with the terminal device for performing control input or transfer output to the device, and connecting the operation panel unit of the device to the connector, for example.

[Brief description of drawings]

FIG. 1 is an explanatory diagram of a reception control panel

FIG. 2 is an explanatory view showing a DC power supply operation unit taken out.

FIG. 3 is an enlarged explanatory view of the operation display unit of FIG.

FIG. 4 is an explanatory view of a main body unit of an additional DC power supply device according to the present invention.

5 is a circuit diagram of the main body unit of FIG.

FIG. 6 is an explanatory diagram of an output format for a steady load.

FIG. 7 is an explanatory diagram of an output format for a relay control load.

FIG. 8 is an explanatory diagram of output formats for both relay control load and steady load.

[Explanation of symbols]

 1: Reception control panel 2: Main DC power supply device 3: Extended DC power supply device 4: Operation panel unit 4a: Operation display unit 5: Display unit 6: Operation panel 7,27: Standby power supply test switch 8, 8a: AC power supply lamp 9: Power supply output light 10, 10a: Standby power supply non-connection light 11: Power supply terminals (P1, P2) 12: External line terminal block 13: Switching regulator 14: Battery (standby power supply) 15: Battery connector 16: Output changeover switch 17: Fuse 18: Circuit unit 20: Power switch 21, 23, 25, 29, 35: Transistor 22: AC power transfer relay 24: Power switching relay 26: Standby power test relay 28, 33: Diode bridge 30: Power output transfer Relay 31: Power output switch 32: Power transformer 36: Standby power unconnected relay 37:備電 source test External device 38: power supply output control relay 40 a to 40 f: DIP switch 42: Connector 45: power supply circuit unit

Claims (4)

[Scope of utility model registration request] 1. A reception control panel to be added as a separate power source to a main DC power supply unit provided in the reception control panel for notifying an abnormality by a signal from a detector such as a fire or gas leak and controlling a load. In the extension DC power supply device, a relay contact that is opened / closed by an external control signal and a power output changeover switch that is turned on / off are connected to the line that applies the DC power supply voltage to the power output terminal that connects the detector and load. Addition of a reception control panel characterized in that the output format can be switched between a steady power output and a power output only during relay control depending on the load connected to the power output terminal. DC power supply. 2. The additional DC power supply device for a reception control panel according to claim 1, further comprising another power output terminal fixedly connected to the power input side of the parallel circuit of the relay contact and the output changeover switch. An additional DC power supply device for a reception control panel, characterized in that a stationary power supply output can be taken out from the power supply output terminal regardless of the relay contact and the output changeover switch. 3. A reception control panel to be added as a separate power source to a main DC power supply unit provided in the reception control panel for notifying an abnormality by a signal from a detector such as a fire or gas leak and controlling a load. The extension DC power supply device includes a terminal device having a connection terminal for input / output connection of an external signal line, and a connector device having a connector terminal connected in parallel to each input / output terminal of the terminal device. The external DC power supply for the reception control panel is characterized in that it can be connected to the outside by terminal connection or connector connection. 4. The additional DC power supply device for a reception control panel according to claim 3, further comprising: a switch between the terminal device and the connector device for selecting connection of the connector terminal to the terminal device for each terminal. An additional DC power supply device for the reception control panel, which is characterized in that